Journal of Bacteriology, September 2003, p . 5585-5590, Vol . 185, No . 18

Autotransporters as Scaffolds for Novel Bacterial Adhesins: Surface Properties of Escherichia coli Cells Displaying Jun/Fos Dimerization Domains

Esteban Veiga, Víctor de Lorenzo,^* and Luis Angel Fernández

Department of Microbial Biotechnology, Centro Nacional de Biotecnología CSIC, Campus de Cantoblanco, 28049 Madrid, Spain

Received 2 May 2003/ Accepted 19 June 2003

The AT secretion systems involve the export of two-module polypeptides . These include a C-terminal domain (called transporter or ß module) which ends up being inserted as an oligomer in the OM, and the passenger domain, which is the protein moiety eventually presented on and anchored to the cell surface (17, 37, 49) . Such a design seems to be naturally well suited for the emergence of novel adhesins with new specificities . This is because the protein export and anchoring mechanism appears to be tolerant to a large variety of protein structures (7) . Taking advantage of this property several heterologous passenger polypeptides have been exposed on the cell surface fused to the ß-domain of different members of the AT family, i.e., the mouse metallothionein (47), the B subunit of the cholera toxin (33), the ß-lactamase (28), the bovine adrenodoxin (19), the carboxylesterase EstA from Burkholderia gladioli (43), recombinant scFv antibodies (48), or the fimbrial protein FimH (23), among others (39) .

In this work, we have attempted to reprogram the adhesion properties of E . coli by displaying in its surface an entirely alien protein fold, with potential adhesin-like activity, that attaches distinctly to itself or to a second molecule presented by the target surface . To this end, we created a fusion protein containing the ß-AT domain of the IgA protease of Neisseria gonorrhoeae, an archetypal AT protein (37) and the partner leucine zippers of eukaryotic transcription factors Fos and Jun (2) . Fos and Jun have an intrinsic ability to heterodimerize through the strong interactions between their coiled coils of their protein folds (Jun can also produce homodimers, see below; (1, 2) . When such hybrid proteins were expressed in E . coli, cells acquired novel adherence traits resulting in the self-association and clumping of otherwise planktonic bacteria in liquid media, or in formation of stable consortia between cells of strains expressing the dimerization domains, either being Jun/Jun or Jun/Fos . These cell to cell associations are caused by tight protein-protein interactions that connect matching dimerization domains . Our data shed some light on the evolutionary value of AT systems for the appearance of novel adhesion determinants .

Immunofluorescence microscopy. For detecting the E tag on the surface of E . coli cells, bacteria were washed with phosphate-buffered saline (PBS) (3) and fixed in the same buffer containing 3% (wt/vol) paraformaldehyde . 80 µl of such cell suspensions were laid for 1 h on glass coverslips precoated with poly-L-lysine (1 mg ml^-1) . The glass slides were then blocked for 40 min in B buffer (PBS with 3% [wt/vol] bovine serum albumin) . Samples were incubated for 1 h in the same buffer with an anti-E tag monoclonal antibody (MAb) (10 µg ml^-1; Amersham Pharmacia Biotech) . Each specimen was then washed five times with PBS and further incubated for 1 h with an anti-mouse IgG serum conjugated with Cy3 (Amersham Pharmacia Biotech) diluted at 1:100 in B buffer . Cells were then examined with epifluorescence microscopy as described elsewhere (48) .

Western blotting and protease digestion. For monitoring the presence of the hybrids in cell extracts, proteins samples were denatured and run in sodium dodecyl sulfate-10% polyacrylamide gel electrophoresis as described before (48) . Briefly, after electrophoresis the proteins were blotted onto polyvinylidene difluoride membranes (Immobilon-P; Millipore) and incubated with anti-E tag MAb conjugated with peroxidase (Amersham Pharmacia) . The membranes were developed with a chemiluminescence reaction and exposed to an X-ray film . Protease accessibility analyses were carried out as explained in (49) . In brief, induced E . coli cells were washed and resuspended in PBS, trypsin was added externally (1 µg ml^-1) . Samples were incubated for 25 min at 37°C and stopped by adding trypsin inhibitor (5 µg ml^-1; Sigma) . Total protein extracts from these cells were analyzed by Western blotting .

