A temperature-sensitive lethal mutant of Staphylococcus aureus was found to harbor a mutation in the uncharacterized two-component histidine kinase (HK)-response regulator (RR) pair encoded by yycFG; orthologues of yycFG could be identified in the genomes of Bacillus subtilis and other gram-positive bacteria. Sequence analysis of the mutant revealed a point mutation resulting in a nonconservative change (Glu to Lys) in the regulator domain of the RR at position 63. To confirm that this signal transduction system was essential, a disrupted copy of either the RR (yycF) or the HK (yycG) was constructed with a set of suicide vectors and used to generate tandem duplications in the chromosome. Resolution of the duplications, leaving an insertion in either the yycF or the yycG coding region, was achieved only in the presence of an additional wild-type copy of the two open reading frames. Phenotypic characterization of the conditional lethal mutant showed that at permissive growth conditions, the mutant was hypersusceptible to macrolide and lincosamide antibiotics, even in the presence of the ermB resistance determinant. Other mutant phenotypes, including hypersensitivity to unsaturated long-chain fatty acids and suppression of the conditional lethal phenotype by high sucrose and NaCl concentrations, suggest that the role of the two-component system includes the proper regulation of bacterial cell wall or membrane composition. The effects of this point mutation are strongly bactericidal at the nonpermissive temperature, indicating that this pathway provides an excellent target for the identification of novel antibiotics.
We isolated mutations that reduce plasmid stability in dividing cell populations and mapped these mutations to a previously undescribed gene, recD, that affects recombination frequency and consequently the formation of plasmid concatemers. Insertions of the transposable element TnlO into recD resulted in increased concatemerization and loss of pSC101 and ColEl-like replicons during nonselective growth. Both concatemer formation and plasmid instability in recD mutants require a functional recA gene. Mutations in recD are recessive to recD+ and map to a small region of the Escherichia coi chromosome located between recB and argA. Although the recD locus is distinct from loci encoding the two previously identified subunits of the RecBC enzyme, mutations in recD appear to affect the exonuclease activity of this enzyme.The maintenance of plasmids as extrachromosomal elements in bacterial cells is dependent on a number of complex processes. Of primary importance is the requirement for plasmid replication, which commonly involves at least some host-encoded replication functions (see Scott [39] for a review). Replication of the pSC101 plasmid (7) requires the Escherichia coli dnaA gene product (21). Mutations in other genes involved in chromosomal replication, including dnaB, dnaC, and dnaG (14,22), also affect replication of this plasmid. Stable maintenance of pSC101 in growing cell populations also requires a plasmid locus (named par for partitioning) that is involved in the distribution of plasmid molecules to daughter cells at the time of cell division (29,45). Earlier work has shown that the pSC101 par region does not encode a protein but instead includes partition-related segments (30) that appear to be necessary for plasmids in the intracellular pool to be counted and partitioned as individual molecules (45). To better understand the mechanism by which pSC101 segregates during cell division, we undertook to identify and characterize E. coli genes encoding products involved in the plasmid maintenance (Pma) phenotype.We report here the isolation and characterization of mutations that affect the stable maintenance of pSC101, as well as that of certain other plasmids. We present evidence that these mutations, which can alter plasmid stability by increasing the frequency of multimer formation and are located in a previously unidentified E. coli gene, affect the activity of exonuclease V (ExoV). MATERIALS AND METHODSStrains, media, and general methodology. Relevant bacterial genotypes, plasmids, and phages are listed in Table 1. The media used for these studies have been previously described (31). Minimal medium was M9 or M63 supplemented with 0.2% glucose (or another carbon source), 1 ,ug of thiamine per ml, and any required L-amino acids (Sigma Chemical Co.) at 40 ,ug/ml. Solid media contained 1.5% agar (Difco Laboratories) or 0.7% agar for soft agar overlays. Lactose indicator plates contained 40 ,ug of X-Gal (5-bromo-4-chloro-3-indolyl-,-D-galactopyranoside; Boehringer Mannheim) per ml in minimal medium containing...
This study evaluated the in vitro activity of ceftaroline, a novel cephalosporin with broad-spectrum activity against gram-negative and -positive pathogens, against 4,151 recent clinical isolates collected in the United States. Ceftaroline was very potent against bacteria found in community-and hospital-acquired infections, including methicillin-resistant Staphylococcus aureus, multidrug-resistant Streptococcus pneumoniae, and common Enterobacteriaceae spp.
Increased ceftaroline MICs were associated with decreased PBP2a binding affinity and reflected alterations in PBP2a.
