Two ResD-controlled promoters regulate ctaA expression in Bacillus subtilis.

The Bacillus subtilis ResDE two-component system plays a positive role in global regulation of genes involved in aerobic and anaerobic respiration. ctaA is one of the several genes involved in aerobic respiration that requires ResD for in vivo expression. The ctaAB-divergent promoter regulatory region has three ResD binding sites; A1, A2, and A3. The A2 site is essential for in vivo promoter activity, while binding sites A2 and A3 are required for full ctaA promoter activity. In this study, we demonstrate the role of ResD~P in the activation of the ctaA promoter using an in vitro transcription system. The results indicate that the ctaA promoter (binding sites A2 and A3) has two transcriptional start sites. Binding site A2 was sufficient for weak transcription of the upstream promoter (Pv) by Esigma(A), transcription which was enhanced approximately 1.5-fold by ResD and 5-fold by ResD~P. The downstream promoter (Ps) required both binding sites A2 and A3 and was not transcribed by Esigma(A) with or without ResD~P. RNA polymerase (RNAP) isolated from B. subtilis when cells were at the end of exponential growth (T(0)) or 3, 4, or 5 h into the stationary phase (T(3), T(4), or T( 5), respectively) was used in in vitro transcription assays. Maximal transcription from Ps required T(4) RNAP plus ResD~P. RNAP isolated from a spo0A or a sigE mutant strain was not capable of Ps transcription. Comparison of the Ps promoter sequence with the SigE binding consensus suggests that the ctaA Ps promoter may be a SigE promoter. The collective data from ResD footprinting, in vivo promoter deletion analysis, and in vitro transcription assays suggest that ctaA is transcribed during late exponential to early stationary phases of growth from the Pv promoter, which requires ResD binding site A2, Esigma(A), and ResD~P, and during later stationary phase from Ps, which requires binding sites A2 and A3, ResD~P, and Esigma(E) or a sigma factor whose transcription is dependent on SigE.

Interaction of ResD with regulatory regions of anaerobically induced genes in Bacillus subtilis.

The two-component regulatory proteins ResD and ResE are required for anaerobic nitrate respiration in Bacillus subtilis. ResD, when it undergoes ResE-dependent phosphorylation, is thought to activate transcriptionally anaerobically induced genes such as fnr, hmp and nasD. In this report, deletion analysis of the fnr, hmp and nasD promoter regions was carried out to identify cis-acting sequences required for ResDE-dependent transcription. The results suggest that the hmp and nasD promoters have multiple target sequences for ResDE-dependent regulation and that fnr has a single target site. Gel mobility shift assays and DNase I footprinting analyses were performed to determine whether ResD interacts directly with the regulatory regions of the three genes. Our results indicate that ResD specifically binds to sequences residing upstream of the hmp and nasD promoters and that phosphorylation of ResD significantly stimulates this binding. In contrast, a higher concentration of ResD is required for binding to the fnr promoter region and no stimulation of the binding by ResD phosphorylation was observed. Taken together, these results suggest that ResD activates transcription of fnr, hmp and nasD by interacting with DNA upstream of these promoters. Our results suggest that phosphorylation of ResD stimulates binding to multiple ResD binding sites, but is much less stimulatory if only a single binding site exists.

ResD signal transduction regulator of aerobic respiration in Bacillus subtilis: ctaA promoter regulation.

A two-component signal transduction system composed of a sensor kinase, ResE, and a response regulator, ResD, encoded by resD and resE genes of the res operon (resABCDE), has a regulatory role in both aerobic and anaerobic respiration. In terms of aerobic respiration, resD functions upstream of ctaA, a gene required for haem A biogenesis and hence for the synthesis of haem A-containing cytochrome terminal oxidases. Although ResD is probably a transcription factor, there was no direct evidence that ResD protein, either phosphorylated or unphosphorylated, interacts directly with regulatory regions of ResD-controlled genes. Here, we report the overexpression and purification of ResD and ResE and their role in gene activation. ResD can be phosphorylated by ResE in vitro and is a monomer in solution in either the phosphorylated or unphosphorylated state. The binding activity of ResD to the ctaA promoter was examined by gel shift assays and DNase I footprinting assays. DNase I footprinting showed both unphosphorylated and phosphorylated ResD binding to the ctaA promoter and showed that there are three binding sites (A1, A2 and A3), two (A1 and A2) upstream of the -35 promoter region and one (A3) downstream of the -10 of the promoter. The role of each site in ctaA promoter activity and ResD binding was characterized using deletion analysis, followed by the DNase I footprinting and in vivo transcription assays of promoter-lacZ fusions. Our results showed that the concentration of ResD required to bind at each site is different and that ResD binding at the A1 site is independent of the other two ResD binding sites, but that the concentration of ResD approximately P required to protect site A2 is reduced when site A3 is present. In vivo transcription assays from promoter-lacZ fusion constructs showed that DNA containing ResD-binding site A2 was essential for promoter activity and that promoter constructs containing both binding sites A2 and A3 were sufficient for full promoter activity.