ELISA. The level of surface display of the E-tagged leucine zippers was quantified as follows . For intact cells, E . coli cultures were harvested, washed in PBS and resuspended in the same buffer at a final OD₆₀₀ of 2.0 . Alternatively, bacteria were resuspended in PBS with 20 mM EDTA and lysed by sonication (48) . Either intact or lysed cells were attached to the enzyme-linked immunosorbent assay (ELISA) plate (Maxisorb; Nunc) for 1 h at room temperature . Samples were then blocked with 3% (wt/vol) skim milk in PBS for 1 h, rinsed in PBS and added with 1 µg ml^-1 of the anti-E tag MAb for 1 h . Plates were washed three times prior to incubation with anti-mouse IgG peroxidase conjugate (0.3 U ml^-1; Roche) . The ELISA were developed using o-phenylenediamine (Sigma) . A similar protocol was used for assaying the accessibility of the peptidoglycan in E . coli expressing hybrid proteins . In this case, a rabbit serum anti-E . coli peptidoglycan (38) was used at 1:1,000, followed by treatment with a 1:500 dilution of protein A-peroxidase conjugate (Roche) .

Cell aggregation assays. Liquid cultures of E . coli strains bearing plasmids pFosß, pJunß, or pHEß were separately grown to an OD₆₀₀ of 0.5 and then induced with 0.5 mM IPTG for 3 h at 37°C under vigorous shaking (180 rpm) . After that, 5-ml aliquots of each culture were mixed as indicated . The mixtures were then transferred to 10-ml tubes and cultivated without shaking . Triplicate 100-µl samples were withdrawn at 20-min intervals from the top of each tube for measurement of OD₆₀₀ across time . Additionally induced samples were also taken for examination under the microscope . To this end, 15-µl aliquots of the cultures were deposited on the surface of a microscope slide covered with a thin layer of 1% (wt/vol) agarose in Tris 50 mM (pH 7.5) in order to immobilize the bacteria, and incubated at 37°C for 1 h in a water-saturated atmosphere . Coverslips were then placed on the samples, and subsequently the samples were visualized by phase-contrast microscopy .

 
Once the constructs were made, we examined their production, cellular location and their performance in vivo . Fig . 2A shows the Western blots corresponding to whole cell extracts of IPTG-induced E . coli cells transformed with plasmids pFosß and pJunß . Bands of the expected size for the hybrid ß-fusions were clearly produced when the blots were probed with an anti-E tag MAb . These bands were well defined, with no indication of instability or proteolytic degradation, thereby indicating that the Fosß and the Junß hybrids are produced as full-length polypeptides . Since overproduction of OM proteins may cause damage to the cell envelope resulting in an artifactual display of otherwise not exposed proteins, we ensured also membrane integrity in cells expressing Fosß and the Junß . To this end, we assayed the accessibility of the peptidoglycan in induced E . coli cells transformed with pFosß and pJunß . As shown in the ELISA of Fig . 2B, the same level of peptidoglycan detection was observed in E . coli control cells (nontransformed) than in those expressing the Fosß and Junß hybrids . This result indicated that production of the ß-hybrid did not alter the integrity of the OM .

 
Presentation of Fos and Jun domains on the surface of E . coli cells. The targeting of the Fos and Jun sequences to the envelope of E . coli cells as fusions to the AT domain of the IgA protease was investigated . Once more, the E tag engineered in the corresponding fusion proteins was instrumental to tackle this concern . First, we attempted to visualize directly the location of the E tag on intact cells through epifluorescence microscopy (Fig . 3A) . Cells from IPTG-induced cultures of E . coli cells harboring pFosß, pJunß, and a plasmidless control were fixed and treated first with the anti-E tag MAb described above and then with a Cy3-conjugate of anti-mouse IgG serum (Materials and Methods) . Under the epifluorescence microscope, we observed a strong red signal over the cells transformed with the Fosß- or Junß-encoding plasmids, but not in the control . This was indicative of the display of the E tag on the cell surface . Since the E tag was engineered in pFosß and pJunß behind the leucine zippers (Fig . 1), it is necessarily secreted following the passenger Fos and Jun sequences, which must be exposed on the cell surface as well .

