TREATMENT OF METASTASIS
Technical Field
This invention concerns methods and compositions for the treatment of tumor-induced metastasis, in particular, hematogeneous metastasis. The U. S. Government has rights in this invention pursuant to grants Nos. CA 13943 and CA 07340 provided by the U. S. Public Health Service.
Background of the Invention
Advances in surgical and radiation treatment of primary tumors have left metastasis as perhaps the most devastating aspect of cancer. In operable cases, primary tumor growth or local recurrence is rarely a cause of death. Instead, at present, roughly one-third of cancer victims with operable tumors ultimately succumb to metastatic disease.
The hematogeneous metastatic process begins with the detachment of tumor cells from the primary tumor followed by intravasation with direct shedding of tumor cells into circulation. Although most tumor cells in circulation are quickly destroyed by various mechanisms, a few viable cells may be arrested in the microvaεculature or otherwise may adher to endothelial surfaces.
While in the boood stream or shortly after adhesion to endotheliurm, intravascular cancer cells become surrounded by thrombotic material consisting of platelets, erythrocytes and fibrin. Thrombus formation appears to be a significant event in the establishment of tumor colonies in the capillary beds of various organs. Blood platelets also appear to play an important role in tumor metastasis; it has been demonstrated that many metastasizing tumor cell lines induce platelet aggregation both in vitro and in vivo. Furthermore, upon aggregation, platelets release a substance or substances which promote tumor growth.
Since tumor cell-platelet interactions play a role in tumor metastasis, several laboratories have examined anticoagulants and
anti-aggregating agents, such as heparin, warfarin (Hagmar and Norrby, Vol. 5 Int. J. Cancer, pp. 72-84, [1970]; Lione and Bosmann, Vol. 2 Cell Biol. Int. Res., pp. 81-86 [1972]; Hoover and Ketcham, Vol. 35 Cancer, pp. 5-14 [1975]); aspirin (Gasic et al., Lancet II, pp. 932-933 [1972]; Wood and Hilgard, Lancet II, pp. 1416-1416 [1972]; Hilgard et al., Vol. 86 Z. Krebsforsch., pp. 243-250 [1976]) and dipyridamole (Hilgard in Interaction of Platelets and Tumor Cells, pp. 143-158, Jameson [ed.] [1982]; Ambrus et al. in Platelets: A Multidisciplinary Approach, pp. 467-48 , de Gaetano [ed.] [1982]) to reduce the incidence of tumor metastasis in experimental animal models. However, the results of many of these studies were inconclusive. Recent reports by Honn et al., 212 Science, pp. 1270-1272 (1981) have shown that i.v. injection of prostacyclin (PGI2), a potent inhibitor of platelet aggregation, reduces pulmonary tumor colonization by tail vein injected B16 amelanotic melanoma cells in mice. There exists a need for new and effective agents for treatment and prevention of metastasis. In particular, agents that are capable of reducing the incidence of metastasis by inhibiting platelet aggregation without harmful side-effects would satisfy a long-felt medical need.
Summary of the Invention
It has been discovered that a method for reducing the incidence of metastasis in tumor victims resides in the administration of forskolin or its analogs which are potent inhibitors of platelet aggregation. Forskolin compounds are generally defined as labdane diterpenoids having the general formula:
where R1 is hydrogen or a hydroxy or alkoxy, sulfonate or carbonate group; where R2 is a hydroxy, carbonate, acetyl, or acetoxy or alkanoyl group; where R3 is a hydroxy, carbonate, acetyl or acetoxy group; where R4 is hydrogen or a hydroxy or alkoxy, sulfonate or carbonate group; where R5 is either double-bonded oxygen or separately bound hydrogen and hydroxy groups; and where R6 is a lower alkene or oxygen.
In particular, we have found that 7 beta-acetoxy-8, 13-epoxy-1 alpha, 6 beta, 9 alpha trihydroxy-labd-14-en-11-one (forskolin) is effective in preventing the metastasis of mouse melanoma tumor cells. This compound is defined by the following formula:
It appears that the forskolin blocks human platelet aggregation (induced by a wide variety of aggregation stimulators) by stimulating membrane adenylate cyclase thereby increasing several-fold the intracellular concentrations of cyclic AMP and inhibiting the tumor cell-platelet interactions which seem to play a role in tumor metastasis.
We have demonstrated that forskolin strongly inhibits the melanoma cell-induced human platelet aggregation in vitro. Additionally, we have shown that forskolin, administered intraperitoneally to live animals prior to tail vein injections of cultured cancer cells, reduced tumor colonization in the lungs by more than 70 percent. Moreover, the inhibitory effects of forskolin in vitro have been shown to be potentiated by the combination of this agent with other anti-aggregating compounds, such as prostaglandin E, and 2-fluoroadenosine (F-Ado).