Decay of activated Bacillus subtilis pho response regulator, PhoP approximately P, involves the PhoR approximately P intermediate.

PhoR of Bacillus subtilis is a histidine sensor-kinase belonging to the family of two-component signal transduction systems. PhoR is responsible for processing the phosphate-starvation signal and providing phosphate input to regulate the level of phosphorylated response regulator, PhoP, which activates/represses Pho regulon gene transcription. The catalytic domain of PhoR is sufficient for the low-phosphate inducible expression of Pho regulon genes since removing the N-terminal membrane-associated domain did not alter the kinetics of Pho induction, albeit the total level of induction was decreased (1). In this study we showed that the complete B. subtilis PhoR protein produced in Escherichia coli can be reverse phosphorylated by PhoP-phosphate. We also used a C-terminal fragment of the PhoR protein, PhoR, to demonstrate that the phosphoryl group on phospho-PhoP was transferred back to PhoR in the reverse phosphorylation reaction or released as inorganic phosphate to the reaction mixture. The reverse phosphorylation of the PhoR protein likely occurs at the same histidine residue (His360) that is utilized for the autokinase reaction by the same protein. In the presence of ADP, the phosphoryl group is further transferred to ADP to form ATP. While the autokinase reaction, the forward phosphotransfer reaction from PhoR approximately P to PhoP, and the release of inorganic phosphate from PhoP approximately P in the presence of PhoR require Mg(2+), the reverse phosphotransfer from PhoP approximately P to PhoR does not. These results indicate that the energy levels of the phosphoryl groups on PhoP and PhoR are very similar. The reversible autokinase reaction and/or the reversible phosphotransfer reaction between PhoR approximately P and PhoP may have a role in PhoP approximately P decay thus influencing the PhoP approximately P concentration in the cell.

Mutational analysis of the phoD promoter in Bacillus subtilis: implications for PhoP binding and promoter activation of Pho regulon promoters.

The PhoP-PhoR two-component regulatory system controls the phosphate deficiency response in B. subtilis. A number of Pho regulon genes which require PhoP approximately P for activation or repression have been identified. The studies reported here were initiated to understand the PhoP-DNA interaction necessary for Pho promoter regulation. The regulatory region of phoD was characterized in detail using oligo-directed mutagenesis, DNase I footprinting, and in vivo transcription assays. These data reveal basic principles of PhoP binding relevant to PhoP's interaction with other Pho regulon promoters. Our results show that: (i) a dimer of PhoP approximately P is able to bind two consensus repeats in a stable fashion; (ii) PhoP binding is highly cooperative within the core promoter region, which is located from -66 to -17 on the coding strand and contains four TT(A/T/C)ACA-like repeats; (iii) specific bases comprising the TT(A/T/C)ACA consensus are essential for transcriptional activation, but the specific base pairs of the intervening sequences separating the consensus repeats are not important for either PhoP binding or promoter activation; (iv) the spacing between two consensus repeats within a putative dimer binding site in the core region is important for both PhoP binding and promoter activation; (v) the exact spacing between two dimer binding sites within the core region is important for promoter activation but less so for PhoP binding affinity, as long as the repeats are on the same face of the helix; and (vi) the 5' secondary binding region is important for coordinated PhoP binding to the core binding region, making it nearly essential for promoter activation.

The cytoplasmic kinase domain of PhoR is sufficient for the low phosphate-inducible expression of pho regulon genes in Bacillus subtilis.

