The regulatory nature of the phoB gene for alkaline phosphatase synthesis in Escherichia coli

P2RP: a Web-based framework for the identification and analysis of regulatory proteins in prokaryotic genomes

Background

Regulatory proteins (RPs) such as transcription factors (TFs) and two-component system (TCS) proteins control how prokaryotic cells respond to changes in their external and/or internal state. Identification and annotation of TFs and TCSs is non-trivial, and between-genome comparisons are often confounded by different standards in annotation. There is a need for user-friendly, fast and convenient tools to allow researchers to overcome the inherent variability in annotation between genome sequences.

Results

We have developed the web-server P2RP (Predicted Prokaryotic Regulatory Proteins), which enables users to identify and annotate TFs and TCS proteins within their sequences of interest. Users can input amino acid or genomic DNA sequences, and predicted proteins therein are scanned for the possession of DNA-binding domains and/or TCS domains. RPs identified in this manner are categorised into families, unambiguously annotated, and a detailed description of their features generated, using an integrated software pipeline. P2RP results can then be outputted in user-specified formats.

Conclusion

Biologists have an increasing need for fast and intuitively usable tools, which is why P2RP has been developed as an interactive system. As well as assisting experimental biologists to interrogate novel sequence data, it is hoped that P2RP will be built into genome annotation pipelines and re-annotation processes, to increase the consistency of RP annotation in public genomic sequences. P2RP is the first publicly available tool for predicting and analysing RP proteins in users’ sequences. The server is freely available and can be accessed along with documentation at http://www.p2rp.org.

A role for the PhoBR regulatory system homologue in the Vibrio cholerae phosphate-limitation response and intestinal colonization

To survive and multiply in different environments, Vibrio cholerae has to coordinately regulate the expression of genes involved in adaptive responses. In many pathogens, adaptive responses, including pathogenic responses, are regulated by two-component regulator (TCR) systems. It is likely that members of a TCR family play a role in the regulation of processes involved in intestinal colonization, and therefore pathogenesis, in V. cholerae. We have identified and characterized a TCR system of V. cholerae: this system is a homologue of Escherichia coli PhoBR. The presence of a putative Pho box suggests that the V. cholerae phoBR operon is regulated by inorganic phosphate levels. The phoR and phoB genes are organized the same way as in E. coli. Mutation of the V. cholerae phoB gene affected the expression of the putative Pho regulon, including PhoA, but did not affect the production of cholera toxin. V. cholerae phoB mutants are less able to colonize rabbit intestine than wild-type V. cholerae. The addition of inorganic phosphate at a high concentration to the inoculum only partially restored the ability of the mutants to colonize the intestine, suggesting that the V. cholerae Pho regulon in vivo may not be regulated by inorganic phosphate levels alone.

Guanosine 3',5'-bispyrophosphate (ppGpp) synthesis in cells of Escherichia coli starved for Pi

Cells of Escherichia coli which enter a phase of starvation for Pi induce the synthesis of the nucleotide guanosine 3',5'-bispyrophosphate (ppGpp). This induction is relA independent but depends on the spoT gene product. A mutant unable to produce ppGpp is impaired in the expression of two genes which belong to the pho regulon, a defect which is dependent on the product of spoT. We suggest that ppGpp is essential for the proper induction of the genes which belong to the pho regulon.

Characterization of the Salmonella typhimurium phoE gene and development of Salmonella-specific DNA probes

In Escherichia coli K-12, the phoE gene, encoding a phosphate-limitation-inducible outer membrane pore protein (PhoE), is closely linked to the genes proA and proB. When the corresponding fragment of the Salmonella typhimurium chromosome was transferred to E. coli K-12 using an RP4::miniMu plasmid, pULB113, no production of S. typhimurium PhoE could be detected. Nevertheless, DNA hybridization studies revealed that the corresponding plasmid did contain S. typhimurium phoE. Production of S. typhimurium PhoE in E. coli was detected only after subcloning the gene in a multicopy vector. Nucleotide (nt) sequence analysis showed extensive homology of S. typhimurium phoE to the E. coli gene and suggested possible explanations for the low expression of S. typhimurium phoE in E. coli. In addition, the sequence information was used to develop Salmonella-specific DNA probes. Two oligodeoxyribonucleotides were synthesized based on nt sequences encoding the fifth and eighth cell-surface-exposed regions of PhoE. When used in polymerase chain reactions, these probes turned out to be specific, i.e., no crossreactions occurred with the non-Salmonella strains, whereas 132 out of 133 tested Salmonella strains were recognized.

