Calcium-Regulated Type III Secretion of Yop Proteins by an Escherichia coli hha Mutant Carrying a Yersinia pestis pCD1 Virulence Plasmid
http://www.100md.com
感染与免疫杂志 2006年第2期
Department of Microbiology and Immunology, University of Miami Miller School of Medicine, P.O. Box 016960 (R-138), Miami, Florida 33101
ABSTRACT
A series of four large deletions that removed a total of ca. 36 kb of DNA from the ca. 70-kb Yersinia pestis pCD1 virulence plasmid were constructed using lambda Red-mediated recombination. Escherichia coli hha deletion mutants carrying the virulence plasmid with the deletions expressed a functional calcium-regulated type III secretion system. The E. coli hha/pCD1 system should facilitate molecular studies of the type III secretion process.
TEXT
Yersinia pestis is the etiologic agent of plague, an often fatal disease of both animals and humans (6). The pathogenicty of Y. pestis results largely from its ability to evade the defenses of its mammalian hosts. This ability is dependent upon the presence of a 70-kb plasmid designated pCD1 in Y. pestis KIM (18, 28). Plasmid pCD1 and related plasmids (2) in the enteropathogenic yersiniae (Yersinia enterocolitica and Yersinia pseudotuberculosis) encode a set of secreted antihost proteins termed Yersinia outer proteins (Yops) and a unique delivery system, classified as a type III secretion system (T3SS) (13). The type III secretion apparatus, or "injectisome" as it is sometimes called, spans the bacterial cell envelope and allows extracellular yersiniae to inject Yops directly into host phagocytic cells (15, 29, 32). Injected Yops prevent bacterial engulfment and block production of proinflammatory cytokines (26, 27, 34).
The type III secretion process is activated by contact between a bacterium and the surface of a eukaryotic cell (33). Following cell contact, effector Yops are injected into the eukaryotic cell and are not found in substantial amounts in the extracellular environment, indicating that the type III secretion process is activated only at the point of contact between the two cells. In vitro, Yop secretion is blocked in the presence of millimolar amounts of extracellular calcium and is activated during growth at 37°C in the absence of calcium (23, 35). Secretion of Yops in vitro is accompanied by cessation of bacterial growth, an event termed growth restriction (3).
To determine the minimum number of pCD1 genes required to express a functional calcium-regulated T3SS, we created four large deletions in plasmid pCD1 that together removed more than one-half of the genetic material carried on the plasmid (Fig. 1A). The four deletions eliminated pCD1 sequences at positions 41,640 to 52,022 (1), 3,740 to 15,602 (2), 61,430 to 70,331 (3), and 55,568 to 60,495 (4). In general, the deletions were designed to remove the genes encoding the six effector Yops (yopE, yopH, yopJ, yopM, yopT, and ypkA), two chaperones (sycE and sycT), ylpA, yopK, yadA, all uncharacterized open reading frames, and essentially all transposable elements. The four deletions did not disrupt the low-calcium response (Lcr) region (positions 15,801 to 41,540), the origin of replication, the partitioning region, or the sycH gene.
Lambda Red-mediated recombination was used to delete each specified region of pCD1 and to simultaneously insert an FLP recognition target-flanked kanamycin resistance (kan) cassette or a dhfr cassette essentially as described by Datsenko and Wanner (8). PCR products used to construct the gene replacements were generated using plasmid pKD4 (kan) or dhfr (EZ::TN; Epicentre, Madison, WI) as a template for PCR. The oligonucleotide primers used in this study are listed in Table 1. Deletions were confirmed by PCR analysis. Each individual deletion was initially constructed in plasmid pCD1 of Y. pestis KIM8 (pMT1+, pCD1+, and pPCP1–), which generated kanamycin-resistant (Kmr) strains KIM8 1, KIM8 2, and KIM8 3, as well as trimethoprim-resistant (Tmr) strain KIM8 4. Plasmid pCP20, which encodes the FLP recombinase (8), was electroporated into KIM8 1 to facilitate removal of the FLP recognition target-flanked kan cassette, generating strain KIM8 1s. Plasmids pKD46 and pCP20, which carry temperature-sensitive origins of replication, were cured from the kanamycin-sensitive strain by overnight growth at 39°C (8). The presence of the deletions and the absence of pKD46 and pCP20 were confirmed by PCR analysis and by agarose gel electrophoresis of plasmids isolated by the method of Kado and Liu (21).
To construct a pCD1 variant that had all four deletions, we used lambda Red-mediated recombination (8) to sequentially delete three additional regions (2, 3, and 4) from pCD1 of KIM8 1s. PCR products used to construct the sequential gene replacements were generated using pKD4 (kan), pKD3 (cat), or dhfr as the template for PCR. The 2::kan, 3::cat, and 4::dhfr insertional deletions were confirmed by PCR analysis and by agarose gel electrophoresis of plasmids isolated by the method of Kado and Liu (21). The resultant multiple-deletion pCD1 plasmids pCD1-12 (kan), pCD1-123 (kan2 cat3), and pCD1-1234 (kan2 cat3 dhfr4), as well as the original single-deletion plasmids pCD1-1 (kan), pCD1-2 (kan), pCD1-3 (kan), and pCD1-4 (dhfr), were isolated and electroporated into Y. pestis KIM10 (pMT1+, pCD1–, pPCP1–), generating Y. pestis KIM8 1 (Kmr), KIM8 2 (Kmr), KIM8 3 (Kmr), KIM8 4 (Tmr), KIM8 12 (Kmr), KIM8 123 (Kmr Cmr), and KIM8 1234 (Kmr Cmr Tmr) in a clean genetic background (Fig. 1B). The resultant strains were used in all subsequent studies.
