Insertion and fate of the cell wall in Bacillus subtilis

Cell wall assembly was studied in autolysin-deficient and -sufficient strains of Bacillus subtilis. Two independent probes, one for peptidoglycan and the other for surface-accessible teichoic acid, were employed to monitor cell surface changes during growth. Cell walls were specifically labeled with N-acetyl-D-[3H]glucosamine, and after growth, autoradiographs were prepared for both cell types. The locations of silver grains revealed that label was progressively lost from numerous sites on the cell cylinders, whereas label was retained on the cell poles, even after several generations. In the autolysin-deficient and chain-forming strain, it was found that the distance between densely labeled poles approximately doubled after each generation of growth. In the autolysin-sufficient strain, it was found that the numbers of labeled cell poles remained nearly constant for several generations, supporting the premise that completed septa and poles are largely conserved during growth. Fluorescein-conjugated concanavalin A was also used to determine the distribution of alpha-D-glucosylated teichoic acid on the surfaces of growing cells. Strains with temperature-sensitive phosphoglucomutase were used because in these mutants, glycosylation of cell wall teichoic acids can be controlled by temperature shifts. When the bacteria were grown at 45 degrees C, which stops the glucosylation of teichoic acid, the cells gradually lost their ability to bind concanavalin A on their cylindrical surfaces, but they retained concanavalin A-reactive sites on their poles. Discrete areas on the cylinder, defined by the binding of fluorescent concanavalin A, were absent when the synthesis of glucosylated teichoic acid was inhibited during growth for several generations at the nonpermissive temperature. When the mutant was shifted from a nonpermissive to a permissive temperature, all areas of the cylinder became able to bind the labeled concanavalin A after about one-half generation. Old cell poles were able to bind the lectin after nearly one generation at the permissive temperature, showing that new wall synthesis does occur in the cell poles, although it occurs slowly. These data, based on both qualitative and quantitative experiments, support a model for cell wall assembly in B. subtilis, in which cylinders elongate by inside-to-outside growth, with degradation of the stress-bearing old wall in wild-type organisms. Loss of wall material, by turnover, from many sites on the cylinder may be necessary for intercalation of new wall and normal length extension. Poles tend to retain their wall components during division and are turned over much more slowly.     

Organization of teichoic acid in the cell wall of Bacillus subtilis.

The phytohemagglutinin, concanavalin A (Con A), interacts specifically and reversibly with the polyglucosyl glycerol phosphate teichoic acid of Bacillus subtilis 168 cell walls. Advantage has been taken of this interaction to examine the organization of the surface teichoic acid at the ultrastructural level. Con A-treated whole cells and cell walls contain an irregular, fluffy layer 25 to 60 nm thick which is absent in untreated or alpha-methyl glucoside-treated preparations. This discontinuous layer is present only on the outer profile of Con-A-treated cell walls. The surface teichoic acid is proposed to be oriented perpendicular to the long axis of the cell. Fixation and embedment for electron microscopy result in condensation of this layer which then contributes to the stainable portion of the wall. Con A treatment binds adjacent teichoic acid molecules in their native configuration producing the irregular, fluffy layer visualized.     

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.     

Interaction of Concanavalin A with the Cell Wall of Bacillus subtilis

Interactions between concanavalin A and cell wall digests of Bacillus subtilis 168 resulted in insoluble complexes as observed by double gel diffusion, turbidity, and analysis of the precipitate. The macromolecular constituent of the cell walls complexing with concanavalin A was the polyglucosylglycerol phosphate teichoic acid. The complex exhibited two pH optima: 3.1 and 7.4. The complex could be dissociated by saccharides which bind to concanavalin A. In contrast to concanavalin A-neutral polysaccharide complexes, formation of the concanavalin A-wall complex was inhibited by salts. It was subsequently shown that salts induce conformational changes in cell wall digests. The data suggested that for complex formation to occur a rigid rod conformation in the glucosylated teichoic acid is probably necessary. Concanavalin A can be used as a probe to study structural features of bacterial cell walls.     

Asymmetric distribution of charge on the cell wall of Bacillus subtilis.

