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Journal of Bacteriology, August 2005, p. 5259-5266, Vol. 187, No. 15
0021-9193/05/$08.00+0     doi:10.1128/JB.187.15.5259-5266.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

Identification of an Escherichia coli Operon Required for Formation of the O-Antigen Capsule

Adi Peleg,^1, Yulia Shifrin,^1, Ophir Ilan,¹ Chen Nadler-Yona,¹ Shani Nov,¹ Simi Koby,¹ Kobi Baruch,¹ Shoshy Altuvia,¹ Maya Elgrably-Weiss,¹ Cecilia M. Abe,² Stuart Knutton,² Mark A. Saper,³ and Ilan Rosenshine^1*

Department of Molecular Genetics and Biotechnology, The Hebrew University, Faculty of Medicine, POB 12272, Jerusalem 91120, Israel,¹ Institute of Child Health, University of Birmingham, Whittall Street, Birmingham B4 6NH, United Kingdom,² Biophysics Research Division and Department of Biological Chemistry, University of Michigan, 930 North University Ave., Ann Arbor, Michigan 48109-1055³

Received 3 December 2004/ Accepted 9 May 2005

Top Abstract Introduction Materials and Methods Results Discussion References

 
Escherichia coli produces polysaccharide capsules that, based on their mechanisms of synthesis and assembly, have been classified into four groups. The group 4 capsule (G4C) polysaccharide is frequently identical to that of the cognate lipopolysaccharide O side chain and has, therefore, also been termed the O-antigen capsule. The genes involved in the assembly of the group 1, 2, and 3 capsules have been described, but those required for G4C assembly remained obscure. We found that enteropathogenic E. coli (EPEC) produces G4C, and we identified an operon containing seven genes, ymcD, ymcC, ymcB, ymcA, yccZ, etp, and etk, which are required for formation of the capsule. The encoded proteins appear to constitute a polysaccharide secretion system. The G4C operon is absent from the genomes of enteroaggregative E. coli and uropathogenic E. coli. E. coli K-12 contains the G4C operon but does not express it, because of the presence of IS1 at its promoter region. In contrast, EPEC, enterohemorrhagic E. coli, and Shigella species possess an intact G4C operon.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Escherichia coli strains exhibit variations in their cell surface polysaccharides. The primary surface polysaccharides, lipopolysaccharide (LPS) and capsule, are serotype specific (28, 33). Based on their mechanisms of synthesis and assembly, the E. coli capsules have been classified into four groups (33). Since in some cases the polysaccharide of the group 4 capsule (G4C) is identical to that of the cognate LPS O side chain, G4C was also termed O-antigen capsule (13). E. coli O111 and O127, serotypes which are typical also of enteropathogenic E. coli (EPEC) and enterohemorrhagic E. coli, were reported to form G4C (13, 27). The specific genes required for the assembly of group 1, 2, and 3 capsules have been identified and characterized (33). However, until now, the genes necessary for the assembly of the G4C were not known.

LPS is an amphipathic glycoconjugate whose hydrophobic domain, lipid A, forms the outer leaflet of the outer membrane. The core oligosaccharide links lipid A to the oligosaccharide side chain, known as the O antigen. The structure of lipid A and of the core oligosaccharide is conserved, but the structure of the O antigen is variable (28). The E. coli O antigen may be synthesized by several alternative mechanisms, including the Wzy-dependent pathway. The O antigen, which is synthesized via the Wzy-dependent pathway, is made up of repeat units typically consisting of three to five sugar residues (28). The structural diversity of the O antigens stems mainly from variations in sugar composition, sequence, and linkage. Synthesis and assembly of LPS require numerous proteins, which are encoded by genes clustered in three loci (28): the lipid A biosynthesis region, the core oligosaccharide synthesis locus, and the O-antigen synthesis locus. Lipid A linked to the core oligosaccharide is assembled on the inner leaflet of the plasma membrane and then translocated to the outer leaflet. The O-antigen repeat unit is also synthesized on the inner leaflet of the plasma membrane, on a lipid carrier (undecaprenol phosphate, und-PP). Und-PP, linked to repeat units, is then translocated to the outer leaflet of the plasma membrane (28). Translocation of the individual und-PP-linked O units to the periplasm requires Wzx, the O-unit transporter ("flippase") (23). The und-PP-linked O units are polymerized on the periplasmic face of the plasma membrane. The reaction involves transfer of the nascent polymer from its und-PP carrier to the nonreducing end of the new und-PP-linked O repeat. The net effect is a chain-length increase by 1 repeat unit. Polymerization is catalyzed by the O-polysaccharide polymerase Wzy (2), an integral membrane protein exhibiting specificity for the cognate O unit. The polymerized O antigen is then ligated to the core oligosaccharide. WaaL, an integral membrane protein, is required for this process (28). Upon ligation of the O side chain, the complete LPS is translocated to the external leaflet of the outer membrane.