Regulation of major outer membrane porin proteins of Escherichia coli K 12 by pH

Electrophoretic analysis of total membrane proteins of Escherichia coli cells grown at neutral or acid pH showed that ompF, ompC and lamB porin gene expression was regulated by changes in extracellular pH. Growth at acid pH was correlated with a decrease in outer membrane proteins OmpF and LamB and an increase in protein OmpC. pH-induced effects were confirmed and quantitatively estimated by using strains carrying ompF-lacZ, ompC-lacZ and lamB-lacZ fusions. Our studies showed that the pH-dependent regulation acted at a transcriptional level on ompF and ompC gene expression and also at a post-transcriptional level on ompF gene expression. Similar studies carried out with envZ strains showed that the pH-controlled transducing signal was mediated via the EnvZ protein, although other pH-dependent pathways were also involved.

Contrasting mechanisms of envZ control of mal and pho regulon genes in Escherichia coli

The envZ11 missense mutation in the regulatory gene envZ pleiotropically repressed synthesis of OmpF, alkaline phosphatase, and several proteins of the maltose regulon. Procaine treatment of wild-type cells resulted in the same phenotype through an envZ+-mediated mechanism. Here we show that envZ11-procaine act differently on the mal and pho regulons. In the mal system, the expression of the positive regulator gene malT, measured as beta-galactosidase activity of a malT-lac+ operon fusion, was drastically reduced by procaine treatment or by the envZ11 mutation. In contrast, expression of the positive regulator of the pho regulon phoB was not reduced by procaine treatment. The products of the regulatory genes phoM, phoR, and phoU were also not required for procaine action. Procaine and envZ11 inhibited expression of only two products of the pho regulon, alkaline phosphatase and the PhoE porin. The conclusion that envZ11-procaine act differently on the mal and the pho regulons is supported by our ability to isolate second-site mutations with a Mal+ PhoA- phenotype in an envZ11 strain.

The effect of the locus pstB on phosphate binding in the phosphate specific transport (PST) system of Escherichia coli

The periplasmic phosphate binding protein is a product of the phoS gene and is an essential component of the phosphate specific transport (PST) system, which mediates Pi uptake in Escherichia coli. The binding of Pi to periplasmic protein(s) and the kinetic parameters of Pi uptake were studied in phoT and pstB mutants of E. coli. These mutants are impaired in Pi uptake but have a periplasmic Pi-binding protein whose Pi-binding capacity was estimated by the retention kinetics. The Pi-binding activity in two pstB mutants was found to be weaker as compared to phoT9 and the wild type. The KD values for Pi binding to periplasmic protein were determined by equilibrium dialysis. In the pstB mutants the KD value was found to be 9-31 times higher than the values obtained for the wild type and the phoT mutant. The apparent Km values for Pi uptake in one pstB mutant is 14.3 times higher than in the wild type. Vmax of the mutant is 8.3 times lower that of the wild type. The data indicate that pstB, an essential gene of the PST transport system, is promoting the binding capacity of the Pi-binding protein.

A new locus in the phosphate specific transport (PST) region of Escherichia coli

PhoS64 is a mutation in the Phosphate Specific Transport (PST) region on the E. coli chromosome which lacks the periplasmic phosphate binding protein. In contrast to other phoS mutations (which have the same phenotype) it complements the mutations in phoT and pstB. A detailed genetic map of the PST region constructed by three point transductional crosses has revealed that phoS64 is located distally from other phoS mutations. The genetic order obtained was phoS64-phoU35-pstB401-phoT-phoS-ilvC. The data indicate that phoS64 belongs to a different complementation unit in the PST region not known hitherto. We propose to name it phoV.

