Quantitative Nasal Culture: a Tool in Antibiotic Research

The use of the quantitative nasal culture was investigated as a means of evaluation of new antimicrobial drugs in man. Cyclacillin was somewhat more active in vitro than penicillin G against penicillin G-resistant organisms. Cyclacillin was highly effective in suppressing staphylococci susceptible to penicillin G in nasal carriers but did not suppress staphylococci resistant to penicillin G. Although in previous studies by others cyclacillin was effective in treating mice infected with penicillin G-resistant staphylococci, in the present studies cyclacillin was not effective in suppressing nasal penicillin G-resistant staphylococci in man at doses which markedly suppressed penicillin G-sensitive organisms.     

Action of Penicillin G on Endosymbiote Lambda Particles of Paramecium aurelia

The kinetics of loss from the cytoplasm and changes in ultrastructure of symbiont lambda particles after treatment of axenically cultivated lambda-bearing Paramecium aurelia with penicillin G was investigated. Low concentrations (1 to 2 unit/ml) of the antibiotic caused many particles within the cell to become filamentous; high concentrations (2,000 unit/ml) caused lysis of the particles without noticeably affecting the protozoan. The ED(50) value (2 to 3 unit/ml) was within the range of values found to cause lysis of many gram-negative bacteria. Rapidly dividing lambda were more vulnerable to the action of the antibiotic than slowly dividing particles. Nondividing particles were not affected by exposure to the antibiotic. Ultrastructural changes observed in lambda during lysis by penicillin G were consistent with the view that penicillin interferes with the synthesis of a vital component of the cell envelope of the particle, possibly a peptidoglycan similar to that found in the cell walls of bacteria. The deoxyribonucleic acid of lambda was dispersed throughout the particle as electron dense fibers enclosed within electron transparent areas. The cell envelope appeared to consist of at least two morphologically distinguishable layers, an inner layer homologous to the plasma membrane of bacteria and an outer layer homologous to the bacterial cell wall. Lambda may be regarded as a randomly distributed population of bacteria growing and dividing synchronously within the collective cytoplasm of its protozoan host.     

Onset of penicillin-induced bacteriolysis in staphylococci is cell cycle dependent.

Synchronously growing staphylococci were treated with "lytic" concentrations of penicillin at different stages of their division cycle. Coulter Counter measurements and light microscopy were used to determine the onset of bacteriolysis. Independent of the stage of the division cycle at which penicillin was added, (i) the cells were always able to perform the next cell division; (ii) the following division, however, did not take place; and (iii) instead, at this time, when the onset of the subsequent cell separation was observed in control cultures, lysis of the penicillin-treated cells occurred. These results support a recent model (P. Giesbrecht, H. Labischinski, and J. Wecke, Arch. Microbiol. 141:315-324, 1985) explaining penicillin-induced bacteriolysis of staphylococci as the result of a special morphogenetic mistake during cross wall formation.     

Alterations induced by penicillin in the protein profile and cell structure of Group GStreptococcus

We investigated the effect of a subminimal concentration of penicillin on the ultrastructure and protein profile of Group G streptococci. In cells treated with penicillin (1/3 MIC), the protein content increased by 50%, and several protein bands with a molecular mass of 14–70 kDa were detected. In the hydrophilic phase, carbohydrate-containing proteins were detected by PAS staining, and in the hydrophobic phase, a group of proteins that reacted strongly with homologous antisera were observed. In terms of cell structure, Triton X-114 extraction was found to induce alterations in the cross wall of untreated cells. In bacteria treated with penicillin but not extracted with Triton X-114, the cell wall was observed to detach itself, and regions with reduced amounts of cellular material appeared in the cytoplasm. After Triton-X114 extraction, these penicillin-treated cells exhibited profound morphological changes, leading in some cases to lysis.     

Staphylococcal Cell Wall: Morphogenesis and Fatal Variations in the Presence of Penicillin