Polymerization of G4C polysaccharide is also dependent on the O-antigen polymerase Wzy (1, 32). However, in contrast to LPS, G4Cs are composed of a high-molecular-weight polysaccharide attached to the bacterial surface not via lipid but probably by interaction with a specific surface protein(s) (29). We previously showed that EPEC O127:H6 expresses the etk gene, which encodes a protein tyrosine kinase (17). We now report that etk is encoded within an operon containing six additional genes and that the products of each of these genes are required for the assembly of G4C. The G4C operon appears to encode components of a polysaccharide secretion and capsule assembly apparatus. This operon was found in E. coli K-12, but it is not expressed. It is also present in a specific subset of E. coli and Shigella sp. strains.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Bacterial strains and plasmids. The bacterial strains and plasmids used in this study are listed in Table 1. The primers are listed in Table 2.

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TABLE 1. Bacterial strains and plasmids used in this study

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TABLE 2. Oligonucleotide primers (in 5'-3' orientation) used for PCR

Construction of mutants. The Lambda Red system was used to replace the wild-type alleles with inactivated genes. To inactivate etk, the kan cassette of pUC4Kan (Pharmacia) was inserted into the BglII site of etk cloned in pQE31 (pOI194), resulting in the plasmid pOIK. The etk::kan gene was then amplified and used to replace the wild-type allele. Most of the coding regions of etp, ymcA, ymcB, ymcC, ymcD, and yccZ were replaced with a kan or chloramphenicol (Cm) cassette, amplified from pKD3 or pKD4, respectively. Similarly, the promoter region of the colanic acid (CA) operon and wza, the first gene of the operon, were deleted and replaced with a kan cassette. To construct a mutant containing a polar cassette downstream of the G4C promoter, the ymcD coding region was cloned into the pir-dependent suicide vector pGP704 (25), to give pAP2125. The plasmid was then mobilized into EPEC (Str^r) by conjugation from E. coli SM10 pir. Transconjugants containing chromosomally integrated plasmid were selected on plates containing ampicillin (50 µg/ml) and streptomycin (100 µg/ml). Plasmid integration via homologous recombination between the ymcD alleles was confirmed by PCR.

Plasmid construction. A SalI fragment from pNDMI1 carrying lacI^q was cloned into the SalI site of pACYC184, generating pACYC234. The SalI site distal to the HindIII site was disrupted. The pOI194 plasmid was digested with XhoI and HindIII. The fragment containing 6his-etk under the tac promoter was cloned into the SalI and HindIII sites of pACYC234, giving rise to pOI277, which expresses 6His-Etk. The ymcA, ymcB, ymcC, ymcD, and yccZ genes were amplified with primers fitted with suitable restriction sites and encoding six additional His residues at the 3' end of the genes (Table 1) and cloned into the pSA10 expression vector digested with EcoRI and PstI or SalI. The etp gene was amplified and cloned in pSA10 as described above (to generate pAP2064) or in pQE31 to generate pAP406, which encodes 6his-etp. The primers which were used are listed in Table 2.

