Mutation frequency decline in Escherichia coli B/r after mutagenesis with ethyl methanesulfonate

Nonsense-defective auxotrophic strains of Escherichia coli B/r were used to study mutation frequency decline (MFD) after mutagenesis with ethyl methanesulfonate (EMS). The mutation frequencies for prototrophic revertants that were either converted or de novo glutamine tRNA suppressor mutations declined as treated auxotrophic parental cells were incubated with glucose but without required amino acids (a condition typically producing MFD). The decline for converted suppressor mutations was more rapid than the decline for de novo suppressor mutations after low or moderate EMS treatment, but both suppressor mutation types showed the same slow decline after extensive treatment. The declines for both types of suppressor mutation were eliminated in uvrA-defective cells, and the rapid decline seen for converted suppressor mutations appeared as a slow decline in mfd-defective cells. The results are interpreted that true MFD (the rapid process) affects only the EMS-induced converted glutamine tRNA suppressor mutations. This would account for the rapid decline that is blocked in cells with an mfd defect and in cells with deficient excision repair activity (uvrA or excessive DNA damage). In addition, a second non-specific antimutation mechanism is proposed that is dependent on excision repair only and accounts for the slow decline seen with converted suppressor mutations in some instances and with de novo suppressor mutations at all times. The true MFD mechanism may consist of a physiologically dependent facilitated excision repair specifically for premutational residues located in the transcribed strand of the target DNA sequence (for O6-ethylguanine in cells treated with ethyl methanesulfonate or pyrimidine-pyrimidine photoproducts after UV irradiation).     

Differential repair of premutational UV-lesions at tRNA genes in E. coli.

Summary Ultraviolet radiation produces bacterial revertants that frequently are the result of suppressor mutation. When irradiated cells are incubated under conditions unfavorable for protein synthesis there may be a large decrease in the frequency of observed mutants (mutation frequency decline, or MFD). MFD occurs only in excision-proficient strains and is inhibited by inhibitors of pyrimidine dimer excision. It has therefore been interpreted as enhanced excision of some premutational lesions. Potential de novo UAG suppressor mutation is very susceptible to MFD. Potential conversion mutation, the conversion of a UAG to a UAA suppressor, is at least ten times less susceptible to MFD. A base pair transition at a GC target in a particular tRNA gene is suggested for both de novo suppressor mutation and for conversion mutation. We interpret these results as indicating differential repair of premutational UV photoproducts at two closely spaced sites in the same tRNA gene. The significant difference between these two types of mutation may be the orientation of this target base pair in double helical DNA. The C would be in the transcribed strand of DNA when a nucleic acid alteration produces de novo suppressor mutation. The C would be in the nontranscribed strand, two base pairs removed, when a mutagenic alteration produces suppressor conversion. A model involving facilitated incision by hybridization of the transcribed strand of DNA to its cognate tRNA, under conditions promoting MFD, is described to explain this differential repair.     

Ultraviolet photoproducts at the ochre suppressor mutation site in the glnU gene of Escherichia coli: relevance to "mutation frequency decline"

Summary Ochre suppressor mutations induced by UV in the Escherichia coli glnU tRNA gene are CG to TA transitions at the first letter of the anticodon-encoding triplet, CAA. Premutational UV photoproducts at this site have long been known to exhibit an excision repair anomaly (mutation frequency decline or MFD), whereby post-irradiation inhibition of protein synthesis enhances their excision and reduces suppressor mutation yields ten-fold. We sought to clarify the basis of this unique repair response by determining the spectrum of UV photoproducts on both strands of a 36 by region of glnU which includes the anticodon-encoding triplet. We found that four different photolesions are produced within the 3 by sequence corresponding to the tRNA anticodon: (i) on the transcribed strand, TC (6–4) photoproducts and TC cyclobutane dimers are formed in equal numbers at the site of the C to T transition, indicating that this site is a hotspot for the usually less frequent (6–4) photoproduct; (ii) on the nontranscribed strand, TT dimers are found opposite the second and third letters of the anticodon-encoding triplet, adjacent to the mutation site; and (iii) on the nontranscribed strand, an alkali-sensitive lesion other than a (6–4) photoproduct is formed, apparently at the G in the mutation site. We suggest that mutation frequency decline may reflect excision repair activity at closely spaced UV lesions on opposite strands, resulting in double-strand breaks and the death of potential mutants.     

