CA3098152A1 - Methods of diagnosing and treating patients with cutaneous squamous cell carcinoma - Google Patents

Abstract

The present disclosure relates to methods for predicting the risk of recurrence and/or metastasis in primary cutaneous squamous cell carcinoma (cSCC).

Description

METHODS OF DIAGNOSING AND TREATING PATIENTS WITH CUTANEOUS
SQUAMOUS CELL CARCINOMA
CROSS REFERENCE TO RELATED APPLICATIONS
This application claims the benefit of U.S. Provisional Application No.
62/665,872, filed on May 2,2018, and U.S. Provisional Application No. 62/737,863, filed on September 27, 2018, both of which are incorporated by reference herein in their entirety.
FIELD OF THE DISCLOSURE
The present disclosure relates to methods for predicting the risk of recurrence and/or metastasis in primary cutaneous squamous cell carcinoma (cSCC).
BACKGROUND
Cutaneous squamous cell carcinoma (cSCC) is rivaled only by basal cell carcinoma as the most common cancer in the U.S. Though most cases are cured by excision, a subset recur .. and become incurable with the number of deaths approximating melanoma (Karia et Am. Acad. Dermatol. 68(6): 957-66 (2013)). Despite overall good prognosis for patients with cSCC, a subset will develop local, regional, or distant recurrences following complete excision of the primary tumor. Those at high risk of recurrence are eligible for adjuvant treatment options. While specific clinical features are associated with recurrence, they collectively fail to identify 30-40% of all cSCC recurrences and many tumors that possess high risk features will not recur. Prediction models with increased positive predictive values are needed to prevent unnecessary procedures. To address the need for more accurate predictive factors and facilitate appropriate intervention strategies, gene expression analysis was used to determine a signature associated with recurrence in patients with cSCC.
SUMMARY
There is a need in the art for a more objective method of predicting which tumors display aggressive metastatic activity. Development of an accurate molecular footprint, such as the gene expression profile assay disclosed herein, would be a significant advance forward .. for the field. A multi-center study using archived primary tissue samples with extensive capture of associated clinical data (subjects with pathologically confirmed cSCC diagnosed after 2006, minimum 2 years of follow-up, and two separate outcome measures:
nodal/distant metastasis and local recurrence) was used to identify gene expression profiles that accurately predict primary cSCC with a high risk of regional nodal/distant metastasis, and primary cSCC
with high risk of local recurrence after complete surgical clearance.
In one embodiment, a method for treating a patient with a cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising: (a) obtaining a diagnosis identifying a risk of local recurrence, distant metastasis, or both, in a cSCC tumor sample from the patient, wherein the diagnosis was obtained by: (1) determining the expression level of at least 10 genes in a gene set; wherein the at least 10 genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, Cl QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; (2) comparing the expression levels of the at least 10 genes in the gene set from the cSCC tumor sample to the expression levels of the at least 10 genes in the gene set from a predictive training set to generate a probability score of the risk of local recurrence, distant metastasis, or both, and; (3) providing an indication as to whether the cSCC tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the probability score generated in step (2); and (4) identifying that the cSCC tumor has a high risk of local recurrence, distant metastasis, or both, based on the probability score and diagnosing the cSCC tumor as having a high risk of local recurrence, distant metastasis, or both; (b) administering to the patient an aggressive treatment when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both. In certain embodiments, the method further comprises performing a resection of the cSCC tumor when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both.

2 In some embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR). In certain embodiments, the cSCC
tumor sample is obtained from formalin-fixed, paraffin embedded sample.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, .. NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above.
In another embodiment, a method of treating a patient with a cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising administering an aggressive cancer treatment regimen to the patient, wherein the patient has a cSCC tumor with a probability score of between 0.500 and 1.00 as generated by comparing the expression levels of at least 10 genes selected from ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB,

3 NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31 from the cSCC
tumor with the expression levels of the same at least ten genes selected from ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31 from a predictive training set. In one embodiment, the probability score is determined by a bimodal, two-class analysis, wherein a patient having a value of between 0 and 0.499 is designated as class 1 with a low risk of local recurrence, distant metastasis, or both, and a patient having a value of between 0.500 and 1.00 is designated as class 2 with an increased risk of local recurrence, distant metastasis, or both.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1,

4 PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above.
In another embodiment, a kit comprising primer pairs suitable for the detection and quantification of nucleic acid expression of at least ten genes is disclosed herein, wherein the at least ten genes are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
In some embodiments, the primer pairs suitable for the detection and quantification of nucleic acid expression of at least ten genes are primer pairs for: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38,

5 RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the primer pairs comprise primer pairs for 10 genes, 20 genes, 30 genes, 40 genes, or more than 40 genes of the genes listed above.
In another embodiment, a method for predicting risk of recurrence, metastasis, or both, in a patient with a cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising: (a) obtaining a cSCC tumor sample from the patient and isolating mRNA from the sample; (b) determining the expression level of at least 10 genes in a gene set; wherein the at least ten genes in the gene set are selected from:
ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 .. (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, .. PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; (c) comparing the expression levels of the at least 10 genes in the gene set from the cSCC tumor sample to the expression levels of the at least 10 genes in the gene set from a predictive training set to generate a probability score of the risk of local recurrence, distant metastasis, or both; and (d) providing an indication as to whether the cSCC
tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the probability score generated in step (c).
In some embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR). In certain embodiments, the cSCC
tumor sample is obtained from formalin-fixed, paraffin embedded sample. In one embodiment, the

6 method further comprises identifying the cSCC tumor as having a high risk of local recurrence, distant metastasis, or both, based on the probability score, and administering to the patient an aggressive tumor treatment.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above.
In another embodiment, a method for predicting risk of recurrence, metastasis, or both, in a patient with a cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising: (a) obtaining a cSCC tumor sample from the patient and isolating mRNA from the sample; (b) determining the expression level of at least 10 genes in a gene set; wherein the at least ten genes in the gene set are selected from:
ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38,

7 RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; and (c) providing an indication as to whether the cSCC tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the expression level of at least 10 genes generated in step (b).
In some embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR). In certain embodiments, the cSCC
tumor sample is obtained from formalin-fixed, paraffin embedded sample.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above.
In certain embodiments, the expression level of: ACSBG1 is decreased, AIM2 is increased, ALOX12 is decreased, ANXA9 is decreased, APOBEC3G is increased, ARPC2 is decreased, ATP6AP1 is decreased, ATP6V0E2 is increased, BBC is increased, BHLHB9 is decreased, BLOC1S1 is decreased, Cl QL4 is increased, C21orf59 is increased, C3orf70 is increased, CCL27 is decreased, CD163 is increased, CEP76 is decreased, CHI3L1 is increased, CHMP2B is decreased, CXCL10 is decreased, CXCR4 is increased, (L0C101929829) is decreased, DARS is decreased, DCT is decreased, DDAH1 is decreased,

8 DSS1 is decreased, DUXAP8 is increased, EGFR is increased, EphB2 is increased, is decreased, FDFT1 is decreased, FLG is decreased, FN1 is increased, GTPBP2 is decreased, HDDC3 is increased, HNRNPL is decreased, HOXA10 (HOXA9, MIR196B) is decreased, HPGD is decreased, ID2 is decreased, IL24 is increased, IL2RB is decreased, IL7R is increased, INHBA is increased, IPO5P1 is increased, KIT is increased, KLK5 is decreased, KRT17 is decreased, KRT18 is increased, KRT19 is decreased, KRT6B is decreased, LAMC2 is decreased, LCE2B is decreased, LIME1 (ZGPAT) is increased, L0C100287896 is increased, L0C101927502 is decreased, LOR is decreased, LRRC47 is increased, MIER2 is increased, MIR129-1 is increased, MIR3916 is increased, MKLN1 is increased, MMP1 is increased, MMP10 is decreased, MMP12 is increased, MMP13 is increased, MMP3 is increased, MMP7 is increased, MMP9 is decreased, MRC1 is increased, MRPL21 is increased, MSANTD4 is decreased, MYC is decreased, NEB is decreased, NEFL is decreased, NFASC is decreased, NFIA is decreased, NFIB is decreased, NFIC is decreased, NOA1 is increased, PD1 is decreased, PDL1 is increased, PDPN is increased, PI3 is decreased, PIG3 is decreased, PIGBOS1 is increased, PIM2 is increased, PLAU is increased, PLS3 is decreased, PTHLH is decreased, PTRHD1 is decreased, RBM33 is increased, RCHY1 is increased, RNF135 is increased, RPL26L1 is increased, RPP38 is decreased, RUNX3 is increased, S100A8 is decreased, S100A9 is decreased, SEPT3 is decreased, SERPINB2 is decreased, SERPINB4 is decreased, SLC1A3 is increased, SLC25A11 is increased, SNORD124 is increased, SPATA41 is increased, SPP1 is increased, TAF6L is increased, TFAP2B is decreased, THYN1 is increased, TMEM41B is decreased, TNNC1 is decreased, TUBB3 is decreased, TUFM (MIR4721) is increased, TYRP1 is decreased, UGP2 is decreased, USP7 is decreased, VIM is increased, YKT6 is increased, ZNF48 is increased, ZNF496 is increased, ZNF839 is increased, and/or ZSCAN31 is decreased. In certain embodiments, the increase or decrease in the expression level is the gene level from a recurrent tumor sample versus a non-recurrent tumor sample. In other embodiments, the increase or decrease in the expression level is the gene level from a metastatic tumor sample versus a non-metastatic tumor sample.
In another embodiment, a method for treating a patient with cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising: (a) obtaining a cSCC
tumor sample from the patient and isolating mRNA from the sample; (b) determining the expression level of at least 10 genes in a gene set; wherein the at least ten genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, Cl QL4, C21orf59, C3orf70, CCL27,

9 CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; (c) providing an indication as to whether the cSCC
tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the expression level of at least 10 genes generated in step (b); and (d) administering to the patient an aggressive treatment when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both.
In some embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR). In certain embodiments, the cSCC
tumor sample is obtained from formalin-fixed, paraffin embedded sample.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above.
Other aspects, embodiments, and implementations will become apparent from the following detailed description and claims, with reference, where appropriate, to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows the study design workflow.
FIG. 2 shows the differential expression of 18 genes found to be significantly differentially expressed between recurrent (Rec) and non-recurrent (NR) cSCC cases FIG. 3 shows another exemplary study design workflow.
FIG. 4 shows a metastasis-free survival curve for low risk, Class 1, and high-risk, Class 2, tumors using the 20-1 gene set.
DETAILED DESCRIPTION
Despite overall good prognosis for patients with cSCC, a subset will develop local, regional, or distant recurrences following complete excision of the primary tumor. Those at high risk of recurrence are eligible for adjuvant treatment options. While specific clinical features are associated with recurrence, they collectively fail to identify 30-40% of all cSCC
recurrences and many tumors that express high risk features will not recur. To address the need for more accurate predictive factors and facilitate appropriate intervention strategies, a gene expression analysis was used to determine a signature associated with recurrence in cSCC. In that analysis, 140 candidate genes were selected for evaluation of gene expression changes in recurrent and non-recurrent cases. A total of 230 primary cSCC
tumors were collected under an IRB-approved, multi-center protocol and analyzed. After quality filtering, expression of the genes was assessed across 212 samples. Multiple subsets of genes were significantly differentially expressed between recurrent and non-recurrent cases. The results demonstrate that gene expression differences can distinguish between recurrent and non-recurrent cSCC. Such gene expression differences can help identify those patients who might benefit from additional therapeutic interventions and treatments.
Unless otherwise defined, all technical and scientific terms used herein have the same meaning as would be commonly understood by one of ordinary skill in the art to which the claimed invention belongs. Although methods and materials similar or equivalent to those described herein can be used to practice the methods and kits disclosed or claimed herein, suitable methods and materials are described below. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety.
In case of conflict, the present specification, including definitions, will control. In addition, the materials, methods, and examples are illustrative only and are not intended to be limiting.
Other features and advantages of the claimed invention will be apparent from the following detailed description.
As used herein, the singular forms "a," "an," and "the" include plural referents unless the context clearly dictates otherwise. For example, reference to "a nucleic acid" means one or more nucleic acids.
It is noted that terms like "preferably," "commonly," and "typically" are not utilized herein to limit the scope of the claimed invention or to imply that certain features are critical, essential, or even important to the structure or function of the claimed invention. Rather, these terms are merely intended to highlight alternative or additional features that can or cannot be utilized in a particular embodiment disclosed or claimed herein.
As used herein, the terms "polynucleotide," "nucleotide," "oligonucleotide,"
and "nucleic acid" can be used interchangeably to refer to nucleic acid comprising DNA, cDNA, RNA, derivatives thereof, or combinations thereof In an embodiment, a method for treating a patient with a cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising: (a) obtaining a diagnosis identifying a risk of local recurrence, distant metastasis, or both, in a cSCC tumor sample from the patient, wherein the diagnosis was obtained by: (1) determining the expression level of at least 10 genes in a gene set; wherein the at least 10 genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, Cl QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; (2) comparing the expression levels of the at least 10 genes in .. the gene set from the cSCC tumor sample to the expression levels of the at least 10 genes in the gene set from a predictive training set to generate a probability score of the risk of local recurrence, distant metastasis, or both, and; (3) providing an indication as to whether the cSCC tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the probability score generated in step (2); and (4) identifying that the cSCC tumor has a high risk of local recurrence, distant metastasis, or both, based on the probability score and diagnosing the cSCC tumor as having a high risk of local recurrence, distant metastasis, or both; (b) administering to the patient an aggressive treatment when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both. In certain embodiments, the method further comprises performing a resection of the cSCC tumor when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both.
In some embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR). In certain embodiments, the cSCC
tumor sample is obtained from formalin-fixed, paraffin embedded sample.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRPI, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above.
In an embodiment, a method of treating a patient with a cutaneous squamous cell .. carcinoma (cSCC) tumor is disclosed herein, the method comprising administering an aggressive cancer treatment regimen to the patient, wherein the patient has a cSCC tumor with a probability score of between 0.500 and 1.00 as generated by comparing the expression levels of at least 10 genes selected from ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31 from the cSCC
tumor with the expression levels of the same at least ten genes selected from ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRPI, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31 from a predictive training set. In one embodiment, the probability score is determined by a bimodal, two-class analysis, wherein a patient having a value of between 0 and 0.499 is designated as class 1 with a low risk of local recurrence, distant metastasis, or both, and a patient having a value of between 0.500 and 1.00 is designated as class 2 with an increased risk of local recurrence, distant metastasis, or both.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, .. MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above.
As used herein, the term "recurrence" refers to the recurrence or disease progression that may occur locally (such as local recurrence and in transit disease), regionally (such as nodal micrometastasis or macrometastasis), or distally (such as brain, lung and other tissues).
Risk, as used herein, includes low-risk or high-risk of metastasis according to any of the statistical methods disclosed herein. In one embodiment, risk of recurrence or metastasis for cSCC can be classified from a low risk to a high risk (for example, the cSCC
tumor has a graduated risk from low risk to high risk or high risk to low risk of local recurrence, .. locoregional recurrence, or distant metastasis). In other embodiments, low risk refers to a 5-year relapse-free survival rate, a 5-year metastasis free survival rate, or a 5-year disease specific survival rate of greater than 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, or more than 95%, and high risk refers to a 5-year relapse-free survival rate, a 5-year metastasis free survival rate, or a 5-year disease specific survival rate of less than 50%, 45%, 40%, 35%, 30%, 25%, 20%, 15%, 10%, 5%, or less than 5%.
In certain embodiments, risk stratifications may be binned, for example a group with an arbitrary designation Class A may be selected based on recurrence risk of less than 25%, 20%, 15%, 10%, 5%, or less than 5%. A group with arbitrary designation Class B
may be selected based on a risk of 75%, 70%, 65%, 60%, 55%, 50%, 45%, 40%, 35%, 30%, 25%, or any number in between. A group with arbitrary designation Class C may be selected based on a risk of 75%, 80%, 85%, 90%, 95%, or higher than 95%. These class designations may comprise more than three groups or as few as two groups depending on the separation characteristics of the predictive algorithm. A person familiar with the art will be able to determine the optimal binning strategy depending on the distributions of class probability scores developed by modeling.
As used herein, the term "metastasis" refers to the recurrence or disease progression that may occur locally, regionally (such as nodal metastasis), or distally (such as distant metastasis to the brain, lung and other tissues). Class 1 or class 2 of metastasis, as used herein, includes low-risk (class 1; for example, having a 5-year relapse-free survival rate, a 5-year metastasis free survival rate, or a 5-year disease specific survival rate of greater than 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, or more than 95%) or high-risk (class 2; for example, having a 5-year metastasis free survival rate, or a 5-year disease .. specific survival rate of less than 50%, 45%, 40%, 35%, 30%, 25%, 20%, 15%,

