Sigenobu Kimura

Regulation of the phosphate regulon of Escherichia coli: Activation of pstS transcription by PhoB protein in vitro☆

Expression of the genes in the phosphate regulon, including the pstS (phoS) and phoB genes, is positively regulated by PhoB protein when phosphate is limited. We purified PhoB protein from overproducing cells and studied its interaction with the pstS gene. It binds specifically to the DNA fragment containing the promoter region of pstS. The transcription initiation site of the gene in vivo was identified by S1 nuclease mapping and primer-extension experiments. In-vitro transcription of pstS was activated by the PhoB protein, and the initiation site of transcription agreed with the in-vivo initiation site. Activation of in-vitro transcription by PhoB protein required both the normal sigma factor (sigma 70) and core RNA polymerase. PhoB protein binding sites on the promoter regions of pstS and phoB were determined by footprinting experiments with DNase I and a methylating agent. In both cases the protein binds to the pho box, the concensus sequence shared by regulatory regions of genes in the phosphate regulon. Our findings indicate that PhoB protein recognizes and binds to the pho box and activates transcription of the genes in the phosphate regulon.

Complete nucleotide sequence of the prophage VT1-Sakai carrying the Shiga toxin 1 genes of the enterohemorrhagic Escherichia coli O157: H7 strain derived from the Sakai outbreak.

Shiga toxins 1 and 2 (Stx1 and Stx2) are encoded by prophages lysogenized in enterohemorrhagic Escherichia coli (EHEC) O157:H7 strains. Lytic growth of the phage particles carrying the stx1 genes (stx1A and stx1B) of the EHEC O157:H7 strain RIMD 0509952, which was derived from the Sakai outbreak in 1996 in Japan, was induced after treatment with mitomycin C, but the plaque formation of the phage was not detected. We have determined the complete nucleotide sequence of the prophage VT1-Sakai. The integration site of the prophage was identified within the yehV gene at 47.7 min on the chromosome. The stx1 genes were downstream of the Q gene in the prophage genome, suggesting that their expression was regulated by the Q protein, the regulator of the late gene expression of the phage, which is similar to that of the stx1 or stx2 genes carried by the lambdoid phages reported previously. The sequences of the N gene and its recognition sites, nutL and nutR, were not homologous to those of the phages carrying the stx genes thus far reported, but they were very similar to those of bacteriophage phi21. The sequences of the repressor proteins, CI and Cro, that regulate expression of the early genes had low similarities with those of the known repressors of other phages, and their operator sequences were different from any sequence reported. These data suggest that multiple genetic recombination among bacteriophages with different immunities took place to generate the prophage VT1-Sakai. Comparison between the sequences of VT1-Sakai and lambda suggests that the ancestor of VT1-Sakai was produced by illegitimate excision, like lambda gal and bio phages.

Identification of the human beta-actin enhancer and its binding factor.

An enhancer of the human beta-actin gene and a factor that specifically interacts with it were detected. A mobility shift assay showed that the factor bound to the 25-base-pair sequence (between +759 and +783 downstream from the cap site) with high specificity. This finding correlated with those of DNase I protection and exonuclease III digestion assays. This binding region of the beta-actin enhancer contained a hyphenated dyad symmetry and an enhancer core-like sequence. In vitro competition experiments indicated that the factor did not bind to the simian virus 40 enhancer core region.

Regulation of the phosphate regulon of Escherichia coli: Characterization of the promoter of the pstS gene

SummaryThe pstS gene belongs to the phosphate regulon whose expression is induced by phosphate starvation and regulated positively by the PhoB protein. The phosphate (pho) box is a consensus sequence shared by the regulatory regions of the genes in the pho regulon. We constructed two series of deletion mutations in a plasmid in vitro, with upstream and downstream deletions in the promoter region of pstS, which contains two pho boxes in tandem, and studied their promoter activity by connecting them with a promoterless gene for chloramphenicol acetyltransferase. Deletions extending into the upstream pho box but retaining the downstream pho box greatly reduced promoter activity, but the remaining activity was still regulated by phosphate levels in the medium and by the PhoB protein, indicating that each pho box is functional. No activity was observed in deletion mutants which lacked the remaining pho box or the-10 region. Therefore, the pstS promoter was defined to include the two pho boxes and the-10 region. The PhoB protein binding region in the pstS regulatory region was studied with the deletion plasmids by a gelmobility retardation assay. The results suggest the protein binds to each pho box on the pstS promoter. A phoB deletion mutant was constructed, and we demonstrated that expression of pstS was strictly dependent on the function of the PhoB protein.

Dual Transcriptional Regulation of the Escherichia coli Phosphate-Starvation-Inducible psiE Gene of the Phosphate Regulon by PhoB and the Cyclic AMP (cAMP)-cAMP Receptor Protein Complex

We have shown that the Escherichia coli phosphate-starvation-inducible psiE gene is regulated by both phosphate and the carbon source by using both lacZ and chloramphenicol acetyltransferase gene (cat) fusions. Yet, under all conditions tested, a single transcriptional start site lying 7 bp downstream of a predicted -10 region was revealed by primer extension analysis. DNase I footprinting showed that the PhoB transcriptional-activator protein protects two predicted pho boxes lying upstream of and near the -35 promoter region. Similar analysis showed that the cyclic AMP (cAMP)-cAMP receptor protein (cAMP-CRP) complex binds a region that overlaps with the downstream pho box. These results, together with measurements of the in vivo psiE promoter activity under various conditions, show that expression of the psiE gene is under direct positive and negative control by PhoB and cAMP-CRP, respectively.