PhoP-PhoR, one of three two-component systems known to be required to regulate the pho regulon in Bacillus subtilis, directly regulates the alkaline phosphatase genes that are used as pho reporters. Biochemical studies showed that B. subtilis PhoR, purified from Escherichia coli, was autophosphorylated in vitro in the presence of ATP. Phosphorylated PhoR showed stability under basic conditions but not acidic conditions, indicating that the phosphorylation probably occurs on a conserved histidine residue. Phospho-PhoR phosphorylated its cognate response regulator, PhoP in vitro. B. subtilis phoR was placed in the Bacillus chromosome under the control of the Pspac promoter, which is IPTG inducible. The wild-type phoR, under either native promoter or Pspac promoter with IPTG induction, resulted in a similar level of alkaline phosphatase production. Under high phosphate conditions, strains containing wild-type phoR, or phoR mutant gene products that lacked either the periplasmic domain, or both N-terminal transmembrane PhoR mutant gene products that lacked either the periplasmic domain, or both N-terminal transmembrane PhoR sequences or various extended N-terminal sequences, showed no significant APase production. Under phosphate starvation conditions, in the presence of IPTG, all strains containing mutated phoR genes showed alkaline phosphatase induction patterns similar to that of the wild-type strain, although the fully induced level was lower in the mutants. The decrease in total alkaline phosphatase production in these mutant strains can be compensated completely or partially by increasing the copy number of the mutant phoR gene. These in vivo results suggest that the C-terminal kinase domain of PhoR is sufficient for the induction of alkaline phosphatase expression under phosphate-limited conditions, and that the regulation for repression of APase under phosphate-replete conditions remains intact.

PhoP-P and RNA polymerase sigmaA holoenzyme are sufficient for transcription of Pho regulon promoters in Bacillus subtilis: PhoP-P activator sites within the coding region stimulate transcription in vitro.

The Bacillus subtilis pstS operon and phoA gene are members of the Pho regulon that is controlled by PhoR, a histidine kinase, and PhoP, a response regulator. Footprinting analysis showed that phosphorylated PhoP extended the PhoP protected region in pstS and phoA promoters, and also bound to a separate site within the coding region of each gene. Our previous in vivo studies have shown that, in contrast to other Pho regulon promoters that are not expressed in either phoP or phoR mutants, a low-level induction from the pstS promoter (25% of parent strain) can be detected in a phoR mutant. In this study, by using an in vitro transcription system, we demonstrate that (i) only phosphorylated PhoP is a transcriptional activator of the pstS operon and of the phoA gene; (ii) phosphorylated PhoP and RNA polymerase sigmaA holoenzyme are sufficient for in vitro transcription of the pstS promoter and the phoA promoter; (iii) the activation of the pstS promoter requires lower concentrations of phosphorylated PhoP than does the phoA promoter for transcription; and (iv) PhoP binding sites in both the pstS promoter core binding region and in the 5' coding region of the gene, which have been identified by footprinting analysis, are important for the transcription of the pstS promoter in vitro.

Role of Pho-P in transcriptional regulation of genes involved in cell wall anionic polymer biosynthesis in Bacillus subtilis.

tagA, tagD, and tuaA operons are responsible for the synthesis of cell wall anionic polymer, teichoic acid, and teichuronic acid, respectively, in Bacillus subtilis. Under phosphate starvation conditions, teichuronic acid is synthesized while teichoic acid synthesis is inhibited. Expression of these genes is controlled by PhoP-PhoR, a two-component system. It has been proposed that Pho-P plays a key role in the activation of tuaA and the repression of tagA and tagD. In this study, we demonstrated the role of Pho-P in the switch process from teichoic acid synthesis to teichuronic acid synthesis, by using an in vitro transcription system. The results indicate that PhoP approximately P is sufficient to repress the transcription of the tagA and tagD promoters and also to activate the transcription of the tuaA promoter.

Sites internal to the coding regions of phoA and pstS bind PhoP and are required for full promoter activity.

