AU5590794A

AU5590794A - Fibronectin binding protein as well as its preparation

Info

Publication number: AU5590794A
Application number: AU55907/94A
Authority: AU
Inventors: Staffan Normark; Arne Olsen
Original assignee: Individual
Current assignee: Individual
Priority date: 1992-11-03
Filing date: 1993-11-03
Publication date: 1994-05-24
Anticipated expiration: 2013-11-03
Also published as: AU692140B2; CA2148479A1; FI952108A; WO1994010330A1; NO951679D0; NO951679L; FI952108A0

Description

FIBRONECTIN BINDING PROTEIN AS WELL AS ITS PREPARATION.

Description

Technical Field

The present invention relates to a fibronectin binding protein as well as a hybrid-DNA-molecules, e.g., plasmids and phages comprising a nucleotide sequence coding for said protein. Further the invention relates to microorganims comprising said molecules and their use producing said protein, as well as the synthetic preparation of said protein.

The object of the present invention is to obtain a minimal fibronectin binding protein.

A further object of the present invention is to obtain said protein by means of a genetic engineering technique by using, e.g., a plasmid comprising a nucleotide sequence coding for said protein.

A further object is to obtain a possibility of preparing said protein by chemical synthesis.

Further objects will be apparent from the following description.

Background of the invention

WO-Al-85/05553 discloses bacterial cell surface proteins having fibronectin, fibrinogen, collagen and/or laminin binding ability. Thereby it is shown that different bacteria have an ability to bind to fibronectin, fibrinogen, collagen and/or laminin. It is further shown that fibronectin binding protein derived from Staphylococcus aureus has a molecular weight of 165 kD and/or 87 kD, whereby it is probable that the smaller protein is a part of the larger one.

Fibronectins are a family of high molecular weight glycoproteins occurring in a soluble form in many body fluids and in an insoluble form as a compound of cell surfaces, basement membranes, and extracellular matrices. Fibronectins appear to fulfil a critical role in clearance by phagocytes of autologous tissue debris, immune complexes, and bacteria. Fibronectins also bind to epithelial cells. In doing so it may serve as a receptor for organisms like group A streptococci, but may also shield the epithelial receptors for other organisms. Thus the inability of Gramnegative organisms like Ps. aeuruginosa to colonize the oral cavity of healthy humans may be due to an interference in binding to epithelial receptors by fibronectin. The ability to resist binding to soluble fibronectin has been thought to be a virulence factor in invasive infection by group B streptococci. A number of Grampositive bacterial species including Staphylococcus aureus, other staphylococcus species, and group A, C and G streptococci exhibit specific interaction with fibronectin. In these species binding to fibronectin is thought to be a virulence factor enhancing colonization of wound surfaces and other fibronectin coated surfaces. E. coli can express a variety of adhesins with differing binding specificities. The majority of these adhesins recognize carbohydrate moities present on glycoconjugates. E. coli may also express binding to matrix proteins such as fibronectin, laminin, and collagen. Uropatogenic E. coli expressing the 075 × adhesin bind tubular basement membranes and to the Bowman capsule known to be rich in laminin. The purified 075 × adhesin was specifically found to bind laminin. E. coli isolated from patients with ulcerous colitis frequently bind matrix proteins. Likewise, E. coli isolates from bovine mastitis have been shown to bind to fibronectin at a high frequency. Below a native fibronectin binding protein from E. coli is disclosed, as well as the cloning of the fibronectin binding, fnbA gene from a bovine isolate of E. coli that express curli pili and fibronectin binding when present in E. coli HB101.

Chemically fibronectin is a large glycoprotein (M about 450 kD) with two similar subunits, which may vary in molecular size depending on a complex splicing pattern of a precursor mRNA. The major function of fibronectin which is found in body fluids blood clots and extracellular matrices seems to be related to the ability of the protein to mediate substrate adhesion of most eukaryotic cells.

Description of the present invention

It has now surprisingly been found possible to obtain a native fibronectin binding protein from E. coli, as well as a hybride- DNA-molecule comprising a nucleotide sequence coding for a protein or a polypeptide having fibronectin binding properties. As evident from below the following nucleotide sequence is present in the gene coding for said protein:

AGGTGTTGTT CCTCAGTACG GCGGCGGCGG TAACCACGGT GGTGGCGGTA ATAATAGCGG CCCAAATTCT GAGCTGAACA TTTACCAGTA CGGTGGCGGT AACTCTGCAC TTGCTCTGCA AACTGATGCC CGTAACTCTG ACTTGACTAT TACCCAGCAT GGCGGCGGTA ATGGTGCAGA TGTTGGTCAG GGCTCAGATG ACAGCTCAAT CGATCTGACC CAACGTGGCT TCGGTAACAG CGCTACTCTT GATCAGTGGA ACGGCAAAAA TTCTGAAATG ACGGTTAAAC AGTTCGGTGG TGGCAACGGT GCTGCAGTTG ACCAGACTGC ATCTAACTCT CGTCAACGTG ACTCAGGTTG GCTTTGGTA corresponding to the following amino acid as identified from the N-terminal end