The cell wall of Bacillus subtilis is capable of binding different kinds of metal ions. The wall-ion complex appears to be dependent on both phosphoryl from teichoic acid and carboxylate from peptidoglycan. In the present study, cationized ferritin (CF) was used as a probe for charge distribution on the wall of B. subtilis 168. Detergent-extracted cell walls bound CF only on the outer wall face. Completed cell poles bound CF, but septa did not. When the walls were permitted to autolyze briefly, binding of CF occurred on both faces. In contrast, limited hydrolysis of the walls by egg white lysozyme resulted in the penetration of CF into the wall matrix. When walls were made teichoic acid-free, CF-binding asymmetry was preserved, suggesting that carboxyl groups were oriented toward the surface. Walls with carboxylates chemically neutralized also retained charge asymmetry. Phosphate-free and carboxyl-modified walls bound CF only poorly or not at all. These results indicate that negative charges contributed by both phosphate and carboxyl are responsible for the binding of CF and that the observed asymmetry in the distribution of the label is due to the orientation of teichoic acid and muramyl peptides toward the outside of the cell wall, above the plane of the glycan strands.     

Regulation of the bacterial cell wall: analysis of a mutant of Bacillus subtilis defective in biosynthesis of teichoic acid

Bacillus subtilis 168ts-200B is a temperature-sensitive mutant of B. subtilis 168 which grows as rods at 30 C but as irregular spheres at 45 C. Growth at the nonpermissive temperature resulted in a deficiency of teichoic acid in the cell wall. A decrease in teichoic acid synthesis coupled with the rapid turnover of this polymer led to a progressive loss until less than 20% of the level found in wild-type rods remained in spheres. Extracts of cells grown at 45 C contained amounts of the enzymes involved in the biosynthesis and glucosylation of teichoic acids that were equal to or greater than those found in normal rods. Cell walls of the spheres were deficient also in the endogenous autolytic enzyme (N-acyl muramyl-l-alanine amidase). Genetic analysis of the mutant by PBS1-mediated transduction and deoxyribonucleic acid-mediated transformation demonstrated that the lesion responsible for these effects (tag-1) is tightly linked to the genes which regulate the glucosylation of teichoic acid in the mid-portion of the chromosome of B. subtilis.     

Isolation of the Teichoic Acid of Bacillus Subtilis 168 by Affinity Chromatography

A column of insoluble concanavalin A was prepared by coupling the protein to cyanogen bromide-activated Sepharose. When autolysates of Bacillus subtilis 168 cell walls were passed over the column, the alpha glucosylated teichoic acid component of the cell wall was retained. The teichoic acid could be eluted with dilute alpha-methylglucopyranose. The teichoic acid prepared by affinity chromatography from cell wall autolysates had a higher sedimentation rate than teichoic acids obtained by conventional methods.

Several authors have shown that concanavalin A (con A) forms complexes with alpha-glucosylated teichoic acids^1–3. Doyle and Birdsell¹ found that the teichoic acid of Bacillus subtilis 168 (trp C2) would precipitate with con A at neutral pH in dilute buffer. The formation of a precipitate was inhibited by sugars which bind to the active site of con A. This observation suggested that it should be possible to purify the teichoic acid by affinity chromatography using insoluble con A as the affinity probe. Lloyd⁴ and Donnelly and Goldstein⁵ have successfully employed insoluble con A to purify polysaccharides and glycoproteins. In this communication, we describe conditions for the rapid purification of the alpha-glucosylated teichoic acid of B. subtilis 168. The teichoic acid prepared by this procedure appears to be less degraded than teichoic acids obtained by conventional methods.     

An electron microscopic study of the location of teichoic acid and its contribution to staining reactions in walls of Streptococcus faecalis 8191.

The location of the glucosylated teichoic acid in whole cells and isolated walls of Streptococcus faecalis 8191 has been investigated using ruthenium red, gold-labelled concanavalin A and concanavalin A-peroxidase-diaminobenzidine. Dense laminae were revealed in sections of osmium-fixed walls stained with ruthenium red which corresponded to similar regions stained by uranyl and lead. Such regions were not seen after teichoic acid had been extracted, suggesting that the uptake of stain was by teichoic acid. However, these regions were not labelled on exposure to gold concanavalin A or concanavalin A-peroxidase-diaminobenzidine; these stains indicated that teichoic acid was situated between the dense laminae, although the distribution of stain could have been due to the inability of the concanavalin A stains to penetrate deeply. Chemical binding studies showed that the teichoic acid was the major uranyl binding component in isolated walls, from which it might be inferred that teichoic acid was located in the densely staining regions. However, since osmification significantly increased the binding of uranyl (and lead stains) to non-teichoic acid material, such an inference was not necessarily valid. It is concluded that the presence of teichoic acid can be demonstrated in certain regions of the wall by concanavalin A, but its presence in densely staining regions has not been established. These experiments therefore suggest that teichoic acid may not be intimately associated with the mechanisms that generate contrast patterns in stained sections of cell walls of Streptococcus faecalis.     

