Enzymatic formation of uridine diphosphate N-acetyl-D-mannosaminuronic acid

Enterobacterial Common Antigen: Synthesis and Function of an Enigmatic Molecule

The outer membrane (OM) of Gram-negative bacteria poses a barrier to antibiotic entry due to its high impermeability. Thus, there is an urgent need to study the function and biogenesis of the OM. In Enterobacterales, an order of bacteria with many pathogenic members, one of the components of the OM is enterobacterial common antigen (ECA). We have known of the presence of ECA on the cell surface of Enterobacterales for many years, but its properties have only more recently begun to be unraveled. ECA is a carbohydrate antigen built of repeating units of three amino sugars, the structure of which is conserved throughout Enterobacterales. There are three forms of ECA, two of which (ECAPG and ECALPS) are located on the cell surface, while one (ECACYC) is located in the periplasm. Awareness of the importance of ECA has increased due to studies of its function that show it plays a vital role in bacterial physiology and interaction with the environment. Here, we review the discovery of ECA, the pathways for the biosynthesis of ECA, and the interactions of its various forms. In addition, we consider the role of ECA in the host immune response, as well as its potential roles in host-pathogen interaction. Furthermore, we explore recent work that offers insights into the cellular function of ECA. This review provides a glimpse of the biological significance of this enigmatic molecule.

Construction and characterization of an acapsular mutant of Mannheimia haemolytica A1

The nmaA and nmaB genes, which code for UDP-GlcNAc-2-epimerase and UDP-ManNAc-dehydrogenase, respectively, are involved in capsular polysaccharide biosynthesis in Mannheimia haemolytica A1. A chloramphenicol resistance (Cm(r)) cassette cloned behind an M. haemolytica A1 promoter, plpcat, was created and used to interrupt nmaA and nmaB. A 1.3-kbp DNA fragment that encompasses part of nmaA and nmaB was replaced by the 1.0-kbp plpcat, resulting in a knockout mutant which is Cm(r) and unable to synthesize N-acetylmannosamine (ManNAc) and N-acetylmannosaminuronic acid (ManNAcA). The DNA replacement was confirmed by Southern hybridization and PCR analyses of the nmaA and nmaB loci. Electron microscopy examination of the mutant showed the absence of capsular materials compared to the parent strain. The loss of NmaA and NmaB activity was confirmed by analysis of carbohydrate moieties using capillary electrophoresis. Serum sensitivity assays indicated that the acapsular mutant is as resistant as the encapsulated parent to complement-mediated killing by colostrum-deprived calf serum but is more sensitive to killing by immune bovine serum. Analysis of lipopolysaccharide prepared from the acapsular mutant and encapsulated parent confirmed that these strains have long O-polysaccharide chains, possibly conferring resistance to serum-mediated killing.

Staphylococcus aureus cap5O and cap5P genes functionally complement mutations affecting enterobacterial common-antigen biosynthesis in Escherichia coli

The Staphylococcus aureus cap5P and cap5O genes of the type 5 capsule biosynthetic locus restore enterobacterial common-antigen expression to Escherichia coli mutants defective in rffE and rffD gene expression, respectively. Cap5P and Cap5O likely function as UDP-GlcNAc 2-epimerase and UDP-ManNAc dehydrogenase enzymes, respectively, in the synthesis of the capsule precursor UDP-ManNAcA.

A plasmid-encoded rfbO:54 gene cluster is required for biosynthesis of the O:54 antigen in Salmonella enterica serovar Borreze

Previous studies demonstrated that the presence of a 7-8 kb plasmid is correlated with expression of the lipopolysaccharide (LPS) O:54 antigen in several Salmonella enterica serovars. In this study, a 6.7 kb plasmid from a field isolate of S. enterica serovar Borreze was shown to encode enzymes responsible for the synthesis of the O:54 polysaccharide. Curing the plasmid results in simultaneous loss of smooth O-polysaccharide-substituted LPS molecules and O:54 serotype. SDS-PAGE analysis of other O:54 isolates indicated that the O:54 O-polysaccharide can be co-expressed with an additional O-polysaccharide, likely encoded by chromosomal genes. The structure of the O:54 polysaccharide was determined by a combination of chemical and nuclear magnetic resonance (NMR) methods and was found to be an unusual homopolymer of N-acetylmannosamine (D-ManNAc) residues. The polysaccharide contained a disaccharide repeating unit with the structure:-->4)-beta-D-ManpNAc-(1-->3)-beta-D-ManpNAc-(1--> This structure does not resemble other O-polysaccharides in S. enterica. To examine the role played by plasmid functions in synthesis of the O:54 polysaccharide, the 6.7 kb plasmid was cloned to produce a hybrid plasmid (pWQ800) in pGEM-7Zf(+). In Escherichia coli K-12 delta rfb, pWQ800 directed the synthesis of authentic O:54 polysaccharide. Polymerized O:54 polysaccharide was also produced in S. enterica serovar Typhimurium rfb and rfc mutants. From these data, we conclude that pWQ800 carries the rfbO:54 gene cluster and synthesis of the O:54 polysaccharides does not require host chromosomal rfb functions. However, synthesis of the O:54 polysaccharide requires the function of the rfe and rffE genes which are part of the gene cluster encoding enzymes involved in biosynthesis of enterobacterial common antigen. The rffE gene product synthesizes the O:54 precursor, uridine diphospho-N-acetylmannosamine. This is the first description of a plasmid-encoded rfb gene cluster in Salmonella.

