Specificity of mutation by UV light and delayed photoreversal in umuC-defective Escherichia coli K-12: a targeting intermediate at pyrimidine dimers.

Prototrophic mutants produced by UV light in Escherichia coli K-12 strains with argE3(Oc) and hisG4(Oc) defects are distinguished as backmutations and specific nonsense suppressor mutations. In strains carrying a umuC defect, mutants are not produced unless irradiated cells are incubated and then exposed to photoreversing light (delayed photoreversal mutagenesis). The mutants thus produced are found to be specifically suppressor mutations and not backmutations. The suppressor mutations are primarily glutamine tRNA ochre suppressor mutations, which have been attributed previously to mutation targeted at T = C pyrimidine dimers. In a lexA51 recA441 strain, where the SOS mutagenesis functions are constitutive, targeting at dimers is confirmed by demonstrating that the induction of glutamine tRNA suppressor mutations is susceptible to photoreversal. In the same strain induction of backmutations is not susceptible to photoreversal. Thus delayed photoreversal mutagenesis produces suppressor mutations that can be targeted at pyrimidine dimers and does not produce backmutations that are not targeted at pyrimidine dimers. This correlation supports the idea that delayed photoreversal mutagenesis in umuC defective cells reflects a mutation process arrested at a targeting pyrimidine dimer photoproduct, which is the immediate cause of both the alteration in DNA sequence and the obstruction (unless repaired) to mutation fixation and ultimate expression.     

Mutators in SACCHAROMYCES CEREVISIAE: MUT1–1, MUT1–2 and MUT2–1

The purpose of this study was to characterize two mutator stocks of yeast which were induced and selected on the basis of high spontaneous reversion rates of the suppressible "ochre" nonsense allele lys1-1. In the mutator stock VA-3, a single mutation, designated mut1-1, is responsible for the increase in the reversion rate of the ochre alleles lys1-1 and arg4-17. In stock VA-105, there are two separate mutator mutations. Tetrad analysis data showed these two loci are loosely linked. Based on complementation data, one of these mutations is at the same locus as mut1-1 and designated mut1-2. The second mutator of stock VA-105 was designated mut2-1. All three mutators are recessive. Both mut1-1 and mut1-2 give a high mutation rate for ochre nonsense suppressor (SUP) loci, but not for the ochre nonsense alleles. On the contrary, the mutation rates of the ochre alleles are greatly reduced. With the mutant mut2-1 there were mutations at both the lys1-1 site and its suppressors; mut2-1 is as effective as mut1-2 but not as effective as mut1-1 in inducing reversions of a missense mutant, his1-7. Neither mut1-1, mut1-2 nor mut2-1 were effective in inducing reversions of a putative frameshift mutation, hom3-10, or in inducing forward mutations to canavanine resistance.     

Anti-mutagenic effect of ultraviolet light on spontaneous tyrosine tRNA ochre suppressor mutations in Escherichia coli

Summary The numbers of tyrosine tRNA ochre suppressor mutations arising spontaneously or after UV irradiation in different strains of Escherichia coli K12 are considered. The DNA sequence change requisite for this type of mutation would be a transversion at a cytosine between two purines, where pyrimidine-pyrimidine photoproducts could not form. We find that UV mutagenesis does not produce these tyrosine tRNA ochre suppressor mutations. With lexA51 recA441 defective cells, the spontaneous yield of these mutations is elevated and UV irradiation produces a significant decrease in the numbers of this particular mutation. As explanation we suggest that the spontaneous appearance of these mutations reflects mutation at apurinic sites, the efficiency of which is elevated in lexA51 recA441 cells (with derepressed SOS functions and an activated form of RecA protein). The addition of UV damage in the DNA of these cells cannot further stimulate the positive functions that are required for the production of these mutations and are typically associated with UV mutagenesis (induction of SOS functions, activation of RecA protein and introduction of a targeting photoproduct) but apparently can have a negative effect on mutagenesis, hitherto not realized.     