Agglutination assay. Bacteria were grown overnight in LB without NaCl, and when needed 0.1 mM IPTG (isopropyl-ß-D-thiogalactopyranoside) was added. The bacteria then remained untreated or were heated to 100°C for 2 min and cooled for 1 h at room temperature. Twofold dilutions of anti-O antiserum in phosphate-buffered saline were prepared, and 50 µl of each dilution was added to 50 µl of heated and unheated bacteria in 96-well plates. The plates were then incubated overnight at 50°C and examined for bacterial agglutination.

Electron microscopy. Bacteria grown overnight in LB at 37°C were washed with 0.1 M cacodylate buffer, pH 7.0; labeled with cationized ferritin (2 mg/ml; Sigma) for 30 min; and fixed with 5% glutaraldehyde for 1 h at room temperature (21). Fixed samples were washed, postfixed with 1% osmium tetroxide for 2 h at room temperature, dehydrated in a graded series of ethanol solutions, and embedded in Epon resin. Thin sections were stained with 2% uranyl acetate and lead citrate and examined under a JEOL 1200EX transmission electron microscope operating at 80 kV. To quantify capsule expression, low-power micrographs were recorded and the percentage of bacteria expressing cationized ferritin staining material was determined.

Buoyancy assay. Bacterial strains were grown without shaking in 5 ml LB to an optical density at 600 nm (OD₆₀₀) of 0.3 at 37°C in transparent tubes. The medium was underlaid with 2 ml Percoll (55% Percoll [Amersham], 25 mM phosphate buffer, pH 6.5) and centrifuged in an Eppendorf 5403 centrifuge swing bucket rotor at 1,000 x g at room temperature for 20 min. The wild-type encapsulated EPEC cells formed a band at the Percoll-medium interface, and the noncapsulated strains formed pellets.

Preparation of total cellular polysaccharide. Bacteria were grown overnight in 50 ml LB without NaCl. The OD of the cultures was adjusted to 1.0, and the cultures were centrifuged and resuspended in 500 µl of phosphate-buffered saline. An equal volume of saturated phenol (pH 8.0) was added, and the mixture was incubated for 30 min at 70°C with occasional mixing followed by centrifugation (1 h, 10,000 x g). The top, aqueous phase was recovered, 2 volumes of 100% ethanol was added to each sample, and the polysaccharides were allowed to precipitate for 1 h at –70°C. The samples were centrifuged at 12,000 x g for 30 min, and the pellets were washed with 500 µl of 70% ethanol, recentrifuged, and lyophilized.

Separation of capsule polysaccharide from LPS. The lyophilized total polysaccharide preparations were resuspended in 500 µl of water. The resuspended LPS, which formed micelles, was precipitated by ultracentrifugation (1 h, 86,000 x g) (27). The supernatant containing the capsule polysaccharide was recovered, and residual LPS contamination was removed by phase partition with Triton X-114 as described previously (24). Briefly, Triton X-114 was added to the supernatant to a final concentration of 1%. The mixture was incubated at 4°C for 1 h with constant stirring to ensure a homogenous solution. The mixture was then transferred to a 37°C water bath, incubated for 10 min, and centrifuged (1 h, 1,000 x g) at 25°C. The resulting aqueous phase containing purified capsule polysaccharide was carefully aspirated. We confirmed that the preparation was LPS free by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and Western analysis using anti-O127 (data not shown).

Analysis of LPS and capsule polysaccharide. Total cell polysaccharide was separated on 10% polyacrylamide gels containing 0.5% SDS (SDS-PAGE), and the gels were used for immunoblot analysis. The SDS-PAGE gels allowed visualization of the LPS without the interference of capsular polysaccharide, which cannot enter the gel because of its low net charge and high molecular weight (13, 27). Samples containing purified capsule polysaccharide were applied directly to nitrocellulose membranes for dot blot analysis. Blots were developed with anti-O127 monospecific rabbit antiserum (Statens Serum Institut, Denmark) and secondary anti-rabbit immunoglobulin G conjugated to alkaline phosphatase (Sigma).

