Isolation and characterization of a mutant of Staphylococcus aureus deficient in autolytic activity.

A mutant of Staphylococcus aureus H (RUS3) uas isolated after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. The rate of autolysis of whole cells and isolated cell walls of RUS3 was less than 10% of the parent strain. In addition, the ability of the crude soluble enzyme isolated from RUS3 to degrade cell walls was negligible compared with the parent strain. The cell wall composition and the generation time of RUS3 were comparable to the parent strain. Unlike S. aureus H, RUS3 grew in clumps and did not undergo cell wall turnover. Both strains exhibited identical kinetics of killing by penicillin G. This may indicate that autolytic enzymes play a role in cell wall turnover and cell separation, but in S. aureus most of the autolytic activity is unrelated to the lethal effect of cell wall antibiotics.     

Regulation of bacterial cell walls: correlation between autolytic activity and cell wall turnover in Staphylococcus aureus.

Cell wall turnover was examined in parent and mutant strains of Staphylococcus aureus. Peptidoglycan and teichoic acid were observed to undergo turnover in the wild-type strain during exponential growth; however, the rate of turnover did not decrease when the growth rate slowed, as the culture entered stationary phase. Isolated native cell walls and crude soluble autolytic enzyme were prepared from cells harvested during exponential and postexponential phases of growth. Native cell walls from both phases of growth autolyzed in buffer at identical rates; similarily, crude soluble enzyme from both preparations degraded radioactive cell walls at the same rate. Therefore, the activity of the autolysin in both exponential and postexponential cells was similar. The autolysis of whole cells of a mutant tar-1 was enhanced by 1.0 M NaCl. When 1.0 M NaCl was present under growing conditions, the rate of cell wall turnover was greatly increased. The presence of chloramphenicol, which inhibits whole-cell autolysis, also inhibited turnover. Analysis of the cell wall material recovered from spent medium revealed products consistent with the known mode of action of the endogenous autolysin. It is concluded that cell wall turnover in S. aureus is independent of the stage of culture growth but is dependent instead on the activity of the autolysin.     

Cell Wall Composition and Associated Properties of Methicillin-Resistant Staphylococcus aureus Strains

Methicillin-resistant (MR) Staphylococcus aureus strains have previously been reported to be deficient in surface negative charge; this has been correlated with methicillin resistance and ascribed to a deficiency of teichoic acid at the cell surface (A. W. Hill and A. M. James, Microbios 6:157-167, 1972). Teichoic acid was present in walls of MR organisms as revealed by appreciable phosphate levels and detection of ribitol residues. Phosphate levels in walls from five MR strains (0.54 to 0.77 mumol/mg of wall) were lower than in three unrelated methicillin-sensitive (MS) strains (0.86 to 1.0 mumol/mg of wall). However, two MS strains derived from two of the MR strains had wall phosphate levels very similar to those of the MR strains. No evidence for unusual wall polymers was found. Simple deficiency of wall teichoic acid does not result in methicillin resistance since an independently isolated teichoic acid-deficient strain (0.1 mumol of phosphate per mg of wall) was not methicillin resistant. In studies of biological properties possibly related to wall teichoic acid, it was discovered that walls isolated from MR organisms grown in the presence of methicillin autolyzed more rapidly than those isolated from organisms grown in the absence of the drug. Since methicillin resistance is enhanced by NaCl and suppressed by ethylenediaminetetraacetate, the effects of these compounds on autolysis of isolated walls were studied. NaCl (1.0 M) and ethylenediaminetetraacetate (1.0 mM) inhibited the autolysis of walls isolated from MR and MS strains. An MR strain bound phage 47, 52A, and 3A only slightly less well than their respective propagating strains.     