10%, 5%, or less than 5%) of metastasis according to any of the statistical methods disclosed herein. Class A, Class B, or Class C of metastasis, as used herein, includes low-risk (class A; for example having a recurrence risk of less than 25%, 20%, 15%, 10%, 5%, or less than 5%), intermediated risk (class B; for example having a recurrence risk of 75%, 70%, 65%, 60%, 55%, 50%, 45%, 40%, 35%, 30%, 25%, or any number in between) or high-risk (class C; for example, having a recurrence risk of 75%, 80%, 85%, 90%, 95%, or higher than 95%) of metastasis according to any of the statistical methods disclosed herein. The term "distant metastasis" as used herein, refers to metastases from a primary cSCC tumor that are disseminated widely. Patients with distant metastases require aggressive treatments, which .. can eradicate metastatic cSCC, prolong life, and/or cure some patients.
As used herein, the terms "locoregional recurrence" and "local recurrence" can be used interchangeably and refer to cancer cells that have spread to tissue immediately surrounding the primary cSCC tumor or were not completely ablated or removed by previous treatment or surgical resection. Locoregional recurrences are typically resistant to chemotherapy and radiation therapy. Locoregional recurrence can be difficult to control and/or treat if: (1) the primary cSCC tumor is located or involves a vital organ or structure that limits the potential for treatment; (2) recurrence after surgery or other therapy occurs, because while likely not a result from metastasis, high rates of recurrence indicate an advanced cSCC tumor; and (3) presence of lymph node metastases, while rare in cSCC, indicate advanced disease.
In some embodiments, the methods described herein can comprise determining that the cSCC tumor has an increased risk of metastasis or decreased overall survival by combining with clinical staging factors recommended by, for example, the American Joint Committee on Cancer (AJCC), the Brigham Women's Hospital (BWH), or the National Comprehensive Cancer Network (NCCN), to stage the primary cSCC tumor, or other histological features associated with risk of cSCC tumor metastasis or disease-related death.
As used herein, the terms "cutaneous squamous cell carcinoma" or "cSCC" or "SCC"
refer to any cutaneous squamous cell carcinoma, regardless of tumor size, in patients without clinical or histologic evidence of regional or distant metastatic disease. A
cutaneous squamous cell carcinoma sample may be obtained through a variety of sampling methods such as punch biopsy, shave biopsy, surgical excision, core needle biopsy, incisional biopsy, endoscope ultrasound (EUS) guided-fine needle aspirate (FNA) biopsy, percutaneous biopsy, and other means of extracting RNA from the primary cSCC tumor. A carcinoma is a type of cancer that develops from epithelial cells. Specifically, a carcinoma is a cancer that begins in a tissue that lines the inner or outer surfaces of the body, and that arises from cells originating in the endodermal, mesodermal, and ectodermal germ layer during embryogenesis.
Squamous cell carcinomas have observable features and characteristics indicative of squamous differentiation (e.g., intercellular bridges, keratinization, squamous pearls). The most recognized risk factor for cSCC is exposure to sunlight; thus, most cSCC
tumors develop on sun-exposed skin sites, for example, the head or neck area. They can also be found on the face, ears, lips, trunk, arms, legs, hands, or feet. Squamous cell carcinoma is the second most common skin cancer.
As used herein, "overall survival" (OS) refers to the percentage of people in a study or treatment group who are still alive for a certain period of time after they were diagnosed with or started treatment for a disease, such as cancer. The overall survival rate is often stated as a five-year survival rate, which is the percentage of people in a study or treatment group who are alive five years after their diagnosis or the start of treatment.
The phrase "measuring the gene-expression levels" or "determining the gene-expression levels," as used herein, refers to determining or quantifying RNA
or proteins expressed by the gene or genes. The term "RNA" includes mRNA transcripts, and/or specific spliced variants of mRNA. The term "RNA product of the gene," as used herein, refers to RNA transcripts transcribed from the gene and/or specific spliced variants. In some embodiments, mRNA is converted to cDNA before the gene expression levels are measured.
With respect to proteins, gene expression refers to proteins translated from the RNA
transcripts transcribed from the gene. The term "protein product of the gene"
refers to proteins translated from RNA products of the gene. A number of methods can be used to detect or quantify the level of RNA products of the gene or genes within a sample, including microarrays, Real-Time PCR (RT-PCR; including quantitative RT-PCR), nuclease protection assays, RNA-sequencing, and Northern blot analyses. In one embodiment, the assay uses the APPLIED BIOSYSTEMSTm HT7900 fast Real-Time PCR system. In addition, a person skilled in the art will appreciate that a number of methods can be used to determine the amount of a protein product of a gene of the methods disclosed herein, including immunoassays such as Western blots, ELISA, and immunoprecipitation followed by SDS-PAGE and immunocytochemistry. In certain embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR).
A person skilled in the art will appreciate that a number of detection agents can be used to determine gene expression. For example, to detect RNA products of the biomarkers, probes, primers, complementary nucleotide sequences, or nucleotide sequences that hybridize to the RNA products can be used. In another example, to detect cDNA products of the biomarkers, probes, primers, complementary nucleotide sequences, or nucleotide sequences that hybridize to the cDNA products can be used. To detect protein products of the biomarkers, ligands or antibodies that specifically bind to the protein products can be used.
As used herein, the term "hybridize" refers to the sequence specific non-covalent binding interaction with a complementary nucleic acid. In one embodiment, the hybridization is under high stringency conditions. Appropriate stringency conditions that promote hybridization are known to those skilled in the art.
As used herein, the terms "probe" and "primer" refer to a nucleic acid sequence that will hybridize to a nucleic acid target sequence. In one example, the probe and/or primer hybridizes to an RNA product of the gene or a complementary nucleic acid sequence. In another example, the probe and/or primer hybridizes to a cDNA product. The length of probe or primer depends on the hybridizing conditions and the sequences of the probe or primer and nucleic acid target sequence. In one embodiment, the probe or primer is at least 8, 10, 15, 20, 25, 50, 75, 100, 150, 200, 250, 400, 500, or more than 500 nucleotides in length. Probes and/or primers may include one or more label. Probes and/or primers may be commercially .. sourced from various providers (e.g., ThermoFisher Scientific). In certain embodiments, a label may be any substance capable of aiding a machine, detector, sensor, device, or enhanced or unenhanced human eye from differentiating a labeled composition from an unlabeled composition. Examples of labels include, but are not limited to: a radioactive isotope or chelate thereof, dye (fluorescent or non-fluorescent), stain, enzyme, or nonradioactive metal. Specific examples include, but are not limited to:
fluorescein, biotin, digoxigenin, alkaline phosphates, biotin, streptavidin, 3H, 14c,32P, S, or any other compound capable of emitting radiation, rhodamine, 4-(4'-dimethylamino-phenylazo)benzoic acid; 4-(4'-dimethylamino-phenylazo)sulfonic acid (sulfonyl chloride); 5-((2-aminoethyl)-amino)-naphtalene-1-sulfonic acid; Psoralene derivatives, haptens, cyanines, acridines, fluorescent rhodol derivatives, cholesterol derivatives; ethylene-diamine-tetra-acetic acid and derivatives thereof, or any other compound that may be differentially detected. The label may also include one or more fluorescent dyes. Examples of dyes include, but are not limited to: CAL-Fluor Red 610, CAL-Fluor Orange 560, dR110, 5-FAM, 6FAM, dR6G, JOE, HEX, VIC, TET, dTAMRA, TAMRA, NED, dROX, PET, BHQ+, Gold540, and LIZ.
As used herein, a "sequence detection system" is any computational method in the art that can be used to analyze the results of a PCR reaction. One example is the APPLIED
BIOSYSTEMSTm HT7900 fast Real-Time PCR system. In certain embodiments, gene expression can be analyzed using, e.g., direct DNA expression in microarray, Sanger sequencing analysis, Northern blot, the NANOSTRINGO technology, serial analysis of gene expression (SAGE), RNA-seq, tissue microarray, or protein expression with immunohistochemistry or western blot technique. PCR generally involves the mixing of a nucleic acid sample, two or more primers that are designed to recognize the template DNA, a DNA polymerase, which may be a thermostable DNA polymerase such as Taq or Pfu, and deoxyribose nucleoside triphosphates (dNTP's). Reverse transcription PCR, quantitative reverse transcription PCR, and quantitative real time reverse transcription PCR are other specific examples of PCR. In real-time PCR analysis, additional reagents, methods, optical detection systems, and devices known in the art are used that allow a measurement of the magnitude of fluorescence in proportion to concentration of amplified DNA. In such analyses, incorporation of fluorescent dye into the amplified strands may be detected or measured. In one embodiment, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR).
As used herein, the terms "differentially expressed" or "differential expression" refer to a difference in the level of expression of the genes that can be assayed by measuring the level of expression of the products of the genes, such as the difference in level of messenger RNA transcript expressed (or converted cDNA) or proteins expressed of the genes. In one embodiment, the difference can be statistically significant. The term "difference in the level of expression" refers to an increase or decrease in the measurable expression level of a given gene as measured by the amount of messenger RNA transcript (or converted cDNA) and/or the amount of protein in a sample as compared with the measurable expression level of a given gene in a control, or control gene or genes in the same sample (for example, a non-recurrence sample). In another embodiment, the differential expression can be compared using the ratio of the level of expression of a given gene or genes as compared with the expression level of the given gene or genes of a control, wherein the ratio is not equal to 1Ø
For example, an RNA, cDNA, or protein is differentially expressed if the ratio of the level of expression in a first sample as compared with a second sample is greater than or less than 1Ø
For example, a ratio of greater than 1, 1.2, 1.5, 1.7, 2, 3, 3, 5, 10, 15, 20, or more than 20, or a ratio less than 1, 0.8, 0.6, 0.4, 0.2, 0.1, 0.05, 0.001, or less than 0.0001.
In yet another embodiment, the differential expression is measured using p-value. For instance, when using p-value, a biomarker is identified as being differentially expressed as between a first sample and a second sample when the p-value is less than 0.1, less than 0.05, less than 0.01, less than 0.005, or less than 0.001.
The terms "increased expression" or "decreased expression," as used herein, refer to an expression level of one or more genes, or prognostic RNA transcripts, or their corresponding cDNAs, or their expression products that has been found to be differentially expressed in recurrent versus non-recurrent cSCC tumors. The higher the expression level of a gene that predominantly has increased expression in tumors of patients who had recurrence, the higher is the likelihood that the patient suffering from this tumor is expected to have a poor clinical outcome (i.e., higher risk of recurrence, metastasis, or both).
In contrast, the lower the expression level of a gene that predominantly has increased expressed in tumors of patients who have recurrent tumors, the higher is the likelihood that the patient suffering from this tumor is expected to have a promising clinical outcome (i.e., decreased risk of recurrence, metastasis, or both). The lower the expression level of a gene that predominantly has decreased expression in tumors of patients who had recurrence, the higher is the likelihood that the patient suffering from this tumor is expected to have a poor clinical outcome (i.e., higher risk of recurrence, metastasis, or both). In contrast, the higher the expression level of a gene that predominantly has decreased expressed in tumors of patients who have recurrent tumors, the higher is the likelihood that the patient suffering from this tumor is expected to have a promising clinical outcome (i.e., decreased risk of recurrence, metastasis, or both).
References herein to the "same" level of biomarker indicate that the level of biomarker measured in each sample is identical (i.e., when compared to the selected reference). References herein to a "similar" level of biomarker indicate that levels are not identical but the difference between them is not statistically significant (i.e., the levels have comparable quantities).
As used herein, the terms "control" and "standard" refer to a specific value that one can use to determine the value obtained from the sample. In one embodiment, a dataset may be obtained from samples from a group of subjects known to have a cutaneous squamous cell carcinoma or subtype. The expression data of the genes in the dataset can be used to create a control (standard) value that is used in testing samples from new subjects. In such an embodiment, the "control" or "standard" is a predetermined value for each gene or set of genes obtained from subjects with a cutaneous squamous cell carcinoma whose gene expression values and tumor types are known. In certain embodiments of the methods disclosed herein, non-limiting examples of control genes can include, but are not limited to, BAG6 (probe ID: Hs00190383), KMT2D/MLL2 (probe ID: Hs00912419 ml), MDM2 (probe ID: Hs00540450 sl), FXR1 (probe ID: Hs01096876_g1), KMT2C (probe ID:
Hs01005521 ml), MDM4 (probe ID: Hs00967238 ml), VIM, and NF1B. In some embodiments, a control population may comprise healthy individuals, individuals with cancer, or a mixed population of individuals with or without cancer. In certain embodiments, a control population may comprise individuals with non-metastatic cancer or cancer that did not recur.
As used herein, the term "normal" when used with respect to a sample population refers to an individual or group of individuals that does/do not have a particular disease or condition (e.g., cSCC or recurrent cSCC) and is also not suspected of having or being at risk for developing the disease or condition. The term "normal" is also used herein to qualify a biological specimen or sample (e.g., a biological fluid) isolated from a normal or healthy individual or subject (or group of such subjects), for example, a "normal control sample."
The "normal" level of expression of a marker is the level of expression of the marker in cells in a similar environment or response situation, in a patient not afflicted with cancer. A
normal level of expression of a marker may also refer to the level of expression of a "reference sample" (e.g., a sample from a healthy subject not having the marker associated disease). A reference sample expression may be comprised of an expression level of one or more markers from a reference database. Alternatively, a "normal" level of expression of a marker is the level of expression of the marker in non-tumor cells in a similar environment or response situation from the same patient that the tumor is derived from.
As used herein, the terms "gene-expression profile," "GEP," or "gene-expression profile signature" refer to any combination of genes, the measured messenger RNA transcript expression levels, cDNA levels, or direct DNA expression levels, or immunohistochemistry levels of which can be used to distinguish between two biologically different corporal tissues and/or cells and/or cellular changes. In certain embodiments, a gene-expression profile is comprised of the gene-expression levels of at least 140, 139, 138, 137, 136, 135, 134, 133, 132,131, 130, 129, 128, 127, 126, 125, 124, 123, 122, 121, 120, 119, 118, 117, 116, 115, 114, 113, 112, 111, 110, 109, 108, 107, 106, 105, 104, 103, 102, 101, 100, 99, 98, 97, 96, 95, 94, 93, 92, 91, 90, 89, 88, 87, 86, 85, 84, 83, 82, 81, 80, 79, 78, 77, 76, 75, 74, 73, 72, 71, 70, 69, 68, 67, 66, 65, 64, 63, 62, 61, 60, 59, 58, 57, 56, 55, 54, 53, 52, 51, 50, 49, 48, 47, 46, 45, 44, 43, 42, 41, 40, 39, 38, 37, 36, 35, 34, 33, 32, 31, 30, 29, 28, 27, 26, 25, 24, 23, 22, 21, 20, 19, 18, 17, 16, 15, 14, 13, 12, 11, or 10 genes, or less than 10 genes. In one embodiment, the gene-expression profile is comprised of 56 genes. In another embodiment, the gene-expression profile is comprised of 40 genes. In another embodiment, the gene-expression profile is comprised of 30 genes. In another embodiment, the gene-expression profile is comprised of 20 genes. In certain embodiments, the genes selected are: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C2lorf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above. In some embodiments, the gene set further comprises control genes or normalization genes selected from: BAG6 (probe ID:
Hs00190383), KMT2D/MLL2 (probe ID: Hs00912419 ml), MDM2 (probe ID: Hs00540450 sl), FXR1 (probe ID: Hs01096876 gl), KMT2C (probe ID: Hs01005521 ml), MDM4 (probe ID:
Hs00967238 ml), VIM, and NF1B.
As used herein, the term "predictive training set" refers to a cohort of cSCC
tumors with known clinical outcome for local recurrence, distant metastasis, or both and known genetic expression profile, used to define or establish all other cSCC tumors, based upon the genetic expression profile of each, as a low-risk, class 1 tumor type or a high-risk, class 2 tumor type. Additionally, included in the predictive training set is the definition of "threshold points," which are points at which a classification of metastatic risk is determined, specific to each individual gene expression level.
As used herein, the term "altered in a predictive manner" refers to changes in genetic expression profile that predict local recurrence, distant metastasis, metastatic risk, or predict overall survival. Predictive modeling risk assessment can be measured as: 1) a binary outcome having risk of metastasis or overall survival that is classified as low risk (e.g., termed Class 1 herein) vs. high risk (e.g., termed Class 2 herein); and/or 2) a linear outcome based upon a probability score from 0 to 1 that reflects the correlation of the genetic expression profile of a cSCC tumor with the genetic expression profile of the samples that .. comprise the training set used to predict risk outcome. Within the probability score range from 0 to 1, a probability score, for example, of less than 0.5 reflects a tumor sample with a low risk of local recurrence, metastasis, or death from disease, while a probability score, for example, of greater than 0.5 reflects a tumor sample with a high risk of local recurrence, metastasis, or death from disease. The increasing probability score from 0 to 1 reflects incrementally declining metastasis free survival. In one embodiment, the probability score is a bimodal, two-class analysis, wherein a patient having a value of between 0 and 0.499 is designated as class 1 (low risk; for example, having a 5-year relapse-free survival rate, a 5-year metastasis free survival rate, or a 5-year disease specific survival rate of greater than 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, or more than 95%) and a patient having a value of between 0.500 and 1.00 is designated as class 2 (high risk;
for example, having a 5-year metastasis free survival rate, or a 5-year disease specific survival rate of less than 50%, 45%, 40%, 35%, 30%, 25%, 20%, 15%, 10%, 5%, or less than 5%).
In certain embodiments, the probability score is a tri-modal, three-class analysis, wherein patients are designated as class A (low risk; for example having a recurrence risk of less than 25%, 20%, 15%, 10%, 5%, or less than 5%), class B (intermediate risk; for example having a recurrence risk of 75%, 70%, 65%, 60%, 55%, 50%, 45%, 40%, 35%, 30%, 25%, or any number in between), or class C (high risk; for example, having a recurrence risk of 75%, 80%, 85%, 90%, 95%, or higher than 95%). To develop a ternary, or three-class system of risk assessment, with Class A having a low risk of metastasis or death from disease, Class B
having an intermediate risk, and Class C having a high risk, the median probability score value for all low risk or high risk tumor samples in the training set was determined, and one standard deviation from the median was established as a numerical boundary to define low or high risk. For example, low risk cSCC tumors within the ternary classification system can have a 5-year metastasis free survival of 100% (e.g., Class A; with a probability score of 0-0.337), compared to high risk (e.g., Class C; with a probability score of 0.673-1) cSCC
tumors which can have a 20% 5-year metastasis free survival. Cases falling outside of one standard deviation from the median low or high risk probability scores have an intermediate risk, and intermediate risk (Class B; with a probability score of 0.338-0.672) cSCC tumors can have a 55% 5-year metastasis free survival rate.
The TNM (Tumor-Node-Metastasis) status system is the most widely used cancer staging system among clinicians and is maintained by the American Joint Committee on Cancer (AJCC) and the International Union for Cancer Control (UICC). Cancer staging systems codify the extent of cancer to provide clinicians and patients with the means to quantify prognosis for individual patients and to compare groups of patients in clinical trials and who receive standard care around the world.
Local recurrence rates for cSCC have been reported to be 1-10%, but can be as high as 47% in patients who have cSCCs with high-risk clinical features. While the overall rate of metastasis is -5%, this rate increases up to -45% in patients with high-risk clinical features or who have already experienced a recurrence. After regional or distant metastasis occurs, prognosis is usually poor, with 5-year survival rates ranging from 26-34% and 10-year survival rates of 16%. Although the overall percentages of patients who die from cSCC
(-1%) are low, the absolute number of deaths are estimated to be equal to or greater than those attributed to melanoma, due to the large number of yearly cSCC diagnoses (400,000-700,000 patients), and account for the majority of NMSC-related deaths. In effect, local and regional recurrence from primary cSCC tumors remains a significant health burden.
Cutaneous squamous cell carcinoma stems from interfollicular epidermal keratinocytes and can arise from precancerous lesions, the most common of which are actinic keratoses. Once the malignant cells enter the dermis, the cSCC becomes invasive.
Squamous cell carcinoma can present as smooth or hyperkeratinized lesions that are pink or skin-colored. They can exhibit ulceration and bleed when traumatized. Risk factors that contribute to the development of cSCC include exposures to ultraviolet radiation, ionizing radiation, and chemicals, as well as increased age and male gender.
Immunosuppressed individuals, those with a history of non-Hodgkin lymphoma, including chronic lymphocytic leukemia, those with certain genetic skin conditions, and those who have had organ transplants are at a significantly increased risk for developing cSCC. In fact, the latter group has risk up to 100 times that of the normal population. Some drugs used to treat other types of skin cancer (e.g., basal cell carcinoma (BCC), melanoma), including hedgehog, BRAF, and MET inhibitors, can also increase the propensity for cSCC. Small, low-risk lesions can be treated with cryosurgery, curettage and electrodessication, or surgery, while larger, higher risk lesions are generally treated with surgical excision or Mohs surgery.
Radiotherapy can be used in conjunction with surgery if margins are not cleared surgically or if there is perineural invasion. If regional recurrence occurs, the lymph nodes are the primary site of involvement, accounting for ¨80-85% of cSCC recurrences, while distant metastasis occurs in ¨15-20% of patients.
Because the risk for local recurrence in clinically or pathologically high risk squamous cell carcinoma lesions can approach 45%, and the risk of metastasis then increases upon local recurrence, there has been an increased interest in more accurately identifying such lesions. As such, the National Comprehensive Cancer Network (NCCN) and American Joint Committee on Cancer (AJCC) have recently proposed parameters to distinguish high risk lesions and follow-up measures for these lesions. These high-risk features include tumor size and location ("mask" areas of the face and/or ear and non-glabrous lip), increased thickness or Clark's level, immunosuppression, recurrent lesions, sites of chronic inflammation or previous radiation, poor differentiation, and perineural invasion. However, high-risk cSCC definitions from different groups are discordant, with the AJCC
classifying a majority of lesions as low-risk and NCCN classifying a majority as high-risk.
Such discrepancies, especially in the T2a and T2b groups, have led to the proposal of alternative staging criteria that can better elucidate high risk cSCC cases. In effect, there is a clinically unmet need for better markers to identify high-risk lesions, particularly molecular biomarkers that can be objectively evaluated. The validated prognostic gene expression profiles disclosed herein could inform clinical decision-making on, for example: (1) preoperative surgical staging, based on shave biopsy; (2) adjuvant radiation, nodal staging, adjuvant systemic therapy to reduce regional/distant metastasis; and (3) improving identification of patients with cSCC who can benefit from surgical, radiation and immunotherapy interventions.
Squamous cell carcinoma that is predicted to have an increased risk of recurrence, progression, or metastasis can be treated with an aggressive cancer treatment regimen.
Advanced cSCC may be defined under two headings: (1) locoregional disease;
and/or (2) distant metastases. Locoregional disease can be difficult to control and/or treat if: (1) the primary cSCC has invaded into neuronal or vascular structures; (2) there is presence of lymph node metastases, which indicate advanced disease; or (3) distant metastases have been detected.
In an embodiment, a method for predicting risk of recurrence, metastasis, or both, in a patient with a cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising: (a) obtaining a cSCC tumor sample from the patient and isolating mRNA
from the sample; (b) determining the expression level of at least 10 genes in a gene set;
wherein the at least ten genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; (c) comparing the expression levels of the at least 10 genes in the gene set from the cSCC tumor sample to the expression levels of the at least 10 genes in the gene set from a predictive training set to generate a probability score of the risk of local recurrence, distant metastasis, or both; and (d) providing an indication as to whether the cSCC
tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the probability score generated in step (c).
In some embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR). In certain embodiments, the cSCC
tumor sample is obtained from formalin-fixed, paraffin embedded sample. In one embodiment, the method further comprises identifying the cSCC tumor as having a high risk of local recurrence, distant metastasis, or both, based on the probability score, and administering to the patient an aggressive tumor treatment.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 10 genes, 20 genes, 30 genes, or 40 genes selected from the genes listed above.
In an embodiment, a method for predicting risk of recurrence, metastasis, or both, in a patient with a cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising: (a) obtaining a cSCC tumor sample from the patient and isolating mRNA
from the sample; (b) determining the expression level of at least 10 genes in a gene set;
wherein the at least ten genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; and (c) providing an indication as to whether the cSCC tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the expression level of at least 10 genes generated in step (b).
In some embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR). In certain embodiments, the cSCC
tumor sample is obtained from formalin-fixed, paraffin embedded sample.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 10 genes, 20 genes, 30 genes, or 40 genes selected from the genes listed above.
In certain embodiments, the expression level of: ACSBG1 is decreased, AIM2 is increased, ALOX12 is decreased, ANXA9 is decreased, APOBEC3G is increased, ARPC2 is .. decreased, ATP6AP1 is decreased, ATP6V0E2 is increased, BBC is increased, BHLHB9 is decreased, BLOC1S1 is decreased, Cl QL4 is increased, C21orf59 is increased, C3orf70 is increased, CCL27 is decreased, CD163 is increased, CEP76 is decreased, CHI3L1 is increased, CHMP2B is decreased, CXCL10 is decreased, CXCR4 is increased, (L0C101929829) is decreased, DARS is decreased, DCT is decreased, DDAH1 is decreased, .. DSS1 is decreased, DUXAP8 is increased, EGFR is increased, EphB2 is increased, FCHSD1 is decreased, FDFT1 is decreased, FLG is decreased, FN1 is increased, GTPBP2 is decreased, HDDC3 is increased, HNRNPL is decreased, HOXA10 (HOXA9, MIR196B) is decreased, HPGD is decreased, ID2 is decreased, IL24 is increased, IL2RB is decreased, IL7R is increased, INHBA is increased, IPO5P1 is increased, KIT is increased, KLK5 is decreased, KRT17 is decreased, KRT18 is increased, KRT19 is decreased, KRT6B is decreased, LAMC2 is decreased, LCE2B is decreased, LIME1 (ZGPAT) is increased, L0C100287896 is increased, L0C101927502 is decreased, LOR is decreased, LRRC47 is increased, MIER2 is increased, MIR129-1 is increased, MIR3916 is increased, MKLN1 is increased, MMP1 is increased, MMP10 is decreased, MMP12 is increased, MMP13 is increased, MMP3 is increased, MMP7 is increased, MMP9 is decreased, MRC1 is increased, MRPL21 is increased, MSANTD4 is decreased, MYC is decreased, NEB is decreased, NEFL is decreased, NFASC is decreased, NFIA is decreased, NFIB is decreased, NFIC is decreased, NOA1 is increased, PD1 is decreased, PDL1 is increased, PDPN is increased, PI3 is decreased, PIG3 is decreased, PIGBOS1 is increased, PIM2 is increased, PLAU is increased, PLS3 is decreased, PTHLH is decreased, PTRHD1 is decreased, RBM33 is increased, RCHY1 is increased, RNF135 is increased, RPL26L1 is increased, RPP38 is decreased, RUNX3 is increased, S100A8 is decreased, S100A9 is decreased, SEPT3 is decreased, SERPINB2 is decreased, SERPINB4 is decreased, SLC1A3 is increased, SLC25A11 is increased, SNORD124 is increased, SPATA41 is increased, SPP1 is increased, TAF6L is increased, TFAP2B is decreased, THYN1 is increased, TMEM41B is decreased, TNNC1 is decreased, TUBB3 is decreased, TUFM (MIR4721) is increased, TYRP1 is decreased, UGP2 is decreased, USP7 is decreased, VIM is increased, YKT6 is increased, ZNF48 is increased, ZNF496 is increased, ZNF839 is increased, and/or ZSCAN31 is decreased. In certain embodiments, the increase or decrease in the expression level is the gene level from a recurrent tumor sample versus a non-recurrent tumor sample.
In an embodiment, a method for treating a patient with cutaneous squamous cell carcinoma (cSCC) tumor is disclosed herein, the method comprising: (a) obtaining a cSCC
tumor sample from the patient and isolating mRNA from the sample; (b) determining the expression level of at least 10 genes in a gene set; wherein the at least ten genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, Cl QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; (c) providing an indication as to whether the cSCC
tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the expression level of at least 10 genes generated in step (b); and (d) administering to the patient an aggressive treatment when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both.
In some embodiments, the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR). In certain embodiments, the cSCC
tumor sample is obtained from formalin-fixed, paraffin embedded sample.
In another embodiment, the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In other embodiments, the gene set comprises 20 genes, 30 genes, or 40 genes selected from the genes listed above.
As used herein, the terms "treatment," "treat," or "treating" refer to a method of reducing the effects of a disease or condition or symptom of the disease or condition. Thus, in the methods disclosed herein, treatment can refer to a 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, or 100% reduction in the severity of an established disease or condition or symptom of the disease or condition. For example, a method of treating a disease is considered to be a treatment if there is a 5% reduction in one or more symptoms of the disease in a subject as compared to a control. Thus, the reduction can be a 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100% or any percent reduction between 5%
and 100% as compared to native or control levels. It is understood that treatment does not necessarily refer to a cure or complete ablation of the disease, condition, or symptoms of the disease or condition. After a cSCC is found and staged, a medical professional or team of medical professionals will recommend one or several treatment options. In determining a treatment plan, factors to consider include the type, location, and stage of the cancer, as well as the patient's overall physical health. Prior to the initiation of treatment and or therapy, all patients should be evaluated and managed by a multidisciplinary team with expertise and experience in cSCC. Patients with cSCC typically have a multidisciplinary health care team made up of doctors from different specialties, such as: a dermatologist (in particular, a dermatologist who specializes in Mohs micrographic surgery), an orthopedic surgeon (in particular, a surgeon who specializes in diseases of the bones, muscles, and joints), a surgical oncologist, a thoracic surgeon, a medical oncologist, a radiation oncologist, and/or a physiatrist (or rehabilitation doctor). After a cSCC is found and staged, a medical professional or team of medical professionals will typically recommend one or several treatment options including one or more of surgery, radiation, chemotherapy, and targeted therapy.
Low risk cSCC tumors as defined in the NCCN Guidelines involve: (1) an area of less than 20 mm (for truck and extremities) or less than 10 mm for the cheeks, forehead, scalp, neck and pretibial; (2) well defined borders; (3) primary cSCC tumor;
(4) not rapidly growing; (5) from a patient who has no neurologic symptoms and is not considered immunosuppressed; (6) from a site free of chronic inflammation; (7) well or moderately differentiated; (8) free of acantholytic, adenosquamous, desmoplastic, or metaplastic subtypes; (9) depths of less than 2 mm; and (10) free of perineural, lymphatic, or vascular involvement.
High risk cSCC tumors as defined in the NCCN Guidelines involve: (1) an area of greater than 20 mm (for truck and extremities), greater than 10 mm for the cheeks, forehead, scalp, neck and pretibial, or any cSCC involving the "mask areas" (such as central face, eyelids, eyebrows, periorbital, nose, lips, chin, mandible, temple or ear), genitalia, hands and feet; (2) poorly defined borders; (3) recurrent cSCC tumor; (4) rapidly growing; (5) from a patient who has neurologic symptoms or is considered immunosuppressed; (6) from a site with chronic inflammation; (7) poorly differentiated; (8) presence of acantholytic, adenosquamous, desmoplastic, or metaplastic subtypes; (9) depths of greater than or equal 2 mm; and (10) presence of perineural, lymphatic, or vascular involvement.
As used herein, the term "aggressive cancer treatment regimen" refers to a treatment regimen that is determined by a medical professional or team of medical professionals and can be specific to each patient. In certain embodiments, a cSCC tumor predicted to have a high-risk of recurrence or a high-risk of metastasis, or a decreased chance of survival using the methods and kits disclosed herein, would be treated using an aggressive cancer treatment regimen. Whether a treatment is considered to be aggressive will generally depend on the cancer-type, the age of the patient, and other factors known to those of skill in the art. For example, in breast cancer, adjuvant chemotherapy is a common aggressive treatment given to complement the less aggressive standards of surgery and hormonal therapy.
Those skilled in the art are familiar with various other aggressive and less aggressive treatments for each type of cancer. An aggressive cancer treatment regimen is defined by the National Comprehensive Cancer Network (NCCN), and has been defined in the NCCN
Guidelines as including one or more of: 1) imaging (CT scan, PET/CT, MRI, chest X-ray), 2) discussion and/or offering of tumor resection if a tumor is determined to be resectable (e.g., by Mohs micrographic surgery or resection with complete circumferential margin assessment), 3) radiation therapy (RT), 4) chemoradiation, 5) chemotherapy, 6) regional limb therapy, 7) palliative surgery, 8) systemic therapy, 9) immunotherapy, and 10) inclusion in ongoing clinical trials. Guidelines for clinical practice are published in the National Comprehensive Cancer Network (NCCN Guidelines Squamous Cell Skin Cancer Version 2.2018, updated October 5, 2017, available on the World Wide Web at NCCN.org).
Additional therapeutic options may include, but are not limited to: 1) combination regimens such as: AD (doxorubicin, dacarbazine); AIM (doxorubicin, ifosfamide, mesna);
MAID (mesna, doxorubicin, ifosfamide, dacarbazine); ifosfamide, epirubicin, mesna;
gemcitabine and docetaxel; gemcitabine and vinorelbine; gemcitabine and dacarbazine;
doxorubicin and olaratumab ; methotrexate and vinblastine; tamoxifen and sulindac;
vincristine, dactinomycin, cylclophosphamide; vincristine, doxorubicin, cyclophosphamide;
vincristine, doxorubicin, cyclophosphamide with ifosfamide and etoposide;
vincristine, doxorubicin, ifosfamide; cyclophosphamide topotecan; or ifosfamide, doxorubicin; and/or 2) single agents, such as: cisplatin or other metallic compounds, 5-FU/capecitabine (Xeloda0), cetuximab (Erbitux0), pembrolizumab (MK-3475), panitumumab (Vectibix0), dacomitinib .. (PF-00299804), gefitinib (ZD1839, Iressa), doxorubicin, ifosfamide, epirubicin, gemcitabine, dacarbazine, temozolomide, vinorelbine, eribulin, trabectedin, pazopanib, imatinib, sunitinib, regorafenib, sorafenib, nilotinib, dasatinib, interferon, toremifene, methotrexate, irinotecan, topotecan, paclitaxel, nab-paclitaxel (abraxane), docetaxel, bevacizumab, temozolomide, sirolimus (Rapamune0), everolimus, temsirolimus, crizotinib, ceritinib, or palbociclib.
While surgical excision remains the mainstay for treating operable (Stage I-III) cSCC
patients, for Stage I patients, en bloc resection with negative margins is generally considered sufficient for long-term local control. For those with incomplete excision margins and/or other unfavorable pathologic features, pre- or post-operative chemotherapy and/or radiation treatment can be recommended. No therapy has shown consistent efficacy for the treatment of excised cSCC, and treatment options for unresectable or advanced cSCC are limited.
Immunotherapy using an anti-PD1 inhibitor has shown promising results in early phase studies with cSCC patients. Examples of immunotherapies (that can be used alone or in combination with any one or more of tumor resection if a tumor is determined to be resectable, radiation therapy, chemoradiation, chemotherapy, regional limb therapy, palliative surgery, systemic therapy, additional immunotherapeutic, or inclusion in ongoing clinical trials), can include, for example, pembrolizumab (Keytruda0) and nivolumab (Opdivo0), cemiplimab (REGN2810; a fully human monoclonal antibody to Programmed Death-1).
PD-1 is a protein on T-cells that normally help keep T-cells from attacking other cells in the body. By blocking PD-1, these drugs can boost the immune response against cancer cells.

