The function of teichoic acids in cation control in bacterial membranes

1. The effects of teichoic acids on the Mg(2+)-requirement of some membrane-bound enzymes in cell preparations from Bacillus licheniformis A.T.C.C. 9945 were examined. 2. The biosynthesis of the wall polymers poly(glycerol phosphate glucose) and poly(glycerol phosphate) by membrane-bound enzymes is strongly dependent on Mg(2+), showing maximum activity at 10-15mm-Mg(2+). 3. When the membrane is in close contact with the cell wall and membrane teichoic acid, the enzyme systems are insensitive to added Mg(2+). The membrane appears to interact preferentially with the constant concentration of Mg(2+) that is bound to the phosphate groups of teichoic acid in the wall and on the membrane. When the wall is removed by the action of lysozyme the enzymes again become dependent on an external supply of Mg(2+). 4. A membrane preparation that retained its membrane teichoic acid was still dependent on Mg(2+) in solution, but the dependence was damped so that the enzymes exhibited near-maximal activity over a much greater range of concentrations of added Mg(2+); this preparation contained Mg(2+) bound to the membrane teichoic acid. The behaviour of this preparation could be reproduced by binding membrane teichoic acid to membranes in the presence of Mg(2+). Addition of membrane teichoic acid to reaction mixtures also had a damping effect on the Mg(2+) requirement of the enzymes, since the added polymer interacted rapidly with the membrane. 5. Other phosphate polymers behaved in a qualitatively similar way to membrane teichoic acid on addition to reaction mixtures. 6. It is concluded that in whole cells the ordered array of anionic wall and membrane teichoic acids provides a constant reservoir of bound bivalent cations with which the membrane preferentially interacts. The membrane teichoic acid is the component of the system which mediates the interaction of bound cations with the membrane. The anionic polymers in the wall scavenge cations from the medium and maintain a constant environment for the membrane teichoic acid. Thus a function of wall and membrane teichoic acids is to maintain the correct ionic environment for cation-dependent membrane systems.     

Cell wall teichoic acid as a reserve phosphate source in Bacillus subtilis.

Although exponential growth of Bacillus subtilis 168 in a phosphate-limited medium halted with the exhaustion of inorganic phosphate, the bacteria continued to grow at a slower rate for a further 3 to 4 h at 37 degrees C. This postexponential growth in the absence of an exogenous phosphate supply was accompanied by a loss of teichoic acid from the cell walls of the bacteria. Quantitative analysis of walls and culture fluids showed that the phosphate loss from the walls could not be accounted for by an increase in phosphate-containing compounds in the medium, which implied that the cells were using their own wall teichoic acids to supply phosphate necessary for growth. Addition of exogenous teichoic acid to phosphate-starved cultures resulted in stimulation of growth and in the simultaneous disappearance of teichoic acid phosphate from the medium. It is proposed that teichoic acids, which can contain more than 30% of the total phosphorus of exponential-phase cells, can be used as a reserve phosphate source when the bacteria are starved for inorganic phosphate.     

The cell wall teichoic acids of streptomycetes from the "Streptomyces cyaneus" cluster

The cell wall anionic polymers of the 13 species of the "Streptomyces cyaneus" cluster have a similar structure and contain beta-glucosylated 1,5-poly(ribitol phosphate) and 1,3-poly(glycerol phosphate). In the degree of glucosylation of the ribitol phosphate units of their teichoic acids, the cluster members can be divided into two groups. The streptomycetes of the first group (S. afghaniensis, S. janthinus, S. purpurascens, S. roseoviolaceus, and S. violatus) are characterized by a very similar structure of their cell walls, completely glucosylated 1,5-poly(ribitol phosphate) chains, and a high degree of DNA homology (67-88%). The cell wall teichoic acids of the second group (S. azureus, S. bellus, S. caelestis, S. coeruleorubidus, S. curacoi, and S. violarus) differ in the degree of beta-glucosylation of their 1,5-poly(ribitol phosphate) chains and have a lower level of DNA homology (54-76%). Two streptomycetes of the cluster (S. cyaneus and S. hawaiiensis) are genetically distant from the other cluster members but have the same composition and structure of the cell wall teichoic acids as the second-group streptomycetes. The data obtained confirm the genetic relatedness of the "S. cyaneus" cluster members and suggest that the structure of the cell wall teichoic acids may serve as one of the taxonomic criteria of the species-level status of streptomycetes.     

