Histidine Mutants Requiring Adenine: Selection of Mutants with Reduced hisG Expression in SALMONELLA TYPHIMURIUM

A method is described for the selection of Salmonella typhimurium mutants with reduced levels of hisG enzyme activity. This method is based on the fact that the hisG enzyme catalyzes the consumption of ATP in the first step of histidine biosynthesis. Normally, this reaction is closely regulated, both by feedback inhibition and by repression of the operon. However, conditions can be set up that result in the uncontrolled use of adenine in histidine biosynthesis. Cells grown under these conditions become phenotypic adenine auxotrophs. Some revertant clones that no longer require adenine contain mutations in hisG, hisE, or the his-control region. The hisG mutations are of all types (nonsense, frameshift, missense, deletion and leaky types), and they map throughout the hisG gene.     

The role of the excision and error-prone repair systems in mutagenesis by fluorinated quinolones in Salmonella typhimurium

Patterns of reversion produced by ciprofioxacin, enoxacin and ofloxacin in Salmonella typhimurium strains carrying the hisG428 ochre mutation have been studied. These fluorinated quinolones produce a significant increase in reversion of this mutation, even when it is located on the chromosome. Nevertheless, reversion is higher when the hisG428 mutation is on the multicopy plasmid pAQ1 than when it is on the chromosome. Reversion of hisG428 induced by fluorinated quinolones is abolished both in a uvrB genetic background and in the absence of the plasmid pKM101. Therefore, mutagenesis produced by fluorinated quinolones in the Salmonella mutagenicity assay is significantly affected by both the excision repair and the error-prone repair systems. Furthermore, fluorinated quinolones are also detected as moderate mutagens with the base substitution hisG46 mutation when both repair systems are functional in the tester strain.     

Induction of base-pair substitution and prameshift mutations in wild-type and repair-deficient strains of Salmonella typhimurium by the photodynamic action of methylene blue

Induction of back mutations to prototrophy by methylene blue (MB)-sensitized photodynamic (PD) treatment has been studied in wild-type and repair-deficient strains of Salmonella typhimurium carrying either the base-pair substitution mutation hisG46 or the frameshift mutation hisD3052. We found that reversion of the hisG46 mutation was increased in a strain carrying a uvrB deletion and decreased in a strain carrying a recA-type mutation. Reversion of the hisD3052 (frameshift) mutation, on the other hand, was decreased in both uvrB deletion and recA-type strains. The former results are consistent with the hypothesis that the majority of MB-sensitized PD-induced base-pair substitution mutations arise by a mechanism similar to that currently believed to be involved in UV mutagenesis. The latter results suggest that PD-induced frameshift mutations may arise in some other way, and two possible mechanisms involving sequential action of the excision repair and recombinational repair pathways are considered.     

Purification and characterization of a mutant ATP phosphoribosyltransferase hypersensitive to histidine feedback inhibition.

A mutant form of ATP phosphoribosyltranferase (EC 2.4.2.17), hisG1708c, which results in abnormally slow growth of Salmonella typhimurium at 20 °C was purified to homogeneity and kinetic and chemical behavior were characterized. Initial velocity steady-state substrate kinetics of wild-type and mutant enzymes at 37 °C were consistent with sequential kinetics and demonstrated that standard assay concentrations of substrates were sufficient to substantially saturate both enzymes. Nearly time-independent inhibition by histidine at 37 °C could be obtained only after incubation in the presence of product and histidine. Studies at 37 °C showed that the mutant enzyme is 24 times more sensitive to histidine than the wild type in a negatively cooperative manner instead of the positively cooperative manner seen for wild type. Pure mutant enzyme exhibits two major electrophoretic species of native enzyme. Although one less cysteine is titratable in native mutant enzyme, the amino acid compositions of mutant and wild-type enzymes are similar. Histidine produces an ultraviolet difference spectrum in mutant enzyme closely resembling that produced in wild type. Binding of histidyl-tRNA to mutant enzyme is substantially inhibited by histidine. It is concluded that the hisG1708c mutation alters some conformational processes coupled to the histidine binding site while not affecting others.     