Secretion of Yops by Y. pestis KIM8, KIM8 1, KIM8 12, KIM8 123, and KIM8 1234 was measured following growth of the bacteria in TMH medium for 5 h at 37°C in the presence and absence of calcium. Concentrated culture supernatant proteins were separated by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) and stained with Coomassie blue R-250 (Fig. 2A). All five strains secreted Yops in the absence of calcium but not in the presence of calcium. Y. pestis KIM8 1234, which had all four deletions, expressed and secreted YopB, YopD, YopN, and LcrV but none of the effector Yops. In addition to the deletions in plasmid pCD1 mentioned above, a deletion (5) eliminating the pCD1 sequence at positions 55,568 to 70,331 from pCD1 of Y. pestis KIM8 was constructed using primers 4-P1 and 3-P2. Y. pestis KIM8 carrying plasmid pCD1-5, in which the sycH gene was deleted, expressed and secreted only low levels of Yops (data not shown), confirming that SycH is required for efficient T3SS gene expression (4). These studies confirmed that with the exception of sycH, all of the genes required to express a functional calcium-regulated T3SS are encoded in the Lcr region of plasmid pCD1. Similar results were obtained by Trulzsch et al. (36), who inserted the entire Lcr region of the Y. enterocolitica pYV virulence plasmid into a cosmid vector (mini-pYV). In this case, the mini-pYV plasmid directed secretion and translocation of effector Yops encoded on expression plasmids provided in trans. Although the mini-pYV plasmid encoded a functional T3SS, it did not carry the sycH gene; therefore, LcrQ (YscM)-dependent regulation of T3SS gene transcription was not reconstituted with this construct. SycH, the chaperone for YopH and LcrQ, is required for efficient export of the negative regulatory component LcrQ in the absence of calcium (4, 37). Deletion of sycH prevents secretion of LcrQ and results in repression of T3SS gene transcription (30, 31).
The injection of Yops into a eukaryotic cell is essentially a three-step process that involves (i) attachment of the bacterium to a eukaryotic cell via specific bacterial adhesins, (ii) secretion of effector Yops across the bacterial membranes, and (iii) translocation of Yops across the eukaryotic membrane. The ability of Y. pestis KIM8 123 and KIM8 1234 to inject Yops into a eukaryotic cell was evaluated using the ELK tag reporter system described previously (9). Y. pestis KIM8 123, KIM8 1234, KIM8-3002.P40 (yopE yopJ), KIM8-3002.41 (yopE yopJ yopB), and KIM8-3002.41 carrying pYopB2 were transformed with plasmid pYopE129-ELK (9). The reporter plasmid encodes a truncated YopE protein with a C-terminal ELK tag that is phosphorylated upon translocation into a eukaryotic cell. Cultured HeLa cells were infected at a multiplicity of infection of 30 for 3 h at 37°C, and the infected monolayers were analyzed by SDS-PAGE and immunoblot analysis (Fig. 2B). The total YopE129-ELK expressed during the infection was detected with anti-ELK antipeptide antibodies, whereas YopE129-ELK translocated into the HeLa cells was phosphorylated and detected with phospho-specific antipeptide antibodies (Cell Signaling Technology).
Immunoblot analysis with anti-ELK antipeptide antibodies demonstrated that all the strains expressed comparable amounts of the YopE129-ELK protein (Fig. 2B, top panel). Y. pestis KIM8-3002.P40 (parent), KIM8 123, and KIM8 1234 translocated approximately equal amounts of YopE129-ELK into the HeLa cells (Fig. 2B, bottom panel). In contrast, the translocation-defective yopB strain was unable to inject the YopE129-ELK protein into the HeLa cells. Providing complementing plasmid pYopB2 in trans completely restored the ability of the yopB deletion mutant to translocate the YopE129-ELK protein. These studies confirmed that the pCD1-1234 plasmid encodes a functional T3SS capable of injecting Yops into eukaryotic cells.
The calcium-regulated secretion of Yops by Yersinia spp. is dependent upon at least 30 different pCD1 genes; however, the role of chromosomal genes in this process is not fully understood. Recently, several chromosomal genes required for efficient expression of the Yersinia spp. T3SS have been identified (7, 10, 19, 20); however, the gene products identified thus far do not appear to be intimately involved in the type III secretion process per se. To determine if the Y. pestis chromosome carries genes that are essential for expression of a functional calcium-regulated T3SS, we moved the pCD1-1234 construct into E. coli DH5 and BL21. Only low levels of Yop expression and no Yop secretion were observed in E. coli DH5 or BL21 carrying plasmid pCD1-1234, indicating that pCD1 T3SS genes are not efficiently expressed in E. coli (17) (Fig. 3 and data not shown).
Transcription of T3SS genes in Yersinia spp. is negatively regulated by a small histone-like protein designated YmoA (7). E. coli strains express a protein homologous to YmoA, designated Hha (24), which functions with H-NS to thermoregulate the transcription of several virulence-related genes (22, 25). To examine the role of Hha in regulating the expression of pCD1-1234 T3SS genes in E. coli DH5 and BL21, we used lambda Red-mediated recombination to delete the hha locus and to insert a kan cassette at the site of the deletion. The deletion of hha in both DH5 and BL21 was confirmed by PCR analysis. Plasmid pKD46 was cured from the hha deletion mutants, and the pCD1-1234 plasmid was electroporated into the pKD46-cured hha deletion strains.
Expression and secretion of YopN and YopD by Y. pestis KIM8 and KIM8 1234 and by E. coli BL21, BL21 hha, DH5, and DH5 hha with and without plasmid pCD1-1234 were determined following growth of the bacteria at 37°C in TMH medium in the presence and absence of calcium (Fig. 3). The E. coli BL21 and DH5 hha deletion strains carrying plasmid pCD1-1234 secreted YopN and YopD in the absence of calcium but not in the presence of calcium. The amounts of YopN and YopD secreted by these strains were comparable to or slightly less than the amounts secreted by Y. pestis KIM8 or KIM8 1234. These studies confirmed that plasmid pCD1-1234 contains the complete complement of genes unique to the yersiniae that are required to express a functional T3SS. Interestingly, the E. coli hha strains carrying pCD1-1234 secreted high levels of Yops but did not exhibit growth restriction (data not shown), suggesting that the physiological determinants that link growth and secretion are unique to the yersiniae.
