Bacteriophage-typable revertants from pleiotropic staphylococcal mutants.

Cell walls were physically purified from bacteriophage-typable revertants that had been isolated from modified cell wall pleiotropic strains derived from Staphylococcus aureus NCTC 8511. The quantitative amino acid, amino sugar, and phosphorus contents of these cell walls are reported. Among the revertants were some whose walls possessed elevated serine and one strain whose walls contained the novel amino sugar galactosamine. The similarities in bacteriophage typing patterns between the revertants and the original parental strain lead to the conclusion that the previously described pleiotropic strains are mutants of NCTC 8511.     

Chemical composition of Streptococcus mutans cell walls and their susceptibility to Flavobacterium L-11 enzyme

The susceptibility to a cell wall lytic L-11 enzyme from Flavobacterium sp. and the quantitative and/or qualitative composition of the cell walls of some strains of cariogenic Streptococcus mutans and a non-cariogenic strain of Streptococcus mitis were determined. The purified cell walls of S. mutans strains HS-1 (serotype a), BHT (b), NCTC10449 (c), C67-1 (c), C67-25 (c), OMZ 176 (d), MT703 (e), MT557 (f), OMZ65 (g), and AHT (g), and S. mitis CHT contained glutamic acid, alanine, and lysine as well as muramic acid and glucosamine as a peptidoglycan component. Besides these amino acids, significant amounts of threonine were detected in strains HS-1, OMZ65, and AHT cell walls, and considerable amounts of aspartic acid and/or threonine as well as several other amino acids in OMZ176, OMZ65, and CHT cell walls. Rhamnose was a common special component of the cell walls of S. mutans strains BHT, NCTC10449, MT703, B2 (e), MT557, and AHT, and S. mitis CHT. An additional sugar component, glucose, was detected in the cell walls of all of these strains except BHT, and galactose was found in BHT, AHT, and CHT cell walls. Galactosamine was present in S. mitis CHT cell walls. Varying amounts of phosphorus were detected in the cell walls of all the strains examined. The cell walls of all these streptococcal strains except MT703, 6715, and AHT were susceptible to the lytic action of the L-11 enzyme to various extents. No consistent relationship was observed between the amino acid and sugar composition of these cell walls and their susceptibility to the L-11 enzyme. The chemical composition of these cell walls is discussed in terms of the serological classification of S. mutans.     

Cell wall constituents of Leuconostoc citrovorum and Leuconostoc mesenteroides

The cell wall constituents of Leuconostoc citrovorum 8082, L. mesenteroides 10830a, and L. mesenteroides 11449 have been ascertained. All three strains contained glycerol. Glucose and rhamnose were the major reducing sugar constituents. Alanine, glutamic acid, lysine, glucosamine, and muramic acid were the principal amino acids and amino sugars in all three strains. In addition, strain 10830a contained l-serine as a major cell wall component. Quantitative amino acid analyses indicate that glutamic acid, lysine, glucosamine, muramic acid, and serine may be present in the cell walls in equimolar amounts and that alanine is present in three to four times these quantities. The similarities and differences between the cell wall constituents of the leuconostocs and those of the lactobacilli and streptococci are discussed.     

Structure of the glucan-binding sugar chain of Tip1p, a cell wall protein of Saccharomyces cerevisiae

Tip1p is one of the major cell wall mannoproteins of Saccharomyces cerevisiae and is presumed to be synthesized as a glycosylphosphatidylinositol (GPI)-anchored form. We purified Tip1p from a glucanase extract of yeast cell walls and analyzed the sugar chain involved in the cell wall linkage. One mol of glucanase-extracted Tip1p contained 7.5 mol of glucose derived from glucan and 1 mol of ethanolamine, a component of the GPI anchor. One mol of the C-terminal peptide of Tip1p digested with Achromobacter protease I also contained 7.9 mol of glucose and 1 mol of ethanolamine. On the other hand, Tip1p contained no glucosamine, which is a component of the GPI anchor. The glucan-binding sugar chain of Tip1p was released by hydrazinolysis and isolated. This sugar chain contained ethanolamine with a free amino group and a glucose reducing end, but no mannose reducing end. Phosphodiesterase treatment eliminated the free amino group from this sugar chain, suggesting that a phosphodiester bond exists between the ethanolamine and the glucan remnant. These results indicate (1) the glucan-binding sugar chain of Tip1p is a GPI derivative, and (2) the GPI anchor is cleaved at the glycosyl moiety, and the resultant mannose reducing end is probably used to link Tip1p to cell wall glucan.     