Polyelectrolyte Nature of Bacterial Teichoic Acids

Several physicochemical properties of the teichoic acid of Bacillus subtilis 168 have been determined. The teichoic acid partial specific volume was found to be 0.57 ml/g. The apparent weight-average molecular weight of the polymer was 24,800. Sedimentation was strongly dependent on solvent. The sedimentation coefficient of the teichoic acid was found to have a value of s(20.w) (0) = 1.90S. In dilute buffers and distilled water, the teichoic acid possessed a rigid rod or extended conformation. Salts induced a loss of secondary structure in the polymer, resulting in a random coil configuration. Salt-induced structural changes in the teichoic acid were determined by viscosities, ultraviolet difference spectra, and inhibition of precipitation with concanavalin A. Divalent cations such as Mg(2+) had little effect on the teichoic acid structure. The salt-induced structural changes were reversible, as evidenced by return of the original properties upon dialysis of the teichoic acid against water. Sodium chloride inhibited the adsorption of bacteriophage ?25 to B. subtilis cell walls. Teichoic acid conformation may have a significant influence on the physiology of bacteria.     

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 membrane-induced proton motive force influences the metal binding ability of Bacillus subtilis cell walls.

Bacillus subtilis 168 is a gram-positive bacterium whose cell wall contains the highly electronegative polymers peptidoglycan (chemotype A1 gamma) and glycerol-based teichoic acid to produce a surface with a net negative charge with high metal binding capacity. During metabolism, a membrane-induced proton motive force continuously pumps protons into the wall fabric. As a result, a competition between protons and metal ions for anionic wall sites occurs, and less metal is bound in living cells than in nonliving cells or those in which the plasma membrane has been uncoupled. This was shown by using two metallic ions, UO2(2+) and Sc3+, on control cells, cells uncoupled with either carbonyl cyanide m-chlorophenylhydrazone or NaN3, or cells killed by gamma radiation. Transmission electron microscopy, energy-dispersive X-ray spectroscopy, and inductively coupled plasma atomic-emission spectroscopy showed that more metal was retained in the walls of nonliving cells and those with deenergized membranes than in their living counterparts.     

The membrane-induced proton motive force influences the metal binding ability of Bacillus subtilis cell walls.

Bacillus subtilis 168 is a gram-positive bacterium whose cell wall contains the highly electronegative polymers peptidoglycan (chemotype A1 gamma) and glycerol-based teichoic acid to produce a surface with a net negative charge with high metal binding capacity. During metabolism, a membrane-induced proton motive force continuously pumps protons into the wall fabric. As a result, a competition between protons and metal ions for anionic wall sites occurs, and less metal is bound in living cells than in nonliving cells or those in which the plasma membrane has been uncoupled. This was shown by using two metallic ions, UO2(2+) and Sc3+, on control cells, cells uncoupled with either carbonyl cyanide m-chlorophenylhydrazone or NaN3, or cells killed by gamma radiation. Transmission electron microscopy, energy-dispersive X-ray spectroscopy, and inductively coupled plasma atomic-emission spectroscopy showed that more metal was retained in the walls of nonliving cells and those with deenergized membranes than in their living counterparts.     

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.     

Ultrastructural localization of cell wall teichoic acids in Streptococcus faecalis by means of concanavalin A

Some teichoic acids are known to be partially substituted by α-D-glucopyranosyl residues such as the teichoic acids of Streptococcus faecalis NCIB 8191. They will, therefore, bind specifically the phytohemagglutinin concanavalin A. Concanavalin A labelled with mercury or colloidal gold coated with concanavalin A has been used to mark isolated cell walls in order to localize the teichoic acids at the ultrastructural level. Besides these two direct marking techniques, the indirect concanavalin A-peroxidase technique (localization of peroxidase by the diaminobenzidine method followed by postosmication) has been applied to thin sections of premarked cells. All three methods gave almost identical results, namely, a dense and homogeneous distribution of the cell wall teichoic acids. In control experiments total inhibition was achieved in the presence of methyl-α-D-mannopyranoside. After trichloroacetic acid or alkali extraction of the teichoic acids from isolated walls no marking could be detected.     