Kinetics of Mutation Induction by Ultraviolet Light in Excision-Deficient Yeast

We have measured the frequency of UV-induced reversions (locus plus suppressor) for the ochre alleles ade2-1 and lys2-1 and forward mutations (ade2 adex double auxotrophs) in an excision-deficient strain of Saccharomyces cerevisiae (rad2-20). For very low UV doses, both mutational systems exhibit linear induction kinetics. However, as the dose increases, a strikingly different response is observed: in the selective reversion system a transition to higher order induction kinetics occurs near 9 ergs/mm2 (25% survival), whereas in the nonselective forward system the mutation frequency passes through a maximum near 14 ergs/mm2 (4.4% survival) and then declines. This contrast in kinetics cannot be explained in any straightforward way by current models of induced mutagenesis, which have been developed primarily on the basis of bacterial data. The bacterial models are designed to accommodate the quadratic induction kinetics that are frequently observed in these systems. We have derived a mathematical expression for mutation frequency that enables us to fit both the forward and reversion data on the assumptions that mutagenesis is basically a "single event" Poisson process, and that mutation and killing are not necessarily independent of one another. In particular, the dose-response relations are consistent with the idea that the sensitivity of the revertants is about 25% less than that of the original cell population, whereas the sensitivity of the forward mutants is about 29% greater than the population average. We argue that this relatively small differential sensitivity of mutant and nonmutant cells is associated with events that take place during mutation expression and clonal growth.     

Nonsense Mutations in Essential Genes of Saccharomyces Cerevisiae

A new method for isolating nonsense mutations in essential yeast genes has been used to develop a collection of 115 ochre mutations that define 94 complementation groups. The mutants are isolated in a genetic background that includes an ochre suppressor on a metastable plasmid and a suppressible colony-color marker on a chromosome. When the parental strain is plated on a rich medium, the colonies display a pattern of red, plasmid-free sectors on a white background. Mutants containing an ochre mutation in any essential yeast gene give rise to nonsectoring, white colonies, since cell growth is dependent on the presence of the plasmid-borne suppressor. Analysis of the data suggests that mutations are being recovered from a pool of approximately 250 genes.     

Genetic Characterization of the SufJ Frameshift Suppressor in SALMONELLA TYPHIMURIUM

A new suppressor of +1 frameshift mutations has been isolated in Salmonella typhimurium. This suppressor, sufJ, maps at minute 89 on the Salmonella genetic map between the argH and rpo(rif) loci, closely linked to the gene for the ochre suppressor tyrU(supM). The suppressor mutation is dominant to its wild-type allele, consistent with the suppressor phenotype being caused by an altered tRNA species. The sufJ map position coincides with that of a threonine tRNA(ACC/U) gene; the suppressor has been shown to read the related fourbase codons ACCU, ACCC, ACCA.--The ability of sufJ to correct one particular mutation depends on the presence of a hisT mutation which causes a defect in tRNA modification. This requirement is allele specific, since other frameshift mutations can be corrected by sufJ regardless of the state of the hisT locus.--Strains carrying both a sufJ and a hisT mutation are acutely sensitive to growth inhibition by uracil; the inhibition is reversed by arginine. This behavior is characteristic of strains with mutations affecting the arginine-uracil biosynthetic enzyme carbamyl phosphate synthetase. The combination of two mutations affecting tRNA structure may reduce expression of the structural gene for this enzyme (pyrA).     

Gene Conversion and Intragenic Recombination at at the SUP6 Locus and the Surrounding Region in SACCHAROMYCES CEREVISIAE

Spontaneous secondary mutations of the ochre suppressor SUP6 were selected in a haploid strain of Saccharomyces cerevisiae . Unselected tetrads were dissected from crosses heterozygous for one of three alleles of SUP6 and for three other loci in this region which span a length of 14 map units (his2, cdc14 and met10). The study showed that all of these markers were characterized by high frequency of meiotic gene conversion and long conversion lengths which frequently extended into adjacent marked loci. Despite the high conversion frequency of SUP6 , recombination between alleles of this locus reached a maximum frequency of only 2 x 10^-3 prototrophs/spore. Although the allelic recombination frequencies were not distance dependent and consequently could not be used to order the alleles, the inequality between the two recombinant outside marker combinations among selected intragenic recombinants produced an internally consistent map of the suppressor locus. Recombination at SUP6 (whether detected as conversion in tetrads or the production of recombinants among random spores) was accompanied by significantly less than 50% outside marker recombination.     

A Genetic Characterization of the Nadc Gene of Salmonella Typhimurium

The nadC gene of Salmonella encodes the pyridine biosynthetic enzyme PRPP-quinolinate phosphoribosyltransferase. Using a combination of genetic techniques, a deletion map for the Salmonella nadC gene has been generated which includes over 100 point mutants and 18 deletion intervals. The nadC alleles obtained by hydroxylamine mutagenesis include those suppressed by either amber, ochre, or UGA nonsense suppressors as well as alleles suppressed by the missense suppressor, sumA. Deletions were obtained by three separate protocols including spontaneous selection for loss of the nearby aroP gene, recombination between aroP::MudA and nadC::MudA insertion alleles, and selection for spontaneous loss of tetracycline resistance in a nearby guaC::Tn10dTc insertion mutant allele. The nadC mutants comprise one complementation group and the nadC+ allele is dominant to simple, nadC auxotrophic mutant alleles. Intragenic complementation of two nadC alleles, nadC493 and nadC494, mapping to deletion intervals 17 and 18, respectively, suggests that nadC encodes a multimeric enzyme. Both nadC and the nearby aroP locus are transcribed counterclockwise on the standard genetic map of Salmonella, in opposite orientation to the direction of chromosome replication.     