GWPOYGGGG NHGGGGNNSG PNSELNTYOY GGGNSALALQ TDARNSDLTI TQHGGGNGAD VGQGSDDSSI DLTQRGFGNS ATLDQWNGKN SEMTVKQFGG GNGAAVDQTA SNSRQRDSGWLW* wheirein

A Alanine

R Arginine

N Asparagine

D Aspartic acid

C Cysteine

C Cystine

G Glycine

E Glutamic acid

Q Glutamine

H Histidine I Isoleucine

L Leucine

K Lysine

M Methionine

F Phenylalaniπe

P Proline

S Serine

T Threonine

W Tryptophan

Y Tyrosine

V Valine

* stop codon

The mature curlin protein has a molecular weight of 17 kD when gel-purified, and when determined via the nucleotide sequence it is predicted to contain 122 amino acids providing for a molecular weight of 14,345 dalton.

The invention further comprises a plasmid or phage comprising a nucleotide sequence coding for said fibronectin binding protein.

The invention further comprises a micro-organism comprising at least one hybrid-DNA-molecule according to the above. The micro- organism, E. coli HB101/pFnb20 encompassing the plasmid encoding for said nucleotide sequence was deposited May 05, 1988 at Deut- sche Sammlung von Mikroorganismen und Zellkulturen, Braun- schweig, FRG under the deposition number DSM 4585.

The invention further comprises a method for producing a fibronectin binding protein whereby at least one hybrid-DNA-molecule of above is introduced into a micro-organism, cultivating said micro-organism in a growth medium, and isolating the protein thus formed and expressed by means of an affinity chromatography on a fibronectin bound to an insolubilized carrier followed by ion exchange chromatography.

A further aspect of the invention comprises a chemical synthesis of the fibronectin binding protein, whereby an amino acid sequence is built up based on said nucleotide sequence encoding for said protein starting from the C-terminal amino acid which is stepwise reacted with the appropriate amino acid, whereby it is finally reacted with the amino acid at the N-terminal end, to form the fibronectin peptide region.

Appropriate carrier proteins can be coupled to the amino acid sequence as well, such as IgG binding regions of protein A.

The invention will be described in the following with reference to the example given below, however, without being restricted thereto. Example

Isolation and characterization of a recombinant clone expressing fibronectin binding.

In a collection of bovine faecal and mastitis isolates of Eschericia coli, 58% and 56%, respectively, bound to ¹²⁵I-1abelled fibronectin. In some of the mastitis isolates the ability to bind to fibronectin was not a stable property. Thus a chromosomal cosmid bank was generated from faecal E coli isolate AO12, since that strain stably expressed binding to fibronectin. Such binding was preferentially expressed when the cells were grown on CFA-agar at temperatures between 26°C and 32°C. Electron microscopy of 40 fibronectin binding E. coli isolates revealed that they all produced coiled surface structures when grown on CFA-agar at 26°C. High magnification of these structures showed them to be thin, wiry fibers with a diameter of about 2 nm. The lateral aggregation of individual fibers produced considerably thicker structures.

Bacteriophage transducing particles carrying portions of the strain AO12 genome cloned into cosmid vector pJB8 were used to transform E. coli HB101. Strain AO12 expressed fibronectin binding when grown on CFA plates at 30°C, but to a lesser extent at 37ºC. Transductants were thus screened for fibronectin binding after growth on CFA plates for 40 hrs at 30ºC. Out of 560 transductants one, AO450, showed fibronectin binding. The recombinant cosmid in this transductant, designated pAO450, was isolated and shown to contain an insert of about 24 kb. pAO450 was digested with restriction endonuclease Sail and subcloned into the vector pACYC184, giving pFnb01. A subclone of pFnb01, viz. pFnb10 containing a 3 kb large SphI-KpnI fragment expressed fibronectin binding when transformed into E. coli HB101. The subclone pFnb10 was digested with a series of restriction endonucleases to prepare a restriction map as shown in FIG. 1. To further localize the region on pFnb10 expressing fibronectin binding several subclones were constructed from pFnb10 as were various deletion derivatives. These constructs were tested for their ability to confer binding to E. coli HB101. The HpaI and SphI sites delineates the 1.2 kb region required for fibronectin binding as shown in FIG. 1.

