Detection of capsule and slime polysaccharide layers in two strains of Rhodopseudomonas capsulata

A capsule and slime were visualized electronmicroscopically in Rhodopseudomonas capsulata strain St. Louis (=ATCC 23782) and strain Sp 11 after pre-incubation of the cells in the homologous O/K antisera. The slime consists of loosely associated material surrounding the cell in irregular distribution. The capsule is directly adjacent to the cell wall and has a constant thickness of 75–85 nm in strain St. Louis and 30–40 nm in strain Sp 11. The capsule has a fibrillar fine-structure with radial orientation to the cell surface. In contrast to the slime, it is not removed from the cells by washing with saline.An acidic polysaccharide fraction was obtained from both strains by cetavlon fractionation of hot phenol-water extracts. The composition is strain-specific: the relative amounts of the common sugars found, i.e. rhamnose, galactose, glucose, glucosamine and galacturonic acid are different, the fraction from strain Sp 11 contains additionally fucose, 3-amino-3,6-dideoxygalactose, an unknown amino sugar and an unknown acidic component. Whether the polysaccharides of these fractions are in fact the slime or capsular substances remains to be established.     

Lipopolysaccharides of two strains of the phototrophic bacterium Rhodopseudomonas capsulata

The lipopolysaccharides of Rhodopseudomonas capsulata strains St. Louis (ATCC 23782) and Sp 11 both contain L-acofriose, rhamnose, glucose and glucosamine as the main sugar constituents. 2-Keto-3-deoxyoctonate and neuraminic acid were tentatively identified. The fatty acid spectrum found with both strains comprises 3-OH-C10 and C12:1 (ester-linked) and 3-oxo-C14 (amide-linked). Isolated lipid A from strain Sp 11 contains glucosamine, glucosamine-phosphate and the total of the fatty acids of the lipopolysaccharide. Methylation analysis of the degraded polysaccharide of this lipopolysaccharide shows L-acofriose in both terminal and 1 leads to 2 chain-linked positions in a 1:4 molar ratio. Rhamnose is exclusively chain-linked (1 leads to 2), glucose is both terminally and chain-linked (1 leads to 6) in a 1:1 molar ratio. The serological activity of the lipopolysaccharide of both the R. capsulata strains is low in antisera against living or heat-killed cells when tested by passive hemagglutination, Ouchterlony immunoprecipitation or gel-immunoelectrophoresis. No crossreaction was observed among the lipopolysaccharides of R. capsulata strains St. Louis, Sp 11 and 37b4 in immunoprecipitation. Lipopolysaccharide of strain Sp 11 was found to lack lethal toxicity in galactosamine-sensitized mice.     

The capsule and slime polysaccharides of the wild type and a phage resistant mutant ofRhodopseudomonas capsulata St. Louis

A rhamnose, galactose and pyruvic acid containing polysaccharide (capsule) together with the peptidoglycan was isolated fromRhodopseudomonas capsulata St. Louis as the insoluble sediment after sodium dodecyl sulfate extraction of cell envelope fractions. Treatment with pronase E separated the soluble polysaccharide from the insoluble peptidoglycan. After lysozyme-digestion, both the capsule polysaccharide and peptidoglycan were soluble.The capsule was also accumulated in the combined interphase/phenol-phase of hot phenol-water extracts of whole cells. Again, the capsule and peptidoglycan were sedimented together as long as no pronase E-treatment was performed. With the phage-resistant mutant (R. capsulata St. Louis RC1^-), no capsule polysaccharide was obtained in the combined interphase/phenol phase.An acidic polysaccharide (slime) different from the capsule in composition and serology was obtained by Cetavlon fractionation of hot phenol/water extracts of cells of both the wild-type and the mutant cells. It was shown to consist mainly of rhamnose, glucosamine and galacturonic acid.The use of O/K-antisera and of capsule polysaccharideantisera allowed a separate visualization of the capsule and slime layers.This paper is dedicated to Professor Hans G. Schoegel on the occasion of his 60th birthday     

