Biosynthesis of the 09 Antigen of Escherichia coli. The Polysaccharide Component of E. coli 09: K29-

Extracellular polysaccharide biosynthesis in Cordyceps

Cordyceps is a parasitic edible fungus with a variety of metabolically active ingredients. The main active ingredient, extracellular polysaccharide (EPS), shows favourable application prospects in prevention and treatment of certain diseases. EPS extracted from different parts of various Cordyceps species can be used in health foods or medicinal preparations because of the structural diversity and multiple bioactivities. In terms of the complexity of composition and structure, researchers have speculated on the anabolic pathways of EPSs and the genes involved in the synthesis process. Studies to increase the yield of polysaccharides are limited because the synthesis pathways and anabolic regulation mechanisms of Cordyceps exopolysaccharide remain unknown. This review summarises the current researches in the yield of Cordyceps polysaccharides. A mechanism for the biosynthesis of Cordyceps polysaccharides was proposed by referring to the polysaccharide synthesis in other species. Furthermore, we also discuss the future perspective and ongoing challenges of EPS in uses of health foods and pharmaceutics.

Genetic basis for Rhizobium etli CE3 O-antigen O-methylated residues that vary according to growth conditions

The Rhizobium etli CE3 O antigen is a fixed-length heteropolymer with O methylation being the predominant type of sugar modification. There are two O-methylated residues that occur, on average, once per complete O antigen: a multiply O-methylated terminal fucose and 2-O methylation of a fucose residue within a repeating unit. The amount of the methylated terminal fucose decreases and the amount of 2-O-methylfucose increases when bacteria are grown in the presence of the host plant, Phaseolus vulgaris, or its seed exudates. Insertion mutagenesis was used to identify open reading frames required for the presence of these O-methylated residues. The presence of the methylated terminal fucose required genes wreA, wreB, wreC, wreD, and wreF, whereas 2-O methylation of internal fucoses required the methyltransferase domain of bifunctional gene wreM. Mutants lacking only the methylated terminal fucose, lacking only 2-O methylation, or lacking both the methylated terminal fucose and 2-O methylation exhibited no other lipopolysaccharide structural defects. Thus, neither of these decorations is required for normal O-antigen length, transport, or assembly into the final lipopolysaccharide. This is in contrast to certain enteric bacteria in which the absence of a terminal decoration severely affects O-antigen length and transport. R. etli mutants lacking only the methylated terminal fucose were not altered in symbiosis with host Phaseolus vulgaris, whereas mutants lacking only 2-O-methylfucose exhibited a delay in nodule development during symbiosis. These results support previous conclusions that the methylated terminal fucose is dispensable for symbiosis, whereas 2-O methylation of internal fucoses somehow facilitates early events in symbiosis.

The C-terminal domain of the nucleotide-binding domain protein Wzt determines substrate specificity in the ATP-binding cassette transporter for the lipopolysaccharide O-antigens in Escherichia coli serotypes O8 and O9a

The polymannan O-antigenic polysaccharides (O-PSs) of Escherichia coli O8 and O9a are synthesized via an ATP-binding cassette (ABC) transporter-dependent pathway. The group 2 capsular polysaccharides of E. coli serve as prototypes for polysaccharide synthesis and export via this pathway. Here, we show that there are some fundamental differences between the ABC transporter-dependent pathway for O-PS biosynthesis and the capsular polysaccharide paradigm. In the capsule system, mutants lacking the ABC transporter are viable, and membranes isolated from these strains are no longer able to synthesize polymer using an endogenous acceptor. In contrast, E. coli strains carrying mutations in the membrane component (Wzm) and/or the nucleotide-binding component (Wzt) of the O8 and O9a polymannan transporters are nonviable under conditions permissive to O-PS biosynthesis and take on an aberrant elongated cell morphology. Whereas the ABC transporters for capsular polysaccharides with different structures are functionally interchangeable, the O8 and O9a exporters are specific for their cognate polymannan substrates. The E. coli O8 and O9a Wzt proteins contain a C-terminal domain not present in the corresponding nucleotide-binding protein (KpsT) from the capsule exporter. Whereas the Wzm components are functionally interchangeable, albeit with reduced efficiency, the Wzt components are not, indicating a specific role for Wzt in substrate specificity. Chimeric Wzt proteins were constructed in order to localize the region involved in substrate specificity to the C-terminal domain.