Influence of the processing of MucA protein on the reversion of the frameshift hisD3052 and the base substitution hisG46 mutations by chemical mutagens in Salmonella typhimurium

The correlation between the proficiency at promoting mutagenesis of MucA/B proteins and MucA processing has been considered to be very high (Hauser et al., 1992) on the basis of the results of UV mutagenicity (Shiba et al., 1990). Here we show that this correlation is only partial. We have assayed the mutagenicity of benzo[a]pyrene (B[a]P) and aflatoxin B1 (AFB1) in Salmonella typhimurium tester strains containing plasmids which encode MucA proteins with an altered cleavage site. Reversion of the frameshift hisD3052 mutation by B[a]P or AFB1 was observed in the presence of non-cleavable MucA protein although at a lower level than that found in cells containing wild-type MucA protein. Reversion of the base substitution hisG46 mutation by AFB1 requires a significant processing of MucA, while lower levels of this processing would be enough for the hisG46 reversion by B[a]P. These results suggest that the specificity of mutations induced by mutagens forming DNA adducts is influenced by the activity of MucA protein. They also show the relevance of mutagenicity assays in the mechanistic studies of mutagenesis.     

Sequence Analysis of Mutations Arising during Prolonged Starvation of Salmonella Typhimurium

We have examined the effects of prolonged histidine deprivation on the reversion of Salmonella typhimurium histidine auxotrophs containing either hisG46, a missense mutation (CTC----CCC), or hisG428, an ochre mutation (CAA----TAA). Both of these mutants can revert to His+ via intragenic and extragenic mechanisms. Whereas the hisG46 mutant site consists of G/C base pairs, extragenic suppression of hisG46 requires mutation at an A/T site. Conversely, the hisG428 site itself contains only A/T base pairs, and extragenic suppression of hisG428 occurs principally at G/C sites. Thus, by examining the mutational spectrum of hisG46 and hisG428 revertants that occurred in the presence and in the absence of histidine, it was possible to determine the effects of histidine starvation on mutations at G/C vs. A/T sites as well as on intragenic sites vs. extragenic suppressor sites. Using DNA-colony hybridization, we determined the DNA sequences of over 1300 hisG46 and hisG428 revertants. Histidine-independent revertants that arose during growth in liquid medium that contained histidine included both intragenic and extragenic suppressor mutations. The relative frequency of such extragenic suppressors was greatly reduced among the His+ revertants that were isolated after 5-10 days of histidine starvation on agar medium. Moreover, DNA sequence analysis revealed striking differences in the distribution of particular transversions at the hisG428 locus in revertants arising after prolonged histidine starvation as compared to those arising after growth in the presence of histidine.     

Establishment of a Genetic Transformation System and Its Application in Thermoanaerobacter tengcongensis

The whole-genome sequence of Thermoanaerobacter tengcongensis,an anaerobic thermophilic bacterium isolated from the Tengchong hot spring in China,was completed in 2002.However,in vivo studies on the genes of this strain have been hindered in the absence of genetic manipulation system.In order to establish such a system,the plasmid pBOLOl containing the replication origin of the T.tengcongensis chromosome and a kanamycin resistance cassette,in which kanamycin resistance gene expression was controlled by the ttel482 promoter from T.tengcongensis,was constructed and introduced into T.tengcongensis via electroporation.Subsequently,the high transformation efficiency occurred when using freshly cultured T.tengcongensis cells without electroporation treatment,suggesting that T.tengcongensis is naturally competent under appropriate growth stage.A genetic transformation system for this strain was then established based on these important components,and this system was proved to be available for studying physiological characters of T.tengcongensis in vivo by means of hisG gene disruption and complementation.     

Polarity Effects in the Hisg Gene of Salmonella Require a Site within the Coding Sequence

A single site in the middle of the coding sequence of the hisG gene of Salmonella is required for most of the polar effect of mutations in this gene. Nonsense and insertion mutations mapping upstream of this point in the hisG gene all have strong polar effects on expression of downstream genes in the operon; mutations mapping promotor distal to this site have little or no polar effect. Two previously known hisG mutations, mapping in the region of the polarity site, abolish the polarity effect of insertion mutations mapping upstream of this region. New polarity site mutations have been selected which have lost the polar effect of upstream nonsense mutations. All mutations abolishing the function of the site are small deletions; three are identical, 28-bp deletions which have arisen independently. A fourth mutation is a deletion of 16 base pairs internal to the larger deletion. Several point mutations within this 16-bp region have no effect on the function of the polarity site. We believe that a small number of polarity sites of this type are responsible for polarity in all genes. The site in the hisG gene is more easily detected than most because it appears to be the only such site in the hisG gene and because it maps in the center of the coding sequence.     