Formation of Novel Polysaccharides by Bradyrhizobium japonicum Bacteroids in Soybean Nodules

Certain strains of Bradyrhizobium japonicum form a previously unknown polysaccharide in the root nodules of soybean plants (Glycine max (L.) Merr.). The polysaccharide accumulates inside of the symbiosome membrane—the plant-derived membrane enclosing the bacteroids. In older nodules (60 days after planting), the polysaccharide occupies most of the symbiosome volume and symbiosomes become enlarged so that there is little host cytoplasm in infected cells. The two different groups of B. japonicum which produce different types of polysaccharide in culture produce polysaccharides of similar composition in nodules. Polysaccharide formed by group I strains (e.g., USDA 5 and USDA 123) is composed of rhamnose, galactose, and 2-O-methylglucuronic acid, while polysaccharide formed by group II strains (e.g., USDA 31 and USDA 39) is composed of rhamnose and 4-O-methylglucuronic acid. That the polysaccharide is a bacterial product is indicated by its composition plus the fact that polysaccharide formation is independent of host genotype but is dependent on the bacterial genotype. Polysaccharide formation in nodules is common among strains in serogroups 123, 127, 129, and 31, with 27 of 39 strains (69%) testing positive. Polysaccharide formation in nodules is uncommon among other B. japonicum serogroups, with only 1 strain in 18 (6%) testing positive.     

Localization and Biological and Physicochemical Properties of the Cell Wall Lipopolysaccharide of Rhodopseudomonas capsulata

Electron micrographs of phenol-water-extracted lipopolysaccharide (LPS) of Rhodopseudomonas capsulata show filamentous and netlike aggregates. Treatment of the LPS with sodium deoxycholate resulted in a reversible splitting into subunits. The LPS represents a cell wall constituent with O-antigenic specificity. In passive hemagglutination tests, high titers were obtained when erythrocytes sensitized with untreated or heat-treated LPS were incubated with antisera obtained by immunization of rabbits with whole cells of R. capsulata. The alkali-treated LPS was not active in this test. Mouse lethality tests have shown that the LPS of R. capsulata is less toxic than LPS of Escherichia coli. Also, the X-ray protection efficacy and the phagocytic activity stimulation of LPS from R. capsulata in mice are small, as compared with LPS of E. coli. Incubation of living bacteria in saline (37 C) resulted in a solubilization of an LPS-protein-lipid complex from the outer layer of the cell wall. The isolated complex contained the components which were found in the LPS. In addition, 20% amino acids and a large amount of palmitic and stearic acids, which are typical phospholipid components, were present.     

The polysaccharide component of Pseudomonas pseudomallei slime

The polysaccharide component contained in the slime of the causative agent of melioidosis was obtained. This component was found to be a biopolymer, mainly of the carbohydrate nature, consisting of galactose, glucose, mannose, rhamnose and two unidentified carbohydrates. The slime polysaccharide component contained two thermostable and acid-resistant antigens. The action of alkali led to the loss of one of these antigens. Rabbit antisera to the preparations of the slime polysaccharide component with titers of 1:64 to 1:256, determined in the immunodiffusion test, were obtained. In the precipitation test the slime polysaccharide component reacted with antisera from sick experimental animals, thus confirming the suggestion of its secretion in the process of the development of melioidosis infection.     

Chemical analysis of and degradation studies on the cell wall lipopolysaccharide of Rhodopseudomonas capsulata