Complement sensitivity assay. Blood was taken from healthy subjects after receiving their informed consent. The blood was left to clot at 37°C for 45 min, and the serum was separated from the clot by centrifugation (10 min, 700 x g). Aliquots containing 0.2 ml of bacterial culture in early log phase (OD₆₀₀ of 0.2) were mixed with 0.6 ml serum and incubated at 37°C. Samples of 0.1 ml were diluted and plated for viable count at different time points. Complement was inactivated by incubating the serum for 20 min at 56°C before mixing it with the bacterial culture.

Transposon mutagenesis and isolation of noncapsulated mutant. Transposon mutagenesis with mini-Tn10kan was carried out as described previously (6). Mutants deficient in capsule formation were isolated as pellet-forming bacteria in the Percoll buoyancy assay.

RNA analysis. Primer extension assays were carried out as described previously (10). Briefly, bacterial cultures grown to an OD₆₀₀ of 0.3 or 1.0 were pelleted and resuspended in 10 mM Tris, pH 7.5, and 1 mM EDTA. Lysozyme was added to 0.9 mg/ml, and the samples were subjected to three freeze-thaw cycles. Total RNA was isolated using an Ultraspec RNA kit according to the manufacturer's (BIOTECX Laboratories) instructions, except that 1 ml of reagent was used for 12 to 16 OD₆₀₀ units of cells. The RNA samples (3 µg) were subjected to primer extension at 42°C for 45 min, using avian myeloblastosis virus reverse transcriptase (CHIMWEx) and end-labeled primer 828. The extension products and the sequencing reaction mixtures primed with end-labeled primer 828 were separated on a 6% sequencing gel.

Genome comparison. We used the coliBASE server (http://colibase.bham.ac.uk/) to access the different databases and for comparison of the G4C operon region in different genomes.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Etk and Etp are required for capsule formation by EPEC. Homologs of Etk (YccC) and Etp (YccY) are frequently involved in capsule formation (17, 31, 33). We, therefore, tested the role of Etk and Etp in capsule formation by EPEC O127:H6. A common definition of the E. coli capsule is "a heat-sensitive structure that interferes with bacterial agglutination upon incubation with anti-O antibody" (12, 13). We, therefore, used the agglutination test to compare wild-type EPEC with the etp::kan and etk::kan mutants. The titer of the anti-O127 antiserum required to agglutinate the etp and etk mutants was 16-fold lower than that required to agglutinate the wild-type EPEC (Table 3). This indicates that LPS is masked by a capsule in the wild type but not in the mutants. LPS masking was removed upon heat destruction of the capsule (Table 3). Complementation with plasmids expressing etk or etp (pOI277 and pAP2064, respectively) restored the LPS-masking effect. Taken together, these results indicate that Etk and Etp are required for capsule formation by EPEC.

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TABLE 3. Agglutination with anti-O127 antibody of wild-type EPEC O127, etk::kan and etp::kan mutants, and mutants complemented with plasmids carrying wild-type etk or etp alleles

To further support this notion, we examined the bacteria by transmission electron microscopy, following staining with cationized ferritin. A thick layer of ferritin-stained material was seen at the surface of most (80.5%) of the wild-type bacteria, although this layer was not always uniformly dense over the bacterial surface (Fig. 1C). The appearance of the etk mutant complemented with plasmid expressing etk was similar to that of the wild type (77.5% encapsulated bacteria), whereas very few etk::kan mutants were stained with ferritin (8%). In the latter case, the staining was sparse and generally appeared filamentous, suggesting that the ferritin might be staining a glycosylated surface pilus structure rather than capsular material. Colonies of heavily encapsulated bacteria are usually mucoid. In contrast, the wild-type EPEC, as well as the etp and etk mutants, exhibited a nonmucoid colony morphology. Differences in bacterial buoyancy on a Percoll step density gradient were exploited to detect capsules that do not produce mucoid colonies (16). Using this assay, we found that the EPEC etk::kan mutant exhibited a lower buoyancy than did the wild-type strain (Fig. 1B). The buoyancy of the etk mutant was restored upon complementation with a plasmid expressing etk. Similar results were obtained using the EPEC etp mutant (data not shown). These findings support the notion that etk and etp are required for capsule formation.

