Gene-enzyme relationships of aromatic acid biosynthesis in Bacillus subtilis

Mutants have been isolated which correspond to every step concerned with the biosynthesis of the aromatic amino acids in Bacillus subtilis. Each mutant has been characterized, and the lesion it bore was analyzed by deoxyribonucleic acid transformation and PBS-1 mediated transduction. The biochemical analysis revealed that each of the mutations appears to have affected a single enzyme, except for two groups of pleiotropic mutations. All aroF mutants (chorismic acid synthetase) lack dehydroquinic acid synthetase (aroB) activity. The gene that specifies aroB is closely linked to the gene coding for the aroF enzyme. Both genes are a part of the aro cluster. Mutants lacking chorismate mutase activity also lack d-arabino-heptulosonic acid-7-phosphate synthetase and shikimate kinase activity, presumably as a result of these three activities forming a multi-enzyme complex. Another mutant, previously undescribed, had been isolated. The affected gene codes for the tyrosine and phenylalanine aminotransferase activity. All of the mutations have been located on the B. subtilis genome except those in the genes specifying shikimate kinase activity and tyrosine-phenylalanine aminotransferase activity.     

Genetic characterization of an Escherichia coli mutant altered in the structure of murein lipoprotein.

Mutants defective in the structure, biosynthesis, and assembly of murein lipoprotein have been isolated. One of these mutants has been shown to synthesize a structurally altered lipoprotein. The biochemical features of the mutant lipoprotein (lipid deficiency, dimer formation, and a reduced, bound form of lipoprotein) could be attributed to a single mutation (or closely linked mutations) located at 36.4 min of the Escherichia coli map. We propose that this mutant is altered in the structural gene for murein lipoprotein (mlpA). Biochemical studies carried out with a heterogenote, mlpA/F'mlpA+, revealed the biochemical codominance of the wild-type and mutant genes.     

The structural gene for NADP L-glutamate dehydrogenase in Aspergillus nidulans.

A total of 41 mutants lacking NADP L-glutamate dehydrogenase (NADP-GDH) activity have been studied. All the mutations were located at the gdhA locus within 0-1% recombination of gdhAI. Two mutants, gdhAI and gdhA2, out of five examined, produced cross-reacting material which neutralized NADP-GDH anti-serum. The mutant gdhA9 has altered Km values for all five substrates: ammonium, alpha-ketoglutarate, l-glutamate, NADPH and NADP. The mutant gdhA20 had temperature-sensitive growth, abnormal ammonium-regulation characteristics and thermolabile NADP-GDH activity. These results show that gdhA is the structural gene for NADP-GDH.     

Selection of SALMONELLA TYPHIMURIUM Mutants with Altered Serine Transhydroxymethylase Regulation

In Salmonella typhimurium the glyA gene product, serine transhydroxymethylase (E.C. 2.1.2.1.; L-serine:tetrahydrofolate-5,10-hydroxymethyltransferase) is responsible for the interconversion of serine and glycine. This reaction also provides the cell with one-carbon units from the 5,10-methylene-tetrahydrofolate formed during glycine synthesis. Despite the importance of this enzyme, however, no mutants in which its regulation has been specificially altered have been isolated. To isolate such mutants, we have devised a selection procedure using a strain (glyA951) in which the serine transhydroxymethylase activity is reduced. When this enzyme is completely repressed, the mutant requires gylcine for growth. Revertants which retain the glyA951 lesion, but no longer require glycine, have been isolated and the serine transhydroxymethylase regulation examined. One revertant has a 7-fold elevated serine transhydroxymethylase level, which can be repressed the normal amount (about 5-fold) when the cells are grown in supplemented media. Another revertant has only a 2-fold higher serine transhydroxymethylase level; however, the amount of repression is reduced. The new lesions in both mutants cotransduce with the glyA gene and are distinct from other mutations that alter the regulation of both serine transhydroxymethylase and the methionine biosyntheitc enzymes.     

Structural gene for ornithine decarboxylase in Neurospora crassa.

To define the structural gene for ornithine decarboxylase (ODC) in Neurospora crassa, we sought mutants with kinetically altered enzyme. Four mutants, PE4, PE7, PE69, and PE85, were isolated. They were able to grow slowly at 25 degrees C on minimal medium but required putrescine or spermidine supplementation for growth at 35 degrees C. The mutants did not complement with one another or with ODC-less spe-1 mutants isolated in earlier studies. In all of the mutants isolated to date, the mutations map at the spe-1 locus on linkage group V. Strains carrying mutations PE4, PE7, and PE85 displayed a small amount of residual ODC activity in extracts. None of them had a temperature-sensitive enzyme. The enzyme of the PE85 mutant had a 25-fold higher Km for ornithine (5mM) than did the enzyme of wild-type or the PE4 mutant (ca. 0.2 mM). The enzyme of this mutant was more stable to heat than was the wild-type enzyme. These characteristics were normal in the mutant carrying allele PE4. The mutant carrying PE85 was able to grow well at 25 degrees C and weakly at 35 degrees C with ornithine supplementation. This mutant and three ODC-less mutants isolated previously displayed a polypeptide corresponding to ODC in Western immunoblots with antibody raised to purified wild-type ODC. We conclude that spe-1 is the structural gene for the ODC.     