A lipopolysaccharide (LPS) has been isolated from the gram-negative photosynthetic bacterium Rhodopseudomonas capsulata. Chemical analysis revealed the presence of d-glucose, d-galactose, l-rhamnose, 3-O-methyl-l-rhamnose (l-acofriose), d-glucosamine, 2-keto-3-deoxyoctonate, and neuraminic acid. The LPS does not contain l-glycero-d-mannoheptose, a typical component of the LPS of enteric bacteria. Fatty acid analysis showed that, apart from lauric acid, two hydroxy fatty acids (hydroxycaproic and hydroxymyristic acids) are the main components. By hydrolysis in weak acid, the LPS has been separated into a polysaccharide part (degraded polysaccharide) and a lipid part (lipid A). Presumably the lipid A contains a glucosamine backbone. Whereas the OH-groups of glucosamine are esterified with lauric and hydroxycaproic acids, hydroxymyristic acid is linked to the amino group of the sugar. By separation of the degraded polysaccharide by gel filtration, a fraction has been isolated which inhibited hemagglutination in a system containing antiserum, obtained by immunization of rabbits with whole cells, and isolated LPS. This fraction, which includes the determinant group, contains the sugars glucose, rhamnose, and acofriose. A second fraction obtained in this way was found to be serologically inactive and is composed of glucose, galactose, neuraminic acid, and phosphate.     

Ultrastructure of the capsule of Klebsiella pneumoniae and slime of Enterobacter aerogenes revealed by freeze etching

Summary The capsule of Klebsiella pneumoniae type I and slime of Enterobacter aerogenes strain A3 (SL) was examined by electron microscopy using the freeze etch technique. The capsules of K. pneumoniae were found to be composed of several layers of polysaccharide 10 nm thick; while the polysaccharide slime of E. aerogenes strain A3 (SL) was found to be composed of a diffuse network of fibrils. This work represents the first effort to visualize the replica of the unfixed, partially hydrated bacterial capsule or slime in the electron microscope. The slime of E. aerogenes strain A3 (SL) which was purified, and then freeze etched, resembled the layered structure of the capsule of K. pneumoniae. It is suggested that the charge or dielectric constant of the slime polysaccharide polymers was altered during purification, thereby permitting the layering to occur.Paper presented at the Annual Meeting of the American Society for Microbiology, Philadelphia, Pa. (U.S.A.), 1972.     

Isolation and preliminary characterization of two forms of ribulose 1,5-bisphosphate carboxylase from Rhodopseudomonas capsulata.

The presence of two distinct forms of ribulose 1,5-bisphosphate carboxylase has been demonstrated in extracts of Rhodopseudomonas capsulata, similar to the form I (peak I) and form II (peak II) carboxylases previously described from R. sphaeroides (J. Gibson and F. R. Tabita, J. Biol. Chem 252:943-949, 1977). The two activities, separated by diethylaminoethyl-cellulose chromatography, were shown to be of different molecular size after assay on polyacrylamide gels. The higher-molecular-weight carboxylase from R. capsulata was designated form I-C, whereas the smaller enzyme was designated form II-C. Catalytic studies revealed significant differences between the two enzymes in response to pH and the effector 6-phosphogluconate. Immunological studies with antisera directed against the carboxylases from R. sphaeroides demonstrated antigenic differences between the two R. capsulata enzymes; cross-reactivity was observed only between R. sphaeroides anti-form II serum and the corresponding R. capsulata enzyme, form II-C.     

Bioactive polysaccharides from the stems of the Thai medicinal plant Acanthus ebracteatus: their chemical and physical features

Crude water-soluble polysaccharides were isolated from Acanthus ebracteatus by hot water extraction followed by ethanol precipitation after pre-treatment with 80% ethanol. The crude polysaccharides were separated into neutral and acidic polysaccharides by anion-exchange chromatography. The neutral polysaccharide (A1001) was rich in galactose, 3-O-methylgalactose and arabinose, whereas the acidic polysaccharide (A1002) consisted mainly of galacturonic acid along with rhamnose, arabinose and galactose as minor components indicating a pectin-type polysaccharide with rhamnogalacturonan type I (RG-1) backbone. 3-O-Methylgalactose is also present in the acidic fraction. Both neutral and acidic fractions showed potent effects on the complement system using pectic polysaccharide PM II from Plantago major as a positive control. A small amount of 3-O-methylgalactose present in the pectin seemed to be of importance for activity enhancement in addition to the amount of neutral sugar side chains attached to RG-1. The relationship between chemical structure and effect on the complement system of the isolated polysaccharides is considered in the light of these data. The presence of the rare monosaccharide 3-O-methylgalactose may indicate that this can be used as a chemotaxonomic marker. The traditional way of using this plant as a medical remedy appears to have a scientific basis.     

