Peptidoglycan recognition proteins kill bacteria by activating protein-sensing two-component systems

Mammalian peptidoglycan recognition proteins (PGRPs), similar to antimicrobial lectins, bind the bacterial cell wall and kill bacteria through an unknown mechanism. We show that PGRPs enter the Gram-positive cell wall at the site of daughter cell separation during cell division. In Bacillus subtilis, PGRPs activate the CssR-CssS two-component system that detects and disposes of misfolded proteins that are usually exported out of bacterial cells. This activation results in membrane depolarization, cessation of intracellular peptidoglycan, protein, RNA and DNA synthesis, and production of hydroxyl radicals, which are responsible for bacterial death. PGRPs also bind the outer membrane of Escherichia coli and activate the functionally homologous CpxA-CpxR two-component system, which kills the bacteria. We exclude other potential bactericidal mechanisms, including inhibition of extracellular peptidoglycan synthesis, hydrolysis of peptidoglycan and membrane permeabilization. Thus, we reveal a previously unknown mechanism by which innate immunity proteins that bind the cell wall or outer membrane exploit the bacterial stress defense response to kill bacteria.     

Characterization of the proteins of intracisternal type A and extracellular oncornavirus-like particles produced by MOPC-460 myeloma cells.

A number of translation inhibitors were tested for their effects on both control and encephalomyocarditis virus-infected mouse 3T6 cells. The virus-infected cells were specifically inhibited by gougerotin, edeine, and blasticidin S, whereas these drugs failed to penetrate into uninfected cells. Inhibition of infected cells by gougerotin became apparent when the synthesis of viral proteins commenced, suggesting that the latter process is accompanied by a permeability change in the cells that allows uptake of the drug. This permeability change was not observed in cells treated with cycloheximide soon after viral infection, although treatment with actinomycin D did not prevent inhibition of gougerotin. It is possible, therefore, that a specific viral protein is involved in the permeability change of the plasma membrane. Moreover, gougerotin was unable to inhibit protein synthesis in the presence of zinc ions, thus preventing gougerotin from entering into the infected cell. Membrane leakiness was not restricted to the encephalomyocarditis virus-3T6 system; it was also observed in mengovirus-infected 3T6 cells, Semliki Forest virus-infected BHK cells, and simian virus 40-infected CVI1 cells at the time in which the synthesis of late proteins is maximal.     

Antibacterial activity of hypocrellin A against Staphylococcus aureus

The antibacterial activity and acting mechanism of hypocrellin A (HA) were conducted regarding in vitro activity of HA on Staphylococcus aureus GZ86 by analyzing the growth, permeability, and morphology of the bacterial cells following treatment with HA. The experimental results indicated 1.5?mg/l HA could completely inhibit the growth of 10^7?CFU/ml S. aureus cells in liquid beef extract-peptone medium under a halogen?Ctungsten lamp for 120?min. Meanwhile, HA resulted in the leakage of reducing sugars and proteins and induced the respiratory chain dehydrogenases into inactive state, suggesting that HA were able to destroy the permeability of the bacterial membranes. When the cells of S. aureus were exposed to 2.5?mg/l HA under a halogen?Ctungsten lamp for 120?min, many pits and gaps were observed in bacterial cells by scanning electron microscopy, and the cell wall was fragmentary, indicating the bacterial cells were damaged severely. The experiments strongly confirmed the contribution of multiform reactive oxygen species (ROS) to bactericidal effect. In conclusion, the combined results suggested that ROS may damage the structure of bacterial cell wall and depress the activity of some membranous enzymes, which cause S. aureus bacteria to die eventually.     

Mutagenicity, carcinogenicity and teratogenicity of beryllium

The carcinogenicity of a number of beryllium compounds has been confirmed in experiments on laboratory animals and this metal has to be treated as a possible carcinogenic threat to man. These carcinogenic properties are associated with mutagenic activity as shown by the results of short-term tests performed in vitro with beryllium chloride and beryllium sulfate. These soluble beryllium compounds can produce some infidelity of in vitro synthesis, forward gene mutations in microorganisms and in mammalian cells. They are also able to induce cell transformation. In addition to the positive results obtained in several short-term assays beryllium compounds have been found to bind to nucleoproteins, to inhibit certain enzymes needed for DNA synthesis, to bind nucleic acids to cell membranes and to inhibit microtubule polymerization. The teratogenicity of beryllium salts is relatively unknown and needs additional investigation.     