Synthesis of the heteropolysaccharide O antigen of Escherichia coli O52 requires an ABC transporter: structural and genetic evidence

The structural and genetic organization of the Escherichia coli O52 O antigen was studied. As identified by sugar and methylation analysis and nuclear magnetic resonance spectroscopy, the O antigen of E. coli O52 has a partially O-acetylated disaccharide repeating unit (O unit) containing D-fucofuranose and 6-deoxy-D-manno-heptopyranose, as well as a minor 6-deoxy-3-O-methylhexose (most likely, 3-O-methylfucose). The O-antigen gene cluster of E. coli O52, which is located between the galF and gnd genes, was found to contain putative genes for the synthesis of the O-antigen constituents, sugar transferase genes, and ABC-2 transporter genes. Further analysis confirmed that O52 employs an ATP-binding cassette (ABC) transporter-dependent pathway for translocation and polymerization of the O unit. This is the first report of an ABC transporter being involved in translocation of a heteropolysaccharide O antigen in E. coli. Genes specific for E. coli O52 were also identified.

Production of monoclonal antibody discriminating serological difference in Escherichia coli O9 and O9a polysaccharides

A monoclonal antibody (mAb) with a unique antigenic specificity against Escherichia coli O9 was produced. The O9a mAb was reactive with a part of the strains in E. coli O9. The O9a mAb did not react with LPS from the E. coli O9 test strain Bi316-42. The distribution of the antigen defined by the O9a mAb in E. coli O9 was consistent with that of E. coli O9a present in E. coli O9 strains. The chemical structure of the repeating unit of the O-specific polysaccharide detected by the mAb was demonstrated to be a mannotetraose by two-dimensional nuclear magnetic resonance spectroscopy. It was confirmed that the mAb recognized E. coli O9a serotype in E. coli O9 serotype strains, suggesting that E. coli O9a serotype might be a dominant strain in E. coli O9.

A Wzz (Cld) protein determines the chain length of K lipopolysaccharide in Escherichia coli O8 and O9 strains

The modal distribution of O-antigen chain length is determined by the Wzz (Cld/Rol) protein in those cases in which it has been studied. The system of O-antigen synthesis in Escherichia coli serotypes O8 and O9 is different from that reported for most other bacteria, and chain length distribution is thought not to be determined by a Wzz protein. We report the existence in E. coli O8 and O9 strains of wzz genes which are very similar to and have sequences within the range of variation of those which determine the chain length of typical O antigens. We also find that wzz genes previously identified by their effect on O-antigen chain length, when cloned and transferred to O8 and O9 strains, affect the chain length of a capsule-related form of LPS, K(LPS). We conclude that in at least some O8 and O9 strains there is a wzz gene which controls the chain length of K(LPS) but has no effect on the O8 or O9 antigen.

Expression of the O9 polysaccharide of Escherichia coli: sequencing of the E. coli O9 rfb gene cluster, characterization of mannosyl transferases, and evidence for an ATP-binding cassette transport system

The rfb gene cluster of Escherichia coli O9 directs the synthesis of the O9-specific polysaccharide which has the structure -->2-alpha-Man-(1-->2)-alpha-Man-(1-->2)-alpha-Man-(1-->3)-alpha- Man-(1-->. The E. coli O9 rfb cluster has been sequenced, and six genes, in addition to the previously described rfbK and rfbM, were identified. They correspond to six open reading frames (ORFs) encoding polypeptides of 261, 431, 708, 815, 381, and 274 amino acids. They are all transcribed in the counter direction to those of the his operon. No gene was found between rfb and his. A higher G+C content indicated that E. coli O9 rfb evolved independently of the rfb clusters from other E. coli strains and from Shigella and Salmonella spp. Deletion mutagenesis, in combination with analysis of the in vitro synthesis of the O9 mannan in membranes isolated from the mutants, showed that three genes (termed mtfA, -B, and -C, encoding polypeptides of 815, 381, and 274 amino acids, respectively) directed alpha-mannosyl transferases. MtfC (from ORF274), the first mannosyl transferase, transfers a mannose to the endogenous acceptor. It critically depended on a functional rfe gene (which directs the synthesis of the endogenous acceptor) and initiates the growth of the polysaccharide chain. MtfB (from ORF381) then transfers two mannoses into the 3 position of the previous mannose, and MtfA (from ORF815) transfers three mannoses into the 2 position. Further chain growth needs only the two transferases MtfA and MtfB. Thus, there are fewer transferases needed than the number of sugars in the repeating unit. Analysis of the predicted amino acid sequence of the ORF261 and ORF431 proteins indicated that they function as components of an ATP-binding cassette transport system. A possible correlation between the mechanism of polymerization and mode of membrane translocation of the products is discussed.