Ceftaroline fosamil is a novel cephalosporin with broad-spectrum activity against Gram-positive pathogens, including methicillin-resistant Staphylococcus aureus (MRSA) and multidrug-resistant Streptococcus pneumoniae, and common Gram-negative organisms. The activity of ceftaroline against MRSA is attributed to its ability to bind to penicillin-binding protein (PBP) 2a with high affinity and inhibit the biochemical activity of PBP 2a more efficiently than other presently available β-lactams. The activity of ceftaroline against MRSA and the β-haemolytic streptococci makes it an attractive monotherapy agent for the treatment of complicated skin and skin structure infections (cSSSIs). Recent profiling and surveillance studies have shown that ceftaroline is active against contemporary skin pathogens collected from US and European medical centres in 2008. The mean free drug %T > MIC (percentage of time the drug concentration remains above the MIC) needed for stasis ranged from 26% for S. aureus to 39% for S. pneumoniae in the murine thigh infection model. Pharmacokinetic and pharmacodynamic target attainment predictions for 600 mg of ceftaroline fosamil every 12 h showed that the mean %T > MICs for which plasma free-drug concentrations exceeded an MIC of 1 and 2 mg/L were 71% and 51% of the dosing interval, respectively. For a 40% T > MIC target, the predicted attainments for infections due to pathogens for which ceftaroline MICs were 1 or 2 mg/L were 100% and 90%, respectively. Clinical and microbiological successes of ceftaroline fosamil in treating cSSSIs were demonstrated in two Phase III clinical studies, in which 96.8% of all baseline cSSSI isolates from the microbiologically evaluable population were inhibited by ceftaroline at ≤ 2 mg/L. Ceftaroline fosamil is a promising broad-spectrum agent for the treatment of cSSSIs.
SummaryLow-copy number plasmids of bacteria rely on specific centromeres for regular partition into daughter cells. When also present on a second plasmid, the centromere can render the two plasmids incompatible, disrupting partition and causing plasmid loss. We have investigated the basis of incompatibility exerted by the F plasmid centromere, sopC , to probe the mechanism of partition. Measurements of the effects of sopC at various gene dosages on destabilization of mini-F, on repression of the sopAB operon and on occupancy of mini-F DNA by the centromere-binding protein, SopB, revealed that among mechanisms previously proposed, no single one fully explained incompatibility. sopC on multicopy plasmids depleted SopB by titration and by contributing to repression. The resulting SopB deficit is proposed to delay partition complex formation and facilitate pairing between mini-F and the centromere vector, thereby increasing randomization of segregation. Unexpectedly, sopC on mini-P1 exerted strong incompatibility if the P1 parABS locus was absent. A mutation preventing the P1 replication initiation protein from pairing (handcuffing) reduced this strong incompatibility to the level expected for random segregation. The results indicate the importance of kinetic considerations and suggest that mini-F handcuffing promotes pairing of SopB-sopC complexes that can subsequently segregate as intact aggregates.
A Staphylococcus aureus surveillance program was initiated in the United States to examine the in vitro activity of ceftaroline and epidemiologic trends. Susceptibility testing by Clinical and Laboratory Standards Institute broth microdilution was performed on 4,210 clinically significant isolates collected in 2009 from 43 medical centers. All isolates were screened for mecA by PCR and evaluated by pulsed-field gel electrophoresis. Methicillin-resistant S. aureus (MRSA) were analyzed for Panton-Valentine leukocidin (PVL) genes and the staphylococcal cassette chromosome mec (SCCmec) type. All isolates had ceftaroline MICs of <2 g/ml with an MIC 50 of 0.5 and an MIC 90 of 1 g/ml. The overall resistance rates, expressed as the percentages of isolates that were intermediate and resistant (or nonsusceptible), were as follows: ceftaroline, 1.0%; clindamycin, 30.2% (17.4% MIC > 4 g/ml; 12.8% inducible); daptomycin, 0.2%; erythromycin, 65.5%; levofloxacin, 39.9%; linezolid, 0.02%; oxacillin, 53.4%; tetracycline, 4.4%; tigecycline, 0%; trimethoprim-sulfamethoxazole, 1.6%; vancomycin, 0%; and high-level mupirocin, 2.2%. The mecA PCR was positive for 53.4% of the isolates. The ceftaroline MIC 90 s were 0.25 g/ml for methicillin-susceptible S. aureus and 1 g/ml for MRSA. Among the 2,247 MRSA isolates, 51% were USA300 (96.9% PVL positive, 99.7% SCCmec type IV) and 17% were USA100 (93.4% SCCmec type II). The resistance rates for the 1,137 USA300 MRSA isolates were as follows: erythromycin, 90.9%; levofloxacin, 49.1%; clindamycin, 7.6% (6.2% MIC > 4 g/ml; 1.4% inducible); tetracycline, 3.3%; trimethoprim-sulfamethoxazole, 0.8%; high-level mupirocin, 2.7%; daptomycin, 0.4%; and ceftaroline and linezolid, 0%. USA300 is the dominant clone causing MRSA infections in the United States. Ceftaroline demonstrated potent in vitro activity against recent S. aureus clinical isolates, including MRSA, daptomycinnonsusceptible, and linezolid-resistant strains.
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