Phenotypic and reversion analysis of a Salmonella typhimurium constructed to have an arginine codon at the hisG46 missense codon

Of the 6 single-base mutations that would be predicted to change the missense mutation hisG46 away from a proline codon in the Salmonella/microsome mutagen selection assay for histidine-independent revertants, only 5 have been observed. We have used site-specific mutagenesis to make the unobserved mutant [CCC (proline)----CGC (arginine)] codon in the Salmonella genome. Experiments with this arginine mutant demonstrate that, like bacteria containing the hisG46 mutation, bacteria with the arginine missense mutation are histidine auxotrophs which are capable of reversion to histidine independence. However, unlike the ATP phosphoribosyltransferase coded by the hisG46 his G gene (with a proline), the arginine mutant enzyme is partially active. This is indicated by a histidine-independent phenotype when the arginine hisG gene is present in multiple copies.     

Pleiotropic effect of his gene mutations on nitrogen fixation in Klebsiella pneumoniae

Several his mutations were found to influence nitrogen fixation in Klebsiella pneumoniae: hisB, hisC, and hisD mutants had 50% of wild-type levels of nitrogenase activity when supplied with 30 μg or less histidine/ml although this concentration did not limit protein synthesis and the mutants retained a Nif⁺ plate phenotype. A hisA mutation had a similar but more dramatic effect. At low concentrations of histidine the hisA mutant strain had only 5% of the nitrogenase activity found at high histidine concentration or in a his⁺ strain, and was also Nif^- on low histidine agar plates. Addition of adenine restored nitrogenase activity in the hisA but not the hisB, hisC, or hisD mutants. Low levels of intracellular ATP, a consequence of hisG enzyme activity, correlated with loss of nitrogen-fixing ability in the hisA mutant which failed to sustain nif gene expression under these conditions. Synthesis of other major cell proteins was relatively unaffected indicating that nif gene expression is selectively regulated by the energy status of the organism.     

Mutation spectrum of a binary mixture of mutagens (methapyrilene and sodium azide) in strain TA1535 of Salmonella

Methapyrilene (MP) is a rat-liver carcinogen and cocarcinogen that exhibits a narrow spectrum of mutagenic activity in Salmonella typhimurium, inducing only a 2-fold increase in revertants only in the base-substitution strain TA1535; it also enhances the mutagenic activity of sodium azide (NaN₃) in the same strain. To examine the effects of MP at the molecular level, we used the colony probe hybridization procedure dveloped by Cebula and Koch (Mutation Res., 229 (1990) 79–87) to identify the base substitutions in ~800 background, MP-, NaN₃-, and MP + NaN₃-induced revertants of the hisG46 allele of strain Ta1535. The predominant mutation in all 4 mutation spectra was a CCC → CTC transition. the results suggest a mechanism by which MP enhances the infidelity of the DNA replication complex or inhibits a DNA reapir of proofreading function, resulting in the production of more of the same error that occurs normally and that is also induced by NaN₃. Such a mechanism might be the basis for the carcinogenic and cocarcinogenic activities of MP. To our knowledge, this is the first report of the molecular analysis of mutants produced by exposure of cells to a binary mixture of mutagens.     

Molecular cloning and characterisation of the ribC gene from Bacillus subtilis : a point mutation in ribC results in riboflavin overproduction

A mutation leading to roseoflavin resistance and deregulated riboflavin biosynthesis was mapped in the genome of the riboflavin-overproducing Bacillus subtilis strains RB52 and RB50 at map position 147°. The chromosomal location indicates that the deregulating mutation in RB52 and RB50 is an allele of the previously identified ribC mutation. We cloned the ribC gene and found that it encodes a putative 36-kDa protein. Surprisingly, RibC has significant sequence similarity to flavin kinases and FAD synthases from various other bacterial species. By comparing the deduced amino acid sequence of RibC from the wild-type parent strain of RB50 with the RibC sequence from the riboflavin-overexpressing RB50 mutant we identified a point mutation that resulted in a Gly to Ser exchange in the C-terminal region of the product     