Studies on the Cell Wall of Chlorella V. Comparison of the Cell Wall Chemical Compositions in Strains of Chlorella ellipsoidea

Cell walls of four strains of Chlorella ellipsoidea (IAM C-27,C-87, C-102 and C-183) were compared as to their chemical compositions.Many differences were found: (1) The sugar composition of alkali-soluble cell walls differedin quantity as well as quality with glucuronic acid being foundonly in C-27 and C-87. (2) In alkali-insoluble cell walls glucosamine was found onlyin C-27. The other three strains contained mainly glucose. (3) The amino acid compositions of the alkali-insoluble cellwalls markedly differed among the four strains. The cell wallof C-102 contained more amino acids than carbohydrates, butC-27 and C-87 contained extremely little amino acid. In addition to the variation in cell wall composition, the opticalanisotropy findings also differed for these cell walls of Chlorellastrains which had been grouped as the same species. (Received August 16, 1983; Accepted December 27, 1983)     

Cell wall composition of the aquatic fungusBlastocladiella emersonii

Cell walls fromBlastocladiella emersonii were isolated by repeated washing and centrifugation. Purity and uniformity of cell wall preparations were assessed by light and electron microscopy and chemical reproducibility. Electron microscopy showed the cell walls to consist of an inner microfibrillar network and an outer amorphous layer. Analyses by X-ray and infrared spectroscopy were consistent with chitin as the major wall component. Gross chemical analysis indicated that the cell walls were composed of 74.7% amino sugar (as anhydroN-acetylhexosamine), 10.7% neutral sugar (as anhydro hexose), 10.6% protein, and 4.2% lipid. Analysis of the neutral sugars showed that isolated cell walls contain 1.5% mannose, 3.0% galactose, and 3.0% glucose. Isolated cell walls were fractionated using a hot sodium dodecyl sulfate (SDS) extraction followed by either Pronase digestion or hot KOH extraction. The hot SDS extract was found to contain two polymer types, galactose- and/or glucose-containing polymers and glycoprotein. However, the residue from the hot SDS extraction still contained most of the neutral sugars and protein present in the isolated walls. Both Pronase digestion and the hot potassium hydroxide extraction removed all of the neutral sugars except glucose. The cell wall fractionation results indicate that the major wall component is microfibrillar chitin. The results further suggest that the SDS-solubilized glycoproteins and neutral sugar polymers may represent an outer amorphous layer.     

Elevated cell wall serine in pleiotropic staphylococcal mutants

Korman, Ruth Z. (Cornell University, Ithaca, N.Y.). Elevated cell wall serine in pleiotropic staphylococcal mutants. J. Bacteriol. 92:762-768. 1966.-Physically purified cell walls were prepared from two staphylococcal strains and from pleiotropic variants derived from them. The quantitative amino acid and amino sugar content of these walls is reported. The pleiotypes, which are identified culturally by their failure to elaborate coagulase, their resistance to bacteriophage, and their sensitivity to mannitol, have altered molar ratios of amino acids and amino sugars in their cell walls. In comparison with lysine content, the serine content of the mutant wall is elevated and the glycine content is reduced. The glucosamine content is reduced also. It is postulated that the pleiotropic mutants possess an altered cell wall biosynthetic pathway.     

Anionic carbohydrate-containing polymers of cell walls in two streptoverticille genospecies.

The cell walls of two streptoverticille genospecies which belong to a historically isolated group of the genus Streptomyces contain anionic polymers of different structure. Streptomyces hachijoensis VKM Ac-191T and Streptomyces cinnamoneus subsp. azacoluta VKM Ac-606T assigned to one genospecies on the basis of DNA--DNA hybridization [5] contain 37% of an identical sugar-1-phosphate polymer. The repeating disaccharide units of the polymer, 2-amino-2-deoxy-alpha-D-glucopyranosyl-(1-->6)-2-acetamido-2-deoxy-al pha-D-glucopyranose, are linked at C-1 and C-6' by phosphodiester bonds. The cell walls of Streptomyces biverticillatus VKM Ac-891T and Streptomyces baldaccii VKM Ac-821T, members of another genospecies, contain about 30% 1,3-poly(glycerol phosphate) completely substituted by 2-amino-2-deoxy-alpha-D-glucopyranosyl residues at C-2. Due to the presence of an amino sugar with a free amino group in the repeating unit, the polymers exhibit neutral properties. Polymer structures were determined by chemical methods and NMR spectroscopy. The data indicate taxonomic specificity of anionic polymers in streptoverticille cell walls.     

