Structural investigation of Klebsiella serotype K10 capsular polysaccharide

The primary structure of Klebsiella serotype K10 capsular polysaccharide has been investigated using mainly the techniques of methylation, partial hydrolysis, and 1H and 13C NMR spectroscopy. The polysaccharide was found to consist of hexasaccharide repeating units having the following structure: (formula; see text)     

Studies of the primary structure of the capsular polysaccharide from Klebsiella serotype K15

The capsular polysaccharide of Klebsiella serotype K15 has been investigated mainly by methylation analysis, characterisation of the oligosaccharides obtained by partial acid hydrolysis, periodate oxidation, enzymic degradation, and 1H- and 13C-n.m.r. spectroscopy, and shown to have the hexasaccharide repeating-unit 1. The glycan does not contain any pyruvic acetal or O-acetyl substituents. (formula; see text)     

Escherichia coli capsule bacteriophages. VII. Bacteriophage 29-host capsular polysaccharide interactions.

Different interactions between particles of Escherichia coli capsule bacteriophage 29 and its receptor, the E. coli serotype 29 capsular polysaccharide have been studied. The inactivation of phage 29 (8 x 10(3) PFU/ml) by isolated host capsular glycan was found to be physiologically insignificant (50% inactivation dose equals 100 mug after 1 h at 37 C). No adsorption (less than 2 x 10(4) PFU/mug) of the viruses to K29 polysaccharide-coated erythroyctes (at 0 or 37 C) was observed either. The phage particles were, however, found to catalyze the hydrolysis of beta-D-glucosido-(1leads to 3)-D-glucuronic acid bonds (arrow) in the receptor polymer, leading, ultimately, to the formation of a mixture of K29 hexasaccharide (one repeating unit), dodecasaccharide, and octadecasaccharide: (see article). Testing derivatives of K29 polysaccharide, as well as 82 heterologous bacterial (mainly Enteriobactericeae) capsular glycans, the viral glycanase was found to be highly specific; in accordance with the host range of phage 29, only one enzymatic cross-reaction (with the Klebsiella K31 polysaccharide) was observed. These and previous results, as well as the electron optical findings of M. E. Bayer and H. Thurow (submitted for publication), are discussed in terms of a unifying mechanism of phage 29-host capsule interaction. We propose that the viruses penetrate the capsules by means of their spike-associated glycanase activity, which leads them along capsular polysaccharide strands to membrane-cell wall adhesions where ejection of the viral genomes occurs.     

Chromotropic character of bacterial acidic polysaccharides: Part III--Interaction of cationic dye pinacyanol chloride with Klebsiella K15 capsular polysaccharide

Interaction of cationic dye pinacyanol chloride with the acidic capsular polysaccharide isolated from Klebsiella serotype K15 has been investigated by spectral measurements. Klebsiella K15 polysaccharide consists of hexasaccharide repeating units containing one residue each of glucuronic acid and glucose, and four residues of galactose. Glucuronic acid acts as the potential anionic site and the biopolymer interacts with the dye cations. It induces metachromasy in the dye and a blue shift of about 100 nm is observed in the visible absorption spectrum of the dye. Spectral measurements have been carried out at different polymer/dye molar ratios. Stoichiometry of polymer and dye in the polyanion-dye compound (1:1) indicates that every potential anionic site of the polyanion is associated with the dye cation, and stacking conformation is thus suggested. Effect of different non-aqueous solvents in reversing metachromasy has also been studied. Interaction studies exhibit chromotropic character of the biopolymer.     

Characterisation of coliphage K30, a bacteriophage specific for Escherichia coli capsular serotype K30

Abstract Coliphage K30, a bacteriophage specific for strains bearing the Escherichia coli serotype K30 capsular polysaccharide, produced plaques surrounded by extensive haloes, a characteristic of phage which produce capsule depolymerase (glycanase) enzymes. Klebsiella K20, a strain producing a capsular polysaccharide chemically identical to that of E. coli K30, was not lysed by coliphage K30, although the bacteriophage encoded glycanase enzyme did degrade the K20 polysaccharide. Morphologically, coliphage K30 belonged to Bradley group C. The coliphage K30 particle comprised 20 structural polypeptides which varied from 9.5–136 kDa and genomic DNA of 38.7 ± 1.0 kb.     

Structural studies of the capsular polysaccharide of Klebsiella type 81.

The structure of the capsular polysaccharide from Klebsiella Type 81 has beeninvestigated. Methlylation analysis, uronic acid degradation, Smith degradation, andgraded acid hydrolysis were the principle methods used. Theanomeric nature of theglycosidic linkages was determined by characterization of fragments obtained from thevarious methods of degradation used. One of the L-rhamnosidic linkages was notpresent in any of these fragments, but is assumed to be an alpha-linkage from consideerationsof optical-rotation data. These studies show that they polysaccharide consits of thefollowing hexasaccharide repeating-unit: yield2)-alpha-L-Rhap-(1yields3)-alpha-L-Rhap-(1-yields4)-beta-D-GlcAP-(1-yields2)-alpha-L-Rhap-(1-yields3)-alpha-L-Rhap-(1-yields3)-beta-D-Galp-(1-yields.     

