Mode of action of a bacteriocin produced byEnterobacter cloacae DF 13

Enterobacter cloacae DF 13 produces a bacteriocin with killing action onKlebsiella edwardsii var.edwardsii. The degree of sensitivity to the bacteriocin depended on the medium in which the cells were grown and on the bacteriocin concentration used. An excess of bacteriocin (60 K.U./ml) arrested growth in about 60 min. Growth of bacteriocin-treated cultures could be restored by trypsin treatment. In Brain Heart Infusion cultures trypsin rapidly restored bacterial growth even after 60 min of bacteriocin treatment. However, in broth cultures and minimal medium cultures treated with bacteriocin for only 10 min, it took 4 to 5 hr before growth started again. The bacteriocin had little effect on resting cells. Broth-grown cells had about 280 and BHI-grown cells about 340 bacteriocin receptor sites. Bacteriocin DF 13 strongly inhibited protein synthesis after a lag-time of 15 to 60 min depending on the concentration used but had no effect on RNA and DNA synthesis nor on respiration and fermentation. The bacteriocin stimulated RNA synthesis in a leucine-deficient mutant after leucine deprivation.We are grateful to W. Schipper and H. R. de Jonge for assistence in some experiments. The investigations were supported (in part) by the Netherlands Foundation for Chemical Research (SON) with financial aid from the Netherlands Organization for the Advancement of Pure Research (ZWO).     

Nalidixic Acid and the Metabolism of Escherichia coli

Nalidixic acid (NAL) is bactericidal for E. coli B. Synthesis of deoxyribonucleic acid (DNA), ribonucleic acid and protein was necessary to initiate the lethal effect, but only protein synthesis was necessary to sustain it. NAL inhibited DNA synthesis specifically, but this inhibition occurred even under conditions that were not lethal to the bacteria. In contrast to other inhibitors of DNA synthesis, NAL did not cause the solubilization of cellular DNA even when bacteria were exposed to it for 2 hr. A bacterial mutant deficient in DNA polymerase was much more sensitive to the lethal action of NAL than its parent strain. Moreover, inhibition of protein synthesis did not protect this mutant from NAL-induced killing. NAL inhibited neither DNA polymerase, nor thymidine or thymidylate kinases. The data are interpretated as suggesting that NAL altered the structure of DNA or a protein attached to nascent DNA and that this lesion can be partially repaired by DNA polymerase.     

Studies on mode of action of a bacteriocin from Clostridium septicum.

A bacteriocin was found in the supernatant fluid of Clostridium septicum strain Ovinus. Sensitivity to the bacteriocin was confined to other strains of C. septicum and to strains of C. chauvoei; the other Gram-positive and Gram-negative bacteria tested for sensitivity were unaffected by the bacteriocin. The bacteriocin killed sensitive cells rapidly but cell lysis did not appear to be involved. The bacteriocin inhibited protein and RNA synthesis immediately after its addition to sensitive cells; DNA synthesis was inhibited 10 min later.     

The need for protein synthesis in UV-irradiated Escherichia coli cells for fixation of induced Str mutations

The kinetics of accumulation of fixed Str mutations was determined during incubation in nutritional medium of Escherichia coli WP2 irradiated with 6.8 J/m2 either at log growth phase or after completion of DNA replication. Those Str mutations which lost ability for photoreactivation (fixation I) or susceptibility to antimutagenic activity of mfd-type (fixation II) were considered as fixed mutations. It was shown that both fixations occurred synchronously, starting in about 10 min after irradiation and being over in 40-50 min. In cells irradiated after completion of replication, fixation depended on protein synthesis de novo: chloramphenicol added to irradiated culture blocked fixation. An attempt to study the effect of chloramphenicol on fixation in a culture irradiated at the log phase failed, because of high lethal action of the antibiotic on such cells. Fixation could proceed in the presence of acriflavine. Possible mechanisms for fixation of Str mutations are discussed in connection with the fact of its dependence on protein synthesis.     

