Adaptive reversions of a frameshift mutation in arrested Saccharomyces cerevisiae cells by simple deletions in mononucleotide repeats

Adaptive mutations are characterised as the outcome of an as yet unknown mechanism, which allows a few individuals of a cell population to overcome a starvation-induced cell cycle arrest and to proliferate. A release from such a non-lethal growth limitation is accomplished by mutations generated without DNA replication. Originally adaptive mutations were described in Escherichia coli, but more recently also in a simple eukaryote, the budding yeast Saccharomyces cerevisiae. We are studying the adaptive reversion of a frameshift allele which occurs when an auxotrophic yeast strain is starved for the amino acid essential for its proliferation. In this communication, we report on the DNA sequences from the locus concerned. Comparison between sequences from revertant clones which arose several days after growth arrest by starvation and those from revertants produced during proliferation shows significantly different mutation spectra: for replication-dependent revertants nucleotide gains and losses in a variety of sequence contexts are reasonably balanced, whereas for the replication-independent, i.e. adaptive, revertants mainly simple deletions in mononucleotide repeats were observed. These mutations resemble those known to originate from DNA polymerase slippage errors which were miscorrected or had escaped correction by the mismatch repair machinery. Our data present strong evidence for differences in the mechanistic origins of adaptive versus DNA replication-dependent mutations in a eukaryote. Most probably, mutations in non-replicating cells contribute to evolution, and if conserved in mammals, to human carcinogenesis.     

Replication-dependent and selection-induced mutations in respiration-competent and respiration-deficient strains of Saccharomyces cerevisiae

Adaptive or selection-induced mutations are defined as mutations that occur in non-dividing cells as a response to prolonged non-lethal selective pressure such as starvation for an essential amino acid. In the absence of DNA replication, the processing of endogenous DNA lesions by repair enzymes probably acts as a source of mutations. We are studying selection-induced reversions of frameshift alleles in the eukaryote Saccharomyces cerevisiae. Here we show that respiration-deficient strains, totally devoid of mitochondrial DNA, yield selection-induced mutants at slightly elevated frequencies compared to isonucleic respiration-competent strains. Therefore factors of mitochondrial origin such as reactive oxygen species or hypothetical recombinogenic DNA fragments are unlikely to be mediators of selection-induced nuclear frameshift mutation in yeast. Furthermore we compared sequence spectra of reversions of the +1 hom3-10 frameshift allele and found a strong preference for ?1 deletions in mononucleotide repeats in selection-induced and replication-dependent revertants, indicating slippage errors during DNA repair synthesis as well as during DNA replication. Remarkably, a higher degree of variation in the site of the reverting frameshift and accompanying base substitutions was found among selection-induced revertants.     

适应性突变的遗传学特征

基于大肠杆菌FC40菌株的研究结果表明,适应性突变依赖RecBCD重组途径的酶,要求SOS反应的部分基因功能,lac+回复突变序列都是在单核苷酸短重复序列处的一个碱基缺失。有证据表明有的适应性突变来自一个或多个暂时性的超突变的细胞亚群,它们的基因组发生大量的突变,转座子高频丢失。产生这种暂时性的超突变的增变子可能是因为细胞的MMR活性暂时不足,或是因错误翻译产生丧失了校读活性的DNA聚合酶III。其他一些研究系统虽然得到了一些同FC40菌株不一致的结论,但所有实验证据都表明,在饥饿等环境胁迫因子作用下,非生长或缓慢生长的细胞可以产生突变,这种突变具有生长依赖的自发突变所不同的一些遗传学特征。 Abstract:The research based on the Escherichia coli FC40 showed that adaptive mutations required the enzymes of RecBCD recombination pathway and some unknown proteins of SOS response,and the mutation spectrum of lac+ revertants is single-base deletions in the small mononucleotide repeats.Some evidence showed that the revertants with adaptive mutations partly come from one (or some) subset of transient hypermutable subpopulation of cells,in which high frequently losing of transposons and genome-wide mutations were observed.It was suggested that this kind of transient hypermutability may be due to the transient deficient activity of mismatch repair (MMR) system,or a defective epsilon unit of DNA polymerase III generated by mistranslation.Although other systems demonstrated some different mechanisms from FC40,all research works suggested that,adaptive mutations occurred in nondividing or nongrowing cells under environmental stresses,for example,starvation,displayed different genetic features from growth-dependent spontaneous mutation.     