Plant nonsense suppressor tRNA(Tyr) genes are expressed at very low levels in vitro due to inefficient splicing of the intron-containing pre-tRNAs.

Oligonucleotide-directed mutagenesis was used to generate amber, ochre and opal suppressors from cloned Arabidopsis and Nicotiana tRNA(Tyr) genes. The nonsense suppressor tRNA(Tyr) genes were efficiently transcribed in HeLa and yeast nuclear extracts, however, intron excision from all mutant pre-tRNAs(Tyr) was severely impaired in the homologous wheat germ extract as well as in the yeast in vitro splicing system. The change of one nucleotide in the anticodon of suppressor pre-tRNAs leads to a distortion of the potential intron-anticodon interaction. In order to demonstrate that this caused the reduced splicing efficiency, we created a point mutation in the intron of Arabidopsis tRNA(Tyr) which affected the interaction with the wild-type anticodon. As expected, the resulting pre-tRNA was also inefficiently spliced. Another mutation in the intron, which restored the base-pairing between the amber anticodon and the intron of pre-tRNA(Tyr), resulted in an excellent substrate for wheat germ splicing endonuclease. This type of amber suppressor tRNA(Tyr) gene which yields high levels of mature tRNA(Tyr) should be useful for studying suppression in higher plants.     

The isolation and characterisation of a mutant of Salmonella typhimurium defective in mutation frequency decline

A mutant of Salmonella typhimurium strain trpC3 has been isolated which is defective in mutation frequency decline (MFD) for UV-induced suppressor revertants to tryptophan independence. Several characteristics of this mutant, PW₄, suggest that it is altered in the timing or rate of the general excision repair mechanism. Survival is greater in strain PW₄ when the first post-irradiation cell division is delayed by the inhibition of immediate protein synthesis. Similarly, stationary phase cells, which show an extended lag after irradiation, are more UV-resistant than lag-phase cells, which recover more rapidly. These data are consistent with the hypothesis that, in contrast with the parent strain trpC₃, the time available in the mutant strain for the action of excision repair is critical in the determination of survival after UV treatment. Contransductional analysis of the mutant locus indicates close linkage to metE, a region in which excision repair genes have been located.     

UV mutagenesis in E. coli with excision repair initiated by uvrABC or denV gene products

Mutation frequency responses produced by ultraviolet light are compared in 4 closely related strains of E. coli B/r having the same tyr(Oc) allele and different excision-repair capabilities: uvr+ (excision repair initiated by wild-type UvrABC activity), uvrA (excision repair defective), uvrA/pdenV-7 (excision repair initiated by endonuclease V of bacteriophage T4, DenV activity), and uvr+/pdenV-7 (excision repair initiated by UvrABC and DenV activities). The production of Tyr+ prototrophic mutants is classified into back-mutations and de novo or converted glutamine tRNA suppressor mutations to indicate different mutation events. Cells transformed with the plasmid pdenV-7 require larger exposures than the parent strains to produce comparable mutation frequency responses, indicating that DenV activity can repair mutagenic photoproducts. When damage reduction by UvrABC or DenV is compared for each of the specific categories of mutation, the results are consistent with the idea that pyrimidine dimers infrequently or never target back-mutations of this allele, frequently target the de novo suppressor mutations, and extensively or exclusively target the converted suppressor mutations. This analysis is based on the distinction that UvrABC-initiated excision repair recognizes dimer and non-dimer (pyrimidine (6-4) pyrimidone) photoproducts but that DenV-initiated repair recognizes only pyrimidine dimers.     