The recombinant plasmids shown in FIG. 1 were transformed into the minicell producing strain AA10. Plasmid encoded polypeptides were analysed from S-methionine labelled minicells. Plasmid pFnb10 expressed two polypeptides with molecular masses of 43 kD and 17 kD respectively as shown in FIG 2. pFnb30 is a deletion derivative of pFnb10 that lacks a 0.9 kb ClaI fragment. This derivative no longer confer fibronectin binding to E. coli HB101. The 49 kD polypeptide was still expressed from this clone but the smaller 17 kD polypeptide was missing. The larger polypeptide must be encoded from a gene positioned between the ClaI₂ and KpnI sites on pFnb10, since the region between SphI₁ and ClaI₁ site is to small (0.4 kb) to encompass a gene coding for a 49 kD protein. It is also concluded that the 49 kD polypeptide is not required for fibronectin binding. Plasmids pFnb20 and pFnb58 both expressed fibronectin binding in E. coli The 17 kD polypeptide but not the 49 kD polypeptide was encoded by pFnb20 showing that the gene for the latter polypeptide must span the SphI₂ site. The HpaI-SphI₁ subclone pFnb56 no longer expressed the 17 kD polypeptide. Instead a slightly larger polypeptide species of 19 kD was expressed. An 1.5 kb large fragment carrying the aminoglycoside 3 phosphotransferase gene plasmid of pUC-4K was cloned into the single ClaI site of pFnb56 giving pFnb59. This derivative no longer mediated fibronectin binding. In minicells there was no expression of the 19 kD polypeptide. The conclusion is that the 19 kD polypeptide is due the deletion in the pFnb56 of the normal translational stop codon of the gene for the 17 kD polypeptide giving rise to a slightly longer translational product containing some carboxyterminal amino acids encoded by the vector.

The coiled surface structure could be shared from the surface of HB101/pFnb20 in an omnimixer and such partially purified preparations contained a dominating protein species with a molecular weight of 17 kD. The 17 kD polypeptide was elektroeluted onto an Immobulon filter and the aminoterminal sequence determined by sequential Edman degradation . In order to determine if the iso- lated protein was the same 17 kD gene product of the structural gene spanning the ClaI, and the HpaI sites in pFnb20 this region was sequenced. One open reading frame consisting of 133 codons was identified spanning the ClaI and Hpal sites. The protein sequence of the 5 amino terminal residues was identical to the DNA sequence specified by codons 2-6 in the open reading frame confirming that the open reading frame identified encodes the subunit protein of the coiled surface structure. The name "curlin" is proposed for this subunit protein, curli for the structure and csgA for the structural gene.

The curlin subunit appears to be strictly different from E. coli pilins and E. coli pilins have several features in commnon such such as cleavable signal peptide, two cysteine in the amino-terminal half, and several conserved amino acids in the amino- and carboxy terminal regions thought to be involved in the subunit-subunit interactions. Likewise no homologoes were found with the N-methyl Phe class of pilus expressed by Neisseria qonorrhoeae and many other Gram negative species. Flagellin is not a true secretory protein since it is transported directly from the cy- toplasm to the growing tip through the hollow flagellum. The small diameter of the curli suggest that they are assembled from the base. Hence expression of pili is not possible in E. coli HB101 when only the major pilus subunit protein is introduced into thsi strain. In contrast curlin is able to polymerize into curli in the absence of any other cloned gene products.

Furthermore the data implicates that the gene for the 17 kD polypeptide spans the ClaI₂ site on pFnb10. Since fibronectin binding was mapped to this gene it was denoted fnbA. E. coli pilin proteins are all known to be produced in a precursor form with a cleavable N-terminal signalpeptide. To see if the Fnb protein was synthetised from fnbA in a precursor form, minicells expressing Fnb from plasmids were treated with 9% ethanol to prevent processing. There was no appearance of a large molecular weight species suggesting that Fnb is not synthetized with a cleavable signalpeptide.

Nucleotide sequence of fnbA gene

Sequence analysis of a CsCl₂-purified double-stranded plasmid

DNA from pCSG4 was performed by denaturring approximately 4 ug of DNA with 2 M NaOH/2 mM EDTA and neutralizing it with 7.5 M ammonium acetate (pH 5). Appropriate oligonucleotides (1 pmole) were annealed to alkalidenatured DNA and sequenced using the Sequenase^R protocol as described by the manufacturer (United

States Biochemical, Cleveland, OH). Electrophoresis was performed in a 90 mM TBE buffer system for 2-5 hrs at 45 mA in 8 M urea/6% polyacrylamide gels. Gels were fixed, dried, and exposed to Hyperfilm (Amersham).

AGGTGTTGTT CCTCAGTACG GCGGCGGCGG TAACCACGGT GGTGGCGGTA ATAATAGCGG CCCAAATTCT GAGCTGAACA TTTACCAGTA CGGTGGCGGT AACTCTGCAC TTGCTCTGCA AACTGATGCC CGTAACTCTG ACTTGACTAT TACCCAGCAT GGCGGCGGTA ATGGTGCAGA TGTTGGTCAG GGCTCAGATG ACAGCTCAAT CGATCTGACC CAACGTGGCT TCGGTAACAG CGCTACTCTT GATCAGTGGA ACGGCAAAAA TTCTGAAATG ACGGTTAAAC AGTTCGGTGG TGGCAACGGT GCTGCAGTTG ACCAGACTGC ATCTAACTCT CGTCAACGTG ACTCAGGTTG GCTTTGGTA

This will correspond to the following amino acid sequence GWPOYGGGO NHGGGGNNSG PNSELNTYOY GGGNSALALQ TDARNSDLTI TQHGGGNGAD VGQGSDDSSI DLTQRGFGNS ATLDQWNGKN SEMTVKQFGG GNGAAVDQTA SNSRQRDSGWLW

Expression of a curli pili from the original strain AO12 and from HB101 clones expressing the Fnb protein.

