Nucleotide mutations in purA gene and pur operon promoter discovered in guanosine- and inosine-producing Bacillus subtilis strains

The promoter region of the pur operon, which contains 12 genes for inosine monophosphate biosynthesis from phosphoribosylpyrophosphate, and the purA gene, encoding the adenylosuccinate synthetase, were compared among wild-type and three purine-producing Bacillus subtilis strains. A single nucleotide deletion at position 55 (relative to translation start site) in purA gene was found in a high inosine-producing strain and in a high guanosine-producing strain, which correlates with the absence of adenylosuccinate synthetase activity in these strains. Within the pur operon promoter of high guanosine-producing strain, in addition to a single nucleotide deletion in PurBox1 and a single nucleotide substitution in PurBox2, there were 4 substitutions in the flanking region of the PurBoxes and 32 nucleotide mutations in the 5′ untranslated region. These mutations may explain the purine accumulation in purine-producing strains and be helpful to the rational design of high-yield recombinant strains.     

Mutations in the Bacillus subtilis Purine Repressor That Perturb PRPP Effector Function In Vitro and In Vivo

The Bacillus subtilis pur operon repressor (PurR) has a PRPP (5-phosphoribosyl 1-pyrophosphate) binding motif at residues 199–211. Two PurR PRPP binding region mutations (D203A and D204A) were constructed, and the effects on binding of repressor to the pur operon control site in vitro and on regulation of pur operon expression in vivo were investigated. PRPP significantly inhibited the binding of wild-type but not mutant PurR to pur operon control site DNA. In strains with the D203A and D204A mutations, pur operon expression in vivo was super-repressed by addition of adenine to the growth medium. These results support the role of PRPP in modulating the regulatory function of PurR in vivo. YabJ, the product of the distal gene in the bicistronic purR operon, is also required for PurR function in vivo. Received: 5 January 2000 / Accepted: 9 February 2000     

Gene-enzyme relationships of the purine biosynthetic pathway in Bacillus subtilis

Summary The gene-enzyme relationship has been established for most of the steps of the purine de novo biosynthetic pathway in Bacillus subtilis. The synthesis of inosine monophosphate (IMP) involves ten steps, and the branching from IMP to AMP and to guanosine monophoshate (GMP) synthesis both require two steps. To avoid confusion in the nomenclature of the pur genes we have adopted the Escherichia coli system for B. subtilis. The two genes specifying the enzymes catalysing the conversion of IMP to succinyl-AMP (purA), and the conversion of IMP to xanthosine monophosphate (guaB), occur as single units whilst the other purine genes are clustered at 55 degrees on the B. subtilis linkage map. Based on transformation and transduction studies, and on complementation studies using B. subtilis pur genes cloned in plasmids, the arrangement of some of the clustered genes has been determined relative to outside markers. The following gene order has been established: pbuG-purB-purF-purM-purH-purD-tre. Three other genes were also found to be located in the cluster, guaA, purL and purE/C. However, we were not able to find their exact location. When the purF, purM, purD and purB genes of B. subtilis are present in plasmids they are capable of directing the synthesis in E. coli of phosphoribosylpyrophosphate amidotransferase (purF), aminoimidazole ribonucleotide synthetase (purM), glycinamide ribonucleotide synthetase (purD) and adenylosuccinate lyase (purB), respectively.     

New Purine Markers in Bacillus subtilis

Four new genetic markers involved in purine biosynthesis in Bacillus subtilis are clustered and lie between purE and tre. An additional new pur marker is located near purA.     

Occurrence of a regulatory deficiency in purine biosynthesis among purA mutants of Salmonella typhimurium

Summary A defect in the repression of the de novo purine biosynthetic enzymes was detected among purA mutants of Salmonella typhimurium. We suggest that the defect is caused by an altered purine regulation gene (purR) which affects the response level of at least five of the de novo enzymes to repression by excess adenine. Thus the unlinked genes controlling these enzymes constitute a regulation controlled wholly or in part by a purR gene product. The regulation of the guanine operon is regulated by some other mechanism independent of purR.     