E. coli DH5 and BL21 are avirulent bacteria that do not express the surface adhesins required for attachment to the surface of eukaryotic cells (5). Therefore, the E. coli strains that express a functional T3SS should not be able to attach to HeLa cells and inject Yops. Indeed, E. coli DH5 hha and BL21 hha carrying pCD1-1234 and pYopE129-ELK expressed the YopE129-ELK protein but did not translocate the protein into cultured HeLa cells (data not shown).
Previous studies have suggested that Hha and YmoA, which exhibit 82% amino acid sequence identity, are interchangeable (1, 11). Our results indicate that Hha in E. coli, but not YmoA in Y. pestis, prevents essentially all pCD1 T3SS gene expression at 37°C. The reason for the difference is unclear; however, we hypothesize that it could be related to the amount of YmoA or Hha present in the relevant bacterial cells at 37°C. We have demonstrated previously that YmoA is rapidly degraded by the Lon protease at 37°C in Y. pestis, a process that is essential to trigger T3SS gene transcription in Y. pestis (20). It is possible that Hha is more resistant to Lon-mediated proteolysis and is not rapidly degraded at 37°C in E. coli. To begin to examine this possibility, we constructed plasmid pFLAG-Hha, which encodes the Hha protein with an N-terminal 14-amino-acid tag (N-MDYKDDDDKVKLLE-Hha). Plasmid pFLAG-Hha was electroporated into E. coli DH5 and BL21, whereas plasmid pFLAG-YmoA was electroporated into Y. pestis KIM5-3001 (20). The stability of FLAG-Hha and FLAG-YmoA at 37°C was determined by determining the amounts of these proteins after new synthesis was blocked by addition of chloramphenicol (40 μg/ml) to the cultures, as described previously (20). Samples corresponding to equal numbers of bacteria were removed at specific times and analyzed by SDS-PAGE and immunoblot analysis with the FLAG M2 antibody (Sigma, St. Louis, MO) (Fig. 4). As previously demonstrated, FLAG-YmoA was rapidly degraded at 37°C in Y. pestis. FLAG-Hha was stable at 37°C in lon-deficient E. coli BL21 (14), but it was degraded in E. coli DH5. These results suggest that Hha, like YmoA, is degraded in a Lon-dependent manner; however, the half-life of FLAG-YmoA in Y. pestis (19.3 min) was significantly less than the half-life of FLAG-Hha in DH5 (40.3 min). These results suggest that the degradation of Hha in E. coli and the degradation of YmoA in Y. pestis are to some extent different, and the difference may account for the ability of Hha to suppress pCD1 gene transcription at 37°C in E. coli. Alternate explanations are also possible, and further studies are required to determine the mechanism by which Hha represses T3SS gene transcription at 37°C in E. coli.
The E. coli hha/pCD1-1234 strain-plasmid combination provides a system to study the Yersinia spp. type III secretion process in a heterologous host. Previously, only the Erwinia chrysanthemi T3SS has been shown to function in a heterologous bacterial host (16). The combination of the pCD1-1234 virulence plasmid lacking the genes encoding all six translocated effector Yops with an avirulent E. coli host provides a reliable and safe system to analyze the molecular events involved in the Y. pestis type III secretion process. The procedures for preparation and manipulation of membrane vesicles suitable for in vitro secretion studies have been developed and fine-tuned in E. coli (12). Thus, the E. coli hha/pCD1-1234 system should facilitate the development of in vitro secretion assays that are required to dissect the molecular events involved in the type III secretion process.
ACKNOWLEDGMENTS
This work was supported by Public Health Service grants AI 50552 and AI 39575 from the National Institutes of Health to G.V.P.
REFERENCES
1. Balsalobre, C., A. Juarez, C. Madrid, M. Mourino, A. Prenafeta, and F. J. Munoa. 1996. Complementation of the hha mutation in Escherichia coli by the ymoA gene from Yersinia enterocolitica: dependence on the gene dosage. Microbiology 142:1841-1846.
2. Ben-Gurion, R., and A. Shafferman. 1981. Essential virulence determinants of different Yersinia species are carried on a common plasmid. Plasmid 5:183-187.
3. Brubaker, R. R. 1983. The Vwa+ virulence factor of yersiniae: the molecular basis of the attendant nutritional requirement for Ca++. Rev. Infect. Dis. 5:748-758.
4. Cambronne, E. D., L. W. Cheng, and O. Schneewind. 2000. LcrQ/YscM1, regulators of the Yersinia yop virulon, are injected into host cells by a chaperone-dependent mechanism. Mol. Microbiol. 37:263-273.
5. Chart, H., H. R. Smith, R. M. La Ragione, and M. J. Woodward. 2000. An investigation into the pathogenic properties of Escherichia coli strains BLR, BL21, DH5 and EQ1. J. Appl. Microbiol. 89:1048-1058.
6. Cornelis, G. R. 2000. Molecular and cell biology aspects of plague. Proc. Natl. Acad. Sci. USA 97:8778-8783.
7. Cornelis, G. R., C. Sluiters, I. Delor, D. Geib, K. Kaniga, C. Lambert de Rouvroit, M. P. Sory, J. C. Vanooteghem, and T. Michiels. 1991. ymoA, a Yersinia enterocolitica chromosomal gene modulating the expression of virulence functions. Mol. Microbiol. 5:1023-1034.
8. Datsenko, K. A., and B. L. Wanner. 2000. One-step inactivation of chromosomal genes in Escherichia coli K-12 using PCR products. Proc. Natl. Acad. Sci. USA 97:6640-6645.
9. Day, J. B., F. Ferracci, and G. V. Plano. 2003. Translocation of YopE and YopN into eukaryotic cells by Yersinia pestis yopN, tyeA, sycN, yscB and lcrG deletion mutants measured using a phosphorylatable peptide tag and phosphospecific antibodies. Mol. Microbiol. 47:807-823.
10. DeBord, K. L., N. S. Galanopoulos, and O. Schneewind. 2003. The ttsA gene is required for low-calcium-induced type III secretion of Yop proteins and virulence of Yersinia enterocolitica W22703. J. Bacteriol. 185:3499-3507.
11. de la Cruz, F., M. Carmona, and A. Juarez. 1992. The Hha protein from Escherichia coli is highly homologous to the YmoA protein from Yersinia enterocolitica. Mol. Microbiol. 6:3451-3452.