Biosynthetic elongation of isolated teichuronic acid polymers via glucosyl- and N-acetylmannosaminuronosyltransferases from solubilized cytoplasmic membrane fragments of Micrococcus luteus

Cytoplasmic membrane fragments of Micrococcus luteus catalyze in vitro biosynthesis of teichuronic acid from uridine diphosphate D-glucose (UDP-glucose), uridine diphosphate N-acetyl-D-mannosaminuronic acid (UDP-ManNAcA), and uridine diphosphate N-acetyl-D-glucosamine. Membrane fragments solubilized with Thesit (dodecyl alcohol polyoxyethylene ether) can utilize UDP-glucose and UDP-ManNAcA to effect elongation of teichuronic acid isolated from native cell walls. When UDP-glucose is the only substrate supplied, the detergent-solubilized glucosyltransferase incorporates a single glucosyl residue onto each teichuronic acid acceptor. When both UDP-glucose and UDP-ManNAcA are supplied, the glucosyltransferase and the N-acetylmannosaminuronosyltransferase act cooperatively to elongate the teichuronic acid acceptor by multiple additions of the disaccharide repeat unit. As shown by polyacrylamide gel electrophoresis, low-molecular-weight fractions of teichuronic acid are converted to higher-molecular-weight polymers by the addition of as many as 17 disaccharide repeat units.

Localization of enterobacterial common antigen immunoreactivity in the ribosomal cytoplasm of Escherichia coli cells cryosubstituted and embedded at low temperature

The application of two on-section immunogold labeling techniques, the Lowicryl K4M (progressive lowering of temperature) procedure and the cryosection technique of Tokuyasu, in a previous work to study the topology of enterobacterial common antigen (ECA) biosynthesis revealed the presence of label on the outer membrane and in areas associated with the inner side of the cytoplasmic membrane. However, labeling was also observed in the ribosomal cytoplasm. The question of whether the cytoplasmic label was a result of ECA displacement during the more slowly acting aldehyde fixation or whether cytoplasmic ECA precursors are true constituents of the ribosomal cytoplasm could not be resolved from these results. In the study described here, cells of the same Escherichia coli F470 strain were reinvestigated by comparison of the progressive lowering of temperature and improved cryosubstitution-low-temperature embedment techniques. The latter procedure, applied directly to nonpretreated and noncentrifuged cells, led to superior ultrastructural preservation of the cytoplasmic organization, with little opportunity for cytoplasmic antigen displacement after the primary cryofixation step; the label distribution obtained supports the conclusion that N-acetylmannosaminuronic acid (ManNAcA)-containing ECA precursors are real constituents of the ribosomal cytoplasm. Results from tunicamycin inhibition studies of ECA biogenesis in the E. coli mutant 2465 suggested that even the ECA precursor UDP-ManNAcA alone or a chemically unidentified product(s) generated from accumulated ManNAcA residues may react with the monoclonal antibody used, leading to weak but clearly positive cytoplasmic labeling. The relatively intense labeling obtained with cells grown in the absence of the drug can be explained by the reactivity of further ManNAcA-containing ECA precursors with the monoclonal antibody used.

ECA, the enterobacterial common antigen

Enterobacterial common antigen (ECA) is a family-specific surface antigen shared by all members of the Enterobacteriaceae and is restricted to this family. It is found in freshly isolated wild-type strains as well as in laboratory strains like Escherichia coli K-12. The family specificity of ECA can be used for taxonomic and diagnostic purposes. ECA is located in the outer leaflet of the outer membrane. It is a glycophospholipid built up by an aminosugar heteropolymer linked to an L-glycerophosphatidyl residue. In a few rough mutants, in addition, the sugar chain can be bound to the complete lipopolysaccharide (LPS) core. Recently, for Shigella sonnei a lipid-free cyclic form of ECA was reported. The genetical determination of ECA is closely related to that of lipopolysaccharide. For biosynthesis of ECA and LPS partly the same sugar precursors and the same carrier lipid is used.