Bacillus subtilis PhoP and PhoR, a pair of two-component regulatory proteins, regulate the phosphate starvation response. Here, we used two other pho regulon promoters, the phoA and pstS promoters, to examine the mechanism of PhoP-specific activation of its target promoters. Both gel shift and DNase I footprinting assays indicate that PhoP bound to the two promoters. Unphosphorylated PhoP bound only to the multiple TTAACA-like sequences upstream of these two promoters, while phosphorylated PhoP extended the binding region in both the 5' and the 3' direction and, additionally, protected sequences internal to the coding region of these two genes. The PhoP binding sites in the coding region were necessary for full induction from either promoter during phosphate starvation. Deletion of these sites eliminated approximately 75% and 45% of the induced promoter activity of the phoA and pstS promoters respectively. In vitro transcription assays using the phoA promoters with various 3' ends confirmed the requirement of the PhoP-P binding to the coding region for full promoter activity. The multiple TTAACA-like sequences in the phoA and pstS promoters were essential for promoter activity, and deletion of one or more of these sequences in either promoter eliminated the promoter activity. Two pairs of TTAACA-like sequences were required for efficient PhoP binding and were suggested to be one B. subtilis Pho box. Based on our data, we have proposed a model for activation of the phoA and the pstS promoter by PhoP.

Bacillus licheniformis MC14 alkaline phosphatase I gene with an extended COOH-terminus.

Bacterial alkaline phosphatases (APases), except those isolated from Bacillus licheniformis, are approximately 45-kDa proteins while eucaryotic alkaline phosphatases are 60 kDa. To answer the question of whether the apparent 60-kDa alkaline phosphatase from Bacillus licheniformis accurately reflected the size of the protein, the entire gene was analyzed. DNA sequence analysis of the alkaline phosphatase I (APaseI) gene of B. licheniformis MC14 indicated that the gene could code for a 60-kDa protein of 553 amino acids. The deduced protein sequence of APaseI showed about 32% identity to those of B. subtilis APase III and IV and had apparent sequence homologies in the core structure and active sites that are conserved among APases of various sources. The extra carboxy-terminal sequence of APaseI, which made the enzyme bigger than other procaryotic APases, was not homologous to those of eucaryotic APases. The amino acid composition of APaseI was most similar to that of salt-dependent APase among the isozymes of B. licheniformis MC14. Another open reading frame of 261 amino acids was present 142 nucleotide upstream of the APaseI gene and its predicted amino acid sequence showed 68% identity to that of glucose dehydrogenase of B. megaterium.

Analysis of Bacillus subtilis tagAB and tagDEF expression during phosphate starvation identifies a repressor role for PhoP-P.

The tagAB and tagDEF operons, which are adjacent and divergently transcribed, encode genes responsible for cell wall teichoic acid synthesis in Bacillus subtilis. The Bacillus data presented here suggest that PhoP and PhoR are required for direct repression of transcription of the two operons under phosphate starvation conditions but have no regulatory role under phosphate-replete conditions. These data identify for the first time that PhoP-P has a negative role in Pho regulon gene regulation.

Pho signal transduction network reveals direct transcriptional regulation of one two-component system by another two-component regulator: Bacillus subtilis PhoP directly regulates production of ResD.

The Bacillus subtilis ResD-ResE two-component system is responsible for the regulation of a number of genes involved in cytochrome c biogenesis and haem A biosynthesis, and it is required for anaerobic respiration in this organism. We reported previously that the operon encoding these regulatory proteins, the resABCDE operon, is induced under several conditions, one of which is phosphate starvation. We report here that this transcription requires the PhoP-PhoR two-component system, whereas other induction conditions do not. The PhoPP response regulator directly binds to and is essential for transcriptional activation of the resABCDE operon as well as being involved in repression of the internal resDE promoter during phosphate-limited growth. The concentration of ResD in various phoP mutant strains corroborates the role of PhoP in the production of ResD. These interactions result in a regulatory network that ties together the cellular functions of respiration/energy production and phosphate starvation. Significantly, this represents the first evidence for direct involvement of one two-component system in transcription of a second two-component system.

Bacillus subtilis PhoP binds to the phoB tandem promoter exclusively within the phosphate starvation-inducible promoter.