Relationship between the Latent Form and the Active Form of the Autolytic Enzyme of Streptococcus faecalis

A 10-hr starvation of Streptococcus faecalis ATCC 9790 for the amino acids methionine and threonine results in cells which are resistant to autolysis and which contain greatly reduced quantities of both active and latent (proteinase activable) forms of the autolytic enzyme (an N-acetyl-muramide glycanhydrolase). Cell walls were isolated from cells harvested at various times during the recovery from such starvation and were assayed for active and latent forms of the autolysin. Within 10 min of recovery the latent enzyme began to increase. Only after 30 to 60 min did the active enzyme begin to increase; after a similar lag, the cells' proneness to lysis markedly increased. The intracellular localization of both forms of the autolysin was examined, using as an experimental tool the ability of added cell wall to bind autolysin. (14)C-lysine-labeled, inactivated cell walls were added to exponential-phase cells, which were then disrupted, and the mixed wall population was isolated. Measurement of the (14)C release during wall autolysis indicated that the active enzyme in the cells was not available for binding to the added (14)C-labeled walls and was therefore wall-bound in vivo. In contrast, up to 85% of latent autolysin activity was found to have been efficiently bound to the added (14)C walls. The results obtained suggest (i) cellular autolysis is a reflection of the level of active enzyme and not of latent enzyme, and (ii) autolysin is synthesized and mainly located in the cytoplasm as an inactive latent precursor (proenzyme) which is transported to sites on the cell wall associated with wall biosynthesis, where it becomes activated.     

Cell wall structure regulates the autolytic process throughout growth of Cicer arietinum epicotyls

The autolytic process in epicotyl cell walls of Cicer arietinum L. cv. Castellana, and also the hydrolysis of heat-inactivated cell walls as mediated by a cell wall β-galactosidase (EC 3.2.1.23) (named βIII and previously characterized as responsible for the autolysis), are maximal on the fourth day of germination and coincide with the maximal growth capacity. They decrease during the following days, in which the growth rate diminishes. In both cases, no differences were observed in the percentages of the different sugars released, galactose being the principal one. The βIII fraction from aged epicotyl cell walls hydrolyzed young walls in proportion to its specific activity, and more efficient than when cell walls from aged material were used as the substrate. The βIII fraction from 4 day-old epicotyls (the time for maximal autolysis) was incapable of hydrolyzing aged epicotyl cell walls to the same extent as young ones. These results, together with the levels and activity of the enzyme throughout growth, allow the assumption that the variations in the autolysis and hydrolysis caused by βIII during growth processes are due to structural modifications in the cells walls, modifications that would limit access of the enzyme to its substrate, thus impeding the release of galactose, even though the enzyme is present.     

Regulation of Bacterial Cell Walls: Turnover of Cell Wall in Staphylococcus aureus

The cell wall of Staphylococcus aureus was shown to undergo turnover during exponential growth. The rate of turnover, about 15% per generation, was identical for both cell wall polymers, peptidoglycan and teichoic acid. Both the old and newly synthesized wall material appeared to undergo turnover at similar rates. The rate of turnover followed first-order kinetics until more than 90% of the original wall was lost. Cell wall turnover was completely blocked under conditions of unbalanced synthesis known to inhibit cellular autolysis, e.g., addition of chloramphenicol. Cell wall turnover was shown to occur in a number of different strains of S. aureus and appears to be widely distributed in this species.     

Autolysis of cell walls in pea epicotyls during growth. Enzymatic activities involved

Pisum sativum L. (cv. Lincoln) epicotyl cell walls show autohydrolysis and release into the incubation medium up to 120 μg of sugar per mg of cell wall dry weight in 30 h. Cell walls from younger epicotyls with high growth capacity showed higher auto-lytic capacity than older epicotyls. This suggests that both processes, growth and au-tolysis, are related. The proteins responsible for autolysis were extracted from the wall fraction with high saline solution (3 M LiCl) and enzymatic activities associated with the proteins were studied. The highest activity corresponded to α-galactosidase; lower activities were found for β-galactosidase, a-arabinosidase and exoglucanase. Changes in enzymatic activities and changes in the proportion of sugars released in autolysis by cell walls during the growth of epicotyls support the notion that α-galac-tosidase is one of the enzymes involved in the process of autolysis, and that the liberation of arabinose and galactose in this process occurs as arabinogalactan.     

