The Bacillus subtilis phoAIV gene: effects of in vitro inactivation on total alkaline phosphatase production

Cys303 in the histidine kinase PhoR is crucial for the phosphotransfer reaction in the PhoPR two-component system in Bacillus subtilis

The PhoPR two-component system activates or represses Pho regulon genes to overcome a phosphate deficiency. The Pho signal transduction network is comprised of three two-component systems, PhoPR, ResDE, and Spo0A. Activated PhoP is required for expression of ResDE from the resA promoter, while ResD is essential for 80% of Pho induction, establishing a positive feedback loop between these two-component systems to amplify the signal received by the Pho system. The role of ResD in the Pho response is via production of terminal oxidases. Reduced quinones inhibit PhoR autophosphorylation in vitro, and it was proposed that the expression of terminal oxidases leads to oxidation of the quinone pool, thereby relieving the inhibition. We show here that the reducing environment generated by dithiothreitol (DTT) in vivo inhibited Pho induction in a PhoR-dependent manner, which is in agreement with our previous in vitro data. A strain containing a PhoR variant, PhoR(C303A), exhibited reduced Pho induction and remained sensitive to inhibition by DTT, suggesting that the mechanisms for Pho reduction via PhoR(C303A) and DTT are different. PhoR and PhoR(C303A) were similar with regard to cellular concentration, limited proteolysis patterns, rate of autophosphorylation, stability of PhoR approximately P, and inhibition of autophosphorylation by DTT. Phosphotransfer between PhoR approximately P or PhoR(C303A) approximately P and PhoP occurred rapidly; most label from PhoR approximately P was transferred to PhoP, but only 10% of the label from PhoR(C303A) approximately P was associated with PhoP, while 90% was released as inorganic phosphate. No difference in PhoP approximately P or PhoR autophosphatase activity was observed between PhoR and PhoR(C303A) that would explain the release of inorganic phosphate. Our data are consistent with a role for PhoR(C303) in PhoR activity via stabilization of the phosphoryl-protein intermediate(s) during phosphotransfer from PhoR approximately P to PhoP, which is stabilization that is required for efficient production of PhoP approximately P.

Bacillus subtilis phosphorylated PhoP: direct activation of the E(sigma)A- and repression of the E(sigma)E-responsive phoB-PS+V promoters during pho response

The phoB gene of Bacillus subtilis encodes an alkaline phosphatase (PhoB, formerly alkaline phosphatase III) that is expressed from separate promoters during phosphate deprivation in a PhoP-PhoR-dependent manner and at stage two of sporulation under phosphate-sufficient conditions independent of PhoP-PhoR. Isogenic strains containing either the complete phoB promoter or individual phoB promoter fusions were used to assess expression from each promoter under both induction conditions. The phoB promoter responsible for expression during sporulation, phoB-P(S), was expressed in a wild-type strain during phosphate deprivation, but induction occurred >3 h later than induction of Pho regulon genes and the levels were approximately 50-fold lower than that observed for the PhoPR-dependent promoter, phoB-P(V). E(sigma)E was necessary and sufficient for P(S) expression in vitro. P(S) expression in a phoPR mutant strain was delayed 2 to 3 h compared to the expression in a wild-type strain, suggesting that expression or activation of sigma(E) is delayed in a phoPR mutant under phosphate-deficient conditions, an observation consistent with a role for PhoPR in spore development under these conditions. Phosphorylated PhoP (PhoP approximately P) repressed P(S) in vitro via direct binding to the promoter, the first example of an E(sigma)E-responsive promoter that is repressed by PhoP approximately P. Whereas either PhoP or PhoP approximately P in the presence of E(sigma)A was sufficient to stimulate transcription from the phoB-P(V) promoter in vitro, roughly 10- and 17-fold-higher concentrations of PhoP than of PhoP approximately P were required for P(V) promoter activation and maximal promoter activity, respectively. The promoter for a second gene in the Pho regulon, ykoL, was also activated by elevated concentrations of unphosphorylated PhoP in vitro. However, because no Pho regulon gene expression was observed in vivo during P(i)-replete growth and PhoP concentrations increased only threefold in vivo during phoPR autoinduction, a role for unphosphorylated PhoP in Pho regulon activation in vivo is not likely.

Purification and characterization of Ulva pertusa Kjellm alkaline phosphatase

The activity of alkaline phosphatase (ALP, EC 3.1.3.1.) was found in seaweeds, including five kinds of green alga, eighteen kinds of red alga, and six kinds of brown alga, collected from the seaside of Dalian in China. The enzyme was purified 1230-fold from Ulva pertusa Kjellm. It had a specific activity of 48.6 U/mg protein and was proven to be homogeneous by SDS-PAGE with a subunit molecular mass of 19.5 kDa. The activity of ALP peaked at pH9.8, and was completely inhibited by DTT and partly by NBS. The Michaelis-Menten constant Km and the maximum reaction velocity Vmax, at pH 9.8 and 37 degrees C were 0.950 mM and 5.00 microM/min, respectively.