Accumulation of a lipid-linked intermediate involved in enterobacterial common antigen synthesis in Salmonella typhimurium mutants lacking dTDP-glucose pyrophosphorylase

The heteropolysaccharide chains of enterobacterial common antigen (ECA) are composed of linear trisaccharide repeat units having the structure----3)-alpha-Fuc4NAc-(1----4)-beta-D-ManNAcA-(1---- 4)-alpha-D-GlcNAc- (1----. Mutants of Salmonella typhimurium lacking the structural gene for dTDP-glucose pyrophosphorylase (rfbA) are severely impaired in their ability to synthesize dTDP-glucose, which is a precursor of dTDP-4-acetamido-4,6-dideoxy-D-galactose (Fuc4NAc), the donor of Fuc4NAc residues for ECA synthesis. These mutants synthesize only trace amounts of ECA, and they are hypersensitive to sodium dodecyl sulfate (SDS). Incubation of delta rfbA mutants with [3H]N-acetylglucosamine ([3H]GlcNAc) resulted in the accumulation of radioactivity in N-acetyl-D-mannosaminuronic acid (ManNAcA)-GlcNAc-pyrophosphorylundecaprenol (lipid II), the putative acceptor of Fuc4NAc residues in ECA synthesis. Lipid II did not accumulate in either wild-type cells or in rff mutants unable to synthesize ManNAcA. Both the accumulation of lipid II and the synthesis of trace amounts of ECA were abolished when delta rfbA mutants were grown in the presence of the antibiotic tunicamycin. Tunicamycin also prevented the SDS-mediated lysis of the mutants. SDS-resistant derivatives of delta rfbA mutants were isolated that were no longer able to synthesize trace amounts of ECA. Characterization of these derivatives revealed that they were defective in various steps of ECA synthesis leading to the synthesis of lipid II. The data support the conclusion that accumulation of lipid II is responsible in some way for the hypersensitivity of delta rfbA mutants to SDS.

Characterization of an Escherichia coli rff mutant defective in transfer of N-acetylmannosaminuronic acid (ManNAcA) from UDP-ManNAcA to a lipid-linked intermediate involved in enterobacterial common antigen synthesis

The rff genes of Salmonella typhimurium include structural genes for enzymes involved in the conversion of UDP N-acetyl-D-glucosamine (UDP-GlcNAc) to UDP N-acetyl-D-mannosaminuronic acid (UDP-ManNAcA), the donor of ManNAcA residues in enterobacterial common antigen (ECA) synthesis. An rff mutation (rff-726) of Escherichia coli has been described (U. Meier and H. Mayer, J. Bacteriol. 163:756-762, 1985) that abolished ECA synthesis but which did not affect the synthesis of UDP-ManNAcA or any other components of ECA. The nature of the enzymatic defect resulting from the rff-726 lesion was investigated in the present study. The in vitro synthesis of GlcNAc-pyrophosphorylundecaprenol (lipid I), an early intermediate in ECA synthesis, was demonstrated by using membranes prepared from a mutant of E. coli possessing the rff-726 lesion. However, in vitro synthesis of the next lipid-linked intermediate in the biosynthetic sequence, ManNAcA-GlcNAc-pyrophosphorylundecaprenol (lipid II), was severely impaired. Transduction of wild-type rff genes into the mutant restored the ability to synthesize both lipid II and ECA as determined by in vitro assay and Western blot (immunoblot) analyses done with anti-ECA monoclonal antibody, respectively. Our results are consistent with the conclusion that the rff-726 mutation is located in the structural gene for the transferase that catalyzes the transfer of ManNAcA from UDP-ManNAcA to lipid I.

Biosynthesis of enterobacterial common antigen

Cultures of Salmonella typhimurium pulse-labeled with N-acetyl-D-[3H]glucosamine ([3H]GlcNAc) incorporated isotope into a GlcNAc-linked lipid that was tentatively identified as GlcNAc-pyrophosphorylundecaprenol. The incorporation of [3H]GlcNAc into this compound was abolished when cells were pulse-labeled in the presence of the antibiotic tunicamycin. Tunicamycin also abolished the in vivo synthesis of the haptenic form of enterobacterial common antigen (ECA) in S. typhimurium as determined by the passive hemagglutination test. These data indicated that the synthesis of the GlcNAc-linked lipid is related to ECA synthesis. Support for this conclusion was provided by the following observations. Cultures of Escherichia coli and S. typhimurium incorporated [3H]GlcNAc into cell envelope components that migrated as a homologous series of polymers when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The [3H]GlcNAc-labeled polymers were not detected in mutants of E. coli and S. typhimurium defective in ECA synthesis due to lesions in either the rfe or rff gene clusters. These polymers were identified as ECA based on Western blot analyses employing anti-ECA monoclonal antibody. The incorporation of [3H]GlcNAc into ECA polymers was abolished by tunicamycin when the drug was added to cultures to give a minimum concentration of 3 micrograms/ml. In addition, pulse-chase experiments provided evidence for a precursor-product relationship between the GlcNAc-linked lipid and ECA. These results strongly suggest that the GlcNAc-linked lipid is involved in the biosynthesis of ECA in a manner analogous to the role of carrier lipid in the biosynthesis of O-antigen and peptidoglycan.