E. coli strain AO12 grown at 26°C expressed unusually curli pili like structures when viewed under the electron microscope as shown in FIG. 4. No such structures can be seen on E. coli HB101 growing at either 26°C or 37°C. However, cells of HB101 harbouring either pFnb20 of pFnb56 produced large amounts of curli pili structures when grown on CFA medium at 26ºC as shown in FIG. 5. However, no surface structures was found on HB101/pFnb20 and HB101/pFnb56 after growth at 37°C as shown in FIG. 6, a temperature at which these strains do not express fibronectin binding. No surface structures was found on HB101/pFnb56 deleted for the fnbA gene when grown at either 26°C or 37°C.

Hence the expression of curli pili in HB101 was strictly correlated to the expression of the Fnb protein. Moreover, the expression of curli pili correlated strictly with the ability of HB101 to bind to fibronectin.

E. coli HB101 has been used as a host to clone and express a number of E. coli pili types. In no other case it has been possible to obtain surface located pili by only expressing the pilin gene. All other known gene cluster that have been examined today contain additional genes required for transport and assembly of the pilus fiber. When plasmid pFnb20 was present in E_. coli AA10 curli pili were not observed at 26°C as shown in FIG. 7 and the cells did not bind fibronectin. Most E. coli strains carry in their chromosome, genes for type 1 pili. Both E. coli Hb101 and AA10 are unable to form such pili. In the former strain some genes from the type 1 operon are still functioning whereas the entire type 1 gene cluster is deleted in AA10. Plas- mid pSJH9 carries all accessory genes required for type 1 pilus formation but is deleted for the fimA gene encoding the major pilin subunit. E. coli AA10 harbouring plasmid pSJH9 and pFnb20 did not bind fibronectin. Hence the ability of pFnb20 to express fibronectin binding and curli pili in HB101 does not seem to depend on the complementation from chromosomal type 1 pilus genes. To see if accessory genes located close to fnbA could confer fibronectin binding to E. coli AA10 this strain was transformed with the original cosmid clone pAO450. Strain AA10/pAO450 was not expressing fibronectin binding. Minicell experiments revealed that strain AA10 is able to synthetize the FnbA protein at 26°c as well as at 37°C. It is therefore concluded that the FnbA protein can not be expressed for surface localization, nor be assembled into curli pili in this strain.

Eschericia coli is a common cause of bovine mastitis. E. coli milk isolates from cases of acute mastitis do not differ from the normal faecal E. coli flora in the cow. When examining possible virulence associated properties of bovine E. coli the ability to bind to fibronectin stands out as a common property shared by 50-80% of the isolates studied. To more closely study fibronectin binding in E. coli the fnbA gene was cloned and characterized. The fnb gene codes for a 17,000 dalton protein that is able to polymerize into curli pili like structures when expressed in E. coli Hb101.

It is surprising that DNA fragment expressing the FnbA protein, only, could confer piliation in HB101. E. coli pili are encoded from an operon consisting of 11 pap genes. The accessory genes papC coding for an 88 kD outer membrane pore protein, and papD expressing a 28 kD periplasmic transport protein arc needed in addition to papA, the major subunit gene to form surface located pili. Even though other classes of pili adhesin genecluster appear to be less complex and contain fewer genes than the pap system all carry genes functionally equivalent to papC and papD. The fact that the fnb plasmid pFnb20 did not confer piliation or curli pili when harboured by E. coli AA10 suggests that E. coli HB101 express the accessory proteins required for the biogenesis of curli Fnb pili. It is known that E. coli HB101 carry some DNA that hybridize to cloned type 1 DNA. However, E. coli HB101 do not express type 1 pili if transformed with a type 1 clone deleted for either the fimD ( the papC equivalent) or the fimC (tht papD equivalent) gene. It is therefore unlikely that it is chromosomal type 1 DNA that encodes the accessory proteins required for the formation of curli Fnb pili. This is further supported by the observation that AA10 cells expressing both the Fnb protein and the accessory of the type 1 did not express fibronectin binding Fnb pili. Strain AA10 is a minicell producing strain. The Fnb protein was clearly synthesized in the minicells although no pili were formed. In the pap system a similar phenotype would have been obtained by mutating the papC gene. Mutations in the papD gene results in a rapid proteolysis of PapA pilin. If similar accessory genes were at hand in the fnb system it could be argued that E. coli AA10 lacks a papC equivalent so that the Fnb protein can not be surface localized.