Involvement of the galactosyl-1-phosphate transferase encoded by the Salmonella enterica rfbP gene in O-antigen subunit processing

rfbT of Salmonella enterica LT2 was previously thought, together with rfaL, to be involved in the ligation of polymerized O antigen to core-lipid A, and three mutants were known. We report the mapping of the mutations to rfbP, the galactosyl-1-phosphate transferase gene, which is now shown to encode a bifunctional protein. The mutations which have the former rfbT phenotype are referred to as rfbP(T). We also show that rfbP(T) mutants are not blocked in the ligation step as previously believed but in an earlier step, possibly in flipping the O-antigen subunit on undecaprenyl pyrophosphate from the cytoplasmic to periplasmic face of the cytoplasmic membrane.

Biosynthesis of the Escherichia coli K5 polysaccharide, a representative of group II capsular polysaccharides: polymerization in vitro and characterization of the product

Biosynthesis of the capsular K5 polysaccharide of Escherichia coli, which has the structure 4)-beta GlcA-1,4-alpha GlcNAc-(1, was studied with membrane preparations from an E. coli K5 wild-type strain and from a recombinant K-12 strain expressing the K5 capsule. Polymerization occurs at the inner face of the cytoplasmic membrane without the participation of lipid-linked oligosaccharides. The serological K5 specificity of the in vitro product was determined with a K5-specific monoclonal antibody in an antigen-binding assay. The K5 polysaccharide, as obtained from the membranes after an in vitro incubation, has 2-keto-3-deoxyoctulosonic acid as the reducing sugar, which indicates that the polysaccharide grows by chain elongation at the nonreducing end.

Fine structure of A and M antigens from Brucella biovars

Brucella A and M epitopes were found on single O-polysaccharide chains of all biotype strains of this species. Lipopolysaccharides from the type and reference strains of five of the six Brucella species, B. abortus, B. melitensis, B. suis, B. canis, and B. neotomae, were extracted and purified. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, in conjunction with silver staining and immunoblotting developed by monoclonal antibodies, showed bands characteristic of A, M, or mixed A and M antigens. The A antigen previously described as an exclusively alpha 1,2-linked homopolymer of 4,6-dideoxy-4-formamido-D-mannopyranose was shown by 1H and 13C nuclear magnetic resonance spectroscopy to possess a fine structure consistent with the low-frequency occurrence of alpha 1, 3-linked 4,6-dideoxy-4-formamido-D-mannopyranose residues. This feature was previously attributed only to the M antigen, which is also a homopolymer of the same sugar. B. melitensis biotype 3 and B. suis biotype 4 lipopolysaccharides showed characteristics of mixed A and M antigens. Immunoabsorption of these O polysaccharides on a column of immobilized A-antigen-specific monoclonal antibody enriched polymer chains with A-antigen characteristics but did not eliminate M epitopes. Composite A- and M-antigen characteristics resulted from O polysaccharides in which the frequency of alpha 1,3 linkages, and hence, M-antigen characteristics, varied. All biotypes assigned as A+ M- expressed one or two alpha 1,3-linked residues per polysaccharide O chain. M antigens (M+ A-) also possessed a unique M epitope as well as a tetrasaccharide determinant common to A-antigen structures. B. canis and B. abortus 45/20, both rough strains, expressed low-molecular-weight A antigen.