12. Douville, K., A. Price, J. Eichler, A. Economou, and W. Wickner. 1995. SecYEG and SecA are the stoichiometric components of preprotein translocase. J. Biol. Chem. 270:20106-20111.
13. Ghosh, P. 2004. Process of protein transport by the type III secretion system. Microbiol. Mol. Biol. Rev. 68:771-795.
14. Gottesman, S. 1989. Genetics of proteolysis in Escherichia coli. Annu. Rev. Genet. 23:163-198.
15. Grosdent, N., I. Maridonneau-Parini, M. P. Sory, and G. R. Cornelis. 2002. Role of Yops and adhesins in resistance of Yersinia enterocolitica to phagocytosis. Infect. Immun. 70:4165-4176.
16. Ham, J. H., D. W. Bauer, D. E. Fouts, and A. Collmer. 1998. A cloned Erwinia chrysanthemi Hrp (type III protein secretion) system functions in Escherichia coli to deliver Pseudomonas syringae Avr signals to plant cells and to secrete Avr proteins in culture. Proc. Natl. Acad. Sci. USA 95:10206-10211.
17. Heesemann, J., U. Gross, N. Schmidt, and R. Laufs. 1986. Immunochemical analysis of plasmid-encoded proteins released by enteropathogenic Yersinia sp. grown in calcium-deficient media. Infect. Immun. 54:561-567.
18. Hu, P., J. Elliott, P. McCready, E. Skowronski, J. Garnes, A. Kobayashi, R. R. Brubaker, and E. Garcia. 1998. Structural organization of virulence-associated plasmids of Yersinia pestis. J. Bacteriol. 180:5192-5202.
19. Jackson, M. W., and G. V. Plano. 1999. DsbA is required for stable expression of outer membrane protein YscC and for efficient Yop secretion in Yersinia pestis. J. Bacteriol. 181:5126-5130.
20. Jackson, M. W., E. Silva-Herzog, and G. V. Plano. 2004. The ATP-dependent ClpXP and Lon proteases regulate expression of the Yersinia pestis type III secretion system via regulated proteolysis of YmoA, a small histone-like protein. Mol. Microbiol. 54:1364-1378.
21. Kado, C. I., and S. T. Liu. 1981. Rapid procedure for detection and isolation of large and small plasmids. J. Bacteriol. 145:1365-1373.
22. Madrid, C., J. M. Nieto, and A. Juarez. 2002. Role of the Hha/YmoA family of proteins in the thermoregulation of the expression of virulence factors. Int. J. Med. Microbiol. 291:425-432.
23. Michiels, T., P. Wattiau, R. Brasseur, J. M. Ruysschaert, and G. Cornelis. 1990. Secretion of Yop proteins by yersiniae. Infect. Immun. 58:2840-2849.
24. Nieto, J. M., M. Carmona, S. Bolland, Y. Jubete, F. de la Cruz, and A. Juarez. 1991. The hha gene modulates haemolysin expression in Escherichia coli. Mol. Microbiol. 5:1285-1293.
25. Nieto, J. M., C. Madrid, E. Miquelay, J. L. Parra, S. Rodriguez, and A. Juarez. 2002. Evidence for direct protein-protein interaction between members of the enterobacterial Hha/YmoA and H-NS families of proteins. J. Bacteriol. 184:629-635.
26. Orth, K., L. E. Palmer, Z. Q. Bao, S. Stewart, A. E. Rudolph, J. B. Bliska, and J. E. Dixon. 1999. Inhibition of the mitogen-activated protein kinase kinase superfamily by a Yersinia effector. Science 285:1920-1923.
27. Palmer, L. E., S. Hobbie, J. E. Galan, and J. B. Bliska. 1998. YopJ of Yersinia pseudotuberculosis is required for the inhibition of macrophage TNF-alpha production and downregulation of the MAP kinases p38 and JNK. Mol. Microbiol. 27:953-965.
28. Perry, R. D., S. C. Straley, J. D. Fetherston, D. J. Rose, J. Gregor, and F. R. Blattner. 1998. DNA sequencing and analysis of the low-Ca2+-response plasmid pCD1 of Yersinia pestis KIM5. Infect. Immun. 66:4611-4623.
29. Persson, C., R. Nordfelth, A. Holmstrom, S. Hakansson, R. Rosqvist, and H. Wolf-Watz. 1995. Cell-surface-bound Yersinia translocate the protein tyrosine phosphatase YopH by a polarized mechanism into the target cell. Mol. Microbiol. 18:135-150.
30. Pettersson, J., R. Nordfelth, E. Dubinina, T. Bergman, M. Gustafsson, K. E. Magnusson, and H. Wolf-Watz. 1996. Modulation of virulence factor expression by pathogen target cell contact. Science 273:1231-1233.
31. Rimpilainen, M., A. Forsberg, and H. Wolf-Watz. 1992. A novel protein, LcrQ, involved in the low-calcium response of Yersinia pseudotuberculosis shows extensive homology to YopH. J. Bacteriol. 174:3355-3363.
32. Rosqvist, R., A. Forsberg, and H. Wolf-Watz. 1991. Intracellular targeting of the Yersinia YopE cytotoxin in mammalian cells induces actin microfilament disruption. Infect. Immun. 59:4562-4569.
33. Rosqvist, R., K. E. Magnusson, and H. Wolf-Watz. 1994. Target cell contact triggers expression and polarized transfer of Yersinia YopE cytotoxin into mammalian cells. EMBO J. 13:964-972.
34. Schesser, K., A. K. Spiik, J. M. Dukuzumuremyi, M. F. Neurath, S. Pettersson, and H. Wolf-Watz. 1998. The yopJ locus is required for Yersinia-mediated inhibition of NF-kappaB activation and cytokine expression: YopJ contains a eukaryotic SH2-like domain that is essential for its repressive activity. Mol. Microbiol. 28:1067-1079.
35. Straley, S. C., G. V. Plano, E. Skrzypek, P. L. Haddix, and K. A. Fields. 1993. Regulation by Ca2+ in the Yersinia low-Ca2+ response. Mol. Microbiol. 8:1005-1010.