Several gene products, including three two-component systems, make up a signal transduction network that controls the phosphate starvation response in Bacillus subtilis. Epistasis experiments indicate that PhoP, a response regulator, is furthest downstream of the known regulators in the signaling pathway that regulates Pho regulon genes. We report the overexpression, purification, and use of PhoP in investigating its role in Pho regulon gene activation. PhoP was a substrate for both the kinase and phosphatase activities of its cognate sensor kinase, PhoR. It was not phosphorylated by acetyl phosphate. Purified phosphorylated PhoP (PhoPP) had a half-life of approximately 2.5 h, which was reduced to about 15 min by addition of the same molar amount of *PhoR (the cytoplasmic region of PhoR). ATP significantly increased phosphatase activity of *PhoR on PhoPP. In gel filtration and cross-linking studies, both PhoP and PhoPP were shown to be dimers. The dimerization domain was located within the 135 amino acids at the N terminus of PhoP. Phosphorylated or unphosphorylated PhoP bound to one of the alkaline phosphatase gene promoters, the phoB promoter. Furthermore, PhoP bound exclusively to the -18 to -73 region (relative to the transcriptional start site +1) of the phosphate starvation-inducible promoter (Pv) but not to the adjacent developmentally regulated promoter (Ps). These data corroborate the genetic data for phoB regulation and suggest that activation of phoB is via direct interaction between PhoP and the phoB promoter. Studies of the phosphorylation, oligomerization, and DNA binding activity of the PhoP protein demonstrate that its N-terminal phosphorylation and dimerization domain and its C-terminal DNA binding domain function independently of one another, distinguishing PhoP from other response regulators, such as PhoB (Escherichia coli) and NtrC.

The pst operon of Bacillus subtilis has a phosphate-regulated promoter and is involved in phosphate transport but not in regulation of the pho regulon.

Genes from Bacillus subtilis predicted to encode a phosphate-specific transport (Pst) system were shown by mutation to affect high-affinity Pi uptake but not arsenate resistance or phosphate (Pho) regulation. The transcription start of the promoter upstream of the pstS gene was defined by primer extension. The promoter contains structural features analogous to the Escherichia coli pst promoter but not sequence similarity. Expression from this promoter was induced >5,000-fold upon phosphate starvation and regulated by the PhoP-PhoR two-component regulatory system. These data indicate that the pst operon is involved in phosphate transport and is a member of the Pho regulon but is not involved in Pi regulation.

Adaptation of Bacillus subtilis to oxygen limitation.

Bacillus subtilis grows anaerobically by at least two different pathways, respiration using nitrate as an electron acceptor and fermentation in the absence of electron acceptors. Regulatory mechanisms have evolved allowing cells to shift to these metabolic capabilities in response to changes in oxygen availability. These include transcriptional activation of fnr upon oxygen limitation, a process requiring the ResD-ResE two-component signal transduction system that also regulates aerobic respiration. FNR then activates transcription of other anaerobically induced genes including the narGHJI operon which encodes a respiratory nitrate reductase. Genes involved in fermentative growth are controlled by an unidentified FNR-independent regulatory pathway.

A Bacillus subtilis secreted phosphodiesterase/alkaline phosphatase is the product of a Pho regulon gene, phoD.

A secreted phosphodiesterase/alkaline phosphatase, APaseD, was purified from a culture of Bacillus subtilis JH646MS. Its phosphodiesterase activity was reminiscent of an APase isolated and characterized previously. Immunoassay and N-terminal sequencing showed the two proteins to be identical. Using the first 20 amino acids of the mature protein, a BLAST search of GenBank was used to find an homologous sequence. An exact match was found but in a putative non-coding region. It was hypothesized that there was a base pair deletion in the phoD gene. A DNA fragment internal to the coding region was generated by PCR using template DNA from a strain which produced APaseD. The PCR fragment was cloned and used to interrupt the gene. Western blot analysis of the parent and the mutated strains showed that APaseD was missing in the mutant. Resequencing of the gene revealed a larger ORF encoding a protein similar in size to the 49 kDa APaseD estimated by SDS-PAGE. The promoter was then cloned, sequenced and used in phoD-lacZ promoter fusions which showed that the gene was phosphate-starvation-induced and dependent on PhoP and PhoR for expression.

Two-component regulatory proteins ResD-ResE are required for transcriptional activation of fnr upon oxygen limitation in Bacillus subtilis.

Bacillus subtilis can grow anaerobically in the presence of nitrate as a terminal electron acceptor. The two component regulatory proteins, ResD and ResE, and an anaerobic gene regulator, FNR, were previously shown to be indispensable for nitrate respiration in B. subtilis. Unlike Escherichia coli fnr, B. subtilis fnr transcription was shown to be highly induced by oxygen limitation. fnr is transcribed from its own promoter as well as from a promoter located upstream of narK, the first gene in the narK-fnr dicistronic operon. DNA fragments containing the narK promoter, the fnr promoter, and both of the promoters were used to construct three lacZ fusions to examine the transcriptional regulation of the narK-fnr operon. ResDE was found to be required for transcriptional activation of fnr from the fnr-specific promoter, and FNR was required for activation of narK-fnr transcription from the FNR-dependent narK operon promoter under anaerobiosis. In order to determine if the requirement for ResDE in nitrate respiration is solely to activate fnr transcription, fnr was placed under control of the IPTG (isopropyl-beta-D-thiogalactopyranoside)-inducible promoter, Pspac. The observed defect in anaerobic growth of a Pspac-fnr delta resDE mutant in the presence of IPTG indicated that resDE has an additional role in B. subtilis anaerobic gene regulation.

