Sialic acids are structurally unique nine-carbon keto sugars occupying the interface between the host and commensal or pathogenic microorganisms. An important function of host sialic acid is to regulate innate immunity, and microbes have evolved various strategies for subverting this process by decorating their surfaces with sialylated oligosaccharides that mimic those of the host. These subversive strategies include a de novo synthetic pathway and at least two truncated pathways that depend on scavenging host-derived intermediates. A fourth strategy involves modification of sialidases so that instead of transferring sialic acid to water (hydrolysis), a second active site is created for binding alternative acceptors. Sialic acids also are excellent sources of carbon, nitrogen, energy, and precursors of cell wall biosynthesis. The catabolic strategies for exploiting host sialic acids as nutritional sources are as diverse as the biosynthetic mechanisms, including examples of horizontal gene transfer and multiple transport systems. Finally, as compounds coating the surfaces of virtually every vertebrate cell, sialic acids provide information about the host environment that, at least in Escherichia coli, is interpreted by the global regulator encoded by nanR. In addition to regulating the catabolism of sialic acids through the nan operon, NanR controls at least two other operons of unknown function and appears to participate in the regulation of type 1 fimbrial phase variation. Sialic acid is, therefore, a host molecule to be copied (molecular mimicry), eaten (nutrition), and interpreted (cell signaling) by diverse metabolic machinery in all major groups of mammalian pathogens and commensals
Escherichia coli K-12 and K-12 hybrid strains constructed to express a polysialic acid capsule, the Kl antigen, were able to efficiently use sialic acid as a sole carbon source. This ability was dependent on induction of at least two activities: a sialic acid-specific transport activity, and an aldolase activity specific for cleaving sialic acids. Induction over basal levels required sialic acid as the apparent inducer, and induction of both activities was repressed by glucose. Induction also required the intracellular accumulation of sialic acid, which could be either added exogenously to the medium or accumulated intraceliularly through biosynthesis. Exogenous sialic acid appeared to be transported by an active mechanism that did not involve covalent modification of the sugar. Mutations affecting either the transport or degradation of sialic acid prevented its use as a carbon source and have been designated nanT and nanA, respectively. These mutations were located by transduction near min 69 on theE. coli K-12 genetic map, between argG and glnF. In addition to being unable to use sialic acid as a carbon source, aldolase-negative mutants were growth-inhibited by this sugar. Therefore, the intracellularly accumulated sialic acid was toxic in aldolase-deficient E. coli strains. The dual role of aldolase in dissimilating and detoxifying sialic acids is consistent with the apparent multiple controls on expression of this enzyme.
The kps gene cluster of Escherichia coli K1 encodes functions for sialic acid synthesis, activation, polymerization, and possibly translocation qf polymer to the cell surface. The size and complexity of this membrane polysaccharide biosynthetic cluster have hindered genetic mapping and functional descriptions of the kps genes. To begin a detailed investigation of the polysialic acid synthetic mechanism, acapsular mutants were characterized to determine their probable defects in polymer synthesis. The mutants were tested for complementation with kps fragments subcloned from two separately isolated, functionally intact kps gene clusters. Complementation was assayed by immunological and biochemical methods and by sensitivity to the Kl-specific bacteriophage K1F. The kps cluster consisted of a central 5.8-kilobase region that contained at least two genes coding for sialic acid synthetic enzymes, a gene encoding the sialic acid-activating enzyme, and a gene encoding the sialic acid polymerase. This biosynthetic region is flanked on one side by an approximately 2.8-kilobase region that contains a potential regulatory locus and at least one structural gene for a polypeptide that appears to function in polysialic acid assembly. Flanking the biosynthetic region on the opposite side is a 6-to 8.4-kilobase region that codes for at least three proteins which may also function in polymer assembly and possibly in translocating polymer to the outer cell surface. Results of transduction crosses supported these conclusions and indicated that some of the kps genes flanking the central biosynthetic region may not function directly in transporting polymer to the cell surface. The results also demonstrate that the map position and probable function of most of the kps cluster genes have been identified.The polysialic acid capsule of Escherichia coli K1 is an unbranched homopolymer of 200 sialic acid residues in a-2,8-ketosidic linkage (19). Molecules with more than three ao-2,8-linked internal sialic acid residues are rare in nature and, until recently, only were known in E. coli K1 and Neisseria meningitidis group B (26). Poly-x-2,8-sialic acid chains similar to the K1 antigen are now known to be widely distributed on the vertebrate cell adhesion molecule NCAM (20, 31). The rarity of sialic acids in bacteria and the association of polysialic acid capsules with virulence suggested that the bacterial polysaccharide may mimic polysialic acid moieties on mammalian host glycoconjugates (5). Repeated failures to develop effective vaccines for the a-2,8-linked capsule may thus be due to immune tolerance in the host (5). Through a better understanding of the genetics and biochemistry of capsule biosynthesis, it may be possible to develop alternative therapeutic approaches for treating infections caused by polysialic acid-encapsulated bacteria.Polysialic acid synthesis in E. coli K1 has been one of the best-characterized capsular polysaccharide biosynthetic systems. The broad outlines of polysialic acid synthesis are understood at a biochemi...
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