Partial deletion of the cloned rfb gene of Escherichia coli O9 results in synthesis of a new O-antigenic lipopolysaccharide

The rfb gene, involved in the synthesis of the O-specific polysaccharide (a mannose homopolymer) of Escherichia coli O9 lipopolysaccharide (LPS), was cloned in E. coli K-12 strains. The O9-specific polysaccharide covalently linked to the R core of K-12 was extracted from the K-12 strains harboring the O9 rfb gene. All the other genes required for the synthesis of rfe-dependent LPS are therefore considered to be present in the K-12 strains. It was found that bacteria harboring some clones with deletions of the ca. 20-kilobase-pair (kbp) BglII-StuI fragment no longer synthesized the O9-specific polysaccharide. However, bacteria harboring clones del 21, del 22, and del 25, which carry deletions of the 10-kbp PstI-StuI fragment, synthesized an O-specific polysaccharide antigenically distinct from E. coli O9 LPS. Although this new O-specific polysaccharide consisted solely of mannose and the mannose residues were combined only through alpha-1,2 linkage, it was still composed of a repeating oligosaccharide unit, possibly a trisaccharide unit,----2)alpha Man-(1----2)alpha Man-(1----2)alpha Man-(1----. It is therefore likely that this new O-specific polysaccharide was derived from a part of the O9-specific polysaccharide----3)alpha Man-(1----3)alpha Man-(1----2)alpha Man-(1----2)alpha Man-(1----2)alpha Man-(1----and that the deleted part of the clones was responsible for the synthesis of alpha-1,3 linkages of the O9-specific polysaccharide.

Biosynthesis of the O9 antigen of Escherichia coli. Synthetic glycosyldiphosphomoraprenols as probes for requirement of mannose acceptors

Synthetic monosaccharide derivatives (alpha-glucosyl, beta-glucosyl, alpha-mannosyl) and disaccharide derivatives (alpha-mannosyl-1,2-alpha-glucosyl, alpha-mannosyl-1,3-alpha-glucosyl, alpha-mannosyl-1,4-alpha-glucosyl, alpha-mannosyl-1,6-alpha-glucosyl) of diphosphomoraprenol were used as putative mannose acceptors in the biosynthesis of Escherichia coli O9 antigen. Membranes of E. coli O9 derived from the rfe mutant F 1357 were reconstituted with these compounds and then incubated with different concentrations of GDP-[14C]mannose. Of the monosaccharide derivatives tested, only alpha-glucodiphosphomoraprenol was a mannose acceptor and the only disaccharide derivative which accepted mannose was alpha-mannosyl-1,3-alpha-glucosyldiphosphomoraprenol. The alpha-glucosyl derivative accepted only one mannose unit at 4 microM GDP-[14C]mannose, and above 50 microM GDP-[14C]mannose about 25% of the product had a minimum size of about 30 mannose units. The alpha-mannosyl-1,3-alpha-glucosyl derivative was only a mannose acceptor at a GDP-[14C]mannose concentration of 50 microM and higher, and the product had a minimum size of about 30 mannose units. The results are discussed with respect to requirement of mannose acceptors.

Role of lipid intermediate(s) in the synthesis of serogroup B Neisseria meningitidis capsular polysaccharide

Neisseria meningitidis serogroup B strain M986 was examined for the involvement of lipid intermediate(s) participating in the biosynthesis of the sialic acid capsular polysaccharide. The addition of exogenous undecaprenyl phosphate, phosphatidylethanolamine, or phosphatidylglycerol to particulate membranes, in the presence of cytidine 5'-monophosphosialic acid, resulted in the stimulation of sialyltransferase activity specifically by undecaprenyl phosphate. Sialyltransferase activity, after delipidation of particulate membrane proteins, was specifically reconstituted by undecaprenyl phosphate. After the addition of 14C-labeled cytidine 5'-monophosphosialic acid to particulate membranes, the level of labeled lipid intermediate(s), extracted by chloroform-methanol (2:1), increased up to a maximum level between 3.75 and 5.0 min, which subsequently decreased to a lower steady-state level. Pulse-chase experiments revealed a transient, solvent-extractable, lipid-linked component. The extracted N-acetylneuraminic acid was in polymeric form. Sequential oxidation and reduction of the extracted radioactivity followed by neuraminidase treatment revealed an average degree of polymerization of four or five N-acetylneuraminic acid residues. Bacitracin-sensitive peptidoglycan was synthesized in vitro by particulate membranes. Cross-competition experiments between peptidoglycan and capsular polysaccharide synthesis by preincubation of precursors of one pathway during synthesis of the other revealed a competitive effect for a common component. This component was believed to be a common pool of undecaprenyl phosphate. A model for the production and regulation of the capsular polysaccharide is proposed.