Isolation and Characterization of an Extracellular Polysaccharide from Physarum polycephalum

The myxomycetes are called slime molds because of the synthesis of copious amounts of extracellular material (slime) during parts of the life cycle. In Physarum polycephalum, small amounts of slime are produced during exponential growth of microplasmodia in shake flasks, but the amount of this slime increased 10- to 20-fold at 16 to 34 hr after microplasmodia were induced to form spherules by transferring them to salt solution. The slime obtained during both periods is the same; an acidic polysaccharide consisting of galactose, sulfate, and trace amounts of rhamnose. Analysis of the galactose-to-sulfate ratio gave a value of about 4 to 1. Infrared spectroscopy showed increased absorbance at 820 cm⁻¹ characteristic of C-O-S vibrations. Electrophoresis on polyacrylamide gel revealed that the material moved as a single band which stained with Alcian Blue and periodic acid Shiff reagent. However, fractionation of identical material on Dowex columns and electrophoresis on cellulose acetate showed the slime to be made up of three major fractions. The polysaccharide appeared as an extracellular capsule closely adhering to the walls of the spherules. It could be separated from the wall by vigorous shaking. The increased synthesis of slime during spherulation was not blocked by cycloheximide, suggesting that new enzyme synthesis was not necessary for its formation.     

Immunochemistry of the Cell Walls of Listeria monocytogenes

The antigenic specificity of Listeria monocytogenes types I, II, III, IVa, and IVb was studied by immunochemical techniques. Immunologically active carbohydrates of the various types were extracted from cell walls and were chemically analyzed. Types I and II contained predominantly glucosamine and rhamnose; type III, galactose, rhamnose, and glucosamine; and types IVa and IVb, glucose and galactose. Quantitative precipitin inhibition tests with purified monosaccharides indicated that the major antigenic determinant of types I and II is rhamnose. Precipitin reactions could not be detected with type III carbohydrate and homologous or heterologous antisera. The major determinants of types IVa and IVb were found to be galactose and glucose, respectively. As much as 87% inhibition of the quantitative precipitin test for types I and II was obtained with rhamnose, 72% for type IVa with galactose, and 72% for type IVb with glucose. The immunochemical basis for the antigenic specificity of L. monocytogenes types I, II, IVa, and IVb was further confirmed by using agar gel diffusion. Cross-reactions among the various type-specific carbohydrates and heterologous antisera were also studied. Type II carbohydrate was found to contain galactose and react with type IVa antisera. This reaction could be blocked by galactose. Type I carbohydrate did not contain galactose nor did it react with antiserum prepared from type IVa cells. Therefore, the somatic antigens of type I and type II L. monocytogenes, previously thought to be identical, appeared to differ. The dominant immuno-specific group in the cross-reaction between type IVb carbohydrate and type IVa antisera was found to be galactose. Type IVa absorbed antisera did not produce a significant cross-reaction with type IVb carbohydrate. The results obtained from this investigation indicate a lesser degree of antigenic relationship between type IVa and type IVb L. monocytogenes than was previously believed to exist.     

Immunochemical analysis of O-specific polysaccharides from the soil nitrogen-fixing bacteria Azospirillum brasilense

Immunochemical reactivity of O-specific polysaccharide and the monosaccharide composition of O-antigenic determinants of the lipopolysaccharide isolated from the type strain Sp7 of Azospirillum brasilense were studied. An original modification of the method of spectroturbidimetry for disperse biological systems and a nonstandard procedure for the preparation of monospecific antibodies against cell surface antigens were used. The polysaccharide fraction, which contained residues of galactose, rhamnose, and galacturonic acid, was able to bind about 50% of the antibodies raised against whole bacterial cells. Twelve immunodeterminant groups were shown to be present in its molecule. Galactose and, less effectively, rhamnose but not galacturonic acid inhibited the antigen-antibody reactions. It is concluded that the serotype of the strain studied is determined by galactose residues.     