Chemotaxonomic differentiation of coryneform bacteria isolated from biofilters.

Coryneform bacteria that were isolated from biofilters which are used for waste gas treatment of animal-rendering plant emissions were differentiated and partially identified by using chemotaxonomic methods. On the basis of the results of a numerical analysis of whole-cell fatty acid profiles, 79 isolates were divided into two major groups; the members of the first group contained saturated and monounsaturated fatty acids, whereas the members of the second group were characterized by iso- and anteiso-branched fatty acids. Division into subclusters was based mainly on quantitative differences in fatty acid composition and was confirmed by the results obtained for additional chemical markers (e.g., respiratory quinones, mycolic acids, polar lipids, cell wall amino acids, and whole-cell sugar patterns). By combining the results obtained for chemotaxonomic analyses that were performed for strains containing saturated and monounsaturated fatty acids, we were able to identify the genus Corynebacterium (two Corynebacterium species were differentiated on the basis of the occurrence of tuberculostearic acid), the genus Gordona, and the genus Mycobacterium. Among the strains that produced iso-anteiso fatty acid patterns, one subgroup was affiliated with the "nicotianae" group of the genus Arthrobacter; however, some strains contained a new combination of chemical markers. Peptidoglycan type A4 alpha, L-Lys-Gly-L-Glu was combined with menaquinones MK-7 and MK-8, whereas peptidoglycan type A4 alpha, L-Lys-L-Glu occurred together with MK-8 and MK-9. The second subgroup was characterized by a new type B peptidoglycan and MK-11, as well as small amounts of MK-12. Differentiation that was based first on chemotaxonomy and second on physiology gave reliable results. Thus, coryneform strains with new characteristics were isolated from biofilters.     

The location of N-acetylgalactosamine in the walls of Bacillus subtilis 168

The N-acetylgalactosamine in the walls of Bacillus subtilis 168 occurs in two polymers. One of these contains N-acetylgalactosamine, glucose and phosphorus and is attached to the peptidoglycan through an alkali-labile bond; preliminary studies indicate that a repeating unit of this polymer is glucosyl-N-acetylgalactosamine 1-phosphate. N-Acetylgalactosamine is also associated with the peptidoglycan in a component that is not converted into the free sugar or other soluble compounds on treatment of the walls with alkali. The two polymers containing N-acetylgalactosamine are released on autolysis of the walls and can be separated by ion-exchange chromatography. As glucose 6-phosphate is produced by gentle hydrolysis of the wall with acid a third phosphate polymer, poly(glucose 1-phosphate), may occur in this wall. However, as no polymer with this structure could be separated from that containing galactosamine, its existence has not been established unequivocally. The methods described permit the study of variations in N-acetylgalactosamine content with respect to growth conditions.     

Use of bacteriophage-resistant mutants to study the nature of the bacteriophage receptor site of Staphylococcus aureus

Bacteriophage-resistant strains of Staphylococcus aureus H were isolated after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. Cell walls isolated from about half of these resistant strains were incapable of inactivating phages and were shown to lack N-acetyl-d-glucosamine (GlcNAc) in their cell wall teichoic acid. Apart from the lack of GlcNAc, two of these mutant strains were deficient in cell wall phosphorus and ester-linked d-alanine. These two strains were also found to be resistant to both phage K and a host-range mutant isolated from the parent phage. These two phages could lyse the other phage-resistant mutants which lacked GlcNAc in their teichoic acid. Cell walls from the remaining phage-resistant mutant strains did inactivate phages and were found to have normal cell wall teichoic acid. Although GlcNAc in teichoic acid was required for phage inactivation, no difference in phage inactivation ability was detected with cell walls isolated from strains of S. aureus having exclusively alpha- or exclusively beta-linked GlcNAc in their cell wall teichoic acid.     

Features of ionogenic group composition in polymeric matrix of lily pollen wall

The composition of ionogenic groups and ion-exchange capacity were studied in the polymeric matrix of cell walls isolated from the pollen grain and tissues of vegetative organs (leaves and stems) of Lilium longiflorum Thunb. The ion-exchange capacity was evaluated at different pH values and ionic strength of 100 mM. In the two-layered pollen wall and the somatic cell walls four types of ionogenic groups were found: amino groups, two carboxyl groups (represented by residues of uronic and hydroxycinnamic acids), and phenolic OH-groups. The groups of all four types are present in the intine, whereas the exine contains one type of anion-exchange and two types of cation-exchange groups. The contents of each type group and their ionization constants were determined. The qualitative and quantitative compositions of structural polymers of the pollen intine and somatic cell walls are significantly different. It is suggested that hydroxycinnamic acids should be involved in cross-linking of polysaccharide chains in both the intine and somatic cell primary walls, and such cross-links play a crucial role in the structural organization and integrity of the pollen grain wall.     

