Isolation from Klebsiella and characterization of two rcs genes that activate colanic acid capsular biosynthesis in Escherichia coli

Two genes, designated rcsA (regulation of capsule synthesis) and rcsB, that had been cloned from the chromosome of Klebsiella aerogenes (K. pneumoniae) capsular serotype K21 were capable of activating expression of colanic acid capsular polysaccharide in Escherichia coli K12. The Klebsiella rcsA gene encoded a polypeptide of 23 kDa that was required for the induction of a mucoid phenotype at less than or equal to 30 degrees C but not at greater than or equal to 37 C. The Klebsiella rcsB locus encoded no apparent polypeptides and was not capable by itself of causing the overproduction of colanic acid. However, when present in the same cell with rcsA, either in cis or in trans, rcsB caused expression of mucoidy in E. coli at all growth temperatures. These findings are best explained if the Klebsiella rcsA gene product acts as a positive regulator of colanic acid biosynthesis in E. coli and that activity of this protein is in turn subject to regulation by Lon protease. The Klebsiella rcsB locus may exert its effect by preferentially binding a negative regulator of capsular biosynthesis, possibly Lon itself. DNA sequences homologous to the Klebsiella K21b rcsA and rcsB genes were found in the genomes of all other capsular serotypes of klebsiellae examined, including K2, K12, K36 and K43. However, there was no homology between such genes and the chromosome of E. coli. The ability of these rcs genes to induce a mucoid phenotype explains the apparent conjugative transfer from klebsiellae to E. coli of the ability to produce K21 or other Klebsiella capsular polysaccharides that are structurally and antigenically related to colanic acid.     

Coexpression of colanic acid and serotype-specific capsular polysaccharides in Escherichia coli strains with group II K antigens.

In Escherichia coli K-12, the rcsA and rcsB gene products are positive regulators in expression of the slime polysaccharide colanic acid. We have previously demonstrated the presence of rcsA sequences in E. coli K1 and K5, strains with group II capsular K antigens, and shown that introduction of multicopy rcsA into these strains results in the expression of colanic acid. We report here the presence of rcsB sequences in E. coli K1 and K5 and demonstrate that RcsB also plays a role in the biosynthesis of colanic acid in strains with group II K antigens. In E. coli K1 and K5 grown at 37 degrees C, multicopy rcsB and the resulting induction of colanic acid synthesis had no significant effect on synthesis of the group II K antigens. K-antigen-specific sugar transferase activities were not significantly different in the presence or absence of multicopy rcsB, and introduction of a cps mutation to eliminate colanic acid biosynthesis in a K1-derivative strain did not influence the activity of the polysialyltransferase enzyme responsible for synthesis of the K1 polymer. Furthermore, immunoelectron microscopy showed no detectable difference in the size or distribution of the group II K-antigen capsular layer in cells which produced colanic acid. Colanic acid expression therefore does not appear to significantly affect synthesis of the group II K-antigen capsule and, unlike for group I K antigens, expression of group II K antigens is not positively regulated by the rcs system.     

Characterization of rcsB and rcsC from Escherichia coli O9:K30:H12 and examination of the role of the rcs regulatory system in expression of group I capsular polysaccharides.

In Escherichia coli K-12, RcsC and RcsB are thought to act as the sensor and effector components, respectively, of a two-component regulatory system which regulates expression of the slime polysaccharide colanic acid (V. Stout and S. Gottesman, J. Bacteriol. 172:659-669, 1990). Here, we report the cloning and DNA sequence of a 4.3-kb region containing rcsC and rcsB from E. coli O9:K30:H12. This strain does not produce colanic acid but does synthesize a K30 (group I) capsular polysaccharide. The rcsB gene from E. coli K30 (rcsBK30) is identical to the rcsB gene from E. coli K-12 (rcsBK-12). rcsCK30 has 16 nucleotide changes, resulting in six amino acid changes in the predicted protein. To examine the function of the rcs regulatory system in expression of the K30 capsular polysaccharide, chromosomal insertion mutations were constructed in E. coli O9:K30:H12 to independently inactivate rcsBK30 and the auxiliary positive regulator rcsAK30. Strains with these mutations maintained wild-type levels of K30 capsular polysaccharide expression and still produced a K30 capsule, indicating that the rcs system is not essential for expression of low levels of the group I capsular polysaccharide in lon+ E. coli K30. However, K30 synthesis is increased by introduction of a multicopy plasmid carrying rcsBK30. K30 polysaccharide expression is also markedly elevated in an rcsBK30-dependent fashion by a mutation in rcsCK30, suggesting that the rcs system is involved in high levels of synthesis. To determine whether the involvement of the rcs system in E. coli K30 expression is typical of group I (K antigen) capsules, multicopy rcsBK30 was introduced into 22 additional strains with structurally different group I capsules. All showed an increase in mucoid phenotype, and the polysaccharides produced in the presence and absence of multicopy rcsBK30 were examined. It is has been suggested that E. coli strains with group I capsules can be subdivided based on K antigen structure. For the first time, we show that strains with group I capsules can also be subdivided by the ability to produce colanic acid. Group IA contains capsular polysaccharides (including K30) with repeating-unit structures lacking amino sugars, and expression of group IA capsular polysaccharides is increased by multicopy rcsBK30. Group IB capsular polysaccharides all contain amino sugars. In group IB strains, multicopy rcsBK30 activates synthesis of colanic acid.     

