Project description:?Ef11, a temperate Siphoviridae bacteriophage, was isolated by induction from a root canal isolate of Enterococcus faecalis. Sequence analysis suggested that the ?Ef11 genome included a contiguous 8 gene module whose function was related to head structure assembly and another module of 10 contiguous genes whose products were responsible for tail structure assembly. SDS-PAGE analysis of virions of a ?Ef11 derivative revealed 11 well-resolved protein bands. To unify the deduced functional gene assignments emanating from the DNA sequence data, with the structural protein analysis of the purified virus, 6 of the SDS-PAGE bands were subjected to mass spectrometry analysis. 5 of the 6 protein bands analyzed by mass spectrometry displayed identical amino acid sequences to those predicted to be specified by 4 of the ORFs identified in the ?Ef11 genome. These included: ORF8 (predicted scaffold protein), ORF10 (predicted major head protein), ORF15 (predicted major tail protein), and ORF23 (presumptive antireceptor).

Project description:Penicillin binding protein 4 (PBP4) can provide high-level ?-lactam resistance in Staphylococcus aureus A series of missense and promoter mutations associated with pbp4 were detected in strains that displayed high-level resistance. We show here that the missense mutations facilitate the ?-lactam resistance mediated by PBP4 and the promoter mutations lead to overexpression of pbp4 Our results also suggest a cooperative interplay among PBPs for ?-lactam resistance.

Project description:Background:PBP4 is typically considered unimportant for conferring high-level ?-lactam resistance in Staphylococcus aureus. Mutations in PBP4 have been associated with ?-lactam non-susceptibility among natural strains of S. aureus. We have previously shown that PBP4 can mediate high-level ?-lactam resistance in laboratory-generated strains passaged in ?-lactam antibiotics. Mutations in the pbp4 promoter that up-regulate its expression and missense mutations that surround PBP4's active site were detected in high frequencies among passaged strains, suggesting PBP4 plays a key role in resistance. How these mutations participate in PBP4's ability to provide high-level ?-lactam resistance is unknown. Objectives:To determine whether enzymatic activity of PBP4 is required for high-level ?-lactam resistance and to investigate how the pbp4-associated mutations provide ?-lactam resistance. Methods:The catalytic activity of PBP4 was disabled through introduction of a serine to alanine point mutation in its active site (Ser-75?Ala) in a representative and well-studied passaged strain, CRB. pbp4 promoter and missense mutations detected in CRB were reconstituted in a WT strain individually and in combination. ?-Lactam resistance of the resultant strains was evaluated by population analysis. Bacterial peptidoglycan composition of the pbp4 mutants was evaluated with and without antibiotic treatment using LC. Results:PBP4 inactivation imparted complete ?-lactam susceptibility of CRB. Reconstitution of PBP4 missense mutations alone did not impart ?-lactam resistance, but did so in synergism with pbp4 promoter mutation. A similar synergistic interaction of pbp4 mutations was observed in enhanced peptidoglycan cross-linking upon antibiotic treatment. Conclusions:PBP4's activity and overexpression both contribute to high-level ?-lactam resistance.

Project description:E. faecalis, wildtype, rpoN deletion mutant and rpoN complement strains were grown in colony biofilms on a defined medium with glucose. Gene expression differences were recorded.