Cell wall degradation in the autolysis of filamentous fungi

A systematic study on autolysis of the cell walls of fungi has been made on Neurospora crassa, Botrytis cinerea, Polystictus versicolor, Aspergillus nidulans, Schizophyllum commune, Aspergillus niger, and Mucor mucedo. During autolysis each fungus produces the necessary lytic enzymes for its autodegradation. From autolyzed cultures of each fungus enzymatic precipitates were obtained. The degree of lysis of the cell walls, obtained from non-autolyzed mycelia, was studied by incubating these cell walls with and without a supply of their own lytic enzymes. The degree of lysis increased with the incubation time and generally was higher with a supply of lytic enzymes.Cell walls from mycelia of different ages were obtained. A higher degree of lysis was always found, in young cell walls than in older cell walls, when exogenous lytic enzymes were present.In all the fungi studied, there is lysis of the cell walls during autolysis. This is confirmed by the change of the cell wall structure as well as by the degree of lysis reached by the cell wall and the release of substances, principally glucose and N-acetylglucosamine in the medium.     

Electrostatic effects and the dynamics of enzyme reactions at the surface of plant cells. 3. Interplay between limited cell-wall autolysis, pectin methyl esterase activity and electrostatic effects in soybean cell walls

Soybean cell walls display a process of autolysis which results in the release of reducing sugars from the walls. Loosening and autolysis of cell wall are involved in the cell-wall growth process, for autolysis is maximum during both cell extension and cell-wall synthesis. Autolysis goes to completion within about 50 h and is an enzymatic process that results from the activity of cell wall exo- and endo-glycosyltransferases. The optimum pH of autolysis is about 5. Increasing the ionic strength of the bulk phase where cell-wall fragments are suspended, results in a shift of the pH profile towards low pH. This is consistent with the view that at 'low' ionic strength, the local pH in the cell wall is lower than in the bulk phase. One of the main ideas of the model proposed in a preceding paper, is that pectin methyl esterase reaction, by building up a high fixed charge density, results in proton attraction in the wall. Low pH must then activate the wall loosening enzymes involved in autolysis and cell growth. This view may be directly confirmed experimentally. The pH of a cell-wall suspension, initially equal to 5, was brought to 8 for 20 min, then back to 5. Under these conditions, the rate of cell-wall autolysis was enhanced with respect to the rate of autolysis obtained with cell-wall fragments kept at pH 5. The pH response of the multienzyme plant cell-wall system basically relies on opposite pH sensitivities of the two types of enzymes involved in the growth process. Pectin methyl esterase, which generates the cell-wall Donnan potential, is inhibited by protons, whereas the wall-loosening enzymes involved in cell growth are activated by protons.     

Alterations of cell wall structure and metabolism accompany reduced susceptibility to vancomycin in an isogenic series of clinical isolates of Staphylococcus aureus

A series of isogenic methicillin-resistant Staphylococcus aureus isolates recovered from a bacteremic patient were shown to acquire gradually increasing levels of resistance to vancomycin during chemotherapy with the drug (K. Sieradzki, T. Leski, L. Borio, J. Dick, and A. Tomasz, J. Clin. Microbiol. 41:1687-1693, 2003). We compared properties of the earliest (parental) vancomycin-susceptible isolate, JH1 (MIC, 1 microg/ml), to two late (progeny) isolates, JH9 and JH14 (vancomycin MIC, 8 microg/ml). The resistant isolates produced abnormally thick cell walls and poorly separated cells when grown in antibiotic-free medium. Chemical analysis of the resistant isolates showed decreased cross-linkage of the peptidoglycan and drastically reduced levels of PBP4 as determined by the fluorographic assay. Resistant isolates showed reduced rates of cell wall turnover and autolysis. In vitro hydrolysis of resistant cell walls by autolytic extracts prepared from either susceptible or resistant strains was also slow, and this abnormality could be traced to a quantitative (or qualitative) change in the wall teichoic acid component of resistant isolates. Some change in the structure and/or metabolism of teichoic acids appears to be an important component of the mechanism of decreased susceptibility to vancomycin in S. aureus.     