36. Trulzsch, K., A. Roggenkamp, M. Aepfelbacher, G. Wilharm, K. Ruckdeschel, and J. Heesemann. 2003. Analysis of chaperone-dependent Yop secretion/translocation and effector function using a mini-virulence plasmid of Yersinia enterocolitica. Int. J. Med. Microbiol. 293:167-177.
37. Wattiau, P., B. Bernier, P. Deslee, T. Michiels, and G. R. Cornelis. 1994. Individual chaperones required for Yop secretion by Yersinia. Proc. Natl. Acad. Sci. USA 91:10493-10497.(Sara Schesser Bartra, Mic)
ABSTRACT
A series of four large deletions that removed a total of ca. 36 kb of DNA from the ca. 70-kb Yersinia pestis pCD1 virulence plasmid were constructed using lambda Red-mediated recombination. Escherichia coli hha deletion mutants carrying the virulence plasmid with the deletions expressed a functional calcium-regulated type III secretion system. The E. coli hha/pCD1 system should facilitate molecular studies of the type III secretion process.
TEXT
Yersinia pestis is the etiologic agent of plague, an often fatal disease of both animals and humans (6). The pathogenicty of Y. pestis results largely from its ability to evade the defenses of its mammalian hosts. This ability is dependent upon the presence of a 70-kb plasmid designated pCD1 in Y. pestis KIM (18, 28). Plasmid pCD1 and related plasmids (2) in the enteropathogenic yersiniae (Yersinia enterocolitica and Yersinia pseudotuberculosis) encode a set of secreted antihost proteins termed Yersinia outer proteins (Yops) and a unique delivery system, classified as a type III secretion system (T3SS) (13). The type III secretion apparatus, or "injectisome" as it is sometimes called, spans the bacterial cell envelope and allows extracellular yersiniae to inject Yops directly into host phagocytic cells (15, 29, 32). Injected Yops prevent bacterial engulfment and block production of proinflammatory cytokines (26, 27, 34).
The type III secretion process is activated by contact between a bacterium and the surface of a eukaryotic cell (33). Following cell contact, effector Yops are injected into the eukaryotic cell and are not found in substantial amounts in the extracellular environment, indicating that the type III secretion process is activated only at the point of contact between the two cells. In vitro, Yop secretion is blocked in the presence of millimolar amounts of extracellular calcium and is activated during growth at 37°C in the absence of calcium (23, 35). Secretion of Yops in vitro is accompanied by cessation of bacterial growth, an event termed growth restriction (3).
To determine the minimum number of pCD1 genes required to express a functional calcium-regulated T3SS, we created four large deletions in plasmid pCD1 that together removed more than one-half of the genetic material carried on the plasmid (Fig. 1A). The four deletions eliminated pCD1 sequences at positions 41,640 to 52,022 (1), 3,740 to 15,602 (2), 61,430 to 70,331 (3), and 55,568 to 60,495 (4). In general, the deletions were designed to remove the genes encoding the six effector Yops (yopE, yopH, yopJ, yopM, yopT, and ypkA), two chaperones (sycE and sycT), ylpA, yopK, yadA, all uncharacterized open reading frames, and essentially all transposable elements. The four deletions did not disrupt the low-calcium response (Lcr) region (positions 15,801 to 41,540), the origin of replication, the partitioning region, or the sycH gene.
Lambda Red-mediated recombination was used to delete each specified region of pCD1 and to simultaneously insert an FLP recognition target-flanked kanamycin resistance (kan) cassette or a dhfr cassette essentially as described by Datsenko and Wanner (8). PCR products used to construct the gene replacements were generated using plasmid pKD4 (kan) or dhfr (EZ::TN
To construct a pCD1 variant that had all four deletions, we used lambda Red-mediated recombination (8) to sequentially delete three additional regions (2, 3, and 4) from pCD1 of KIM8 1s. PCR products used to construct the sequential gene replacements were generated using pKD4 (kan), pKD3 (cat), or dhfr as the template for PCR. The 2::kan, 3::cat, and 4::dhfr insertional deletions were confirmed by PCR analysis and by agarose gel electrophoresis of plasmids isolated by the method of Kado and Liu (21). The resultant multiple-deletion pCD1 plasmids pCD1-12 (kan), pCD1-123 (kan2 cat3), and pCD1-1234 (kan2 cat3 dhfr4), as well as the original single-deletion plasmids pCD1-1 (kan), pCD1-2 (kan), pCD1-3 (kan), and pCD1-4 (dhfr), were isolated and electroporated into Y. pestis KIM10 (pMT1+, pCD1–, pPCP1–), generating Y. pestis KIM8 1 (Kmr), KIM8 2 (Kmr), KIM8 3 (Kmr), KIM8 4 (Tmr), KIM8 12 (Kmr), KIM8 123 (Kmr Cmr), and KIM8 1234 (Kmr Cmr Tmr) in a clean genetic background (Fig. 1B). The resultant strains were used in all subsequent studies.
Secretion of Yops by Y. pestis KIM8, KIM8 1, KIM8 12, KIM8 123, and KIM8 1234 was measured following growth of the bacteria in TMH medium for 5 h at 37°C in the presence and absence of calcium. Concentrated culture supernatant proteins were separated by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) and stained with Coomassie blue R-250 (Fig. 2A). All five strains secreted Yops in the absence of calcium but not in the presence of calcium. Y. pestis KIM8 1234, which had all four deletions, expressed and secreted YopB, YopD, YopN, and LcrV but none of the effector Yops. In addition to the deletions in plasmid pCD1 mentioned above, a deletion (5) eliminating the pCD1 sequence at positions 55,568 to 70,331 from pCD1 of Y. pestis KIM8 was constructed using primers 4-P1 and 3-P2. Y. pestis KIM8 carrying plasmid pCD1-5, in which the sycH gene was deleted, expressed and secreted only low levels of Yops (data not shown), confirming that SycH is required for efficient T3SS gene expression (4). These studies confirmed that with the exception of sycH, all of the genes required to express a functional calcium-regulated T3SS are encoded in the Lcr region of plasmid pCD1. Similar results were obtained by Trulzsch et al. (36), who inserted the entire Lcr region of the Y. enterocolitica pYV virulence plasmid into a cosmid vector (mini-pYV). In this case, the mini-pYV plasmid directed secretion and translocation of effector Yops encoded on expression plasmids provided in trans. Although the mini-pYV plasmid encoded a functional T3SS, it did not carry the sycH gene; therefore, LcrQ (YscM)-dependent regulation of T3SS gene transcription was not reconstituted with this construct. SycH, the chaperone for YopH and LcrQ, is required for efficient export of the negative regulatory component LcrQ in the absence of calcium (4, 37). Deletion of sycH prevents secretion of LcrQ and results in repression of T3SS gene transcription (30, 31).