CTLA-4 inhibitors (for example, ipilimumab (Yervoy0)) are another class of drugs that can boost the immune response. In some instances, cytokine therapy (such as, interferon-alpha and interleukin-2) can be used to boost the immune system. Examples of interferon and interleukin-based treatments can include, but are not limited to, aldesleukin (proleukin0), interferon alpha-2b (INTRONO), and pegylated interferon alpha-2b (Sylvatron0;
PEG-INTRONO, PEGASYS). In another embodiment, oncolytic virus therapy can be used.

Along with killing the cells directly, the oncolytic viruses can also alert the immune system to attack the cancer cells. For example, talimogene laherparepvec (Imlygic0), also known as T-VEC, is an oncolytic virus that can be used to treat melanomas. Additional immunotherapies may include CV8102.
Additionally, targeted therapies may be used to treat patients with cSCC. For example, targeted therapies can include, but are not limited to, vemurafenib (Zelboraf0), dabrafenib (Tafinlar0), trametinib (Mekinist0), CLL442, and cobimetinib (Cotellic0).
These drugs target common genetic mutations, such as the BRAFV600 mutation, that may be found in a subset of cSCC patients.
In some embodiments, the cSCC tumor is a frozen sample. In another embodiment, the cSCC sample is formalin-fixed and paraffin embedded. In certain embodiments, the cSCC sample is taken from a formalin-fixed, paraffin embedded wide local excision sample.
In another embodiment, the cSCC tumor is taken from a formalin-fixed, paraffin embedded primary biopsy sample. In some embodiments, the cSCC sample can be from image guided surgical biopsy, shave biopsy, wide excision, or a lymph node dissection.
In certain embodiments, analysis of genetic expression and determination of outcome is carried out using radial basis machine and/or partial least squares analysis (PLS), partition tree analysis, logistic regression analysis (LRA), K-nearest neighbor, neural networks, ensemble learners, voting algorithms, or other algorithmic approach. These analysis techniques take into account the large number of samples required to generate a training set that will enable accurate prediction of outcomes as a result of cut-points established with an in-process training set or cut-points defined for non-algorithmic analysis, but that any number of linear and nonlinear approaches can produce a statistically significant and clinically .. significant result. As used herein, the term "Kaplan-Meier survival analysis" is understood in the art to be also known as the product limit estimator, which is used to estimate the survival function from lifetime data. In medical research, it is often used to measure the fraction of patients living for a certain amount of time after treatment. JMP GENOMICSO, R, Python libraries including SciPy, SciKit, and numpy software or systems such as TensorFlow provides an interface for utilizing each of the predictive modeling methods disclosed herein, and should not limit the claims to methods performed only with JMP GENOMICSO, R, Python, or TensorFlow software.
In an embodiment, a kit comprising primer pairs suitable for the detection and .. quantification of nucleic acid expression of at least ten genes is disclosed herein, wherein the at least ten genes are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
In some embodiments, the primer pairs suitable for the detection and quantification of nucleic acid expression of at least ten genes are primer pairs for: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, .. NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31. In one embodiment, the primer pairs comprise primer pairs for 10 genes, 20 genes, 30 genes, 40 genes or more.
In another aspect, this disclosure relates to kits to be used in assessing the expression of a gene or set of genes in a cSCC sample or biological sample from a subject to assess the risk of developing recurrence, metastasis, or both. In one embodiment, the disclosure relates to a kit comprising primer pairs suitable for the detection and quantification of nucleic acid expression of at least ten genes selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, Cl QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), LOC100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, .. MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
Kits can include any combination of components that facilitates the performance of an assay. A kit that facilitates assessing the expression of the gene or genes may include suitable nucleic acid-based and/or immunological reagents as well as suitable buffers, control reagents, and printed protocols. A "kit" is any article of manufacture (e.g., a package or container) comprising at least one reagent, e.g., a probe or primer set, for specifically detecting a marker or set of markers used in the methods disclosed herein. The article of manufacture may be promoted, distributed, sold, or offered for sale as a unit for performing the methods disclosed herein. The reagents included in such a kit comprise probes, primers, or antibodies for use in detecting one or more of the genes and/or gene sets disclosed herein and demonstrated to be useful for predicting recurrence, metastasis, or both, in patients with cSCC. Kits that facilitate nucleic acid based methods may further include one or more of the following: specific nucleic acids such as oligonucleotides, labeling reagents, enzymes including PCR amplification reagents such as Taq or Pfu, reverse transcriptase, or other, and/or reagents that facilitate hybridization. In addition, the kits disclosed herein may preferably contain instructions which describe a suitable detection assay.
Such kits can be conveniently used, e.g., in clinical settings, to diagnose and evaluate patients exhibiting symptoms of cancer, in particular patients exhibiting the possible presence of a cutaneous squamous cell carcinoma.
EXAMPLES
The Examples that follow are illustrative of specific embodiments of the claimed invention, and various uses thereof They are set forth for explanatory purposes only, and should not be construed as limiting the scope of the claimed invention in any way.
Example 1: cSSC tumor sample preparation and expression analysis a. cSCC tumor sample preparation and RNA isolation Formalin-fixed paraffin embedded (FFPE) primary squamous cell carcinoma tumor specimens arranged in 5 p.m sections on microscope slides were acquired from multiple institutions under Institutional Review Board (IRB) approved protocols. All tissue was reviewed by a pathologist. Tissue was marked and tumor tissue was dissected from the slide using a sterile disposable scalpel, collected into a microcentrifuge tube, and deparaffinized using xylene. RNA was isolated from each specimen using the QIAGEN QIAsymphony RNA kit (Hilden, Germany) on the QIAGEN QIAsymphony SP sample preparation automated extractor. RNA quantity was assessed using the NanoDropTM 8000 system.
b. cDNA generation and RT-PCR analysis RNA isolated from FFPE samples was converted to cDNA using the Applied Biosystems High Capacity cDNA Reverse Transcription Kit (Life Technologies Corporation, Grand Island, NY). Prior to performing the RT-PCR assay, each cDNA sample underwent a 14-cycle pre-amplification step. Pre-amplified cDNA samples were diluted 20-fold in TE
buffer. 7.5 pL of each diluted sample was mixed with 7.5 pL of TaqMan OpenArray Real-Time Mastermix, and the solution was loaded to a custom high throughput microfluidics OpenArray card containing primers specific for the genes. Each sample was run in triplicate.
The gene expression profile test was performed on a ThermoFisher QuantStudio12k Flex Real-Time PCR system (Life Technologies Corporation, Grand Island, NY).
c. Expression analysis and class assignment Mean Ct values were calculated for triplicate sample sets, and AC t values were calculated by subtracting the mean Ct of each discriminating gene from the geometric mean of the mean Ct values of all endogenous control genes. AC t values were standardized according to the mean of the expression of all discriminant genes with a scale equivalent to the standard deviation. Various predictive modeling methods, including radial basis machine, k-nearest neighbor, partition tree, logistic regression, discriminant analysis and distance scoring, and neural network analysis were performed using R version 3.3.2.
Example 2: cSCC metastatic risk genetic signature and biomarker expression The study design workflow is shown in Figure 1. First, in order to develop the gene expression profile for cSCC prognostication, cases with annotated clinical data and sufficient follow-up were used as a development set. Pre-specified bins of patients within the recurrent and non-recurrent group were created, including immunocompromised, immunocompetent, those with a certain number of high risk features and low risk cases. The goal was to satisfy the pre-specified number of cases in each bin for development. Predictive modeling was performed on gene expression data from the development cohort. The predictive model was then validated. 221 cases were included in the development set (see Table 1).
Table 1 shows the demographics for the cohort of 221 cases used in this study. They are also stratified by non-recurrence or recurrence. Recurrence is defined as any recurrence ¨ local nodal (satellitosis through regional nodes and distant metastasis). Note that cases with R1 or R2 and local recurrence in the scar or contiguous to the scar were embargoed from this analysis.
Characteristics that are associated with higher risk tumors (such as male sex, compromised immune system, head and neck primary tumor, poor differentiation or undifferentiated, higher Clark Level, perineural invasion, and invasion into subcutaneous fat) are features included. This is after embargoing cases that have not yet had data monitoring and did not meet very stringent gene expression data requirements.
Table 1: Demographics for the cohort of 221 cases used in Examples 2 and 3 All Non- With Feature Recurrence Recurrence p-value (n=221) (n=196) (n=25) Age: Median years (range) 74 (43-97) 74 (45-97) 69 (43-91) n.s.
Mean +/- SD 72.8 +/- 11.2 73.3 +/- 10.8 68.6 +/-13.2 Definitive surgery: Mohs 181 (82%) 1 161 (82%) 20 (80%) n.s.
WLE 39 (18%) 34 (17%) 5 (20%) Male sex 164 (74%) 143 (73%) 21(84%) n.s.
Patient immunocompromised 30 (14%) 20 (10%) 10 (40%) p<0.001 Located on head or neck 146 (66%) 129 (66%) 17 (68%) n.s.
Tumor diameter:
p<0.001 Median cm (range) 1.4 (0-28) I 1.15 (0-8.8) 2.9 (0.25-28) Mean +/- SD 1.88 +/- 2.34 1.62 +/- 1.47 3.89 +/-5.27 Differentiation Status:
Poor / Undifferentiated p<0.001 Clark Level IV / V 73 (33%) 67 (34%) 6 (24%) p<0.001 Perineural invasion present 12 (5%) 9 (5%) 3 (12%) p<0.001 Invasion into subcutaneous fat 22 (10%) 19 (10%) 3 (12%) P=0.015 Gene expression differences (RT-PCR data from 73 genes) between recurrent and non-recurrent cSCC cases were evaluated. Using the gene expression data, several control genes were identified that had stable expression across all of the samples.
These control genes were then used to normalize the expression of the remaining genes. Gene expression differences between recurrent and non-recurrent cases were investigated to find the genes that are significant. Significant gene expression differences that were associated with local recurrences, regional metastases, and distant metastases were also evaluated.
Table 2 below shows genes associated with regional/distant metastases. Genetic expression of the discriminant genes in the signature (Table 2) was assessed in a cohort of 240 cSCC samples using RT-PCR, 18 of these were independently significant to a p-value of p<0.05 (see Figure 2). As shown in Table 3 below, of the 63 discriminating genes, 18 were altered in metastatic cSCC tumors compared to nonmetastatic tumors with a p-value of p<0.05.
Table 2: 63 candidate genes for the GEP signature to predict metastatic risk and/recurrence in cSCC tumors Gene symbol p-value mean - Recurrence mean - Non-Recurrence LOR 0.000 0.310 2.935 KRT18 0.000 0.454 -1.081 LCE2B 0.000 0.447 2.490 EphB2 0.001 -1.846 -2.648 FLG 0.001 -4.104 -1.594 DCT 0.001 -5.696 -3.003 TFAP2B 0.001 -6.571 -3.836 NEB 0.002 -3.495 -2.807 TYRP1 0.006 -5.869 -3.709 MMP3 0.006 -2.887 -5.159 MMP7 0.010 -3.915 -5.568 MMP1 0.014 2.290 0.970 INHB A 0.016 -1.203 -2.222 ACSBG1 0.024 -3.613 -2.489 USP7 0.029 0.689 1.076 APOBEC3G 0.035 -3.800 -4.260 NFIB 0.036 -2.623 -2.385 ANXA9 0.050 -8.007 -7.059 RCHY1 0.055 -2.418 -2.665 PDPN 0.056 1.672 1.251 ALOX12 0.066 -4.112 -3.688 YKT6 0.070 1.449 1.140 PLAU 0.091 1.873 1.913 ID2 0.110 -0.921 -0.550 MMP10 0.119 -0.067 -1.164 HPGD 0.141 -6.830 -5.781 FN1 0.147 1.594 1.186 HNRNPL 0.156 -0.036 0.085 AIM2 0.159 -4.093 -4.610 MMP13 0.178 -7.096 -8.365 BBC 0.179 -7.464 -7.738 EGFR 0.189 0.908 0.705 SPP1 0.200 -0.144 -1.332 SERPINB4 0.251 -11.815 -10.852 NEFL 0.292 -2.876 -1.321 NFASC 0.301 -3.832 -3.738 P13 0.324 4.686 4.847 PIG3 0.333 -3.420 -3.698 LAMC2 0.350 0.480 0.196 ARPC2 0.353 -0.053 -0.006 AADAC 0.379 -16.094 -15.629 IL24 0.387 -3.969 -4.629 S100A8 0.388 3.838 3.936 CCL27 0.398 -12.922 -13.230 PTHLH 0.401 0.777 0.907 S100A9 0.457 7.525 7.534 DDA1-11 0.461 -5.660 -5.216 PDL1 0.471 -3.067 -3.124 DSS1 0.477 -5.722 -5.442 KRT19 0.486 -2.982 -3.853 KIT 0.529 -2.391 -2.415 TUBB3 0.599 -4.541 -5.167 MYC 0.631 -3.816 -3.749 CHI3L1 0.653 -0.029 0.025 MMP9 0.684 1.649 1.733 CXCR4 0.742 -8.733 -8.858 ATP6V0E2 0.750 -8.562 -8.519 CXCL10 0.785 -3.039 -3.184 PD1 0.825 -1.878 -1.870 IL7R 0.872 -8.524 -8.094 MMP12 0.919 -2.958 -3.225 CEP76 0.981 -4.361 -4.656 Table 3: 18 Genes included in a GEP signature able to predict recurrence in cSCC
Gene mean -symbol p-value Recurrence mean - Non-Recurrence ACSBG1 0.024 -3.613 -2.489 ANXA9 0.050 -8.007 -7.059 APOBEC3G 0.035 -3.800 -4.260 DCT 0.001 -5.696 -3.003 EphB2 0.001 -1.846 -2.648 FLG 0.001 -4.104 -1.594 INHBA 0.016 -1.203 -2.222 KRT18 0.000 0.454 -1.081 LCE2B 0.000 0.447 2.490 LOR 0.000 0.310 2.935 MMP 1 0.014 2.290 0.970 MMP3 0.006 -2.887 -5.159 MMP7 0.010 -3.915 -5.568 NEB 0.002 -3.495 -2.807 NFIB 0.036 -2.623 -2.385 TFAP2B 0.001 -6.571 -3.836 TYRP1 0.006 -5.869 -3.709 USP7 0.029 0.689 1.076 Example 3: Initial training set development studies and comparison to validation cohort R version 3.3.2 was used to train multiple predictive models (e.g., multiple machine-learning methods such as, neural networks, gradient boosting machine, generalized linear model boost, radial basis function, rule-based classification, decision tree classification, and/or regularized linear discriminant analysis) against the normalized Ct values obtained from RT-PCR analysis in 181 cSCC cases selected at random from the 240 cases in the combined set. The average of the top predictive models was more sensitive than either the Brigham and Women's Hospital (BWH) or American Joint Committee on Cancer (AJCC) models with minimal loss of specificity. These results show that recurrent and non-recurrent cSCC can be identified through gene expression profiling and gene expression can be used to identify cSCC patients with a higher risk of recurrence. A validated prognostic test could inform clinical decision-making on preoperative surgical staging (for example, based on shave biopsy), surgical approach (SLNB) or adjuvant radiation to reduce local recurrence, and adjuvant radiation, nodal staging, adjuvant systemic therapy to reduce regional/distant metastasis. Such a test could improve such intervention decisions and help determine which patients may benefit from additional therapeutic modalities.