Replication-dependent and selection-induced mutations in respiration-competent and respiration-deficient strains of Saccharomyces cerevisiae

Adaptive or selection-induced mutations are defined as mutations that occur in non-dividing cells as a response to prolonged non-lethal selective pressure such as starvation for an essential amino acid. In the absence of DNA replication, the processing of endogenous DNA lesions by repair enzymes probably acts as a source of mutations. We are studying selection-induced reversions of frameshift alleles in the eukaryote Saccharomyces cerevisiae. Here we show that respiration-deficient strains, totally devoid of mitochondrial DNA, yield selection-induced mutants at slightly elevated frequencies compared to isonucleic respiration-competent strains. Therefore factors of mitochondrial origin such as reactive oxygen species or hypothetical recombinogenic DNA fragments are unlikely to be mediators of selection-induced nuclear frameshift mutation in yeast. Furthermore we compared sequence spectra of reversions of the +1 hom3-10 frameshift allele and found a strong preference for −1 deletions in mononucleotide repeats in selection-induced and replication-dependent revertants, indicating slippage errors during DNA repair synthesis as well as during DNA replication. Remarkably, a higher degree of variation in the site of the reverting frameshift and accompanying base substitutions was found among selection-induced revertants. Received: 25 May 1998 / Accepted: 20 August 1998     

Molecular handles on adaptive mutation

In one experimental system, several handles on the molecular mechanism of apparent adaptive mutation have emerged. The system is reversion of a lac frame-shift mutation in Escherichia coli . The molecular handles include a requirement for homologous recombination; the implication of DNA double-strand breaks as a molecular intermediate; a unique sequence spectrum of −1 deletions in mononucleotide repeats which implies polymerase errors, and also implies a failure of post-synthesis mismatch repair on those errors; and the involvement of sexual functions at some stage of the process. These molecular handles are revealing an unexpected new mechanism of mutagenesis.     

Non-homologous end joining as an important mutagenic process in cell cycle-arrested cells

Resting cells experience mutations without apparent external mutagenic influences. Such DNA replication-independent mutations are suspected to be a consequence of processing of spontaneous DNA lesions. Using experimental systems based on reversions of frameshift alleles in Saccharomyces cerevisiae, we evaluated the impact of defects in DNA double-strand break (DSB) repair on the frequency of replication-independent mutations. The deletion of the genes coding for Ku70 or DNA ligase IV, which are both obligatory constituents of the non-homologous end joining (NHEJ) pathway, each resulted in a 50% reduction of replication-independent mutation frequency in haploid cells. Sequencing indicated that typical NHEJ-dependent reversion events are small deletions within mononucleotide repeats, with a remarkable resemblance to DNA polymerase slippage errors. Experiments with diploid and RAD52- or RAD54-deficient strains confirmed that among DSB repair pathways only NHEJ accounts for a considerable fraction of replication-independent frameshift mutations in haploid and diploid NHEJ non-repressed cells. Thus our results provide evidence that G(0) cells with unrepressed NHEJ capacity pay for a large-scale chromosomal stability with an increased frequency of small-scale mutations, a finding of potential relevance for carcinogenesis.     