A comparative study of three bacteriocins of Bacteroides fragilis

Three different bacteriocins produced by strains of Bacteroides fragilis were compared in terms of their production kinetics, physico-chemical nature, and action on macromolecular synthesis in a common indicator strain. Bacteriocin 78/438 was produced during the logarithmic growth phase, was thermolabile and stable between pH 5 and 9. It was susceptible to trypsin and pepsin, and affected DNA, RNA and protein syntheses in susceptible cells. Bacteriocin A49 was produced during the stationary growth phase, was thermolabile and stable between pH 7 and 9. This bacteriocin was also susceptible to trypsin and pepsin, but only RNA synthesis was affected in the indicator strain. Bacteriocin A55 differed markedly from both 78/438 and A49, and was found to be predominantly cell-bound, resistant to inactivation by high temperatures and stable over a wide pH range of 2 to 12. It was susceptible to trypsin but resistant to pepsin. A55 had a delayed effect on macromolecular synthesis with DNA synthesis being inhibited after 60 min. With all three bacteriocins, killing of the indicator strain followed single hit kinetics with the interaction of bacteriocin and target cell occurring in two stages. Killing by bacteriocin A55 was much slower than the other two and this may be related to its effect on macromolecular synthesis. The killing action of all three bacteriocins was dependent on the growth phase of the susceptible cells.     

Antibacterial activity of plantaricin SIK-83, a bacteriocin produced by Lactobacillus plantarum

Lactobacillus plantarum SIK-83 produces a bacteriocin, designated plantaricin SIK-83, which inhibits 66 of 68 lactic acid bacteria from the genera Lactobacillus, Leuconostoc, Pediococcus and Streptococcus. A 500-fold dilution of L. plantarum SIK-83 MRS culture supernatant with phosphate buffer was sufficient to kill 10(5) cells/ml of Pediococcus pentosaceus within 120 s. The killing of a sensitive population followed exponential kinetics. It was shown that the bacteriocin binds specifically to sensitive cells but not to nonsensitive lactic acid bacteria, the producer strain or Gram-negative bacteria. Sensitive cells, after exposure to the bacteriocin, could be rescued by treatment with proteolytic enzymes. In buffer, plantaricin SIK-83 was adsorbed to the cell surface almost immediately, and morphological lesions were observed within 2 h after the cells were exposed to the bacteriocin. The lethal mode of action appeared to be due to damage to the cell membrane, resulting in cell lysis, which was detected by electron microscopy and by determination of released intracellular components.     

Mechanism of action of lactostrepcin 5, a bacteriocin produced by Streptococcus cremoris 202

The mechanism of bactericidal activity of lactostrepcin 5 (Las 5), a bacteriocin produced by Streptococcus cremoris 202, was investigated. Las 5 did not kill protoplasts of sensitive cells, and its activity was decreased about 10-fold after pretreatment of the cells with trypsin, suggesting the involvement of the cell wall in the activity of this bacteriocin. In susceptible cells, the bacteriocin slowed down and then stopped synthesis of DNA, RNA, and protein, although this did not appear to be the primary effect of Las 5 action. Las 5 also inhibited uridine transport in susceptible cells and induced leakage of K+ ions and ATP. Survival of cells treated with Las 5 in phosphate buffer was higher in the presence of K+, CA2+, or Mg2+ ions.     

Mechanism of action of lactostrepcin 5, a bacteriocin produced by Streptococcus cremoris 202.

The mechanism of bactericidal activity of lactostrepcin 5 (Las 5), a bacteriocin produced by Streptococcus cremoris 202, was investigated. Las 5 did not kill protoplasts of sensitive cells, and its activity was decreased about 10-fold after pretreatment of the cells with trypsin, suggesting the involvement of the cell wall in the activity of this bacteriocin. In susceptible cells, the bacteriocin slowed down and then stopped synthesis of DNA, RNA, and protein, although this did not appear to be the primary effect of Las 5 action. Las 5 also inhibited uridine transport in susceptible cells and induced leakage of K+ ions and ATP. Survival of cells treated with Las 5 in phosphate buffer was higher in the presence of K+, CA2+, or Mg2+ ions.     

Aminoglycoside and aminocyclitol antibiotics: hygromycin B is an atypical bactericidal compound that exerts effects on cells of Escherichia coli characteristics for bacteriostatic aminocyclitols.