Curli Fnb pili are formed in HB101 at 26°C but not at 37°C. In AA10 minicells the Fnb protein is synthesized to the same extent at both temperatures. It is thus suggested that the temperature regulation of piliation and fibronectin binding do not operate at the level of transcription but at the level of pilus biogenesis. Pap pili and many other virulence associated properties are also temperature regulated but the effect of incubation temperature is the reverse of what has been observed concerning the Fnb pili. In these former system transcription is increased with an increased temperature. This kind of temperature regulation is thought to reflect the adaptation of the micro-organism to the mammalian host. Wound pathogens such as Staphylococcus aureus and Staphylococcus genera frequently bind to fibronectin. The temperature of the skin is lower than 37°C. If fibronectin binding of E. coli also reflects an adaptation to bind to wounds on the exterior' of the host it would be an advantage for the micro-organism to have optimal binding at a temperature lower than 37°C. Herein there is no evidence given for the fact that fibronectin binding curli pili actually plays a role in the pathogenesis of bovine mastitis. The frequent presence of ulcers, due for example to machine milking on the udder might, however, enable colonization of fibronectin binding E. coli. Fibronectin is a large glycoprotein known to bind to a large set of proteins. It is therefore uncertain how specific the interaction is between fibronectin and Fnb pili. The fnbA cosmid pAO450 was the single one out of 560 cosmids tested that expressed fibronectin binding in HB101. It is thus believed that this gene is the sole determinant of fibronectin binding in E. coli A012.

Materials and methods.

Bacterial strains and growth conditions.

Except for the bovine isolate AO12 all bacterial strains are derivatives of E. coli K-12, HB101, (hsdr-, hsdm-, recA13, supE44, lacZ4, leuB6, proA2, thr-1, Sm^r) were used as host in the fibronectin binding assay. JM83 (ara, (lac-proAB), rpsL, 80, lacZ M15 ) were used as host in all transformation experi-ments. For protein expression analyses a recA derivative of P678-54 (Lund et al, J. Bact. 162, 1293-1301), AA10 (obtained from

P.Orndorf, Stanford Univeristy, Stanford, Calif) was used. M13 cloning and phage propagation were carried out in strain JM103 (Messing et al, N.A.R. 9:309-321). Strain A012 is a bovine faecal isolate obtained from a healthy cow.

Other E. coli K12 strains were tested and analysed for the production of curli and the ability to bind fibronectin. Strain C600 (thr-1 leuB6 lacY1 suoE44 rfbD1 thi-1 tonA21) was found to bind fibronectin when grown on CFA-agar at 26ºC, at which temperature it also produced curli. The proA2 deletion mutant AB1157 did not, as expected express neither property.The minicell producing E. coli K12 strain AA10 carries the crl region as reveal ed by DNA-DNA hybridization using the 1.5 kb large BglII-SphI fragment as a probe, but did not express curli and did not bind soluble fibronectin. Bacteria were normally grown in L-broth (Bertani 1951). For the fibronectin binding assay bacteria were grown on CFA-agar (Inf. and Imm, 25 , 738-748, Evans) and containing 0.005% magnesium sulphate and 0.0005% magnesium chloride in 2% Bacto agar (Dif- co). Competent cells for transformation were prepared with 50 mM CaCl₂ (Gene 6, 23-28, Dagert).

The antibiotics ampicillin (100 ug/ml), kanamycin (50 ug/ml) and chloramphenicol (20 ug/ml) were used for selection of plasmid-containing strains. Unless otherwise stated incubation of bacterial cultures was carried out at 37ºC.

The present fibronectin binding protein will sometimes be synthesized in the cell wall and is not expressed as a pili. This protein thus synthesized can be isolated as well by known biochemical methods, such as affinity chromatography.

Recombinant DNA technique.

Restriction endonucleases, T4 ligase and Sequence TM were used according to the conditions recommended by the manufactures (New England, Biolabs, PL, Pharmacia, Uppsala, Sweden; USB, Cleave- land, Ohio, USA ).

Isolation of plasmid DNA, agarose gel electrophoresis, transformation of E. coli and isolation of DNA fragments from polyacrylamide gels were performed essentially as described by Maniatis et al ( 1982). Relevant fragments were subcloned into M13mp18 and M13mp19 vector (Messing, J and Vieira, J, Gene, 19 , 269-272 (1982)), and sequenced using the dideoxy chain terminating method of Sanger et al, PNAS, 74, 5463-5467. For DNA sequencing the bacteriophage T7 DNA polymerase, and Sequenase™ were used.

The primer used was Universal M13 17mer and synthesized 20mer oligonucleotides supplied by Symbicom, Umea, Sweden. Isolation of chromosomal and plasmid DNA.