Identification of the phoM gene product and its regulation in Escherichia coli K-12

Plasmids containing the chromosome region of Escherichia coli encoding phoM, whose product is a positive regulator of alkaline phosphatase expression, were isolated from the Clarke and Carbon plasmid bank. A 9.9-kilobase EcoRI fragment of plasmid pLC17-39 (subcloned into pBR322) was able to complement both phoM and thrB mutations. Restriction endonuclease analysis and in vitro mutagenesis of the hybird plasmids enabled the localization of the phoM gene locus to 3 kilobases of the cloned chromosomal fragment. The phoM gene product was identified, with maxicell techniques, as a protein with an approximate molecular weight of 55,000. A phoM-lacZ protein fusion was constructed by using a plasmid carrying the phoM gene and a derivative of phage lambda, lambda plac Mu2. Restriction endonuclease analysis of the plasmid carrying the fusion indicated that phoM is transcribed in a clockwise direction on the circular E. coli chromosome. Analysis of strains bearing the fusion on a multiple-copy plasmid or integrated at the lambda attachment site of the chromosome indicated that the synthesis of the phoM gene product was unaffected by phosphate limitation of growth. The expression of the phoM gene was studied in strains with mutations in genes encoding effectors of the pho regulon. A threefold increase in phoM expression was seen in a phoU strain in comparison with the wild-type strain.

Cloning of phoM, a gene involved in regulation of the synthesis of phosphate limitation inducible proteins in Escherichia coli K12

Like the synthesis of alkaline phosphatase, the synthesis of outer membrane PhoE protein is shown to be dependent on the phoM gene product in phoR mutants of E. coli K12. This phoM gene has been cloned into the multi-copy vector pACYC184 using selection for alkaline phosphatase constitutive synthesis in a phoR background. The gene was localized on the hybrid plasmids by analysis of deletion plasmids constructed in vitro and of mutant plasmids generated by gamma delta insertions. Interestingly, two of the selected hybrid plasmids contained the entire phoA-phoB-phoR region of the chromosome, as a multiple copy state of these genes results in the constitutive synthesis of alkaline phosphatase. The presence of multiple copies of the phoM gene hardly influences the level of expression of alkaline phosphatase and PhoE protein in a pho+ strain, but significantly increases the levels of these proteins in a phoR mutant strain.

Isolation and characterization of a new type of Escherichia coli K12 phoB mutants

A new type of Escherichia coli K12 phoB mutant was isolated as 5-fluorouracil-plus-adenosine-resistant derivatives of a upp phoS,T strain. Such phoB mutants (called type III) differ from previously described phoB mutants (types I and II) in the synthesis pattern of phosphate-regulated periplasmic proteins P4a and 30.5 K, sensitivity to toxic compounds, and several other phenotypic characters. The analysis of isogenic strains carrying phoB mutations (type I, II or III) showed that; the phoB gene product exerted (i) a positive control over the synthesis of periplasmic proteins 30.5 K, 11.5 K, and 9 K, inner membrane proteins 32 K and 17.5 K, and outer membrane protein Tsx, (ii) and a direct or indirect negative control over the synthesis of a 20 K phosphate-inducible periplasmic protein.

New pleiotropic alkaline phosphatase-negative mutants of Escherichia coli K-12

Escherichia coli K-12 mutants showing reduced alkaline phosphatase activity were isolated as 5-fluorouracil-plus-adenosine-resistant derivatives of a upp pho (either phoS or phoT) strain. One class of these mutants displayed a temperature-sensitive alkaline phosphatase-negative phenotype, a pleiotropic defect for growth on some substrates, an increased sensitivity to toxic compounds (e.g., EDTA, mitomycin, and chloramphenicol), and alterations in the expression of some membrane proteins. It phenotypically differed from previously described mutants. The mutation was located at min 8.5 close to the phoA gene and defines a new genetic locus we called napA (for negative alkaline phosphatase pleiotropic phenotype). As these mutants have lost the ability to grow on lactose and galactose, Lac+ and Gal+ revertants were isolated that simultaneously recovered the parental phenotype.

The nucleotide sequence of the promoter and the amino-terminal region of alkaline phosphatase structural gene (phoA) of Escherichia coli

The promoter and the amino-terminal region of phoA, the structural gene for alkaline phosphatase of Escherichia coli K12, was cloned by using a promoter cloning vector pMC1403. The nucleotide sequence of the cloned fragment has been determined. A sequence encoding the amino-terminal portion of mature alkaline phosphatase is found and it is preceded by a sequence encoding the signal peptide. The signal peptide consists of 21 amino acids; Met-Lys-Gln-Ser-Thr-Ile-Ala-Leu-Ala-Leu-Leu-Pro-Leu-Leu-Phe-Thr-Pro-Val-Thr-Lys-Ala. The translation initiation codon is GUG, which is preceded by the Shine-Dalgarno sequence GGAG. Upstream to these sequences, there is a typical procaryotic promoter. TATAGTC for the Pribnow box. Around the Pribnow box, there are several dyad symmetrical sequences, which may probably be concerned with the regulation of this gene.