The effects of aminoglycoside and aminocyclitol antibiotics on intact cells of Escherichia coli were compared. The aminoglycosides streptomycin, gentamicin, kanamycin and neomycin had similar, but not identical, effects. They all caused misreading during protein synthesis, permeabilization of the cell membrane, inhibition of the initiation of DNA replication, and loss of cell viability. Cells treated with these antibiotics continued to synthesize two proteins (apparent molecular masses 72 and 60 kDa) that were not made by cells treated with the aminocyclitol hygromycin B, which did not cause misreading. Cells treated with the aminoglycosides regained their membrane tightness after residual protein synthesis in these cells had been inhibited by chloramphenicol, suggesting that under these conditions the mistranslated membrane proteins were rapidly degraded. The bacteriostatic aminocyclitols spectinomycin and kasugamycin did not cause membrane permeabilization, suggesting that these compounds do not cause misreading. Hygromycin B resembled these aminocyclitols in that it inhibited protein synthesis without causing misreading, membrane permeabilization or inhibition of initiation of DNA synthesis. However, hygromycin B also decreased cell viability. In minimal medium this lethal effect began late in comparison to the process of inhibition of protein synthesis. It is concluded that hygromycin B is an atypical bactericidal antibiotic that strongly resembles the bacteriostatic aminocyclitols spectinomycin and kasugamycin in its action.     

Biochemical changes in lysogenic Bacillus stearothermophilus after bacteriophage induction

Welker, N. E. (University of Illinois, Urbana), and L. Leon Campbell. Biochemical changes in lysogenic Bacillus stearothermophilus after bacteriophage induction. J. Bacteriol. 90:1129-1137. 1965.-Cultures of Bacillus stearothermophilus 1503-4R (TP-1) continued to grow at an unaltered rate after induction with mitomycin C (MC). MC-induced cultures exhibited a 2.5-fold increase in cell number before lysis occurred. Prior to lysis, cells were observed to elongate and to contain areas of lesser density. Protein synthesis was slightly inhibited in MC- or ultraviolet light (UV)-induced cultures for a period of 5 to 10 min, and then proceeded at a rate identical to that in the noninduced culture. Ribonucleic acid (RNA) synthesis was not affected by MC induction. UV induction caused RNA synthesis to occur in two stages: in the first stage, the rate of RNA synthesis was one-third that observed in the noninduced culture and lasted for a period of 15 min; the second stage of RNA synthesis then proceeded at a rate identical to that in the noninduced culture. The synthesis of deoxyribonucleic acid (DNA) in an MC- or UV-induced culture occurred in two stages. In the first stage, DNA synthesis in induced cultures occurred at a rate of one-half (MC) and one-third (UV) of that observed in the noninduced culture. The first stage of DNA synthesis in MC- or UV-induced cultures lasted for 25 to 30 min and 15 to 20 min, respectively. In the second stage, the rate of DNA synthesis in MC- or UV-induced cultures occurred at a rate three times that of the noninduced culture. UV induction appeared to have a greater inhibitory effect than MC induction on protein, RNA, and DNA synthesis as well as phage yield. The differential rate (K) of inducible and constitutive alpha-amylase synthesis was inhibited by 75 and 100%, respectively, for a period of 20 min after MC induction. After 20 min, the K values for alpha-amylase synthesis were identical to those obtained in the absence of MC induction. The synthesis of TP-1 phage DNA occurred rapidly and was complete 25 min after MC induction, whereas bacterial DNA was degraded or its rate of synthesis was decreased. During the second stage of DNA synthesis, only bacterial DNA was synthesized, but at a rate greater than that found in the noninduced culture.     

Uptake of cloacin DF13 by susceptible cells: removal of immunity protein and fragmentation of cloacin molecules.

Monoclonal antibodies (MAb) directed against different epitopes on the equimolar complex of cloacin and immunity protein (cloacin DF13) were isolated, characterized, and used to study the uptake of cloacin DF13 by susceptible cells. Four MAbs recognized the amino-terminal part, one MAb recognized the central part, and three MAbs recognized the carboxyl-terminal part of the cloacin molecule. Three MAbs reacted with the immunity protein. Five MAbs inhibited the lethal action of cloacin DF13, but none of the MAbs inhibited the binding of cloacin DF13 to its purified outer membrane receptor protein or the in vitro inactivation of ribosomes. Binding of cloacin DF13 to susceptible cells cultured in broth resulted in a specific, time-dependent dissociation of the complex and a fragmentation of the cloacin molecules. Increasing amounts of immunity protein were detected in the culture medium from about 20 min after the addition of cloacin DF13. Cloacin was fragmented into two carboxyl-terminal fragments with relative molecular masses of 50,000 and 10,000. The larger fragment was detected 5 min after the binding of the bacteriocin complex to the cells. The smaller fragment was detected after 10 min. Both fragments were associated with the cells and could not be detected in the culture supernatant fraction. Cells grown in brain heart infusion were much less susceptible to cloacin DF13 than cells grown in broth, although they possessed a similar number of outer membrane receptor molecules. This decreased susceptibility correlated with a decreased translocation, dissociation, and fragmentation of cloacin DF13.     