Effects of multiple yeast rad3 mutant alleles on UV sensitivity, mutability, and mitotic recombination.

A yeast strain was constructed that had a disruption of the chromosomal RAD3 gene and carried a series of centromeric plasmids with defined mutations in this gene. Using this isogenic collection, we examined sensitivity to UV radiation, spontaneous and UV radiation-induced mutagenesis, and mitotic recombination. Several alleles resulted in a marked increase in UV sensitivity. Most of these alleles were found to carry mutations located in consensus motifs for DNA helicases. Other alleles caused a modest or no increase in UV sensitivity and carried mutations in regions of the Rad3 polypeptide that are apparently not conserved. This correlation suggests that the DNA helicase activity of Rad3 protein is required for nucleotide excision repair of DNA. Some rad3 alleles conferred a marked increase in the frequency of spontaneous mutagenesis, including nonsuppressor reversion of the lys2-1 ochre mutation. These alleles also showed a good correlation with conserved DNA helicase domains, suggesting that the Rad3 DNA helicase also plays a role in the fidelity of DNA synthesis or postreplicative mismatch correction. Several rad3 mutator alleles also resulted in increased levels of mitotic recombination. Increased spontaneous mutagenesis and mitotic recombination are characteristic features of the Rem- phenotype. However, in contrast to the prototypic Rem- phenotype, the rad3 mutator alleles identified in this study did not confer inviability in the presence of mutations in the RAD50 or RAD52 gene required for strand break repair of DNA.     

Gene RAD31 is identical to gene MEC1 of yeast Saccharomyces cerevisiae

The earlier identified gene RAD31 was mapped on the right arm of chromosome II in the region of gene MEC1 localization. Epistatic analysis demonstrated that the rad31 mutation is an allele of the MEC1 gene, which allows further designation of the rad31 mutation as mec1-212. Mutation mec1-212, similar to deletion alleles of this gene, causes sensitivity to hydroxyurea, disturbs the check-point function, and suppresses UV-induced mutagenesis. However, this mutation significantly increases the frequency of spontaneous canavanine-resistance mutations induced by disturbances in correcting errors of DNA replication and repair, which distinguishes it from all identified alleles of gene MEC1.     

Gene <Emphasis Type="Italic">RAD31</Emphasis> is identical to gene <Emphasis Type="Italic">MEC1</Emphasis> of yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The earlier identified gene RAD31 was mapped on the right arm of chromosome II in the region of gene MEC1 localization. Epistatic analysis demonstrated that the rad31 mutation is an allele of the MEC1 gene, which allows further designation of the rad31 mutation as mec1-212. Mutation mec1-212, similar to deletion alleles of this gene, causes sensitivity to hydroxyurea, disturbs the check-point function, and suppresses UV-induced mutagenesis. However, this mutation significantly increases the frequency of spontaneous canavanine-resistance mutations induced by disturbances in correcting errors of DNA replication and repair, which distinguishes it from all identified alleles of gene MEC1.     

Close Linkage Between Ochre and Missense Suppressors in Escherichia coli

It was previously shown that the ochre suppressor mutation sup15B in Escherichia coli determines the accumulation of altered 30S ribosomal subunits and the presence of altered transfer ribonucleic acid (tRNA) capable of suppressing in vitro the UAG codon. This mutation has been mapped in the present study by means of conjugation and transduction experiments. After establishing the location of sup15B near argH, the following order was determined for the markers tested: metB-argH-(sup15B, supA36)-rif-thi. A comparison of location, growth rate, and suppressor pattern determined by sup15B and supM indicates the high probability that both suppressor mutations are identical. This study has also yielded a more precise location for the rifampin resistance gene. The most interesting finding is the very close (if not adjacent) location of the suppressor mutations sup15B and supA36, both of which determine tRNA alterations.     

