Chlorobenzenes are toxic, highly persistent and ubiquitously distributed environmental contaminants that accumulate in the food chain. The only known microbial transformation of 1,2,3,5-tetrachlorobenzene (TeCB) and higher chlorinated benzenes is the reductive dechlorination to lower chlorinated benzenes under anaerobic conditions observed with mixed bacterial cultures. The lower chlorinated benzenes can subsequently be mineralized by aerobic bacteria. Here we describe the isolation of the oxygen-sensitive strain CBDB1, a pure culture capable of reductive dechlorination of chlorobenzenes. Strain CBDB1 is a highly specialized bacterium that stoichiometrically dechlorinates 1,2,3-trichlorobenzene (TCB), 1,2,4-TCB, 1,2,3,4-TeCB, 1,2,3,5-TeCB and 1,2,4,5-TeCB to dichlorobenzenes or 1,3,5-TCB. The presence of chlorobenzene as an electron acceptor and hydrogen as an electron donor is essential for growth, and indicates that strain CBDB1 meets its energy needs by a dehalorespiratory process. According to their 16S rRNA gene sequences, strain CBDB1, Dehalococcoides ethenogenes and several uncultivated bacteria form a new bacterial cluster, of which strain CBDB1 is the first, so far, to thrive on a purely synthetic medium.
Staphylococcal Cell Wall: Morphogenesis and Fatal Variations in the Presence of Penicillin
SUMMARY 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 inactivation of FemB by insertion of TnS51 in the central part of thefemB open reading frame was shown to increase susceptibility of methicillin-resistant Staphylococcus aureus strains toward 13-lactam antibiotics to the same extent as did inactivation offemA. Strains carrying the methicillin resistance determinant (mec) and expressing PBP 2' were affected to the same extent as were strains selected for in vitro resistance, which did not express PBP 2'. BothfemA andfemB, which form an operon, are involved in a yet unknown manner in the glycine interpeptide bridge formation of the S. aureus peptidoglycan. FemB inactivation was shown to reduce the glycine content of peptidoglycan by approximately 40%o, depending on the S. aureus strain. The reduction of the interpeptide bridge glycine content led to significant reduction in peptidoglycan cross-linking, as measured by gel permeation high-pressure liquid chromatography of muramidase-digested cell walls. Maximum peptide chain length was reduced by approximately 40%. It is shown that the complete pentaglycine interpeptide bridge is important for the sensitivity against 13-lactam antibiotics and for the undisturbed activity of the staphylococcal cell wall-synthesizing and hydrolyzing enzymes, as was also apparent from electron microscopic examinations, which revealed aberrant placement of cross walls and retarded cell separation, leading to a pseudomulticellular phenotype of the cells for bothfemA and femB mutants.Methicillin resistance in staphylococci is an intrinsic resistance of the cells to virtually all 1-lactam antibiotics, including cephalosporins and carbapenems, and does not involve drug destruction (12). The genetic determinant of methicillin resistance (mec) carries the structural gene mecA, coding for an additional low-affinity penicillin-binding protein, PBP 2' or 2a (25,37,40). PBP 2' is thought to be the only functional PBP in cell wall synthesis in the presence of otherwise inhibitory concentrations of methicillin (10,13,21,29,34) and is a prerequisite for methicillin resistance.mec-mediated methicillin resistance in clinical isolates of Staphylococcus aureus is typically heterogeneous in phenotypic expression despite genetic homogeneity (reviewed by Matthews and Stewart [30] 1-lactams (27).The product of femA is a 48-kDa protein involved in the pentaglycine cross-bridge formation of the S. aureus peptidoglycan (27). This conclusion was subsequently sustained by mass spectrometric analysis of related mutants (11). Whereas the inactivation offemA correlates with a 40 to 60% reduction in the interpeptide glycine content of S. aureus peptidoglycan, with a reduction in cross-linking and cell wall turnover, and with increased susceptibility to 1-lactams, no influence on the synthesis of PBP 2' was observed. Downstream and adjacent to femA lies a second factor, femB. femB mutants described earlier (4) apparently still retained part of their activity, presumably because they were insertionally inactivated at their outmost carboxy terminus. We show here t...
Staphylococcal Peptidoglycan Interpeptide Bridge Biosynthesis: A Novel Antistaphylococcal Target?
In staphylococci, crosslinking of the peptide moiety of peptidoglycan is mediated via an additional spacer, the interpeptide bridge, consisting of five glycine residues. The femAB operon, coding for two approximately 50-kDa proteins is known to be involved in pentaglycine bridge formation. Using chemical mutagenesis of the beta-lactam-resistant strain BB270 and genetic, biochemical, and biophysical characterization of mutants selected for loss of beta-lactam resistance and reduced lysostaphin sensitivity it is shown that peptide bridge formation proceeds via three intermediate bridge lengths (cell wall peptides with no, one, three, and five glycine units). To proceed from one intermediate to the next, three genes appear necessary: femX, femA, and femB. The drastic loss of beta-lactam resistance after inactivation of FemA or partial impairment of FemX even beyond the level of the sensitive wild-type strains renders these proteins attractive antistaphylococcal targets.
It is generally assumed that nucleic acids are localized inside of living cells and that their primary function is the storage of information. In contrast, extracellular DNA is mainly considered as a remnant of lysed cells. Here, we report the formation of extracellular bacterial DNA as a spatial structure. An aquatic bacterium, strain F8, was isolated, which produced a stable filamentous network of extracellular DNA. Different staining and enzymatic techniques confirmed that it was DNA. We were able to amplify the 16S rRNA gene from the extracellular DNA. Restriction endonuclease cleavage and randomly amplified polymorphic DNA analysis of extracellular and genomic DNAs revealed major similarities, but also some differences in both sequences. Our data demonstrate a new function and relevance for extracellular DNA.
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