Ribosomal alterations contribute to bacterial resistance against the dipeptide antibiotic TAN 1057.

TAN 1057-resistant Staphylococcus aureus and Escherichia coli strains were selected to elucidate the mechanism of resistance and the mode of action of this dipeptide antibiotic. Cell-free translation with isolated ribosomes and S150 fractions from sensitive and resistant S. aureus strains demonstrated that alterations in the ribosomes contribute to the resistance of the bacteria.

Ribosomal RNA is the target for oxazolidinones, a novel class of translational inhibitors.

Oxazolidinones are antibacterial agents that act primarily against gram-positive bacteria by inhibiting protein synthesis. The binding of oxazolidinones to 70S ribosomes from Escherichia coli was studied by both UV-induced cross-linking using an azido derivative of oxazolidinone and chemical footprinting using dimethyl sulphate. Oxazolidinone binding sites were found on both 30S and 50S subunits, rRNA being the only target. On 16S rRNA, an oxazolidinone footprint was found at A864 in the central domain. 23S rRNA residues involved in oxazolidinone binding were U2113, A2114, U2118, A2119, and C2153, all in domain V. This region is close to the binding site of protein L1 and of the 3' end of tRNA in the E site. The mechanism of action of oxazolidinones in vitro was examined in a purified translation system from E. coli using natural mRNA. The rate of elongation reaction of translation was decreased, most probably because of an inhibition of tRNA translocation, and the length of nascent peptide chains was strongly reduced. Both binding sites and mode of action of oxazolidinones are unique among the antibiotics known to act on the ribosome.

The 39-kilodalton outer membrane protein of Proteus mirabilis is an OmpA protein and mitogen for murine B lymphocytes.

Partial amino acid sequence analysis of a major outer membrane protein of Proteus mirabilis (39-kDa protein) indicates that it is an OmpA protein. The mitogenic activities of the 39-kDa protein for murine lymphocytes were also investigated with T lymphocytes isolated by passing spleen cells over columns of nylon wool fiber and B lymphocytes obtained by treating spleen cells with monoclonal antibodies to Thy1 plus complement. The 39-kDa protein showed little activity in stimulating T cells to proliferate but was strongly mitogenic for B cells.

Composition of the outer membrane of Proteus mirabilis in relation to serum sensitivity in progressive stages of cell form defectiveness.

A serum-resistant strain of Proteus mirabilis was used to determine whether changes in the composition of surface components could be detected following induction of progressive stages of cell form defectiveness by beta-lactam antibiotics. The critical stage was the conversion from filaments to the spheroplast form, which was accompanied by increased susceptibility to the bactericidal action of human serum. Inner and outer membranes of the bacterium, its filament form and its spheroplast form were separated by sucrose density-gradient centrifugation after digestion of peptidoglycan, followed by osmotic lysis of the cells. Outer membranes of the bacterial and the filament forms sedimented at the same density, whilst the outer membrane fraction of the spheroplast form sedimented in a region of lesser density. In addition, the amounts of two major outer-membrane proteins as well as the O-polysaccharide content of the lipopolysaccharide were reduced in the spheroplast form. These results indicate a general disorganization in structure and assembly of components in regard to their interactions with one another in the outer membrane of the spheroplast form.

The capsular polysaccharide is a major determinant of serum resistance in K-1-positive blood culture isolates of Escherichia coli.

Serum resistance is a major virulence factor of gram-negative bacteria, and K-1 polysaccharide has been shown to contribute to serum resistance in selected strains. To obtain further information about the role of K-1 in serum resistance and to find out whether loss of the ability to produce K-1 can induce loss of serum resistance, we studied the serum resistance of mutants derived from completely serum-resistant, K-1-positive blood culture isolates of Escherichia coli by selection for resistance to infection with K-1 specific bacteriophages. The amounts of K-1 polysaccharide produced by wild-type strains and mutants were measured, and outer membrane protein and lipopolysaccharide (LPS) patterns were analyzed. In each group of mutants, several highly serum-sensitive strains were found. All mutant strains expressed less K-1 than did the corresponding wild-type strains. Mutants that became highly serum sensitive always had less K-1 than did mutants with less-pronounced changes of serum resistance. A few mutants derived from different wild-type strains showed increased expression of outer membrane proteins with molecular weights of about 46,000 and 67,000. All of the wild-type strains examined had smooth-type LPS, and only two mutants had altered LPS structures; alterations of mutants in outer membrane proteins and LPS could not be correlated with alterations of serum resistance. The results indicate that for K-1-positive blood culture strains of E. coli, K-1 expression is a prerequisite for serum resistance, and loss of ability to synthesize K-1 leads to loss of serum resistance.

Reduced proliferative response of mouse spleen cells to mitogens during infection with Salmonella typhimurium or Listeria monocytogenes.