Autolytic Enzyme System of Streptococcus faecalis III. Localization of the Autolysin at the Sites of Cell Wall Synthesis

Cell walls from exponential-phase cultures of Streptococcus faecalis ATCC 9790 autolyzed in dilute buffers. Walls were isolated from cultures grown in the presence of (14)C-lysine for about 10 generations and then on (12)C-lysine for 0.1 to 0.8 of a generation (prelabeled). These walls released (14)C to the soluble fraction more slowly than they lost turbidity during the initial stages of autolysis. Walls isolated from cultures grown in the presence of (14)C-lysine for only the last 0.1 to 0.4 of a generation (postlabeled) released (14)C to the supernatant fluid more rapidly than they lost turbidity. Autolysin in both pre- and postlabeled walls was inactivated, and such walls were then incubated in the presence of unlabeled walls containing active autolysin. The inactivated walls lost their (14)C label only very slowly until autolysis of the unlabeled walls was virtually complete and release of soluble autolysin was expected. When this experiment was done in the presence of trypsin, a fourfold increase in the autolysis rate resulted, but the same pattern of (14)C release was observed. A parallel release of (14)C and loss of turbidity from pre- or postlabeled walls was observed upon trypsin "activation" and by addition of isolated soluble autolysin to inactivated walls. We conclude that the wall-bound autolysin acts first on the more recently synthesized portion of the wall. Trypsin appears to speed wall autolysis by activating additional latent autolysin in situ at sites in the older portion of the wall.     

Cell wall-DNA association in Bacillus subtilis.

Autolysis of cell walls of Bacillus subtilis 168 resulted in solubilization of wall-associated DNA. Most of the DNA was solubilized only in the later stages of autolysis. Solubilization of up to 70% of the wall by autolysins resulted in only 25 to 30% solubilization of wall-associated DNA. When the wall fragments remaining after 70% autolysis were analyzed by electron microscopy, it was observed that the preparations were highly enriched for completed septa, or poles. Partial autolysis at pH 5.2 or pH 8.6, both of which reflect hydrogen ion levels that permit either N-acetylglucosaminidase or N-acetylmuramyl-L-alanine amidase, but not both, to act, gave rise to enrichment of cell poles. When walls were incubated with subtilisin, DNase, or RNase, release of DNA (or DNA fragments) was accelerated. Density gradient centrifugation patterns of lysates of cells pulse-labeled with N-[3H]acetylglucosamine and then chased revealed that a small, but significant, proportion of the radioactivity sedimented to a density position equivalent to that of DNA-membrane complexes. Because the pulse-chase sequence enriched for radioactivity in cell poles, the results suggest that at least some molecules from polar cell walls have an affinity for DNA-membrane complexes. We suggest that DNA binds strongly, possibly via a DNA-membrane complex, to cell poles of B. subtilis. The results provide support for a view offered previously (Koch et al., FEMS Microbiol. Lett. 12:201-208, 1981) that some special structure in or very near the poles of gram-positive bacilli is involved in the segregation of DNA during cell division.     

Autolysis of Lactococci: Detection of Lytic Enzymes by Polyacrylamide Gel Electrophoresis and Characterization in Buffer Systems

