LYSIS OF STREPTOCOCCUS FAECALIS

Role of Temperate Bacteriophage ϕ20617 on Streptococcus thermophilus DSM 20617T Autolysis and Biology

Streptococcus thermophilus DSM 20167^T showed autolytic behavior when cultured in lactose- and sucrose-limited conditions. The amount of cell lysis induced was inversely related to the energetic status of the cells, as demonstrated by exposing cells to membrane-uncoupling and glycolysis inhibitors. Genome sequence analysis of strain DSM 20617^T revealed the presence of a pac-type temperate bacteriophage, designated Φ20617, whose genomic organization and structure resemble those of temperate streptococcal bacteriophages. The prophage integrated at the 3'-end of the gene encoding the glycolytic enzyme enolase (eno), between eno and the lipoteichoic acid synthase-encoding gene ltaS, affecting their transcription. Comparative experiments conducted on the wild-type strain and a phage-cured derivative strain revealed that the cell-wall integrity of the lysogenic strain was compromised even in the absence of detectable cell lysis. More importantly, adhesion to solid surfaces and heat resistance were significantly higher in the lysogenic strain than in the phage-cured derivative. The characterization of the phenotype of a lysogenic S. thermophilus and its phage-cured derivative is relevant to understanding the ecological constraints that drive the stable association between a temperate phage and its bacterial host.

Replacement of Lysine by Hydroxylysine and Its Effects on Cell Lysis in Streptococcus faecalis

Shockman, Gerald D. (Temple University, Philadelphia, Pa.), J. Stuart Thompson, and Margaret J. Conover. Replacement of lysine by hydroxylysine and its effects on cell lysis in Streptococcus faecalis. J. Bacteriol. 90:575-588. 1965.-Hydroxylysine was not significantly incorporated by Streptococcus faecalis ATCC 9790 or 8043 until exponential growth ceased as a result of lysine exhaustion. Uptake was then rapid and virtually complete within 1 hr. Lysine absence, rather than physiological age, seemed to be the governing factor. Hydroxylysine uptake rapidly reached a peak in the acid-soluble fraction, suggesting a precursor role for substances in this fraction. Substitution of hydroxylysine for lysine was much more efficient in mucopeptide synthesis than in protein synthesis. In wall medium, less than 1% of the incorporated hydroxylysine was found in the protein fraction. Addition of lysine to both growth and wall media inhibited both further hydroxylysine uptake and transfer of hydroxylysine from acid-soluble to mucopeptide or protein fractions. Hydroxylysine resulted in decreased penicillin susceptibility only after it was postexponentially incorporated. This effect was physiologically similar to that seen after threonine deprivation or chloramphenicol treatment. Hydroxylysine incorporation increased resistance to autolysis, but failed to decrease lysozyme susceptibility when measured after heat inactivation of autolysis. Electron microscopy of negatively stained cells showed increased thickness of cell walls containing hydroxylysine. Thus, most of the effects of replacement of lysine by hydroxylysine resemble those seen after deprivation of a nonwall amino acid (e.g., threonine or valine) or after chloramphenicol treatment. Each of these conditions results in inhibition of protein synthesis while permitting cell-wall synthesis to continue, resulting in autolysis-resistant, thick-walled cells.

Characterization of Streptococcus thermophilus strains that undergo lysis under unfavourable environmental conditions

The autolysis of starter lactic acid bacteria appears as a promising way to enhance the flavour of fermented dairy products. The present work was aimed at investigating the autolysis phenomenon in Streptococcus thermophilus, a thermophilic lactic acid bacteria involved in the starters used for the production of yoghurts, Italian and Swiss-type cheeses. Out of 146 strains screened for their aptitude to spontaneously lyse at the end of growth in M17 medium containing lactose in limited concentration, six strains, among which is the type strain CNRZ 1358, were found to be highly autolytic. These autolytic strains are characterized by a typical bell-shaped growth curve. Lysis of the type strain, which was studied as the model, was triggered under unfavourable environmental conditions, such as lactose depletion and NaCl or organic solvents addition. The lysogenic character of this strain was evidenced. Taken together, our results indicate that the autolytic phenotype in S. thermophilus is linked to the lysogenic character but does not result from the massive prophage induction under stressing conditions.

