Definition of the Bacillus subtilis PurR operator using genetic and bioinformatic tools and expansion of the PurR regulon with glyA, guaC, pbuG, xpt-pbuX, yqhZ-folD, and pbuO.

The expression of the pur operon, which encodes enzymes of the purine biosynthetic pathway in Bacillus subtilis, is subject to control by the purR gene product (PurR) and phosphoribosylpyrophosphate. This control is also exerted on the purA and purR genes. A consensus sequence for the binding of PurR, named the PurBox, has been suggested (M. Kilstrup, S. G. Jessing, S. B. Wichmand-Jørgensen, M. Madsen, and D. Nilsson, J. Bacteriol. 180:3900-3906, 1998). To determine whether the expression of other genes might be regulated by PurR, we performed a search for PurBox sequences in the B. subtilis genome sequence and found several candidate PurBoxes. By the use of transcriptional lacZ fusions, five selected genes or operons (glyA, yumD, yebB, xpt-pbuX, and yqhZ-folD), all having a putative PurBox in their upstream regulatory regions, were found to be regulated by PurR. Using a machine-learning algorithm developed for sequence pattern finding, we found that all of the genes identified as being PurR regulated have two PurBoxes in their upstream control regions. The two boxes are divergently oriented, forming a palindromic sequence with the inverted repeats separated by 16 or 17 nucleotides. A computerized search revealed one additional PurR-regulated gene, ytiP. The significance of the tandem PurBox motifs was demonstrated in vivo by deletion analysis and site-directed mutagenesis of the two PurBox sequences located upstream of glyA. All six genes or operons encode enzymes or transporters playing a role in purine nucleotide metabolism. Functional analysis showed that yebB encodes the previously characterized hypoxanthine-guanine permease PbuG and that ytiP encodes another guanine-hypoxanthine permease and is now named pbuO. yumD encodes a GMP reductase and is now named guaC.

Functional analysis of 14 genes that constitute the purine catabolic pathway in Bacillus subtilis and evidence for a novel regulon controlled by the PucR transcription activator.

The soil bacterium Bacillus subtilis has developed a highly controlled system for the utilization of a diverse array of low-molecular-weight compounds as a nitrogen source when the preferred nitrogen sources, e.g., glutamate plus ammonia, are exhausted. We have identified such a system for the utilization of purines as nitrogen source in B. subtilis. Based on growth studies of strains with knockout mutations in genes, complemented with enzyme analysis, we could ascribe functions to 14 genes encoding enzymes or proteins of the purine degradation pathway. A functional xanthine dehydrogenase requires expression of five genes (pucA, pucB, pucC, pucD, and pucE). Uricase activity is encoded by the pucL and pucM genes, and a uric acid transport system is encoded by pucJ and pucK. Allantoinase is encoded by the pucH gene, and allantoin permease is encoded by the pucI gene. Allantoate amidohydrolase is encoded by pucF. In a pucR mutant, the level of expression was low for all genes tested, indicating that PucR is a positive regulator of puc gene expression. All 14 genes except pucI are located in a gene cluster at 284 to 285 degrees on the chromosome and are contained in six transcription units, which are expressed when cells are grown with glutamate as the nitrogen source (limiting conditions), but not when grown on glutamate plus ammonia (excess conditions). Our data suggest that the 14 genes and the gde gene, encoding guanine deaminase, constitute a regulon controlled by the pucR gene product. Allantoic acid, allantoin, and uric acid were all found to function as effector molecules for PucR-dependent regulation of puc gene expression. When cells were grown in the presence of glutamate plus allantoin, a 3- to 10-fold increase in expression was seen for most of the genes. However, expression of the pucABCDE unit was decreased 16-fold, while expression of pucR was decreased 4-fold in the presence of allantoin. We have identified genes of the purine degradation pathway in B. subtilis and showed that their expression is subject to both general nitrogen catabolite control and pathway-specific control.

Introduction: community action research and the prevention of alcohol problems at the local level.

Many community action projects from around the world exist to reduce alcohol problems at the local level. The role of research within this international movement is discussed within this introduction for the entire special issue on community action research in alcohol problem prevention. Previous community prevention programs have utilized a variety of prevention strategies: (a) an educational approach which focuses on changing behavior through changes in knowledge, attitudes, and information; and (b) an environmental approach which focuses on changing behavior through changes in the social and economic systems within a community. Many projects have used both approaches. This special issue provides a current overview of many types of community action projects from different countries and summarizes what has been learned to date from these experiences.