Lactococcal strains were screened for bacteriolytic activity against Micrococcus luteus cells, lactococcal cells, and cell walls. Thirty strains were screened for bacteriolytic activity against cells and cell walls incorporated into agar medium. Enzymes from all strains hydrolyzed the substrates; however, the activity against Micrococcus cells was much higher than against Lactococcus cells or cell walls. Electrophoretic profiles of bacteriolytic activities of culture supernatants, sodium dodecyl sulfate-treated cell extracts, cell wall fractions, and cell extracts were analyzed in sodium dodecyl sulfate-polyacrylamide gels containing M. luteus cells or lactococcal cell walls as the substrate. The 22 strains tested contained two to five lytic bands in the culture supernatant, ranging in size between 32 and 53 kDa. The cell extracts, the sodium dodecyl sulfate-treated cell extracts, and the cell wall fractions revealed two lytic bands of 47 and 53 kDa. Effects of external factors on autolysis of some strains were determined in buffer systems. Optimal autolysis was observed in the exponential growth phase at pH 6.0 to 7.5 and at a temperature of 30(deg)C. Two of three strains tested seemed to contain a glycosidase, and all three strains contained an N-acetylmuramyl-l-alanine amidase or an endopeptidase.     

Behaviour of the cell walls of Aspergillus niger during the autolytic phase of growth

Abstract Autolysis of Aspergillus niger cultures has been studied. The stability of the cell wall fraction was followed throughout a 57-day period of autolysis. The results indicated that both a persistence of existing walls and an extra wall deposition due to continued synthesis of walls or wall components during the first 12 days of autolysis seem to take place.     

Autolysis of microbial cells: salt activation of autolytic enzymes in a mutant of Staphylococcus aureus

The effect of various salts on the autolysis of cell wall of a ribitol teichoic acid-deficient mutant of Staphylococcus aureus H (strain 52A5 carrying tar-1) was compared with the parent strain. In the presence of high concentrations of certain salts such as 1.0 m NaCl, the mutant undergoes autolysis with the release of osmotically sensitive spheroplasts. The parent strain is not affected by these conditions. The stimulation of lysis is related to an activation of N-acylmuramyl-l-alanine amidase.     

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.     

Modification of autolysis by synthetic peptides derived from the presumptive binding domain of Staphylococcus aureus autolysin

The autolytic cell wall hydrolase of Staphylococcus aureus, Atl, contains three highly cationic repeats in the central region of the amino acid sequence, and the repeats are presumed to have the role of binding the enzyme to some components on the cell surface. To explain the possible function of the repeats, we synthesized a number of 10- to 30-mer oligopeptides based on the Atl amino acid sequence (Thr432-Lys610) containing repeat 1, and examined their effects on the autolysis of S. aureus cells. When the peptides were added to a cell suspension of S. aureus under low ionic strength conditions, five peptides, A10, A11, A14, A16 and B9, showed immediate increases in optical density (OD) of the cell suspension accompanied by decreases in viable cell counts. After the immediate increases, the ODs for A10 and A14 changed little in the first 2 hr. In contrast, the ODs for A11 and A16 decreased rapidly. When peptide A10 was added to suspensions of heat-killed whole cells, crude cell walls and a crude peptidoglycan preparation, their ODs were increased approximately 2-fold. In contrast, the OD was not increased when the peptide was added to a suspension of pure peptidoglycan from which anionic polymers had been removed. Light microscopic and transmission electron microscopic study showed that A10 and A14 inhibited autolysis and that A11 and A16 induced autolysis earlier than the control. These results suggest strongly that the peptides adsorb to and precipitate on the anionic cell surface polymers such as teichoic acid and lipoteichoic acid via ionic interaction. The effects of peptides on the autolysis may be the results of the modification of S. aureus autolysin activities. These peptides, especially the 10-mer peptide B9 (PGTKLYTVPW) that represents the C-terminal half of A10 and N-terminal half of A11, may be important segments for Atl to bind to the cell surface.     