Biosynthesis of the 09 antigen of Escherichia coli. Core structure of rfe mutant as indication of assembly mechanism

The chemical structure of the outer (hexose) regions of the core oligosaccharide from Escherichia coli 09 with the complete R1 core, and from a R1-derived rfe mutant were analyzed using compositional analysis, methylation and gas chromatography/mass spectrometry. It was found that, in contrast to the branched outer region of the R1 core, the outer region of the core from the rfe mutant lacked terminal glucose and was linear. These results are in agreement with recent findings on the biosynthesis of the 09 antigen. They suggest a cotransfer of glucose with the 09-specific mannan to a 'pre-core' lacking terminal glucose, as the assembly (translocation) step in the 09 antigen synthesis. Thus it is suggested that the initiation of O-chain synthesis (by the formation of an acceptor glucolipid ) and the termination of core synthesis are closely correlated. In conjunction with previous biochemical data, the analytical results presented here indicate a novel core synthesis.

Glucosyldiphosphoundecaprenol, the mannose acceptor in the synthesis of the O9 antigen of Escherichia coli. Biosynthesis and characterization

We describe the biosynthesis in vitro of the mannose acceptor of the O9 mannan synthesis by Escherichia coli membranes and its analysis with chemical, enzymatic and physical means. Membranes from E. coli 1357 (O9:K29-:H-his,pmi,rfe) were incubated with 10 mM UDP-glucose and 20 mM magnesium chloride in large scale. The incubation mixtures were extracted with butan-1-ol and the extract was fractionated by ion-exchange chromatography on DEAE-cellulose. The presence of the mannose acceptor was detected in the column effluent by using aliquots of the fractions in membrane-reconstitution experiments. The purified mannose acceptor was hydrolyzed for 10 min in 0.1 M hydrochloric acid at 100 degrees C and the hydrolyzate was extracted with light petroleum. Mass spectrometric analysis of the material from the organic phase showed it to be undecaprenol. The aqueous phase contained phosphate and glucose (as determined with glucose oxidase peroxidase) in the ratio of 1.9, alpha-Galactosyldiphosphoundecaprenol and beta-glucosylphosphoundecaprenol were prepared for comparison in these experiments. The results obtained showed that the mannose acceptor in the synthesis of the O9 mannan of E. coli is alpha-glucosyldiphosphoundecaprenol.

Mechanism of O-specific polysaccharide biosynthesis in Salmonella serogroups C2 and C3

Cell envelope and soluble glycosyl transferase preparations from Salmonella newport (serogroup C2) and Salmonella kentucky (serogroup C3) were found to catalyze formation of polyprenyl pyrophosphate tetrasaccharides corresponding to the structure of the repeating unit of the main chain of O-specific polysaccharides. Plant polyprenyl phosphate may serve as an exogenous sugar acceptor. Galactose residue is an initiator of a chain growth: transfer of galactosyl phosphate from uridine diphosphate galactose onto the acceptor is followed by two consecutive mannosyl transfers from guanosine diphosphate mannose and rhamnosyl transfer thymidine diphosphate rhamnose. Uridine diphosphate glucose and polyprenyl phosphate are converted by the enzyme preparations into polyprenyl monophosphate glucose which may transfer a glucosyl residue onto the polyprenyl pyrophosphate oligosaccharides. The resulting pentasaccharide derivatives may be polymerised by enzymes present in cell envelope preparations. The significance of these results for the understanding of the mechanism of O-specific polysaccharide biosynthesis is discussed.

Demonstration by membrane reconstitution of a butanol-soluble intermediate in the biosynthesis of the O9 antigen of Escherichia coli

The activity in vitro of the mannan-synthesizing system of Escherichia coli O9 depends on the presence of glucose in the growth medium of the bacteria. Inactive membranes of E. coli strain F988 grown without gain mannan-synthesizing activity by reconstitution with a butanol extract obtained from the same bacteria grown with glucose. Inactive membranes could also be restored to biosynthetic activity by incubation with UDP-glucose in the presence of magnesium chloride. In this magnesium-ion-dependent reaction, a glucolipid was formed which was extractable with butanol. It could be used for the reconstitution of inactive membranes. The products of incubations with GDP-mannose of reconstituted and active membranes were analysed for electrophoretic mobility in sodium dodecylsulfate/polyacrylamide gel electrophoresis, molecular weight and composition. In all cases they proved to be the mannan attached to a hydrophobic mannose carrier, presumably a glucolipid. These results suggest that a glucolipid is the intermediary mannose acceptor in the biosynthesis of the O9 antigen.