 
Closer inspection of the images of Fig . 3A revealed that not every E . coli cell in the cultures bearing pFosß or pJunß produced epifluorescence . This could be explained on the basis of the stochastic induction that appears to operate on the lac promoter (4, 45) . But also, it may well happen that not all the expressed Fosß and Junß proteins target the E tag (and the accompanying Fos and Jun modules) to the surface . To examine this possibility, we carried out a second assay to ascertain whether all or only part of the E tag of the fusion proteins was accessible from the outside . Intact cells expressing Fosß and Junß were treated with externally added trypsin . This protease is not able to penetrate into intact cells (Fig . 2B) and thus is only able to degrade exposed domains (26, 42, 49) . After trypsin digestion cells were collected and their whole protein extracts analyzed by Western blotting with the anti-E tag MAb . The data shown in Fig . 3B indicates that 100% of the E tag signal disappears in samples treated with trypsin, thus demonstrating the full localization of the epitope on the cell outermost, accessible surface . In addition we performed ELISA in which we compared the levels of E tag which could be recognized by the anti-E Tag MAb in intact cells versus lysed cells . As shown in Fig . 3C, a minimum of 75% of the entire complement of E tags produced in vivo were detected in whole cells expressing Fosß or Junß . Since integrity of the outer membrane of cells expressing Fosß or Junß is preserved (see above; Fig . 2B) we conclude that the ELISA signals from whole-cell assays were due to the display of the E tags encoded by the hybrid proteins . The difference observed in the level of surface exposed passenger domains (100% measured by trypsin digestion versus 75% by ELISA) was maybe due to the interference in ELISA of the surface polysaccharides presented on intact E . coli cells .

Taken together, the results above show that all the produced Fosß and Junß proteins complete the AT secretion pathway and localize their N-terminal domains (encompassing the E-tag and the Fos/Jun moieties) on the cell surface . This is especially intriguing in the case of the Junß protein, since (unlike Fos) the corresponding leucine zipper has a tendency to associate with itself, a property which could interfere with the secretory mechanism . However, this was clearly not the case, most likely because the mechanism of AT secretion also involves the formation of an oligomer (49) and tolerates the efficient translocation of folded protein domains towards the cell surface (E . Veiga, V . de Lorenzo, and L . A . Fernández, submitted for publication) . The next step was thus to examine the biological activity of the secreted dimerization domains .

Cell adhesion properties mediated by surface display of leucine zippers. If leucine zippers of the Jun and Fos sequences retained their ability to bring about strong protein-protein interactions when exposed on the surface of E . coli cells, then their expression should cause cell aggregation . On this basis, we set out several assays to monitor cell-to-cell adhesion mediated by the occurrence of dimerization of the corresponding leucine zippers . The background of these assays is that Fos domains can form heterodimers only with the partner Jun domains . On the contrary, Jun modules can form both homo- and heterodimers (1, 2) .

As shown in Fig . 4A, 90 min after induction (see Materials and Methods), E . coli cells expressing Fosß remained in suspension, while the same cells bearing the pJunß plasmid sedimented spontaneously (thereby quickly lowering the OD₆₀₀ of the culture from 2.2 to 0.3; Fig . 4B) . This was accompanied by formation of a thick bacterial precipitate . This bacterial precipitate could be resuspended by vortexing and the cultures recovered the same OD₆₀₀ than that of the culture expressing Fosß (data not shown) . Interestingly, a mixed population of cells expressing Fosß and Junß cosedimented very rapidly as well (Fig . 4A and B) suggesting that the cells expressing the Junß fusion pulled down entirely those presenting Fosß .

 
To determine whether the aggregation observed in the mixed population of Fosß and Junß expressing bacteria was due to specific interactions between the Fos and Jun leucine zippers we performed similar experiments using a control ß fusion devoid of leucine zipper (HEß) . This control fusion consisted in a poly-His segment fused to the ß domain of the IgA protease . Cells expressing HEß remained in a planktonic state identical to those expressing Fosß (Fig . 4B) . The OD₆₀₀ of a mixed culture of bacteria expressing Junß and HEß decreased only by half of the initial OD . This indicated that only part of the mix culture (probably this corresponding to the Junß expressing bacteria) precipitated . On the contrary (Fig . 4A) a mixed population of cells expressing Fosß and Junß cosedimented to the same extent as the cells expressing Junß alone . These data confirm that precipitation of the mixed culture of bacteria expressing Fosß and Junß was due to the heterodimeric interactions of Fos and Jun exposed leucine zipper domains .

Samples from the different cultures were also inspected by phase contrast microscopy as shown in Fig . 4C in order to visualize the bacterial associations that promoted the precipitation of the cultures . The resulting images were fully consistent with what was observed at a macroscopic scale, namely, that cells expressing Fosß grew basically as a populations of individual cells, while those bearing pJunß and the mixed population of bacteria expressing Fosß and Junß formed large aggregates . All these data showed unequivocally that the new cell surface properties were due to the adhesin-like activity created by the Fos/Jun leucine zippers .