Residue R113 is essential for PhoP dimerization and function: a residue buried in the asymmetric PhoP dimer interface determined in the PhoPN three-dimensional crystal structure

Bacillus subtilis PhoP is a member of the OmpR/PhoB family of response regulators that is directly required for transcriptional activation or repression of Pho regulon genes in conditions under which P(i) is growth limiting. Characterization of the PhoP protein has established that phosphorylation of the protein is not essential for PhoP dimerization or DNA binding but is essential for transcriptional regulation of Pho regulon genes. DNA footprinting studies of PhoP-regulated promoters showed that there was cooperative binding between PhoP dimers at PhoP-activated promoters and/or extensive PhoP oligomerization 3' of PhoP-binding consensus repeats in PhoP-repressed promoters. The crystal structure of PhoPN described in the accompanying paper revealed that the dimer interface between two PhoP monomers involves nonidentical surfaces such that each monomer in a dimer retains a second surface that is available for further oligomerization. A salt bridge between R113 on one monomer and D60 on another monomer was judged to be of major importance in the protein-protein interaction. We describe the consequences of mutation of the PhoP R113 codon to a glutamate or alanine codon and mutation of the PhoP D60 codon to a lysine codon. In vivo expression of either PhoP(R113E), PhoP(R113A), or PhoP(D60K) resulted in a Pho-negative phenotype. In vitro analysis showed that PhoP(R113E) was phosphorylated by PhoR (the cognate histidine kinase) but was unable to dimerize. Monomeric PhoP(R113E) approximately P was deficient in DNA binding, contributing to the PhoP(R113E) in vivo Pho-negative phenotype. While previous studies emphasized that phosphorylation was essential for PhoP function, data reported here indicate that phosphorylation is not sufficient as PhoP dimerization or oligomerization is also essential. Our data support the physiological relevance of the residues of the asymmetric dimer interface in PhoP dimerization and function.

The cell surface associated phosphatase activity of Mycobacterium bovis BCG is not regulated by environmental inorganic phosphate

Non-specific phosphomonoesterase activities (alkaline phosphatase (EC 3.1.3.1) and acid phosphatase (EC 3.1.3.2)) were examined at the cell surface of Mycobacterium bovis BCG. Using p-nitrophenylphosphate as the substrate, peaks of phosphatase activity were detected at pH 6.0, pH 10.0 and pH 12.0, suggesting the presence of one acid phosphatase and two alkaline phosphatases with distinct optimum pH values. Contrary to the situation observed in several other microorganisms, the expression of these enzymes is not regulated by the environmental inorganic phosphate concentration.

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.

Influence of Bacillus subtilis phoR on cell wall anionic polymers

In Bacillus subtilis the Pho regulon is controlled by a sensor and regulator protein pair, PhoR and PhoP, that respond to phosphate concentrations. To facilitate studies of the Pho regulon, a strain with an altered PhoR protein was isolated by in vitro mutagenesis. The mutation in this strain (phoR12) leads to the production of a PhoR sensor kinase that, unlike the wild-type, is functionally active in phosphate-replete conditions. The lesion in PhoR12 was shown to be a single base change that results in an Arg to Ser substitution in a region of PhoR that is highly conserved in histidine sensor kinases. While a phoR-negative mutant was unable to induce the synthesis of cell wall teichuronic acid under phosphate-limited conditions, the phoR12 mutant showed a relative increase in teichuronic acid and a decrease in teichoic acid, even under phosphate-replete conditions. The latter suggests that some or all of the genes required for teichuronic acid synthesis are members of the Pho regulon.

Cloning and characterization of spoVR, a gene from Bacillus subtilis involved in spore cortex formation

Screening for sigma E-dependent promoters led to the isolation of a gene from Bacillus subtilis, designated spoVR, which appears to be involved in spore cortex formation. Cultures of strains carrying mutations in spoVR had an increased proportion of phase-dark spores, which correlated with an increased proportion of cortexless spores seen by electron microscopy. The numbers of heat- and chloroform-resistant phase-bright spores produced by these mutants were decreased by about 3- to 10-fold, and accumulation of dipicolinate was decreased by more than 3-fold. The spoVR gene was located on the B. subtilis chromosome immediately upstream from, and in the opposite orientation of, the phoAIV gene. Expression of spoVR was initiated at the second hour of sporulation from a sigma E-dependent promoter, and this expression did not require any of the other known mother-cell-specific transcriptional regulators. The spoVR gene was predicted to encode a product of 468 residues.