Purine Regulon of Gamma-Proteobacteria: A Detailed Description

The structure of the purine regulon was studied by a comparative genomic approach in seven genomes of gamma-proteobacteria: Escherichia coli, Salmonella typhimurium, Yersinia pestis, Haemophilus influenzae, Pasteurella multocida, Actinobacillus actinomycetemcomitans, and Vibrio cholerae. The palindromic binding site of the purine repressor (consensus ACGCAAACGTTTGCGT) is fairly well conserved upstream genes encoding enzymes that participate in the synthesis of inosine monophosphate from phosphoribozylpyrophosphate and in transfer of one-carbon units, and also upstream of some transport protein genes. These genes may be regarded as the main part of the purine regulon. In terms of physiology, the regulation of the purC and gcvTHP/folD genes seems to be especially important, because the PurR site was found upstream nonorthologous but functionally replaceable genes. However, the PurR site is poorly conserved upstream orthologs of some genes belonging to the E. coli purine regulon, such as genes involved in general nitrogen metabolism, biosynthesis of pyrimidines, and synthesis of AMP and GMP from IMP, and also upstream of the purine repressor gene. It is predicted that purine regulons of the examined bacteria include the following genes: upp participating in synthesis of pyrimidines; uraA encoding an uracil transporter gene; serA involved in serine biosynthesis; folD responsible for the conversion of N5,N10-methenyl tetrahydrofolate into N10-formyltetrahydrofolate; rpiA involved in ribose metabolism; and genes with an unknown function (yhhQ and ydiK). The PurR site was shown to have different structure in different genomes. Thus, the tendency for a decline of the conservatism of site positions 2 and 15 was observed in genomes of bacteria belonging to the Pasteurellaceae and Vibrionaceae groups.     

Identification of hypoxanthine and guanine as the co-repressors for the purine regulon genes of Escherichia coli

Addition of purine compounds to the growth medium of Escherichia coli and Salmonella typhimurium causes repressed synthesis of the purine biosynthetic enzymes. The repression is mediated through a regulatory protein, PurR. To identify the co-repressor(s) of PurR, two approaches were used: (i) mutations were introduced into purine salvage genes and the effects of different purines on pur gene expression were determined; (ii) purine compounds which dictate the binding of the PurR protein to its operator DNA were resolved by gel retardation. Both the in vivo and the in vitro data indicated that guanine and hypoxanthine are co-repressors. The toxic purine analogues 6-mercaptopurine and 6-thioguanine also activated the binding of PurR to its operator DNA.     

Structural characterization and corepressor binding of the Escherichia coli purine repressor.

The Escherichia coli purine repressor, PurR, binds to a 16-bp operator sequence and coregulates the genes for de novo synthesis of purine and pyrimidine nucleotides, formation of a one-carbon unit for biosynthesis, and deamination of cytosine. We have characterized the purified repressor. Chemical cross-linking indicates that PurR is dimeric. Each subunit has an N-terminal domain of 52 amino acids for DNA binding and a C-terminal 289-residue domain for corepressor binding. Each domain was isolated after cleavage by trypsin. Sites for dimer formation are present within the corepressor binding domain. The corepressors hypoxanthine and guanine bind cooperatively to distinct sites in each subunit. Competition experiments indicate that binding of one purine abolishes cooperativity and decreases the affinity and the binding of the second corepressor. Binding of each corepressor results in a conformation change in the corepressor binding domain that was detected by intrinsic fluorescence of three tryptophan residues. These experiments characterize PurR as a complex allosteric regulatory protein.     

Nitrate reductase and cytochrome bnitrate reductase structural genes as parts of the nitrate reductase operon

Summary The existence of a nitrate-reductase operon in the tryptophane region was deduced from the effects of prophage insertion in each of chl I and chl C genes and from transposition of the Mu-mediated host DNA fragments on F-prime. This operon appears to be polarized from chlC to chlI and the gene order in the region is trp-chlI-chlC-purB.