Project description:Enterococcus faecalis is a commensal bacterium in the gastrointestinal tract (GIT) of humans and other organisms. Outside of the GIT, E. faecalis can cause infections in root canals, wounds, surgical sites, the urinary tract, and on heart valves. Many of these infections can be polymicrobial, and a variety of toxins and nutritional signals influence interactions between E. faecalis and other microbes. Like other bacteria, E. faecalis metabolizes arginine through the arginine deiminase (ADI) pathway, which converts arginine to ornithine and releases ATP, ammonia, and CO2. E. faecalis arginine metabolism also affects virulence of other pathogens, such as Clostridioides difficile and Escherichia coli, during co-culture. E. faecalis may encounter elevated levels of arginine in the GIT or the oral cavity, where arginine is used as an additive in dental therapeutics to disrupt plaque formation and biofilm growth by oral streptococci. However, little is known about how E. faecalis responds to growth in arginine. To address this gap, we used RNAseq and additional in vitro assays to measure changes in growth, gene expression, and biofilm formation in arginine relative to control conditions. Here, we demonstrate that arginine decreases E. faecalis biofilm production and causes widespread differential expression of genes related to metabolism, nutrient transport, quorum sensing, and polysaccharide synthesis. Growth in arginine also increases aggregation of E. faecalis cultures and promotes decreased susceptibility to the antibiotics ampicillin and ceftriaxone. Together, this shows that E. faecalis undergoes global transcriptional changes during growth in arginine and provides a platform for better understanding of how the presence of arginine in the niches colonized by E. faecalis affects the physiology of this organism in addition to the virulence of surrounding microbes.

Project description:We assessed the ability of gene transfer to reverse vancomycin resistance in class A (VanA) glycopeptide-resistant Enterococcus faecalis. Recombinant shuttle vectors containing a vanH promoter-vanA antisense gene cassette fully restored vancomycin susceptibility through a combined transcriptional activator binding domain decoy and inducible vanA antisense RNA effect.

Project description:BACKGROUND: Iron-sulfur clusters are ubiquitous and evolutionarily ancient inorganic prosthetic groups, the biosynthesis of which depends on complex protein machineries. Three distinct assembly systems involved in the maturation of cellular Fe-S proteins have been determined, designated the NIF, ISC and SUF systems. Although well described in several organisms, these machineries are poorly understood in Gram-positive bacteria. Within the Firmicutes phylum, the Enterococcus spp. genus have recently assumed importance in clinical microbiology being considered as emerging pathogens for humans, wherein Enterococcus faecalis represents the major species associated with nosocomial infections. The aim of this study was to carry out a phylogenetic analysis in Enterococcus faecalis V583 and a structural and conformational characterisation of it SufU protein. RESULTS: BLAST searches of the Enterococcus genome revealed a series of genes with sequence similarity to the Escherichia coli SUF machinery of [Fe-S] cluster biosynthesis, namely sufB, sufC, sufD and SufS. In addition, the E. coli IscU ortholog SufU was found to be the scaffold protein of Enterococcus spp., containing all features considered essential for its biological activity, including conserved amino acid residues involved in substrate and/or co-factor binding (Cys50,76,138 and Asp52) and, phylogenetic analyses showed a close relationship with orthologues from other Gram-positive bacteria. Molecular dynamics for structural determinations and molecular modeling using E. faecalis SufU primary sequence protein over the PDB:1su0 crystallographic model from Streptococcus pyogenes were carried out with a subsequent 50 ns molecular dynamic trajectory. This presented a stable model, showing secondary structure modifications near the active site and conserved cysteine residues. Molecular modeling using Haemophilus influenzae IscU primary sequence over the PDB:1su0 crystal followed by a MD trajectory was performed to analyse differences in the C-terminus region of Gram-positive SufU and Gram-negative orthologous proteins, in which several modifications in secondary structure were observed. CONCLUSION: The data describe the identification of the SUF machinery for [Fe-S] cluster biosynthesis present in the Firmicutes genome, showing conserved sufB, sufC, sufD and sufS genes and the presence of the sufU gene coding for scaffold protein, instead of sufA; neither sufE nor sufR are present. Primary sequences and structural analysis of the SufU protein demonstrated its structural-like pattern to the scaffold protein IscU nearby on the ISC machinery. E. faecalis SufU molecular modeling showed high flexibility over the active site regions, and demonstrated the existence of a specific region in Firmicutes denoting the Gram positive region (GPR), suggested as a possible candidate for interaction with other factors and/or regulators.