Chromotropic character of bacterial acidic polysaccharides: Part II--Induction of metachromasy in cationic dye pinacyanol chloride by Klebsiella K10 capsular polysaccharide

The acidic capsular polysaccharide isolated from Klebsiella K10 exhibited chromotropic character with respect to induction of metachromasy in the cationic dye pinacyanol chloride (1-ethyl-2-[3-(1-ethyl-2(1H)-quinolylidene)propenyl]quinolinium chloride). Klebsiella K10 polymer consists of hexasaccharide repeating units containing one residue of glucuronic acid along with other neutral sugars in each repeating unit. It induces a metachromatic blue shift in the visible absorption spectrum of the dye from 600 nm to 500 nm. The spectral changes have been studied during interaction of the dye cations with the polyanions at different polymer/dye molar ratios. The polyanion-dye compounds are formed with polymer/dye stoichiometry of 1:1, indicating formation of stacking conformation. The complete reversal of polymer-induced metachromasy has also been observed by the addition of ethanol and urea.     

Escherichia coli serotype-39 capsular polysaccharide: primary structure and depolymerisation by a bacteriophage-associated glycanase

The acidic capsular polysaccharide isolated from Escherichia coli O9:K39:H9 was investigated, using n.m.r. spectroscopy, methylation analysis, uronic acid degradation of the native and methylated polysaccharides, and bacteriophage-associated enzyme degradation. The structure of the repeating unit, which is shown below, is identical to that reported for Klebsiella serotype-61 capsular polysaccharide. (formula; see text)     

Monoclonal antibodies against the capsular K antigen of Escherichia coli (O9:K30(A):H12): characterisation and use in analysis of K antigen organisation on the cell surface

Monoclonal antibodies were produced against the capsular antigen of Escherichia coli serotype K(A)30, using a mouse hybridoma system. The antibodies also recognised the chemically identical capsular polysaccharide produced by Klebsiella K20. Chemical modification of the K30 polysaccharide indicated that the glucuronic acid residues found in the E. coli K30 capsular antigen were important in the epitope recognised by these antibodies. Use of the antibodies as molecular probes revealed the presence of two discrete forms of the K30 antigen. One form was comprised of high molecular weight polysaccharide, present as a surface capsular layer. The second form of the antigen was of low molecular weight and was associated with lipopolysaccharide fractions from cell surface polysaccharide extracts. Separation of lipopolysaccharide fractions using gel chromatography in the presence of detergent showed that the low molecular weight K-antigenic fraction comigrated with a lipopolysaccharide lipid A core fraction present in encapsulated E. coli K30 bacteria but absent in acapsular mutants.     

Structural investigation of Klebsiella serotype K36 polysaccharide

Klebsiella K36 capsular polysaccharide has been investigated by methylation, Smith-periodate oxidation and partial hydrolysis techniques. The structure was found to consist of a hexasaccharide repeating unit as shown. The anomeric configurations of the sugar were determined by ¹H and ¹³C n.m.r. spectroscopy on isolated oligomers obtained during the degradative studies and on the intact polysaccharide.     

Molecular cloning and characterization of chondroitin polymerase from Escherichia coli strain K4

Escherichia coli strain K4 produces the K4 antigen, a capsule polysaccharide consisting of a chondroitin backbone (GlcUA beta(1-3)-GalNAc beta(1-4))(n) to which beta-fructose is linked at position C-3 of the GlcUA residue. We molecularly cloned region 2 of the K4 capsular gene cluster essential for biosynthesis of the polysaccharide, and we further identified a gene encoding a bifunctional glycosyltransferase that polymerizes the chondroitin backbone. The enzyme, containing two conserved glycosyltransferase sites, showed 59 and 61% identity at the amino acid level to class 2 hyaluronan synthase and chondroitin synthase from Pasteurella multocida, respectively. The soluble enzyme expressed in a bacterial expression system transferred GalNAc and GlcUA residues alternately, and polymerized the chondroitin chain up to a molecular mass of 20 kDa when chondroitin sulfate hexasaccharide was used as an acceptor. The enzyme exhibited apparent K(m) values for UDP-GlcUA and UDP-GalNAc of 3.44 and 31.6 microm, respectively, and absolutely required acceptors of chondroitin sulfate polymers and oligosaccharides at least longer than a tetrasaccharide. In addition, chondroitin polymers and oligosaccharides and hyaluronan polymers and oligosaccharides served as acceptors for chondroitin polymerization, but dermatan sulfate and heparin did not. These results may lead to elucidation of the mechanism for chondroitin chain synthesis in both microorganisms and mammals.     

The structure of capsule polysaccharide of Klebsiella ozaenae K4 containing 3-deoxynonulosonic acid

3-Deoxy-D-glycero-D-galacto-nonulosonic acid was identified as a component of the Klebsiella ozaenae K4 capsular polysaccharide. On the basis of methylation, complete and partial acid hydrolyses, Smith degradation, and NMR analysis including computer-assisted 13C NMR evaluation, the following structure of the polysaccharide has been established.     