Are adaptive mutations due to a decline in mismatch repair? The evidence is lacking

The levels of proteins required for methyl-directed mismatch repair appear to decline in stationary-phase and nutritionally-deprived cells of Escherichia coli. It has been hypothesized that error-correction by the system also declines, and this decline is responsible for adaptive or stationary-phase mutations. However, evidence in support of this hypothesis is lacking. The mismatch repair system is no less effective in correcting errors during prolonged selection than it is during growth. Furthermore, mismatch repair proteins supplied in excess reduce both growth-dependent and adaptive mutation.     

Escherichia coli mutator (Delta)polA is defective in base mismatch correction: the nature of in vivo DNA replication errors

We constructed a set of Escherichia coli strains containing deletions in genes encoding three SOS polymerases, and defective in MutS and DNA polymerase I (PolI) mismatch repair, and estimated the rate and specificity of spontaneous endogenous tonB(+)-->tonB- mutations. The rate and specificity of mutations in strains proficient or deficient in three SOS polymerases was compared and found that there was no contribution of SOS polymerases to the chromosomal tonB mutations. MutS-deficient strains displayed elevated spontaneous mutation rates, consisting of dominantly minus frameshifts and transitions. Minus frameshifts are dominated by warm spots at run-bases. Among 57 transitions (both G:C-->A:T and A:T-->G:C), 35 occurred at two hotspot sites. PolI-deficient strains possessed an increased rate of deletions and frameshifts, because of a deficiency in postreplicative deletion and frameshift mismatch corrections. Frameshifts in PolI-deficient strains occurred within the entire tonB gene at non-run and run sequences. MutS and PolI double deficiency indicated a synergistic increase in the rate of deletions, frameshifts and transitions. In this case, mutS-specific hotspots for frameshifts and transitions disappeared. The results suggested that, unlike the case previously known pertaining to postreplicative MutS mismatch repair for frameshifts and transitions and PolI mismatch repair for frameshifts and deletions, PolI can recognize and correct transition mismatches. Possible mechanisms for distinct MutS and PolI mismatch repair are discussed. A strain containing deficiencies in three SOS polymerases, MutS mismatch repair and PolI mismatch repair was also constructed. The spectrum of spontaneous mutations in this strain is considered to represent the spectrum of in vivo DNA polymerase III replication errors. The mutation rate of this strain was 219x10(-8), about a 100-fold increase relative to the wild-type strain. Uncorrected polymerase III replication errors were predominantly frameshifts and base substitutions followed by deletions.     

The Escherichia coli histone-like protein HU has a role in stationary phase adaptive mutation

Stationary phase adaptive mutation in Escherichia coli is thought to be a mechanism by which mutation rates are increased during stressful conditions, increasing the possibility that fitness-enhancing mutations arise. Here we present data showing that the histone-like protein, HU, has a role in the molecular pathway by which adaptive Lac(+) mutants arise in E. coli strain FC40. Adaptive Lac(+) mutations are largely but not entirely due to error-prone DNA polymerase IV (Pol IV). Mutations in either of the HU subunits, HUalpha or HUbeta, decrease adaptive mutation to Lac(+) by both Pol IV-dependent and Pol IV-independent pathways. Additionally, HU mutations inhibit growth-dependent mutations without a reduction in the level of Pol IV. These effects of HU mutations on adaptive mutation and on growth-dependent mutations reveal novel functions for HU in mutagenesis.     

SOS mutator DNA polymerase IV functions in adaptive mutation and not adaptive amplification.

Adaptive point mutation and amplification are induced responses to environmental stress, promoting genetic changes that can enhance survival. A specialized adaptive mutation mechanism has been documented in one Escherichia coli assay, but its enzymatic basis remained unclear. We report that the SOS-inducible, error-prone DNA polymerase (pol) IV, encoded by dinB, is required for adaptive point mutation in the E. coli lac operon. A nonpolar dinB mutation reduces adaptive mutation frequencies by 85% but does not affect adaptive amplification, growth-dependent mutation, or survival after oxidative or UV damage. We show that pol IV, together with the major replicase, pol III, can account for all adaptive point mutations at lac. The results identify a role for pol IV in inducible genetic change.     