DNA was isolated. as described by Lund et al. Plasmid DNA from clones carrying recombinant DNA was isolated by the alkaline lysis procedure (Maniatis, CSH, N.Y., USA).

Cosmid cloning procedure.

Chromosomal DNA purified from E. coli AO12 were partially cleaved with endonuclease Sau3AI. The DNA was size fractionated on a 10-40% linear sucrose gradient. Fractions containing DNA fragments larger than 20 kb in size were pooled and ligated into the BamHI site of the cosmid vector pJB8 as described by Maniatis, CSH Lab, N.Y. USA. Recombinant molecules were packaged in vitro into -particles using a lambda DNA in vitro packaging kit (code N.334, Amersham). The phage was then used to infect E. coli HB101 by selecting for ampicillin resistant clones after growth on CFA agar plates at 30°C for 40-48 hrs.

Plasmid construction

The cosmid clone pAO450 carried a roughly 24 kb large chromosomal insert. Plasmid pFnb01 was constructed by subcloning a 4.9 kb large SalI fragment from this cosmid into pACYC184. An internal 3 kb large SphI₁-KpnI from pFnb01 was cloned into pUC18 (Messing) giving pFnb10. A number of subclones from pFnb10 were generated by cloning into the polylinker site in pUC18. Plasmid pFnb59 is a ClaI cut back derivative of pFnb10. Subclones were constructed as follows. pFnb10 consists of the 3.0 kb KpnI-PstI fragment of the original clone ligated into the polylinker cloning cassette of pUC18, while pFnb30 is a Clal deletion derivative of pFnb10. Plasmid pFnb20 was obtained bby cloning the 1.5 kb Sphl-BglII fragment from the original plasmid into pUC18.

Analysis of this construct which lacks the 5'' terminal end of the gene coding for the 49 kD peptide showed that this protein was not necessary for curli production or for fibronectin binding. Plasmids pFnb56 and pFnb46 are SphlHpal and ClaI-BglII subclones, respectively of pFnb10 in pUC18. Plasmid pFnb59 was obtained by first subcloning the Kpnl-BglII fragment of the origi nal plasmid in pUC18 and then inserting the aminoglycoside-3'- phosphotransferase gene (APH) from the mobilization plasmid pUC- 4K into the Clal₁ site. To perform the fibronectin binding assay bacteria waere gromn on CFA-agar plates for 42-48 hrs at 26ºC or 37°C.

AccI digested plasmid pUC-4K (Pharmacia, Uppsala, Sweden) carrying the kanamycin resistance gene from transposon Tn903 coding for aminoglycoside 3 phosphotransferase (APH) was ligated to ClaI digested pFnb56. Transformants in HB101 were screened for ampicillin and kanamycin resistance. One such clone carrying the Kana fragment at the ClaI site was denoted pFnb59.

Fibronectin binding assay.

The fibronectin binding assay was a modification of the procedure described by G. Froman et al, (JBC, 259, 14899-14905). Bacteria were inoculated on CFA plates for 42-48 hrs at 26ºC or

37°C. Cells were resuspended in cold phosphate-buffered saline (pH 7.5) to an optimal density of 10⁹ cfu/ml. 100 ul of cells were added to an assay tube containing 1 ml of PBS + 0.1% Tween

80 + 100 ul of ¹²⁵I-fibronectin (5×105 cpm) and the mixture was end over incubated in room temperature for 1 hr. Tubes were centrifuged in Eppendorf centrifuge for five min. Supernatants were carefully aspirated. The radioactivity in the pellet was measured in a liquid scintillation counter ( LKB-Wallac).

Analysis of protein expression in minicells.

Plasmid constructs were transformed into the minicell-producing strain AA10. Preparation and labelling of minicells with ³⁵S-methionine were as described by Thompson and Achtman (Mol. Gen.

Genet. 165, 295-304 (1978)).

The radioactive samples were separated on linear 15% (wt/vol) SDS-polyacrylamide gels (Laemmli, UK, Nature, 227, 880-885,

(1970)). The gels were fixed, stained, destained, and exposed to X-ray film (DuPont) for 1-5 days. Molecular weight standards were from Pharmacia Fine Chemicals, Uppsala, Sweden. Precursor form of proteins encoded by different constructions were monitored after radiolabelling of minicells in the presence of 9% ethanol (Palva, J. Bact., 146. 325-330) and analysed on SDS-polyacrylamide gels.

Electron microscopy.