Biosynthesis of N-acetylmannosaminuronic-acid-containing cell-wall polysaccharide of Bacillus subtilis

The particulate enzyme from Bacillus subtilis AHU 1031 catalyzed the synthesis of a polysaccharide and glycolipids from UDP-N-acetylmannosaminuronic acid (UDP-ManNAcUA), UDP-N-acetylglucosamine (UDP-GlcNAc), and UDP-glucose (UDP-Glc). The polysaccharide synthesis required UDP-ManNAcUA and UDP-GlcNAc, proceeded optimally at pH 8.5 and in the presence of 5 mM MgCl2 and 2.5 mM dithiothreitol, and was stimulated by the addition of UDP-Glc. The molar ratio of ManNAcUA, GlcNAc, and Glc incorporated into polysaccharide was calculated to be 1:1:1.8 from chemical analysis involving reduction with water soluble carbodiimide; its relative molecular mass was estimated to be 12000. The analysis of Smith degradation products revealed that the polysaccharide backbone is composed of repeating trisaccharide units comprising ManNAcUA, GlcNAc, and Glc. Based on the data regarding the time course of the incorporation of glucose into the polysaccharide, extra glucose seems to be attached to the polysaccharide backbone as lateral branches. The saccharide moieties of the glycolipids were identified as GlcNAc, ManNAcUA-GlcNAc, and Glc-ManNAcUA-GlcNAc from several analytical criteria. The addition of antibiotic 24010, a tunicamycin-like antibiotic, at 10 micrograms/ml resulted in almost complete inhibition of the synthesis of glycolipids and polysaccharide. It is therefore concluded that the glycolipids function as intermediates in polysaccharide formation. Incubation of the ManNAcUA-GlcNAc-linked lipid. (labeled in the ManNAcUA moiety) with the particulate enzyme and UDP-Glc resulted incorporation of radioactivity into a trisaccharide-linked lipid and a polysaccharide. These results suggest that the particulate enzyme utilizes the trisaccharide moiety of the Glc-ManNAcUA-GlcNAc-linked lipid for the elongation of the main polysaccharide chain presumed to be cell wall acidic polysaccharide of this strain.

Elongation of teichuronic acid chains by a wall-membrane preparation from Micrococcus luteus

A wall-plus-membrane preparation from Micrococcus luteus catalyzes the incorporation of [14C]glucose from UDP-[14C]glucose, into two fractions of teichuronic acid, which is the cell wall polysaccharide consisting of alternating residues of glucose and N-acetylmannosaminuronic acid (ManNAcUA). Membrane-associated teichuronic acid was extracted from the wall-membrane fraction of reaction mixtures by sodium dodecyl sulfate. The synthesis of membrane-associated teichuronic acid required UDP-glucose, UDP-ManNAcUA, and UDP-N-acetylglucosamine and was inhibited by tunicamycin. Glucose incorporated into wall-bound teichuronic acid remained in wall fragments after extraction with sodium dodecyl sulfate, and its incorporation required UDP-glucose and UDP-ManNAcUA (but not UDP-N-acetylglucosamine) and was insensitive to tunicamycin. Radioactive material incorporated into wall-bound teichuronic acid could be released by treatment with mild acid or by digestion with lysozyme, indicating that the wall-bound teichuronic acid was covalently linked to peptidoglycan. There were about 600 pmol of wall-bound teichuronic acid acceptor sites for glucose per mg of protein as measured in incorporation reaction mixtures lacking UDP-ManNAcUA. In the presence of both UDP-glucose and UDP-ManNAcUA, elongation of teichuronic acid acceptor sites occurred, with the addition of six to eight disaccharide units to each acceptor site.

Structural and immunological studies of the Escherichia coli K7 (K56) capsular polysaccharide

The structure of the Escherichia coli K7 capsular polysaccharide has been investigated by a combination of chemical and spectroscopic methods. The Structure of the repeating unit of the polymer was found to be goes to 3)-beta-D-ManNAcA-(1 leads to 4)-beta-D-Glc-(1 goes to ; the O-6 atom of the D-glucosyl residue in the repeating unit is acetylated. The K7 polysaccharide is cross-reactive with the Streptococcus pneumoniae type 3 polysaccharide, the structure of which had previously been determined; our n.m.r. studies of the S. pneumoniae type 3 polysaccharide are in accord with this structure. The E. coli K7 and K56 capsular antigens have been shown by serology and 13C-n.m.r. spectroscopy to be identical.

Teichoic and teichuronic acids: biosynthesis, assembly, and location

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