The primary goal of this review is to provide a compilation of the complex architectural features of staphylococcal cell walls and of some of their unusual morphogenetic traits including the utilization of murosomes and two different mechanisms of cell separation. Knowledge of these electron microscopic findings may serve as a prerequisite for a better understanding of the sophisticated events which lead to penicillin-induced death. For more than 50 years there have been controversial disputes about the mechanisms by which penicillin kills bacteria. Many hypotheses have tried to explain this fatal event biochemically and mainly via bacteriolysis. However, indications that penicillin-induced death of staphylococci results from overall biochemical defects or from a fatal attack of bacterial cell walls by bacteriolytic murein hydrolases were not been found. Rather, penicillin, claimed to trigger the activity of murein hydrolases, impaired autolytic wall enzymes of staphylococci. Electron microscopic investigations have meanwhile shown that penicillin-mediated induction of seemingly minute cross wall mistakes is the very reason for this killing. Such “morphogenetic death” taking place at predictable cross wall sites and at a predictable time is based on the initiation of normal cell separations in those staphylococci in which the completion of cross walls had been prevented by local penicillin-mediated impairment of the distribution of newly synthesized peptidoglycan; this death occurs because the high internal pressure of the protoplast abruptly kills such cells via ejection of some cytoplasm during attempted cell separation. An analogous fatal onset of cell partition is considered to take place without involvement of a detectable quantity of autolytic wall enzymes (“mechanical cell separation”). The most prominent feature of penicillin, the disintegration of bacterial cells via bacteriolysis, is shown to represent only a postmortem process resulting from shrinkage of dead cells and perturbation of the cytoplasmic membrane. Several schematic drawings have been included in this review to facilitate an understanding of the complex morphogenetic events.     

THE GROWTH OF BACTERIOPHAGE AND LYSIS OF THE HOST

1. A new strain of B. coli and of phage active against it is described, and the relation between phage growth and lysis has been studied. It has been found that the phage can lyse these bacteria in two distinct ways, which have been designated lysis from within and lysis from without. 2. Lysis from within is caused by infection of a bacterium by a single phage particle and multiplication of this particle up to a threshold value. The cell contents are then liberated into solution without deformation of the cell wall. 3. Lysis from without is caused by adsorption of phage above a threshold value. The cell contents are liberated by a distension and destruction of the cell wall. The adsorbed phage is not retrieved upon lysis. No new phage is formed. 4. The maximum yield of phage in a lysis from within is equal to the adsorption capacity. 5. Liberation of phage from a culture in which the bacteria have been singly infected proceeds at a constant rate, after the lapse of a minimum latent period, until all the infected bacteria are lysed. 6. If the bacteria are originally not highly in excess, this liberation is soon counterbalanced by multiple adsorption of the liberated phage to bacteria that are already infected. This leads to a reduction of the final yield.     

Penicillin-induced changes in the cell wall composition of Staphylococcus aureus before the onset of bacteriolysis

To analyze if chemical cell wall alterations contribute to penicillin-induced bacteriolysis, changes in the amount, stability, and chemical composition of staphylococcal cell walls were investigated. All analyses were performed before onset of bacteriolysis i.e. during the first 60 min following addition of different penicillin G doses. Only a slight reduction of the amount of cell wall material incorporated after penicillin addition at the optimal lytic concentration was observed as compared to control cells. However, the presence of higher penicillin G concentrations reduced the incorporation of wall material progressively without bacteriolysis. Losses of wall material during isolation of dodecylsulfate insoluble cell walls were monitored to assess the stability of the wall material following penicillin addition. Wall material grown at the lytic penicillin concentration was least stable but about 30% of the newly incorporated wall material withstood even the harsh conditions of mechanical breakage and dodecylsulfate treatment. Dodecylsulfate insoluble cell walls were used for chemical analyses. While peptidoglycan chain length was unaffected in the presence of penicillin, other wall parameters were considerably altered: peptide cross-linking was reduced in the wall material synthesized after addition of penicillin; reductions from approx. 85% in controls to about 60% were similar for lytic and also for very high penicillin concentrations leading to nonlytic death. O-acetylation was also reduced after treatment with penicillin; this effect paralleled the occurence of subsequent bacteriolysis at different drug concentrations. The results are not consistent with hypotheses explaining penicillin-induced lysis as a result of an overall weakened cell wall structure or an overall activation of autolytic wall enzymes but not conflicting with the model that ascribes penicillin-induced bacteriolysis as the result of a very restricted, local perforation of the peripheral cell wall (murosome-induced bacteriolysis).Abbreviations CL Cross-linking - DNFB 2,4-dinitro-1-fluorobenzole - MIC Minimal inhibitory concentration - OD Optical density at 578 nm - PEN Penicillin G     

Mechanism of pneumococcal cell wall degradation in vitro and in vivo.