The Streptococcus thermophilus autolytic phenotype results from a leaky prophage

Streptococcus thermophilus autolytic strains are characterized by a typical bell-shaped growth curve when grown under appropriate conditions. The cellular mechanisms involved in the triggering of lysis and the bacteriolytic activities of these strains were investigated in this study. Lactose depletion and organic solvents (ethanol, methanol, and chloroform) were shown to trigger a premature and immediate lysis of M17 exponentially growing cells. These factors and compounds are suspected to act by altering the cell envelope properties, causing either the permeabilization (organic solvents) or the depolarization (lactose depletion) of the cytoplasmic membrane. The autolytic character was shown to be associated with lysogeny. Phage particles, most of which were defective, were observed in the culture supernatants after both mitomycin C-induced and spontaneous lysis. By renaturing sodium dodecyl sulfate-polyacrylamide gel electrophoresis, a bacteriolytic activity was detected at 31 kDa exclusively in the autolytic strains. This enzyme was detected during both growth and spontaneous lysis with the same intensity. We have shown that it was prophage encoded and homologous to the endolysin Lyt51 of the streptococcal temperate bacteriophage phi01205 (M. Sheehan, E. Stanley, G. F. Fitzgerald, and D. van Sinderen, Appl. Environ. Microbiol. 65:569-577, 1999). It appears from our results that the autolytic properties are conferred to the S. thermophilus strains by a leaky prophage but do not result from massive prophage induction. More specifically, we propose that phagic genes are constitutively expressed in almost all the cells at a low and nonlethal level and that lysis is controlled and achieved by the prophage-encoded lysis proteins.

Formation of protoplasts from Streptococcus faecalis by lysozyme

Bibb, William R. (University of North Carolina, Chapel Hill) and W. R. Straughn. Formation of protoplasts from Streptococcus faecalis by lysozyme. J. Bacteriol. 84:1094-1098. 1962.-Incubation of whole cells of Streptococcus faecalis F24 in the presence of the crystalline egg-white lysozyme and appropriate sucrose concentration resulted in the formation of discrete spherical structures. On dilution, these osmotically fragile structures lysed immediately. Methyl pentose determinations on isolated cell walls and protoplast membranes verified the presence of rhamnose in the cell walls and its essentially complete absence in protoplast membranes. Cell walls were rendered soluble by lysozyme. After lysozyme treatment of cell walls, 96% of the rhamnose present was not sedimented by centrifugation at 12,500 x g for 30 min. No cell-wall structures were recognized by phasecontrast or electron microscopy. After direct lysis of whole cells of S. faecalis F24 by lysozyme, protoplast membranes were isolated. It is concluded that, in the strain of group D streptococcus studied, lysozyme effectively removes the cell wall.

Inhibition by antibiotics of the growth of bacterial and yeast protoplasts

Shockman, Gerald D. (Temple University School of Medicine, Philadelphia, Pa.) and J. Oliver Lampen. Inhibition by antibiotics of the growth of bacterial and yeast protoplasts. J. Bacteriol. 84:508-512. 1962.-The characteristics and requirements for growth of bacterial (Streptococcus faecalis) and yeast (Saccharomyces cerevisiae) protoplasts were established and the effect of a variety of antibacterial and antifungal antibiotics determined. A clear differentiation was obtained between such inhibitors of bacterial cell wall synthesis as penicillin and cycloserine, which did not prevent protoplast growth, and all others, antibacterial and antifungal, which inhibited protoplasts and intact organisms at the same range of concentration. Novobiocin, previously reported to inhibit bacterial wall synthesis, was also effective against a reaction(s) essential to the growth of S. faecalis protoplasts. The antibacterial action of streptomycin, neomycin, and kanamycin was essentially eliminated by the high salt concentration needed to maintain the protoplasts. Removal of the cell wall did not significantly increase antibiotic susceptibility of a resistant species. Protoplasts of Bacillus megaterium were insensitive to the antifungal agent, nystatin, and did not bind it to any detectable degree. Thus, the yeast or bacterial cell wall does not appear to play a major role in determining relative antibiotic susceptibility by masking internal sensitive target sites. A variety of antifungal antibiotics tested on the growth of log-phase yeast cells failed to produce osmotically fragile forms.

Evidence that the PBP 5 synthesis repressor (psr) of Enterococcus hirae is also involved in the regulation of cell wall composition and other cell wall-related properties

psr has been reported by M. Ligozzi, F. Pittaluga, and R. Fontana, (J. Bacteriol. 175:2046-2051, 1993) to be a genetic element located just upstream of the structural gene for the low-affinity penicillin-binding protein 5 (PBP 5) in the chromosome of Enterococcus hirae ATCC 9790 and to be involved in the repression of PBP 5 synthesis. By comparing properties of strains of E. hirae that contain a full-length, functional psr with those of strains that possess a truncated form of the gene, we have obtained data that indicate that psr is involved in the regulation of several additional surface-related properties. We observed that cells of strains that possessed a truncated psr were more sensitive to lysozyme-catalyzed protoplast formation, autolyzed more rapidly in 10 mM sodium phosphate (pH 6.8), and, in contrast to strains that possess a functional psr, retained these characteristics after the cultures entered the stationary growth phase. Cellular lytic properties did not correlate with differences in the cellular contents of muramidase-1 or muramidase-2, with the levels of PBP 5 produced, or with the penicillin susceptibilities of the strains. However, a strong correlation was observed with the amounts of rhamnose present in the cell walls of the various strains. All of the strains examined that possessed a truncated form of psr also possessed approximately one-half of the rhamnose content present in the walls of strains that possessed a functional psr. These data suggest that psr is also involved in the regulation of the synthesis of, or covalent linkage to the cell wall peptidoglycan of, a rhamnose-rich polysaccharide. These differences in cell wall composition could be responsible for the observed phenotypic differences. However, the multiple effects of psr suggest that it is part of a global regulatory system that, perhaps independently, affects several cell surface-related properties.