Project description:BackgroundPBP4, a low-molecular-weight PBP in Staphylococcus aureus, is not considered to be a classical mediator of β-lactam resistance. Previous studies carried out by our group with laboratory strains of S. aureus demonstrated the ability of PBP4 to produce β-lactam resistance through mutations associated with the pbp4 promoter and/or gene. Recent studies of β-lactam-resistant clinical isolates of S. aureus have reported similar mutations associated with pbp4.ObjectivesTo determine if pbp4-associated mutations reported among clinical strains of S. aureus mediate β-lactam resistance.MethodsThe pbp4 promoters and genes bearing mutations from clinical isolates were cloned into a heterologous host. Reporter, growth and Bocillin assays were performed to assess their role in β-lactam resistance. X-ray crystallography was used to obtain acyl-enzyme intermediate structures of the WT and mutant PBP4 with nafcillin and cefoxitin.ResultsOf the five strains that contained pbp4 promoter mutations, three strains exhibited enhanced expression of PBP4. The R200L mutation in pbp4 resulted in increased survival in the presence of the β-lactams nafcillin and cefoxitin. Further, introduction of either a promoter or a gene mutation into the genome of a WT host increased the ability of the strains to resist the action of β-lactams. The four high-resolution X-ray structures presented demonstrate the binding pose of the β-lactams tested and provide hints for further drug development.ConclusionsMutations associated with the pbp4 promoter and pbp4 gene altered protein activity and mediated β-lactam resistance among the clinically isolated strains that were studied.

Project description:A global transcriptional regulatory network was generated in the pathogenic bacterium Enterococcus faecalis in order to understand how this organism can activate and coordinate its expression at different copper concentrations. The topological evaluation of the network showed common patterns described in other organisms. Integrating microarray experiments allowed the identification of two sub-networks activated at low (0.05 mM CuSO4) and high (0.5 mM CuSO4) concentrations of copper. The analysis indicates the presence of specific functionally activated modules induced by copper levels, highlighting the regulons LysR and ArgR as global regulators and CopY, Fur and LexA as local regulators. Taking advantage of the fact that E. faecalis presented a homeostatic module, we produced an in vivo intervention by removing this system from the cell without affecting the connectivity of the global transcriptional network. This strategy led us to find that this bacterium can reconfigure its gene expression to maintain cellular homeostasis, activating new modules principally related to glucose metabolism and transcriptional processes. Finally, these results position E. faecalis as the most complete and controllable systemic model organism for copper homeostasis available to date.

Project description:Ethanolamine, a product of the breakdown of phosphatidylethanolamine from cell membranes, is abundant in the human intestinal tract and in processed foods. Effective utilization of ethanolamine as a carbon and nitrogen source may provide a survival advantage to bacteria that inhabit the gastrointestinal tract and may influence the virulence of pathogens. In this work, we describe a unique series of posttranscriptional regulatory strategies that influence expression of ethanolamine utilization genes (eut) in Enterococcus, Clostridium, and Listeria species. One of these mechanisms requires an unusual 2-component regulatory system. Regulation involves specific sensing of ethanolamine by a sensor histidine kinase (EutW), resulting in autophosphorylation and subsequent phosphoryl transfer to a response regulator (EutV) containing a RNA-binding domain. Our data suggests that EutV is likely to affect downstream gene expression by interacting with conserved transcription termination signals located within the eut locus. Breakdown of ethanolamine requires adenosylcobalamin (AdoCbl) as a cofactor, and, intriguingly, we also identify an intercistronic AdoCbl riboswitch that has a predicted structure different from previously established AdoCbl riboswitches. We demonstrate that association of AdoCbl to this riboswitch prevents formation of an intrinsic transcription terminator element located within the intercistronic region. Together, these results suggest an intricate and carefully coordinated interplay of multiple regulatory strategies for control of ethanolamine utilization genes. Gene expression appears to be directed by overlapping posttranscriptional regulatory mechanisms, each responding to a particular metabolic signal, conceptually akin to regulation by multiple DNA-binding transcription factors.