We compared the products of autolytic amidase-catalyzed wall degradation in vivo (in penicillin-induced lysis) and in vitro. Pneumococci labeled in their cell wall stem peptides by radioactive lysine were treated with penicillin, and the nature of wall degradation products released to the medium during lysis of the bacteria was determined. At early times of lysis (20% loss of wall label), virtually all the radioactive peptides released (greater than 94%) were of high molecular size and were still attached to glycan and teichoic acid. At times of more extensive bacterial lysis (56%), progressively larger and larger fractions of the released peptides became free, i.e., detached from glycan and teichoic acid. Analysis of the nondegraded residual wall material by high-resolution high-pressure liquid chromatography revealed that this in vivo-triggered autolysis did not involve selective hydrolysis of some of the chemically distinct stem peptides. Parallel in vitro experiments yielded completely different results. Purified pneumococcal cell walls labeled with radioactive lysine were treated in vitro with low concentrations of pure amidase, and the nature of wall degradation products released during limited hydrolysis and after more extensive degradation was determined. In sharp contrast to the in vivo experiments, the main products of in vitro hydrolysis were free peptides. After a short treatment with amidase (resulting in a 20% loss of label), the material released was enriched for the monomeric stem peptides. At all times of hydrolysis (including the time of extensive degradation), only a relatively small fraction of the released wall peptides was covalently attached to glycan and teichoic acid components (17% as compared with 40% in the intact cell wall). We propose that the in vivo-triggered amidase activity first attacks the amide bonds in some strategically located (or unprotected) stem peptides that hold large segments of cell wall material together. The observations indicate that the in vivo activity of the pneumococcal autolysin is under topographic constraints.     

Cell wall modifications during osmotic stress in Lactobacillus casei

AIMS: To study the modification of the cell wall of Lactobacillus casei ATCC 393 grown in high salt conditions. METHODS AND RESULTS: Differences in the overall structure of cell wall between growth in high salt (MRS + 1 mol l(-1) NaCl; N condition) and control (MRS; C condition) conditions were determined by transmission electronic microscopy and analytical procedures. Lactobacillus casei cells grown in N condition were significantly larger than cells grown under unstressed C condition. Increased sensitivity to mutanolysin and antibiotics with target in the cell wall was observed in N condition. Purified cell wall also showed the increased sensitivity to lysis by mutanolysin. Analysis of peptidoglycan (PG) from stressed cells showed that modification was at the structural level in accordance with a decreased PG cross-link involving penicillin-binding proteins (PBP). Nine PBP were first described in this species and these proteins were expressed in low percentages or presented a modified pattern of saturation with penicillin G (Pen G) during growth in high salt. Three of the essential PBP were fully saturated in N condition at lower Pen G concentrations than in C condition, suggesting differences in functionality in vivo. CONCLUSIONS: The results show that growth in high salt modified the structural properties of the cell wall. SIGNIFICANCE AND IMPACT OF STUDY: Advances in understanding the adaptation to high osmolarity, in particular those involving sensitivity to lysis of lactic acid bacteria.     

Triolein,as a Phagostimulant for Albino Rat

Protaminobacter ruber, having a firm cell wall, could be lyzed by treatment with glycine or penicillin. Among amino acids tested, only glycine showed an excellent effect for the lysis. The optimal amount and time of addition of glycine for the lysis were 6 mg per ml culture and 4 to 5 hr after initiation of the cultivation, respectively. Aeration was necessary for the lysis as well as the growth of P. ruber. Morphological changes during the lysis of the bacterium were confirmed by electron microscopy. Proteins and (δ-ALA dehydratase were excreted into the medium with the progress of lysis.     

Protoplast formation and regeneration of dehydrodivanillin-degrading strains of Fusobacterium varium and Enterococcus faecium

Two strains of rumen anaerobes isolated from dehydrodivanillin-degrading cultures were identified as Fusobacterium varium and Enterococcus faecium. These organisms degraded dehydrodivanillin synergistically to 5-carboxymethylvanillin and vanillic acid. Specific conditions for protoplast formation and cell wall regeneration for both bacteria were determined, under strictly anaerobic conditions, to be as follows. The cell wall of each bacterium in yeast extract medium was loosened by adding penicillin G during early log-phase growth. The cell wall of F. varium was lysed by lysozyme (1 mg/ml) in glycerol (0.2 M)-phosphate buffer (0.05 M; pH 7.0). The addition of NaCl (0.08 M) with lysozyme was necessary for lysis of E. faecium in this solution. Almost all cells were converted to protoplasts after 2 h of incubation at 37 degrees C. Regeneration of both protoplasts was 20 to 30% on an agar-containing yeast extract medium.     