Our experiments also indicate that forskolin compares favorably with PGI2 when in vivo activity in reducing metastasis is measured. Although PGI2, compared to forskolin on a molar basis, is several hundred-fold more potent in inhibiting the platelet aggregation in vitro, the potencies of PGI2 and forskolin as inhibitors of pulmonary tumor metastasis are similar. According to Honn, doses of PGI2 in the range of 50-200 micrograas/mouse were required to obtain decreases in pulmonary tumor foci of greater than 50 percent. Our studies show that a single dose of forskolin (82 microgram/mouse, i.p.) reduced pulmonary colonization by more than 70 percent. Forskolin may be unique in its action and perhaps interacts directly with the catalytic subunit of adenylate cyclase. Thus, forskolin's high activity coupled with its low toxicity (reported LD 50 values for mice are 105 mg/kg i.p. and 3,100 mg/kg per OS) suggest that it can be a highly effective agent in reducing metastasis.
The invention will next be described in connection with certain preferred embodiments; however, it should be clear that various changes and modifications can be made by those skilled in the art without departing from the spirit and scope of the invention. For example, although the experiments reported herein
employed the 7 beta-acetoxy-8, 13-epoxy-1 alpha, 6 beta, 9 alphatrihydroxy-labd-14-en-11-one compound forskolin, various analog compounds can be expected to exhibit similar properties. See generally, Bhat et al., "Structures and Stereochemistry of New Labdane Diterpenoids from Coleus Forskohlii Briq.", Tetrahedron Letters, pp. 1669-1672 (1977); Adnot et al., "Forskolin (a powerful inhibitor of human platelet aggregation)", Vol. 31, Biochemical Pharmacology, pp. 4071-4074 (1982); Bhat et al., "Antihypertensive and Positive Inotropic Diterpene Forskolin: Effects of Structural Modifications on its Activity", Vol. 26, J. Med. Chem., pp. 486-492 (1983) and DeSouza et al., "Forskolin: A Labdane Diterpenoid with Antihypertensive, Positive Inotropic, Platelet Aggregation Inhibitory, and Adenylate Cyclase Activating Properties", Vol. 3, Medicinal Research Reviews, pp. 201-219 (1983), all of which are incorporated herein by reference, for discussions of pharmalogically active forskolin analogs.
Specifically, forskolin analogs with similar properties include various modifications of the groups labeled R1 to R6 in formula I above. The 6-hydroxy group may be acetylated. The 7-acetyl group may be removed or replaced by r-alkaroyl or tosyl groups. The delta 14 15 bond may be substituted by oxygen.
1,9-dideoxyforskolin as well as the 6,7-carbonate and the 1,9:
6,7-dicarbonate may also be effective. The 6-acetyl-7-deacetyl derivative also appears to be active as do compounds where the chain length of the 6-alkanoyl group is increased or diethylarainocthyl groups are introduced at the 1 -position. Moreover, 7-Deacetyl-11-deoxo-11 beta-hydroxyforskolin and 1-methyl-6 acetyl-7 deacetyl derivatives also appear to be pharmacologically active. The forskolin compounds described above may be administered alone or in conjunction with other agents. The forskolin compounds may be combined with nucleoside transport inhibitors which retard the uptake of adenosine by red blood cells and the like; such inhibitors include p-nitrobenzylthioinosine and dilazep. Our compounds may also be combined with agents that block the action of cAMP phosphodiesterase in converting cAMP to
AMP, such as theophylline analogs, or compounds that both inhibit nucleoside transport and block cAMP conversion, such as dipyridamole and its analogs (i.e., RA-233), oxagrelate and papaverine. Additionally, the forskolin compounds may be combined with other compounds that act upon adenylate cyclase in different fashions to create a synergistic effect; such compounds include adenosine analogs and prostacyclins.
Brief Description of the Figures
Fig. 1 is a graph plotting in vitro human platelet aggregation induced by the melanoma cells. (A) control (B) after treatment of platelet-rich plasma with forskolin.
Figs. 2a-2d are photographs comparing representative lung specimens from forskolin-treated and untreated mice.
Description of the Preferred Embodiments
The following non-limiting working examples illustrate our invention.