Construction of a novel suicide vector: selection for Escherichia coli HB101 recombinants carrying the DNA insert.

We constructed a new type of cloning vector, pERISH2, that transforms Escherichia coli HB101 only when a foreign DNA fragment is ligated into the cloning site of the plasmid vector. Plasmid pERISH2 carries the rcsB gene which is derived from the chromosome of E. coli HB101 and is involved in the regulation of colanic acid production. When E. coli HB101 is transformed by this vector carrying the intact rcsB gene, the gene product RcsB blocks bacterial growth. However, if the rcsB gene is inactivated by the insertion of a foreign DNA fragment, this recombinant plasmid no longer inhibits the growth of E. coli HB101. Although E. coli HB101 is not stably transformed by pERISH2, E. coli K-12 strains such as JM109 and C600 can harbor this vector. Therefore, pERISH2 can be amplified in JM109 and be prepared from this strain in a large quantity using conventional methods. A chromosomal gene library of Klebsiella pneumoniae is constructed easily and efficiently by the utilization of this new cloning vector.     

Plasmid-mediated conjugative transfer of Klebsiella sp. rcs genesable to induce colanic acid capsular polysaccharide biosynthesis in Escherichia coli

Regulation of capsular biosynthesis (rcs) genes, encoding the ability to induce the production of a colanic acid polysaccharide capsule, were transferred to Escherichia coli by conjugation with Klebsiella pneumoniae (aerogenes) of capsular serotype K36. Transfer was mediated by a 58.4-MDa conjugative plasmid of incompatibility group IncM, which carried a copy of Tn7 (specifying resistance to trimethoprim and streptomycin) together with determinants for several further resistances. This plasmid did not carry the rcs genes itself, but mediated the conjugative recA-dependent transfer of part of the Klebsiella chromosome to E. coli. Once resident in E. coli, the rcs gene(s) could not be mobilised to other strains of E. coli, and the mobilising plasmid could be cured from capsulate transconjugants without loss of the ability to produce colanic acid. All such cured transconjugants contained an insertion of Tn7 in the chromosome, suggesting that the transposon might be involved in mobilisation of the rcs genes from Klebsiella sp. to E. coli. These findings explain previous observations that the ability to manufacture capsular polysaccharide could be transferred by plasmids between Klebsiella sp. and E. coli.     

Plasmid-mediated conjugative transfer of Klebsiella sp. rcs genes able to induce colanic acid capsular polysaccharide biosynthesis in Escherichia coli

Abstract Regulation of capsular biosynthesis ( rcs ) genes, encoding the ability to induce the production of a colanic acid polysaccharide capsule, were transferred to Escherichia coli by conjugation with Klebsiella pneumoniae (aerogenes) of capsular serotype K36. Transfer was mediated by a 58.4-MDa conjugative plasmid of incompatibility group IncM, which carried a copy of Tn7 (specifying resistance to trimethoprim and streptomycin) together with determinants for several further resistances. This plasmid did not carry the rcs genes itself, but mediated the conjugative recA -dependent transfer of part of the Klebsiella chromosome to E. coli . Once resident in E. coli , the rcs gene(s) could not be mobilised to other strains of E. coli , and the mobilising plasmid could be cured from capsulate transconjugants without loss of the ability to produce colanic acid. All such cured transconjugants contained an insertion of Tn7 in the chromosome, suggesting that the transposon might be involved in mobilisation of the rcs genes from Klebsiella sp. to E. coli . These findings explain previous observations that the ability to manufacture capsular polysaccharide could be transferred by plasmids between Klebsiella sp. and E. coli .     