Role of the pneumococcal autolysin (murein hydrolase) in the release of progeny bacteriophage and in the bacteriophage-induced lysis of the host cells.

The pneumococcal bacteriophage Dp-1 seems to require the activity of the N-acetylmuramic acid-L-alanine amidase of the host bacterium for the liberation of phage progeny into the medium. This conclusion is based on a series of observations indicating that the exit of progeny phage particles is prevented by conditions that specifically inhibit the activity of the pneumococcal autolysin. These inhibitory conditions are as follows: (i) growth of the bacteria on ethanolamine-containing medium; (ii) growth of the cells at pH values that inhibit penicillin-induced lysis of pneumococcal cultures and lysis in the stationary phase of growth; (iii) addition of trypsin or the autolysin-inhibitory pneumococcal Forssman antigen (lipoteichoric acid) to the growth medium before lysis; (iv) infection of an autolysin-defective pneumococcal mutant at a multiplicity of infection less than 10 (treatment of such infected mutant bacteria with wild-type autolysin from without can liberate the entrapped progeny phage particles); (v) release of phage particles and culture lysis can also be inhibited by the addition of chloramphenicol to infected cultures just before the time at which lysis would normally occur. Bacteria infected with Dp-1 under conditions nonpermissive for culture lysis and phage release secrete into the growth medium a substantial portion of their cellular Forssman antigen in the form of a macromolecular complex that has autolysin-inhibitory activity. We suggest that a phage product may trigger the bacterial autolysin by a mechanism similar to that operating during treatment of pneumococci with penicillin (Tomasz and Waks, 1975).     

Protoplast formation and regeneration of dehydrodivanillin-degrading strains of Fusobacterium varium and Enterococcus faecium.

Two strains of rumen anaerobes isolated from dehydrodivanillin-degrading cultures were identified as Fusobacterium varium and Enterococcus faecium. These organisms degraded dehydrodivanillin synergistically to 5-carboxymethylvanillin and vanillic acid. Specific conditions for protoplast formation and cell wall regeneration for both bacteria were determined, under strictly anaerobic conditions, to be as follows. The cell wall of each bacterium in yeast extract medium was loosened by adding penicillin G during early log-phase growth. The cell wall of F. varium was lysed by lysozyme (1 mg/ml) in glycerol (0.2 M)-phosphate buffer (0.05 M; pH 7.0). The addition of NaCl (0.08 M) with lysozyme was necessary for lysis of E. faecium in this solution. Almost all cells were converted to protoplasts after 2 h of incubation at 37 degrees C. Regeneration of both protoplasts was 20 to 30% on an agar-containing yeast extract medium.     

Effect of an interferon preparation on increasing bacterial sensitivity to antibiotics

Under the effect of human leukocytic alpha-interferon-II for injections there was observed an increase in sensitivity of bacteria to benzylpenicillin, ristomycin, novobiocin, streptomycin, kanamycin, monomycin and erythromycin. A higher antibacterial effect of the penicillin and erythromycin was recorded only with respect to initially resistant strains of staphylococci. For the antibiotic resistant strains of staphylococci the MICs of the penicillin and erythromycin decreased on the average 17.8 and 208 times (p less than 0.001) respectively. The interferon had no effect on sensitivity of bacteria to chloramphenicol.     

Factors affecting sensitivity of group B streptococci to an exogenous murein hydrolase

Group B streptococci treated with cell wall synthesis inhibitors (penicillin or vancomycin) or by a variety of membrane-acting agents are sensitized to the lytic action of exogenous M1 muramidase. Muramidase without a sensitizing agent caused rupture of bacterial chains only, accompanied by the release of a small amount of cell wall peptidoglycan label and an increase of the number of colony-forming units. In combination with sensitizing agents the exogenous muramidase appeared to initiate hydrolysis of biosynthetically new peptidoglycan. Treatment of the cells with chloramphenicol or starvation for nutritionally required amino acids suppressed the rate of cell lysis and peptidoglycan hydrolysis during subsequent sensitization and muramidase treatment of the bacteria. Purified cell walls prepared from the amino acid starved cells were also hydrolyzed with a slower rate by muramidase. It is suggested that agents sensitizing the bacteria to the exogenous muramidase act by perturbing or removing some nonmurein components of the cell envelope which protect the peptidoglycan from the activity of exogenous enzyme. Agents increasing resistance against exogenous muramidase may also cause some alteration in peptidoglycan structure.     