Length of CTG.CAG repeats determines the influence of mismatch repair on genetic instability

We showed previously that mutations in methyl-directed mismatch repair of Escherichia coli reduced the occurrence of large deletions in (CTG.CAG)(175) repeats contained on plasmids. By contrast, other workers reported that mutations in mismatch repair increase the frequency of small-length changes in the shorter (CTG.CAG)(64). Using plasmids with a variety of lengths and purity of (CTG.CAG) repeats, we have resolved these apparently conflicting observations. We show that all lengths of (CTG.CAG) repeats are subject to small-length changes (eight repeats) in (CTG.CAG)(n) occur more readily in cells with active mismatch repair. The frequency of large deletions is proportional to the tract length; in our assays they become prominent in tracts greater than 100 repeats. Interruptions in repeat purity enhance the occurrence of large deletions. In addition, we observed a high level of incidence of deletions in (CTG.CAG) repeats for cultures passing repeatedly through stationary phase during long-term growth experiments of all strains (i.e. with active or inactive mismatch repair). These results agree with current theories on mismatch repair acting on DNA slippage events that occur in DNA triplet-repeats.     

Relative rates of insertion and deletion mutations in dinucleotide repeats of various lengths in mismatch repair proficient mouse and mismatch repair deficient human cells

Microsatellites are DNA elements composed of short tandem repeats of 1-5bp. These sequences are particularly prone to frameshift mutation by insertion-deletion loop formation during replication. The mismatch repair system is responsible for correcting these replication errors, and microsatellite mutation rates are significantly elevated in the absence of mismatch repair. We have investigated the effect of varying the number of repeats in a (CA)n microsatellite on mutation rates in cultured mammalian cells proficient or deficient in mismatch repair. We have also compared the relative rates of single-repeat insertions and deletions in these cells. Two plasmid vectors were constructed for each repeat unit number (n=8, 17, and 30), such that the microsatellites, placed upstream of a bacterial neomycin resistance gene (neo), disrupted the reading frame of the gene in the (-1) or (+1) direction. Plasmids were introduced separately into the cells, where they integrated into the cellular genome. Mutation rates were determined by selection of clones with frameshift mutations in the microsatellite that restored the reading frame of the neo gene. We found that mutation rates were significantly higher for (CA)17 and (CA)30 tracts than for (CA)8 tracts in both mismatch repair proficient (mouse) and deficient (human) cells. A mutational bias favoring insertions was generally observed. In both (CA)17 and (CA)30 tracts, single-repeat insertion rates were higher than single-repeat deletion rates with or without mismatch repair; deletions of multiple repeat units (> or =8bp) were observed in these tracts, where as deletions this large were not found in the (CA)8 tract. Single-repeat mutations of both types were made at similar rates in (CA)8 tracts in human mismatch repair deficient (MMR-) cells, but single-repeat insertion rates were higher than single-repeat deletion rates in mouse mismatch repair proficient (MMR+) cells. Results of these direct studies on microsatellite mutations in cultured cells should be useful for refinement of mathematical models for microsatellite evolution.     

A molecular characterization of spontaneous frameshift mutagenesis within the trpA gene of Escherichia coli