The injection of Yops into a eukaryotic cell is essentially a three-step process that involves (i) attachment of the bacterium to a eukaryotic cell via specific bacterial adhesins, (ii) secretion of effector Yops across the bacterial membranes, and (iii) translocation of Yops across the eukaryotic membrane. The ability of Y. pestis KIM8 123 and KIM8 1234 to inject Yops into a eukaryotic cell was evaluated using the ELK tag reporter system described previously (9). Y. pestis KIM8 123, KIM8 1234, KIM8-3002.P40 (yopE yopJ), KIM8-3002.41 (yopE yopJ yopB), and KIM8-3002.41 carrying pYopB2 were transformed with plasmid pYopE129-ELK (9). The reporter plasmid encodes a truncated YopE protein with a C-terminal ELK tag that is phosphorylated upon translocation into a eukaryotic cell. Cultured HeLa cells were infected at a multiplicity of infection of 30 for 3 h at 37°C, and the infected monolayers were analyzed by SDS-PAGE and immunoblot analysis (Fig. 2B). The total YopE129-ELK expressed during the infection was detected with anti-ELK antipeptide antibodies, whereas YopE129-ELK translocated into the HeLa cells was phosphorylated and detected with phospho-specific antipeptide antibodies (Cell Signaling Technology).
Immunoblot analysis with anti-ELK antipeptide antibodies demonstrated that all the strains expressed comparable amounts of the YopE129-ELK protein (Fig. 2B, top panel). Y. pestis KIM8-3002.P40 (parent), KIM8 123, and KIM8 1234 translocated approximately equal amounts of YopE129-ELK into the HeLa cells (Fig. 2B, bottom panel). In contrast, the translocation-defective yopB strain was unable to inject the YopE129-ELK protein into the HeLa cells. Providing complementing plasmid pYopB2 in trans completely restored the ability of the yopB deletion mutant to translocate the YopE129-ELK protein. These studies confirmed that the pCD1-1234 plasmid encodes a functional T3SS capable of injecting Yops into eukaryotic cells.
The calcium-regulated secretion of Yops by Yersinia spp. is dependent upon at least 30 different pCD1 genes; however, the role of chromosomal genes in this process is not fully understood. Recently, several chromosomal genes required for efficient expression of the Yersinia spp. T3SS have been identified (7, 10, 19, 20); however, the gene products identified thus far do not appear to be intimately involved in the type III secretion process per se. To determine if the Y. pestis chromosome carries genes that are essential for expression of a functional calcium-regulated T3SS, we moved the pCD1-1234 construct into E. coli DH5 and BL21. Only low levels of Yop expression and no Yop secretion were observed in E. coli DH5 or BL21 carrying plasmid pCD1-1234, indicating that pCD1 T3SS genes are not efficiently expressed in E. coli (17) (Fig. 3 and data not shown).
Transcription of T3SS genes in Yersinia spp. is negatively regulated by a small histone-like protein designated YmoA (7). E. coli strains express a protein homologous to YmoA, designated Hha (24), which functions with H-NS to thermoregulate the transcription of several virulence-related genes (22, 25). To examine the role of Hha in regulating the expression of pCD1-1234 T3SS genes in E. coli DH5 and BL21, we used lambda Red-mediated recombination to delete the hha locus and to insert a kan cassette at the site of the deletion. The deletion of hha in both DH5 and BL21 was confirmed by PCR analysis. Plasmid pKD46 was cured from the hha deletion mutants, and the pCD1-1234 plasmid was electroporated into the pKD46-cured hha deletion strains.
Expression and secretion of YopN and YopD by Y. pestis KIM8 and KIM8 1234 and by E. coli BL21, BL21 hha, DH5, and DH5 hha with and without plasmid pCD1-1234 were determined following growth of the bacteria at 37°C in TMH medium in the presence and absence of calcium (Fig. 3). The E. coli BL21 and DH5 hha deletion strains carrying plasmid pCD1-1234 secreted YopN and YopD in the absence of calcium but not in the presence of calcium. The amounts of YopN and YopD secreted by these strains were comparable to or slightly less than the amounts secreted by Y. pestis KIM8 or KIM8 1234. These studies confirmed that plasmid pCD1-1234 contains the complete complement of genes unique to the yersiniae that are required to express a functional T3SS. Interestingly, the E. coli hha strains carrying pCD1-1234 secreted high levels of Yops but did not exhibit growth restriction (data not shown), suggesting that the physiological determinants that link growth and secretion are unique to the yersiniae.
E. coli DH5 and BL21 are avirulent bacteria that do not express the surface adhesins required for attachment to the surface of eukaryotic cells (5). Therefore, the E. coli strains that express a functional T3SS should not be able to attach to HeLa cells and inject Yops. Indeed, E. coli DH5 hha and BL21 hha carrying pCD1-1234 and pYopE129-ELK expressed the YopE129-ELK protein but did not translocate the protein into cultured HeLa cells (data not shown).