Table 4: Predictive modeling - local recurrence Local Recurrence GEP BWH AJCCv7 AJCCv8 Example 2 Sensitivity 75% 17% 0% 39%
Specificity 92% 90% 99.5% 79%
negative predictive value 98% 92% 92% 94%
(NPV) positive predictive value 50% 13% 94% 14%
(PPV) Table 5: Predictive modeling - metastasis Regional/Distant GEP BWH AJCCv7 AJCCv8 Metastasis Example 2 Sensitivity 83% 23% 0% 46%
Specificity 95% 90% 100% 79%
negative predictive value 99% 95% 94% 96%
(NPV) positive predictive value 53% 13% 0% 12%
(PPV) Example 4: Prognostic gene expression profile test in cSCC in patients with one or more high-risk features To identify a gene expression profile that accurately predicts: (1) primary cSCC with a high risk of regional nodal/distant metastasis; and (2) primary cSCC with high risk of local recurrence after complete surgical clearance, a multi-center study was performed using archived primary tissue samples with extensive capture of associated clinical data. The approach uses targeted candidate genes from the literature combined with genes from a global approach microarray screen. Samples are from subjects with pathologically confirmed cSCC diagnosed after 2006, minimum 3 years of follow-up or event (see Tables 6 and 7).
Two separate outcomes were measured: (1) nodal/distant metastasis; and (2) local recurrence. Accuracy metrics demonstrate that the gene expression signature has prognostic value for in an independent cohort (see Table 8 and Figure 4). The prognostic test could inform clinical decision-making on: (1) preoperative surgical staging, based on shave biopsy;
and (2) adjuvant radiation, nodal staging, adjuvant systemic therapy to reduce regional/distant metastasis.

Table 6: Demographics for development stage of Example 4.
All Non-Metastatic Regional/distant Feature (n=122) (n=108) metastasis (n=14) Age: Median years (range) 74 (49-97) 74 (50-97) 74.5 (49-91) # #
Definitive surgery: Mohs 99 (82%) 88 (82%) 11(79%) Male sex 94 (77%) 81(75%) 13 (93%) Patient immunocompromised 17 (14%) 13 (12%) 4 (29%) Located on head or neck 87 (71%) 77 (71%) 10 (71%) Tumor diameter: Mean +/- SD 2.0 +/- 2.9 1.5 +/- 1.3 5.8 +/-6.7***
Differentiation Status:
Poorly differentiated 5 (4%) 4 (4%) 1 (7%) Clark Level IV / V 45 (37%) 40 (37%) 5 (36%) Perineural invasion present 7 (6%) 6 (6%) 1 (7%) Invasion into subcutaneous fat 7 (6%) 4 (4%) 3 (21%) **
#
1 case with unknown surgery type; Wilcoxon F or Chi-square test p **<0.01 ***<0.001 Table 7: Demographics for validation stage of Example 4.
All Non-Met Regional/distant met Feature (n=107) (n=90) (n=17) Age: Median years (range) 72 (30-93) 72.5 (45-93) 72 (30-88) Definitive surgery: Mohs 86 (81%)# 76 (84%) 10 (63%)#*
Male sex 78 (73%) 64 (71%) 14 (82%) Patient immunocompromised 12 (11%) 10 (11%) 2 (12%) Located on head or neck 76 (71%) 62 (69%) 14 (82%) Tumor diameter: Mean +/- SD 1.9 +/- 1.7 1.9 +/- 1.2 3.3 +/-2.6**
Differentiation Status:
Poorly differentiated 13 (12%) 6 (7%) 7 (42%)***
Clark Level IV / V 32 (30%) 25 (28%) 7 (41%) Perineural invasion present 9 (8%) 3 (3%) 6 (35%)***
Invasion into subcutaneous fat 17 (16%) 11(12%) 6 (35%)*
#
1 case with unknown surgery type; Wilcoxon F or Chi-square test p *<0.05 **<0.01 ***<0.001 Table 8: Predictive modeling Metric GEP AJCC 8 BWH
Example 4 Sensitivity 53% 53% 41%
Specificity 93% 87% 88%
negative predictive value 91% 91% 89%
(NPV) positive predictive value 60% 43% 39%
(PPV) Example 5: Prognostic gene expression signature for risk assessment in cSCC
with a subanalysis in the head and neck region To identify a gene expression profile that accurately predicts: (1) primary cSCC with a high risk of regional nodal/distant metastasis; and (2) primary cSCC with high risk of local recurrence after complete surgical clearance, a multi-center study was performed using archived primary tissue samples with extensive capture of associated clinical data. The approach uses targeted candidate genes from the literature combined with genes from a global approach microarray screen. Samples are from subjects with pathologically confirmed cSCC diagnosed after 2006, minimum 3 years of follow-up or event (see Table 9). Two separate outcomes were measured: (1) nodal/distant metastasis; and (2) local recurrence.
Accuracy metrics accuracy metrics for all and head and neck cSCC cases suggest that gene expression signature has prognostic value in an independent cohort (see Table 10). The prognostic signature with a robust PPV for high-risk disease will improve identification of patients with cSCC who can benefit from surgical, radiation and immunotherapy interventions.
Table 9: Demographics - head and neck subanalysis Non-Metastasis Feature of head and neck case Metastatic (n=34) (n=9) Age: Median years (range) 75 (49-89) 77 (49-89) Definitive surgery: Mohs 33 (97%) 8 (89%) Male sex 31(91%) 8 (89%) Tumor diameter: Mean cm +/- SD 2.52 +/- 1.35 5.89 +/-8.36 Differentiation Status:
Poor / Undifferentiated 2 (6%) 2 (22%) Clark Level IV / V 4 (12%) 1(11%) Perineural invasion present 4 (12%) 0 (0%) Invasion into subcutaneous fat 7 (21%) 1(11%) Table 10: Predictive modeling - head and neck subanalysis All (n = 107) H&N (n = 76) Metric GEP BWH GEP BWH
Example 5 this study Sensitivity 53% 41% 43% 43%
Specificity 93% 88% 94% 89%
negative predictive value 91% 89% 88% 87%
(NPV) positive predictive value 60% 39% 60% 46%
(PPV) Table 11: Genes included in the gene sets that are able to predict risk of recurrence and/or metastasis Gene name Probe Identifier median median delta p-value (ThermoFisher) Recurrent Non- median *
Recurrent KRT6B Hs00745492_s1 5.522 7.091 -1.569 0.000070 LOR Hs01894962_s1 1.970 4.492 -2.522 0.000265 FLG Hs00856927_gl -2.724 0.303 -3.027 0.000291 LCE2B Hs04194422_s1 1.153 3.665 -2.512 0.000809 PLS3 Hs00543973_m1 -0.416 0.080 -0.497 0.001048 SERPINB2 Hs01010736_m1 0.304 1.455 -1.150 0.001277 KLK5 Hs00202752_m1 1.170 3.239 -2.069 0.001468 KRT18 Hs01920599_gH 0.975 -0.238 1.213 0.002094 BBC Hs00248075_m1 -4.614 -5.334 0.720 0.002663 M1R3916 Hs04232205_s1 -0.709 -1.334 0.625 0.002734 L0C100287896 Hs01931732_s1 -2.224 -2.796 0.572 0.003547 TFAP2B Hs01560931_m1 -4.288 -2.456 -1.832 0.004135 HPGD Hs00960591_m1 -5.491 -3.113 -2.378 0.007656 CHMP2B Hs00387770_m1 -3.117 -2.591 -0.526 0.008827 ANXA9 Hs01070154_m1 -5.583 -4.284 -1.299 0.009038 ID2 Hs00747379_m1 -0.345 0.493 -0.838 0.009695 EphB2 Hs00362096 ml -1.124 -1.614 0.491 0.012203 NEB Hs00189880_m1 -2.611 -1.904 -0.706 0.014937 FDFT1 Hs00926053_m1 -1.589 -0.657 -0.932 0.017046 USP7 Hs00931763_m1 1.509 1.960 -0.452 0.017046 TAF6L Hs01008033_m1 -0.699 -0.961 0.262 0.018195 Gene name Probe Identifier median median delta p-value (ThermoFisher) Recurrent Non- median *
Recurrent ACSBG1 Hs01025572_m1 -2.992 -1.336 -1.657 0.026077 HNRNPL Hs00704853_s1 0.776 0.980 -0.204 0.031337 ARPC2 Hs01031740_m 1 0.715 1.147 -0.432 0.031337 DUXAP8 Hs04942686_m1 -6.816 -9.507 2.691 0.039746 PIM2 Hs01546752_g 1 -1.160 -1.752 0.592 0.050944 KRT17 Hs00356958_m1 6.944 7.254 -0.310 0.053874 APOBEC3G Hs00222415_m1 -2.574 -3.024 0.450 0.056942 DSS1 Hs00428732_m 1 -4.131 -3.182 -0.949 0.056942 EGFR Hs01076090_m 1 1.598 1.332 0.266 0.069464 SERPINB4 Hs01691258_g 1 -12.838 -8.116 -4.722 0.070706 UGP2 Hs00900510_ml -1.783 -1.437 -0.346 0.073246 SPATA41 Hs03028557_sl -12.073 -13.333 1.261 0.077195 SN0RD124 Hs03464469_sl -2.848 -2.958 0.110 0.082729 P13 Hs00964384_gl 5.550 6.140 -0.589 0.085614 LIME1-ZGPAT Hs00738791_gl -4.044 -4.312 0.267 0.090094 MMP3 Hs00968305_m 1 -1.478 -2.397 0.919 0.099619 S100A8 Hs00374264_gl 4.237 5.014 -0.777 0.104673 PTRHD1 Hs00415546_m 1 -1.338 -1.216 -0.122 0.109930 MMP7 Hs01042796_m 1 -2.399 -3.937 1.538 0.115392 TMEM41B Hs01379134_m 1 -1.979 -1.562 -0.417 0.119151 SPP1 Hs00959010_m 1 1.650 0.427 1.224 0.121066 RBM33 Hs00997579_ml 1.600 1.349 0.251 0.152768 NFIB Hs01029174_m 1 -1.757 -1.633 -0.124 0.159806 NEFL Hs00196245_m 1 -0.069 0.561 -0.631 0.162206 NFIC Hs00232157_m 1 -0.500 -0.300 -0.200 0.167086 DCT Hs01098278_ml -3.033 -1.300 -1.733 0.174613 RCHY1 Hs00996236_ml -1.807 -2.038 0.231 0.177178 ZSCAN31 Hs00372831_g 1 -3.639 -2.926 -0.713 0.179770 IPO5P1 Hs05052601_sl -2.927 -3.231 0.303 0.179770 RUNX3 Hs00231709_ml -0.927 -1.342 0.415 0.204381 MKLN1 Hs00992679_ml -0.787 -0.930 0.144 0.204381 ATP6V0E2 Hs04189864_ml -5.596 -6.247 0.651 0.207260 YKT6 Hs00559914_m 1 2.007 1.788 0.220 0.210168 FCHSD1 Hs00703025_sl -6.048 -5.195 -0.854 0.216073 MMP1 Hs00899658_m 1 3.156 2.381 0.774 0.225153 CEP76 Hs00950371_m 1 -3.743 -3.455 -0.288 0.225153 TUFM-M1R4721 Hs00944507_gl 2.465 2.281 0.184 0.228239 AIM2 Hs00915710_m 1 -2.525 -2.720 0.195 0.244123 PTHLH Hs00174969_ml 0.986 1.833 -0.848 0.264188 BHLHB9 Hs01089557_s 1 -14.090 -12.657 -1.433 0.264188 CD163 Hs00174705_m 1 -0.829 -1.156 0.327 0.307655 ZNF839 Hs00901350_g 1 -1.060 -1.316 0.256 0.307655 Gene name Probe Identifier median median delta p-value (ThermoFisher) Recurrent Non- median *
Recurrent BLOC1S1 Hs00155241_m1 -1.061 -0.787 -0.273 0.311480 HDDC3 Hs00826827_gl -1.299 -1.567 0.267 0.319223 TNNC1 Hs00896999_gl -7.015 -5.911 -1.105 0.323141 S100A9 Hs00610058_m1 8.071 8.385 -0.314 0.327091 TUBB3 Hs00801390_s1 -3.190 -2.711 -0.479 0.331071 KIT Hs00174029_m1 -1.168 -1.574 0.406 0.351443 FN1 Hs01549976_m1 2.302 1.859 0.443 0.364039 INHBA Hs01081598_m1 -1.107 -1.166 0.060 0.368299 PIGBOS1 Hs05036222_s1 -0.970 -1.132 0.162 0.372591 THYN1 Hs01553775_gl 0.011 -0.219 0.230 0.376913 HOXA10- Hs00365956_m1 -3.574 -2.521 -1.053 0.412594 MYC Hs00153408_m1 -2.553 -2.337 -0.215 0.440624 IL24 Hs01114274_m1 -3.039 -3.394 0.355 0.455038 NFIA Hs00379134_m1 -0.852 -0.709 -0.143 0.499836 RPL26L1 Hs01631495_s1 -6.405 -6.603 0.198 0.504954 ZNF48 Hs00399035_m1 -3.340 -3.577 0.237 0.520473 MIER2 Hs00380101_m1 -0.275 -0.382 0.108 0.530953 MMP13 Hs00942584_m1 -4.547 -5.058 0.511 0.536233 TYRP1 Hs00167051_m1 -2.547 -2.510 -0.037 0.546872 VIM Hs00958111_m1 4.763 4.373 0.390 0.552231 LRRC47 Hs00975850_m1 0.130 0.070 0.060 0.552231 ALOX12 Hs00167524_m1 -3.032 -2.563 -0.469 0.590445 PLAU Hs01547054_m1 3.212 2.870 0.342 0.612814 IL7R Hs00902334_m1 -4.480 -4.820 0.340 0.624137 DARS Hs00962398_m1 2.314 2.486 -0.172 0.624137 L0C101927502 Hs05033260_s1 -8.529 -8.227 -0.302 0.624137 M1R129-1 Hs03302824_pri -12.122 -13.033 0.910 0.647050 PD1 Hs00240906_m1 -1.233 -1.099 -0.134 0.652832 CYP2D6- Hs03043789_gl -5.343 -5.128 -0.215 0.676166 GTPBP2 Hs01051445_gl -2.289 -2.127 -0.163 0.687952 CXCL10 Hs00171042_m1 -1.850 -1.595 -0.255 0.693874 SLC1A3 Hs00904817_m1 -2.518 -2.534 0.016 0.699815 RNF135 Hs00260480_m1 -0.694 -0.725 0.030 0.711752 NOA1 Hs00260452_m1 -2.426 -2.528 0.102 0.747977 ZNF496 Hs00262107_m1 -1.484 -1.549 0.065 0.760181 MMP12 Hs00159178_m1 -2.301 -2.567 0.266 0.772445 C3orf70 Hs01395177_m1 -4.175 -4.227 0.052 0.784767 LAMC2 Hs01043717_m1 0.874 1.000 -0.126 0.797143 MMP10 Hs00233987_m1 -0.255 0.441 -0.696 0.803350 C1QL4 Hs00884853 sl -10.397 -10.511 0.113 0.822045 Gene name Probe Identifier median median delta p-value (ThermoFisher) Recurrent Non- median *
Recurrent C21orf59 Hs00937509_m1 0.903 0.829 0.074 0.822045 KRT19 Hs01051611_gH -3.414 -2.626 -0.788 0.828299 PDL1 Hs00204257_m1 -2.051 -2.218 0.166 0.847127 SLC25A11 Hs01087946_gl 0.664 0.641 0.024 0.847127 MRC1 Hs00267207_m1 -5.005 -5.020 0.015 0.853423 PIG3 Hs00936519_m1 -3.104 -2.896 -0.207 0.853423 IL2RB Hs00386692_m1 -1.702 -1.592 -0.110 0.878697 ATP6AP 1 Hs05016463_s1 0.173 0.183 -0.011 0.878697 MSANTD4 Hs00411188_gl -3.627 -3.612 -0.015 0.929591 MRPL21 Hs00698959_m1 0.665 0.664 0.002 0.929591 CXCR4 Hs00607978_s1 -5.555 -5.868 0.313 0.935977 RPP38 Hs00705626_s1 -4.839 -4.719 -0.120 0.935977 SEPT3 Hs00251883_m1 -5.165 -5.094 -0.071 0.942368 PDPN Hs00366766_m1 1.995 1.893 0.102 0.948762 CCL27 Hs00171157_m1 -12.962 -11.407 -1.555 0.967963 CHI3L1 Hs01072228_m1 0.794 0.689 0.105 0.974368 DDAH1 Hs00201707_m1 -3.775 -3.568 -0.207 0.980774 MMP9 Hs00957562_m1 2.233 2.368 -0.135 0.987182 NFASC Hs00978280_m1 -2.781 -2.716 -0.066 0.993591 * Positive values indicate an INCREASE in gene expression in recurrent cancer when compared to non-recurrent control; and negative values indicate a DECREASE in gene expression in recurrent cancer when compared to non-recurrent control.
Table 12: Accuracy of gene sets used to predict risk of recurrence and/or metastasis Gene Sensitivity Specificity PPV NPV AUC Kappa set 20-1 0.4958 0.9481 0.5931 0.9370 0.8604 0.4537 20-2 0.5208 0.9333 0.5869 0.9385 0.8101 0.4524 20-3 0.4438 0.9472 0.5829 0.9292 0.8131 0.4147 20-4 0.4708 0.9324 0.5688 0.9318 0.8766 0.4084 20-5 0.4833 0.9324 0.4990 0.9335 0.8242 0.4033 20-6 0.4542 0.9389 0.5722 0.9306 0.8275 0.3991 20-7 0.5396 0.9065 0.4634 0.9395 0.8384 0.3934 20-8 0.3917 0.9537 0.5922 0.9238 0.7275 0.3783 20-9 0.4396 0.9259 0.5132 0.9274 0.8220 0.3673 20-10 0.3708 0.9556 0.5888 0.9228 0.7970 0.3621 20-11 0.4542 0.9241 0.4625 0.9299 0.7701 0.3615 20-12 0.4292 0.9324 0.4984 0.9280 0.7876 0.3613 20-13 0.3896 0.9472 0.5367 0.9234 0.8228 0.3605 20-14 0.4146 0.9343 0.5150 0.9254 0.7698 0.3600 20-15 0.4417 0.9278 0.4798 0.9299 0.7799 0.3553 20-16 0.4271 0.9278 0.4667 0.9262 0.7650 0.3506 20-17 0.4146 0.9287 0.4673 0.9248 0.7613 0.3506 20-18 0.4563 0.9139 0.4518 0.9297 0.8198 0.3491 20-19 0.4188 0.9315 0.5352 0.9270 0.8132 0.3489 20-20 0.4229 0.9296 0.4484 0.9264 0.7674 0.3438 20-21 0.4396 0.9231 0.4449 0.9290 0.8336 0.3420 20-22 0.4354 0.9194 0.4282 0.9268 0.8127 0.3418 20-23 0.3563 0.9537 0.5608 0.9213 0.7605 0.3379 20-24 0.3896 0.9296 0.4846 0.9221 0.7662 0.3357 20-25 0.3896 0.9370 0.4919 0.9218 0.8326 0.3354 30-1 0.4021 0.9648 0.6285 0.9275 0.8091 0.3893 30-2 0.4771 0.9204 0.4672 0.9335 0.8005 0.3739 30-3 0.4438 0.9287 0.4984 0.9287 0.8083 0.3685 30-4 0.4208 0.9306 0.5525 0.9270 0.8064 0.3613 30-5 0.4000 0.9407 0.5432 0.9255 0.7804 0.3513 30-6 0.4542 0.9167 0.4574 0.9288 0.7920 0.3480 30-7 0.3875 0.9407 0.5049 0.9240 0.8209 0.3378 30-8 0.3792 0.9454 0.5218 0.9225 0.7739 0.3375 30-9 0.3542 0.9593 0.5714 0.9207 0.6822 0.3347 30-10 0.4458 0.9157 0.4271 0.9281 0.7544 0.3339 30-11 0.4167 0.9213 0.4288 0.9245 0.7915 0.3329 30-12 0.3813 0.9380 0.4732 0.9216 0.7236 0.3318 30-13 0.3229 0.9565 0.6146 0.9170 0.7093 0.3243 30-14 0.3729 0.9361 0.4768 0.9222 0.7127 0.3187 30-15 0.4042 0.9176 0.3988 0.9225 0.7716 0.3103 30-16 0.3667 0.9306 0.4688 0.9195 0.7127 0.3052 30-17 0.3375 0.9426 0.4744 0.9178 0.6708 0.3025 30-18 0.3813 0.9213 0.4323 0.9205 0.8029 0.2996 30-19 0.4146 0.9102 0.3787 0.9241 0.7652 0.2984 30-20 0.3667 0.9296 0.4427 0.9199 0.7452 0.2954 30-21 0.3583 0.9306 0.4480 0.9197 0.7475 0.2900 30-22 0.3625 0.9241 0.4685 0.9181 0.7671 0.2897 30-23 0.3833 0.9194 0.3956 0.9199 0.7480 0.2891 30-24 0.3417 0.9380 0.4473 0.9187 0.7222 0.2885 30-25 0.3979 0.9120 0.3898 0.9221 0.7419 0.2868 40-1 0.4688 0.9481 0.6105 0.9334 0.8198 0.4340 40-2 0.4021 0.9435 0.5360 0.9242 0.7960 0.3565 40-3 0.3792 0.9426 0.5311 0.9230 0.7486 0.3354 40-4 0.3563 0.9509 0.5030 0.9200 0.7427 0.3325 40-5 0.4125 0.9278 0.4898 0.9257 0.8127 0.3300 40-6 0.3896 0.9361 0.4924 0.9235 0.7824 0.3294 40-7 0.3854 0.9324 0.4662 0.9219 0.7421 0.3248 40-8 0.3646 0.9398 0.5220 0.9212 0.7262 0.3228 40-9 0.3583 0.9380 0.5303 0.9199 0.7621 0.3189 40-10 0.3500 0.9472 0.4906 0.9201 0.7059 0.3161 40-11 0.3938 0.9222 0.4707 0.9225 0.7623 0.3143 40-12 0.3417 0.9500 0.5070 0.9188 0.7769 0.3115 40-13 0.3896 0.9296 0.4195 0.9233 0.7851 0.3047 40-14 0.3479 0.9407 0.4750 0.9178 0.8177 0.3036 40-15 0.3729 0.9269 0.4124 0.9206 0.6769 -- 0.3034 40-16 0.3646 0.9343 0.4224 0.9200 0.7467 0.2989 40-17 0.3792 0.9222 0.4296 0.9204 0.7539 0.2983 40-18 0.3208 0.9435 0.5381 0.9152 0.6774 -- 0.2980 40-19 0.3688 0.9194 0.4660 0.9192 0.6873 0.2940 40-20 0.3854 0.9204 0.4162 0.9224 0.8275 0.2939 40-21 0.3833 0.9167 0.3896 0.9215 0.7007 0.2904 40-22 0.3625 0.9185 0.4270 0.9177 0.6769 0.2904 40-23 0.3313 0.9343 0.4227 0.9160 0.6716 0.2836 40-24 0.3438 0.9407 0.4236 0.9193 0.6736 0.2799 40-25 0.3250 0.9389 0.4582 0.9160 0.6687 -- 0.2774 Table 13: Exemplary gene sets used to predict risk of recurrence and/or metastasis Gene Probe identifiers used for each gene set (probe identifiers from ThermoFisher set Scientific).
20-1 "Hs00705626 sl" "Hs00248075 ml" "Hs01560931 ml" "Hs00167524 ml"
"Hs00366766 ml" "Hs01051445 gl" "Hs00996236 ml" "Hs01089557 sl"
"Hs00262107 ml" "Hs01931732 sl" "Hs00399035 ml" "Hs00231709 ml"
"Hs00411188 gl" "Hs00978280 ml" "Hs00826827 gl" "Hs00232157 ml"
"Hs00747379 ml" "Hs00233987 ml" "Hs01008033 ml" "Hs04194422 sl"
20-2 "Hs00884853 sl" "Hs01920599_gH" "Hs00996236 ml" "Hs00248075 ml"
"Hs00167524 ml" "Hs00747379 ml" "Hs00942584 ml" "Hs01042796 ml"
"Hs00964384 gl" "Hs05052601 sl" "Hs00356958 ml" "Hs00901350_gl"
"Hs01691258 gl" "Hs00992679 ml" "Hs01051611 gH" "Hs04194422 sl"
"Hs01089557 sl" "Hs01087946_gl" "Hs05036222 sl" "Hs00856927 gl"
20-3 "Hs00248075 ml" "Hs00251883 ml" "Hs01089557 sl" "Hs00356958 ml"
"Hs00856927 gl" "Hs00202752 ml" "Hs00950371 ml" "Hs00899658 ml"
"Hs00362096 ml" "Hs01043717 ml" "Hs01560931 ml" "Hs00826827_gl"
"Hs01010736 ml" "Hs00167524 ml" "Hs01031740 ml" "Hs01920599_gH"
"Hs00201707 ml" "Hs00738791 gl" "Hs00962398 ml" "Hs00543973 ml"
20-4 "Hs00962398 ml" "Hs01920599_gH" "Hs01025572 ml" "Hs00159178 ml"
"Hs01089557 sl" "Hs00167524 ml" "Hs00248075 ml" "Hs00386692 ml"
"Hs00856927 gl" "Hs00996236 ml" "Hs01031740 ml" "Hs01010736 ml"
"Hs00900510 ml" "Hs00826827 gl" "Hs01008033 ml" "Hs00415546 ml"
"Hs04942686 ml" "Hs00801390 sl" "Hs01072228 ml" "Hs01547054 ml"
20-5 "Hs00411188 gl" "Hs00248075 ml" "Hs00202752 ml" "Hs00747379 ml"
"Hs01042796 ml" "Hs01920599_gH" "Hs01114274 ml" "Hs00942584 ml"
"Hs00996236 ml" "Hs00167524 ml" "Hs00978280 ml" "Hs00543973 ml"
"Hs00826827 gl" "Hs01560931 ml" "Hs00931763 ml" "Hs01089557 sl"
"Hs00174029 ml" "Hs01029174 ml" "Hs00415546 ml" "Hs00964384_gl"
20-6 "Hs00975850 ml" "Hs04942686 ml" "Hs00202752 ml" "Hs00233987 ml"
"Hs00926053 ml" "Hs00856927 gl" "Hs00992679 ml" "Hs00251883 ml"
"Hs00415546 ml" "Hs00960591 ml" "Hs00901350_gl" "Hs00747379 ml"