L-Methionine SR-sulfoximine-resistant glutamine synthetase from mutants of Salmonella typhimurium

Two mutants of Salmonella typhimurium resistant to growth inhibition by the glutamine synthetase transition state analog, L-methionine SR-sulfoximine, were isolated and characterized. These mutants are glutamine bradytrophs and cannot use growth rate-limiting nitrogen sources. Although this phenotype resembles that of mutants with lesions in the regulatory gene for glutamine synthetase, glnG, these mutations do not lie in the glnG gene. Purification and characterization of the glutamine synthetase from one of the mutants and a control strain demonstrated that the mutant enzyme is defective in the reverse gamma-glutamyltransferase activity but has biosynthetic activity that is resistant to inhibition by L-methionine SR-sulfoximine. The mutant enzyme also has a 4.4-fold higher apparent Km for glutamate (0.2 mM versus 2.1 mM, respectively) and a 13.8-fold higher Km for NH3 (6.4 mM versus 0.46 mM) than the enzyme from the control. These data show that the glutamine synthetase protein has been altered by this mutation, designated as glnA982, and suggest that the L-methionine SR-sulfoximine resistance is conferred by a change in the NH3 binding domain of the enzyme.     

Mutations affecting glutamine synthetase activity in Salmonella typhimurium.

A positive selection procedure has been devised for isolating mutant strains of Salmonella typhimurium with altered glutamine synthetase activity. Mutants are derived from a histidine auxotroph by selecting for ability to grow on D-histidine as the sole histidine source. We hypothesize that the phenotype may be based on a regulatory increase in the activities of the D-histidine racemizing enzymes, but this has not been established. Spontaneous glutamine-requiring mutants isolated by the above selection procedure have two types of alterations in glutamine synthetase activity. Some have less than 10% of parent activity. Others have significant glutamine synthetase activity, but the enzyme have an altered response to divalent cations. Activity in mutants of the second type mimics that of highly adenylylated wild-type enzyme, which is believed to be in-active in vivo. Glutamine synthetase from one such mutant is more heat labile than wild-type enzyme, indicating that it is structurally altered. Mutations in all strains are probably in the glutamine synthetase structural gene (glnA). They are closely linked on the Salmonella chromosome and lie at about min 125. The mutants have normal glutamate dehydrogenase activity.     

Genetic evidence for a multi-subunit complex in the O-methyltransferase steps of coenzyme Q biosynthesis

Coq3 O-methyltransferase carries out both O-methylation steps in coenzyme Q (ubiquinone) biosynthesis. The degree to which Coq3 O-methyltransferase activity and expression are dependent on the other seven COQ gene products has been investigated. A panel of yeast mutant strains harboring null mutations in each of the genes required for coenzyme Q biosynthesis (COQ1-COQ8) have been prepared. Mitochondria have been isolated from each member of the yeast coq mutant collection, from the wild-type parental strains and from respiratory deficient mutants harboring deletions in ATP2 or COR1 genes. These latter strains constitute Q-replete, respiratory deficient controls. Each of these mitochondrial preparations has been analyzed for COQ3-encoded O-methyltransferase activity and steady state levels of Coq3 polypeptide. The findings indicate that the presence of the other COQ gene products is required to observe normal levels of O-methyltransferase activity and the Coq3 polypeptide. However, COQ3 steady state RNA levels are not decreased in any of the coq mutants, relative to either wild-type or respiratory deficient control strains, suggesting either a decreased rate of translation or a decreased stability of the Coq3 polypeptide. These data are consistent with the involvement of the Coq polypeptides (or the Q-intermediates formed by the Coq polypeptides) in a multi-subunit complex. It is our hypothesis that a deficiency in any one of the COQ gene products results in a defective complex in which the Coq3 polypeptide is rendered unstable.     