Constitutive expression of Pasteurella multocida toxin

Abstract The introduction of a plasmid containing skc (streptokinase-coding gene) fused with ompA signal sequence into Escherichia coli K-12 strains, rendered the bacteria mucoid. Measurement of the synthesis of β-galactosidase from a cps-lacZ fusion ( lacZ fusion to a gene necessary for capsule synthesis) showed that the mucoid phenotype was due to induction of the capsular polysaccharide colanic acid synthesis. The introduction of a plasmid carrying skc fused with malE (gene encoding maltose-binding protein) also induced cps-lacZ expression, but intracellular expression of streptokinase in E. coli did not. The cps expression by secretion of streptokinase was diminished to the basal level in a cps-lacZ strain carrying a rcsC mutation. These results show that the secretion of streptokinase in E. coli induces colanic acid synthesis through the RcsC-dependent pathway.     

functional analysis of conserved gene products involved in assembly of Escherichia coli capsules and exopolysaccharides: evidence for molecular recognition between Wza and Wzc for colanic acid biosynthesis

Group 1 capsular polysaccharides (CPSs) of Escherichia coli and some loosely cell-associated exopolysaccharides (EPSs), such as colanic acid, are assembled by a Wzy-dependent polymerization system. In this biosynthesis pathway, Wza, Wzb, and Wzc homologues are required for surface expression of wild-type CPS or EPS. Multimeric complexes of Wza in the outer membrane are believed to provide a channel for polymer export; Wzc is an inner membrane tyrosine autokinase and Wzb is its cognate phosphatase. This study was performed to determine whether the Wza, Wzb, and Wzc proteins for colanic acid expression in E. coli K-12 could function in the E. coli K30 prototype group 1 capsule system. When expressed together, colanic acid Wza, Wzb, and Wzc could complement a wza-wzb-wzc defect in E. coli K30, suggesting conservation in their collective function in Wzy-dependent CPS and EPS systems. Expressed individually, colanic acid Wza and Wzb could also function in K30 CPS expression. In contrast, the structural requirements for Wzc function were more stringent because colanic acid Wzc could restore translocation of K30 CPS to the cell surface only when expressed with its cognate Wza protein. Chimeric colanic acid-K30 Wzc proteins were constructed to further study this interaction. These proteins could restore K30 biosynthesis but were unable to couple synthesis to export. The chimeric protein comprising the periplasmic domain of colanic acid Wzc was functional for effective K30 CPS surface expression only when coexpressed with colanic acid Wza. These data highlight the importance of Wza-Wzc interactions in group 1 CPS assembly.     

Polysaccharides cellulose, poly-beta-1,6-n-acetyl-D-glucosamine, and colanic acid are required for optimal binding of Escherichia coli O157:H7 strains to alfalfa sprouts and K-12 strains to plastic but not for binding to epithelial cells

When Escherichia coli O157:H7 bacteria are added to alfalfa sprouts growing in water, the bacteria bind tightly to the sprouts. In contrast, laboratory K-12 strains of E. coli do not bind to sprouts under similar conditions. The roles of E. coli O157:H7 lipopolysaccharide (LPS), capsular polysaccharide, and exopolysaccharides in binding to sprouts were examined. An LPS mutant had no effect on the binding of the pathogenic strain. Cellulose synthase mutants showed a significant reduction in binding; colanic acid mutants were more severely reduced, and binding by poly-beta-1,6-N-acetylglucosamine (PGA) mutants was barely detectable. The addition of a plasmid carrying a cellulose synthase gene to K-12 strains allowed them to bind to sprouts. A plasmid carrying the Bps biosynthesis genes had only a marginal effect on the binding of K-12 bacteria. However, the introduction of the same plasmid allowed Sinorhizobium meliloti and a nonbinding mutant of Agrobacterium tumefaciens to bind to tomato root segments. These results suggest that although multiple redundant protein adhesins are involved in the binding of E. coli O157:H7 to sprouts, the polysaccharides required for binding are not redundant and each polysaccharide may play a distinct role. PGA, colanic acid, and cellulose were also required for biofilm formation by a K-12 strain on plastic, but not for the binding of E. coli O157:H7 to mammalian cells.     

Characterization of the RcsC→YojN→RcsB Phosphorelay Signaling Pathway Involved in Capsular Synthesis in Escherichia coli

Escherichia coli and other enteric microorganisms produce an extracellular polysaccharide capsule, called colanic acid, under certain environmental conditions. This capsular synthesis is regulated by the RcsC (sensor kinase)→YojN (phosphotransfer intermediate)→RcsB (response regulator) phosphorelay signal transduction under certain growth conditions. Nonetheless, little is known about signals that exaggerate the Rcs-system. To gain insight into signals that activate the Rcs-system, here we searched for genes that activate the Rcs-system, provided that those on a multicopy plasmid were introduced into E. coli. We identified several such genes, namely, rcsB, rcsA, djlA, lolA, and ompG. The DjlA, LolA, and OmpG proteins are particularly interesting in that they are all located on the cell surface, where the primary sensor RcsC histidine-kinase is localized. Implications of these findings are discussed with special reference to the mechanism by which RcsC perceives external signals.     