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FIG. 1. Expression of Etk and its relation to buoyant density and capsule formation. Bacterial proteins were extracted and used for immunoblotting to which an anti-Etk antibody was applied (A). Etk is expressed by wild-type EPEC (lane 1) and by the EPEC etk::kan mutant complemented with a plasmid expressing etk (lane 3), but not by the EPEC etk::kan mutant (lane 2). The bacterial buoyancy assay is shown in panel B. Bacteria were grown to an OD600 of 0.3, and 5 ml of the cultures was underlaid with 2 ml Percoll in a transparent tube and centrifuged. Wild-type EPEC (tube 1) and an etk::kan mutant containing a plasmid expressing etk (tube 3) appear at the Percoll-medium interface (arrow), whereas the etk::kan cells (tube 2) form a pellet. Panel C shows electron microscopy images of the Etk-dependent capsule formed by EPEC O127. The etk::kan mutant appears noncapsulated, whereas the wild-type strain and the etk::kan mutant complemented with an etk-expressing plasmid form capsules (indicated by arrows).

The CA operon is not required for production of the Etk-dependent capsule. We identified in the EPEC genome database two gene clusters encoding enzymes required for polysaccharide biosynthesis. One is the CA biosynthesis operon, and downstream of it resides the LPS O side chain biosynthesis region. To test the possible involvement of the CA operon in the formation of the etk/etp-dependent capsule, we deleted the CA operon promoter region and part of the operon's first gene (wza). To confirm inactivation of the CA operon, we introduced into the mutant (MS1651) and into wild-type EPEC a plasmid overexpressing RcsA, a regulator that activates expression of the CA operon (14). As expected, RcsA-expressing EPEC, grown in LB at 37°C, produced mucoid colonies, but strain MS1651 lost this ability upon RcsA overexpression (data not shown). In contrast, the buoyancy of this mutant was similar to that of wild-type EPEC when grown in LB at 37°C. These results indicate that the CA operon is not required for the production of the etp/etk-dependent capsule. It also suggests that etp and etk may be involved in the formation of G4C, composed of polymers similar to those of the O side chain polysaccharide.

Etp and Etk are required for the formation of G4C. Some E. coli strains of serogroups O127 and O111 form G4C, which is composed of a polysaccharide similar to that of the LPS O side chain (13, 27). G4C polymers extracted from these strains reacted with anti-O antibody, but the encapsulated O111 bacteria do not undergo agglutination by anti-O111 antibodies (13). To investigate whether Etp and Etk are involved in the production of G4C, the capsule and LPS of EPEC strain E2348/69, serogroup O127, were extracted and separated by differential centrifugation and phase partition (24, 27). SDS-PAGE and Western blotting with anti-O127 were used to assess the amount of LPS side chain without the possible interference of the capsular polysaccharide, which cannot enter the gel because of its low net charge and high molecular weight (13, 27, 34) (Fig. 2A). The purified capsular polysaccharide was analyzed by immuno-dot blot assay with anti-O127 (Fig. 2B). We found that anti-O127 antibody reacted with the purified capsular polysaccharide, indicating that this is an O-antigen capsule. We also found that synthesis of the capsular polysaccharide was abolished upon inactivation of etk or etp and was associated with increased synthesis of the LPS O side chain (Fig. 2A and B). Introduction of complementing plasmids partially restored capsule production, which was associated with a reduction in LPS O side chain synthesis (Fig. 2A and B). These results indicate that etp and etk are required for the assembly of G4C and are consistent with the hypothesis that the capsule synthesis system and the LPS O side chain synthesis system are competing for the same repeat-unit precursor (27). Some strains producing G4C are sensitive to complement; spontaneous variants, deficient in capsule formation, exhibit increased O-antigen synthesis, which may lead to changes in O-antigen conformation (12, 18, 19). These changes in O-antigen synthesis correlated with increased bacterial complement resistance (12, 18, 19). Given our previous results, we predicted that the etk mutant would be complement resistant. To test this hypothesis, cultures in early logarithmic growth phase were mixed with fresh human serum and survival was monitored. The human serum rapidly killed wild-type EPEC (Fig. 2C), but the EPEC etk::kan mutant was barely affected. Complementation with plasmid expressing etk partially restored complement sensitivity. Inactivation of the complement by heat treatment abolished the serum's ability to kill the bacteria (Fig. 2C). The tested serum did not contain anticapsule antibody (data not shown), excluding the possibility that the complement was specifically recruited to the encapsulated bacteria by anticapsule antibodies. These results indicate that in EPEC O127 the interplay between G4C and LPS synthesis is similar to that described for E. coli O111 (12).

