The Bacillus subtilis 168 alkaline phosphatase III gene: impact of a phoAIII mutation on total alkaline phosphatase synthesis.

The first alkaline phosphatase (APase) structural gene mutant of Bacillus subtilis 168 was constructed by using a clone identified by hybridization to a synthetic degenerative oligonucleotide. The design of the probe was based on the first 29 amino acids of the sequenced mature APase III protein, which had been isolated from the secreted fraction of vegetative, phosphate-starved cells. DNA sequencing of the clone revealed the first 80 amino acids of the APase III protein, including a typical procaryotic signal sequence of 32 amino acids preceding the start of the mature protein. The 29 amino acids encoded by the predicted open reading frame immediately following the signal sequence are identical to the first 29 amino acids of the sequenced mature protein. This region shows 80% identity to strand A of the beta sheet that is very well conserved in Escherichia coli and mammalian APases. A phoAIII structural mutant was constructed by insertional mutagenesis with a fragment internal to the coding region. The effects of this mutation on APase production in B. subtilis 168 were analyzed under both phosphate starvation and sporulation conditions. The mutation in APase III reduced the total vegetative APase specific activity by approximately 40% and sporulation APase specific activity by approximately 45%. An APase protein was isolated from sporulating cells at stage III and was identified as APase III by protein sequencing of the amino terminus and by its absence in the phoAIII mutant. The APase III gene has been mapped to approximately 50 degrees on the B. subtilis chromosome.     

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 P _spac promoter, which is IPTG inducible. The wild-type phoR , under either native promoter or P _spac 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 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.     

Regulation of synthesis of alkaline phosphatase by deoxyribonucleic acid synthesis in a constitutive mutant of Bacillus subtilis

Hiraga, Sota (Osaka University, Osaka, Japan). Regulation of synthesis of alkaline phosphatase by deoxyribonucleic acid synthesis in a constitutive mutant of Bacillus subtilis. J. Bacteriol. 91:2192-2199. 1966.-It was found that synthesis of alkaline phosphatase (APase) correlated with deoxyribonucleic acid (DNA) synthesis in a partially constitutive mutant of Bacillus subtilis. When cultures of the mutant were made to undergo synchronous growth by germination of spores in an excess-phosphate medium, synthesis of APase was repressed at the beginning of DNA synthesis. If the initiation of DNA synthesis was inhibited by thymine starvation, the repression of APase was not observed. When DNA synthesis, previously initiated, was inhibited by thymine or uracil starvation, or by addition of mitomycin C, the repression was partially released at a later stage. In contrast, this correlation between repression and DNA synthesis was not observed in a repressible strain.     

Extracellular manganese-stimulated deoxyribonuclease as a marker event in sporulation of Bacillus subtilis.

A considerable amount of Mn2+-stimulated DNAase (deoxyribonuclease) activity is released by Bacillus subtilis 168 during sporulation in a glucose-deficient medium; much smaller amounts are released during starvation for phosphate or nitrogen. Protein synthesis is required. Two forms of evidence are presented that production of the DNAase is associated with events late in stage II of sporulation. 19 Thymidine starvation, which inhibits the biochemical events associated with sporulation, also inhibits release of the DNAase. 2. Several asporogenous mutants blocked at stage II or earlier and unable to produce alkaline phosphatase (a stage-II event) do not produce the enzyme. Mutants blocked towards the end of stage II or later produce both enzymes. During sporulation of the wild-type strain, the DNAase appears about 1 h after alkaline phosphatase. The results suggest that production of the DNAase is controlled by a still-undiscovered stage-II genetic locus.     

Bacillus licheniformis APase I gene promoter: a strong well-regulated promoter in B. subtilis

The 5' regulatory region and the portion of the structural gene coding for the amino-terminal sequence of alkaline phosphatase I (APase I) were isolated from Bacillus licheniformis MC14 using a synthetic oligodeoxynucleotide deduced from the amino acid sequence of the enzyme. The DNA sequence analysis of this region revealed an open reading frame of 129 amino acids containing the amino-terminal sequence of the mature APase protein. The protein sequence was preceded by a putative signal sequence of 32 amino acid residues. The predicted amino acid sequence of the partial APase clone as well as the experimentally determined amino acid sequence of the enzyme indicated that B. licheniformis APase retains the important features conserved among other APases of Bacillus subtilis, Escherichia coli, Saccharomyces cerevisiae, and various human tissues. Heterologous expression studies of the promoter using a fusion with the lacZ gene indicated that it functions as a very strong inducible promoter in B. subtilis that is tightly regulated by phosphate concentration.     

Interrelationship between metabolic and genetic regulation of alkaline and acid phosphatases in E. coli cells]

The effect of exogenous orthophosphate and mutations in regulatory genes of alkaline phosphatase on the level of nonspecific acid phosphatase was studied. The level of this enzyme as well as the level of alkaline phosphatase were shown to be regulated by exogenous orthophosphate being derepressed under phosphate starvation. The derepression of acid phosphatase is accompanied by more rapid secretion of enzyme from membranes to soluble fraction. Mutations in all the four regulatory genes decrease the level of enzyme in cells. Genes phoR and phoS, participating in regulation of alkaline phosphatase, are required for the derepression of acid phosphatase under the conditions of phosphate starvation.     