A significant reduction in the mitogenic responsiveness (uptake of 3H-thymidine) of murine spleen cells to concanavalin A, phytohemagglutinin or lipopolysaccharide was observed during infection with virulent Salmonella typhimurium. The decreased response to mitogens could be observed independent of the immunity to typhimurium (Ity) genotype, i.e. in CBA/J mice and C3H/HeJ mice (Ityr) as well as in C57BL/6 mice (Itys). Because reduced responsiveness was demonstrated in C3H/HeJ mice, which are susceptible to S. typhimurium infection but are unresponsive to lipopolysaccharide, it is concluded that the two phenomena are not correlated with one another. A similar decrease in response to mitogens was shown in mice infected with Listeria monocytogenes. Reduction in mitogenic responsiveness was directly correlated with the number of viable bacteria detected in the spleen cell suspension. Decreased lymphoproliferation could be observed as early as 2 days after infection and lasted 3 weeks in sublethally infected mice. The question remains whether or not the reduced responsiveness indicates an enhanced susceptibility to infection or merely represents a high degree of activation of defense mechanisms.

Influence of beta-lactam antibiotics and ciprofloxacin on cell envelope of Escherichia coli.

The effects of subinhibitory concentrations of different beta-lactam antibiotics and one quinolone on the quantitative composition of the outer membrane (OM) of two strains of Escherichia coli, on lipid translocation into the OM, and on the production of capsular K1 polysaccharide were studied. The phospholipid/amino acid ratio was reduced in almost all OM preparations from antibiotic-treated bacteria. In one strain, antibiotic treatment increased the lipopolysaccharide/amino acid ratio. The amount of peptidoglycan fragments bound to the OM was increased by all the antibiotics. In pulse-chase experiments with a radioactive lipid precursor, ciprofloxacin, imipenem, and aztreonam inhibited phospholipid translocation into the OM. Furthermore, imipenem, cephaloridine, and ciprofloxacin induced a pronounced reduction of the production of capsular K1 polysaccharide. Thus, antibiotics seem to induce marked changes of the quantitative composition of the cell envelope of E. coli. Possible connections of these data with findings on the influence of antibiotics on functional parameters of the host-parasite relationship such as OM immunogenicity and serum resistance are discussed.

Serological response to type 1-like somatic fimbriae in diarrheal infection due to classical enteropathogenic Escherichia coli.

Fimbriae from enteropathogenic Escherichia coli strain E2349/69 (0127:H6) and its plasmid-minus derivative, MAR20, were purified and characterized as type 1-like by their physicochemical and hemagglutination patterns. Sera from adult volunteers challenged with the diarrheagenic parent strain and the attenuated plasmid-minus derivative were examined to detect an immune response, using the purified fimbriae as antigens in an enzyme linked immunosorbent assay (ELISA) and immunoblot assay. An anti-fimbrial response was evident in sera of 7 of 10 volunteers fed the diarrheagenic parent strain E2348 but also in 8 of 9 individuals fed the attenuated, plasmid-cured, derivative MAR20. The antibody response appeared specific in that the sera failed to react in an ELISA and by immunoblot assay with type 1 fimbriae from other E. coli. These findings suggest that the type 1 fimbriae of this representative EPEC strain are antigenically distinct. The results of this investigation provide the first evidence of seroconversion to type 1-like fimbriae in infections caused by diarrheagenic E. coli.

Influence of beta-lactam antibiotics and ciprofloxacin on composition and immunogenicity of Escherichia coli outer membrane.

The effects of subinhibitory concentrations of different beta-lactam antibiotics and one quinolone on the sedimentation of outer membranes (OMs) of Escherichia coli and on the qualitative properties and immunogenicity of OM components were studied. Membranes were prepared by osmotic lysis of plasmolyzed bacteria. OM and cytoplasmic membrane vesicles were separated by sucrose density ultracentrifugation. Two peaks of OM vesicles with different buoyant densities could be isolated; the quantitative contribution of these to the total OM varied, depending upon the growth phase. In early log phase, the OM consisted mainly of lighter material; in late log and stationary phases, the OM consisted mainly of heavier material. Moxalactam, imipenem, and ciprofloxacin inhibited the formation of heavier material in all growth phases. The immunogenicity of OM vesicles was tested in mice by the hemolytic plaque test. The lighter OM material was markedly less immunogenic than the heavier OM material. The vesicles from antibiotic-treated bacteria and those from early-log-phase cells were less immunogenic than vesicles from untreated late-log-phase and stationary-phase bacteria. These changes were found for the immune response against lipopolysaccharides, as well as against OM proteins. Thus, the immunogenicity of OM components seems to be dependent upon the quantitative composition of lighter and heavier compounds, which is strongly influenced by growth phase and treatment with certain antibiotics.