Structural differentiation of the Bacillus subtilis 168 cell wall.

Exponential-growth-phase cultures of Bacillus subtilis 168 were probed with polycationized ferritin (PCF) or concanavalin A (localized by the addition of horseradish peroxidase conjugated to colloidal gold) to distinguish surface anionic sites and teichoic acid polymers, respectively. Isolated cell walls, lysozyme-digested cell walls, and cell walls treated with mild alkali to remove teichoic acid were also treated with PCF. After labelling, whole cells and walls were processed for electron microscopy by freeze-substitution. Thin sections of untreated cells showed a triphasic, fibrous wall extending more than 30 nm beyond the cytoplasmic membrane. Measurements of wall thickness indicated that the wall was thicker at locations adjacent to septa and at pole-cylinder junctions (P < 0.001). Labelling studies showed that at saturating concentrations the PCF probe labelled the outermost limit of the cell wall, completely surrounding individual cells. However, at limiting PCF concentrations, labelling was observed at only discrete cell surface locations adjacent to or overlying septa and at the junction between pole and cylinder. Labelling was rarely observed along the cell cylinder or directly over the poles. Cells did not label along the cylindrical wall until there was visible evidence of a developing septum. Identical labelling patterns were observed by using concanavalin A-horseradish peroxidase-colloidal gold. Neither probe appeared to penetrate between the fibers of the wall. We suggest that the fibrous appearance of the wall seen in freeze-substituted cells reflects turnover of the wall matrix, that the specificity of labelling to discrete sites on the cell surface is indicative of regions of extreme hydrolytic activity in which alpha-glucose residues of the wall teichoic acids and electronegative sites (contributed by phosphate and carboxyl groups of the teichoic acids and carboxyl groups of the peptidoglycan polymers) are more readily accessible to our probes, and that the wall of exponentially growing B. subtilis cells contains regions of structural differentiation.     

Teichoic acids in the cell walls of Microbispora mesophila Ac-1953t and Thermobifida fusca Ac-1952t

The cell walls of Microbispora mesophila strain Ac-1953T (the family Streptosporangiaceae) and Thermobifida fusca Ac-1952T (the family Nocardiopsiceae) were found to contain teichoic acids of a poly(glycerol phosphate) nature. The teichoic acid of M. mesophila (formerly Thermomonospora mesophila) represents a poly(glycerol phosphate) containing 5% of substituent 2-acetamido-2-deoxy-alpha-galactosaminyl residues. The teichoic acid of such kind was found in actinomycetes for the first time. The cell wall of T. fusca (formerly Thermonospora fusca) contains two teichoic acids, namely, unsubstituted 1,3-poly(glycerol phosphate) and beta-glucosylated 1,3-poly(glycerol phosphate).     

Teichoic acids from the cell wall of Nocardiopsis prasina BKM Ac-1880T

The cell wall of Nocardiopsis prasina VKM Ac-1880T was found to contain two structurally different teichoic acids: unsubstituted 3,5-poly(ribitol phosphate) and 1,3-poly(glycerol phosphate), substituted at position 2 by 10% with alpha-N-acetylglucosamine and by 5% with O-acetyl groups. The structure of the polymers was studied by chemical analysis and NMR spectroscopy. The results obtained correlate well with 16S rRNA sequence data and confirm the species-specificity of teichoic acids in the genus Nocardiopsis.     

Cell wall teichoic acids from Streptomyces daghestanicus VKM Ac-1722T and Streptomyces murinus INA-00524T

The structure of cell wall teichoic acids was studied by chemical methods and NMR spectroscopy in the type strains of two actinomycete species of the "Streptomyces griseoviridis" phenetic cluster: Streptomyces daghestanicus and Streptomyces murinus. S. daghestanicus VKM Ac-1722T contained two polymers having a 1,5-poly(ribitol phosphate) structure. In one of them, the ribitol units had alpha-rhamnopyranose and 3-O-methyl-alpha-rhamnopyranose substituents; in the other, each ribitol unit was carrying 2,4-ketal-bound pyruvic acid. Such polymers were earlier found in the cell walls of Streptomyces roseolus and Nocardiopsis albus, respectively; however, their simultaneous presence in the cell wall has never been reported. The cell wall teichoic acid of Streptomyces murinus INA-00524T was is a 1,5-poly(glucosylpolyol phosphate), whose repeating unit was [-6)-beta-D-glucopyranosyl-(1 --> 2)-glycerol phosphate-(3-P-]. Such a teichoic acid was earlier found in Spirilliplanes yamanashiensis. The 13C NMR spectrum of this polymer is presented for the first time. The results of the present investigation, together with earlier published data, show that the type strains of four species of the "Streptomyces griseoviridis" phenetic cluster differ in the composition and structure of their teichoic acids; thus, teichoic acids may serve as chemotaxonomic markers of the species.     

