We thank Teiko Yamada for technical assistance with NMR spectroscopy, Kazuhiko AC220 supplier Saeki for providing cosmid clones from the ordered M. loti genomic library, and Makoto Hayashi for valuable advice on
rhizobial infection processes. This work was supported in part by a Grant-in-Aid for Scientific Research (no. 19580077) to H.M. from the Japan Society for the Promotion of Science. “
“Streptococcus mutans, a major etiological agent of dental caries, is resistant to bacitracin. Microarray analysis revealed that mbrA and mbrB, encoding a putative ATP-binding cassette transporter, are prominently induced in the presence of bacitracin. On the basis of the latest report that MbrC, a putative response regulator in a two-component signaling system, binds the promoter region of mbrA and thus regulates its transcription, we cut into the mechanism by generating a mutant MbrC (D54N-MbrC) that www.selleckchem.com/products/Lapatinib-Ditosylate.html substituted asparagine for aspartate at position 54, the predicted phosphorylation site. MbrC, but not the mutant D54N-MbrC, showed affinity for a DNA probe that contained
the hypothetical mbrA promoter sequence. Furthermore, we introduced a point mutation (D54N-MbrC) into UA159; this mutant strain exhibited neither mbrA induction nor resistance in the presence of bacitracin. These data suggest that the aspartate residue at position 54 of MbrC is a promising candidate for phosphorylation in a bacitracin-sensing system and indispensable for S. mutans bacitracin resistance. Bacitracin is produced by Bacillus spp. and is known to bind tightly to the C55-isoprenyl pyrophosphate (IPP), thus preventing its interaction with a membrane-bound pyrophosphatase. During peptidoglycan synthesis, IPP is detached and dephosphorylated to C55-isoprenyl phosphate (IP) by the pyrophosphatase after the translocation of sugar–peptide units to the ends of peptidoglycan strands. In this way, IP is recycled for subsequent peptidoglycan synthesis (Siewert
& Strominger, 1967). However, the inhibition of pyrophosphatase activity by bacitracin results in a reduction in the amount of available IP. That is, the inhibition of peptidoglycan synthesis is thought to be the primary mechanism of action of bacitracin (Storm, 1974). Several possible mechanisms of bacitracin resistance 5-Fluoracil have been reported. IPP phosphatase is encoded by bacA in Escherichia coli and bcrC in Bacillus subtillis (El Ghachi et al., 2004; Bernard et al., 2005). Elevated levels of BacA or BcrC can outcompete bacitracin for phosphatase activity and thus restore the IP supply. The second is reduced IP utilization due to a lack of membrane-derived oligosaccharides, reported in an E. coli mutant (Fiedler & Rotering, 1988). The third mechanism is the shutting down of the synthesis of exopolysaccharides for which IP is required in certain Gram-negative bacteria (Pollock et al., 1994).