Three-dimensional structure of fimbriae determines specificity of immune response.

We recently described how a fraction of isolated fimbriae from a multifimbriated strain of Escherichia coli O7:K1:H6 (WF96) could be subdivided by sequential disaggregation in disrupting agents into individual subunits with different molecular weights. In this study, antibodies were raised in rabbits against these isolated fimbrial subunits and against purified intact WF96 fimbriae. These sera were tested by Western blot analysis or by enzyme-linked immunosorbent assays for reactivity against the following antigens: intact WF96 fimbriae, dissociated WF96 fimbriae, dissociated and reaggregated WF96 fimbriae, the WF96 21K fimbrial subunit, reaggregated WF96 21K subunits, the WF96 16K subunits, reaggregated WF96 16K subunits, intact fimbriae from four other E. coli strains, and deaggregated fimbriae from these strains. We found that antibody against intact WF96 fimbriae only reacted strongly with intact WF96 fimbriae, depolymerized and reaggregated WF96 fimbriae, or reaggregated fimbrial subunits; no reactions were evident with intact fimbriae from four other E. coli strains. Conversely, antisera prepared against the WF96 16K subunit and against the WF96 21K subunit did not react with intact WF96 fimbriae or with depolymerized and reaggregated WF96 fimbriae, but did react with homologous isolated subunits. One cross-reaction between fimbrial subunits was apparent: anti-WF96 16K subunit bound to a 21K subunit of deaggregated fimbriae, from another E. coli strain. Taken together, the findings indicate that the three-dimensional structure of the fimbrial preparation used to immunize animals determines the specificity of the immune response.

Isolation and separation of physicochemically distinct fimbrial types expressed on a single culture of Escherichia coli O7:K1:H6.

The fimbrial (pili) profile of a single strain of Escherichia coli O7:K1:H6 (WF96) was evaluated. Fimbriae were isolated by sucrose density gradient ultracentrifugation, purified from flagellae by the use of 0.4% sodium dodecyl sulfate (SDS), and separated into distinct fimbrial types. Analysis of the purified WF96 fimbriae by SDS-polyacrylamide gel electrophoresis revealed two polypeptide bands with molecular weights of 16,000 and 21,000. Treatment of the fimbrial mixture with saturated guanidine hydrochloride resulted in the appearance of a third band with a molecular weight of 19,500. The relative susceptibilities of the WF96 fimbrial types to disrupting chemicals (octyl-glucoside, urea, SDS, and guanidine hydrochloride) were assessed by exposure of the fimbrial mixture to each agent, separation of the depolymerized fimbriae from intact fimbriae by gel filtration on Sepharose CL-4B, and identification of the disaggregated fimbrial types by SDS-polyacrylamide gel electrophoresis of column fractions. The physicochemical heterogeneity of the three fimbrial types coexpressed on WF96 was exploited to develop a method for separation of individual fimbriae.

Stable insertion of C5b-9 complement complexes into the outer membrane of serum treated, susceptible Escherichia coli cells as a prerequisite for killing.

Escherichia coli 17, a K12 derivative, was rapidly killed by human serum following a short lag period of 10 min. Stable binding of terminal C5b-9 complement complexes was investigated in time course experiments. Serum treated E. coli cells were lysed osmotically and the resulting outer and cytoplasmic membrane vesicles separated by sucrose gradient centrifugation. Exposure of E. coli 17 to serum rapidly reduced the degree of recoverability of cytoplasmic membrane vesicles. Electron microscopy revealed no interaction of C5b-9 complexes with CM vesicles. In contrast there was a clear time-dependent deposition of terminal complement complexes onto OM-vesicles. Very few complexes were detected during the prekilling phase of the reaction; initiation of the active killing phase was accompanied by a large increase in complement lesions. In contrast, no C5b-9 complexes could be visualised on outer or cytoplasmic membrane vesicles of a smooth, serum-resistant E. coli strain. We conclude that complement-mediated killing is a consequence of stable binding of C5b-9 complexes to the outer membrane of susceptible strains.

Interaction of human complement proteins with serum-sensitive and serum-resistant strains of Escherichia coli.

Exposure of serum-susceptible Escherichia coli strains to lethal concns of lysozyme-free human serum resulted in stable binding of complement components to the outer membrane (OM), but not to the cytoplasmic membrane (CM). The short prekilling phase of the reaction was accompanied by binding of C3b; loss of viability was immediately preceeded by stable deposition onto the OM of the component proteins of the membrane attack complex. During the early stages of the active killing phase, bound monomeric C9 could be resolved into two distinct bands on SDS-polyacrylamide gels. Serum exposure lead to a progressive loss of CM recoverability, which appeared to result from partial degradation of CM phospholipids. In contrast, exposure of a resistant E, coli strain to human serum resulted in little change in the membrane profile and very little stable deposition of terminal complement components onto the OM.