Teichoic acid is an essential polymer in Bacillus subtilis that is functionally distinct from teichuronic acid

Wall teichoic acids are anionic, phosphate-rich polymers linked to the peptidoglycan of gram-positive bacteria. In Bacillus subtilis, the predominant wall teichoic acid types are poly(glycerol phosphate) in strain 168 and poly(ribitol phosphate) in strain W23, and they are synthesized by the tag and tar gene products, respectively. Growing evidence suggests that wall teichoic acids are essential in B. subtilis; however, it is widely believed that teichoic acids are dispensable under phosphate-limiting conditions. In the work reported here, we carefully studied the dispensability of teichoic acid under phosphate-limiting conditions by constructing three new mutants. These strains, having precise deletions in tagB, tagF, and tarD, were dependent on xylose-inducible complementation from a distal locus (amyE) for growth. The tarD deletion interrupted poly(ribitol phosphate) synthesis in B. subtilis and represents a unique deletion of a tar gene. When teichoic acid biosynthetic proteins were depleted, the mutants showed a coccoid morphology and cell wall thickening. The new wall teichoic acid biogenesis mutants generated in this work and a previously reported tagD mutant were not viable under phosphate-limiting conditions in the absence of complementation. Cell wall analysis of B. subtilis grown under phosphate-limited conditions showed that teichoic acid contributed approximately one-third of the wall anionic content. These data suggest that wall teichoic acid has an essential function in B. subtilis that cannot be replaced by teichuronic acid.     

Electrical properties and interaction with silicon dioxide particles of Bacillus subtilis cells

It was shown that, depending on the quantity of phosphate in cultivation media, the surface layer of the Bacillus subtilis cell wall can mainly consist of either teichoic or teichuronic acids. It was found that the addition of silicon dioxide particles to the bacterial suspension induces an increase in the negative charge of the cell. This cell response to contact interaction with solid particles is observed in bacteria whose surface components are teichoic acids.     

A balancing act times two: sensing and regulating cell envelope homeostasis in Bacillus subtilis

Bacterial cell wall homeostasis is an intricately coordinated process that ensures that envelope integrity is maintained during cell growth and division, but can also adequately respond to growth‐limiting conditions such as phosphate starvation. In Bacillus subtilis, biosynthesis of the two major cell wall components, peptidoglycan and anionic polymers, is controlled by a pair of paralogous two‐component systems, WalRK and PhoPR respectively. Favorable growth conditions allow for a fast rate of cell wall biosynthesis (WalRK‐ON) and the incorporation of the phosphate‐containing anionic polymer teichoic acids (PhoPR‐OFF). In contrast, growth‐restricted cells under phosphate‐limiting conditions reduce the incorporation of peptidoglycan building blocks (WalRK‐OFF) and switch from the phosphate‐containing teichoic acids to the phosphate‐free anionic polymer teichuronic acid (PhoPR‐ON). Botella et al. (2014) deepen our knowledge on the PhoPR system by identifying one signal that is perceived by its histidine kinase PhoR. In fast‐growing cells, intracellular intermediates of teichoic acid biosynthesis are sensed by the cytoplasmic Per‐Arnt‐Sim domain as an indicator of favorable conditions, thereby inhibiting the autokinase activity of PhoR and keeping the system inactive. Depletion of teichoic acid building blocks under phosphate‐limiting conditions relieves this inhibition, activates PhoPR‐dependent signal transduction and hence the switch to teichuronic acid biosynthesis.     