"Hs01089557 sl" "Hs00936519 ml" "Hs03043789 gl" "Hs01560931 ml"
"Hs00232157 ml" "Hs00957562 ml" "Hs00248075 ml" "Hs01549976 ml"
20-7 "Hs04194422 s1' "Hs00262107 ml" "Hs01546752 gl" "Hs01920599_gH"
"Hs04189864 ml" "Hs01089557 sl" "Hs01560931 ml" "Hs00705626 s 1"
"Hs01043717 ml" "Hs00747379 ml" "Hs00248075 ml" "Hs00856927_g1"
"Hs01029174 ml" "Hs00543973 ml" "Hs01395177 ml" "Hs00260480 ml"
"Hs00174029 ml" "Hs00387770 ml" "Hs01894962 sl" "Hs00745492 sl"
20-8 "Hs01560931 ml" "Hs00738791 gl" "Hs00856927 gl" "Hs00362096 ml"
"Hs00826827 gl" "Hs01098278 ml" "Hs00975850 ml" "Hs00167524 ml"
"Hs00260452 ml" "Hs04194422 sl" "Hs01043717 ml" "Hs00233987 ml"
"Hs00703025 sl" "Hs00896999_gl" "Hs00167051 ml" "Hs00942584 ml"
"Hs01087946 gl" "Hs00411188 gl" "Hs00747379 ml" "Hs05016463 s 1"
20-9 "Hs00362096 ml" "Hs00942584 ml" "Hs01560931 ml" "Hs00167524 ml"
"Hs00884853 sl" "Hs00248075 ml" "Hs01920599 gH" "Hs00996236 ml"
"Hs00747379 ml" "Hs01089557 sl" "Hs00959010 ml" "Hs00372831_gl"
"Hs04194422 sl" "Hs01043717 ml" "Hs00399035 ml" "Hs01051611_gH"
"Hs01042796 ml" "Hs00968305 ml" "Hs00260452 ml" "Hs01031740 ml"
20-10 "Hs05033260 sl" "Hs00233987 ml" "Hs04194422 sl" "Hs00992679 ml"
"Hs00926053 ml" "Hs00167524 ml" "Hs00202752 ml" "Hs01549976 ml"
"Hs00415546 ml" "Hs01072228 ml" "Hs01691258_gl" "Hs00387770 ml"
"Hs00380101 ml" "Hs00231709 ml" "Hs01920599 gH" "Hs00543973 ml"
"Hs00386692 ml" "Hs00705626 sl" "Hs00196245 ml" "Hs01081598 ml"
20-11 "Hs01114274 ml" "Hs01560931 ml" "Hs00738791_gl" "Hs00931763 ml"
"Hs00996236 ml" "Hs00362096 ml" "Hs00747379 ml" "Hs00411188_gl"
"Hs00900510 ml" "Hs01098278 ml" "Hs00233987 ml" "Hs04194422 s 1"
"Hs00826827 gl" "Hs00856927 gl" "Hs00232157 ml" "Hs01010736 ml"
"Hs00704853 sl" "Hs00959010 ml" "Hs00260480 ml" "Hs00915710 ml"
20-12 "Hs00992679 ml" "Hs00159178 ml" "Hs00167524 ml" "Hs00958111 ml"
"Hs00901350 gl" "Hs00931763 ml" "Hs00233987 ml" "Hs01549976 ml"
"Hs01894962 sl" "Hs01089557 sl" "Hs00171157 ml" "Hs00153408 ml"
"Hs00248075 ml" "Hs03464469 sl" "Hs04194422 sl" "Hs00745492 sl"
"Hs00366766 ml" "Hs00856927 gl" "Hs00957562 ml" "Hs01025572 ml"
20-13 "Hs01379134 ml" "Hs00362096 ml" "Hs05052601 sl" "Hs00959010 ml"
"Hs00251883 ml" "Hs01089557 sl" "Hs00856927 gl" "Hs00167524 ml"
"Hs00159178 ml" "Hs04942686 ml" "Hs00356958 ml" "Hs01042796 ml"
"Hs03464469 sl" "Hs01029174 ml" "Hs00248075 ml" "Hs00610058 ml"
"Hs01070154 ml" "Hs00703025 sl" "Hs00964384 gl" "Hs00705626 sl"
20-14 "Hs00362096 ml" "Hs00996236 ml" "Hs00931763 ml" "Hs01081598 ml"
"Hs01560931 ml" "Hs00167524 ml" "Hs00543973 ml" "Hs01098278 ml"
"Hs00856927 gl" "Hs03043789 gl" "Hs01089557 sl" "Hs01051445 gl"
"Hs00747379 ml" "Hs01114274 ml" "Hs00826827_gl" "Hs00936519 ml"
"Hs00960591 ml" "Hs00201707 ml" "Hs00899658 ml" "Hs04189864 ml"
20-15 "Hs00856927 gl" "Hs04942686 ml" "Hs00248075 ml" "Hs01029174 ml"

"Hs00992679 ml" "Hs00975850 ml" "Hs03464469 sl" "Hs00167524 ml"
"Hs01691258 gl" "Hs00960591 ml" "Hs01089557 sl" "Hs04194422 sl"
"Hs01114274 ml" "Hs00901350 gl" "Hs00936519 ml" "Hs00233987 ml"
"Hs00411188 gl" "Hs00900510 ml" "Hs00174969 ml" "Hs01070154 ml"
20-16 "Hs00826827 gl" "Hs00738791 gl" "Hs00698959 ml" "Hs00153408 ml"
"Hs00167051 ml" "Hs00365956 ml" "Hs04194422 sl" "Hs00167524 ml"
"Hs01560931 ml" "Hs00610058 ml" "Hs00232157 ml" "Hs00996236 ml"
"Hs00705626 sl" "Hs00362096 ml" "Hs01098278 ml" "Hs00997579 ml"
"Hs00559914 ml" "Hs00856927 gl" "Hs00944507 gl" "Hs00379134 ml"
20-17 "Hs00232157 ml" "Hs00543973 ml" "Hs05052601 sl" "Hs00196245 ml"
"Hs01042796 ml" "Hs00411188 gl" "Hs00899658 ml" "Hs00374264_gl"
"Hs01894962 sl" "Hs04194422 sl" "Hs03464469 sl" "Hs00992679 ml"
"Hs00901350 gl" "Hs00362096 ml" "Hs00856927 gl" "Hs00167524 ml"
"Hs01089557 sl" "Hs01931732 sl" "Hs01549976 ml" "Hs01395177 ml"
20-18 "Hs00884853 sl" "Hs00167524 ml" "Hs00978280 ml" "Hs00747379 ml"
"Hs01931732 sl" "Hs00931763 ml" "Hs04942686 ml" "Hs04194422 sl"
"Hs00856927 gl" "Hs00248075 ml" "Hs00901350 gl" "Hs00415546 ml"
"Hs01089557 sl" "Hs01025572 ml" "Hs00231709 ml" "Hs00386692 ml"
"Hs01920599 gH" "Hs00202752 ml" "Hs01029174 ml" "Hs00942584 ml"
20-19 "Hs01547054 ml" "Hs00960591 ml" "Hs03464469 sl" "Hs01560931 ml"
"Hs00153408 ml" "Hs00233987 ml" "Hs01089557 sl" "Hs00366766 ml"
"Hs00248075 ml" "Hs01010736 ml" "Hs00251883 ml" "Hs00996236 ml"
"Hs00610058 ml" "Hs00900510 ml" "Hs01008033 ml" "Hs00978280 ml"
"Hs00260452 ml" "Hs04194422 sl" "Hs00196245 ml" "Hs05052601 sl"
20-20 "Hs01098278 ml" "Hs01072228 ml" "Hs01691258_gl" "Hs00387770 ml"
"Hs00543973 ml" "Hs01920599_gH" "Hs04189864 ml" "Hs05033260 sl"
"Hs00856927 gl" "Hs00366766 ml" "Hs03043789 gl" "Hs04194422 sl"
"Hs00202752 ml" "Hs00936519 ml" "Hs01560931 ml" "Hs00958111 ml"
"Hs00251883 ml" "Hs00704853 sl" "Hs00738791 gl" "Hs00962398 ml"
20-21 "Hs01042796 ml" "Hs01560931 ml" "Hs00884853 sl" "Hs00958111 ml"
"Hs00411188 gl" "Hs05052601 sl" "Hs01920599 gH" "Hs00248075 ml"
"Hs00747379 ml" "Hs00996236 ml" "Hs00251883 ml" "Hs00202752 ml"
"Hs01008033 ml" "Hs00201707 ml" "Hs01051445_gl" "Hs00950371 ml"
"Hs01029174 ml" "Hs00232157 ml" "Hs01087946_gl" "Hs00267207 ml"
20-22 "Hs00559914 ml" "Hs00856927 gl" "Hs00978280 ml" "Hs01920599_gH"
"Hs01560931 ml" "Hs00365956 ml" "Hs00610058 ml" "Hs01008033 ml"
"Hs04194422 sl" "Hs00975850 ml" "Hs00204257 ml" "Hs00950371 ml"
"Hs00705626 sl" "Hs01089557 sl" "Hs00196245 ml" "Hs01042796 ml"
"Hs00174029 ml" "Hs01546752 gl" "Hs01098278 ml" "Hs00231709 ml"
20-23 "Hs04194422 sl" "Hs01089557 sl" "Hs00155241 ml" "Hs00942584 ml"
"Hs05033260 sl" "Hs01546752_gl" "Hs01920599 gH" "Hs01560931 ml"
"Hs00387770 ml" "Hs00399035 ml" "Hs00232157 ml" "Hs00931763 ml"
"Hs00231709 ml" "Hs00856927 gl" "Hs00233987 ml" "Hs01098278 ml"