Electron microscopy was performed using a JEOL 100B microscope with 100-mesh copper grids coated with thin films of 2% Formvar. Bacteria from CFA agar plates were resuspended in 10 mM Tris- HCl,-pH 7.5 + 10 mM MgCl₂, and placed on the grid. Grids were washed with buffer and negatively stained for 5 sec. with 3.55& ammonium molybdate, followed by washing with redistilled water. The present fibronectin binding protein can be used for immunization, whereby the protein, preferably in combination with a fusion protein to create a large antigen to respond to, or the pili shaken off from the E. coli expressing the curli pili when grown around about 30°C, preferably at 26°C, or the inactivated E. coli comprising the curli pili consisting of the fibronectin binding 17 kD protein, is injected in dosages causing immunological reaction in the host mammal. Thus the fibronectin binding protein can be used in vaccination of ruminants against mastitis caused by E. coli infections. The fibronectin binding protein can further be used for immunization against urinary tract infections, normally caused by E. coli, or intestinal infections normally caused by E. coli, such as ulcerous colitis. The fibronectin binding protein of this invention has shown to form antibodies against E.coli related infections. Further, the fibronectin binding protein can be used to block an infection in an open skin wound by wound treatment using the fibronectin binding protein in a suspension. Thus the fibronectin binding protein can be used for the treatment of wounds, e.g., for blocking protein receptors, or for immunization (vaccination). In the latter case the host body produces specific antibodies which can protect against invasion of bacterial strains comprising such a fibronectin binding protein. Hereby the antibodies block the adherence of the bacterial strains to damaged tissue.

Examples of colonizing of tissue damage are:

a) colonizing of wounds in skin and connective tissue , which wounds have been caused by a mechanical trauma, chemical damage, and/or thermical damage;

b) colonizing of wounds on mucous membranes such as in the mouth cavity, or in the mammary glands, urethra, or vagina;

c) colonizing on connective tissue proteins, which have been exposed by minimal tissue damage (micro lesion) in connection with epithelium and endothelium (mastitis, heart valve infection, hip exchange surgery). when using the present fnb protein or a synthesized amino acid polypeptide for the purpose of immunization (vaccination) in mammals, including humans, the protein, or polypeptide, or curli pili, or whole inactivated bacteria, is dispersed in sterile, isotonic saline solution, optionally while adding a pharmaceutically acceptable dispersing agent. Different types of adjuvants can further be used in order to sustain the release in the tissue, and thus expose the protein for a longer time to the immuno defence system of a body. The injectible solutions will usually be given subcutaneously or intramuscularly.

A suitable dosage to obtain immunization is 0.5 to 5 ug of fnb protein per kg bodyweight and injection of immunization. In order to obtain durable immunization, vaccinations should be carried out at more than one consecutive occasions with an interval of 1 to 3 weeks, preferably at three occasions.

When using the present fnb protein for topical local administration the protein is dispersed in an isotonic saline solution to a concentration of 25 to 250 u per ml. The wounds are then treated with such an amount only to obtain a complete wetting of the wound surface. For an average wound thus only a couple of millilitres of solution are used in this way. After treatment using the protein solution the wounds are suitably washed with isotonic saline or another suitable wound treatment solution.

Further the fibronectin binding protein, or the synthesized polypeptide of the present invention can be used to diagnoze bacterial infections caused by E. coli strains, whereby a fibronectin binding protein of the present invention is immobilized on a solid carrier, such as small latex or Sepharose beads, whereupon sera containing antibodies are allowed to pass and react with the fibronectin binding protein thus immobilized. The agglutination is then measured by known methods.

Further the fibronectin binding protein or the polypeptide can be used in ELISA test (Enzyme Linked Immuno Sorbent Assay; E Engvall, Med. Biol. 55, 193, (1977)). Hereby wells in a polystyrene microtitre plate are coated with the fnb protein and incubated over night at 4°C. The plates are then thoroughly washed using PBS containing 0.05% Tween 20, and dried. Serial dilution of the patient serum is made in PBS-Tween, are added to the wells, and incubated at 30°C for 1.5 hrs. After rinsing anti- human-IgG conjugated with an enzyme, or a horseradish peroxidase, or an alkaline phosphatase is added to the wells and incubated at 30ºC for 1.5 hrs, whereupon when the IgG has been bound thereto, and after rinsing, an enzyme substrate is added, a p-nitrophosphate in case of an alkaline phosphatase, or or- thophenylene diamine substrate (OPD) in case a peroxidase has been used, respectively. The plates comprising the wells are thus then rinsed using a citrate buffer containing 0.055% OPD, and 0,005% H₂O₂, and incubated at 30ºC for 10 min. Enzyme reaction is stopped by adding a 4N solution of H₂SO₄. to each well. The colour development is measured using a spectrophotometer.

Depending on the type of enzyme substrate used a fluoroscense measurement can be used as well.

Another method to diagnoze E. coli infections is by using the DNA gene probe method based on the fnb protein sequence or the synthetic polypeptide sequence. Thereby the natural or synthetic DNA sequences are attached to a solid carrier, such as a polystyrene plate as mentioned above, by e.g. adding a milk in the case of diagnozing a mastitis, to the surface. The DNA gene probe, optionally labelled enzymatically, or by a radioactive isotope is then added to the solid surface plate comprising the DNA sequence, whereby the DNA gene probe attaches to the sequence where appearing. The enzyme or the radioactive isotope can then readily be determined by known methods.