Inactivation of nonsense suppressor transfer RNA genes in Schizosaccharomyces pombe. Intergenic conversion and hot spots of mutation

Intergenic conversion is a mechanism for the concerted evolution of repeated DNA sequences. A new approach for the isolation of intergenic convertants of serine tRNA genes in the yeast Schizosaccharomyces pombe is described. Contrary to a previous scheme, the intergenic conversion events studied in this case need not result in functional tRNA genes. The procedure utilizes crosses of strains that are homozygous for an active UGA suppressor tRNA gene, and the resulting progeny spores are screened for loss of suppressor activity. In this way, intergenic convertants of a tRNA gene are identified that inherit varying stretches of DNA sequence from either of two other tRNA genes. The information transferred between genes includes anticodon and intron sequences. Two of the three tRNA genes involved in these information transfers are located on different chromosomes. The results indicate that intergenic conversion is a conservative process. No infidelity is observed in the nucleotide sequence transfers. This provides further evidence for the hypothesis that intergenic conversion and allelic conversion are the result of the same molecular mechanism. The screening procedure for intergenic revertants also yields spontaneous mutations that inactivate the suppressor tRNA gene. Point mutations and insertions of A occur at various sites at low frequency. In contrast, A insertions at one specific site occur with high frequency in each of the three tRNA genes. This new type of mutation hot spot is found also in vegetative cells.     

A new look at adaptive mutations in bacteria

This is a short survey of the adaptive mutation processes that arise in non- or slowly-dividing bacterial cells and includes: (i) bacterial models in which adaptive mutations are studied; (ii) the mutagenic lesions from which these mutations derive; (iii) the influence of DNA repair processes on the spectrum of adaptive mutations. It is proposed that in starved cells, likely as during the MFD phenomenon, lesions in tRNA suppressor genes are preferentially repaired and no suppressor tRNAs are formed as a result of adaptive mutations. Perhaps the most provocative proposal is (iv) a hypothesis that the majority of adaptive mutations are selected in a pre-apoptotic state where the cells are either mutated, selected, and survive, or they die.     

Study of MFD in Bacillus subtilis.

The frequency of UV-induced extragenic suppressor reversions to leucine independence in B. subtilis carrying a leu8 mutation decreased when irradiated cells were temporarily incubated in medium deprived of nitrogen sources. This mutation frequency decline (MFD) was inhibited by acriflavine and was poorly expressed in a uvr1 mutant. Consequently, MFD may be considered as the manifestation of an anti-mutagenic activity of excision repair. MFD was decelerated and even vanished in cells subjected to prolonged starvation of nitrogen sources before irradiation. MFD was accelerated in bacteria that were first irradiated and incubated in nutritional medium for at least 30 min. The stimulation of MFD by UV exposure was observed only in the uvr+ strain and depended on protein synthesis after irradiation. It is assumed that different rates of MFD in cells of various pre-radiation histories reflect different levels of the excision-repair activity inherent in these cells.     

Genomic approaches to DNA repair and mutagenesis

DNA damage is a constant threat to cells, causing cytotoxicity as well as inducing genetic alterations. The steady-state abundance of DNA lesions in a cell is minimized by a variety of DNA repair mechanisms, including DNA strand break repair, mismatch repair, nucleotide excision repair, base excision repair, and ribonucleotide excision repair. The efficiencies and mechanisms by which these pathways remove damage from chromosomes have been primarily characterized by investigating the processing of lesions at defined genomic loci, among bulk genomic DNA, on episomal DNA constructs, or using in vitro substrates. However, the structure of a chromosome is heterogeneous, consisting of heavily protein-bound heterochromatic regions, open regulatory regions, actively transcribed genes, and even areas of transient single stranded DNA. Consequently, DNA repair pathways function in a much more diverse set of chromosomal contexts than can be readily assessed using previous methods. Recent efforts to develop whole genome maps of DNA damage, repair processes, and even mutations promise to greatly expand our understanding of DNA repair and mutagenesis. Here we review the current efforts to utilize whole genome maps of DNA damage and mutation to understand how different chromosomal contexts affect DNA excision repair pathways.     

The broth effect and mutation frequency decline in cells ofEscherichia coli after irradiation with UV-light

Dependence of the broth effeot and the phenomenon of mutation frequency decline on dose of the applied UV radiation was investigated in the strainEscherichia coli B/r Hcr+ thy trp. Reversions to Trp⁺ were followed. The degree of the broth effect and the mutation frequency decline is minimal within the range of UV doses corresponding to a survival of cells lower than 10-1. In connection with the two effects, excision of thymine dimers, initiation of synthesis, synthesis and degradation of DNA were also investigated. It was found that stimulation or inhibition of an inaccurate postreplication repair mechanism, rather than inhibition or stimulation of excision of thymine dimers, are responsible for the broth effect and the mutation frequency decline, respectively.