Nucleosides as a carbon source in Bacillus subtilis: characterization of the drm-pupG operon.

In Bacillus subtilis, nucleosides are readily taken up from the growth medium and metabolized. The key enzymes in nucleoside catabolism are nucleoside phosphorylases, phosphopentomutase, and deoxyriboaldolase. The characterization of two closely linked loci, drm and pupG, which encode phosphopentomutase (Drm) and guanosine (inosine) phosphorylase (PupG), respectively, is reported here. When expressed in Escherichia coli mutant backgrounds, drm and pupG confer phosphopentomutase and purine-nucleoside phosphorylase activity. Northern blot and enzyme analyses showed that drm and pupG form a dicistronic operon. Both enzymes are induced when nucleosides are present in the growth medium. Using mutants deficient in nucleoside catabolism, it was demonstrated that the low-molecular-mass effectors of this induction most likely were deoxyribose 5-phosphate and ribose 5-phosphate. Both Drm and PupG activity levels were higher when succinate rather than glucose served as the carbon source, indicating that the expression of the operon is subject to catabolite repression. Primer extension analysis identified two transcription initiation signals upstream of drm; both were utilized in induced and non-induced cells. The nucleoside-catabolizing system in B. subtilis serves to utilize the base for nucleotide synthesis while the pentose moiety serves as the carbon source. When added alone, inosine barely supports growth of B. subtilis. This slow nucleoside catabolism contrasts with that of E. coli, which grows rapidly on a nucleoside as a carbon source. When inosine was added with succinate or deoxyribose, however, a significant increase in growth was observed in B. subtilis. The findings of this study therefore indicate that the B. subtilis system for nucleoside catabolism differs greatly from the well-studied system in E. coli.

Expression of the Methanobacterium thermoautotrophicum hpt gene, encoding hypoxanthine (Guanine) phosphoribosyltransferase, in Escherichia coli.

The hpt gene from the archaeon Methanobacterium thermoautotrophicum, encoding hypoxanthine (guanine) phosphoribosyltransferase, was cloned by functional complementation into Escherichia coli. The hpt-encoded amino acid sequence is most similar to adenine phosphoribosyltransferases, but the encoded enzyme has activity only with hypoxanthine and guanine. The synthesis of the recombinant enzyme is apparently limited by the presence of the rare arginine codons AGA and AGG and the rare isoleucine AUA codon on the hpt gene. The recombinant enzyme was purified to apparent homogeneity.

Purine salvage in two halophilic archaea: characterization of salvage pathways and isolation of mutants resistant to purine analogs.

In exponentially growing cultures of the extreme halophile Halobacterium halobium and the moderate halophile Haloferax volcanii, growth characteristics including intracellular protein levels, RNA content, and nucleotide pool sizes were analyzed. This is the first report on pool sizes of nucleoside triphosphates, NAD, and PRPP (5-phosphoribosyl-alpha-1-pyrophosphate) in archaea. The presence of a number of salvage and interconversion enzymes was determined by enzymatic assays. The levels varied significantly between the two organisms. The most significant difference was the absence of GMP reductase activity in H. halobium. The metabolism of exogenous purines was investigated in growing cultures. Both purine bases and nucleosides were readily taken up and were incorporated into nucleic acids. Growth of both organisms was affected by a number of inhibitors of nucleotide synthesis. H. volcanii was more sensitive than H. halobium, and purine base analogs were more toxic than nucleoside analogs. Growth of H. volcanii was inhibited by trimethoprim and sulfathiazole, while these compounds had no effect on the growth of H. halobium. Spontaneous mutants resistant to purine analogs were isolated. The most frequent cause of resistance was a defect in purine phosphoribosyltransferase activity coupled with reduced purine uptake. A single phosphoribosyltransferase seemed to convert guanine as well as hypoxanthine to nucleoside monophosphates, and another phosphoribosyltransferase had specificity towards adenine. The differences in the metabolism of purine bases and nucleosides and the sensitivity to purine analogs between the two halobacteria were reflected in differences in purine enzyme levels. Based on our results, we conclude that purine salvage and interconversion pathways differ just as much between the two archaeal species as among archaea, bacteria, and eukarya.

Xanthine metabolism in Bacillus subtilis: characterization of the xpt-pbuX operon and evidence for purine- and nitrogen-controlled expression of genes involved in xanthine salvage and catabolism.