Conclusion. This report shows that protein dimerization domains (i.e., coiled coils of Jun/Fos leucine zippers) which are typical of some eukaryotic transcription factors become effective mediators of strong and distinct cell-cell attachment when fused to a carrier module of AT . Because of their unusual self-secretion mechanism, the ß-domain of ATs such as the IgA protease of N . gonorrhoeae can mediate, with few restrictions, the presentation of a large variety of protein structures . The size of the pore formed by the oligomeric AT complex (49) allows the efficient secretion of folded Ig domains (submitted for publication) . Interestingly, Ig domains are frequently found naturally in bacterial adhesins (6, 15, 32, 40) .

Although the passenger domains of some AT proteins (typically the IgA protease) are released into the external medium (16), the AT ß domains anchor in many cases protein modules which endow cells with novel adhesion properties . AT systems are highly similar in their C-terminal portion, which encompasses the ß barrel plus the linker region necessary for secretion (25, 34) . Yet, ATs are very divergent in their N-terminal part (i.e., the passenger domain) . Thus, ATs are suited as scaffolds for the generation of novel adhesins . These could be selected in vivo through a simple attachment-mediated clonal selection similar to that observed in Igs (35) or the selection of clones of interest by phage display (13) . Unlike fimbriae, the attachment properties of which are strongly limited by structural constrains (7, 39), ATs tolerate a wide range of protein modules that become displayed with the same structure that they had prior to become fused to the ß domain (19, 23, 28, 33, 47, 48) . Adventitious fusion of a protein fold typical of distant DNA binding proteins result in novel cell surface adhesion properties . In light of our results, it is tempting to speculate with the possibility that this recruitment of protein-protein interaction domains may occur also in nature for the generation of novel adhesins . Such aleatory fusions to AT domains could easily lead to functional switching of the recruited protein folds .

This work was supported by EU contracts QLK3-CT-2002-01933, QLK3-CT-2002-01923, and INCO-CT-2002-1001; by grants BIO2001-2274 and BMC2002-03024 of the Spanish Ministerio de Ciencia y Tecnología (MCyT); by grant COLIRED-O157 (G03/025) of the Fondo de Investigaciones Sanitarias (FIS); and by the Strategic Research Groups Program of the Autonomous Community of Madrid .

