Capsular and exopolysaccharides play crucial roles in the biology of many bacteria, acting either as virulence determinants that withstand host-cell defenses, or in establishing symbiotic relationships between bacteria and plants. More than 80 different capsular structures (known as K antigens) are produced by Escherichia coli isolates and these are subdivided into four different groups based on genetic and biochemical criteria (1). Surface polysaccharides with similar features are formed by other bacterial genera. The his-linked cps loci encode enzymes for the assembly of group 1 capsular K-antigens in E. coli and Klebsiella pneumoniae. The cps loci all contain a conserved region comprising the first 4 genes (orfX, wza, wzb, and wzc cps ) (2), indicating a shared role in CPS 1 expression. Following the conserved genes is a serotype-specific region encoding enzymes that participate in synthesis of polysaccharide repeat units and their polymerization via a Wzy-dependent mechanism (3). The Wzy-mediated polymerization reaction is thought to result in formation of an undecaprenyl pyrophosphate-linked glycan at the periplasmic face of the plasma membrane. The nascent polymer is then translocated to the cell surface via a process that requires outer membrane complexes formed by multimers of Wza cps (4). These complexes resemble the "secretins" for secretion of proteins via type II and type III systems.
The group 1 K30 antigen from Escherichia coli (O9a:K30) is present on the cell surface as both a capsular structure composed of high‐molecular‐weight K30 polysaccharide and as short K30 oligosaccharides linked to lipid A‐core in a lipopolysaccharide molecule (K30LPS). To determine the molecular processes that are responsible for the two forms of K antigen, the 16 kb chromosomal cps region has been characterized. This region encodes 12 gene products required for the synthesis, polymerization and translocation of the K30 antigen. The gene products include four glycosyltransferases responsible for synthesis of the K30 repeat unit; a PST(1) exporter (Wzx), required to transfer lipid‐linked K30 units across the plasma membrane to the periplasmic space; and a K30‐antigen polymerase (Wzy). These gene products are typical of those seen in O‐antigen biosynthesis gene clusters and they interact with the lipopolysaccharide translocation pathway to express K30LPS on the cell surface. The same gene products also provide the biosynthetic intermediates for the capsule assembly pathway, although they are not in themselves sufficient for synthesis of the K30 capsule. Three additional genes, wza, wzb and wzc, encode homologues to proteins that are encoded by gene clusters involved in expression of a variety of bacterial exopolysaccharides. Mutant analysis indicates that Wza and Wzc are required for wild‐type surface expression of the capsular structure but are not essential for polymerization and play no role in the translocation of K30LPS. These surface expression components provide the key feature that distinguishes the assembly systems for O antigens and capsules.
Surface expression of the group 1 K30 capsular polysaccharide of Escherichia coli strain E69 (O9a:K30) requires Wza(K30), a member of the outer membrane auxiliary (OMA) protein family. A mutation in wza(K30) severely restricts the formation of the K30 capsular structure on the cell surface, but does not interfere with the biosynthesis or polymerization of the K30 repeat unit. Here we show that Wza(K30) is a surface-exposed outer membrane lipoprotein. Wza(K30) multimers form ring-like structures in the outer membrane that are reminiscent of the secretins of type II and III protein translocation systems. We propose that Wza(K30) forms an outer membrane pore through which the K30-capsular antigen is translocated. This is the first evidence of a potential mechanism for translocation of high molecular weight polysaccharide across the outer membrane. The broad distribution of the OMA protein family suggests a similar process for polysaccharide export in diverse Gram-negative bacteria.
Protozoan parasites of the genus Leishmania are found as promastigotes in the sandfly vector and as amastigotes in mammalian macrophages. Mechanisms controlling stage-regulated gene expression in these organisms are poorly understood. Here, we applied a comprehensive approach consisting of protein prefractionation, global proteomics and targeted DNA microarray analysis to the study of stage differentiation in Leishmania. By excluding some abundant structural proteins and reducing complexity, we detected and identified numerous novel differentially expressed protein isoforms in L. infantum. Using 2-D gels, over 2200 protein isoforms were visualized in each developmental stage. Of these, 6.1% were strongly increased or appeared unique in the promastigote stage, while the relative amounts of 12.4% were increased in amastigotes. Amastigote-specific protein isoform and mRNA expression trends correlated modestly (53%), while no correlation was found for promastigote-specific spots. Even where direction of regulation was similar, fold-changes were more modest at the RNA than protein level. Many proteins were present in multiple spots, suggesting that PTM is extensive in this organism. In several cases, different isoforms appeared to be specific to different life stages. Our results suggest that post-transcriptional controls at translational and post-translational levels could play major roles in differentiation in Leishmania parasites.
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