The molecular structure of bacterial walls. The size of ribitol teichoic acids and the nature of their linkage to glycosaminopeptides

1. Ribitol teichoic acids prepared by fractional precipitation of trichloroacetic acid extracts of bacterial cell walls are essentially undegraded and have similar chain length to the teichoic acid originally present in the walls. 2. The chain length of teichoic acid can be determined directly, without prior extraction from the wall. Accurate values have been obtained by measurement of the formaldehyde produced by oxidation of walls with periodate. Less accurate values have been derived from the amount of inorganic phosphate formed by heating walls at pH4. 3. The relative amounts of N-acetylglucosaminylribitol and its mono- and di-phosphates produced by heating walls of Staphylococcus aureus with alkali agree with the amounts calculated for the hydrolysis of teichoic acid having the chain length determined by other methods. 4. Chemical considerations indicate that the linkage between teichoic acid and the wall may involve a phosphoramidate bond between the terminal phosphate of the teichoic acid and one of the amino groups in the glycosaminopeptide.     

Late-stage polyribitol phosphate wall teichoic acid biosynthesis in Staphylococcus aureus

Wall teichoic acids are cell wall polymers that maintain the integrity of the cellular envelope and contribute to the virulence of Staphylococcus aureus. Despite the central role of wall teichoic acid in S. aureus virulence, details concerning the biosynthetic pathway of the predominant wall teichoic acid polymer are lacking, and workers have relied on a presumed similarity to the putative polyribitol phosphate wall teichoic acid pathway in Bacillus subtilis. Using high-resolution polyacrylamide gel electrophoresis for analysis of wall teichoic acid extracted from gene deletion mutants, a revised assembly pathway for the late-stage ribitol phosphate-utilizing enzymes is proposed. Complementation studies show that a putative ribitol phosphate polymerase, TarL, catalyzes both the addition of the priming ribitol phosphate onto the linkage unit and the subsequent polymerization of the polyribitol chain. It is known that the putative ribitol primase, TarK, is also a bifunctional enzyme that catalyzes both ribitol phosphate priming and polymerization. TarK directs the synthesis of a second, electrophoretically distinct polyribitol-containing teichoic acid that we designate K-WTA. The biosynthesis of K-WTA in S. aureus strain NCTC8325 is repressed by the accessory gene regulator (agr) system. The demonstration of regulated wall teichoic acid biosynthesis has implications for cell envelope remodeling in relation to S. aureus adhesion and pathogenesis.     

Surface electrical properties of <Emphasis Type="Italic">bacillus subtilis</Emphasis> cells and the effect of interaction with silicon dioxide particles

Depending on the amount of phosphate in the growth medium, the surface layer of the Bacillus subtilis cell wall may be composed mainly of either teichoic or teichuronic acids. Only in the former case the negative charge of the cell surface increases upon addition of silicon dioxide particles into the cell suspension.     

Production and release of peptidoglycan and wall teichoic acid polymers in pneumococci treated with beta-lactam antibiotics

Autolysin-defective pneumococci treated with inhibitory concentrations of penicillin and other beta-lactam antibiotics continued to produce non-cross-linked peptidoglycan and cell wall teichoic acid polymers, the majority of which were released into the surrounding medium. The released cell wall polymers were those synthesized by the pneumococci after the addition of the antibiotics. The peptidoglycan and wall teichoic acid chains released were not linked to one another; they could be separated by affinity chromatography on an agarose-linked phosphorylcholine-specific myeloma protein column. Omission of choline, a nutritional requirement and component of the pneumococcal teichoic acid, from the medium inhibited both teichoic acid and peptidoglycan synthesis and release. These observations are discussed in terms of plausible mechanisms for the coordination between the biosynthesis of peptidoglycan and cell wall teichoic acids.     

Loss of D-alanine during sublethal heating of Staphylococcus aureus S6 and magnesium binding during repair.

Staphylococcus aureus S6 sublethally heated at 52 degrees C for 15 min to 0-1 M-potassium phosphate buffer pH 7-2, lost neither the ribitol teichoic acid of the wall nor the glycerol teichoic acid of the membrane. Hurst et al. (1974) showed that this heating caused 40% loss of the cellular Mg, and we now report the loss of 65% of the ester-bound D-alanine of teichoic acid. Repair from sublethal heat injury, measured by the return of salt tolerance, occurs in a simple no-growth medium provided that the cell concentration is less than 5 x 10(8)/ml. During repair, D-alanine is rapidly synthesized. Fully-repaired cells contain four times more D-alanine than do freshly-injured cells. Magnesium is present in the medium at only 3 x 10(-6) M, yet the cellular Mg concentration returns to normal within 1 h of incubation, even in the presence of EDTA. The results suggest that repair occurs in two stages. Soon after injury, in the absence of the competitive effect of D-alanine, Mg is strongly bound to teichoic acid. In repaired or uninjured cells Mg is less strongly bound. The implications of these findings are discussed in relation to the cation-binding function of teichoic acid.     