Above the term fibronectin binding protein includes any of the polypeptide sequences as well, which polypeptide sequences form the minimal fibronectin binding site of the complete protein.

Figure legends .

Figure 1

Physical map of the different pFnb plasmid constructs. Fnb+ or indicate fibronectin binding phenotype.

Constructs:

pFnb10 SphI₁-KpnI fragment in pUC18

" 30 ClaI cut back of pFnb10

" 20 BgIII-SphI fragment in pUC18

" 56 SphI-HpaI

" 59 APH ligated to the ClaI₂ site in pFnb56 " 46 Clal-BglII fragment in pUC18

Figure 2

Restriction map and gene organization of fnb gene. The hatched boxes indicate the 17 kD

Figure 3

Nucleotide and predicted amino acid sequence of fnbA gene. Three stars indicate the stop codons.

Electron microscopy pictures

Figure 4 AO12 26°C

Figure 5 HB101/pFnb56 26°C

Figure 6 HB101 /pFnb56 37°C

Figure 7 AA10/pFnb20 26°C

Electron microscopy was performed with a JOEL 100B microscope with 100-mesh copper grids coated with thin films of 2% Formvar. Bacteria from CFA-agar plates were resuspended in 10mM tris-HCl, pH 7,5-10mM MgCl₂ and placed on the grid. Grids were washed with buffer and negatively stained for 5 sec. with 3.55% ammonium molybate, followed by washing with redistilled water.

Claims

CLAIMS.

1. A fibronectin binding protein appearing in the form of a polymer protein on the surface of E. coli in the form of curli pili, hereby defined as curlin.

2. A fibronectin binding protein according to claim 1, wherein the molecular weight of the protein is about 17kD.

3. Hybrid-DNA-molecule comprising a nucleotide sequence from E. coli coding for a protein or polypeptide having fibronectin binding ability.

4. Plasmid or phage comprising a nucleotide sequence from E. coli coding for a protein or a polypeptide having fibronectin binding ability.

5. A plasmid pFnb20 as contained in the E. coli HB101 strain having the deposit number DSM 4585.

6. An E. coli strain expressing said fibronectin binding protein in the form of a curli pili, hereby defined as curlin.

7. A micro-organism transformed by recombinant DNA molecule of claims 3-5.

8. Hybrid-DNA-molecule according to claim 1, characterized in that it comprises one or more of the following nucleotide sequences AGGTGTTGTT CCTCAGTACG GCGGCGGCGG TAACCACGGT GGTGGCGGTA ATAATAGCGG CCCAAATTCT GAGCTGAACA TTTACCAGTA CGGTGGCGGT AACTCTGCAC TTGCTCTGCA AACTGATGCC CGTAACTCTG ACTTGACTAT TACCCAGCAT GGCGGCGGTA ATGGTGCAGA TGTTGGTCAG GGCTCAGATG ACAGCTCAAT CGATCTGACC CAACGTGGCT TCGGTAACAG CGCTACTCTT GATCAGTGGA ACGGCAAAAA TTCTGAAATG ACGGTTAAAC AGTTCGGTGG TGGCAACGGT GCTGCAGTTG ACCAGACTGC ATCTAACTCT CGTCAACGTG ACTCAGGTTG GCTTTGGTA

9. Plasmid or phage comprising one or more nucleotide sequences according to claim 8.

10. Micro-organism containing at least a plasmid or a phage according to claim 9.

11. A method for producing a fibronectin binding protein or polypeptide, wherein a) at least one hybrid-DNA-molecule according to claim 3 is introduced into a micro-organism, b) said micro- organism is cultivated in a CFA growth medium at a temperature ooff 25-30°C for 35-50 hrs. and ) the protein thus expressed and formed as a pili is isolated

12. A chemical synthesizing method for producing a fibronectin binding protein or polypeptide according to claims 1-3, whereby an amino acid residue is built up based on said nucleotide sequence encoding for said protein or polypeptide, starting from the C-terminal amino acid, alanine, which is stepwise reacted with the appropriate amino acid, whereby it is finally reacted with the amino acid at the N-terminal end, threonine, to form said fibronectin binding protein or polypeptide.

13. A fibronectin binding protein or polypeptide comprising at least the amino acid sequence GWPOYGGGG NHGGGGNNSG PNSELNTYOY GGGNSALALQ TDARNSDLTI

TQHGGGNGAD VGQGSDDSSI DLTQRGFGNS ATLDQWNGKN SEMTVKQFGG GNGAAVDQTA SNSRQRDSGWLW

14. Pharmaceutical composition for the treatment of infections caused by E. coli, characterized in that it comprises a fibronectin binding protein according to claims 1-13 together with a pharmaceutically acceptable carrier.

15. Method for the treatment of infections caused by E. coli in mammals, whereby a pharmaceutically active amount of a fibronectin binding protein according to claims 1-13 is administered, optionally in combination with a pharmaceutically acceptable carrier.