Citrobacter O-antigens: structure of the O-antigenic polysaccharide from Citrobacter sp. 396

The structure of the O-specific polysaccharide moiety of the lipopolysaccharide from Citrobacter 396 was elucidated by composition, methylation, and periodate oxidation studies. The repeating unit consists of four 2-linked mannoses and one 3-linked N-acetylglucosamine. One of the mannose units is substituted at C3 with alpha-glucose, and one is substituted at C3 with alpha-(2-O-acetyl)-abequose. All the mannosyl linkages appear to have the beta-configuration; the N-acetylglucosaminyl linkage has the alpha-configuration. In bacterial agglutination and passive hemagglutination in some Salmonella antisera, Citrobacter 396 as well as its O-antigenic lipopolysaccharide expressed the serological factors 5 and 6. In corroboration of our structural studies, this showed the presence of alpha-(2-O-acetyl)-abequosyl-1,3-mannose (factor 5) and alpha-glucosyl-1,3-mannose (factor 6).

Presence of rfe genes in Escherichia coli: their participation in biosynthesis of O antigen and enterobacterial common antigen

In Salmonella, ilv-linked rfe genes participate in the biosynthesis of the enterobacterial common antigen (CA) as well as of certain types of O antigen (serogroups C1 and L). rff genes, probably in the same cluster with rfe, are required for CA synthesis (P.H. Mäkelä et al., in preparation). Several Escherichia coli strains were studied to determine whether they also have rfe-rff genes that are involved in the synthesis of O antigen and CA, or of CA only. In a first approach, E, coli K-12 F-prime factors carrying the genes ilv and argH or argE and presumably rfe-rff genes were introduced into CA-negative Salmonella mutants that are blocked in CA synthesis because of mutated rfe or rff genes. All resulting ilv+ hybrids were CA positive. In recipients with group C1-derived rfb genes, the synthesis of O6,7-specific antigen was also restored. This result shows that E. coli K-12 has rfe and rff genes providing the functions required in the synthesis of CA and Salmonella 6,7-specific polysaccharide. By introduction of defective rfe regions from suitable Salmonella donors into E. coli O8, 09, and O100 strains, the synthesis of CA as well as of the O-specific polysaccharides was blocked. This indicates that in the E. coli strains tested the rfe genes are involved in the synthesis of both O antigen and CA. This suggestion was confirmed by the finding of E. coli rough mutants that had simultaneously become CA negative. In transduction experiments it could be shown that the appearance of the rough and CA- phenotype was due to a defect in the ilv-linked rfe region.

The O9 antigen of Escherichia coli. Structure of the polysaccharide chain

The lipopolysaccharide from Escherichia coli O9:K30- was isolated in about 2% yield with aqueous 45% phenol at 65 degrees C, followed by ultracentrifugation. The polysaccharide moiety was obtained by graded hydrolysis and gel permeation chromatography. It consisted of a mannan which carried on its reducing end the core oligosaccharide of the R1 type. The mannan contained 1 leads to 2 and 1 leads to 3 linkages in a ratio of 3:2, as determined by methylation analysis and mass spectrometry. On periodate oxidation, 58% of the mannose residues were destroyed. Degradation of oligosaccharide mixtures with alpha-mannosidase from jack bean meal, as well as a specific rotation of [alpha]25D = +89 degrees indicated that all mannosyl linkages have the alpha-configuration. Smith degradation resulted in the liberation of mannosyl (1 leads to 3)-mannose (bound to glyceraldehyde), as established by methylation analysis. From these results we conclude that the O9 polysaccharide of E. coli has a pentasaccharide repeating unit of alpha-mannosyl(1 leads to 3)-alpha-mannosyl-(1 leads to 2)-alpha-mannosyl-(1 leads to 2)-alpha-mannosyl-(1 leads to 2)-mannose, which are joined in the polysaccharide through alpha-(1 leads to 3)-mannosyl linkages.