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FIG. 2. Etk and Etp are required for synthesis of G4C. Total polysaccharides (LPS and capsular polysaccharide) were extracted, and the capsular polysaccharide was separated from the LPS. Production of LPS O antigen was analyzed by Western blotting (A), and the amount of purified capsular polysaccharide was estimated by dot blot assay (B). In both cases, care was taken to apply amounts of material equivalent to the same amount of bacteria in all the lanes. The Western blot and the dot blots were developed with anti-O127 antiserum. The genotypes of the analyzed strains are indicated above the lanes. The etk::kan and the etp::Cm mutants did not produce capsules (B) but synthesized greater amounts of the LPS side chain (A). Complementation of the mutants with plasmids expressing etk or etp partially restored capsule production (B) and reduced synthesis of the LPS side chain (A). Panel C shows the resistance of the etk::kan mutant to complement-mediated killing. Early-log cultures were incubated with fresh or inactivated human serum. Wild-type EPEC cells were killed rapidly by the fresh serum (line 1) but not by the heat-inactivated serum (line 4). The EPEC etk::kan mutant (line 3) was highly resistant to fresh serum; complementation of the mutant with plasmid expressing etk (line 2) resulted in a partial increase in serum sensitivity. All experiments were carried out in triplicate, and the standard error is indicated.

The G4C operon. To identify additional genes involved in capsule formation, we screened a mini-Tn10 mutant library and isolated an EPEC mutant, SN40, which exhibits decreased buoyancy in the Percoll buoyancy assay. The mini-Tn10 insertion site in SN40 was mapped to ymcA, a gene located three open reading frames upstream of etk (Fig. 3A). Western analysis showed that SN40 does not produce Etk (Fig. 4A), nor is Etk production restored upon complementation with ymcA-expressing plasmid (data not shown). These results indicate that the mini-Tn10 insertion in SN40 introduced a polar effect and suggest that ymcA and etk are encoded within an operon containing seven genes: ymcD, ymcC, ymcB, ymcA, yccZ, etp, and etk (Fig. 3A). To test this prediction, we performed primer-extension analysis of RNA extracted from EPEC, using a primer complementing the ymcD mRNA (Fig. 3). A transcription start site was localized to a G residue located 166 bp upstream of the ymcD translation start site (Fig. 3B). To test whether this is the only promoter of the G4C operon, we inserted a suicide plasmid, which served as a polar cassette, between the G4C promoter and ymcD. The insertion abolished the production of Etk (Fig. 3C), confirming that ymcD and etk are the first and last genes, respectively, of the G4C operon.

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FIG. 3. The G4C operon. Schematic of the G4C operon and flanking genes (cspH and appA) (A). The location of the G4C operon promoter is indicated by an arrow. Mapping of the G4C promoter (B). Total RNA was extracted from exponential- and stationary-phase EPEC cultures (OD600 of 0.3 and 1, respectively). Primer extension analysis (3 µg, total RNA) of the ymcD promoter region and the sequencing reaction were carried out using the same primer. Plasmid pAP2133 served as a template for the sequencing reaction. The transcription start site was mapped to a G residue located 166 bases upstream of the ymcD translation start site. In panel C, Western analysis with anti-Etk antibody was used to compare wild-type EPEC with strain AD2119, in which a polar cassette between ymcD and the promoter was inserted. The polar insertion abolished Etk expression, confirming that ymcD through etk are expressed by the same transcriptional unit.