Structure and functions of linkage unit intermediates in the biosynthesis of ribitol teichoic acids in Staphylococcus aureus H and Bacillus subtilis W23

The stepwise formation and characterization of linkage unit intermediates and their functions in ribitol teichoic acid biosynthesis were studied with membranes obtained from Staphylococcus aureus H and Bacillus subtilis W23. The formation of labeled polymer from CDP-[14C]ribitol and CDP-glycerol in each membrane system was markedly stimulated by the addition of N-acetylmannosaminyl(beta 1----4)N-acetylglucosamine (ManNAc-GlcNAc) linked to pyrophosphorylyisoprenol. Whereas incubation of S. aureus membranes with CDP-glycerol and ManNAc-[14C]GlcNAc-PP-prenol led to synthesis of (glycerol phosphate) 1-3-ManNAc-[14C]GlcNAc-PP-prenol, incubation of B. subtilis membranes with the same substrates yielded (glycerol phosphate)1-2-ManNAc-[14C]GlcNAc-PP-prenol. In S. aureus membranes, (glycerol phosphate)2-ManNAc-[14C]GlcNAc-PP-prenol as well as (glycerol phosphate)3-ManNAc-[14C]GlcNAc-PP-prenol served as an acceptor for ribitol phosphate units, but (glycerol phosphate)-ManNAc-[14C]GlcNAc-PP-prenol did not. In B. subtilis W23 membranes, (glycerol phosphate)-ManNAc-[14C]GlcNAc-PP-prenol served as a better acceptor for ribitol phosphate units than (glycerol phosphate)2-ManNAc-[14C]GlcNAc-PP-prenol. In this membrane system (ribitol phosphate)-(glycerol phosphate)-ManNAc-[14C]GlcNAc-PP-prenol was formed from ManNAc-[14C]GlcNAc-PP-prenol, CDP-glycerol and CDP-ribitol. The results indicate that (glycerol phosphate)1-3-ManNAc-GlcNAc-PP-prenol and (glycerol phosphate)1-2-ManNac-GlcNAc-PP-prenol are involved in the pathway for the synthesis of wall ribitol teichoic acids in S. aureus H and B. subtilis W23 respectively.     

D-alanine incorporation into macromolecules and effects of D-alanine deprivation on active transport in Bacillus subtilis.

An auxotroph of Bacillus subtilis 168 unable to synthesize D-alanine loses the ability to support endogenously energized transport when deprived of D-alanine. Revertants of the mutant retain transport activity. The loss of transport is specific for substrates taken up by active transport; substrates taken up by group translocation are transported at normal rates. The loss of transport can be retarded by pretreatment of the cells with inhibitors of protein synthesis. Since the loss of transport could be due to an alteration in a D-alanine-containing polymer, we investigated the incorporation of D-[14C]alanine into macromolecules. The major D-alanine-containing polymers in B. subtilis are peptidoglycan and teichoic acid, with 4 to 6% of the D-[14C]alanine label found in trypsin-soluble material. Whereas the peptidoglycan and teichoic acid undergo turnover, the trypsin-soluble material does not. Treatment of the trypsin-soluble material with Pronase releases free D-alanine. Analysis of acid-hydrolyzed trypsin-soluble material indicated that approximately 75% of the radioactivity is present as D-alanine, with the remainder present as L-alanine. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of partially purified D-[14C]alanine-labeled membranes indicated the presence of two peaks of radioactivity (molecular weights, 230,000 and 80,000) that could be digested by trypsin. The results suggest that D-alanine may be covalently bound to cellular proteins.     

Cell-wall thickening in Bacillus subtilis. Comparison of thickened and normal walls

1. Incubation of Bacillus subtilis 168 trp in a glucose-amino acids-salts medium lacking tryptophan leads to an inhibition of cellular growth without affecting cell-wall synthesis. The cell walls increased approximately two- to three-fold in thickness and at the same time the amount of mucopeptide in the cells measured chemically increased to about the same extent. 2. Synthesis of mucopeptide and teichoic acid as measured by the extent of incorporation of radioactivity continued linearly for approximately 1h and then stopped. No reason was found for the strictly limited synthesis of the wall polymers. 3. The initial rates of incorporation of [(32)P]P(i) or [(3)H]alanine into teichoic acid and of (3)H-labelled amino acids into mucopeptide were not appreciably inhibited by the addition of chloramphenicol to the glucose-amino acids-salts medium. 4. There was no selective turnover of the mucopeptide synthesized by the cells in a medium lacking tryptophan on resumption of growth in a complete medium. 5. Wall synthesis taking place during the thickening process was similar to normal wall synthesis proceeding in growing cells. Walls of different thicknesses prepared from cells incubated for various times in incomplete medium did not differ qualitatively in composition. The products of autolysis of thickened walls were isolated and the analyses indicated a close similarity in the details of their mucopeptide structure compared with the mucopeptide of cells growing in the exponential phase.     