薯蔓多糖的分离纯化和性质鉴定

以我国资源量巨大的薯蔓为原料, 采用中试设备, 利用水提醇沉法提取多糖。研究了活性炭脱色工艺, 经初步纯化获得薯蔓多糖(PSPV), 并研究了其理化性质。DEAE-纤维素柱对来自于二个季节的PSPV进行分离、纯化, 分别得到PSPVⅠ和PSPVⅡ、PSPVⅢ三个多糖组分, 高效凝胶过滤色谱法测定三个组分的分子量分别为6.278×104 D, 3.801×104 D和1.418×104 D, 气相色谱结合标样测定单糖组成。研究结果为充分高效利用薯蔓资源提供了理论依据。     

Composition of Pseudomonas aeruginosa slime

1. The slime produced by eight strains of Pseudomonas aeruginosa on a number of different media was demonstrated to be qualitatively the same. Small quantitative differences may be occasioned by differences in the extraction procedure, the growth medium or the strain of organism used. 2. The slime was shown to be predominantly polysaccharide with some nucleic acid material and a small amount of protein. 3. The hydrolysed polysaccharide fraction consists mainly of glucose with smaller amounts of mannose. This accounts for some 50-60% of the total slime. In addition, there is some 5% of hyaluronic acid. The nucleic acid material represents approx. 20% of the total weight, and is composed of both RNA and DNA. 4. Minor components are protein, rhamnose and glucosamine, the protein being less than 5% of the total. 5. Hyaluronic acid is produced in greater quantities from nutrient broth than from chemically defined media, and is more firmly attached to the cells than the other components.     

Biochemical and immunochemical properties of the cell surface of Renibacterium salmoninarum.

The biochemical composition of the cell envelope of Renibacterium salmoninarum was investigated in a total of 13 strains isolated from different salmonid fish species at various geographical locations of the United States, Canada, and Europe. A marked similarity with the type strain R. salmoninarum ATCC 33209 was found both in the peptidoglycan and the cell wall polysaccharide. The primary structure of the peptidoglycan was found to be consistent with lysine in the third position of the peptide subunit, a glycyl-alanine interpeptide bridge between lysine and D-alanine of adjacent peptide subunits, and a D-alanine amide substituent at the alpha-carboxyl group of D-glutamic acid in position 2 of the peptide subunit. The cell wall polysaccharide contained galactose as the major sugar component which was accompanied by rhamnose, N-acetylglucosamine, and N-acetylfucosamine. The polysaccharide amounted to more than 60% of the dry weight of the cell walls. It was found to be covalently linked to the peptidoglycan and was released by hot formamide treatment. On gel filtration chromatography the extracted polysaccharide behaved like a homogeneous polymeric compound. The purified cell wall polysaccharide showed antigenic activity with antiserum obtained by immunization of rabbits with heat-inactivated trypsinized cells of R. salmoninarum. Immunoblotting experiments with nontrypsinized cell walls and antisera raised against R. salmoninarum cells revealed that antigenic proteins were attached to the cell walls.     