The membrane teichoic acid of Staphylococcus lactis I3

1. Teichoic acid was isolated by extraction with trichloroacetic acid of the membrane fraction of disrupted cells of Staphylococcus lactis I3. 2. The purified material contains glycerol, phosphate and alanine, but little or no sugar or amino sugar. 3. A study of the products of hydrolysis with acid and alkali established that the membrane teichoic acid is a (1-->3)-linked poly(glycerol phosphate) that differs in structure from the glycerol teichoic acid in the wall of this organism. 4. The alanine ester residues show the characteristic high lability to alkali and are thus distinguishable from the more stable alanine ester residues of the wall teichoic acid. 5. The significance of these structural features and the possible function of teichoic acids are discussed.     

Function of Teichoic Acids and Effect of Novobiocin on Control of Mg<Superscript>2+</Superscript> at the Bacterial Membrane

ALTHOUGH the occurrence of both wall and membrane teichoic acids in Gram-positive bacteria has been known for a considerable time and it is believed that they are essential for normal cellular activity, their main function has been somewhat obscure. Confirmatory evidence for the proposal¹ that teichoic acids participate in ion-exchange in the outer regions of the bacterial cell has been described recently². It has been shown that the phosphate groups of the wall teichoic acid are responsible for the capacity of isolated walls to bind magnesium ions; but whole cells of Gram-positive bacteria also invariably contain a poly-glycerol phosphate-teichoic acid located in the region between the wall and the cytoplasmic membrane³ and it is believed that this must be able to bind Mg²⁺ as does the wall polymer. These two regions of anionic polymer might thus constitute an integrated cation-exchange system between the exterior of the cell and the cytoplasmic membrane, where relatively high concentrations of Mg²⁺ are required for a variety of processes. We report here experiments with a membrane-bound enzyme system that requires Mg²⁺, obtained from a broken cell preparation and in which the close contact between the outer layers of the cell is preserved. In this preparation the enzyme system displays maximum activity in the presence of Mg²⁺ bound to the endogenous teichoic acid and is insensitive to changes in the concentration of added Mg²⁺, in marked contrast to the behaviour of the enzyme system in isolated cytoplasmic membrane. These results provide the first direct demonstration of the function of teichoic acids in concentrating Mg²⁺at the cytoplasmic membrane. They lead to the conclusion that failure of teichoic acid biosynthesis in the whole cell would cause inhibition of membrane function through magnesium starvation. In view of this the effect of novobiocin, an antibiotic shown to inhibit teichoic acid biosynthesis in vitro^4–6, is discussed.     

生物矿化一蜡状芽孢杆菌聚金作用的研究

介绍了生物矿化-蜡状芽孢杆菌聚金作用原理.生物活动对矿石的风化、淋滤和沉积都有很大的影响.蜡状芽孢杆菌聚金作用主要与蜡状芽孢杆菌细胞壁的化学成分和结构功能有关.原因是其细胞壁有一层很厚的网状的肽聚糖、多糖、核酸和蛋白质结构,并且在细胞壁表面存在的磷壁酸质和糖醛酸磷壁酸质连接到网状的肽聚糖上.磷壁酸质的磷酸二脂和糖醛酸磷壁酸质的羧基使细胞壁带负电荷,具有离子交换的性质,能与溶液中带正电荷的金属离子进行交换反应.这些过程是蜡状芽孢杆菌细胞壁聚集金的主要作用机制.     

Cell wall teichoic acids ofNocardiopsis prasina VKM Ac-1880T

The cell wall ofNocardiopsis prasina VKM Ac-1880^T was found to contain two structurally different teichoic acids: unsubstituted 3,5-poly(ribitol phosphate) and l,3-poly(glycerol phosphate) substituted at position 2 by 10% with α-N-acetylglucosamine and by 5% withO-acetyl groups. The structure of the polymers was studied by chemical analysis and NMR spectroscopy. The results obtained correlate wellwith 16S rRNA sequence data and confirm the species-specificity of teichoic acids in the genusNocardiopsis.