1. Abate, C., D . Luk, E . Gagne, R . G . Roeder, and T . Curran. 1990 . Fos and jun cooperate in transcriptional regulation via heterologous activation domains . Mol . Cell . Biol . 10:5532-5535.
2. Abate, C., D . Luk, R . Gentz, F . J . Rauscher III, and T . Curran. 1990 . Expression and purification of the leucine zipper and DNA-binding domains of Fos and Jun: both Fos and Jun contact DNA directly . Proc . Natl . Acad . Sci . USA 87:1032-1036.
3. Ausubel, F . M., R . Brent, R . E . Kingston, D . D . Moore, J . G . Seidman, J . A . Smith, and K . Struhl (ed.). 1994 . Current protocols in molecular biology . John Wiley & Sons, New York, N.Y.
4. Becskei, A., and L . Serrano. 2000 . Engineering stability in gene networks by autoregulation . Nature 405:590-593.
5. Benz, I., and M . A . Schmidt. 1992 . AIDA-I, the adhesin involved in diffuse adherence of diarrhoeagenic Escherichia coli strain 2787 (O126:H27), is synthesized via a precursor molecule . Mol, Micriobiol . 6:1539-1546.
6. Choudhury, D., A . Thompson, V . Stojanoff, S . Langermann, J . Pinkner, S . J . Hultgren, and S . D . Knight. 1999 . X-ray structure of the FimC-FimH chaperone-adhesin complex from uropathogenic Escherichia coli . Science 285:1061-1066.
7. Cornelis, P. 2000 . Expressing genes in different Escherichia coli compartments . Curr . Opin . Biotechnol . 11:450-454.
8. Crameri, R., and M . Suter. 1993 . Display of biologically active proteins on the surface of filamentous phages: a cDNA cloning system for selection of functional gene products linked to the genetic information responsible for their production . Gene 137:69-75.
9. Danese, P . N., L . A . Pratt, S . L . Dove, and R . Kolter. 2000 . The outer membrane protein, antigen 43, mediates cell-to-cell interactions within Escherichia coli biofilms . Mol . Microbiol . 37:424-432.
10. Emsley, P., I . G . Charles, N . F . Fairweather, and N . W . Isaacs. 1996 . Structure of Bordetella pertussis virulence factor P . 69 pertactin . Nature 381:90-92.
11. Fink, D . L., B . A . Green, and J . W . St . Geme III. 2002 . The Haemophilus influenzae Hap autotransporter binds to fibronectin, laminin, and collagen IV . Infect . Immun . 70:4902-4907.
12. Finn, T . M., and D . F . Amsbaugh. 1998 . Vag8, a Bordetella pertussis bvg-regulated protein . Infect . Immun . 66:3985-3989.
13. Griffiths, A . D., and A . R . Ducan. 1998 . Strategies for selection of antibodies by phage display . Curr . Opin . Bio/Technol . 9:102-108.
14. Grodberg, J., and J . J . Dunn. 1988 . ompT encodes the Escherichia coli outer membrane protease that cleaves T7 RNA polymerase during purification . J . Bacteriol . 170:1245-1253.
15. Hamburger, Z . A., M . S . Brown, R . R . Isberg, and P . J . Bjorkman. 1999 . Crystal structure of invasin: a bacterial integrin-binding protein . Science 286:291-295.
16. Henderson, I . R., and J . P . Nataro. 2001 . Virulence functions of autotransporter proteins . Infect . Immun . 69:1231-1243.
17. Henderson, I . R., F . Navarro-Garcia, and J . P . Nataro. 1998 . The great escape: structure and function of the autotransporter proteins . Trends Microbiol . 6:370-378.
18. Hendrixson, D . R., and J . W . St . Geme III. 1998 . The Haemophilus influenzae Hap serine protease promotes adherence and microcolony formation, potentiated by a soluble host protein . Mol . Cell 2:841-850.
19. Jose, J., R . Bernhardt, and F . Hannemann. 2002 . Cellular surface display of dimeric Adx and whole cell P450-mediated steroid synthesis on E . coli. J . Biotechnol . 95:257-268.
20. Keen, N . T., and S . Tamaki. 1986 . Structure of two pectate lyase genes from Erwinia chrysanthemi EC16 and their high-level expression in Escherichia coli. J . Bacteriol . 168:595-606.
21. Kingsley, R . A., R . L . Santos, A . M . Keestra, L . G . Adams, and A . J . Baumler. 2002 . Salmonella enterica serotype Typhimurium ShdA is an outer membrane fibronectin-binding protein that is expressed in the intestine . Mol . Microbiol . 43:895-905.
22. Kingsley, R . A., K . van Amsterdam, N . Kramer, and A . J . Baumler. 2000 . The shdA gene is restricted to serotypes of Salmonella enterica subspecies I and contributes to efficient and prolonged fecal shedding . Infect . Immun . 68:2720-2727.
23. Kjaergaard, K., H . Hasman, M . A . Schembri, and P . Klemm. 2002 . Antigen 43-mediated autotransporter display, a versatile bacterial cell surface presentation system . J . Bacteriol . 184:4197-4204.
24. Kjaergaard, K., M . A . Schembri, H . Hasman, and P . Klemm. 2000 . Antigen 43 from Escherichia coli induces inter- and intraspecies cell aggregation and changes in colony morphology of Pseudomonas fluorescens. J . Bacteriol . 182:4789-4796.
25. Klauser, T., J . Krämer, K . Otzelberger, J . Pohlner, and T . F . Meyer. 1993 . Characterization of the Neisseria Igaß-core . The essential unit for outer membrane targeting and extracellular protein secretion . J . Mol . Biol . 234:579-593.