"Hs00978280 ml" "Hs04942686 ml" "Hs00411188_g1" "Hs00201707 ml"
20-24 "Hs00232157 ml" "Hs01010736 ml" "Hs00704853 sl" "Hs00167051 ml"
"Hs00738791 gl" "Hs00975850 ml" "Hs00362096 ml" "Hs00826827_gl"
"Hs00233987 ml" "Hs00950371 ml" "Hs00204257 ml" "Hs01560931 ml"
"Hs00196245 ml" "Hs01042796 ml" "Hs00174029 ml" "Hs00705626 sl"
"Hs00856927 gl" "Hs01051445 gl" "Hs00399035 ml" "Hs05036222 sl"
20-25 "Hs00233987 ml" "Hs00380101 ml" "Hs00167524 ml" "Hs04189864 ml"
"Hs00543973 ml" "Hs01920599_gH" "Hs00856927_gl" "Hs00155241 ml"
"Hs01098278 ml" "Hs00703025 sl" "Hs00231709 ml" "Hs00365956 ml"
"Hs00204257 ml" "Hs01395177 ml" "Hs00968305 ml" "Hs00374264_gl"
"Hs00248075 ml" "Hs00202752 ml" "Hs00801390 sl" "Hs03464469 sl"
30-1 "Hs00387770 ml" "Hs00155241 ml" "Hs00251883 ml" "Hs01560931 ml"
"Hs00428732 ml" "Hs00992679 ml" "Hs00705626 sl" "Hs00356958 ml"
"Hs00960591 ml" "Hs00171157 ml" "Hs01072228 ml" "Hs01051445_gl"
"Hs00232157 ml" "Hs00233987 ml" "Hs04232205 sl" "Hs00559914 ml"
"Hs00931763 ml" "Hs00167524 ml" "Hs00171042 ml" "Hs01089557 sl"
"Hs04194422 sl" "Hs03464469 sl" "Hs00944507_gl" "Hs00196245 ml"
"Hs00950371 ml" "Hs01395177 ml" "Hs01070154 ml" "Hs01051611_gH"
"Hs00399035 ml" "Hs00703025 sl"
30-2 "Hs00937509 ml" "Hs00379134 ml" "Hs00899658 ml" "Hs00248075 ml"
"Hs01920599 gH" "Hs04194422 sl" "Hs03043789 gl" "Hs00610058 ml"
"Hs01089557 sl" "Hs00705626 sl" "Hs00362096 ml" "Hs01560931 ml"
"Hs00233987 ml" "Hs00372831 gl" "Hs01072228 ml" "Hs01379134 ml"
"Hs01076090 ml" "Hs04189864 ml" "Hs00957562 ml" "Hs01931732 sl"
"Hs00856927 gl" "Hs01546752 gl" "Hs00171157 ml" "Hs00992679 ml"
"Hs00931763 ml" "Hs00411188 gl" "Hs01008033 ml" "Hs00387770 ml"
"Hs00996236 ml" "Hs00231709 ml"
30-3 "Hs00411188 gl" "Hs01395177 ml" "Hs01560931 ml" "Hs00379134 ml"
"Hs00960591 ml" "Hs00745492 sl" "Hs00232157 ml" "Hs00899658 ml"
"Hs00248075 ml" "Hs01010736 ml" "Hs00167524 ml" "Hs01691258_gl"
"Hs00260452 ml" "Hs01070154 ml" "Hs00196245 ml" "Hs00747379 ml"
"Hs01547054 ml" "Hs00950371 ml" "Hs00962398 ml" "Hs01087946_gl"
"Hs00262107 ml" "Hs00260480 ml" "Hs00978280 ml" "Hs00428732 ml"
"Hs00944507 gl" "Hs00387770 ml" "Hs00399035 ml" "Hs00738791_gl"
"Hs00698959 ml" "Hs01549976 ml"
30-4 "Hs00415546 ml" "Hs00705626 sl" "Hs00204257 ml" "Hs00174969 ml"
"Hs00745492 sl" "Hs01920599_gH" "Hs00387770 ml" "Hs01560931 ml"
"Hs00958111 ml" "Hs01076090 ml" "Hs00379134 ml" "Hs00196245 ml"
"Hs00232157 ml" "Hs01549976 ml" "Hs00801390 sl" "Hs00399035 ml"
"Hs01089557 sl" "Hs00607978 sl" "Hs00960591 ml" "Hs00171157 ml"
"Hs05033260 sl" "Hs00233987 ml" "Hs00904817 ml" "Hs01031740 ml"
"Hs05016463 sl" "Hs00153408 ml" "Hs00968305 ml" "Hs00174029 ml"
"Hs00944507 gl" "Hs00248075 ml"

30-5 "Hs05033260 sl" "Hs00362096 ml" "Hs00559914 ml" "Hs01560931 ml"
"Hs00968305 ml" "Hs00931763 ml" "Hs04942686 ml" "Hs01920599_gH"
"Hs00899658 ml" "Hs00248075 ml" "Hs00958111 ml" "Hs05016463 sl"
"Hs03464469 sl" "Hs01931732 sl" "Hs01076090 ml" "Hs00992679 ml"
"Hs00901350 gl" "Hs00937509 ml" "Hs00960591 ml" "Hs01114274 ml"
"Hs01043717 ml" "Hs00167524 ml" "Hs01089557 sl" "Hs00204257 ml"
"Hs00703025 sl" "Hs01549976 ml" "Hs01031740 ml" "Hs00262107 ml"
"Hs00957562 ml" "Hs01029174 ml"
30-6 "Hs00958111 ml" "Hs00411188 gl" "Hs05036222 sl" "Hs00386692 ml"
"Hs00745492 sl" "Hs01010736 ml" "Hs00997579 ml" "Hs00222415 ml"
"Hs03464469 sl" "Hs00233987 ml" "Hs01547054 ml" "Hs00202752 ml"
"Hs01025572 ml" "Hs00379134 ml" "Hs04194422 sl" "Hs00926053 ml"
"Hs01560931 ml" "Hs00705626 sl" "Hs01920599 gH" "Hs00171042 ml"
"Hs03043789 gl" "Hs00610058 ml" "Hs01089557 sl" "Hs00362096 ml"
"Hs00380101 ml" "Hs00899658 ml" "Hs00801390 sl" "Hs00374264_gl"
"Hs00964384 gl" "Hs00240906 ml"
30-7 "Hs00704853 sl" "Hs01560931 ml" "Hs01379134 ml" "Hs00958111 ml"
"Hs00386692 ml" "Hs04942686 ml" "Hs00747379 ml" "Hs00167524 ml"
"Hs03302824_pri" "Hs00248075 ml" "Hs00387770 ml" "Hs00978280 ml"
"Hs00379134 ml" "Hs00233987 ml" "Hs00992679 ml" "Hs01931732 sl"
"Hs00380101 ml" "Hs00705626 sl" "Hs00155241 ml" "Hs05033260 sl"
"Hs01089557 sl" "Hs00171157 ml" "Hs00745492 sl" "Hs00937509 ml"
"Hs00374264 gl" "Hs00240906 ml" "Hs01098278 ml" "Hs00174705 ml"
"Hs00260480 ml" "Hs00372831_gl"
30-8 "Hs00202752 ml" "Hs00231709 ml" "Hs00366766 ml" "Hs00201707 ml"
"Hs00826827 gl" "Hs00856927 gl" "Hs00174969 ml" "Hs00387770 ml"
"Hs00167524 ml" "Hs01031740 ml" "Hs03464469 sl" "Hs01025572 ml"
"Hs00996236 ml" "Hs00950371 ml" "Hs00610058 ml" "Hs01920599_gH"
"Hs01051445 gl" "Hs00975850 ml" "Hs00978280 ml" "Hs00167051 ml"
"Hs01560931 ml" "Hs00704853 sl" "Hs00902334 ml" "Hs01553775_gl"
"Hs00962398 ml" "Hs01098278 ml" "Hs00356958 ml" "Hs01087946_gl"
"Hs01029174 ml" "Hs00747379 ml"
30-9 "Hs00362096 ml" "Hs01560931 ml" "Hs04942686 ml" "Hs05033260 sl"
"Hs00958111 ml" "Hs00232157 ml" "Hs00899658 ml" "Hs00607978 sl"
"Hs01549976 ml" "Hs00262107 ml" "Hs00968305 ml" "Hs00233987 ml"
"Hs00904817 ml" "Hs00356958 ml" "Hs00900510 ml" "Hs00174969 ml"
"Hs04194422 sl" "Hs01043717 ml" "Hs00745492 sl" "Hs00171042 ml"
"Hs00379134 ml" "Hs00559914 ml" "Hs04232205 sl" "Hs00957562 ml"
"Hs00167051 ml" "Hs05052601 sl" "Hs00380101 ml" "Hs01546752_gl"
"Hs00801390 sl" "Hs01070154 ml"
30-10 "Hs00380101 ml" "Hs03464469 sl" "Hs00372831 gl" "Hs05052601 sl"
"Hs04189864 ml" "Hs00248075 ml" "Hs00968305 ml" "Hs04942686 ml"
"Hs00159178 ml" "Hs00386692 ml" "Hs00937509 ml" "Hs00960591 ml"

"Hs00543973 ml" "Hs01894962 sl" "Hs00233987 ml" "Hs01051445_gl"
"Hs01560931 ml" "Hs01089557 sl" "Hs00232157 ml" "Hs00387770 ml"
"Hs01025572 ml" "Hs01395177 ml" "Hs00801390 sl" "Hs00884853 sl"
"Hs01072228 ml" "Hs00201707 ml" "Hs00996236 ml" "Hs01114274 ml"
"Hs00747379 ml" "Hs00167051 ml"
30-11 "Hs00801390 sl" "Hs01920599_gH" "Hs00931763 ml" "Hs00262107 ml"
"Hs04942686 ml" "Hs00233987 ml" "Hs00399035 ml" "Hs00248075 ml"
"Hs00171157 ml" "Hs00167524 ml" "Hs00899658 ml" "Hs00232157 ml"
"Hs00362096 ml" "Hs00915710 ml" "Hs00174969 ml" "Hs00900510 ml"
"Hs00387770 ml" "Hs00428732 ml" "Hs00607978 sl" "Hs00380101 ml"
"Hs00260480 ml" "Hs00996236 ml" "Hs00958111 ml" "Hs01070154 ml"
"Hs00543973 ml" "Hs00937509 ml" "Hs01089557 sl" "Hs00968305 ml"
"Hs01072228 ml" "Hs01042796 ml"
30-12 "Hs00745492 sl" "Hs00950371 ml" "Hs00233987 ml" "Hs01560931 ml"
"Hs00379134 ml" "Hs00167524 ml" "Hs00826827_gl" "Hs00978280 ml"
"Hs00904817 ml" "Hs00856927_gl" "Hs00899658 ml" "Hs01008033 ml"
"Hs00931763 ml" "Hs00365956 ml" "Hs03302824_pri" "Hs00428732 ml"
"Hs00975850 ml" "Hs01894962 sl" "Hs00703025 sl" "Hs01072228 ml"
"Hs01098278 ml" "Hs00958111 ml" "Hs00944507_gl" "Hs01010736 ml"
"Hs00996236 ml" "Hs01920599_gH" "Hs00387770 ml" "Hs01547054 ml"
"Hs00610058 ml" "Hs01087946_gl"
30-13 "Hs00856927 gl" "Hs00915710 ml" "Hs00379134 ml" "Hs00233987 ml"
"Hs01008033 ml" "Hs00167524 ml" "Hs00899658 ml" "Hs00559914 ml"
"Hs00904817 ml" "Hs04942686 ml" "Hs00386692 ml" "Hs00704853 sl"
"Hs00978280 ml" "Hs00415546 ml" "Hs00399035 ml" "Hs00374264 gl"
"Hs01560931 ml" "Hs01546752 gl" "Hs00231709 ml" "Hs00387770 ml"
"Hs00964384 gl" "Hs00698959 ml" "Hs00196245 ml" "Hs01395177 ml"
"Hs01076090 ml" "Hs00201707 ml" "Hs03302824_pri" "Hs00703025 sl"
"Hs01114274 ml" "Hs01631495 sl"
30-14 "Hs00380101 ml" "Hs00232157 ml" "Hs00428732 ml" "Hs03302824_pri"
"Hs01031740 ml" "Hs00171042 ml" "Hs01549976 ml" "Hs00260452 ml"
"Hs00745492 sl" "Hs00411188_gl" "Hs00167524 ml" "Hs01560931 ml"
"Hs00356958 ml" "Hs00559914 ml" "Hs00262107 ml" "Hs03464469 sl"
"Hs00801390 sl" "Hs00202752 ml" "Hs00233987 ml" "Hs00196245 ml"
"Hs00960591 ml" "Hs01546752_gl" "Hs01087946_gl" "Hs01547054 ml"
"Hs00260480 ml" "Hs01070154 ml" "Hs00267207 ml" "Hs00174705 ml"
"Hs00747379 ml" "Hs00387770 ml"
30-15 "Hs00960591 ml" "Hs00231709 ml" "Hs00251883 ml" "Hs00387770 ml"
"Hs00356958 ml" "Hs00196245 ml" "Hs00174969 ml" "Hs00996236 ml"
"Hs00559914 ml" "Hs00962398 ml" "Hs00856927_gl" "Hs00826827_gl"
"Hs01025572 ml" "Hs00801390 sl" "Hs03043789 gl" "Hs00950371 ml"
"Hs00233987 ml" "Hs00202752 ml" "Hs00260480 ml" "Hs00944507_gl"
"Hs00978280 ml" "Hs01894962 sl" "Hs00204257 ml" "Hs00174029 ml"

"Hs00703025 sl" "Hs01051611_gH" "Hs00958111 ml" "Hs00262107 ml"
"Hs00167524 ml" "Hs01098278 ml"
30-16 "Hs00944507 gl" "Hs05016463 sl" "Hs03464469 sl" "Hs00167051 ml"
"Hs00900510 ml" "Hs00904817 ml" "Hs04232205 sl" "Hs00356958 ml"
"Hs00957562 ml" "Hs00745492 sl" "Hs00931763 ml" "Hs01043717 ml"
"Hs00167524 ml" "Hs00856927 gl" "Hs00992679 ml" "Hs00380101 ml"
"Hs01549976 ml" "Hs00559914 ml" "Hs01560931 ml" "Hs01098278 ml"
"Hs00703025 sl" "Hs00248075 ml" "Hs01081598 ml" "Hs00428732 ml"
"Hs00968305 ml" "Hs00705626 sl" "Hs00386692 ml" "Hs00174705 ml"
"Hs00251883 ml" "Hs00415546 ml"
30-17 "Hs00543973 ml" "Hs00159178 ml" "Hs01098278 ml" "Hs00399035 ml"
"Hs01029174 ml" "Hs00705626 sl" "Hs03302824_pri" "Hs01051611 gH"
"Hs05033260 sl" "Hs01560931 ml" "Hs00167524 ml" "Hs01042796 ml"
"Hs05052601 sl" "Hs00944507_gl" "Hs00978280 ml" "Hs00747379 ml"
"Hs00171042 ml" "Hs00251883 ml" "Hs00960591 ml" "Hs01072228 ml"
"Hs03043789 gl" "Hs00233987 ml" "Hs04942686 ml" "Hs00801390 sl"
"Hs00992679 ml" "Hs01010736 ml" "Hs00232157 ml" "Hs00896999 gl"
"Hs00826827 gl" "Hs00231709 ml"
30-18 "Hs01920599_gH" "Hs00248075 ml" "Hs00411188_gl" "Hs01560931 ml"
"Hs00900510 ml" "Hs00996236 ml" "Hs00745492 sl" "Hs00202752 ml"
"Hs00233987 ml" "Hs00222415 ml" "Hs01089557 sl" "Hs05052601 sl"
"Hs00960591 ml" "Hs00958111 ml" "Hs01379134 ml" "Hs00380101 ml"
"Hs00856927 gl" "Hs04189864 ml" "Hs01031740 ml" "Hs01042796 ml"
"Hs01098278 ml" "Hs01395177 ml" "Hs00950371 ml" "Hs01691258_gl"
"Hs00899658 ml" "Hs00962398 ml" "Hs00240906 ml" "Hs00399035 ml"
"Hs00428732 ml" "Hs04942686 ml"
30-19 "Hs00428732 ml" "Hs01560931 ml" "Hs01025572 ml" "Hs00232157 ml"
"Hs01089557 sl" "Hs01043717 ml" "Hs00705626 sl" "Hs00884853 sl"
"Hs00543973 ml" "Hs00992679 ml" "Hs00899658 ml" "Hs00233987 ml"
"Hs00745492 sl" "Hs01031740 ml" "Hs01076090 ml" "Hs00260480 ml"
"Hs00856927 gl" "Hs00189880 ml" "Hs00231709 ml" "Hs01920599_gH"
"Hs00171042 ml" "Hs00415546 ml" "Hs01894962 sl" "Hs04189864 ml"
"Hs00174969 ml" "Hs00610058 ml" "Hs00153408 ml" "Hs01379134 ml"
"Hs00915710 ml" "Hs01395177 ml"
30-20 "Hs00267207 ml" "Hs00366766 ml" "Hs04942686 ml" "Hs00231709 ml"
"Hs01098278 ml" "Hs05016463 sl" "Hs00155241 ml" "Hs00900510 ml"
"Hs00975850 ml" "Hs04194422 sl" "Hs01114274 ml" "Hs01072228 ml"
"Hs01089557 sl" "Hs00747379 ml" "Hs00944507 gl" "Hs00705626 sl"
"Hs00202752 ml" "Hs00978280 ml" "Hs01920599 gH" "Hs00196245 ml"
"Hs04189864 ml" "Hs01025572 ml" "Hs05052601 sl" "Hs00380101 ml"
"Hs01081598 ml" "Hs00372831 gl" "Hs00167051 ml" "Hs00232157 ml"
"Hs01553775 gl" "Hs00738791 gl"
30-21 "Hs00174705 ml" "Hs01042796 ml" "Hs00856927_gl" "Hs00372831_gl"

"Hs03302824_pri" "Hs05033260 sl" "Hs04189864 ml" "Hs00992679 ml"
"Hs01560931 ml" "Hs00159178 ml" "Hs00196245 ml" "Hs05052601 sl"
"Hs01031740 ml" "Hs00233987 ml" "Hs00975850 ml" "Hs01098278 ml"
"Hs00248075 ml" "Hs00167524 ml" "Hs00171042 ml" "Hs01920599 gH"
"Hs00380101 ml" "Hs00559914 ml" "Hs04942686 ml" "Hs00202752 ml"
"Hs00937509 ml" "Hs00978280 ml" "Hs00936519 ml" "Hs00222415 ml"
"Hs00365956 ml" "Hs00379134 ml"
30-22 "Hs00380101 ml" "Hs00233987 ml" "Hs00171042 ml" "Hs00411188_gl"
"Hs00248075 ml" "Hs00559914 ml" "Hs00826827_gl" "Hs01894962 sl"
"Hs01098278 ml" "Hs00232157 ml" "Hs01920599 gH" "Hs00975850 ml"
"Hs00356958 ml" "Hs00543973 ml" "Hs01029174 ml" "Hs00159178 ml"
"Hs05052601 sl" "Hs04194422 sl" "Hs01025572 ml" "Hs00950371 ml"
"Hs00167524 ml" "Hs01072228 ml" "Hs00900510 ml" "Hs00705626 sl"
"Hs01114274 ml" "Hs00904817 ml" "Hs00231709 ml" "Hs00745492 sl"
"Hs00155241 ml" "Hs01081598 ml"
30-23 "Hs00964384 gl" "Hs00899658 ml" "Hs00374264 gl" "Hs00399035 ml"
"Hs00703025 sl" "Hs00415546 ml" "Hs00232157 ml" "Hs00387770 ml"
"Hs00826827 gl" "Hs01395177 ml" "Hs00202752 ml" "Hs00171042 ml"
"Hs00996236 ml" "Hs00937509 ml" "Hs05016463 sl" "Hs00233987 ml"
"Hs01114274 ml" "Hs01042796 ml" "Hs00248075 ml" "Hs00957562 ml"
"Hs00196245 ml" "Hs01560931 ml" "Hs01089557 sl" "Hs00222415 ml"
"Hs04194422 sl" "Hs01931732 sl" "Hs00884853 sl" "Hs00978280 ml"
"Hs00959010 ml" "Hs00559914 ml"
30-24 "Hs01042796 ml" "Hs00801390 sl" "Hs00960591 ml" "Hs00992679 ml"
"Hs00978280 ml" "Hs00937509 ml" "Hs01931732 sl" "Hs01560931 ml"
"Hs05016463 sl" "Hs00171157 ml" "Hs00167524 ml" "Hs00260452 ml"
"Hs01089557 sl" "Hs00232157 ml" "Hs00899658 ml" "Hs00904817 ml"
"Hs00202752 ml" "Hs00958111 ml" "Hs00968305 ml" "Hs00248075 ml"
"Hs00607978 sl" "Hs04942686 ml" "Hs01920599 gH" "Hs00365956 ml"
"Hs00944507 gl" "Hs01043717 ml" "Hs00745492 sl" "Hs00704853 sl"
"Hs00610058 ml" "Hs04194422 sl"
30-25 "Hs00738791 gl" "Hs04232205 sl" "Hs00362096 ml" "Hs00260452 ml"
"Hs01547054 ml" "Hs00196245 ml" "Hs01560931 ml" "Hs00964384_gl"
"Hs00415546 ml" "Hs00202752 ml" "Hs03043789_gl" "Hs00997579 ml"
"Hs00745492 sl" "Hs00174029 ml" "Hs04194422 sl" "Hs00899658 ml"
"Hs00251883 ml" "Hs00915710 ml" "Hs01042796 ml" "Hs04942686 ml"
"Hs00248075 ml" "Hs00222415 ml" "Hs01081598 ml" "Hs01089557 sl"
"Hs00705626 sl" "Hs00356958 ml" "Hs00204257 ml" "Hs00926053 ml"
"Hs05052601 sl" "Hs00372831_gl"
40-1 "Hs00262107 ml" "Hs01560931 ml" "Hs00159178 ml" "Hs00975850 ml"
"Hs00366766 ml" "Hs00543973 ml" "Hs00231709 ml" "Hs00372831_gl"
"Hs00745492 sl" "Hs01072228 ml" "Hs04194422 sl" "Hs00174029 ml"
"Hs00171157 ml" "Hs01029174 ml" "Hs01089557 sl" "Hs00801390 sl"