Kinetics of murine type C virus-specific DNA synthesis newly infected cells.

Replicating transforming functions of Rauscher leukemia virus (RLV) and the RLV pseudotype of Moloney sarcoma virus in mouse embryo fibroblasts were found to be most sensitive to inhibition by cytosine arabinoside (ara-C) 30 to 90 min after infection. The initiation of intracellular RLV DNA synthesis was detected by nucleic acid hybridization within this time interval. Treatment of infected cells with cytosine arabinoside abolished RLV DNA synthesis. Peak synthesis of the DNA complementary to the infecting RLV genome, the (-) strand, occurred 40 to 60 min after infection. During this interval two s two species of DNA were observed with estimated molecular weights of 0.5 X 10(5) to 1.0 X 10(5) and 3 X 10(6). Peak synthesis of the (+) strand viral DNA occurred 50 to 70 min after infection. The initial species detected had a molecular weight of 1.5 X 10(5) to 4.0 X 10(5) which shifted as a function of time to 3 X 10(6). Both (+) strand species were initially detected in the cytoplasm followed by a rapid (10-min interval) appearance of the faster-sedimenting species in the nucleus. The virus-specific (-) and (+) strand DNA species are presumably unintegrated intermediates in provirus formation.     

Effects of a bacteriocin from Mycobacterium smegmatis on BALB/3T3 and simian virus 40-transformed BALB/c mouse cells

The effects of a bacteriocin from Mycobacterium smegmatis ATCC 14468 on simian virus 40-transformed BALB/c mouse cells (mKS-A TU-7 cells) and nontransformed BALB/3T3 cells originating from the BALB/c mouse strain were studied. The percentage of nigrosin-unstained (viable) cells in the bacteriocin-treated mKS-A TU-7 cells decreased time-dependently with an increase in the bacteriocin activity. There was a time-dependent decrease in the bacteriocin activity after treatment with the cell membrane preparation from mKS-A TU-7 cells. There was no apparent effect of the bacteriocin on the viability of nontransformed BALB/3T3 cells. Wheat germ agglutinin blocked the toxic effect of bacteriocin on mKS-A TU-7 cells. These results indicate that the higher sensitivity and binding capacity of the tumor cells to the bacteriocin is probably due to the presence of a large amount of N-acetyl-glucosamine or closely related sugar residues with a high affinity for bacteriocin, as compared with normal cells. The bacteriocin produced morphological alterations and inhibition of synthesis of ribonucleic acid, deoxyribonucleic acid and protein in the transformed but not in the nontransformed cells.     

Collapse of the proton motive force in Listeria monocytogenes caused by a bacteriocin produced by Pediococcus acidilactici.

The effect of pediocin JD, a bacteriocin produced by Pediococcus acidilactici JD1-23, on the proton motive force and proton permeability of resting whole cells of Listeria monocytogenes Scott A was determined. Control cells, treated with trypsin-inactivated bacteriocin at a pH of 5.3 to 6.1, maintained a pH gradient and a membrane potential of approximately 0.65 pH unit and 75 mV, respectively. However, these gradients were rapidly dissipated in cells after exposure to pediocin JD, even though no cell lysis had occurred. The pH gradient and membrane potential of the producer cells were also unaffected by the bacteriocin. Whole cells treated with bacteriocin were twice as permeable to protons as control cells were. The results suggest that the inhibitory action of pediocin JD against L. monocytogenes is directed at the cytoplasmic membrane and that inhibition of L. monocytogenes may be caused by the collapse of one or both of the individual components of the proton motive force.     

Collapse of the proton motive force in Listeria monocytogenes caused by a bacteriocin produced by Pediococcus acidilactici.