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FIG. 4. Inactivation of each of the G4C operon genes results in lack of buoyancy on a Percoll step gradient. Each of the G4C operon genes was inactivated. To confirm nonpolarity, expression of Etk by the different mutants was determined using Western blot analysis with anti-Etk antibody (A). The genotype of the tested EPEC is indicated above each lane. SN40 is an EPEC strain containing a mini-Tn10kan polar insertion in ymcA. The wild-type strain is indicated as EPEC. Below the blot, the results of the buoyancy assays using the corresponding mutants (B) and the mutants complemented with plasmid expressing the corresponding gene (C) are shown. Buoyancy on Percoll is indicated as a plus sign, lack of buoyancy is indicated as a minus sign, and a slash indicates that buoyancy was not tested.

All the genes in the G4C operon are required for capsule formation. We next introduced a nonpolar mutation into each of the G4C operon genes and confirmed the lack of polarity by Western analysis, using anti-Etk antibody (Fig. 4A). All the mutants proved to be deficient in capsule formation, as determined by the buoyancy assay (Fig. 4B). We then cloned each of the G4C genes in the pSA10 expression vector (Table 1) and used these plasmids in complementation assays. Capsule production was restored by complementation with plasmids expressing the corresponding genes (Fig. 4C). These results indicate that each of the seven proteins encoded by the operon is required for G4C formation.

The G4C operon in different E. coli and Shigella sp. strains. Using genomic databases, we compared the chromosomal region containing the G4C operon with the corresponding region in several E. coli and Shigella sp. strains. We found an intact G4C operon in seven genomes. These include EPEC O127 strain E2348/69; two EHEC strains, EDL933 and Sakai; and three Shigella strains, S. sonnei 53G, S. flexneri strains 2a 301 and 2a 2457T, and S. dysenteriae M131649. These E. coli and Shigella strains are expected to form G4C. Intact G4C operons were found also in two E. coli K-12 strains, MG1655 and W3110. But in both cases the promoter was inactivated by an IS1 element inserted 15 bp upstream of the ymcD translation start site, a finding that explains the lack of etk expression in these E. coli K-12 strains (17, 31). The entire G4C operon is absent from uropathogenic E. coli strain CFT073 and from enteroaggregative E. coli strain 042.