"Hs00958111 ml" "Hs01098278 ml" "Hs01920599 gH" "Hs00233987 ml"
"Hs00374264 gl" "Hs04189864 ml" "Hs00155241 ml" "Hs00610058 ml"
"Hs03464469 sl" "Hs00386692 ml" "Hs00964384 gl" "Hs01025572 ml"
"Hs01546752 gl" "Hs01395177 ml" "Hs00248075 ml" "Hs00937509 ml"
"Hs00704853 sl" "Hs03028557 sl" "Hs00747379 ml" "Hs00904817 ml"
"Hs00362096 ml" "Hs01087946 gl" "Hs01031740 ml" "Hs00978280 ml"
40-2 "Hs00231709 ml" "Hs01098278 ml" "Hs00174969 ml" "Hs01029174 ml"
"Hs05036222 sl" "Hs00262107 ml" "Hs00856927 gl" "Hs05052601 sl"
"Hs00233987 ml" "Hs00559914 ml" "Hs01931732 sl" "Hs01560931 ml"
"Hs00167524 ml" "Hs00543973 ml" "Hs01010736 ml" "Hs00174029 ml"
"Hs00260480 ml" "Hs00996236 ml" "Hs00745492 sl" "Hs00204257 ml"
"Hs00374264 gl" "Hs04942686 ml" "Hs00411188 gl" "Hs00380101 ml"
"Hs01051611 gH" "Hs01089557 sl" "Hs00901350 gl" "Hs01081598 ml"
"Hs00738791 gl" "Hs01025572 ml" "Hs00248075 ml" "Hs01894962 sl"
"Hs00957562 ml" "Hs00189880 ml" "Hs00937509 ml" "Hs00362096 ml"
"Hs00962398 ml" "Hs00171042 ml" "Hs01076090 ml" "Hs00801390 sl"
40-3 "Hs00978280 ml" "Hs00900510 ml" "Hs00411188_gl" "Hs00174969 ml"
"Hs00171157 ml" "Hs01546752_gl" "Hs04194422 sl" "Hs00826827_gl"
"Hs01010736 ml" "Hs01043717 ml" "Hs00931763 ml" "Hs01089557 sl"
"Hs00703025 sl" "Hs00559914 ml" "Hs03302824_pri" "Hs01087946 gl"
"Hs00950371 ml" "Hs01051445_gl" "Hs00202752 ml" "Hs00380101 ml"
"Hs01553775 gl" "Hs00232157 ml" "Hs00698959 ml" "Hs01098278 ml"
"Hs03464469 sl" "Hs00884853 sl" "Hs00926053 ml" "Hs00936519 ml"
"Hs00745492 sl" "Hs01560931 ml" "Hs00362096 ml" "Hs00204257 ml"
"Hs00240906 ml" "Hs00366766 ml" "Hs00260480 ml" "Hs01549976 ml"
"Hs00997579 ml" "Hs00738791 gl" "Hs01114274 ml" "Hs03043789_gl"
40-4 "Hs00899658 ml" "Hs00543973 ml" "Hs00260452 ml" "Hs00233987 ml"
"Hs03302824_pri" "Hs04189864 ml" "Hs01089557 sl" "Hs05036222 sl"
"Hs00428732 ml" "Hs00374264_gl" "Hs00958111 ml" "Hs00167524 ml"
"Hs00856927 gl" "Hs00964384 gl" "Hs00900510 ml" "Hs00747379 ml"
"Hs01087946 gl" "Hs05033260 sl" "Hs00607978 sl" "Hs04942686 ml"
"Hs00937509 ml" "Hs00380101 ml" "Hs00386692 ml" "Hs00155241 ml"
"Hs01114274 ml" "Hs03028557 sl" "Hs00240906 ml" "Hs01546752_gl"
"Hs00975850 ml" "Hs00610058 ml" "Hs01631495 sl" "Hs00174029 ml"
"Hs00411188 gl" "Hs00559914 ml" "Hs03043789 gl" "Hs00698959 ml"
"Hs00703025 sl" "Hs00745492 sl" "Hs00387770 ml" "Hs01008033 ml"
40-5 "Hs00607978 sl" "Hs01031740 ml" "Hs00174969 ml" "Hs01114274 ml"
"Hs04942686 ml" "Hs00931763 ml" "Hs00996236 ml" "Hs01395177 ml"
"Hs01098278 ml" "Hs00387770 ml" "Hs04194422 sl" "Hs00248075 ml"
"Hs01546752 gl" "Hs00705626 sl" "Hs01920599 gH" "Hs00801390 sl"
"Hs05052601 sl" "Hs00960591 ml" "Hs01076090 ml" "Hs00232157 ml"
"Hs00262107 ml" "Hs00944507 gl" "Hs00174705 ml" "Hs01089557 sl"
"Hs01029174 ml" "Hs01051445 gl" "Hs00362096 ml" "Hs00399035 ml"

"Hs00745492 sl" "Hs00978280 ml" "Hs01043717 ml" "Hs03028557 sl"
"Hs00233987 ml" "Hs00704853 sl" "Hs01008033 ml" "Hs00543973 ml"
"Hs00251883 ml" "Hs01691258 gl" "Hs00155241 ml" "Hs01042796 ml"
40-6 "Hs01931732 sl" "Hs00174705 ml" "Hs00248075 ml" "Hs00174969 ml"
"Hs00950371 ml" "Hs00374264 gl" "Hs00232157 ml" "Hs00747379 ml"
"Hs00884853 sl" "Hs00411188_gl" "Hs01089557 sl" "Hs00196245 ml"
"Hs01029174 ml" "Hs01560931 ml" "Hs00379134 ml" "Hs04942686 ml"
"Hs00738791 gl" "Hs00960591 ml" "Hs00171042 ml" "Hs05016463 sl"
"Hs01025572 ml" "Hs00260480 ml" "Hs00428732 ml" "Hs00705626 sl"
"Hs01114274 ml" "Hs00153408 ml" "Hs00944507_gl" "Hs00171157 ml"
"Hs00962398 ml" "Hs00975850 ml" "Hs00997579 ml" "Hs00931763 ml"
"Hs01379134 ml" "Hs04194422 sl" "Hs00703025 sl" "Hs01553775 gl"
"Hs00365956 ml" "Hs01098278 ml" "Hs00559914 ml" "Hs00992679 ml"
40-7 "Hs00387770 ml" "Hs01031740 ml" "Hs00356958 ml" "Hs00959010 ml"
"Hs01395177 ml" "Hs00705626 sl" "Hs01010736 ml" "Hs00703025 sl"
"Hs00801390 sl" "Hs01894962 sl" "Hs00233987 ml" "Hs00174029 ml"
"Hs00196245 ml" "Hs01051445_gl" "Hs00153408 ml" "Hs01081598 ml"
"Hs00411188_gl" "Hs01089557 sl" "Hs01920599_gH" "Hs00901350 gl"
"Hs00950371 ml" "Hs00997579 ml" "Hs00415546 ml" "Hs00884853 sl"
"Hs00155241 ml" "Hs00915710 ml" "Hs03302824_pri" "Hs01025572 ml"
"Hs00698959 ml" "Hs00167524 ml" "Hs00936519 ml" "Hs00992679 ml"
"Hs00704853 sl" "Hs00960591 ml" "Hs00968305 ml" "Hs00380101 ml"
"Hs00745492 sl" "Hs00201707 ml" "Hs00996236 ml" "Hs00366766 ml"
40-8 "Hs00155241 ml" "Hs01025572 ml" "Hs01087946_gl" "Hs00204257 ml"
"Hs01395177 ml" "Hs05052601 sl" "Hs00962398 ml" "Hs03028557 sl"
"Hs05033260 sl" "Hs00610058 ml" "Hs00174029 ml" "Hs05036222 sl"
"Hs04189864 ml" "Hs00543973 ml" "Hs01081598 ml" "Hs01894962 sl"
"Hs00738791 gl" "Hs00171042 ml" "Hs00957562 ml" "Hs01560931 ml"
"Hs00231709 ml" "Hs01098278 ml" "Hs00703025 sl" "Hs01089557 sl"
"Hs00374264 gl" "Hs01010736 ml" "Hs00901350 gl" "Hs00174969 ml"
"Hs00260480 ml" "Hs00996236 ml" "Hs05016463 sl" "Hs00415546 ml"
"Hs00362096 ml" "Hs00704853 sl" "Hs00975850 ml" "Hs00174705 ml"
"Hs00251883 ml" "Hs00196245 ml" "Hs00222415 ml" "Hs01931732 sl"
40-9 "Hs00267207 ml" "Hs00904817 ml" "Hs01087946_gl" "Hs00233987 ml"
"Hs04194422 sl" "Hs00196245 ml" "Hs03302824_pri" "Hs01089557 sl"
"Hs00936519 ml" "Hs01560931 ml" "Hs00559914 ml" "Hs00171157 ml"
"Hs00900510 ml" "Hs00174705 ml" "Hs00856927_gl" "Hs00950371 ml"
"Hs01043717 ml" "Hs00960591 ml" "Hs01546752_gl" "Hs00957562 ml"
"Hs00372831 gl" "Hs01029174 ml" "Hs00937509 ml" "Hs00411188_gl"
"Hs05016463 sl" "Hs00705626 sl" "Hs00232157 ml" "Hs00174029 ml"
"Hs00978280 ml" "Hs05052601 sl" "Hs05033260 sl" "Hs01920599 gH"
"Hs00231709 ml" "Hs01098278 ml" "Hs01081598 ml" "Hs00997579 ml"
"Hs01051445 gl" "Hs04232205 sl" "Hs00884853 sl" "Hs00738791_gl"

40-10 "Hs01076090 ml" "Hs00387770 ml" "Hs01031740 ml" "Hs00196245 ml"
"Hs03464469 sl" "Hs04232205 sl" "Hs00884853 sl" "Hs00174969 ml"
"Hs00607978 sl" "Hs04942686 ml" "Hs00931763 ml" "Hs01098278 ml"
"Hs00996236 ml" "Hs00960591 ml" "Hs01920599 gH" "Hs01546752 gl"
"Hs00997579 ml" "Hs01087946 gl" "Hs01560931 ml" "Hs00950371 ml"
"Hs01549976 ml" "Hs00747379 ml" "Hs01081598 ml" "Hs01691258_gl"
"Hs00231709 ml" "Hs00399035 ml" "Hs00428732 ml" "Hs00543973 ml"
"Hs00240906 ml" "Hs00372831 gl" "Hs00703025 sl" "Hs00171042 ml"
"Hs01043717 ml" "Hs01025572 ml" "Hs00222415 ml" "Hs00937509 ml"
"Hs00267207 ml" "Hs00915710 ml" "Hs00366766 ml" "Hs00610058 ml"
40-11 "Hs00610058 ml" "Hs00745492 sl" "Hs00901350_gl" "Hs01051611_gH"
"Hs01087946 gl" "Hs05052601 sl" "Hs03028557 sl" "Hs00248075 ml"
"Hs01089557 sl" "Hs00738791 gl" "Hs00374264_gl" "Hs00543973 ml"
"Hs04189864 ml" "Hs00698959 ml" "Hs05036222 sl" "Hs00962398 ml"
"Hs00362096 ml" "Hs03043789_gl" "Hs03302824_pri" "Hs00380101 ml"
"Hs00232157 ml" "Hs01553775_gl" "Hs01547054 ml" "Hs00174705 ml"
"Hs00936519 ml" "Hs00386692 ml" "Hs00926053 ml" "Hs00996236 ml"
"Hs00960591 ml" "Hs01098278 ml" "Hs01560931 ml" "Hs00202752 ml"
"Hs04942686 ml" "Hs00428732 ml" "Hs01072228 ml" "Hs00884853 sl"
"Hs00931763 ml" "Hs00964384_gl" "Hs00826827_gl" "Hs00155241 ml"
40-12 "Hs00174705 ml" "Hs00698959 ml" "Hs01546752_gl" "Hs00262107 ml"
"Hs03464469 sl" "Hs00996236 ml" "Hs00960591 ml" "Hs00387770 ml"
"Hs00204257 ml" "Hs00801390 sl" "Hs00610058 ml" "Hs01631495 sl"
"Hs01081598 ml" "Hs00240906 ml" "Hs01553775_gl" "Hs00362096 ml"
"Hs00899658 ml" "Hs00248075 ml" "Hs01894962 sl" "Hs01089557 sl"
"Hs00747379 ml" "Hs01560931 ml" "Hs00267207 ml" "Hs01010736 ml"
"Hs00901350 gl" "Hs03302824_pri" "Hs01547054 ml" "Hs00386692 ml"
"Hs01098278 ml" "Hs00399035 ml" "Hs00189880 ml" "Hs00232157 ml"
"Hs00356958 ml" "Hs00167524 ml" "Hs00380101 ml" "Hs04942686 ml"
"Hs00174969 ml" "Hs00968305 ml" "Hs00745492 sl" "Hs00366766 ml"
40-13 "Hs01546752 gl" "Hs01920599 gH" "Hs00801390 sl" "Hs01560931 ml"
"Hs04194422 sl" "Hs01081598 ml" "Hs00251883 ml" "Hs00559914 ml"
"Hs00262107 ml" "Hs00374264_gl" "Hs00543973 ml" "Hs00171157 ml"
"Hs00937509 ml" "Hs01029174 ml" "Hs00174969 ml" "Hs00232157 ml"
"Hs00705626 sl" "Hs05016463 sl" "Hs01553775 gl" "Hs00704853 sl"
"Hs01691258 gl" "Hs00167524 ml" "Hs00962398 ml" "Hs00978280 ml"
"Hs00248075 ml" "Hs00386692 ml" "Hs00959010 ml" "Hs01098278 ml"
"Hs00884853 sl" "Hs00174705 ml" "Hs00996236 ml" "Hs00379134 ml"
"Hs04942686 ml" "Hs00202752 ml" "Hs00189880 ml" "Hs00365956 ml"
"Hs03302824_pri" "Hs00926053 ml" "Hs01395177 ml" "Hs04189864 ml"
40-14 "Hs00747379 ml" "Hs00362096 ml" "Hs00386692 ml" "Hs01089557 sl"
"Hs01029174 ml" "Hs00960591 ml" "Hs00248075 ml" "Hs01547054 ml"
"Hs01631495 sl" "Hs00189880 ml" "Hs00167524 ml" "Hs01098278 ml"

"Hs00996236 ml" "Hs00240906 ml" "Hs01087946_g1" "Hs00884853 sl"
"Hs00899658 ml" "Hs00380101 ml" "Hs04942686 ml" "Hs00936519 ml"
"Hs00856927 gl" "Hs01043717 ml" "Hs00915710 ml" "Hs00231709 ml"
"Hs00964384 gl" "Hs00387770 ml" "Hs00155241 ml" "Hs01081598 ml"
"Hs00926053 ml" "Hs00366766 ml" "Hs00171042 ml" "Hs01031740 ml"
"Hs00959010 ml" "Hs01546752 gl" "Hs00233987 ml" "Hs01042796 ml"
"Hs00896999 gl" "Hs00374264 gl" "Hs04232205 sl" "Hs00201707 ml"
40-15 "Hs00703025 sl" "Hs01087946_gl" "Hs05016463 sl" "Hs00167524 ml"
"Hs00543973 ml" "Hs01010736 ml" "Hs05052601 sl" "Hs00957562 ml"
"Hs00856927 gl" "Hs04232205 sl" "Hs01029174 ml" "Hs00251883 ml"
"Hs01931732 sl" "Hs00262107 ml" "Hs00374264 gl" "Hs01560931 ml"
"Hs00174969 ml" "Hs00937509 ml" "Hs00222415 ml" "Hs00801390 sl"
"Hs00959010 ml" "Hs00231709 ml" "Hs00747379 ml" "Hs00411188_gl"
"Hs01051445 gl" "Hs00174029 ml" "Hs01553775 gl" "Hs01072228 ml"
"Hs01089557 sl" "Hs00415546 ml" "Hs00705626 sl" "Hs00387770 ml"
"Hs00745492 sl" "Hs00153408 ml" "Hs00196245 ml" "Hs00884853 sl"
"Hs04189864 ml" "Hs00936519 ml" "Hs00958111 ml" "Hs00607978 sl"
40-16 "Hs01920599 gH" "Hs04189864 ml" "Hs01114274 ml" "Hs01395177 ml"
"Hs00374264 gl" "Hs00174029 ml" "Hs00958111 ml" "Hs03028557 sl"
"Hs00856927 gl" "Hs00153408 ml" "Hs01089557 sl" "Hs00607978 sl"
"Hs00201707 ml" "Hs00155241 ml" "Hs00233987 ml" "Hs00745492 sl"
"Hs00610058 ml" "Hs00964384 gl" "Hs04942686 ml" "Hs00996236 ml"
"Hs00174969 ml" "Hs00944507 gl" "Hs00248075 ml" "Hs00362096 ml"
"Hs00174705 ml" "Hs01043717 ml" "Hs00260452 ml" "Hs00167524 ml"
"Hs00380101 ml" "Hs00559914 ml" "Hs00159178 ml" "Hs04194422 sl"
"Hs00399035 ml" "Hs01931732 sl" "Hs00703025 sl" "Hs00738791 gl"
"Hs00826827 gl" "Hs00997579 ml" "Hs00204257 ml" "Hs01070154 ml"
40-17 "Hs00978280 ml" "Hs01553775 gl" "Hs01029174 ml" "Hs00996236 ml"
"Hs00386692 ml" "Hs00738791 gl" "Hs01089557 sl" "Hs00365956 ml"
"Hs00607978 sl" "Hs00248075 ml" "Hs01098278 ml" "Hs00962398 ml"
"Hs00196245 ml" "Hs00232157 ml" "Hs00167524 ml" "Hs04942686 ml"
"Hs00201707 ml" "Hs00915710 ml" "Hs01549976 ml" "Hs00901350_gl"
"Hs04194422 sl" "Hs00997579 ml" "Hs01031740 ml" "Hs00904817 ml"
"Hs01631495 sl" "Hs00153408 ml" "Hs00975850 ml" "Hs00428732 ml"
"Hs00366766 ml" "Hs04232205 sl" "Hs01547054 ml" "Hs00900510 ml"
"Hs01560931 ml" "Hs00747379 ml" "Hs00356958 ml" "Hs00899658 ml"
"Hs00415546 ml" "Hs00362096 ml" "Hs00937509 ml" "Hs00958111 ml"
40-18 "Hs00201707 ml" "Hs04942686 ml" "Hs04194422 sl" "Hs00899658 ml"
"Hs00260452 ml" "Hs01043717 ml" "Hs00262107 ml" "Hs01070154 ml"
"Hs01029174 ml" "Hs00856927 gl" "Hs01098278 ml" "Hs00996236 ml"
"Hs00944507 gl" "Hs00372831 gl" "Hs00356958 ml" "Hs01051611_gH"
"Hs00380101 ml" "Hs01076090 ml" "Hs00703025 sl" "Hs00251883 ml"
"Hs01560931 ml" "Hs00171157 ml" "Hs00386692 ml" "Hs05016463 sl"