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.

Observations on the tolerance and the paradoxical effect in enterococci

Enterococci, already know to be relatively unaffected by several antibiotics due to their inheritant characteristics, are increasingly resistant to some very important groups of drugs, by means of acquisition or exchange of new genetic traits of resistance. Resistance or moderate susceptibility towards penicillin is an interesting characteristic of enterococci, whose low degree of susceptibility to this drug is due to a low affinity for penicillin-binding proteins (PBP). Some strains of enterococci are not killed by the action of this drug but are "tolerant" (MIC/MBC > 32 mg/l). This kind of "resistance", in which the probability of surviving under selective pressure of the drug is increased, is probably linked to the deficiency of the cell's autolytic system. Only rarely does another form of resistance called the "paradoxical effect" appear, in which higher numbers of cells survive at high concentrations than at lower concentrations. In our study the degree of bactericidal activity of some beta-lactams was considered. Our results demonstrate that: i) the paradoxical effect appears more in cultures in exponential phase compared to aged cultures; ii) mutated strains show an increased number of cells that respond paradoxically (the behavior is genetically determined); iii) different beta-lactams induced different degrees of autolysis.

The autolytic ('suicidase') system of Enterococcus hirae: from lysine depletion autolysis to biochemical and molecular studies of the two muramidases of Enterococcus hirae ATCC 9790

Autolysis of Enterococcus hirae ATCC 9790 is the result of the action of endogenous enzymes that hydrolyze bonds in the protective and shape-maintaining cell wall peptidoglycan. It is thought that these potentially suicidal enzymes play a positive role(s) in wall growth and division and are expressed as autolysins when cell wall assembly and/or repair are inhibited. E. hirae possesses two potentially autolytic enzymes, both of which are muramidases. Although they hydrolyze the same bond as hen egg-white lysozyme, both are high-molecular-mass, complex enzymes. Muramidase-1 is synthesized as a zymogen, requiring protease activation. It is a glucoenzyme that is also multiply nucleotidylated with an unusual nucleotide, 5-mercaptouridine monophosphate. Muramidase-2 is almost certainly a product of a separate gene. The deduced amino acid sequence of a cloned gene for extracellular muramidase-2 showed several unusual features. It appears to be a two-, or perhaps three-domain protein with a putative glycosidase-active site near the N-terminal end and six 45-amino-acid-long repeats at the C-terminal end which are presumed to be involved with high-affinity binding to the insoluble peptidoglycan substrate. Muramidase-2 binds penicillin with low affinity. The presence of several amino acid groupings characteristic of serine-active site beta-lactam-interactive proteins is consistent with the possible presence of a penicillin-binding, third domain. Indirect evidence consistent with a role(s) for these enzymes in cell wall growth and division has been obtained. However, proof of such role(s) awaits modern genetic, molecular, and biochemical analyses.

Synergism between penicillin G and the antimicrobial ether lipid, rac-1-dodecylglycerol, acting below its critical micelle concentration

rac-1-Dodecylglycerol (DDG) and penicillin G (Pen G) act synergistically to dramatically lower the minimum inhibitory concentration (MIC) of each other in four Gram-positive bacteria studied. At one-half its MIC, DDG ether lowered the MIC of Pen G 10- to 80-fold. Under the same conditions, Pen G lowered the MIC of DDG 4- to 7.5-fold. The critical micelle concentration of DDG was determined to be 7.93 mg/ml (0.0305 mM), which is approximately two-fold greater than the minimum inhibitory concentration of DDG determined in the presence of a protein-free chemically defined medium. This finding suggests that DDG is not killing bacteria through its detergent action. Pen G also did not alter the critical micelle concentration of DDG, which indicates that the synergism between these two agents is not related to micelle formation.