Preferential Inhibition of Penicillinase Induction by Oxytetracycline and Its Effect on the Penicillin Susceptibility of Staphylococci

Exposure of penicillinase-producing staphylococci to a combination of penicillin and oxytetracycline resulted in a synergistic inhibitory activity of the antibiotics on the bacteria. Oxytetracycline was employed in concentrations having little or no effect on bacterial growth. It was found that the synergistic antibacterial effect was caused by the preferential inhibition of penicillinase induction by oxytetracycline, rendering the staphylococci more susceptible to penicillin.     

Induction of penicillinase by staphylococci in vitro and in vivo

Eyckmans, Luc (Cornell University Medical College, New York, N.Y.), and Edward W. Hook. Induction of penicillinase by staphylococci in vitro and in vivo. J. Bacteriol. 91:997-1003. 1966.-Staphylococci in mice with peritoneal infection showed no significant increase in penicillinase activity 6 hr after administration of penicillin G. In contrast, induction of penicillinase was readily demonstrated in leukopenic animals under similar conditions. Induction of penicillinase by staphylococci in vitro was inhibited by including leukocytes and immune serum in the mixtures. The role of leukocytes in inhibiting induction of penicillinase by staphylococci in response to penicillin was investigated.     

The role of Staphylococcus aureus sortase A and sortase B in murine arthritis

Gram-positive pathogenic bacteria display proteins on their surface that play important roles during infection. In Staphylococcus aureus, these surface proteins are anchored to the cell wall by two sortase enzymes, SrtA and SrtB, that recognize specific surface protein sorting signals. The role of sortase enzymes in bacterial virulence was examined using a murine septic arthritis model. Intravenous inoculation with any of the Delta(srtA), Delta(srtB) or Delta(srtAB) mutants resulted in significantly increased survival and significantly lower weight loss compared with the parental strain. Mice inoculated with the Delta(srtA) mutant did not express severe arthritis, while arthritis in mice inoculated with the Delta(srtB) mutant was not different from that seen in mice that were infected with the wild-type parent strain. Furthermore, persistence of staphylococci in kidneys and joints following intravenous inoculation of mice was more pronounced for wild-type and Delta(srtB) mutant strains than for Delta(srtA) or Delta(srtAB) variants. Together these results indicate that sortase B (srtB) plays a contributing role during the pathogenesis of staphylococcal infections, whereas sortase A (srtA) is an essential virulence factor for the establishment of septic arthritis.     

Tumorigenicity of persistently infected tumors in nude mice is a function of both virus and host cell type.

Although BHK-21 cells persistently infected with wild-type vesicular stomatitis virus (VSV) are sensitive to natural killer (NK) cells and do not form tumors in athymic nude mice, BHK-21 cells persistently infected with a previously isolated mutant virus (VSV-P) are resistant to NK cells and form tumors in nude mice. We used this VSV-P mutant to persistently infect HeLa cells and mouse tumor cell lines. A mouse mastocytoma line (P815) persistently infected with VSV-P was similar to BHK-21 cells in that it was resistant to NK cell lysis and formed tumors in nude mice. However, neither HeLa cells nor mouse myeloma lines persistently infected with VSV-P were resistant to NK cell lysis in vitro, and neither formed tumors in nude mice. Rejection by nude mice of HeLa cells and mouse myeloma cell lines persistently infected with VSV-P could be ablated by rabbit antiserum to asialo-GM1, implicating NK cells in the in vivo rejection of these persistently infected tumors. These results suggest that NK cell recognition and killing of virus-infected cells in vivo and in vitro depend upon genetic contributions from both the virus and the host cell.     

Roles of bacteriophage T4 gene 5 and gene s products in cell lysis.

Previous studies indicated that (i) T4 gene s product (gps) protects infected cells from superinfection lysis from without, (ii) the absence of gps in infected cells also leads to lysis from within even when T4 e lysozyme is absent, (iii) T4 gene 5 product (gp5), a polypeptide of the virion baseplate, may be responsible for inducing lysis from without, and (iv) altered gp5 of the T4 mutant 5ts1 can replace e lysozyme to cause lysis from within. Results of this study showed that (i) wild-type gp5 in infected cells lacking e lysozyme was responsible for lysis from within in the absence of gps, and (ii) gps did not protect infected cells from superinfection lysis from without by 5ts1 phage. We prpose that gps normally prevents functional expression of wild-type gp5 activity from either side of the cell wall, whereas the 5ts1 form of gp5 is insensitive to the gps barrier and induces lysis from either side of the cell wall.