The xpt and pbuX genes from Bacillus subtilis were cloned, and their nucleotide sequences were determined. The xpt gene encodes a specific xanthine phosphoribosyltransferase, and the pbuX gene encodes a xanthine-specific purine permease. The genes have overlapping coding regions, and Northern (RNA) blot analysis indicated an operon organization. The translation of the second gene, pbuX, was strongly dependent on the translation of the first gene, xpt. Expression of the operon was repressed by purines, and the effector molecules appear to be hypoxanthine and guanine. When hypoxanthine and guanine were added together, a 160-fold repression was observed. The regulation of expression was at the level of transcription, and we propose that a transcription termination-antitermination control mechanism similar to the one suggested for the regulation of the purine biosynthesis operon exists. The expression of the xpt-pbuX operon was reduced when hypoxanthine served as the sole nitrogen source. Under these conditions, the level of the hypoxanthine- and xanthine-degrading enzyme, xanthine dehydrogenase, was induced more than 80-fold. The xanthine dehydrogenase level was completely derepressed in a glnA (glutamine synthetase) genetic background. Although the regulation of the expression of the xpt-pbuX operon was found to be affected by the nitrogen source, it was normal in a glnA mutant strain. This result suggests the existence of different signalling pathways for repression of the transcription of the xpt-pbuX operon and the induction of xanthine dehydrogenase.

A second form of adenine phosphoribosyltransferase in Arabidopsis thaliana with relative specificity towards cytokinins.

Adenine phosphoribosyltransferase (APRTase) is an important enzyme for its ability to convert adenine, a byproduct of many biochemical reactions, into AMP. By functional complementation of an Escherichia coli mutant, cDNAs encoding two APRTases have been cloned from Arabidopsis thaliana. One of the cDNAs (ATapt1) has been previously identified while the second (ATapt2) is of a previously unknown type. Kinetic analysis of the two enzymes purified from E. coli expressing the two cDNAs indicates that ATapt2 has a higher affinity for cytokinin than the ATapt1. RNase protection studies indicate that the ATapt2, is not expressed in leaves. Analysis of the gene structure indicates that ATapt2 has identical intron positions to ATapt1, but neither the intron sequence nor intron size are conserved between the two genes. The implications of a second, differentially expressed APRTase with affinity for both adenine and cytokinin are discussed.

Role of adenine deaminase in purine salvage and nitrogen metabolism and characterization of the ade gene in Bacillus subtilis.

The isolation of mutants defective in adenine metabolism in Bacillus subtilis has provided a tool that has made it possible to investigate the role of adenine deaminase in adenine metabolism in growing cells. Adenine deaminase is the only enzyme that can deaminate adenine compounds in B. subtilis, a reaction which is important for adenine utilization as a purine and also as a nitrogen source. The uptake of adenine is strictly coupled to its further metabolism. Salvaging of adenine is inhibited by the stringent response to amino acid starvation, while the deamination of adenine is not. The level of adenine deaminase was reduced when exogenous guanosine served as the purine source and when glutamine served as the nitrogen source. The enzyme level was essentially the same whether ammonia or purines served as the nitrogen source. Reduced levels were seen on poor carbon sources. The ade gene was cloned, and the nucleotide sequence and mRNA analyses revealed a single-gene operon encoding a 65-kDa protein. By transductional crosses, we have located the ade gene to 130 degrees on the chromosomal map.

Functional analysis of the Bacillus subtilis purT gene encoding formate-dependent glycinamide ribonucleotide transformylase.

The purT gene from Bacillus subtilis encoding the formate-dependent glycinamide ribonucleotide transformylase T was cloned by functional complementation of an Escherichia coli purN purT double mutant. The nucleotide sequence revealed an open reading frame of 384 amino acids. The purT amino acid sequence showed similarity to the enzyme phosphoribosylaminoimidazole carboxylase encoded by the purK gene but not to the N10-formyltetrahydrofolate-dependent glycinamide ribonucleotide transformylase N enzyme encoded by the purN gene. The glycinamide ribonucleotide transformylase T level was repressed in cells grown in rich medium compared to minimal-medium-grown cells. However, when the culture entered the stationary-growth phase the enzyme level increased in rich medium and decreased in minimal medium. By comparing the deduced amino acid sequence of the B. subtilis purT gene product with translated nucleotide sequences in various databanks, evidence for the existence of putative purT genes in the Gram-negative bacteria Pasteurella haemolytica and Pseudomonas aeruginosa was obtained.

Cloning and characterization of the gsk gene encoding guanosine kinase of Escherichia coli.