Previous studies have suggested that Hha and YmoA, which exhibit 82% amino acid sequence identity, are interchangeable (1, 11). Our results indicate that Hha in E. coli, but not YmoA in Y. pestis, prevents essentially all pCD1 T3SS gene expression at 37°C. The reason for the difference is unclear; however, we hypothesize that it could be related to the amount of YmoA or Hha present in the relevant bacterial cells at 37°C. We have demonstrated previously that YmoA is rapidly degraded by the Lon protease at 37°C in Y. pestis, a process that is essential to trigger T3SS gene transcription in Y. pestis (20). It is possible that Hha is more resistant to Lon-mediated proteolysis and is not rapidly degraded at 37°C in E. coli. To begin to examine this possibility, we constructed plasmid pFLAG-Hha, which encodes the Hha protein with an N-terminal 14-amino-acid tag (N-MDYKDDDDKVKLLE-Hha). Plasmid pFLAG-Hha was electroporated into E. coli DH5 and BL21, whereas plasmid pFLAG-YmoA was electroporated into Y. pestis KIM5-3001 (20). The stability of FLAG-Hha and FLAG-YmoA at 37°C was determined by determining the amounts of these proteins after new synthesis was blocked by addition of chloramphenicol (40 μg/ml) to the cultures, as described previously (20). Samples corresponding to equal numbers of bacteria were removed at specific times and analyzed by SDS-PAGE and immunoblot analysis with the FLAG M2 antibody (Sigma, St. Louis, MO) (Fig. 4). As previously demonstrated, FLAG-YmoA was rapidly degraded at 37°C in Y. pestis. FLAG-Hha was stable at 37°C in lon-deficient E. coli BL21 (14), but it was degraded in E. coli DH5. These results suggest that Hha, like YmoA, is degraded in a Lon-dependent manner; however, the half-life of FLAG-YmoA in Y. pestis (19.3 min) was significantly less than the half-life of FLAG-Hha in DH5 (40.3 min). These results suggest that the degradation of Hha in E. coli and the degradation of YmoA in Y. pestis are to some extent different, and the difference may account for the ability of Hha to suppress pCD1 gene transcription at 37°C in E. coli. Alternate explanations are also possible, and further studies are required to determine the mechanism by which Hha represses T3SS gene transcription at 37°C in E. coli.
The E. coli hha/pCD1-1234 strain-plasmid combination provides a system to study the Yersinia spp. type III secretion process in a heterologous host. Previously, only the Erwinia chrysanthemi T3SS has been shown to function in a heterologous bacterial host (16). The combination of the pCD1-1234 virulence plasmid lacking the genes encoding all six translocated effector Yops with an avirulent E. coli host provides a reliable and safe system to analyze the molecular events involved in the Y. pestis type III secretion process. The procedures for preparation and manipulation of membrane vesicles suitable for in vitro secretion studies have been developed and fine-tuned in E. coli (12). Thus, the E. coli hha/pCD1-1234 system should facilitate the development of in vitro secretion assays that are required to dissect the molecular events involved in the type III secretion process.
ACKNOWLEDGMENTS
This work was supported by Public Health Service grants AI 50552 and AI 39575 from the National Institutes of Health to G.V.P.
REFERENCES
1. Balsalobre, C., A. Juarez, C. Madrid, M. Mourino, A. Prenafeta, and F. J. Munoa. 1996. Complementation of the hha mutation in Escherichia coli by the ymoA gene from Yersinia enterocolitica: dependence on the gene dosage. Microbiology 142:1841-1846.
2. Ben-Gurion, R., and A. Shafferman. 1981. Essential virulence determinants of different Yersinia species are carried on a common plasmid. Plasmid 5:183-187.
3. Brubaker, R. R. 1983. The Vwa+ virulence factor of yersiniae: the molecular basis of the attendant nutritional requirement for Ca++. Rev. Infect. Dis. 5:748-758.
4. Cambronne, E. D., L. W. Cheng, and O. Schneewind. 2000. LcrQ/YscM1, regulators of the Yersinia yop virulon, are injected into host cells by a chaperone-dependent mechanism. Mol. Microbiol. 37:263-273.
5. Chart, H., H. R. Smith, R. M. La Ragione, and M. J. Woodward. 2000. An investigation into the pathogenic properties of Escherichia coli strains BLR, BL21, DH5 and EQ1. J. Appl. Microbiol. 89:1048-1058.
6. Cornelis, G. R. 2000. Molecular and cell biology aspects of plague. Proc. Natl. Acad. Sci. USA 97:8778-8783.
7. Cornelis, G. R., C. Sluiters, I. Delor, D. Geib, K. Kaniga, C. Lambert de Rouvroit, M. P. Sory, J. C. Vanooteghem, and T. Michiels. 1991. ymoA, a Yersinia enterocolitica chromosomal gene modulating the expression of virulence functions. Mol. Microbiol. 5:1023-1034.
8. Datsenko, K. A., and B. L. Wanner. 2000. One-step inactivation of chromosomal genes in Escherichia coli K-12 using PCR products. Proc. Natl. Acad. Sci. USA 97:6640-6645.
9. Day, J. B., F. Ferracci, and G. V. Plano. 2003. Translocation of YopE and YopN into eukaryotic cells by Yersinia pestis yopN, tyeA, sycN, yscB and lcrG deletion mutants measured using a phosphorylatable peptide tag and phosphospecific antibodies. Mol. Microbiol. 47:807-823.
10. DeBord, K. L., N. S. Galanopoulos, and O. Schneewind. 2003. The ttsA gene is required for low-calcium-induced type III secretion of Yop proteins and virulence of Yersinia enterocolitica W22703. J. Bacteriol. 185:3499-3507.
11. de la Cruz, F., M. Carmona, and A. Juarez. 1992. The Hha protein from Escherichia coli is highly homologous to the YmoA protein from Yersinia enterocolitica. Mol. Microbiol. 6:3451-3452.
12. Douville, K., A. Price, J. Eichler, A. Economou, and W. Wickner. 1995. SecYEG and SecA are the stoichiometric components of preprotein translocase. J. Biol. Chem. 270:20106-20111.
13. Ghosh, P. 2004. Process of protein transport by the type III secretion system. Microbiol. Mol. Biol. Rev. 68:771-795.
14. Gottesman, S. 1989. Genetics of proteolysis in Escherichia coli. Annu. Rev. Genet. 23:163-198.
15. Grosdent, N., I. Maridonneau-Parini, M. P. Sory, and G. R. Cornelis. 2002. Role of Yops and adhesins in resistance of Yersinia enterocolitica to phagocytosis. Infect. Immun. 70:4165-4176.