"Hs00167524 ml" "Hs01089557 sl" "Hs00171042 ml" "Hs00745492 sl"
"Hs00610058 ml" "Hs00884853 sl" "Hs00958111 ml" "Hs04189864 ml"
"Hs00704853 sl" "Hs00543973 ml" "Hs00374264 gl" "Hs01087946_gl"
"Hs00415546 ml" "Hs05036222 sl" "Hs00904817 ml" "Hs01072228 ml"
40-19 "Hs01072228 ml" "Hs00915710 ml" "Hs00174705 ml" "Hs00356958 ml"
"Hs00174029 ml" "Hs00958111 ml" "Hs00248075 ml" "Hs01553775_gl"
"Hs01098278 ml" "Hs00957562 ml" "Hs00937509 ml" "Hs00960591 ml"
"Hs00747379 ml" "Hs00387770 ml" "Hs01547054 ml" "Hs00698959 ml"
"Hs00399035 ml" "Hs00607978 sl" "Hs04942686 ml" "Hs00240906 ml"
"Hs00962398 ml" "Hs00232157 ml" "Hs00267207 ml" "Hs00996236 ml"
"Hs00704853 sl" "Hs00365956 ml" "Hs00196245 ml" "Hs00959010 ml"
"Hs00884853 sl" "Hs01691258_gl" "Hs00950371 ml" "Hs00260480 ml"
"Hs00174969 ml" "Hs01560931 ml" "Hs00964384_gl" "Hs00738791_gl"
"Hs00543973 ml" "Hs00171042 ml" "Hs04189864 ml" "Hs00415546 ml"
40-20 "Hs00559914 ml" "Hs00856927_gl" "Hs00232157 ml" "Hs01029174 ml"
"Hs00978280 ml" "Hs01051445_gl" "Hs01031740 ml" "Hs00899658 ml"
"Hs00174705 ml" "Hs00153408 ml" "Hs00362096 ml" "Hs00944507 gl"
"Hs00260452 ml" "Hs00937509 ml" "Hs00826827_gl" "Hs00248075 ml"
"Hs01043717 ml" "Hs01070154 ml" "Hs01076090 ml" "Hs01560931 ml"
"Hs01920599 gH" "Hs00543973 ml" "Hs00380101 ml" "Hs00997579 ml"
"Hs03043789 gl" "Hs00901350 gl" "Hs03302824_pri" "Hs00399035 ml"
"Hs00747379 ml" "Hs01114274 ml" "Hs04232205 sl" "Hs05016463 sl"
"Hs00387770 ml" "Hs00366766 ml" "Hs04194422 sl" "Hs01008033 ml"
"Hs01395177 ml" "Hs00904817 ml" "Hs03464469 sl" "Hs01894962 sl"
40-21 "Hs00826827 gl" "Hs00899658 ml" "Hs01076090 ml" "Hs00411188_gl"
"Hs05036222 sl" "Hs00171042 ml" "Hs00926053 ml" "Hs00233987 ml"
"Hs00174029 ml" "Hs00902334 ml" "Hs00958111 ml" "Hs00153408 ml"
"Hs01081598 ml" "Hs01051445 gl" "Hs04189864 ml" "Hs00962398 ml"
"Hs00155241 ml" "Hs00380101 ml" "Hs01560931 ml" "Hs00167524 ml"
"Hs00171157 ml" "Hs00260480 ml" "Hs00174969 ml" "Hs01114274 ml"
"Hs00705626 sl" "Hs01920599_gH" "Hs00428732 ml" "Hs01031740 ml"
"Hs05016463 sl" "Hs01549976 ml" "Hs00931763 ml" "Hs00703025 sl"
"Hs00960591 ml" "Hs05052601 sl" "Hs00937509 ml" "Hs01098278 ml"
"Hs00968305 ml" "Hs01087946 gl" "Hs00959010 ml" "Hs01089557 sl"
40-22 "Hs00904817 ml" "Hs00260480 ml" "Hs00856927_gl" "Hs01894962 sl"
"Hs00171042 ml" "Hs00171157 ml" "Hs01098278 ml" "Hs00202752 ml"
"Hs01076090 ml" "Hs00964384 gl" "Hs00155241 ml" "Hs00950371 ml"
"Hs01042796 ml" "Hs00826827 gl" "Hs00958111 ml" "Hs00899658 ml"
"Hs00233987 ml" "Hs00926053 ml" "Hs01029174 ml" "Hs00174029 ml"
"Hs01081598 ml" "Hs00159178 ml" "Hs00975850 ml" "Hs00232157 ml"
"Hs00251883 ml" "Hs00372831 gl" "Hs00957562 ml" "Hs00610058 ml"
"Hs01043717 ml" "Hs05033260 sl" "Hs01920599 gH" "Hs00543973 ml"
"Hs01560931 ml" "Hs00901350 gl" "Hs00705626 sl" "Hs05016463 sl"

"Hs00260452 ml" "Hs01553775 gl" "Hs00153408 ml" "Hs00962398 ml"
40-23 "Hs00801390 sl" "Hs00174969 ml" "Hs00959010 ml" "Hs00968305 ml"
"Hs01547054 ml" "Hs01072228 ml" "Hs00262107 ml" "Hs01114274 ml"
"Hs00937509 ml" "Hs01051611_gH" "Hs01920599 gH" "Hs01031740 ml"
"Hs00399035 ml" "Hs00962398 ml" "Hs00233987 ml" "Hs00167524 ml"
"Hs00826827 gl" "Hs01010736 ml" "Hs03302824_pri" "Hs01549976 ml"
"Hs00901350 gl" "Hs00975850 ml" "Hs00904817 ml" "Hs00380101 ml"
"Hs00387770 ml" "Hs04232205 sl" "Hs00240906 ml" "Hs00997579 ml"
"Hs01560931 ml" "Hs01631495 sl" "Hs05052601 sl" "Hs00738791 gl"
"Hs00171157 ml" "Hs00232157 ml" "Hs00978280 ml" "Hs00372831 gl"
"Hs00704853 sl" "Hs00745492 sl" "Hs00936519 ml" "Hs00204257 ml"
40-24 "Hs01549976 ml" "Hs00260480 ml" "Hs01031740 ml" "Hs05052601 sl"
"Hs05016463 sl" "Hs00196245 ml" "Hs01025572 ml" "Hs01042796 ml"
"Hs00944507 gl" "Hs00171157 ml" "Hs00167524 ml" "Hs00962398 ml"
"Hs00428732 ml" "Hs00543973 ml" "Hs01560931 ml" "Hs01087946 gl"
"Hs00960591 ml" "Hs04189864 ml" "Hs00826827_gl" "Hs00380101 ml"
"Hs01691258 gl" "Hs00386692 ml" "Hs00374264_gl" "Hs00745492 sl"
"Hs00884853 sl" "Hs00411188_gl" "Hs00936519 ml" "Hs00240906 ml"
"Hs00232157 ml" "Hs01098278 ml" "Hs03302824_pri" "Hs00248075 ml"
"Hs00801390 sl" "Hs01553775_gl" "Hs03464469 sl" "Hs00738791 gl"
"Hs01631495 sl" "Hs00703025 sl" "Hs00896999 gl" "Hs01010736 ml"
40-25 "Hs04189864 ml" "Hs00386692 ml" "Hs00926053 ml" "Hs00260452 ml"
"Hs00610058 ml" "Hs00958111 ml" "Hs00704853 sl" "Hs00380101 ml"
"Hs00543973 ml" "Hs00167524 ml" "Hs00747379 ml" "Hs00428732 ml"
"Hs00559914 ml" "Hs00738791 gl" "Hs00260480 ml" "Hs00703025 sl"
"Hs00975850 ml" "Hs01025572 ml" "Hs01098278 ml" "Hs01560931 ml"
"Hs00745492 sl" "Hs00233987 ml" "Hs00232157 ml" "Hs05016463 sl"
"Hs00607978 sl" "Hs00171042 ml" "Hs00884853 sl" "Hs01691258 gl"
"Hs00196245 ml" "Hs01081598 ml" "Hs00251883 ml" "Hs00904817 ml"
"Hs01114274 ml" "Hs00222415 ml" "Hs01051445_gl" "Hs01042796 ml"
"Hs00356958 ml" "Hs00944507 gl" "Hs00379134 ml" "Hs00705626 sl"
See Table 11 for gene name associated with each probe ID.
All references cited in this application are expressly incorporated by reference herein.

Claims (26)

WHAT IS CLAIMED IS:
1. Claim 1: A method for treating a patient with a cutaneous squamous cell carcinoma (cSCC) tumor, the method comprising:
   (a) obtaining a diagnosis identifying a risk of local recurrence, distant metastasis, or both in a cSCC tumor sample from the patient, wherein the diagnosis was obtained by:
   (1) determining the expression level of at least 10 genes in a gene set;
   wherein the at least 10 genes in the gene set are selected from:
   ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31;
   (2) comparing the expression levels of the at least 10 genes in the gene set from the cSCC tumor sample to the expression levels of the at least 10 genes in the gene set from a predictive training set to generate a probability score of the risk of local recurrence, distant metastasis, or both;
   (3) providing an indication as to whether the cSCC tumor has a low risk to a high risk of local recurrence, distant metastasis, or both based on the probability score generated in step (2); and (4) identifying that the cSCC tumor has a high risk of local recurrence, distant metastasis, or both based on the probability score and diagnosing the cSCC
   tumor as having a high risk of local recurrence, distant metastasis, or both;
   and (b) administering to the patient an aggressive treatment when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both.
2. Claim 2: The method of claim 1, further comprising performing a resection of the cSCC
   tumor when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both.
3. Claim 3: The method of either claim 1 or 2, wherein the expression level of each gene in a gene set is determined by reverse transcribing the isolated mRNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following RT-PCR.
4. Claim 4: The method of any one of claims 1 to 3, wherein the cSCC tumor sample is obtained from a formalin-fixed, paraffin embedded sample.
5. Claim 5: The method of any one of claims 1 to 4, wherein the probability score is between 0 and 1, and wherein a value of 1 indicates a higher probability of local recurrence, distant metastasis, or both than a value of 0.
6. Claim 6: The method of any one of claims 1 to 5, wherein the probability score is a bimodal, two-class analysis, wherein a patient having a value of between 0 and 0.499 is designated as class 1 (low risk) and a patient having a value of between 0.500 and 1.00 is designated as class 2 (high risk).
7. Claim 7: The method of any one of claims 1 to 6, wherein the probability score is a tri-modal, three-class analysis, wherein patients are designated as class A (low risk), class B
   (intermediate risk), or class C (high risk).
8. Claim 8: The method of any one of claims 1 to 7, wherein the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
9. Claim 9: The method of any one of claims 1 to 8, wherein the gene set comprises 20 genes, 30 genes, or 40 genes.
10. Claim 10: A method of treating a patient with a cutaneous squamous cell carcinoma (cSCC) tumor, the method comprising administering an aggressive cancer treatment regimen to the patient, wherein the patient has a cSCC tumor with a probability score of between 0.500 and 1.00 as generated by comparing the expression levels of at least 10 genes selected from ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERP1NB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31 from the cSCC tumor with the expression levels of the same at least ten genes selected from ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31 from a predictive training set.
11. Claim 11: The method of claim 10, wherein the probability score is determined by a bimodal, two-class analysis, wherein a patient having a value of between 0 and 0.499 is designated as class 1 with a low risk of local recurrence, distant metastasis, or both, and a patient having a value of between 0.500 and 1.00 is designated as class 2 with an increased risk of local recurrence, distant metastasis, or both.
12. Claim 12: The method of either claim 10 or 11, wherein the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP I, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
13. Claim 13: The method of either claim 10 or 12, wherein the gene set comprises 20 genes, 30 genes, or 40 genes.
14. Claim 14: A kit comprising primer pairs suitable for the detection and quantification of nucleic acid expression of at least ten genes selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
15. Claim 15: The kit of claim 14, wherein the primer pairs suitable for the detection and quantification of nucleic acid expression of at least ten genes are primer pairs for: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, S100A8, S100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
16. Claim 16: The kit of claim 14, wherein the primer pairs comprise primer pairs for 10 genes, 20 genes, 30 genes, 40 genes, or more than 40 genes.
17. Claim 17: A method for predicting risk of recurrence, metastasis, or both, in a patient with a cutaneous squamous cell carcinoma (cSCC) tumor, the method comprising:
    (a) obtaining a cSCC tumor sample from the patient and isolating mRNA from the sample;
    (b) determining the expression level of at least 10 genes in a gene set;
    wherein the at least ten genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERP1NB2, SERP1NB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31;
    (c) comparing the expression levels of the at least 10 genes in the gene set from the cSCC tumor sample to the expression levels of the at least 10 genes in the gene set from a predictive training set to generate a probability score of the risk of local recurrence, distant metastasis, or both; and (d) providing an indication as to whether the cSCC tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the probability score generated in step (c).
18. Claim 18: The method of claim 17, wherein the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR).
19. Claim 19: The method of either claim 17 or 18, wherein the cSCC tumor sample is obtained from a formalin-fixed, paraffin embedded sample.
20. Claim 20: The method of any one of claims 17 to 19, wherein the probability score of local recurrence, distant metastasis, or both is between 0 and 1, and wherein a value of 1 indicates a higher probability of local recurrence, distant metastasis, or both than a value of 0.
21. Claim 21: The method of any one of claims 17 to 20, wherein the probability score is a bimodal, two-class analysis, wherein a patient having a value of between 0 and 0.499 is designated as class 1 (low risk) and a patient having a value of between 0.500 and 1.00 is designated as class 2 (high risk).
22. Claim 22: The method of any one of claims 17 to 21, wherein the probability score is a tri-modal, three-class analysis, wherein patients are designated as class A
    (low risk), class B
    (intermediate risk), or class C (high risk).
23. Claim 23: The method of any one of claims 17 to 22, further comprising identifying the cSCC tumor has a high risk of local recurrence, distant metastasis, or both based on the probability score, and administering to the patient an aggressive tumor treatment.
24. Claim 24: The method of any one of claims 17 to 23, wherein the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
25. Claim 25: The method of any one of claims 17 to 24, wherein the gene set comprises 20 genes, 30 genes, or 40 genes.
26. Claim 26: A method for predicting risk of recurrence, metastasis, or both, in a patient with a cutaneous squamous cell carcinoma (cSCC) tumor, the method comprising:
    (a) obtaining a cSCC tumor sample from the patient and isolating mRNA from the sample;
    (b) determining the expression level of at least 10 genes in a gene set;
    wherein the at least ten genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERP1NB2, SERP1NB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31; and (c) providing an indication as to whether the cSCC tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the expression level of at least genes generated in step (b).
    5 Claim 27: The method of claim 26, wherein the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR).
    10 Claim 28: The method of either claim 26 or 27, wherein the cSCC
    tumor sample is obtained from formalin-fixed, paraffin embedded sample.
    Claim 29: The method of any one of claims 26 to 28, wherein the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21 orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), .. L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
    Claim 30: The method of any one of claims 26 to 28, wherein the gene set comprises 20 genes, 30 genes, or 40 genes.
    Claim 31: The method of claim 26, wherein the expression level of:
    ACSBG1 is decreased, AIM2 is increased, ALOX12 is decreased, ANXA9 is decreased, APOBEC3G is increased, ARPC2 is decreased, ATP6AP1 is decreased, ATP6V0E2 is increased, BBC is increased, BHLHB9 is decreased, BLOC1S1 is decreased, C1QL4 is increased, C21orf59 is increased, C3orf70 is increased, CCL27 is decreased, CD163 is increased, CEP76 is decreased, CHI3L1 is increased, CHMP2B is decreased, CXCL10 is decreased, CXCR4 is increased, CYP2D6 (L0C101929829) is decreased, DARS
    is decreased, DCT is decreased, DDAH1 is decreased, DSS1 is decreased, DUXAP8 is increased, EGFR is increased, EphB2 is increased, FCHSD1 is decreased, FDFT1 is decreased, FLG is decreased, FN1 is increased, GTPBP2 is decreased, HDDC3 is increased, HNRNPL is decreased, HOXA10 (HOXA9, MIR196B) is decreased, HPGD is decreased, ID2 is decreased, IL24 is increased, IL2RB is decreased, IL7R is increased, INHBA is increased, IPO5P1 is increased, KIT is increased, KLK5 is decreased, KRT17 is decreased, KRT18 is increased, KRT19 is decreased, KRT6B is decreased, LAMC2 is decreased, LCE2B is decreased, LIME1 (ZGPAT) is increased, L0C100287896 is increased, L0C101927502 is decreased, LOR is decreased, LRRC47 is increased, MIER2 is increased, MIR129-1 is increased, MIR3916 is increased, MKLN1 is increased, MMP1 is increased, MMP10 is decreased, MMP12 is increased, MMP13 is increased, MMP3 is increased, is increased, MMP9 is decreased, MRC1 is increased, MRPL21 is increased, MSANTD4 is decreased, MYC is decreased, NEB is decreased, NEFL is decreased, NFASC is decreased, NFIA is decreased, NFIB is decreased, NFIC is decreased, NOA1 is increased, PD1 is decreased, PDL1 is increased, PDPN is increased, PI3 is decreased, PIG3 is decreased, PIGBOS1 is increased, PIM2 is increased, PLAU is increased, PLS3 is decreased, PTHLH is decreased, PTRHD1 is decreased, RBM33 is increased, RCHY1 is increased, RNF135 is increased, RPL26L1 is increased, RPP38 is decreased, RUNX3 is increased, 5100A8 is decreased, 5100A9 is decreased, SEPT3 is decreased, SERPINB2 is decreased, SERP1NB4 is decreased, SLC1A3 is increased, SLC25A11 is increased, SNORD124 is increased, SPATA41 is increased, SPP1 is increased, TAF6L is increased, TFAP2B is decreased, THYN1 is increased, TMEM41B is decreased, TNNC1 is decreased, TUBB3 is decreased, TUFM (MIR4721) is increased, TYRP1 is decreased, UGP2 is decreased, USP7 is decreased, VIM is increased, YKT6 is increased, ZNF48 is increased, ZNF496 is increased, ZNF839 is increased, and/or ZSCAN31 is decreased when comparing a recurrent tumor to a non-recurrent sample.
    Claim 32: The method of claim 31, wherein the increase or decrease in the expression level is the gene level from a recurrent sample versus a non-recurrent sample.
    
    Claim 33: A method for treating a patient with cutaneous squamous cell carcinoma (cSCC) tumor, the method comprising:
    (a) obtaining a cSCC tumor sample from the patient and isolating mRNA from the sample;
    (b) determining the expression level of at least 10 genes in a gene set;
    wherein the at least ten genes in the gene set are selected from: ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERP1NB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31;
    (c) providing an indication as to whether the cSCC tumor has a low risk to a high risk of local recurrence, distant metastasis, or both, based on the expression level of at least 10 genes generated in step (b); and (d) administering to the patient an aggressive treatment when the determination is made in the affirmative that the patient has a cSCC tumor with a high risk of local recurrence, distant metastasis, or both.
    Claim 34: The method of claim 33, wherein the expression level of each gene in the gene set is determined by reverse transcribing the isolated mRNA into cDNA and measuring a level of fluorescence for each gene in the gene set by a nucleic acid sequence detection system following Real-Time Polymerase Chain Reaction (RT-PCR).
    Claim 35: The method of either claim 33 or 34, wherein the cSCC tumor sample is obtained from a formalin-fixed, paraffin embedded sample.
    
    Claim 36: The method of any one of claims 33 to 35, wherein the gene set comprises the genes ACSBG1, AIM2, ALOX12, ANXA9, APOBEC3G, ARPC2, ATP6AP1, ATP6V0E2, BBC, BHLHB9, BLOC1S1, C1QL4, C21 orf59, C3orf70, CCL27, CD163, CEP76, CHI3L1, CHMP2B, CXCL10, CXCR4, CYP2D6 (L0C101929829), DARS, DCT, DDAH1, DSS1, DUXAP8, EGFR, EphB2, FCHSD1, FDFT1, FLG, FN1, GTPBP2, HDDC3, HNRNPL, HOXA10 (HOXA9, MIR196B), HPGD, ID2, IL24, IL2RB, IL7R, INHBA, IPO5P1, KIT, KLK5, KRT17, KRT18, KRT19, KRT6B, LAMC2, LCE2B, LIME1 (ZGPAT), L0C100287896, L0C101927502, LOR, LRRC47, MIER2, MIR129-1, MIR3916, MKLN1, MMP1, MMP10, MMP12, MMP13, MMP3, MMP7, MMP9, MRC1, MRPL21, MSANTD4, MYC, NEB, NEFL, NFASC, NFIA, NFIB, NFIC, NOA1, PD1, PDL1, PDPN, PI3, PIG3, PIGBOS1, PIM2, PLAU, PLS3, PTHLH, PTRHD1, RBM33, RCHY1, RNF135, RPL26L1, RPP38, RUNX3, 5100A8, 5100A9, SEPT3, SERPINB2, SERPINB4, SLC1A3, SLC25A11, SNORD124, SPATA41, SPP1, TAF6L, TFAP2B, THYN1, TMEM41B, TNNC1, TUBB3, TUFM (MIR4721), TYRP1, UGP2, USP7, VIM, YKT6, ZNF48, ZNF496, ZNF839, and/or ZSCAN31.
    Claim 37: The method of any one of claims 33 to 35, wherein the gene set comprises 20 genes, 30 genes, or 40 genes.