Membrane changes induced by exposure of Escherichia coli to human serum.

The effect of bactericidal concentrations of lysozyme-free human serum on parameters of membrane integrity has been studied in serum-susceptible and serum-resistant Escherichia coli strains. Serum treatment released all of the alkaline phosphatase from the periplasmic space of two rapidly serum-susceptible strains but did so at different rates. In contrast, no periplasmic enzyme was released from two serum-resistant strains or from one moderately susceptible smooth strain. Lysozyme-free serum and heat-inactivated serum released comparable amounts of 86Rb+ from preloaded cells at comparable rates, regardless of serum susceptibility. Serum decreased the rate of phospholipid biosynthesis in both serum-susceptible and serum-resistant strains. In susceptible but not in resistant strains, intracellular ATP pools were depleted after serum exposure. Outer membranes and cytoplasmic membranes were prepared from serum-treated E. coli, and assays for C3 and C5b-9(m) were performed. With rapidly susceptible strains, C3 deposition on the outer membrane without attachment of C5b-9(m) occurred during the short prekilling phase. Subsequent bacterial killing was accompanied by deposition of C5b-9(m), which was recovered with C3 exclusively in outer membrane fractions with increased density and by eventual total loss of recoverable cytoplasmic membranes. Minimal deposition of complement components, without accompanying cytoplasmic membrane loss, occurred with serum-resistant strains. Loss of recoverable cytoplasmic membrane was not due to the action of either serum or bacterial phospholipase A. The results raise the possibilities that C5b-9(m) primarily damages the outer membrane and that the bacteria themselves actively participate in the ensuing, as yet unclarified, metabolic reactions that finally lead to their death.

Killing of an encapsulated strain of Escherichia coli by human serum.

Changes in cell viability and in factors affecting metabolic integrity were examined after exposure of Escherichia coli LP1092 to human serum. Antibody-dependent classical pathway activity accounted for the rapid killing of strain LP1092 by complement. Removal of serum lysozyme by bentonite absorption or by neutralization with anti-human lysozyme immunoglobulin G resulted in a reduction in the rate of killing; optimal activity could be restored by the addition of physiological amounts of egg-white lysozyme. The pattern of 86Rb+ and alkaline phosphatase release obtained after serum treatment did not support the view that complement simultaneously disrupts cytoplasmic and outer membrane integrity. Macromolecular synthesis was affected late in the reaction sequence; complete inhibition of precursor incorporation into RNA, DNA, and protein occurred only after almost total loss of bacterial colony-forming ability. Addition of chloramphenicol, an inhibitor of protein synthesis, to the bactericidal system resulted in a marked reduction in the rate of serum killing. Killing was completely inhibited by an inhibitor (KCN) and an uncoupler (2,4-dinitrophenol) of oxidative phosphorylation. Exposure of LP1092 cells to serum was followed by a rapid and large increase in intracellular ATP levels; ATP synthesis did not occur when bacteria were exposed to dialyzed serum, which killed LP1092 cells at a much reduced rate. Addition of glucose or serum ultrafiltrate to dialyzed serum restored optimal bactericidal activity. We suggest that optimal killing of gram-negative bacteria is an energy-dependent process requiring an input of bacterially generated ATP.

Membranes of the protoplast L-form of Proteus mirabilis.

Isolated membranes of the cell wall-less stable protoplast L-form of Proteus mirabilis were characterized by density gradient centrifugation and by assay for their major chemical constituents, proteins, phospholipids and lipopolysacchartide, and for some specific marker enzymes of the cytoplasmic membrane. In most of the analyzed properties the L-form protoplast membrane resembled the bacterial cytoplasmic membrane, with some notable modifications. Considerable amounts of lipopolysaccharide, normally an exclusive constituent of the outer membrane, were found. Furthermore, the L-form membranes contained the functions of the reduced nicotinamide adenine dinucleotide oxidase system, of D-lactate dehydrogenase (EC 1.1.1.28) and of succinate dehydrogenase (EC 1.3.99.1) at specific activities comparable to, or in some cases considerably higher than, those present in cytoplasmic membranes of the bacterial form. Of two peptidoglycan DD-carboxypeptidase/transpeptidases (EC 3.4.17.8 and EC 2.3.2.10). which are normally present in the cytoplasmic membrane of the bacterial form of P. mirabilis, the membrane of the protoplast L-form contained only one. Electron microscopy of thin sectioned L-form protoplasts showed extensive heterogeneity of membraneous structures. In addition to the single membraneous integument, internal membrane-bounded vesicles and multiple stacks of membranes were present, as the result of unbalanced growth and membrane synthesis in the L-form state.