Effect of NaCl and nafcillin on penicillin-binding protein 2a and heterogeneous expression of methicillin resistance in Staphylococcus aureus

Expression of methicillin resistance in heterogeneous strains of Staphylococcus aureus is enhanced by 2 to 5% NaCl in the medium and by selection with beta-lactam antibiotics. Resistance is associated with production of a penicillin-binding protein (PBP), PBP 2a, with low affinity for binding beta-lactam antibiotics. Therefore, the effects of NaCl and nafcillin on amounts of PBP 2a produced and its binding affinity were examined and correlated with expression of resistance. Nafcillin-triggered autolysis also was examined. No relationships between the level of resistance expressed and (i) relative amounts of PBP 2a, (ii) inducibility of PBP 2a by nafcillin, or (iii) binding affinity of nafcillin for PBP 2a were found. A protective effect of NaCl for the susceptible subpopulation, corresponding to inhibition of autolysis, was observed for heterogeneous strains. Even in the absence of NaCl, highly resistant cells were relatively tolerant to nafcillin-triggered autolysis. These results support the hypothesis that high levels of resistance require an additional factor besides PBP 2a. This factor may act within the autolytic pathway.

Potential role of lysozyme in bactericidal activity of in vitro-acquired salivary pellicle against Streptococcus faecium 9790

The adherence of Streptococcus faecium 9790 to hydroxyapatite (HA) coated with whole saliva supernatant proteins (S-HA) or parotid fluid proteins was studied. The organism was labeled with [3H]thymidine, and adherence was estimated as the radioactivity remaining associated with the variously coated HA preparations after incubation and removal of unbound microbes by washing the adherence substratum. Adherence was time dependent and saturable, characteristics typical of oral streptococci in this in vitro adherence model system. However, adherence to S-HA, but not bare HA, was decreased 20-fold at 4 degrees C compared with room temperature. Furthermore, adherence at 4 degrees C to S-HA was decreased 20-fold relative to bare HA at 4 degrees C. Adherence to HA coated with parotid fluid proteins also was reduced at 4 degrees C. The magnitude of the temperature dependence and the inhibitory effect at 4 degrees C of whole saliva or parotid fluid pellicles on HA was unexpected. Of several sugars and amino sugars tested, the chitin saccharides, chitotriose, chitobiose, and N-acetylglucosamine caused greater than 90% inhibition of adherence to S-HA. These same saccharides were previously shown to inhibit lysozyme, polylysine, or autolytic lysis of the organism (N. J. Laible and G. R. Germaine, Infect. Immun. 48:720-728, 1985). Examination of unbound and adherent microbes revealed that lysis of the organism occurred during the adherence assays. A strong association (r = 0.83) between the extent of lysis and the extent of adherence was found under a variety of conditions. Depletion of lysozyme from saliva specimens used to coat HA resulted in a greater than 90% decrease in both cell lysis and adherence. Lysis of the microbe appeared dependent upon the presence of the saliva pellicle (coating) on HA, since solutions containing proteins desorbed from HA during mock-adherence incubations possessed lytic activity that was 2- to 10-fold too low to account for the extents of lysis observed with greater than or equal to 10(8) input cells. These results demonstrate the potential antibacterial activity of acquired salivary pellicle on enamel in vivo and the likely role of lysozyme in this activity. The data also serve to caution that this widely used in vitro adherence model will not distinguish whole-cell adherence from the adsorption of radiolabeled DNA released from lysing cells. Several additional controls are suggested that will indicate whether test microbes remain intact or lyse during adherence trials.

Prevention of Staphylococcus aureus lysis

Staphylococcus aureus S-6 cells grown in chemically defined media often lysed after exponential growth. Lysis could be prevented by the addition of alanine or proline before the culture reached stationary phase.

Protoplast formation and localization of enzymes in Streptococcus mitis

Cells of Streptococcus mitis ATCC 903 were converted to stable protoplasts by the cell wall-degrading M-1 enzyme of the mutanolysin complex isolated from Streptomyces globisporus. Over 90% of total glucokinase (EC 2.7.1.2), aminopeptidase (EC 3.4.11.1), and dextranglucosidase (EC 3.2.1.70) was recovered in the cytoplasmic fraction, whereas over 20% of total invertase (beta-fructofuranosidase: EC 3.2.1.26) was released during protoplast formation. ATPase (EC 3.6.1.3). chymotrypsin-like protease (EC 3.4.21.1), arginine aminopeptidase (EC 3.4.11.6), and lactate dehydrogenase (EC 1.1.1.27) were detected in Triton X-100 extracts of the cytoplasmic membrane fraction by crossed immunoelectrophoresis in combination with enzyme-staining procedures. By these methods, NADH dehydrogenase (EC 1.6.99.3), aminopeptidase, and lactate dehydrogenase were detected in the cytoplasmic fraction. Aminopeptidases in the cytoplasmic fraction differed from this activity in the membrane fractions in electrophoretic mobility and substrate specificity.