Sequential action of two-component genetic switches regulates the PHO regulon in Bacillus subtilis

Bacillus subtilis has an alkaline phosphatase (APase) gene family composed of at least four genes. All members of this gene family are expressed postexponentially, either in response to phosphate starvation or sporulation induction or, in some cases, in response to both. The phoA gene (formerly called phoAIV) and the phoB gene (formerly called phoAIII) products have both been isolated from phosphate-starved cells, and a mutation in either gene decreased the total APase expressed under phosphate starvation conditions. Data presented here show that a phoA phoB double mutant reduced APase production during phosphate starvation by 98%, indicating that these two genes are responsible for most of the APase activity during phosphate-limited growth. The promoter for phoA was cloned and used, with the phoB promoter, to examine phosphate regulation in B. subtilis. phoA-lacZ reporter gene assays showed that the expression of the phoA gene commences as the culture enters stationary phase as a result of limiting phosphate concentrations in the growth medium, thereby mimicking the pattern of total APase expression. Induction persists for approximately 2 h and is then turned off. phoA is transcribed from a single promoter which initiates transcription 19 bp before the translation initiation codon. PhoP and PhoR are members of the two-component signal transduction system believed to regulate gene expression in response to limiting phosphate. The expression of phoA or phoB in response to phosphate starvation was equally dependent on PhoP and PhoR for induction. lacZ-promoter fusions showed that both phoA and phoB were hyperinduced, or failed to turn off induction after 2 h, in a spo0A strain of B. subtilis. Mutations in genes which are required for phosphorylation of Spo0A, spo0B and spo0F, also resulted in phoA and phoB hyperinduction, suggesting that phosphorylation of Spo0A is required for the repression of both APases in wild-type strains. The hyperinduction of either APase gene in a spo0A strain was dependent on PhoP and PhoR. Analysis of a phoP-lacZ promoter fusion showed that the phoPR operon is hyperinduced in a spo0A mutant strain, suggesting that Spo0A approximately P represses APases by repressing phoPR transcription. We propose a model for PHO regulation in B. subtilis whereby the phoPR operon is transcribed in response to limiting phosphate concentration, resulting in activation of the PHO regulon transcription, including transcription of phoA and phoB. When the phosphate response fails to overcome the nutrient deficiency, signals for phosphorylation of Spo0A result in production of Spo0A approximately P, which represses transcription of phoPR, thereby repressing synthesis of the PHO regulon.

Bacillus subtilis transcription regulator, Spo0A, decreases alkaline phosphatase levels induced by phosphate starvation

Alkaline phosphatase (APase) is induced as a culture enters stationary phase because of limiting phosphate. The results presented here show that expression of APase is regulated both negatively and positively. PhoP, a homolog of a family of bacterial transcription factors, and PhoR, a homolog of bacterial histidine protein kinases, are required for induction of APases when phosphate becomes limiting. The induction period lasts 2 to 3 h, after which the rate of APase accumulation is decreased. Mutant strains defective in the Spo0A transcription factor failed to decrease APase production. The consequent hyperinduction of APase in a spo0A strain was dependent on phoP and phoR. spo0B and spo0F strains also overexpressed APase, suggesting that phosphorylated Spo0A is required for repression of APase. An abrB mutant allele in the presence of the mutant spo0A allele in these strains did not significantly change the APase hyperinduction phenotype, demonstrating that Spo0A repression of abrB expression is not the mechanism by which Spo0A-P regulates APase expression. Our previous report that spo0A mutants do not express APases is in conflict with the present data. We show here that the previously used mutants and a number of commonly used spo0 strains, all of which have an APase deficiency phenotype, contain a previously unrecognized mutation in phoR.

Use of microbial spores as a biocatalyst

Endospores of a bacterium Bacillus subtilis and ascospores of a yeast Saccharomyces cerevisiae contained almost all the activities for the same enzymes as vegetative cells. The biotechnological potential of spores was studied by selecting adenosine 5'-triphosphatase and alkaline phosphatase in bacterial and yeast spores, respectively, as model enzymes. The activity of both enzymes was efficiently expressed when the spores were treated by physical (sonication or electric field pulse) and chemical (organic solvents or detergents) methods. The yeast spores were immobilized in polyacrylamide gel without any appreciable loss of activity. The immobilized spores were packed in a column and used successfully for the continuous reactions of alkaline phosphatase and glyoxalase I. The microbial spores were confirmed to be promising as a biocatalyst for the production of useful chemicals in bioreactor systems.

Separate promoters direct expression of phoAIII, a member of the Bacillus subtilis alkaline phosphatase multigene family, during phosphate starvation and sporulation

Alkaline phosphatase (APase) expression can be induced in Bacillus subtilis by phosphate starvation or by sporulation. We have recently shown that there are multiple APase structural genes contributing to the total alkaline phosphatase expression in B. subtilis. The expression of the alkaline phosphatase III gene (phoAIII) was analysed under both phosphate-starvation induction and sporulation induction conditions. phoAII is transcribed from two promoter regions, PV and PS. The PV promoter initiated transcription 37 bp before the translation initiation codon and was used to transcribe phoAIII during phosphate-starvation induction in vegetative cells. The PS promoter initiated transcription 119 bp before the translation initiation codon and was used during sporulation induction. Genes which have previously been shown to affect total vegatative APase, pho regulon genes phoP, phoR and phoS, affected expression of phoAIII during phosphate starvation. Genes known to affect expression of total sporulation APase, i.e. spoIIA, spoIIG and spoIIE, affected phoAIII expression during sporulation induction. Our data show that one member of the APase multigene family, phoAIII, contributes to the total APase expression both during phosphate-starvation induction and sporulation induction, and that the mechanism of regulation includes two promoters, each requiring different regulatory genes.