The Escherichia coli gsk gene encoding guanosine kinase was cloned from the Kohara gene library by complementation of the E. coli gsk-1 mutant allele. The cloned DNA fragment was sequenced and shown to encode a putative polypeptide of 433 amino acids with a molecular mass of 48,113 Da. Minicell analysis established the subunit M(r) as 43,500. Primer extension analysis indicated the presence of an adequate Pribnow box and suggested that the transcript contained a 110-base leader sequence. Strains harboring the gsk gene on multicopy plasmids overexpressed both guanosine and inosine kinase activities. N-terminal sequence and amino acid composition analyses of the 43,500-M(r) polypeptide band confirmed the correct reading frame assignment and the identity of this band as the gsk gene product. Comparison of the amino acid sequence with the protein database revealed similarity to regions of other mononucleotide-utilizing enzymes.

Molecular characterization of Arabidopsis thaliana cDNAs encoding three purine biosynthetic enzymes.

Glycinamide ribonucleotide (GAR) synthetase, GAR transformylase and aminoimidazole ribonucleotide (AIR) synthetase are the second, third and fifth enzymes in the 10-step de novo purine biosynthetic pathway. From a cDNA library of Arabidopsis thaliana, cDNAs encoding the above three enzymes were cloned by functional complementation of corresponding Escherichia coli mutants. Each of the cDNAs encode peptides comprising the complete enzymatic domain of either GAR synthetase, GAR transformylase or AIR synthetase. Comparisons of the three Arabidopsis purine biosynthetic enzymes with corresponding enzymes/polypeptide-fragments from procaryotic and eucaryotic sources indicate a high degree of conserved homology at the amino acid level, in particular with procaryotic enzymes. Assays from extracts of E. coli expressing the complementing clones verified the specific enzymatic activity of Arabidopsis GAR synthetase and GAR transformylase. Sequence analysis, as well as Northern blot analysis indicate that Arabidopsis has single and monofunctional enzymes. In this respect the organization of these three plant purine biosynthesis genes is fundamentally different from the multifunctional purine biosynthesis enzymes characteristic of other eucaryotes and instead resembles the one gene, one enzyme relationship found in procaryotes.

Genetic and physiological characterization of a formate-dependent 5'-phosphoribosyl-1-glycinamide transformylase activity in Bacillus subtilis.

We have found that Bacillus subtilis possesses a second 5'-phosphoribosyl-1-glycinamide (GAR) transformylase catalysing the first one-carbon transfer reaction in the purine biosynthetic pathway. Inactivation of the purN gene encoding the N10-formyl tetrahydrofolate-dependent enzyme did not result in purine auxotrophy. However, growth of a purN strain was stimulated when either purine or formate was added to the growth medium. In cell-free extracts GAR could be formylated, provided formate was added to the assay mixture. From the purN strain, purine-requiring mutants were isolated. One of these mutant strains was defective in the formate-dependent formylation of GAR in vitro. The gene containing this second mutation was designated purT, and was mapped to approximately 20 degrees on the genetic map between the cysA and aroI markers.

Evidence for a novel glycinamide ribonucleotide transformylase in Escherichia coli.

We demonstrate here that Escherichia coli synthesizes two different glycinamide ribonucleotide (GAR) transformylases, both catalyzing the third step in the purine biosynthetic pathway. One is coded for by the previously described purN gene (GAR transformylase N), and a second, hitherto unknown, enzyme is encoded by the purT gene (GAR transformylase T). Mutants defective in the synthesis of the purN- and the purT-encoded enzymes were isolated. Only strains defective in both genes require an exogenous purine source for growth. Our results suggest that both enzymes may function to ensure normal purine biosynthesis. Determination of GAR transformylase T activity in vitro required formate as the C1 donor. Growth of purN mutants was inhibited by glycine. Under these conditions GAR accumulated. Addition of purine compounds or formate prevented growth inhibition. The regulation of the level of GAR transformylase T is controlled by the PurR protein and hypoxanthine.

Effects of immunomodulators on ecto-5'-nucleotidase activity on blood mononuclear cells in vitro.