Antibiotic-induced lysis of enterococci

Enterococci are resistant to penicillin killing in vivo and in vitro. Because some bacteria resistant to penicillin killing have reduced autolytic activity, we examined the lysis of clinical enterococcal isolates suspended in buffer (spontaneous lysis), and compared it with their susceptibility to antibiotic-induced lysis and killing. We found significant correlations between spontaneous and antibiotic-induced lysis, using five antibiotics that inhibit cell wall synthesis (penicillin, cephalothin, bacitracin, cycloserine, and vancomycin). Among isolates, strains more rapidly lysed by one antibiotic were more rapidly lysed by the other antibiotics, and more susceptible to spontaneous lysis. In studies involving a single strain grown in different media, spontaneous lysis also correlated closely with antibiotic-induced lysis. These results are consistent with a common mechanism for spontaneous and antibiotic-induced lysis, such as the autolytic enzyme system. Human serum was one of the least permissive media tested for enterococcal growth and antibiotic-induced lysis and killing. We suggest that the inhibitory effect of human serum on growth and the activation of the enterococcal autolytic enzyme system may be a critical factor in the resistance of enterococcal endocarditis to treatment with penicillin alone.

Morphological and physiological study of autolytic-defective Streptococcus faecium strains

Three autolytic-defective mutants of Streptococcus faecium (S. faecalis ATCC 9790) were isolated. All three autolytic-defective mutants exhibited the following properties relative to the parental strain: (i) slower growth rates, especially in chemically defined medium; (ii) decreased rates of cellular autolysis and increased survival after exposure to antibiotics which block cell wall biosynthesis; (iii) decreased rates of cellular autolysis when treated with detergents, suspended in autolysis buffers, or grown in medium lacking essential cell wall precursors; (iv) a reduction in the total level of cellular autolytic enzyme (active plus latent forms of the enzyme); (v) an increased ratio of latent to active forms of autolysin; and (vi) increased levels of both cellular lipoteichoic acid and lipids.

Factors regulating cell wall thickening and intracellular iodophilic polysaccharide storage in Streptococcus mutans

The effects of a series of different antibiotics on the synthesis and accumulation of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), protein, cell wall peptidoglycan (PG), and intracellular iodophilic polysaccharide (IPS) in Streptococcus mutans FA-1 were examined. d-Cycloserine, penicillin G, or vancomycin treatment resulted in rapid inhibitions of PG synthesis and a consequent decrease in the relative amount of lysine found in PG fractions. Decreases in culture turbidity, an indicator of gross cellular lysis, were not observed. Secondary inhibitions of the rates and extent of syntheses of DNA, RNA, and protein were observed. With all three inhibitors of PG synthesis, IPS synthesis continued for varying time intervals but, at most, resulted in only relatively small and transient increases in cellular IPS content. Chloramphenicol inhibited protein synthesis but permitted continued synthesis of RNA and PG. After 6 h, the cells contained 42% of their [(3)H] lysine in the PG fraction compared with 25% in exponential-phase cells, a good indication of thickened cell walls. In the presence of chloramphenicol, cellular IPS content increased about 2.5-fold during the first 45 min and then decreased to a level (13%) at 6 h very similar to that of exponential-phase cells (about 10%). Rifampin inhibition of RNA (and, consequently, also protein) synthesis resulted in accumulation of cellular PG and IPS. After 6 h, IPS accounted for 38% of the cellular dry weight, and the cells contained 43% of their lysine in PG. Thus, rifampin-inhibited cells appear to have both thickened walls and a high IPS content. The correlation between inhibition of RNA synthesis and IPS accumulation was confirmed by exposing cultures to rifampin for 60 min and then removing the drug, thus permitting the cells to regrow. Upon removal of rifampin and resumption of RNA synthesis, cellular IPS content rapidly decreased to the level expected for exponentialphase cells.

Envelope-associated folded chromosomes for Escherichia coli: variations under different physiological conditions

The folded chromosome of Escherichia coli has been investigated under various lysis and physiological conditions. A new gradient system was devised that allows excellent separation between unlysed cells and envelope-associated and envelope-free chromosomes. Isotope incorporation experiments showed that the fraction often called "membrane-bound nucleoids" contains cell wall in addition to nucleic acids, membranes, and proteins. The amount of lysozyme added and the lysozyme digestion time were found to be important when comparing the rate of sedimentation of envelope-associated chromosomes obtained under various physiological conditions. Amino acid-starved cells were found to be much harder to lyse with lysozyme than exponentially grown cells, The difference in sedimentation coefficient of envelope-associated chromosomes described earlier (Ryder and Smith, 1974) was not detected when the latter two types of cells had been given equivalent, but not identical, lysozyme treatment such that detergent-mediated lysis proceeded at the same rate. Analysis of pulse- and uniformly labeled chromosomes from amino acid-starved cultures revealed no preferential labeling of either envelope-associated or -released nucleoids. Nor was there a difference in sedimentation coefficient between uniform and pulse-labeled envelope-associated nucleoids. These results are in disagreement with the models for chromosome replication of Worcel and Burgi (1974) and Ryder and Smith (1974), respectively. Growing cells on carbon sources poorer than glucose demonstrated that the replicating chromosomes sediment faster than the bulk of envelope-associated nucleoids. The slower the growth rate, the greater this difference became. An alternative hypothesis regarding chromosome replication and its association with the cell envelope is presented.