Ubiquitin metabolism affects cellular response to volatile anesthetics in yeast

To investigate the mechanism of action of volatile anesthetics, we are studying mutants of the yeast Saccharomyces cerevisiae that have altered sensitivity to isoflurane, a widely used clinical anesthetic. Several lines of evidence from these studies implicate a role for ubiquitin metabolism in cellular response to volatile anesthetics: (i) mutations in the ZZZ1 gene render cells resistant to isoflurane, and the ZZZ1 gene is identical to BUL1 (binds ubiquitin ligase), which appears to be involved in the ubiquitination pathway; (ii) ZZZ4, which we previously found is involved in anesthetic response, is identical to the DOA1/UFD3 gene, which was identified based on altered degradation of ubiquitinated proteins; (iii) analysis of zzz1Delta zzz4Delta double mutants suggests that these genes encode products involved in the same pathway for anesthetic response since the double mutant is no more resistant to anesthetic than either of the single mutant parents; (iv) ubiquitin ligase (MDP1/RSP5) mutants are altered in their response to isoflurane; and (v) mutants with decreased proteasome activity are resistant to isoflurane. The ZZZ1 and MDP1/RSP5 gene products appear to play important roles in determining effective anesthetic dose in yeast since increased levels of either gene increases isoflurane sensitivity whereas decreased activity decreases sensitivity. Like zzz4 strains, zzz1 mutants are resistant to all five volatile anesthetics tested, suggesting there are similarities in the mechanisms of action of a variety of volatile anesthetics in yeast and that ubiquitin metabolism affects response to all the agents examined.     

Mannosyltransferase is required for cell wall biosynthesis, morphology and control of asexual development in Neurospora crassa

Two Neurospora mutants with a phenotype that includes a tight colonial growth pattern, an inability to form conidia and an inability to form protoperithecia have been isolated and characterized. The relevant mutations were mapped to the same locus on the sequenced Neurospora genome. The mutations responsible for the mutant phenotype then were identified by examining likely candidate genes from the mutant genomes at the mapped locus with PCR amplification and a sequencing assay. The results demonstrate that a map and sequence strategy is a feasible way to identify mutant genes in Neurospora. The gene responsible for the phenotype is a putative alpha-1,2-mannosyltransferase gene. The mutant cell wall has an altered composition demonstrating that the gene functions in cell wall biosynthesis. The results demonstrate that the mnt-1 gene is required for normal cell wall biosynthesis, morphology and for the regulation of asexual development.     

Histidyl-transfer ribonucleic acid synthetase mutants requiring a high internal pool of histidine for growth

Mutants that require histidine due to an altered structural gene for the histidyl-transfer ribonucleic acid synthetase (hisS) have been isolated by a general selection for histidine-requiring strains in which the mutation producing histidine auxotrophy is unlinked to the histidine operon. One of the mutants has been shown to require an abnormally high internal histidine pool for growth owing to an altered synthetase that is unstable at low histidine concentrations. It is difficult to determine accurately the K(m) for histidine of the synthetase enzyme from the mutant because of the instability of the enzyme at limiting histidine concentrations; however, a histidine K(m) value has been estimated that is approximately 100 times higher than the histidine K(m) of the wild-type enzyme. For the mutant strains to achieve the high internal pool of histidine required for growth, all the systems that transport histidine from the growth medium must be functioning to capacity. Amino acids that interfere with histidine transport strongly inhibit the growth of the mutants. The mutants have been useful in providing a selective genetic marker for transductional mapping in the hisS region. The mutants are discussed as representative of a general class of curable mutants that have an altered enzyme with poor affinity for a substrate or coenzyme.     

Glutamine synthetase/glutamate synthase ammonium-assimilating pathway in Schizosaccharomyces pombe

Kinetic parameters of glutamine synthetase (GS) and glutamate synthase (glutamineoxoglutarate aminotransferase) (GOGAT) activities, including initial velocity, pH, and temperature optima, as well as K _m values, were estimated in Schizosaccharomyces pombe crude cell-free extracts. Five glutamine auxotrophic mutants of S. pombe were isolated following MNNG treatment. These were designated gln1-1,2,3,4,5, and their growth could be repaired only by glutamine. Mutants gln1-1,2,3,4,5 were found to lack GS activity, but retained wild-type levels of NADP-glutamate dehydrogenase (GDH), NAD-GDH, and GOGAT. One further glutamine auxotrophic mutant, gln1-6, was isolated and found to lack both GS and GOGAT but retained wild-type levels of NADP-GDH and NAD-GDH activities. Fortuitously, this isolate was found to harbor an unlinked second mutation (designated gog1-1), which resulted in complete loss of GOGAT activity but retained wild-type GS activity. The growth phenotype of mutant gog1-1 (in the absence of the gln1-6 mutation) was found to be indistinguishable from the wild type on various nitrogen sources, including ammonium as a sole nitrogen source. Double-mutant strains containing gog1-1 and gdh1-1 or gdh2-1 (mutations that result specifically in the abolition of NADP-GDH activity) result in a complete lack of growth on ammonium as sole nitrogen source in contrast to gdh or gog mutants alone.     

