The methicillin resistance factor encoded by fmtA is a core member of the Staphylococcus aureus cell wall stimulon, but its function has remained elusive for the past two decades. First identified as a factor that affects methicillin resistance in S. aureus strains, FmtA was later shown to interact with teichoic acids and to localize to the cell division septum. We have made a breakthrough in understanding FmtA function. We show that FmtA hydrolyzes the ester bond between d-Ala and the backbone of teichoic acids, which are polyglycerol-phosphate or polyribitol-phosphate polymers found in the S. aureus cell envelope. FmtA contains two conserved motifs found in serine active-site penicillin-binding proteins (PBPs) and β-lactamases. The conserved SXXK motif was found to be important for the d-amino esterase activity of FmtA. Moreover, we show that deletion of fmtA (ΔfmtA) led to higher levels of d-Ala in teichoic acids, and this effect was reversed by complementation of ΔfmtA with fmtA. The positive charge on d-Ala partially masks the negative charge of the polyol-phosphate backbone of teichoic acids; hence, a change in the d-Ala content will result in modulation of their charge. Cell division, biofilm formation, autolysis, and colonization are among the many processes in S. aureus affected by the d-Ala content and overall charge of the cell surface teichoic acids. The esterase activity of FmtA and the regulation of fmtA suggest that FmtA functions as a modulator of teichoic acid charge, thus FmtA may be involved in S. aureus cell division, biofilm formation, autolysis, and colonization.
In Staphylococcus aureus the VraSR two-component system acts as a sentinel that can rapidly sense cell wall peptidoglycan damage and coordinate a response to enhance the resistance phenotype. VraR is a transcription factor and its cognate kinase, VraS, modulates the DNA-binding activity of VraR by regulating its phosphorylation state and hence its dimerization state. Here we provide the first report on the VraR transcriptional activity by investigating the interaction with the vraSR operon control region. We found that this region contains three VraR-binding sites, each with unique VraR-binding features. VraR binding to the most conserved site is phosphorylation independent, and dimerization is proposed to be induced through binding to DNA. By contrast, binding to the less conserved site requires phosphorylation of VraR. This site overlaps with the binding site of the sigma subunit of the RNA polymerase complex, suggesting that VraR could be interacting with the transcription machinery in the presence of the cell wall stress signal. Mutagenesis studies on the VraR binding sites suggest that there is directionality in the binding of VraR to the target DNA, probably dictated by VraR dimerization. We also constructed a P(vraSR)-fused lux operon reporter vector to investigate in vivo the significance of our in vitro studies. These studies show that upon cell wall stress, induced by oxacillin, the expression level of the lux operon goes up and it is affected by the integrity of the two identified VraR-binding sites in agreement with the in vitro studies. Further, they demonstrate that the VraR most conserved binding site is essential to the vraSR operon expression. On the other hand, they suggest that the role of the VraR less conserved site could be that of mediating high levels of vraSR operon expression during cell wall stress conditions.
Background: OXA-58 is a carbapenem-hydrolyzing class D -lactamase (CHDL) found in Acinetobacter baumannii. Results: OXA-58 exploits a carbamylated lysine in its catalysis. The deacylating water molecule comes from the ␣-face. Conclusion: CHDLs employ the same hydrolytic machinery as oxacillinases. Structural changes in the active site may lead to imipenem hydrolysis. Significance: This study provides insights for the design of CHDL inactivators.
Virus-induced gene silencing (VIGS) is a method of rapid and transient gene silencing in plants using viral vectors. A VIGS vector for gene silencing in rice has been developed from Rice tungro bacilliform virus (RTBV), a rice-infecting virus containing DNA as the genetic material. A full-length RTBV DNA cloned as a partial dimer in a binary plasmid accumulated in rice plants when inoculated through Agrobacterium (agroinoculation) within 2 weeks and produced detectable levels of RTBV coat protein. Deletion of two of the four viral ORFs did not compromise the ability of the cloned RTBV DNA to accumulate in rice plants. To modify the cloned RTBV DNA as a VIGS vector (pRTBV-MVIGS), the tissue-specific RTBV promoter was replaced by the constitutively expressed maize ubiquitin promoter, sequences comprising the tRNA-binding site were incorporated to ensure reverse transcription-mediated replication, sequences to ensure optimal context for translation initiation of the viral genes were added and a multi-cloning site for the ease of cloning DNA fragments was included. The silencing ability of pRTBV-MVIGS was tested using the rice phytoene desaturase (pds) gene on rice. More than half of the agroinoculated rice plants showed white streaks in leaves within 21 days post-inoculation (dpi), which continued to appear in all emerging leaves till approximately 60-70 dpi. Compared to control samples, real-time PCR showed only 10-40% accumulation of pds transcripts in the leaves showing the streaks. This is the first report of the construction of a VIGS vector for rice which can be introduced by agroinoculation.
Cell wall damage in Staphylococcus aureus induces a rapid genome-wide response, referred to as the cell wall stress stimulon. This response is mediated by a two-component system, the vancomycin resistance-associated sensor/regulator (VraSR). The response regulator protein VraR is a transcription factor. Here, we demonstrate that two VraR binding sites in the vraSR operon control region are involved in the regulation of the vraSR operon. The sites are centered at the ؊60 and ؊35 nucleotide positions and are referred to as R1 and R2, respectively. DNase I footprinting and lux operon reporter vector studies showed that both of these sites communicate intimately with each other to fine-tune the activity of the vraSR operon. Mutagenesis of the VraR binding sites showed that dimerization of unphosphorylated VraR at R1 is driven by a hierarchy in VraR binding and by the proximity of the two tandem VraR binding sequences at this site. On the other hand, these studies show that the lack of sequence conservation and the distance between the VraR binding sequences in R2 ensure that VraR is recruited to this site only when phosphorylated (hence, under stress conditions). Furthermore, we demonstrate that sigma A (SigA) factor is involved in the regulation of the vraSR operon. Our study shows that sigma A factor does not bind to the vraSR operon control region in the absence of VraR, suggesting that VraR may interact directly with this factor.
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