Top Abstract Introduction Materials and Methods Results Discussion References

 
E. coli employs several alternative mechanisms to synthesize the O side chain, of which the Wzy-dependent pathway is used also for synthesis of the G4C polymers (1, 32). In this report we describe the identification and characterization of an operon containing seven genes that are required for G4C formation. Thus, the genes required for G4C formation are organized in two separate operons. One operon contains genes required for the Wzy-dependent synthesis of the O side chain and the G4C polymers. The other, the G4C operon, is required for secretion of the G4C polymers and for capsule assembly. The G4C operon is conserved between different E. coli serogroups, indicating that the encoded secretion apparatus is not specific to the cognate O polymers. Wzy-dependent O-antigen synthesis requires Wzy, the O side chain polymerase (2), and WaaL, which ligates the polymerized O antigen to the core oligosaccharide (28). The Wzz protein is required for determination of O side chain length, which is typically 15 to 25 repeat units (7, 11). It has been speculated that Wzy, WaaL, and Wzz are components in an O side chain synthesis complex (28). We are currently testing the hypothesis that the products of the G4C operon form a complex that competes with the O side chain synthesis complex for the repeat unit precursor. The G4C operon encodes seven proteins: Etk, Etp, YzzZ, YmcA, YmcB, YmcC, and YmcD. Etk, Etp, and YccZ are similar to Wzc, Wzb, and Wza, respectively, which are required for secretion of polysaccharide including colanic acid and of K30 polymers (9, 31, 35). Members of the Etk protein family are inner membrane proteins possessing two transmembrane helices and tend to oligomerize (8, 26). They are composed of three distinct domains: a short cytoplasmic N-terminal domain, a large periplasmic loop, and a large C-terminal cytoplasmic domain (8). Since the periplasmic domains of Etk and Wzz show some similarity, we are currently testing whether Etk uses its Wzz-like domain to recruit the Wzy to the G4C complex and to modulate it to polymerize very long capsular O polymers. The C-terminal domain of Etk and related proteins contains a protein tyrosine kinase catalytic site. These proteins undergo autophosphorylation at several conserved tyrosines clustered at the C terminus. The phosphorylation is essential for secretion of the cognate polysaccharides (26, 31, 35). An additional, minor substrate of Wzc is Ugd (UDP-glucose dehydrogenase) (15). Etk was reported also to phosphorylate RpoH and RseA (anti-RpoE) (20), and therefore, it might also be involved in genetic regulation. Etp is a low-molecular-weight protein tyrosine phosphatase (31). It is predicted to reside in the cytoplasm and mediate Etk dephosphorylation both in vitro and in vivo (reference 31 and our unpublished results). We speculate that Etp and Etk might energize the G4C assembly system by repeated phosphorylation and dephosphorylation of the Etk C-terminal cytoplasmic domain. YccZ is an outer membrane lipoprotein. Octamers of Wza-K30, and probably also of other Wza-like proteins, including YccZ, form pore-like structures in the outer membrane (3, 9). It is believed that the polysaccharides are delivered to the surface via these pores (3, 9). We predict, therefore, that the G4C polymer is secreted via the YccZ channel. Based on their deduced sequence, YmcA, YmcB, YmcC, and YmcD contain an N-terminal signal sequence and should be exported proteins. Two of them, YmcA and YmcC, are putative lipoproteins. YmcB appears to reside in the periplasm in a soluble form or is associated with the inner or outer membrane. YmcD is a small protein containing two putative transmembrane domains. It is unusually rich in threonine: 28 of its 107 residues are threonines. E. coli contains paralogs of the ymcABCD genes, the yjbHGFE genes, which form a putative operon localized in the xylE malG region. The function of the yjbHGFE genes is unknown. Interestingly, Vibrio cholerae O139 contains homologs of the ymcABC genes, the otnGFE genes (4). The function of these genes has not been determined, but they are located in the vicinity of otnAB, which are transcribed in the opposite direction and required for the formation of the O139 capsule (4).

In conclusion, we here identify seven genes required for G4C formation by EPEC O127. We recently found that all the tested EPEC serotypes, including O111, O119, O142, and O55, and the closely related enterohemorrhagic E. coli serotype O157, form G4C and/or express Etk (reference 17 and unpublished data). This correlation suggests that G4C may play a role in the virulence of these closely related pathogens. We are now testing this hypothesis. G4C might also be involved in the virulence of Shigella strains containing intact G4C operons.

 
We thank S. Gottesman for the rcsA-expressing plasmid.

This work was supported by grants from the United States-Israel Binational Science Foundation, The Israel Science Foundation founded by The Israel Academy of Science and Humanities (grant 223/99-2), the European Union Fifth Framework Quality of Life Program (QLK2-2000-00600), and the Center of Study of Emerging Disease. I.R. is the Etta Rosensohn Professor in Bacteriology, and M.A.S. was a Lady Davis Visiting Professor, at The Hebrew University.

 
* Corresponding author. Mailing address: Department of Molecular Genetics and Biotechnology, Faculty of Medicine, The Hebrew University, POB 12272, Jerusalem 91120, Israel. Phone: 972 2 6758754. Fax: 972 2 6757308. E-mail: ilanro{at}cc.huji.ac.il.

Y. Shifrin and A. Peleg contributed equally to this study.

Top Abstract Introduction Materials and Methods Results Discussion References

 

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Journal of Bacteriology, August 2005, p. 5259-5266, Vol. 187, No. 15
0021-9193/05/$08.00+0     doi:10.1128/JB.187.15.5259-5266.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

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