Saccharomyces cerevisiae mutants with enhanced induced mutation and altered mitotic gene conversion

We have developed a method to isolate yeast (Saccharomyces cerevisiae) mutants with enhanced induced mutagenesis based on nitrous acid-induced reversion of the ade2-42 allele. Six mutants have been isolated and designated him (high induced mutagenesis), and 4 of them were studied in more detail. The him mutants displayed enhanced reversion of the ade2-42 allele, either spontaneous or induced by nitrous acid, UV light, and the base analog 6-N-hydroxylaminopurine, but not by gamma-irradiation. It is worth noting that the him mutants turned out not to be sensitive to the lethal effects of the mutagens used. The enhancement in mutation induced by nitrous acid, UV light, and 6-N-hydroxylaminopurine has been confirmed in a forward-mutation assay (induction of mutations in the ADE1, ADE2 genes). The latter agent revealed the most apparent differences between the him mutants and the wild-type strain and was, therefore, chosen for the genetic analysis of mutants, him mutations analyzed behaved as a single Mendelian trait; complementation tests indicated 3 complementation groups (HIM1, HIM2, and HIM3), each containing 1 mutant allele. Uracil-DNA glycosylase activity was determined in crude cell extracts, and no significant differences between the wild-type and him strains were detected. Spontaneous mitotic gene conversion at the ADE2 locus is altered in him1 strains, either increased or decreased, depending on the particular heteroallelic combination. Genetic evidence strongly suggests him mutations to be involved in a process of mismatch correction of molecular heteroduplexes.     

Genes involved in caryogamy and meiosis in Podospora anserina

Summary Ten new mutants affected during caryogamy and first meiotic prophase have been isolated in Podospora anserina. They belong to nine loci, and only one mutant is allelic with a gene previously known. The loci are distributed on six of the seven linkage groups. The precise moment where meiosis is blocked or altered has been studied by light microscopy for each mutant. Several of them have a pleiotropic phenotype which suggests that the altered functions involved in meiotic process in these mutants are also involved in vegetative growth.The systematic search of meiotic mutants in P. anserina permitted the identification of twelve genes involved during first meiotic prophase. The time of gene action and the nature of the controled steps are discussed.     

Influence of methionine biosynthesis on serine transhydroxymethylase regulation in Salmonella typhimurium LT2.

The enzyme serine transhydroxymethylase (EC 2.1.2.1; L-serine:tetrahydrofolate-5,10-hydroxymethyltransferase) is responsible both for the synthesis of glycine from serine and production of the 5,10-methylenetetrahydrofolate necessary as a methyl donor for methionine synthesis. Two mutants selected for alteration in serine transhydroxymethylase regulation also have phenotypes characteristic of metK (methionine regulatory) mutants, including ethionine, norleucine, and alpha-methylmethionine resistance and reduced levels of S-adenosylmethionine synthetase (EC 2.5.1.6; adenosine 5'-triphosphate:L-methionine S-adenosyltransferase) activity. Because this suggested the existence of a common regulatory component, the regulation of serine transhydroxymethylase was examined in other methionine regulatory mutants (metK and metJ mutants). Normally, serine transhydroxymethylase levels are repressed three- to sixfold in cells grown in the presence of serine, glycine, methionine, adenine, guanine, and thymine. This does not occur in metK and metJ mutants; thus, these mutations do affect the regulation of both serine transhydroxymethylase and the methionine biosynthetic enzymes. Lesions in the metK gene have been reported to reduce S-adenosylmethionine synthetase levels. To determine whether the metK gene actually encodes for S-adenosylmethionine synthetase, a mutant was characterized in which this enzyme has a 26-fold increased apparent Km for methionine. This mutation causes a phenotype associated with metK mutants and is cotransducible with the serA locus at the same frequency as metK lesions. Thus, the affect of metK mutations on the regulation of glycine and methionine synthesis in Salmonella typhimurium appears to be due to either an altered S-adenosylmethionine synthetase or altered S-adenosylmethionine pools.     

On the role of the single-stranded DNA binding protein of bacteriophage T4 in DNA metabolism. I. Isolation and genetic characterization of new mutations in gene 32 of bacteriophage T4

Summary The product of gene 32 of bacteriophage T4 is a single-stranded DNA binding protein involved in T4 DNA replication, recombination and repair. Functionally differentiated regions of the gene 32 protein have been described by protein chemistry. As a preliminary step in a genetic dissection of these functional domains, we have isolated a large number of missense mutants of gene 32. Mutant isolation was facilitated by directed mutagenesis and a mutant bacterial host which is unusually restrictive for missense mutations in gene 32. We have isolated over 100 mutants and identified 22 mutational sites. A physical map of these sites has been constructed and has shown that mutations are clustered within gene 32. The possible functional significance of this clustering is considered.