Selectable cassettes for simplified construction of yeast gene disruption vectors

Cassettes based on a hisG-URA3-hisG insert have been modified by the addition of a Km^R-encoding gene and flanking polylinker sites, greatly simplifying construction of gene disruption vectors in Escherichia coli. After gene disruption in yeast, URA3 can then be excised by recombination between the hisG repeats flanking the gene, permitting reuse of the URA3 marker     

Enhancement of the mutagenicities of N-methyl-N′-nitro-N-nitrosoguanidine and N-methyl-N-nitrosourea by glucose

The mutagenicity of N-methyl-N′-nitro-N-nitrosoguanidine to Salmonella typhimurium hisG46 was enhanced by pre-incubating the chemical with bacteria in sodium phosphate buffer. Addition of glucose (to 15 mM) to the pre-incubation mixture further enhanced the mutagenicity. Pre-incubation with glucose also increased the mutagenicity of N-methyl-N-nitrosourea. Fructose, galactose, pyruvate and succinate also enhanced the mutagenicity of N-methyl-N′-nitro-N-nitrosoguanidine. The effect of glucose was observed with S. typhimurium strains hisG46, TA1975, TA1950, TA1535 and TA100.     

DNA sequences at the sites of three insertions of the transposable element Tn5 in the histidine operon of Salmonella

Summary The DNA sequence has been determined at the sites of three independent occurrences of the transposable element Tn5 in the hisG gene of the histidine operon. All three insertion sites are adjacent to G+C-rich stretches of DNA. In all three cases sequences at the sites of insertion show homology with a region near the ends of Tn5.     

AICAR is not an endogenous mutagen in Escherichia coli

A number of observations in the Escherichia coli and Salmonella typhimurium literature could be explained by the hypothesis that a particular purine ribonucleotide precursor can be converted to the corresponding deoxyribonucleotide triphosphate, thereby becoming a base-analogue mutagen. The metabolite in question, AICAR (5-amino-4-carboxamide imidazole riboside 5′-phosphate), is also a by-product of histidine biosynthesis, and its (ribo)triphosphate derivative, ZTP, has been detected in E. coli. We constructed E. coli tester strains that had either a normal AICAR pool (pur ⁺ his ⁺ strains cultivated without purines or histidine) or no AICAR pool (purF hisG mutant strains, lacking the first enzyme of each pathway and cultivated in the presence of adenine and histidine). Using a set of lacZ mutations, each of which can revert to Lac⁺ only by a specific substitution mutation, we found that no base substitution event occurs at a higher frequency in the presence of an AICAR pool. We conclude that the normal AICAR pool in E. coli is not a significant source of spontaneous base substitution mutagenesis.     

Suppression Analysis Reveals a Functional Difference between the Serines in Positions Two and Five in the Consensus Sequence of the C-Terminal Domain of Yeast RNA Polymerase II

The largest subunit of RNA polymerase II contains a repetitive C-terminal domain (CTD) consisting of tandem repeats of the consensus sequence Tyr(1)Ser(2)Pro(3)Thr(4) Ser(5)Pro(6) Ser(7). Substitution of nonphosphorylatable amino acids at positions two or five of the Saccharomyces cerevisiae CTD is lethal. We developed a selection ssytem for isolating suppressors of this lethal phenotype and cloned a gene, SCA1 (suppressor of CTD alanine), which complements recessive suppressors of lethal multiple-substitution mutations. A partial deletion of SCA1 (sca1Δ::hisG) suppresses alanine or glutamate substitutions at position two of the consensus CTD sequence, and a lethal CTD truncation mutation, but SCA1 deletion does not suppress alanine or glutamate substitutions at position five. SCA1 is identical to SRB9, a suppressor of a cold-sensitive CTD truncation mutation. Strains carrying dominant SRB mutations have the same suppression properties as a sca1Δ::hisG strain. These results reveal a functional difference between positions two and five of the consensus CTD heptapeptide repeat. The ability of SCA1 and SRB mutant alleles to suppress CTD truncation mutations suggest that substitutions at position two, but not at position five, cause a defect in RNA polymerase II function similar to that introduced by CTD truncation.