Nonsense Mutants in the rII A Cistron of Bacteriophage T4

After in vitro treatment of bacteriophage T4 with hydroxylamine (HA), 54 nonsense mutants in the rII A cistron were isolated. These mutants were characterized by growth on suppressor strains of Escherichia coli, and the mutational sites were mapped in the rII A cistron. Twenty-five (9 sites) were amber (UAG), 20 (6 sites) were opal (UGA), and 9 (6 sites) were ochre (UAA). Mapping experiments further indicated that there were three closely linked pairs of amber and opal mutations, conceivably involving mutations occurring in adjacent nucleotides. Based on the specificity of HA mutagenesis (GC → AT), the amino acid codons in which the mutations occurred have been inferred. It is suggested that the three amber-opal pairs arose in tryptophan codons (UGG) and the six ochre mutants arose in glutamine codons (CAA). The six unpaired ambers and the three unpaired opals have been tentatively assigned to glutamine codons (CAG) and arginine codons (CGA), respectively, in the wild-type phage.     

Site-specific mutagenesis of Escherichia coli gltT yields a weak, glutamic acid-inserting ochre suppressor

Of all the Escherichia coli tRNA genes that can give rise to an amber or an ochre suppressor by a single-nucleotide mutation, only the tRNAGlu genes have not been observed to do so. A study of the relationship between the sequences of tRNAs and the codons they translate predicts that the ochre suppressor derived from tRNAGlu would function very poorly on the ribosome. We have used site-specific mutagenesis to create the gene for such a tRNA in order to test this prediction. We cloned the tRNAGlu-Suoc gene into a high copy number plasmid, under control of the lacUV5 promoter. The mutant tRNA suppresses both amber and ochre nonsense mutations. As predicted, it is less efficient than other suppressors expressed under similar conditions.     

Bacillus subtilis mutant allele sup-3 causes lysine insertion at ochre codons: use of sup-3 in studies of translational attenuation.

The mutation sup-3 in Bacillus subtilis suppresses ochre (TAA) mutations at each of three codons in the 5' end of the cat-86 coding sequence. The suppressor is shown to insert lysine at ochre codons. The efficiency of suppression by sup-3 is about 15%, as determined by changing a cat-86 Lys codon (codon 12) to an ochre codon and measuring the level of CAT in the suppressor-containing strain. The results obtained are discussed in light of previous observations that ochre mutations at cat leader codons 2 and 3 can be phenotypically suppressed by sup-3, whereas ochre mutations at leader codons 4 and 5 cannot. Translation of the cat leader is essential to inducible expression of cat. Our data support the interpretation that the nature of amino acids 2 through 5 of the leader peptide contributes to determining whether chloramphenicol can stall a ribosome in the leader, which in turn leads to induction of cat expression.     

Ribosomal assembly deficiency in an Escherichia coli thermosensitive mutant having an altered L24 ribosomal protein.

Localized P1 mutagenesis was used to screen for conditionally lethal mutations in ribosomal protein genes. One such mutation, 2859mis, has been mapped inside the ribosomal protein gene cluster at 72 minutes on the Escherichia coli chromosome and cotransduces at 98% with rpsE (S5). The 2869mis mutation leads to thermosensitivity and impaired assembly in vivo of 50 S ribosomal particles at 42 °C. The strain carrying the mutation has an altered L24 ribosomal protein which at 42 °C shows weaker affinity for 23 S RNA than the wild-type protein. The mutational alteration involves a replacement of glycine by aspartic acid in protein L24 from the mutant. We conclude therefore that the 2859mis mutation affects the structural gene for protein L24 (rplX).     

Mutational spectrum analysis of umuC-independent and umuC-dependent gamma-radiation mutagenesis in Escherichia coli

gamma-Radiation mutagenesis (oxic versus anoxic) was examined in wild-type, umuC and recA strains of Escherichia coli K-12. Mutagenesis [argE3(Oc)----Arg+] was blocked in a delta (recA-srlR)306 strain at the same doses that induced mutations in umuC122::Tn5 and wild-type strains, indicating that both umuC-independent and umuC-dependent mechanisms function within recA-dependent misrepair. Analyses of various suppressor and back mutations that result in argE3 and hisG4 ochre reversion and an analysis of trpE9777 (+1 frameshift) reversion were performed on umuC and wild-type cells irradiated in the presence and absence of oxygen. While the umuC strain showed the gamma-radiation induction of base substitution and frameshifts when irradiated in the absence of oxygen, the umuC mutation blocked all oxygen-dependent base-substitution mutagenesis, but not all oxygen-dependent frameshift mutagenesis. For anoxically irradiated cells, the yields of GC----AT [i.e., at the supB and supE (Oc) loci] and AT----GC transitions (i.e., at the argE3 and hisG4 loci) were essentially umuC independent, while the yields of (AT or GC)----TA transversions (i.e., at the supC, supL, supM, supN and supX loci) were heavily umuC dependent. These data suggest new concepts about the nature of the DNA lesions and the mutagenic mechanisms that lead to gamma-radiation mutagenesis.