The initial step for the successful establishment of urinary tract infections (UTIs), predominantly caused by uropathogenic Escherichia coli, is the adhesion of bacteria to urothelial cells. This attachment is mediated by FimH, a mannose-binding adhesin, which is expressed on the bacterial surface. To date, UTIs are mainly treated with antibiotics, leading to the ubiquitous problem of increasing resistance against most of the currently available antimicrobials. Therefore, new treatment strategies are urgently needed, avoiding selection pressure and thereby implying a reduced risk of resistance. Here, we present a new class of highly active antimicrobials, targeting the virulence factor FimH. When the most potent representative, an indolinylphenyl mannoside, was administered in a mouse model at the low dosage of 1 mg/kg (corresponding to approximately 25 μg/mouse), the minimal therapeutic concentration to prevent UTI was maintained for more than 8 h. In a treatment study, the colony-forming units in the bladder could be reduced by almost 4 orders of magnitude, comparable to the standard antibiotic treatment with ciprofloxacin (8 mg/kg, sc).
SummaryThe cell wall binding domains (CBD) of bacteriophage endolysins target the enzymes to their substrate in the bacterial peptidoglycan with extraordinary specificity. Despite strong interest in these enzymes as novel antimicrobials, little is known regarding their interaction with the bacterial wall and their binding ligands. We investigated the interaction of Listeria phage endolysin PlyP35 with carbohydrate residues present in the teichoic acid polymers on the peptidoglycan. Biochemical and genetic analyses revealed that CBD of PlyP35 specifically recognizes the N-acetylglucosamine (GlcNAc) residue at position C4 of the polyribitol-phosphate subunits. Binding of CBDP35 could be prevented by removal of wall teichoic acid (WTA) polymers from cell walls, and inhibited by addition of purified WTAs or acetylated saccharides. We show that Listeria monocytogenes genes lmo2549 and lmo2550 are required for decoration of WTAs with GlcNAc. Inactivation of either gene resulted in a lack of GlcNAc glycosylation, and the mutants failed to bind CBDP35. We also report that the GlcNAc-deficient phenotype of L. monocytogenes strain WSLC 1442 is due to a small deletion in lmo2550, resulting in synthesis of a truncated gene product responsible for the glycosylation defect. Complementation with lmo2550 completely restored display of characteristic serovar 1/2 specific WTA and the wild-type phenotype.
In vitro gut modeling is a useful approach to investigate some factors and mechanisms of the gut microbiota independent of the effects of the host. This study tested the use of immobilized fecal microbiota to develop different designs of continuous colonic fermentation models mimicking elderly gut fermentation. Model 1 was a three-stage fermentation mimicking the proximal, transverse and distal colon. Models 2 and 3 were based on the new PolyFermS platform composed of an inoculum reactor seeded with immobilized fecal microbiota and used to continuously inoculate with the same microbiota different second-stage reactors mounted in parallel. The main gut bacterial groups, microbial diversity and metabolite production were monitored in effluents of all reactors using quantitative PCR, 16S rRNA gene 454-pyrosequencing, and HPLC, respectively. In all models, a diverse microbiota resembling the one tested in donor’s fecal sample was established. Metabolic stability in inoculum reactors seeded with immobilized fecal microbiota was shown for operation times of up to 80 days. A high microbial and metabolic reproducibility was demonstrated for downstream control and experimental reactors of a PolyFermS model. The PolyFermS models tested here are particularly suited to investigate the effects of environmental factors, such as diet and drugs, in a controlled setting with the same microbiota source.
A study was performed on three isolates (LU2006-1T, LU2006-2 and LU2006-3), which were sampled independently from cheese in western Switzerland in 2006, as well as a fourth isolate (A11-3426), which was detected in 2011, using a polyphasic approach. The isolates could all be assigned to the genus Listeria but not to any known species. Phenotypic and chemotaxonomic data were compatible with the genus Listeria and phylogenetic analysis based on 16S rRNA gene sequences confirmed that the closest relationships were with members of this genus. However, DNA–DNA hybridization demonstrated that the isolates did not belong to any currently described species. Cell-wall-binding domains of Listeria monocytogenes bacteriophage endolysins were able to attach to the isolates, confirming their tight relatedness to the genus Listeria . Although PCR targeting the central portion of the flagellin gene flaA was positive, motility was not observed. The four isolates could not be discriminated by Fourier transform infrared spectroscopy or pulsed-field gel electrophoresis. This suggests that they represent a single species, which seems to be adapted to the environment in a cheese-ripening cellar as it was re-isolated from the same type of Swiss cheese after more than 5 years. Conjugation experiments demonstrated that the isolates harbour a transferable resistance to clindamycin. The isolates did not exhibit haemolysis or show any indication of human pathogenicity or virulence. The four isolates are affiliated with the genus Listeria but can be differentiated from all described members of the genus Listeria and therefore they merit being classified as representatives of a novel species, for which we propose the name Listeria fleischmannii sp. nov.; the type strain is LU2006-1T ( = DSM 24998T = LMG 26584T).
To determine functional subcellular loci of p53, a cellular protein associated with cellular transformation, we analyzed the nucleoplasmic, chromatin, and nuclear matrix fractions from normal mouse 3T3 cells, from methylcholanthren-transformed mouse (MethA) cells, and from various simian virus 40 (SV40)-transformed cells for the presence of p53. In 3T3 and MethA cells, p53 was present in all nuclear subfractions, suggesting an association of p53 with different structural components of the nucleus. In 3T3 cells, p53 was rapidly turned over, whereas in MethA cells, p53 was metabolically stable. In SV40-transformed cells, p53 complexed to large tumor antigen (large T) was found in the nucleoplasmic and nuclear matrix fractions, as described previously (M. Staufenbiel and W. Deppert, Cell 33:173-181, 1983). In addition, however, metabolically stable p53 not complexed to large T (free p53) was also found in the chromatin and nuclear matrix fractions of these cells. This free p53 did not arise by dissocation of large T-p53 complexes, suggesting that stabilization of p53 in SV40-transformed cells can also occur by means other than formation of a complex with large T. p53 is a cellular protein which is associated with cellular transformation in a variety of systems (for reviews, see references 3, 18, and 26). In normal cells, the closely restricted expression of p53 during cell proliferation strongly suggests an important role for p53 in the regulation of this process, especially in controlling initiation of cellular DNA synthesis (6,(14)(15)(16)(17)24). In these cells, p53 exhibits a very short half-life (5 to 20 min, depending on the cell system analyzed) and is present in very low quantities (for reviews, see references 3, 18, and 26). Many transformed cells, in contrast, express a p53 with a strongly increased half-life which is present in grossly elevated levels (for reviews, see references 3, 18, and 26). Thus, it seems likely that expression of elevated levels of p53 or metabolic stabilization of this protein or both are causally related to the process of transformation (for reviews, see references 3, 18, and 26).So far, no distinct biochemical activity has been attributed to p53. Thus, a likely mode of p53 action in both normal and transformed cells is a regulatory interaction with cellular processes leading to cell proliferation. Because these complex processes require the participation of various structural systems of the cell, it may be assumed that p53 associates, at least temporarily, with various structural systems of the cell involved in cell proliferation. We have previously described a method which allows the analysis of various nuclear subfractions for the presence of regulatory proteins (30). Application of this method to determine the subnuclear distribution of the transforming protein of simian virus 40 (SV40), the SV40 large tumor antigen (large T), led to the identification and characterization of three distinct nuclear subclasses of large T: large T in the nucleoplasm, large T at the cellular chr...
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