16. Ham, J. H., D. W. Bauer, D. E. Fouts, and A. Collmer. 1998. A cloned Erwinia chrysanthemi Hrp (type III protein secretion) system functions in Escherichia coli to deliver Pseudomonas syringae Avr signals to plant cells and to secrete Avr proteins in culture. Proc. Natl. Acad. Sci. USA 95:10206-10211.
17. Heesemann, J., U. Gross, N. Schmidt, and R. Laufs. 1986. Immunochemical analysis of plasmid-encoded proteins released by enteropathogenic Yersinia sp. grown in calcium-deficient media. Infect. Immun. 54:561-567.
18. Hu, P., J. Elliott, P. McCready, E. Skowronski, J. Garnes, A. Kobayashi, R. R. Brubaker, and E. Garcia. 1998. Structural organization of virulence-associated plasmids of Yersinia pestis. J. Bacteriol. 180:5192-5202.
19. Jackson, M. W., and G. V. Plano. 1999. DsbA is required for stable expression of outer membrane protein YscC and for efficient Yop secretion in Yersinia pestis. J. Bacteriol. 181:5126-5130.
20. Jackson, M. W., E. Silva-Herzog, and G. V. Plano. 2004. The ATP-dependent ClpXP and Lon proteases regulate expression of the Yersinia pestis type III secretion system via regulated proteolysis of YmoA, a small histone-like protein. Mol. Microbiol. 54:1364-1378.
21. Kado, C. I., and S. T. Liu. 1981. Rapid procedure for detection and isolation of large and small plasmids. J. Bacteriol. 145:1365-1373.
22. Madrid, C., J. M. Nieto, and A. Juarez. 2002. Role of the Hha/YmoA family of proteins in the thermoregulation of the expression of virulence factors. Int. J. Med. Microbiol. 291:425-432.
23. Michiels, T., P. Wattiau, R. Brasseur, J. M. Ruysschaert, and G. Cornelis. 1990. Secretion of Yop proteins by yersiniae. Infect. Immun. 58:2840-2849.
24. Nieto, J. M., M. Carmona, S. Bolland, Y. Jubete, F. de la Cruz, and A. Juarez. 1991. The hha gene modulates haemolysin expression in Escherichia coli. Mol. Microbiol. 5:1285-1293.
25. Nieto, J. M., C. Madrid, E. Miquelay, J. L. Parra, S. Rodriguez, and A. Juarez. 2002. Evidence for direct protein-protein interaction between members of the enterobacterial Hha/YmoA and H-NS families of proteins. J. Bacteriol. 184:629-635.
26. Orth, K., L. E. Palmer, Z. Q. Bao, S. Stewart, A. E. Rudolph, J. B. Bliska, and J. E. Dixon. 1999. Inhibition of the mitogen-activated protein kinase kinase superfamily by a Yersinia effector. Science 285:1920-1923.
27. Palmer, L. E., S. Hobbie, J. E. Galan, and J. B. Bliska. 1998. YopJ of Yersinia pseudotuberculosis is required for the inhibition of macrophage TNF-alpha production and downregulation of the MAP kinases p38 and JNK. Mol. Microbiol. 27:953-965.
28. Perry, R. D., S. C. Straley, J. D. Fetherston, D. J. Rose, J. Gregor, and F. R. Blattner. 1998. DNA sequencing and analysis of the low-Ca2+-response plasmid pCD1 of Yersinia pestis KIM5. Infect. Immun. 66:4611-4623.
29. Persson, C., R. Nordfelth, A. Holmstrom, S. Hakansson, R. Rosqvist, and H. Wolf-Watz. 1995. Cell-surface-bound Yersinia translocate the protein tyrosine phosphatase YopH by a polarized mechanism into the target cell. Mol. Microbiol. 18:135-150.
30. Pettersson, J., R. Nordfelth, E. Dubinina, T. Bergman, M. Gustafsson, K. E. Magnusson, and H. Wolf-Watz. 1996. Modulation of virulence factor expression by pathogen target cell contact. Science 273:1231-1233.
31. Rimpilainen, M., A. Forsberg, and H. Wolf-Watz. 1992. A novel protein, LcrQ, involved in the low-calcium response of Yersinia pseudotuberculosis shows extensive homology to YopH. J. Bacteriol. 174:3355-3363.
32. Rosqvist, R., A. Forsberg, and H. Wolf-Watz. 1991. Intracellular targeting of the Yersinia YopE cytotoxin in mammalian cells induces actin microfilament disruption. Infect. Immun. 59:4562-4569.
33. Rosqvist, R., K. E. Magnusson, and H. Wolf-Watz. 1994. Target cell contact triggers expression and polarized transfer of Yersinia YopE cytotoxin into mammalian cells. EMBO J. 13:964-972.
34. Schesser, K., A. K. Spiik, J. M. Dukuzumuremyi, M. F. Neurath, S. Pettersson, and H. Wolf-Watz. 1998. The yopJ locus is required for Yersinia-mediated inhibition of NF-kappaB activation and cytokine expression: YopJ contains a eukaryotic SH2-like domain that is essential for its repressive activity. Mol. Microbiol. 28:1067-1079.
35. Straley, S. C., G. V. Plano, E. Skrzypek, P. L. Haddix, and K. A. Fields. 1993. Regulation by Ca2+ in the Yersinia low-Ca2+ response. Mol. Microbiol. 8:1005-1010.
36. Trulzsch, K., A. Roggenkamp, M. Aepfelbacher, G. Wilharm, K. Ruckdeschel, and J. Heesemann. 2003. Analysis of chaperone-dependent Yop secretion/translocation and effector function using a mini-virulence plasmid of Yersinia enterocolitica. Int. J. Med. Microbiol. 293:167-177.
37. Wattiau, P., B. Bernier, P. Deslee, T. Michiels, and G. R. Cornelis. 1994. Individual chaperones required for Yop secretion by Yersinia. Proc. Natl. Acad. Sci. USA 91:10493-10497.(Sara Schesser Bartra, Mic)