26. Klauser, T., J . Pohlner, and T . F . Meyer. 1990 . Extracellular transport of cholera toxin B subunit using Neisseria IgA protease ß-domain: conformation-dependent outer membrane translocation . EMBO J . 9:1991-1999.
27. Laarmann, S., D . Cutter, T . Juehne, S . J . Barenkamp, and J . W . St Geme. 2002 . The Haemophilus influenzae Hia autotransporter harbours two adhesive pockets that reside in the passenger domain and recognize the same host cell receptor . Mol . Microbiol . 46:731-743.
28. Lattemann, C . T., J . Maurer, E . Gerland, and T . F . Meyer. 2000 . Autodisplay: functional display of active ß-lactamase on the surface of Escherichia coli by the AIDA-I autotransporter . J . Bacteriol . 182:3726-3733.
29. Lee, V . T., and O . Schneewind. 2001 . Protein secretion and the pathogenesis of bacterial infections . Genes Dev . 15:1725-1752.
30. Li, H., and D . H . Walker. 1998 . rOmpA is a critical protein for the adhesion of Rickettsia rickettsii to host cells . Microb . Pathog . 24:289-298.
31. Lindenthal, C., and E . A . Elsinghorst. 2001 . Enterotoxigenic Escherichia coli TibA glycoprotein adheres to human intestine epithelial cells . Infect . Immun . 69:52-57.
32. Luo, Y., E . A . Frey, R . A . Pfuetzner, A . L . Creagh, D . G . Knoechel, C . A . Haynes, B . B . Finlay, and N . C . Strynadka. 2000 . Crystal structure of enteropathogenic Escherichia coli intimin-receptor complex . Nature 405:1073-1077.
33. Maurer, J., J . Jose, and T . F . Meyer. 1997 . Autodisplay: one-component system for efficient surface display and release of soluble recombinant proteins from Escherichia coli. J . Bacteriol . 179:794-804.
34. Maurer, J., J . Jose, and T . F . Meyer. 1999 . Characterization of the essential transport function of the AIDA-I autotransporter and evidence supporting structural predictions . J . Bacteriol . 181:7014-7020.
35. Meffre, E., R . Casellas, and M . C . Nussenzweig. 2000 . Antibody regulation of B cell development . Nat . Immunol . 1:379-385.
36. Miller, J . H. 1992 . A short course in bacterial genetics: a laboratory manual and handbook for Escherichia coli and related bacteria . Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
37. Pohlner, J., R . Halter, K . Beyreuther, and T . F . Meyer. 1987 . Gene structure and extracellular secretion of Neisseria gonorrhoea IgA protease . Nature 325:458-462.
38. Quintela, J . C., M . A . de Pedro, P . Zöllner, G . Allmaier, and F . Garcia-del Portillo. 1997 . Peptidoglycan structure of Salmonella typhimurium growing within cultured mammalian cells . Mol . Microbiol . 23:693-704.
39. Samuelson, P., E . Gunneriusson, P . A . Nygren, and S . Stahl. 2002 . Display of proteins on bacteria . J . Biotechnol . 96:129-154.
40. Sauer, F . G., K . Futterer, J . S . Pinkner, K . W . Dodson, S . J . Hultgren, and G . Waksman. 1999 . Structural basis of chaperone function and pilus biogenesis . Science 285:1058-1061.
41. Scarselli, M., R . Rappuoli, and V . Scarlato. 2001 . A common conserved amino acid motif module shared by bacterial and intercellular adhesins: bacterial adherence mimicking cell cell recognition? Microbiology 147:250-252.
42. Schenkman, S., A . Tsugita, M . Schwartz, and J . P . Rosenbusch. 1984 . Topology of phage lambda receptor protein . Mapping targets of proteolytic cleavage in relation to binding sites for phage or monoclonal antibodies . J . Biol . Chem . 259:7570-7576.
43. Schultheiss, E., C . Paar, H . Schwab, and J . Jose. 2002 . Functional esterase surface display by the autotransporter pathway in Escherichia coli. J . Mol . Catalysis B Enzymatic 18:89-97.
44. Soto, G . E., and S . J . Hultgren. 1999 . Bacterial adhesins: common themes and variations in architecture and assembly . J . Bacteriol . 181:1059-1071.
45. Tolker-Nielsen, T., K . Holmstrom, L . Boe, and S . Molin. 1998 . Non-genetic population heterogeneity studied by in situ polymerase chain reaction . Mol . Microbiol . 27:1099-1105.
46. Torres, A . G., N . T . Perna, V . Burland, A . Ruknudin, F . R . Blattner, and J . B . Kaper. 2002 . Characterization of Cah, a calcium-binding and heat-extractable autotransporter protein of enterohaemorrhagic Escherichia coli . Mol . Microbiol . 45:951-966.
47. Valls, M., S . Atrian, V . de Lorenzo, and L . A . Fernández. 2000 . Engineering a mouse metallothionein on the cell surface of Ralstonia eutropha CH34 for immobilization of heavy metals in soil . Nat . Biotechnol . 18:661-665.
48. Veiga, E., V . de Lorenzo, and L . A . Fernández. 1999 . Probing secretion and translocation of a beta-autotransporter using a reporter single-chain Fv as a cognate passenger domain . Mol . Microbiol . 33:1232-1243.
49. Veiga, E., E . Sugawara, H . Nikaido, V . de Lorenzo, and L . A . Fernández. 2002 . Export of autotransported proteins proceeds through an oligomeric ring shaped by C-terminal domains . EMBO J . 21:2122-2131.

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