The effect of pediocin JD, a bacteriocin produced by Pediococcus acidilactici JD1-23, on the proton motive force and proton permeability of resting whole cells of Listeria monocytogenes Scott A was determined. Control cells, treated with trypsin-inactivated bacteriocin at a pH of 5.3 to 6.1, maintained a pH gradient and a membrane potential of approximately 0.65 pH unit and 75 mV, respectively. However, these gradients were rapidly dissipated in cells after exposure to pediocin JD, even though no cell lysis had occurred. The pH gradient and membrane potential of the producer cells were also unaffected by the bacteriocin. Whole cells treated with bacteriocin were twice as permeable to protons as control cells were. The results suggest that the inhibitory action of pediocin JD against L. monocytogenes is directed at the cytoplasmic membrane and that inhibition of L. monocytogenes may be caused by the collapse of one or both of the individual components of the proton motive force.     

Mechanism of action of nalidixic acid on Escherichia coli. 3. Conditions required for lethality

Deitz, William H. (Sterling-Winthrop Research Institute, Rensselaer, N.Y.), Thomas M. Cook, and William A. Goss. Mechanism of action of nalidixic acid on Escherichia coli. III. Conditions required for lethality. J. Bacteriol. 91:768-773. 1966.-Nalidixic acid selectively inhibited deoxyribonucleic acid (DNA) synthesis in cultures of Escherichia coli 15TAU. Protein and ribonucleic acid synthesis were shown to be a prerequisite for the bactericidal action of the drug. This action can be prevented by means of inhibitors at bacteriostatic concentrations. Both chloramphenicol, which inhibits protein synthesis, and dinitrophenol, which uncouples oxidative phosphorylation, effectively prevented the bactericidal action of nalidixic acid on E. coli. The lethal action of nalidixic acid also was controlled by transfer of treated cells to drug-free medium. DNA synthesis resumed immediately upon removal of the drug and was halted immediately by retreatment. These studies indicate that nalidixic acid acts directly on the replication of DNA rather than on the "initiator" of DNA synthesis. The entry of nalidixic acid into cells of E. coli was not dependent upon protein synthesis. Even in the presence of an inhibiting concentration of chloramphenicol, nalidixic acid prevented DNA synthesis by E. coli 15TAU.     

Mode of Action of Novobiocin in Escherichia coli

The mechanism of action of novobiocin was studied in various strains of Escherichia coli. In all strains tested except mutants of strain ML, the drug immediately and reversibly inhibited cell division, and later slowed cell growth. The previously described impairment of membrane integrity, degradation of ribonucleic acid (RNA), and associated bactericidal effect were found to be peculiar to ML strains. The earliest and greatest effect in all strains was an inhibition of deoxyribonucleic acid (DNA) synthesis; RNA synthesis was inhibited to a lesser extent, and cell wall and protein synthesis were affected later. The inhibition of nucleic acid synthesis was accompanied by an approximately threefold accumulation of all eight nucleoside triphosphates. Since novobiocin does not inhibit nucleoside triphosphate synthesis, degrade DNA, or immediately affect energy metabolism, it must inhibit the synthesis of DNA and RNA by direct action on template-polymerase complexes.     

Expression of histone and alkaline phosphatase genes in UMR 106-01 rat osteoblast-like cells exposed to the hoechst dye H33342

The fluorescent Dye H33342 (H342) is a bis-benzimidazole used for intravital fluorescent staining. In this report, we found that H342 completely abolished histone 2a mRNA but had no effect on alkaline phosphatase gene expression and protein synthesis in UMR 106-01 rat osteoblast-like cells. The complete loss of histone 2a mRNA occurred after only 20 min of treatment with H342. This effect is unlikely to be a result of inhibition of DNA synthesis, which was only partly suppressed. The mechanism of the action of H342 on histone 2a mRNA is presently unknown. © 1993 Wiley-Liss, Inc.     

Characterization of the protein-synthesis dependent adaptive acid tolerance response in Lactobacillus acidophilus

Exposure of L. acidophilus CRL 639 cells to sublethal adaptive acid conditions (pH 5.0 for 60 min) was found to confer protection against subsequent exposure to lethal pH (pH 3.0). Adaptation, which only occurred in complex media, was dependent on de novo protein synthesis and was inhibited by amino acid analogues. There was no modification in the protein synthesis rate during adaptation, but the protein degradation rate decreased. Synthesis of acid stress proteins may increase the stability of pre-existing proteins. By 2D-PAGE, induction of nine acid stress proteins and repression of several housekeeping proteins was observed. Putative heat shock proteins DnaK, DnaJ, GrpE, GroES and GroEL (70, 43, 24, 10 and 55 kDa, respectively) were among the proteins whose synthesis was induced in response to acid adaptation.