Zero order kinetics of cell wall turnover inStaphylococcus aureus

Cells exponentially grown from four strains ofS. aureus (SG 511, H, 52A5G, and248 PN-1) and uniformly labeled in their walls with³H-N-acetylglucosamine, were found to turn over their old walls at constant rates of up to 25% per generation. Wall turnover was not observed to follow first order kinetics, thus ruling out the implication that maintenance of normal wall thickness was achieved by a random distribution of new wall components in the old wall. Instead, wall turnover in all cases strictly followed zero order kinetics, indicating that newly synthesized wall material was placed layer by layer beneath the inner surface of the old cell wall. This finding correlates with evidence obtained from earlier electron microscopic investigations into the regeneration of the staphylococcal cell wall after chloramphenicol treatment. Based on the experimental data presented, a simplified model for wall turnover of the growing staphylococcal cell was proposed. The model also takes into account the finding, derived from additional experiments with strainSG 511, that the total cell wall turned over at a somewhat higher rate than the old portions of the wall. The rates of cell wall turnover found inS. aureus SG 511 are the highest reported to date for pathogenic bacteria. The medical implications of this finding were discussed.     

Use of resistant mutants to study the interaction of triton X-100 with Staphylococcus aureus.

Staphylococcus aureus mutants resistant to the nonionic detergent Triton X-100, isolated from the wild-type strain H and the autolysin-deficient strain RUS3, could grow and divide in broth containing 5% (vol/vol) Triton X-100, while growth of the parental strains was markedly inhibited above the critical micellar concentration (0.02%) of the detergent. Growth-inhibitory concentrations of Triton X-100 killed wild-type cells without demonstrable cellular lysis. Triton X-100 stimulated autolysin activity of S. aureus cells under nongrowing conditions, and this lytic response was markedly reduced in energy-poisoned cells. In contrast, the detergent had no effect on the activity of autolysins in cell-free systems, and growth in the presence of Triton X-100 did not alter either the cellular autolysin activity or the susceptibility of cell walls to exogenous lytic enzymes. Treatment with either Triton X-100 or penicillin G in the growth medium stimulated release of predominantly acylated intracellular lipoteichoic acid and sensitized staphylococci to Triton X-100-induced autolysis. There was no significant difference in the cell wall and membrane compositions or Triton X-100 binding between the parental strains and the resistant mutants. The resistant mutant TXR1, derived from S. aureus H, had a higher level of L-alpha-glycerophosphate dehydrogenase activity, and its oxygen uptake was more resistant to inhibition by a submicellar concentration (0.008%) of Triton X-100. Growth in the presence of subinhibitory concentrations of Triton X-100 rendered S. aureus H cells phenotypically resistant to the detergent and greatly stimulated the level of oxygen uptake. Membranes isolated from such cells exhibited enhanced activity of the respiratory enzymes succinic dehydrogenase and L-alpha-glycerophosphate dehydrogenase.     

Auxin-enhanced glucan autohydrolysis in maize coleoptile cell walls

Cell walls isolated from auxin-pretreated maize (Zea mays L.) coleoptile segments were assayed to disclose evidence for the existence of enhanced autolysis. To improve the sensitivity of the measurements and to facilitate kinetic analysis, isolated cell walls were consolidated within a small column, and the autolysis rate was directly determined from the sugar content of the effluent. This protocol revealed that the maximum rate of autohydrolysis of walls prepared from segments occurs within the first 2 hours and a steady decline commences almost immediately. Walls from indoleacetic acid pretreated segments (0.5-4 hours) released sugar at a higher rate initially (110-125% of controls) and the enhanced rate of autolysis continued for 6 to 8 hours, but then it became equivalent to that of the controls. Pretreatment of the segments at acidic pH had no effect on the measurable rates of autolysis. The (1→3), (1→4)-β-d-glucan content of the walls and the extractable glucanase activities support the hypothesis that temporal enhancement of autohydrolysis is a function of auxin on enzyme activity. The progressive decline in autolysis during prolonged incubations is consistent with the decrease in the quantity of the β-d-glucan in the wall. The relationship between glucan content and autolysis rate is supported by the observation that while glucose pretreatment of segments had only a small effect on initial autolysis rates, the presence of the sugar during pretreatment served to extend the interval over which higher rates of autolysis could be sustained. The results demonstrate that autolysis is related to auxin-induced wall metabolism in maize coleoptiles.