Use of a bacteriophage-encoded glycanase enzyme in the generation of lipopolysaccharide O side chain deficient mutants of Escherichia coli O9:K30 and Klebsiella O1:K20: role of O and K antigens in resistance to complement-mediated serum killing

Coliphage K30 lysates contain free and phage-associated forms of a bacteriophage-encoded capsule depolymerase (glycanase) enzyme, active against the serotype K30 capsular polysaccharide of Escherichia coli. The free glycanase has been purified to apparent homogeneity. The molecular weight of the enzyme was estimated at 450,000, and when heated in SDS at 100 degrees C, the enzyme dissociated into two subunits of 90,000 and 52,000. The glycanase enzyme was used as a reagent to reversibly degrade the capsular layers on cells of Escherichia coli O9:K30 and Klebsiella O1:K20. This treatment rendered these bacteria sensitive to their respective lipopolysaccharide-specific bacteriophages, coliphage O9-1 and Klebsiella phage O1-3. This novel approach facilitated isolation of lipopolysaccharide O antigen side chain deficient mutants which retained the ability to synthesize the capsule. The response of defined mutants, O+:K-, O-:K+, and O-:K-, to exposure to nonimmune rabbit serum was measured. Results showed that the primary barrier against complement-mediated serum killing in both Escherichia coli O9:K30 and Klebsiella O1:K20 was the O antigen side chains of the lipopolysaccharide molecules. In both strains, the capsule played no role in the determination of serum resistance.     

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.     

Ammonia enhanced dark respiration in Chlorella vulgaris is related to collapse of a transmembrane pH gradient

Abstract We obtained, by different methods, isogenic lipopolysaccharide (O antigen) and capsular polysaccharide (K antigen) mutants from Klebsiella pneumoniae strains able to induce experimental infections (cytitis and pyelonephritis) in rats. We compared the induction of experimental infections in rats by wild-type strains and the lipopolysaccharide and capsular polysaccharide mutants. The high-molecular mass lipopolysaccharide of K. pneumoniae is clearly implicated in the infection process of the rat urinary tract, whilst the capsular polysaccharide seems not to be involved to the same extent.     

Escherichia coli capsule bacteriophages. IV. Primary structure of the bacteriophage 29 receptor, the E. coli serotype 29 capsular polysaccharide.

Using periodate oxidation, methylation analysis, characterization of oligosaccharides by Smith degradation or partial acid hydrolysis, as well as proton magnetic resonance, the primary structure of the Escherichia coli serotype 29 capsular polysaccharide (the receptor of E. coli K phage 29) was reinvestigated. The polymer was found to consist of hexasaccharide repeating units of the following structure: (see article).     

Structure of the capsular polysaccharide of Klebsiella serotype K40

The capsular polysaccharide from Klebsiella Serotype K40 contains D-galactose, D-mannose, L-rhamnose, and D-glucuronic acid in the ratios of 4:1:1:1. Methylation analysis of the native and carboxyl-reduced polysaccharide provided information about the glycosidic linkages in the repeating unit. Degradation of the permethylated polymer with base established the identity of the sugar unit preceding the glycosyluronic acid residue. The modes of linkages of different sugar residues were further confirmed by Smith degradation and partial hydrolysis of the K40 polysaccharide. The anomeric configurations of the different sugar residues were determined by oxidation of the peracetylated native and carboxyl-reduced polysaccharide with chromium trioxide. Based on all of these results, the heptasaccharide structure 1 was assigned to the repeating unit of the K40 polysaccharide. (Formula: see text)     

The structure of the neuraminic acid-containing capsular polysaccharide of Escherichia coli serotype K9

The acidic capsular polysaccharide isolated from Escherichia coli O9:K9:H12 was investigated by using n.m.r. spectroscopy, methylation analysis, periodate oxidation, and bacteriophage-borne enzyme degradation. The polysaccharide, the structure of which is shown below, is the third E. coli capsular polysaccharide reported to contain neuraminic acid, the others being the K1 and K92 polysaccharides, and it is the first in the E. coli series shown to contain a 4-linked neuraminic acid unit.     

Structural studies on the capsular polysaccharide of Klebsiella serotype K40

The capsular polysaccharide of Klebsiella serotype K40 contained D-mannose, D-glucuronic acid, D-galactose, and L-rhamnose in the approximate molar ratios 1:1:1:2. The primary structure of the capsular polysaccharide has been investigated mainly by methylation analysis, periodate oxidation, characterization of oligosaccharides, base degradation reaction, and 1H and 13CNMR spectroscopy. The polysaccharide does not contain any pyruvic acetal or O-acetyl substitution. It has a pentasaccharide repeating unit of the following primary structure: alpha-D-Manp 1----4 ----4)-beta-D-GlcpA-(1----2)-alpha-L-Rhap-(1----3)-beta-D-Ga lp-(1----2)-alpha- L-Rhap-(1----.