In this study the effects of immunomodulators on the ecto-5'-nucleotidase (ecto-5'-NT) activity on blood mononuclear cells (BMC) were examined in vitro. Interleukin-4 (IL-4) and interferon-gamma (IFN-gamma) decreased the level of ecto-5'-NT activity on BMC whereas prostaglandin E2 (PGE2) increased the ecto-5'-NT level. All three immunomodulators influenced the ecto-5'-NT activity of isolated monocytes whereas only IL-4 and PGE2 had an effect on the enzyme level on isolated lymphocytes. The effect was dependent upon protein synthesis. The effect was dose dependent: IL-4 was effective at concentrations down to 0.5 U/ml, IFN-gamma down to 40 U/ml and PGE2 at nanomolar concentrations. These data indicate that immunomodulators may also take part in the regulation of ecto-5'-NT activity on BMC in vivo. BMC from 7 patients with different immunodeficiency syndromes showed decreased ecto-5'-NT activity on freshly isolated cells. However, following culture ecto-5'-NT activity was increased above the level found on freshly isolated BMC from healthy persons. On BMC from 3 patients with hypogammaglobulinaemia, the effect of IL-4 on the level of ecto-5'-NT activity was identical to that found on BMC from healthy donors, whereas PGE2 increased ecto-5'-NT activity on BMC from only 1 of the 3 patients investigated. The decreased ecto-5'-NT activity of BMC from patients with immunodeficiency may thus be due to a defective regulation of ecto-5'-NT activity in vivo.

Regulation of levels of purine biosynthetic enzymes in Bacillus subtilis: effects of changing purine nucleotide pools.

The genes encoding the enzymes of IMP biosynthesis in Bacillus subtilis constitute the pur operon, whereas the genes encoding GMP biosynthetic enzymes, guaA (GMP synthetase) and guaB (IMP dehydrogenase), and the purA gene encoding adenylosuccinate (sAMP) synthetase all occur as single units. The purB gene encodes an enzyme involved in both IMP and AMP biosynthesis and is located in the pur operon. The levels of purine biosynthetic enzymes (except for GMP synthetase) were repressed in cells grown in the presence of purine compounds. Transcription of the pur operon is regulated negatively by adenine and guanine compounds. Our results suggest that ATP and guanine (or hypoxanthine) act as low molecular mass repressors. The level of IMP dehydrogenase was repressed by guanosine, but not in the presence of adenine, and was negatively correlated with the GTP/ATP pools ratio. The level of sAMP synthetase was repressed by adenine and increased by guanosine, and was positively correlated with the GTP/ATP pools ratio. It appears that the mode of regulating purine biosynthetic enzyme levels coincides with the cellular need for the individual enzymes.

Deduced amino acid sequence of Escherichia coli adenosine deaminase reveals evolutionarily conserved amino acid residues: implications for catalytic function.

The goal of the research reported here is to identify evolutionarily conserved amino acid residues associated with enzymatic deamination of adenosine. To do this, we isolated molecular clones of the Escherichia coli adenosine deaminase gene by functional complementation of adenosine deaminase deficient bacteria and deduced the amino acid sequence of the enzyme from the nucleotide sequence of the gene. Nucleotide sequence analysis revealed the presence of a 996-nucleotide open reading frame encoding a protein of 332 amino acids having a molecular weight of 36,345. The deduced amino acid sequence of the E. coli enzyme has approximately 33% identity with those of the mammalian adenosine deaminases. With conservative amino acid substitutions the overall sequence homology approaches 50%, suggesting that the structures and functions of the mammalian and bacterial enzymes are similar. Additional amino acid sequence analysis revealed specific residues that are conserved among all three adenosine deaminases and four AMP deaminases for which sequence information is currently available. In view of previously published enzymological data and the conserved amino acid residues identified in this study, we propose a model to account for the enzyme-catalyzed hydrolytic deamination of adenosine. Potential catalytic roles are assigned to the conserved His 214, Cys 262, Asp 295, and Asp 296 residues of mammalian adenosine deaminases and the corresponding conserved amino acid residues in bacterial adenosine deaminase and the eukaryotic AMP deaminases.

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.

Autoregulation of PurR repressor synthesis and involvement of purR in the regulation of purB, purC, purL, purMN and guaBA expression in Escherichia coli.

The purR gene encodes a repressor (PurR) controlling the synthesis of the enzymes of purine biosynthesis. The subunit of PurR was identified as a 38-kDa polypeptide by SDS/polyacrylamide gel electrophoresis. Analysis of a purR-lacZ transcriptional fusion indicated that purR expression is autoregulated. This was confirmed by gel retardation and DNaseI footprinting experiments, where two PurR-binding sites were identified in the transcribed part of purR. Introduction of a purR mutation in wild-type and pur-lac fusion strains was found to abolish purine repression of all genes of the purine biosynthetic pathway except for purA.