Analysis of growth rate in sucrose-supplemented cultures of Streptococcus mutans

In the presence of sucrose, Streptococcus mutans grows in large glucan-containing aggregates. Because of reports of linear rather than exponential growth of sucrose-grown cultures, the kinetics of growth of sucrose-grown cultures of S. mutans strain OMZ-176 were compared with those of glucose-grown cultures. Culture turbidity measurements indicated that growth of sucrose cultures was slower, did not follow exponential kinetics, and slowed and stopped at lower absorbance values than did glucose-grown cultures. However, measurements of the rates of accumulation of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein using fully equilibrated radioactively labeled precursors of each of these macromolecular species in sucrose and glucose-grown cultures showed that: (i) for glucose cultures the synthesis of each of the three informational molecules occurred at the same exponential rate, which was identical to the rate of turbidity increase; (ii) for sucrose cultures each macromolecular species was synthesized at the same exponential rate and these rates were identical to the rate of increase of turbidity of the glucose-grown culture for periods of up to 7 h. Furthermore, the ratios of DNA to RNA, RNA to protein, and protein to DNA for the sucrose cultures were identical to those for the glucose cultures for up to 10 doublings. From these data it was concluded that in the presence of sucrose S. mutans grows in a balanced fashion at the same exponential rate as it does in glucose. The deviation from an exponential growth model of the absorbance in sucrose cultures was attributed to an optical artifact due to the formation of large glucan-containing aggregates of cells. The addition of dextranase to sucrose cultures resulted in cultures which increased in turbidity at the same exponential rate as glucose-grown cultures, without affecting the rate or extent of macromolecular synthesis.

Autolytic formation of protoplasts (autoplasts) of Streptococcus faecalis 9790: release of cell wall, autolysin, and formation of stable autoplasts

A system for the formation of apparently wall-free protoplasts from exponential-phase cells of Streptococcus faecalis ATCC 9790 in the absence of added lytic enzymes was developed. Exponential-phase cells suspended in 0.04 M ammonium acetate, pH 6.7, 1 mM magnesium acetate, and 0.5 M sucrose become osmotically fragile within 1 to 1.5 h due to the action of the native, autolytic enzyme on the cell wall peptidoglycan. However, maximal cell wall loss occurred much more slowly, being complete only after 3 to 6 h. Under these conditions, the autolytically formed protoplasts (autoplasts) remained intact for prolonged periods (up to 24 h) with less than 5% of their deoxyribonucleic acid, ribonucleic acid, and protein lost during the first 6 h. During dissolution of the cell wall, release of autolytic enzyme to the supernatant fluid began after 60% of the wall was lost. The addition of trypsin to the incubation mixture increased the rate of attainment of osmotic fragility and cell wall loss two- to threefold, apparently due to the activation of the latent form of the autolysin. Electron microscopy was used to confirm cell wall loss and the presence of intact protoplasts at the end of the incubation periods.

Sites of cellular autolysis in Lactobacillus acidophilus

Ultrastructural changes which occur during cellular autolysis of Lactobacillus acidophilus strain 63AM Gasser in 0.05 M citrate buffer, pH 5.0, were examined. Early in the process, randomly distributed electron-dense patches were seen on the wall surface, along with an accompanying eversion of mesosomes. Later, after a loss of about 20% of the initial cellular turbidity, dissolution from the outside of nascent cross walls was seen. This observation was related to the normal process of cell separation. After this stage, short lengths of the cylindrical portion of the wall appeared to be completely removed in a random manner over the entire surface. This dissolution produced gaps in the wall which allowed the extrusion of membrane and cytoplasm. Although membrane was usually extruded through one major, polar, subpolar, or septal site, other secondary points of membrane extrusion were also frequently seen in the same cell section.