Chemical basis for selectivity of metal ions by the Bacillus subtilis cell wall.

The use of equilibrium dialysis techniques established that isolated cell walls of Bacillus subtilis possess selective affinities for several cations. The binding of these cations to the cell wall was influenced by the presence of various functional groups in the peptidoglycan matrix. Selective chemical modification of the free carboxyl and amino groups showed that when amino groups were replaced by neutral, bulky, or negatively charged groups, the sites available for cation complexing generally increased. Introduction of positive charges into the wall resulted in a marked decrease in the numbers of metal binding sites and usually a decrease in the apparent association constants. Both teichoic acid and peptidoglycan contribute to the sites available for interaction with metals. Hill plots of equilibrium dialysis data suggest that metal binding to cell walls involves negative cooperativity. Competition between various metals for binding sites suggested that the cations complex with identical sites on the cell walls. When the hydrogen ion concentration was increased, the affinity of the walls for metals decreased, but the numbers of metal binding sites remained constant, suggesting that cations and protons also compete for the same sites.     

Further evidence for the structure of the teichoic acids from Bacillus stearothermophilus B65 and Bacillus subtilis var. niger WM.

Bacillus stearothermophilus B65 and Bacillus subtilis var. niger WM both contain teichoic acids in their walls composed of glycerol, phosphate and glucose. The 13C nuclear magnetic resonance spectrum of B. stearothermophilus teichoic acid showed 13C-31P coupling on the signals from the C-5 and C-6 carbon atoms of the glucose molecule and an alpha-glucosidic linkage between glucose and the C-1 atom of the glycerol moiety. These data are consistent with a poly[glucosylglycerol phosphate] as the cell-wall teichoic acid in this organism. B. subtilis var. niger WM teichoic acid was oxidized by periodate and incubated in glycine buffer at pH 10.5. This treatment did not significantly increase the phosphomonoester content (by beta-elimination of the phosphate groups) of the teichoic acid molecule (7.1 to 9.5%), which is in accordance with earlier data derived from 13C nuclear magnetic resonance spectroscopy [De Boer et al. (1976) Eur. J. Biochem. 62, 1-6], that in this organism the glucose is not an integral part of the polymer chain. Similar treatment of B. stearothermophilus B65 teichoic acid increased the phosphomonoester content of the preparation from 0.15 to 68.1%.     

Function of alpha-D-glucosyl monophosphorylpolyprenol in biosynthesis of cell wall teichoic acids in Bacillus coagulans.

D-[alpha-14C]]glucosyl phosphorylpolyprenol ([ 14C]Glc-P-prenol) was formed from UDP-D-[14C]glucose in each of the membrane systems obtained from Bacillus coagulans AHU 1631 and AHU 1634 and two Bacillus megaterium strains. Membranes of these B. coagulans strains, which possess beta-D-glucosyl branches on the repeating units in their major cell wall teichoic acids, were shown to catalyze the transfer of the glucose residue from [14C]Glc-P-prenol to endogenous polymer. On the other hand, membranes of B. coagulans AHU 1366, which has no glucose substituents in the cell wall teichoic acid, exhibited neither [14C]Glc-P-prenol synthetase activity nor the activity of transferring glucose from [14C]Glc-P-prenol to endogenous acceptor. The enzyme which catalyzes the polymer glycosylation in the former two B. coagulans strains was most active at pH 5.5 and in the presence of the Mg2+ ion. The apparent Km for [14C]Glc-P-prenol was 0.6 microM. Hydrogen fluoride hydrolysis of the [14C]glucose-linked polymer product yielded a major fragment identical to D-galactosyl-alpha(1----2)(D-glucosyl-beta(1----1/3)) glycerol, the dephosphorylated repeating unit in the major cell wall teichoic acids of these B. coagulans strains. This result, together with the behavior of the radioactive polymer in chromatography on Sepharose CL-6B, DEAE-Sephacel, and Octyl-Sepharose CL-4B, led to the conclusion that [14C]Glc-P-prenol serves as an intermediate in the formation of beta-D-glucosyl branches on the polymer chains of cell wall teichoic acids in B. coagulans.