Example I A mouse melanoma subline, B16-F10, (highly metastatic to the lungs) was obtained from EG & G Mason Research Institute, Worcester, MA, and adapted to growth in cell culture. The cultured cells were harvested by 1 min of trypsinization (0.25% trypsin-0.1% EDTA) or with the use of a rubber policeman, washed gently three times with Hank's balanced salts solution (HBBS, free of Ca and Mg++). The cell viability determined by Trypan Blue exclusion ranged from 70-95% in the separate experiments. Freshly drawn whole blood from healthy adult human donors was anticoagulated with heparin (5 units/ml). The donors had not ingested antiplatelet drugs for at least 10 days. Platelet-rich plasma (PRP) was separated by centrifugation of the whole blood and platelet aggregation was measured in PRP by recording the increase in light transmission after the addition of the tumor cells.
Washed B16-F10 cell suspensions (2 x 107/ml) were treated with potato apyrase (1 unit/ml) for about 5 min to degrade exogenous adenine nucleotides. Fifty microliters of the cell suspension was then added to the platelet-rich plasma after an incubation of 5 min with (A) 5 microliters DMSO (10% in saline) (Control) or (B) 5 microliters forskolin (200 micro Molars in DMSO 10% in saline). Final concentration of forskolin in PRP (500 microliters) was 2 raicromolars. Fig. 1 shows that B16-F10 cells (2 x 106/ml) induced human blood platelet aggregation after a lag of about 1 min. However, if the PRP was preincubated (5 min) with the low concentration of forskolin (2 micromolars), the tumor cell-induced platelet aggregation was strongly blocked.
Example II Intravenous tail vein injections of B16-F10 cells (2 or 3 x 105 cell/mouse) to C57BL/6 mice (5-8 weekB old, 6-9 mice/group), produced a large number of pulmonary tumor foci after 9 or 14 days. However, if the mice were treated with a single intraperitoneally dose of forskolin (82 micrograms/mouse, i.e. 4-5 mg/kg) given 30 or 60 min before the tumor cell injections, reductions in tumor colonization of greater than 70 percent were observed. Similar results were seen in three separate experiments. Washed B16-F10 tumor cells (2 or 3 x 105) in 100 microliters Hanks balanced salts solution were injected from the tail vein 60 min (Exp. 1) or 30 min (Exp. 2,3) after i.p. injection of 200 microliters DMSO (20 percent in saline) in control group; or forskolin (5 mM) prepared in DMSO (100 percent) and diluted to 1 mM with saline just before injection. The mice were sacrificed after 9 days (Exp. 1) or 14 days (Exp. 2,3) and the lungs removed for examination. The tumor foci were counted with the help of a dissecting microscope. No overt signs of toxicity were seen in these mice after the i.p. administration of forskolin. Fig. 2 presents typical specimens of lungs from untreated and forskolin-treated mice of experiments 2 and 3.
Examination under a dissecting microscope revealed that the tumor foci in the forskolin-treated mice were smaller and more superficial than in the untreated mice, which were larger and more deeply embedded. A summary of these experiments is provided in Table 1 below.
TABLE I
CONTROL MICE
No. of pulmonary Median tumor foci* number
Experiment 1 62,69,103,189, 189
(2 x 105 cells/mouse) 191,281,350
FORSKOLIN-TREATED MICE
No. of pulmonary Median P tumor foci number value
0, 17,31 ,32,47,89 3.1 0.014
CONTROL MICE
No. of pulmonary Median tumor foci number
Experiment 2 6,111,189,210,248, 210 (3 x 105 cells/mouse) 267,276
FORSKOLIN-TREATED MICE
No. of pulmonary Median P tumor foci number value
0,0,1,1,48,115 1 0.004
CONTROL MICE
No. of pulmonary Median tumor foci number
Experiment 3 >600 in each of >600
(3 x 105 cells/mouse) nine mice**
FORSKOLIN-TREATED MICE
No. of pulmonary Median P tumor foci number value
0,0,81,123,176, 149-5 <0.001 219,250,281
*Each value is the no. of pulmonary foci per mouse.
**Estimated value. The lungs were fuly occupied by tumor foci. (See Fig. 3, IIA). In experiment 3, the mice were younger (about 5 weeks old).
EXAMPLE III The in vitro experimental procedure of Example I above was repeated using a combinatiop of forskolin and oxagrelate. In this example the cell suspension was added to platelet-rich plasma incubated with a mixture of forskolin and oxagrelate. It was found that low concentrations of oxagrelate (20 micromolar) and forskolin (0.4 micromolar) which were only slightly inhibitory alone (20 percent) acted synergistically (95 percent inhibition) when mixed with the platelets.
EXAMPLE IV The in vivo experimental procedure of Example II above was also repeated using a combination of forskolin and oxagrelate. Intraperitoneal injections of the combination (oxagrelate: 40-45 mb/kg and forskolin: 1-1.5 mg/kg) 30 minutes before tail vein injections of the B16-F10 tumor cells reduced tumor colonization in the lungs of the mice 40 to 70 percent.