Chemical Characterization of Polysaccharide from the Slime Layer of the Cyanobacterium Microcystis flos-aquae C3-40

Macromolecular material from the slime layer of the cyanobacterium Microcystis flos-aquae C3-40 was defined as material that adhered to cells during centrifugation in growth medium but was dislodged by washing with deionized water and retained within dialysis tubing with a molecular-weight cutoff of 3,500. At each step of this isolation procedure, the slime was observed microscopically. Cells in the centrifugal pellet were surrounded by large amounts of slime that excluded negative stain, whereas cells that had been washed with water lacked visible slime. Two independently isolated lots of slime contained no detectable protein (<1%, wt/wt) and consisted predominantly of anthrone-reacting polysaccharide. Sugars in a hydrolysate of slime polysaccharide were derivatized with trimethylsilylimidazole and examined by gas chromatography-mass spectrometry. The composition of the slime polysaccharide was 1.5% (wt/wt) galactose, 2.0% glucose, 3.0% xylose, 5.0% mannose, 5.5% rhamnose, and 83% galacturonic acid. This composition resembles that of the plant polysaccharide pectin, which was treated in parallel as a control. Consistent with earlier indications that M. flos-aquae slime preferentially binds certain cations, the ratio of Fe to Na in the dialyzed slime was 10⁴ times that in the growth medium. The composition of the slime is discussed with respect to possible mechanisms of cation binding in comparison with other cyanobacterial exopolysaccharides and pectin.     

Chemical and serological study of lipopolysaccharide isolated from Shigella flexneri 88-893 possessing a new type-antigen]

The O-specific polysaccharide chain which represents a new type-antigen in lipopolysaccharide (LPS) of Shigella flexneri 88-893 was investigated. The O-polysaccharide chain was found to be composed of repeating units comprising rhamnose, N-acetylglucosamine and glucose (3:1:2). In the passive hemolysis test, group-6 antiserum of S. flexneri exhibited a high hemolytic titer (50% hemolysis titer: 7,900) against sheep red blood cells (SRBC) sensitized with intact 893 LPS, but virtually no hemolytic activity against SRBC sensitized with alkali-treated 893 LPS. None of the type-specific antisera (I-VI), showed any significant hemolytic titer against SRBC sensitized with either intact or alkali-treated 893 LPS. Thus, 893 LPS contained both the group-6 antigen and a new type-antigen which is distinct from any known type-antigen of S. flexneri.     

Biosynthesis of the wall acidic polysaccharide in Bacillus cereus AHU 1356

Biosynthetic studies on an acidic polysaccharide, comprising galactose, rhamnose, N-acetylglucosamine and sn-glycerol 1-phosphate, were carried out with a membrane system obtained from Bacillus cereus AHU 1356. Incubation of the membranes with UDP-[14C]Gal, TDP-[14C]Rha and UDP-[14C]GlcNAc resulted in the formation of four or more labeled-sugar-linked lipids and a labeled polysaccharide. Data on structural analysis of the sugar moieties released from the glycolipids, together with results of enzymatic conversion of [14C]galactose-linked lipid and [14C]Rha-Gal-linked lipid to higher-oligosaccharide-linked lipids and polysaccharide, led to the conclusion that the acidic polysaccharide is probably synthesized through the following pathway: (sequence in text) The glycerophosphate residues seem to be derived from phosphatidylglycerol.     

Colocalization of discoidin-binding ligands with discoidin in developing Dictyostelium discoideum

The Dictyostelium discoideum lectins, discoidin I and discoidin II, and the endogenous ligands to which they bind were immunohistochemically localized in sections of this organism at successive stages of development. For these studies, an axenic strain, AX3, was grown in a macromolecule-depleted medium rather than on bacteria, which themselves contain discoidin-binding ligands. Discoidin I-binding sites (endogenous ligands) in sections of D. discoideum were concentrated in the slime coat around aggregates, whereas discoidin II-binding sites were observed in a vesicle-like distribution in prespore cells and also in spore coats. In contrast, discoidin II did not bind to the slime coat and discoidin I bound relatively poorly to prespore cells and spore coats. The distributions of the endogenous lectins themselves were the same in axenically grown cells as previously reported for cells raised on bacteria. Discoidin I was concentrated in the slime coat and around stalk cells, and discoidin II was prominent in and around prespore cells. The congruent localization of each lectin with its endogenous ligand suggests that discoidin I normally functions in association with glycoconjugates in the slime around aggregates, and discoidin II with the galactose-rich spore coat polysaccharide.