Butyrate inhibits and Escherichia coli-derived mitogen(s) stimulate DNA synthesis in human hepatocytes in vitro

Bacterial constituents and products of the bacterial metabolism pass from the gut lumen to the portal vein and may influence the homeostasis of the liver. Our aim is to examine whether DNA synthesis of human hepatocyte cell lines is affected by constituents of Escherichia coli species as well as by intracolonic products of bacterial fermentation that reach the liver via the portal vein. Supernatant solutions and bacterial cell fractions (containing either whole dead bacteria, cell walls, cytosol or non-soluble intracellular components) of E. coli K12 and of E. coli species from rat fecal flora were separated by multi-step centrifugation, French press, and microfiltration. The supernatant solution and the cell fractions were incubated with a human hepatoma cell line (Hep-G2) and with a cell line derived from non-malignant human liver cells (Chang cells) for 24 h. The cells were labeled with tritiated thymidine before processing to autoradiography. DNA synthesis was estimated by the labeling index (LI%). DNA synthesis was also estimated following incubation of Hep-G2 cells with short chain fatty acids (acetic, propionic, butyric and succinic acid), acetaldehyde, and ammonium chloride. Epidermal growth factor and a water extract of Helicobacter pylori were used as references. The fractions of E. coli from rat fecal flora containing cytosol and non-soluble intracellular components significantly increased the labeling index in both Hep-G2 and Chang cells (p < 0.05). In addition, the supernatant solution significantly increased the LI in Chang cells (p < 0.05). Epidermal growth factor increased the LI of Hep-G2 cells dose-dependently (p < 0.05). Butyric acid reduced DNA synthesis at 10(-4) M (p < 0.05). The highest doses of acetaldehyde were cytotoxic and reduced the LI. Escherichia coli species contain mitogenic factors to human hepatocytes. The mitogen(s) are present in the supernatant solution, in the cytosol and in non-soluble intracellular components. Butyrate, which is a product of bacterial fermentation of colonic substrates inhibit DNA synthesis in the hepatocyte cell lines. Our findings suggest that soluble mitogen(s) that diffuse from the microorganism to the outer environment, intracellular bacterial constituents, and products of the bacterial metabolism that reach the liver via the portal vein may influence the cell kinetic steady-state of hepatic cells.     

Caffeine inactivation of mammalian cells in the S phase of the mitotic cycle due to anomalous replicon initiation during the inhibition of the elongation of replicating DNA

Chinese hamster cells were treated with an inhibitor of DNA synthesis (hydroxyurea or arabinoside-cytesine) in non-toxic concentrations for 20 hours in the presence or absence of caffeine (2 mM). Under these conditions caffeine considerably inactivates the cells. If cells are synchronized by hydroxyurea (0.25 mM) in the S-phase of mitotic cycle, the addition of caffeine kills all the S-phase cells, while gamma-irradiation or novobiocine treatment markedly decreases the sensibilizing effect of caffeine. These findings permit us to conclude that cell inactivation is due to anomalous reinitiation of DNA synthesis stimulated by caffeine in the presence of drugs which inhibit the DNA chain elongation.     

Protein targeting by the bacterial twin-arginine translocation (Tat) pathway

The Tat (twin-arginine translocation) protein export system is found in the cytoplasmic membrane of most prokaryotes and is dedicated to the transport of folded proteins. The Tat system is now known to be essential for many bacterial processes including energy metabolism, cell wall biosynthesis, the nitrogen-fixing symbiosis and bacterial pathogenesis. Recent studies demonstrate that substrate-specific accessory proteins prevent improperly assembled substrates from interacting with the Tat transporter. During the transport cycle itself substrate proteins bind to a receptor complex in the membrane which then recruits a protein-translocating channel to carry out the transport reaction.     

Location of Sulfate-binding Protein in Salmonella typhimurium

A method is described for location of proteins in bacteria. It depends upon two techniques. One technique is the inactivation of the protein by a reagent which is incapable of penetrating the bacterial membrane (permeability barrier). Proteins inside this membrane cannot be inactivated unless the cells are disrupted; proteins on or outside the membrane can be inactivated. The second technique depends upon inactivation of the protein by specific antibody. Antibody should not penetrate the external bacterial wall, and therefore should only inactivate proteins that are on the wall surface. Thus, proteins can be localized inside the membrane, in the wall-membrane area, or outside the wall. One reagent developed for use with the first technique is diazo-7-amino-1,3-naphthalene-disulfonate. It inactivated beta-galactoside transport, but not beta-galactosidase of intact Escherichia coli. Similarly, it inactivated sulfate binding and transport but not uridine phosphorylase activity of Salmonella typhimurium. This indicates that the sulfate-binding protein is on or outside the cell membrane, and that uridine phosphorylase is inside the cell. The organic mercurial compounds used also showed that the sensitive parts of the sulfate and alpha-methylglucoside transport systems are less reactive than the sensitive part of the beta-galactoside system. Antibody to the sulfate-binding protein inactivated the purified protein but did not inactivate this protein when intact bacteria were employed. Thus, it appears that the sulfate-binding protein does not protrude outside the cell wall. The conclusion that the binding protein is located in the wall-membrane region is supported by its release upon spheroplast formation or osmotic shock, and also by its ability to combine with sulfate in bacteria which cannot transport sulfate into the cell.     