Characterization of the RcsC-->YojN-->RcsB phosphorelay signaling pathway involved in capsular synthesis in Escherichia coli.

Escherichia coli and other enteric microorganisms produce an extracellular polysaccharide capsule, called colanic acid, under certain environmental conditions. This capsular synthesis is regulated by the RcsC (sensor kinase)-->YojN (phosphotransfer intermediate)-->RcsB (response regulator) phosphorelay signal transduction under certain growth conditions. Nonetheless, little is known about signals that exaggerate the Rcs-system. To gain insight into signals that activate the Rcs-system, here we searched for genes that activate the Rcs-system, provided that those on a multicopy plasmid were introduced into E. coli. We identified several such genes, namely, rcsB, rcsA, djlA, lolA, and ompG. The DjlA, LolA, and OmpG proteins are particularly interesting in that they are all located on the cell surface, where the primary sensor RcsC histidine-kinase is localized. Implications of these findings are discussed with special reference to the mechanism by which RcsC perceives external signals.     

Activity of CMP-2-keto-3-deoxyoctulosonic acid synthetase in Escherichia coli strains expressing the capsular K5 polysaccharide implication for K5 polysaccharide biosynthesis.

The activity of the cytoplasmic CMP-2-keto-3-deoxyoctulosonic acid synthetase (CMP-KDO synthetase), which is low in Escherichia coli rough strains such as E. coli K-12 and in uncapsulated strains such as E. coli O111, was significantly elevated in encapsulated E. coli O10:K5 and O18:K5. This enzyme activity was even higher in an E. coli clone expressing the K5 capsule. This and the following findings suggest a correlation between elevated CMP-KDO synthetase activity and the biosynthesis of the capsular K5 polysaccharide. (i) Expression of the K5 polysaccharide and elevated CMP-KDO synthetase activity were observed with bacteria grown at 37 degrees C but not with cells grown at 20 degrees C or below. (ii) The recovery kinetics of capsule expression of intact bacteria, in vitro K5 polysaccharide-synthesizing activity of bacteria, and CMP-KDO synthetase activity of bacteria after temperature upshift from 18 to 37 degrees C were the same. (iii) Chemicals which inhibit capsule (polysaccharide) expression also inhibited the elevation of CMP-KDO synthetase activity. The chromosomal location of the gene responsible for the elevation of this enzyme activity was narrowed down to the distal segment of the transport region of the K5 expression genes.     

Escherichia coli Capsule Bacteriophages II. Morphology

The Escherichia coli capsule bacteriophages (K phages) described herein are specific for certain capsular strains of E. coli, all of them test strains for different E. coli K antigens. The phages are not adsorbed to the acapsular mutants of their host organisms nor to similar strains with serologically and chemically different capsular polysaccharides. Thirteen E. coli (and one Klebsiella) K phages were visualized in the electron microscope. Most viruses are similar to P22 and thus belong to Bradley group C; however, one each of group A (long, contractile tail) and group B (long, noncontractile tail) was also found. All K phages were seen to carry spikes but no tail fibers were detected. These results suggest that the structures responsible for the recognition of the thick (about 400 nm or more) capsular polysaccharide gels are located in these spikes.     

Regulation of capsular polysaccharide synthesis in Escherichia coli K-12: characterization of three regulatory genes.

The synthesis of the Escherichia coli capsular polysaccharide varies with growth medium, temperature of growth, and genetic background. lac fusions to genes necessary for capsule synthesis (cps) demonstrated that these genes are regulated negatively in vivo by the lon gene product. We have now isolated, characterized, and mapped mutations in three new regulatory genes (rcs, for regulator of capsule synthesis) that control expression of these same fusions. rcsA and rcsB are positive regulators of capsule synthesis. rcsA is located at min 43 on the E. coli map, whereas rcsB lies at 47 min. rcsC, a negative regulator of capsule synthesis, is located at min 47, close to rcsB. All three regulatory mutations are unlinked to either the structural genes cpsA-F or lon. Mutations in all three rcs genes are recessive to the wild type. We postulate that lon may regulate capsule synthesis indirectly, by regulating the availability of one of the positive regulators.