Some properties of the autolytic N-acetylmuramidase of Lactobacillus acidophilus

The autolytic N-acetylmuramidase present in Lactobacillus acidophilus strain 63 AM Gasser has an optimal pH between 5 and 6 when lysing intact cells or isolated cell walls. Cellular lysis at pH 5 is two to four times more rapid in citrate buffer of 0.01 M and 0.5 M or higher than in 0.1 M acetate buffer. It seems that sulfhydryl groups are required for both cell and wall autolysis. Heavy metal ions and p-chloro-mercuribenzoate, at low concentrations, are powerful inhibitors. Ethylenediaminetetraacetic acid stimulates cellular but not wall autolysis in acetate buffer to the level obtained in citrate buffer. The possible involvement of sulfhydryl groups in a mechanism of control of cellular autolytic activity is discussed. The autolytic enzyme, although unstable in solution at 37 C, can be extracted from walls by the use of solutions of bovine serum albumin (100 mug/ml) in 0.01 N NaOH. Soluble enzyme extracted from walls rebinds on to sodium decylsulfate-treated walls, but three times as much of the wall material is required to completely re-adsorb the activity.

Extracellular cell wall lytic enzyme from Staphylococcus aureus: purification and partial characterization

An autolysin obtained from culture fluid of Staphylococcus aureus strain 8507 was purified 3,000-fold. One milligram of this preparation (S-5DL) will solubilize 12 mg of cell wall in 1 hr. The major activity is N-acetylmuramyl-l-alanine amidase. Recovery of lytic activity in the purified preparation was repeatably only 20% of the starting level. This suggests that other cell wall lytic enzymes may be present in the starting material. The S-5DL enzyme has been compared to freeze-thaw extracted enzyme (AFZ). Both enzymes precipitate in 0.01 m KPO(4) (pH 6.0) and dissolve in 0.1 to 0.7 m NaCl. Fifty per cent of the AFZ activity and 66% of the S-5DL activity bind rapidly to cell walls of S. aureus at 0 C in the presence of magnesium ion. None of the AFZ activity and 66% of the S-5DL activity bind to cell walls at 0 C in the absence of magnesium ion. The cell walls of nine different strains of S. aureus were compared for level of native autolysin activity. These same walls after inactivation of the native autolysin were tested for susceptibility to the S-5DL enzyme.

Site of initiation of cellular autolysis in Streptococcus faecalis as seen by electron microscopy

Low concentrations of glutaraldehyde (0.1% or higher) blocked cellular and wall autolysis. The site of autolytic activity was studied by allowing cell autolysis to proceed for very short periods (0 to 15 min) before addition of glutaraldehyde. Electron microscopy of ultrathin sections showed that the primary site of autolytic activity was the leading edge of the nascent cross wall. The base of the cross wall seemed more resistant than the tip. Evidence supporting the involvement of autolysin activity in continued wall extension and in cell separation as well as in the initiation of new sites of wall extension was obtained. In cells exposed for 10 min to chloramphenicol, wall dissolution was very much slower but occurred at the same cross wall site.

Relationship between the location of autolysin, cell wall synthesis, and the development of resistance to cellular autolysis in Streptococcus faecalis after inhibition of protein synthesis

Ten minutes after inhibition of protein synthesis with chloramphenicol (CAP) the ability of cells of Streptococcus faecalis (ATCC 9790) to autolyze decreased to less than 20% of the rate for exponential-phase cells. After threonine exhaustion, the time for a 50% drop in the rate of cellular autolysis was about 20 min. These rapid increases in resistance to cellular autolysis could not be accounted for by: (i) the relatively slow and small overall decrease in susceptibility of isolated cell walls to added autolysin, or (ii) a decreased content of either the active or latent (proteinase activatable) form of the autolysin in the wall fraction. Continued wall synthesis resulted in dilution of preexisting autolysin in the isolated wall fraction. The release of labeled "old" relative to "new" wall from CAP-treated cultures showed that wall synthesis shifted away from the areas of wall previously shown to be associated with wall synthesis (extension) in exponential-phase cells. A corresponding dispersal of active autolysin activity was not observed. By using actinomycin D and CAP, a requirement for ribonucleic acid and protein synthesis early in the recovery of cells from amino acid starvation was demonstrated for the recovery in the ability of cells to autolyze. Evidence was obtained which suggests that a protein is involved in the conversion of latent to active autolysin. During recovery from amino acid starvation, increase in wall synthesis and content of active autolysin was delayed (25 to 35 min), whereas an increase in turbidity and latent enzyme content began within 10 min. After treatment with CAP at 22 or 52 min of recovery, a further increase in levels of both active and latent autolysin was severely inhibited; however, the increase in rate of wall synthesis was indistinguishable from that of an untreated control. This suggests that an increase in rate of wall synthesis does not depend on an increase in level of active autolysin.

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.