Chemical Composition of the Cell Walls of Clostridium botulinum Type A

Cell walls were isolated by sonic disruption of log-phase cells of Clostridium botulinum type A strain 190L and purified by treatment with sodium dodecyl sulfate (SDS) followed by digestion with proteases. Electron microscopy revealed that the cell walls thus obtained were free of both cytoplasmic membrane and cytoplasmic fragments. The purified cell wall contained 8.7% total nitrogen, 15.0% total hexosamines, 22.4% reducing groups, 8.3% carbohydrate, and 3.1% glucose. The content of total phosphorus was very low (0.02%), and therefore it was expected that teichoic acid might be absent in the cell wall. The wall peptidoglycan contained glutamic acid, alanine, diaminopimelic acid, glucosamine and muramic acid in the molar ratios of 1.00:1.85:0:85:1.06:0.67. A low amount of galactosamine was also present, but no other amino acids were found in significant quantities. The SDS-treated cell walls were not attacked by lysozyme, but after extraction with hot formamide they were completely dissolved by the enzyme and released reducing groups. The lysozyme digest was separated into two constituents, the saccharide moiety and the peptide moiety on Sephadex G-50.     

Quantitative microanalysis of cell walls of Saprolegnia diclina humphrey and Tremella mesenterica fries

Cell walls of the fungi Saprolegnia diclina Humphrey and Tremella mesenterica Fries were analyzed quantitatively. Particular attention was paid to the hydrolysis and analysis of neutral sugars, amino sugars and amino acids. These components, together with total lipids, total uronic acids and the ashed residue, accounted for more than 90% by weight of the original dry cell wall preparation. There were substantial losses of amino acids during hydrolysis; however, analytical recovery approached 100% when total protein was calculated from the total nitrogen analysis. The analytical procedures were reproducible (±3% for amino acids and amino sugars, and ±5–10% for other components) when applied to individual cell wall preparations. However, even under carefully standardized conditions, different cell wall preparations from the same species showed variable composition.Glucose was the predominant neutral sugar in the cell wall polymers of both species. The amino acid compositions were remarkable in that neither species contained detectable levels of cyst(e)ine. Hydroxyproline was detected in both species. The report from Tremella mesenterica is the first for this imino acid from the cell wall of a Basidiomycete.     

Chemical Composition of the Cell Walls of Bacillus stearothermophilus

Cell walls were isolated by mechanical disruption of mid-log phase cells of Bacillus stearothermophilus NCA 1503-4R grown in Trypticase-yeast extract-fructose medium at 55 C. The cell walls were purified by treatment with sodium dodecyl sulfate (SDS) and incubation with deoxyribonuclease and trypsin. The cell wall peptidoglycan contained glucosamine, muramic acid, alpha, epsilon-diaminopimelic acid, and glutamic acid. Low amounts of glycine, galactosamine, serine, aspartic acid, lysine, and valine were also present. The relative mole ratios of glutamic acid-alpha, epsilon-diaminopimelic acid-glycine-alanine were 1.00:1.26:0.08:1.55. The cell walls were free from ribonucleic acid and deoxyribonucleic acid and contained less than 0.2% chloroform-methanol extractable lipid and 0.09 mumole of phosphorus per mg of cell wall. Teichoic acid was not detected in the cell walls of this organism. Cell walls isolated without treatment with SDS contained 7.5% chloroform-methanol extractable lipid, 0.24 mumole of phosphorus per mg of cell wall, and relatively high concentrations of all amino acids. These results suggest that the extracted lipid is not a cell wall component per se, but a contaminant from the lipoprotein cell membrane.     

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.     

Peptidoglycan cross-linking and teichoic acid attachment in Streptococcus pneumoniae.