Cloning and characterization of the Escherichia coli gene coding for alkaline phosphatase

The Escherichia coli structural gene for alkaline phosphatase, phoA, and a promoter-like mutant of phoA, called pho-1003(Bin) phoA+, were cloned by using plasmid vectors. Initially, these genes were cloned on deoxyribonucleic acid fragments of 28.9 kilobases (kb). Subsequently, they were subcloned on fragments and 4.8 and then 2.7 kilobases. A restriction map was developed, and phoA was localized to a 1.7-kb region. The promoter end of the gene was inferred by its proximity to another gene cloned on the same deoxyribonucleic acid fragment, proC. The stability of the largest plasmid (33.3 kb) was found to be recA dependent, although the subcloned plasmids were stable in a recA+ strain. Synthesis of alkaline phosphatase directed by the phoA+ and pho-1003(Bin) phoA+ plasmids in a phoA deletion strain was assayed under repressing and derepressing levels of phosphate. These data were compared with the copy numbers of the plasmids. It was found that synthesis of alkaline phosphatase was tightly regulated, even under derepressing conditions: a copy number of 17 enabled cells to synthesize only about twofold more enzyme than did cells with 1 chromosomal copy of phoA+. Enzyme levels were also compared for cells containing pho-1003(Bin) phoA+ and phoA+.

Complementation tests between alkaline phosphatase-constitutive mutants (phoS and phoT) of Escherichia coli

Complementation tests between phoS and phoT mutations showed that they belong to the same cistron. Homozygosis of a heterozygotic partial diploid resulted from allelic transfer from the chromosome to the F' episome.

Outer membrane protein e of Escherichia coli K-12 is co-regulated with alkaline phosphatase

Outer membrane protein e is induced in wild-type cells, just like alkaline phosphatase and some other periplasmic proteins, by growth under phosphatase limitation. nmpA and nmpB mutants, which synthesize protein e constitutively, are shown also to produce the periplasmic enzyme alkaline phosphatase constitutively. Alternatively, individual phoS, phoT, and phoR mutants as well as pit pst double mutants, all of which are known to produce alkaline phosphatase constitutively, were found to be constitutive for protein e. Also, the periplasmic space of most nmpA mutants and of all nmpB mutants grown in excess phosphate was found to contain, in addition to alkaline phosphatase, at least two new proteins, a phenomenon known for individual phoT and phoR mutants as well as for pit pst double mutants. The other nmpA mutants as well as phoS mutants lacked one of these extra periplasmic proteins, namely the phosphate-binding protein. From these data and from the known positions of the mentioned genes on the chromosomal map, it is concluded that nmpB mutants are identical to phoR mutants. Moreover, some nmpA mutants were shown to be identical to phoS mutants, whereas other nmpA mutants are likely to contain mutations in one of the genes phoS, phoT, or pst.

Arsenate-resistant alkaline phosphatase-constitutive mutants of Escherichia coli

When arsenate-resistant mutants are selected approximately 50 per cent of them are also consitutive for the synthesis of alkaline phosphatase and the Pi-binding protein. Some of these mutants are linked to ilv (phoS- or phoT-), other are linked to proC (phoR-). One of the mutant strains linked to ilv lost the Pi-binding protein (the phoS gene product). Resistance to arsenate, constitutivty for alkaline phosphatase synthesis and loss of the Pi-binding protein occurred pleiotropically by the same phoS- mutation.

Repression of alkaline phosphatase in Salmonella typhimurium carrying a phoA+ phoR- episome from Escherichia coli

Salmonella typhimurium does not produce alkaline phosphatase (nor beta-galactosidase). Nevertheless, it has the function of the phoR+ regulatory gene but lacks the function of the lacI+ regulatory gene. Several periplasmic proteins are derepressed when cells of S. typhimurium are starved for inorganic phosphate. The role of phoR is discussed.

Co-regulation of the phosphate-binding protein and alkaline phosphatase synthesis in Escherichia coli

In phosphate-starved cells of Escherichia coli, the synthesis of alkaline phosphatase and some additional periplasmic proteins is derepressed. One of these proteins, which does not appear in a phoS- constitutive strain, has been identified as well the periplasmic phosphate-binding protein.