Bacteriocin (hemolysin) of Streptococcus zymogenes

The sensitivity of Streptococcus faecalis (ATTC 8043) to S. zymogenes X-14 bacteriocin depends greatly on its physiological age. Sensitivity decreases from the mid-log phase on and is completely lost in the stationary phase. The sensitivity of erythrocytes to the hemolytic capacity of the bacteriocin showed considerable species variation. The order of increasing sensitivity was goose < sheep < dog < horse < human < rabbit. However, when red cell stromata were used as inhibitors of hemolysis in a standard system employing rabbit erythrocytes the order of increasing effectiveness was sheep < rabbit < human < horse < goose. When rabbit cells were used in varying concentrations with a constant hemolysin concentration, there was a lag of about 30 min, which for a given hemolysin preparation was constant for all red cell concentrations. Furthermore, the rate of hemolysis increased with increasing red cell concentration. If red cells are held constant and lysin varied, the time to reach half-maximal lysis varies directly with lysin but is not strictly proportional. Bacterial membranes were one to three orders of magnitude more effective than red cell stromata as inhibitors. The order of increasing effectiveness seems to be Escherichia coli < Bacillus megaterium < S. faecalis < Micrococcus lysodeikticus. In addition to membranes, a d-alanine containing glycerol teichoic acid, trypsin in high concentration, and deoxyribonuclease also inhibited hemolysis. Ribonuclease, d-alanine, l-alanine, dl-alanyl-dl-alanine, N-acetyl-d-alanine, N-acetyl-l-alanine did not inhibit hemolysis.

Molar growth yields of certain lactic acid bacteria as influenced by autolysis

Molar growth yields determined from batch cultures of Streptococcus diacetilactis and S. faecalis were appreciably greater at the peaks of maximal growth than after continued incubation and considerable autolysis. The higher molar growth yields were about equal to those determined in a continuous culture. Autolysis during logarithmic growth was minimal. The average Y value for adenosine triphosphate (ATP), determined by using limiting concentrations of glucose, galactose, lactose, and maltose for growing S. diacetilactis and limiting concentrations of glucose for growing S. lactis, S. cremoris, and S. faecalis, was 17.0. This is close to the Y (arginine) value of 17.8 determined with S. faecalis, but 62% greater than the generally accepted value of 10.5. Data are presented indicating that the often-used Y (ATP) value of 10.5 is erroneously low.

Alterations in the morphology of Bacillus subtilis after exposure to beta-lysin and ultraviolet light

Viable counts, turbidities, and electron micrographs of Bacillus subtilis exposed to beta-lysin and ultraviolet light (UV), singly or in combination, were compared in an attempt to relate death with changes in morphology. The decreases in survival of both the beta-lysin- and UV-treated cells were rapid and preceded decreases in turbidity, as well as the changes in morphology. No significant differences were observed in turbidity reduction or morphological alterations of control cells from those of cells exposed to UV light. These cells developed prominent subcell wall spaces during incubation in the hypertonic stabilizing medium. No observable damage in either the cell wall or the cell membrane had taken place during 4 hr, but by 20 hr extensive damage of these two structures was apparent. The control and UV-treated cells exposed to beta-lysin did not develop prominent subcell wall spaces. Within 2 hr, lesions were observable in their cell walls, and the cytoplasmic membranes were permeable to phosphotungstic acid. The damage to these structures became more extensive with time. Although the visible changes of control and UV-treated cells were evident much later than those induced by beta-lysin, the morphological alterations in all cells were similar. It appeared that beta-lysin caused an accelerated release of an autolytic enzyme which digested the cell walls.

Role of galactose or glucose-1-phosphate in preventing the lysis of Streptococcus diacetilactis

Cells of Streptococcus diacetilactis DRCI grown at 32 C in media containing glucose as the energy source were osmotically fragile and began to lyse immediately after growth was stopped (by the action of chloramphenicol or the exhaustion of glucose), unless they were then stabilized by hypertonic medium or spermine or by storage at low pH or low temperature, or both. In media containing excess glucose, with growth limited by exhaustion of some nutrient other than the energy source, the appearance of lysis was masked by the occurrence of a balance between lysis and synthesis. The osmotic fragility apparently resulted from inability of the organism to use glucose as an adequate precursor of galactosamine, and conditions of temperature and pH that promoted rapid growth on glucose were particularly conducive to the formation of cells that lysed readily. Growing the organism in media containing galactose, lactose, maltose, or glucose (at 17 C) as energy source resulted in the formation of cells that were resistant to lysis and richer in galactosamine than unstable cells formed on glucose at 32 C. The results indicate that the organism phosphorolyzes maltose to glucose plus beta-glucose-1-phosphate, and suggest that it can use the beta-glucose-1-phosphate in place of alpha-glucose-1-phosphate in the formation of cell materials.