Autolysin-defective pneumococci continue to synthesize both peptidoglycan and teichoic acid polymers (Fischer and Tomasz, J. Bacteriol. 157:507-513, 1984). Most of these peptidoglycan polymers are released into the surrounding medium, and a smaller portion becomes attached to the preexisting cell wall. We report here studies on the degree of cross-linking, teichoic acid substitution, and chemical composition of these peptidoglycan polymers and compare them with normal cell walls. peptidoglycan chains released from the penicillin-treated pneumococci contained no attached teichoic acids. The released peptidoglycan was hydrolyzed by M1 muramidase; over 90% of this material adsorbed to vancomycin-Sepharose and behaved like disaccharide-peptide monomers during chromatography, indicating that the released peptidoglycan contained un-cross-linked stem peptides, most of which carried the carboxy-terminal D-alanyl-D-alanine. The N-terminal residue of the released peptidoglycan was alanine, with only a minor contribution from lysine. In addition to the usual stem peptide components of pneumococcal cell walls (alanine, lysine, and glutamic acid), chemical analysis revealed the presence of significant amounts of serine, aspartate, and glycine and a high amount of alanine and glutamate as well. We suggest that these latter amino acids and the excess alanine and glutamate are present as interpeptide bridges. Heterogeneity of these was suggested by the observation that digestion of the released peptidoglycan with the pneumococcal murein hydrolase (amidase) produced peptides that were resolved by ion-exchange chromatography into two distinct peaks; the more highly mobile of these was enriched with glycine and aspartate. The peptidoglycan chains that became attached to the preexisting cell wall in the presence of penicillin contained fewer peptide cross-links and proportionally fewer attached teichoic acids than did their normal counterparts. The normal cell wall was heavily cross-linked, and the cross-linked peptides were distributed equally between the teichoic acid-linked and teichoic acid-free fragments.     

Two distinct classes of polyuronide from the cell walls of a dimorphic fungus, Mucor rouxii

Polyuronides were extracted from purified yeast and mycelial walls of Mucor rouxii by sequential treatments with lithium chloride and potassium hydroxide and were fractionated by ion-exchange chromatography on DEAE-Sephadex. Two polymers (I and II) of different acidity were found in both wall types. Polymer I contained D-glucuronic acid, L-fucose, D-mannose, and much smaller amounts of D-galactose. Yeast and mycelial polymer I had similar uronic acid contents but differed in their neutral sugar compositions and molecular weights. Polymer II from both cell types contained largely D-glucuronic acid and had similar molecular weights. On partial acid hydrolysis, both polymers I and II gave rise to insoluble glucuronans which appeared to be homopolymeric. One-third of the total uronosyl residues of polymer I, and almost all of the uronosyl residues of polymer II, were present in homopolymeric segments. However, homopolymers derived from polymers I and II may not be identical.     

Cell Wall Composition of Hyphomicrobium Species

Chemical analysis of cell walls obtained from Hyphomicrobium B-522 and from a morphologically and nutritionally distinct organism, Hyphomicrobium neptunium (ATCC 15444), showed that the organisms have a similar cell wall composition, which is typical of gram-negative bacteria. The walls of both strains contained many amino acids, including the characteristic mucopeptide components diaminopimelic acid and muramic acid. Isolation of the mucopeptide by use of sodium dodecyl sulfate was successful only with cell walls of H. neptunium, thus revealing a difference between the walls of the two strains. The mucopeptide preparation contained glucosamine, muramic acid, alanine, glutamic acid, diaminopimelic acid, and glycine in molar ratios of 1.05:1.21:1.84:1.0:1.04:0.31, respectively. The concentration of glycine was sufficiently high to suggest that it is a mucopeptide component rather than an impurity.     

Composition of cell walls of 2 mutant strains of Streptomyces chrysomallus

The cell walls and peptidoglycans of two mutant strains, Streptomyces chrysomallus var. carotenoides and Streptomyces chrysomallus var. macrotetrolidi, were studied. The strains are organisms producing carotenes and antibiotics of the macrotetrolide group. By the qualitative composition of the peptidoglycans the mutants belong to Streptomyces and are similar. Their glycan portion consists of equimolar quantities of N-acetyl glucosamine and muramic acid. The peptide subunit is presented by glutamic acid, L, L-diaminopimelic acid, glycine and alanine. The molar ratio of alanine is 1.2-1.3. The mutant strains differ in the content of carbohydrates, total phosphorus and phosphorus belonging to teichoic acids. Teichoic acids of the cell walls of the both strains are of the ribitolhosphate nature. The cell walls of the mutants contain polysaccharides differing from teichoic acids and consisting of glucose, galactose, arabinose and fucose. The influence of the cell wall composition of the mutant strains on their morphology and metabolism and comparison of the data relative to the mutant strains with those relative to the starting strain are discussed.