Genome-wide transcriptional analysis of the phosphate starvation stimulon of Bacillus subtilis

Bacillus subtilis responds to phosphate starvation stress by inducing the PhoP and SigB regulons. While the PhoP regulon provides a specific response to phosphate starvation stress, maximizing the acquisition of phosphate (P(i)) from the environment and reducing the cellular requirement for this essential nutrient, the SigB regulon provides nonspecific resistance to stress by protecting essential cellular components, such as DNA and membranes. We have characterized the phosphate starvation stress response of B. subtilis at a genome-wide level using DNA macroarrays. A combination of outlier and cluster analyses identified putative new members of the PhoP regulon, namely, yfkN (2',3' cyclic nucleotide 2'-phosphodiesterase), yurI (RNase), yjdB (unknown), and vpr (extracellular serine protease). YurI is thought to be responsible for the nonspecific degradation of RNA, while the activity of YfkN on various nucleotide phosphates suggests that it could act on substrates liberated by YurI, which produces 3' or 5' phosphoribonucleotides. The putative new PhoP regulon members are either known or predicted to be secreted and are likely to be important for the recovery of inorganic phosphate from a variety of organic sources of phosphate in the environment.     

Functional analysis of the Bacillus subtilis Zur regulon

The Bacillus subtilis zinc uptake repressor (Zur) regulates genes involved in zinc uptake. We have used DNA microarrays to identify genes that are derepressed in a zur mutant. In addition to members of the two previously identified Zur-regulated operons (yciC and ycdHI-yceA), we identified two other genes, yciA and yciB, as targets of Zur regulation. Electrophoretic mobility shift experiments demonstrated that all three operons are direct targets of Zur regulation. Zur binds to an approximately 28-bp operator upstream of the yciA gene, as judged by DNase I footprinting, and similar operator sites are found preceding each of the previously described target operons, yciC and ycdHI-yceA. Analysis of a yciA-lacZ fusion indicates that this operon is induced under zinc starvation conditions and derepressed in the zur mutant. Phenotypic analyses suggest that the YciA, YciB, and YciC proteins may function as part of the same Zn(II) transport pathway. Mutation of yciA or yciC, singly or in combination, had little effect on growth of the wild-type strain but significantly impaired the growth of the ycdH mutant under conditions of zinc limitation. Since the YciA, YciB, and YciC proteins are not obviously related to any known transporter family, they may define a new class of metal ion uptake system. Mutant strains lacking all three identified zinc uptake systems (yciABC, ycdHI-yceA, and zosA) are dependent on micromolar levels of added zinc for optimal growth.     

Organization and function of the YsiA regulon of Bacillus subtilis involved in fatty acid degradation

The organization and function of the Bacillus subtilis YsiA regulon involved in fatty acid degradation were investigated. Northern and primer extension analyses indicated that this regulon comprises five operons, i.e. lcfA-ysiA-B-etfB-A, ykuF-G, yhfL, yusM-L-K-J, and ywjF-acdA-rpoE. YusJ and AcdA, YsiB and YusL, and YusK presumably encode acyl-CoA dehydrogenases, 3-hydroxyl-CoA dehydrogenase/enoyl-CoA hydratase complexes, and acetyl-CoA C-acyltransferase, respectively, which are directly involved in the fatty acid beta-oxidation cycle. In addition, LcfA and YhfL are likely to encode long chain acyl-CoA ligases. On gel retardation and footprinting analyses involving the purified YsiA protein, we identified cis-sequences for YsiA binding (YsiA boxes) in the promoter regions upstream of ysiA, ykuF, yusL, yhfL, and ywjF, the equilibrium dissociation constants (K(d)) for YsiA binding being 20, 21, 37, 43, and 65 nm, respectively. YsiA binding was specifically inhibited by long chain acyl-CoAs with 14-20 carbon atoms, acyl-CoAs with 18 carbon atoms being more effective; out of long chain acyl-CoAs tested, monounsaturated oleoyl-CoA, and branched chain 12-metyltetradecanoyl-CoA were most effective. These in vitro findings were supported by the in vivo observation that the knock-out of acyl-CoA dehydrogenation through yusJ, etfA, or etfB disruption resulted in YsiA inactivation, probably because of the accumulation of long chain acyl-CoAs in the cells. Furthermore, the disruption of yusL, yusK, yusJ, etfA, etfB, or ykuG affected the utilization of palmitic acid, a representative long chain fatty acid. Based on this work, ysiA, ysiB, ykuF, ykuG, yhfL, yusM, yusL, yusK, yusJ, and ywjF can be renamed fadR, fadB, fadH, fadG, lcfB, fadM, fadN, fadA, fadE, and fadF.     

AbrB is a regulator of the sigma(W) regulon in Bacillus subtilis

The Bacillus subtilis global regulator AbrB was found to negatively control expression of sigW and genes of the sigma(W) regulon. AbrB bound to DNA regions in the autoregulatory sigW promoter and to some, but not all, of the other sigma(W)-dependent promoters in B. subtilis. Defects in antibiotic resistance properties caused by spo0A mutations are at least partially correlated with AbrB repression of the sigma(W) regulon.