Bacillus subtilis alkaline phosphatases III and IV. Cloning, sequencing, and comparisons of deduced amino acid sequence with Escherichia coli alkaline phosphatase three-dimensional structure

Bacillus subtilis has an alkaline phosphatase multigene family. Two members of this gene family, phoAIII and phoAIV, were cloned, taking advantage of in vitro constructed strains containing a plasmid insertion within one or the other of the structural genes. The DNA sequences of the two genes showed approximately 64% identity at the DNA level and 63% identity in the deduced primary amino acid sequences. The phoAIII and phoAIV genes code for predicted proteins of 47,149 and 45,935 Da, respectively. Comparison of the deduced primary amino acid sequence of the mature proteins with other sequenced alkaline phosphatases from Escherichia coli, yeast, and humans shows 25-30% identity. Based on the refined crystal structure of E. coli alkaline phosphatase, it appears that the active site and the core of the structure are retained in both Bacillus alkaline phosphatases. However, both proteins are truncated at the amino terminus compared with other mature alkaline phosphatases, three sizable surface loops of E. coli are deleted, and a minidomain is replaced with a larger domain in the model. Neither Bacillus alkaline phosphatase sequenced contains any cysteine residues, an amino acid implicated in intrachain disulfide bond formation in other alkaline phosphatases.     

短小芽孢杆菌碱性蛋白酶基因启动子的克隆、鉴定及其应用

利用TAIL-PCR(Thermal asymmetric interlaced PCR)从短小芽孢杆菌基因组中扩增到碱性蛋白酶基因编码区上游的启动子片段。对该片段的序列测定和分析表明, 此片段长797 bp, 但与基因表达有关的序列长约390 bp。对启动子片段进行不同长度的缺失突变, 以获得最小的基因启动子片段, 结果表明, 该基因起始密码子上游约160 bp的DNA片段就可以启动基因的表达。将含有该片段的碱性蛋白酶基因WApQ3插入大肠杆菌-芽孢杆菌穿梭质粒载体pSUGV4中, 构建了碱性蛋白酶基因表达质粒pSUBpWApQ3。将该质粒分别转入枯草芽孢杆菌和短小芽孢杆菌中表达, 可在胞外检测到碱性蛋白酶活性, 最高酶活分别为466.5 U/mL和3060 U/mL。     

Polyphosphate-selective porin OprO of Pseudomonas aeruginosa: expression, purification and sequence

The oprO gene of Pseudomonas aeruginosa codes for a polyphosphate-specific porin and terminates 458 bp upstream of the start codon for the phosphate-specific porin OprP. OprO was found to be expressed only under phosphate-starvation conditions in both wild-type and oprP::Tn501 mutant P. aeruginosa strains. However, unlike the rest of the genes of the Pho regulon, including oprP, expression of oprO required cells to be in the stationary growth phase in addition to phosphate starvation. Wild-type P. aeruginosa cells were grown in fermentor culture under these conditions and fractionated by selective solubilization in octylpolyoxyethylene detergent solution. Solubilized OprO was separated from OprP by application to a Mono Q FPLC column and elution with a salt gradient and shown to be functionally identical to cloned OprO produced in Escherichia coli. DNA sequencing of oprO showed the gene product to be highly homologous to OprP, with 76% identity and 16% conserved substitutions. Most genes of the Pho regulon possess a modified -35 region called the Pho box. Two such elements, separated by 4 bp were found in oprO. DNA sequencing also revealed a second Pho box in the oprP gene with the same spacing.     

Peptidyl-tRNA hydrolase in Bacillus subtilis,encoded by spoVC,is essential to vegetative growth,whereas the homologous enzyme in Saccharomyces cerevisiae is dispensable

Peptidyl-tRNA hydrolase in Escherichia coli, encoded by pth, is essential for recycling tRNA molecules sequestered as peptidyl-tRNA as a result of pre-mature dissociation from the ribosome during translation. Genes homologous to pth are present in other bacteria, yeast and man, but not in archaea. The homologous gene in Bacillus subtilis, spoVC, was first identified as a gene involved in sporulation. A second copy of spoVC, under the control of the xyl promoter, was integrated into B. subtilis at the amy locus. In this background, interruption of the original gene was possible provided that expression of the copy at the amy locus was induced. When spoVC was interrupted, both vegetative growth and sporulation were dependent on xylose, showing that SpoVC is essential. The role of SpoVC in sporulation is discussed and appears to be consistent with previous hypotheses that a relaxation of translational accuracy may occur during sporulation. The homologous gene in Saccharomyces cerevisiae, yHR189W, has been interrupted in both haploid and diploid strains. The mutant haploid strains remain viable, as do the yHR189W mutant spores obtained by tetrad dis-section, with either glucose or glycerol as carbon source, showing that the yHR189W gene product is dispensable for cell growth and for mitochondrial respiration.