Transfer of T-DNA from agrobacteria into plant cells through cell walls and membranes

Discusses probable routes of agrobacterial penetration through the plant integumental tissues, cell wall, and plant cell plasmodesma. Analyzes the contribution of extracellular structures of agrobacteria in penetration through barriers of a plant cell, primary contact (adhesion), and during DNA transfer from bacterial (E. coli, A. tumefaciens) to recipient (bacterial or plant) cells. Discusses the relationship between donor cell adhesion to recipient cell surface and the infectious and conjugation processes. Considers the probable role of piles in conjugative transfer of agrobacterial DNA through membranes of donor and recipient (bacterial and plant) cells. Analyzes the contribution of the plant cell cytoskeleton to T-DNA transfer. Suggests a model of transport of T-DNA-VirD2 complex and VirE2 proteins through independent channels consisting of vir-coded proteins.     

Dependence of mammalian DNA synthesis on DNA supercoiling. III. Characterization of the inhibition of replicative and repair-type DNA synthesis by novobiocin and nalidixic acid

Novobiocin and nalidixic acid, inhibitors of the bacterial enzyme DNA gyrase, inhibit DNA, RNA and protein synthesis in several human and rodent cell lines. The sensitivity of DNA synthesis (both replicative and repair) to inhibition by novobiocin and nalidixic acid is greater than that of protein synthesis. Novobiocin inhibits RNA synthesis about half as effectively as it does DNA synthesis, whereas nalidixic acid inhibits both equally well. Replicative DNA synthesis, as measured by incorporation of [3H]thymidine, is blocked by novobiocin in a number of cell strains; the inhibition is reversible with respect to both DNA synthesis and cell killing, and continues for as long as 20--30 h if the cells are kept in novobiocin-containing growth medium. Both novobiocin and nalidixic acid inhibit repair DNA synthesis (measured by BND-cellulose chromatography) induced by ultraviolet light or N-methyl-N'-nitro-N-nitrosoguanidine (but not that induced by methyl methanesulfonate) at lower concentration (as low as 5 micrograms/ml) than those required to inhibit replicative DNA synthesis (50 micrograms/ml or greater). Neither novobiocin nor nalidixic acid alone induces DNA repair synthesis. Incubation of ultraviolet-irradiated cells with 10--100 micrograms/ml novobiocin results in little, if any, further reduction of colony-forming ability (beyond that caused by the ultraviolet irradiation). Novobiocin at sufficiently low concentrations (200 micrograms/ml) apparently generates a quiescent state (in terms of cellular DNA metabolism) from which recovery is possible. Under more drastic conditions of time in contact with cells and concentration, however, novobiocin itself induces mammalian cell killing.     

Enhancement of conductive anion permeability in cultured cells by cetiedil

Cetiedil, a drug that is reported to block K+-channels, substantially increases the conductive C1- permeability of Chinese hamster ovary (CHO) cells. The permeability was monitored by volume changes in cells treated with gramicidin to increase the cation permeability. Under this circumstance, increases in Cl- conductances result in volume changes detectable by electronic sizing, with the direction determined by the gradients of the permeating ions. In NaCl or KCl media, swelling occurs, but in N-methylglucamine chloride, shrinking. The increases in Cl- conductance could also be measured as an increased 36Cl- flux or by changes in membrane potential (measured by fluorescence of a potential-sensitive dye) toward the Cl- equilibrium potential. The effect of cetiedil was concentration dependent, with maximal effect at 50 microM. The anion specificity for the conductance was NO3- greater than Cl- = Br- much greater than SO4-2 or isethionate. A number of other drugs that influence transport activities had no effect on Cl- conductance. The cetiedil effect on Cl- conductance was observed in one other cell line, but was absent in several other cell types. The cetiedil-induced Cl- conductance in CHO cells appears to involve a different pathway than that induced by exposure to hypotonic medium.     

Diacridines: bifunctional intercalators. III. Definition of the general site of action.

Electron microscopy of HeLa cells exposed to spermine diacridine shows nucleolar distortions which disappear after several days despite the persistence of the metabolic changes promoted by spermine diacridine. This compound inhibits ribosomal RNA synthesis and appears to act independently of any particular phase of the cell cycle. The DNA content of the HeLa cells remains unchanged and the cell distribution is not significantly disturbed from its normal distribution in the various phases of the cell cycle. Spermine diacridine and other diacridines inhibit primarily chain initiation but also chain elongation by DNA-directed RNA polymerase of Azotobacter vinelandii.