The signal-transduction network for Pho regulation in Bacillus subtilis.

Depletion of nutrients, including phosphate, is a stress often encountered by a bacterial cell, and results in slowed growth, marking the cessation of exponential growth. Genes that are transcriptionally activated during phosphate starvation have been used to examine the signal-transduction mechanisms governing the Pho regulon in Bacillus subtilis. Alkaline phosphatase, the traditional reporter protein for Pho regulation in prokaryotes, is encoded by a multigene family in B. subtilis. Characterization of the alkaline phosphatase family was a breakthrough in the study of regulation of the Pho regulon, especially the discovery of promoter elements exclusively responsive to phosphate-starvation regulation. Current data suggest that at least three two-component signal-transduction systems interact, forming a regulatory network that controls the phosphate-deficiency response in B. subtilis. The interconnected pathways involve the PhoP-PhoR system, whose primary role is to mediate the phosphate-deficiency response; the SpoO phosphorelay required for the initiation of sporulation; and a newly discovered signal-transduction system, ResD-ResE, which also has a role in respiratory regulation during late growth. Parallel pathways positively regulate the Pho response via PhoP-PhoR. One pathway includes the ResD-ResE system, while the other involves a transition-state regulator, AbrB. The SpoO system represses the Pho response by negatively regulating both pathways. This review will discuss how the characterization of the APase multigene family made possible studies which show that the Pho regulon in B. subtilis is regulated by the integrated action of the Res, Pho and Spo signal-transduction systems.

Three two-component signal-transduction systems interact for Pho regulation in Bacillus subtilis.

The Pho regulon of Bacillus subtilis is controlled by three two-component signal-transduction systems: PhoP/PhoR, ResD/ResE, and the phosphorelay leading to the phosphorylation of SpoOA. Two of these systems act as positive regulators, while the third is involved in negative regulation of the Pho regulon. Under phosphate-starvation-induction conditions, the response regulator (RR) PhoP, and the histidine protein kinase (HK) PhoR, are involved in the induction of Pho-regulon genes including the phoPR operon and genes encoding the major vegetative alkaline phosphatases, phoA and phoB. ResD (the RR) and ResE (the HK) are positive regulators of both aerobic and anaerobic respiration in B. subtilis. Current data suggest that they are also positive regulators of the Pho regulon, as is the transition-state regulatory protein AbrB. Data presented reveal that ResDE and AbrB are involved in activation of the Pho regulon through separate regulatory pathways. SpoOA approximately P (RR) exerts a negative effect on the Pho regulon through its repression of AbrB, and possibly through repression of ResDE. Both pathways converge to regulate transcription of the phoPR operon.

Regulators of aerobic and anaerobic respiration in Bacillus subtilis.

Two Bacillus subtilis genes, designated resD and resE, encode proteins that are similar to those of two-component signal transduction systems and play a regulatory role in respiration. The overlapping resD-resE genes are transcribed during vegetative growth from a very weak promoter directly upstream of resD. They are also part of a larger operon that includes three upstream genes, resABC (formerly orfX14, -15, and -16), the expression of which is strongly induced postexponentially. ResD is required for the expression of the following genes: resA, ctaA (required for heme A synthesis), and the petCBD operon (encoding subunits of the cytochrome bf complex). The resABC genes are essential genes which encode products with similarity to cytochrome c biogenesis proteins. resD null mutations are more deleterious to the cell than those of resE. resD mutant phenotypes, directly related to respiratory function, include streptomycin resistance, lack of production of aa3 or caa3 terminal oxidases, acid accumulation when grown with glucose as a carbon source, and loss of ability to grow anaerobically on a medium containing nitrate. A resD mutation also affected sporulation, carbon source utilization, and Pho regulon regulation. The data presented here support an activation role for ResD, and to a lesser extent ResE, in global regulation of aerobic and anaerobic respiration i B.subtilis.