Spontaneous frameshift mutations are an important source of genetic variation in all species and cause a large number of genetic disorders in humans. To enhance our understanding of the molecular mechanisms of frameshift mutagenesis, 583 spontaneous Trp+ revertants of two trpA frameshift alleles in Escherichia coli were isolated and DNA sequenced. In order to measure the contribution of methyl-directed mismatch repair to frameshift production, mutational spectra were constructed for both mismatch repair-proficient and repair-defective strains. The molecular origins of practically all of the frameshifts analyzed could be explained by one of six simple models based upon misalignment of the template or nascent DNA strands with or without misincorporation of primer nucleotides during DNA replication. Most frameshifts occurred within mononucleotide runs as has been shown often in previous studies but the location of the 76 frameshift sites was usually outside of runs. Mismatch repair generally was most effective in preventing the occurrence of frameshifts within runs but there was much variation from site to site. Most frameshift sites outside of runs appear to be refractory to mismatch repair although the small number of occurrences at most of these sites make firm conclusions impossible. There was a dense pattern of reversion sites within the trpA DNA region where reversion events could occur, suggesting that, in general, most DNA sequences are capable of undergoing spontaneous mutational events during replication that can lead to small deletions and insertions. Many of these errors are likely to occur at low frequencies and be tolerated as events too costly to prevent or repair. These studies also revealed an unpredicted flexibility in the primary amino acid sequence of the trpA product, the alpha subunit of tryptophan synthase.     

Replication slippage between distant short repeats in Saccharomyces cerevisiae depends on the direction of replication and the RAD50 and RAD52 genes.

Small direct repeats, which are frequent in all genomes, are a potential source of genome instability. To study the occurrence and genetic control of repeat-associated deletions, we developed a system in the yeast Saccharomyces cerevisiae that was based on small direct repeats separated by either random sequences or inverted repeats. Deletions were examined in the LYS2 gene, using a set of 31- to 156-bp inserts that included inserts with no apparent potential for secondary structure as well as two quasipalindromes. All inserts were flanked by 6- to 9-bp direct repeats of LYS2 sequence, providing an opportunity for Lys+ reversion via precise excision. Reversions could arise by extended deletions involving either direct repeats or random sequences and by -1-or +2-bp frameshift mutations. The deletion breakpoints were always associated with short (3- to 9-bp) perfect or imperfect direct repeats. Compared with the POL+ strain, deletions between small direct repeats were increased as much as 100-fold, and the spectrum was changed in a temperature-sensitive DNA polymerase delta pol3-t mutant, suggesting a role for replication. The type of deletion depended on orientation relative to the origin of replication. On the basis of these results, we propose (i) that extended deletions between small repeats arise by replication slippage and (ii) that the deletions occur primarily in either the leading or lagging strand. The RAD50 and RAD52 genes, which are required for the recombinational repair of many kinds of DNA double-strand breaks, appeared to be required also for the production of up to 90% of the deletions arising between separated repeats in the pol3-t mutant, suggesting a newly identified role for these genes in genome stability and possibly replication.     

The Prevention of Repeat-Associated Deletions in Saccharomyces Cerevisiae by Mismatch Repair Depends on Size and Origin of Deletions

We have investigated the effects of mismatch repair on 1- to 61-bp deletions in the yeast Saccharomyces cerevisiae. The deletions are likely to involve unpaired loop intermediates resulting from DNA polymerase slippage. The mutator effects of mutations in the DNA polymerase δ (POL3) gene and the recombinational repair RAD52 gene were studied in combination with mismatch repair defects. The pol3-t mutation increased up to 1000-fold the rate of extended (7-61 bp) but not of 1-bp deletions. In a rad52 null mutant only the 1-bp deletions were increased (12-fold). The mismatch repair mutations pms1, msh2 and msh3 did not affect 31- and 61-bp deletions in the pol3-t but increased the rates of 7- and 1-bp deletions. We propose that loops less than or equal to seven bases generated during replication are subject to mismatch repair by the PMS1, MSH2, MSH3 system and that it cannot act on loops >=31 bases. In contrast to the pol3-t, the enhancement of 1-bp deletions in a rad52 mutant is not altered by a pms1 mutation. Thus, mismatch repair appears to be specific to errors of DNA synthesis generated during semiconservative replication.     

Deletion errors generated during replication of CAG repeats.

Triplet repeat sequence instability is associated with hereditary neurological diseases and with certain types of cancer. Here we study one form of this instability, deletion of triplet repeats during replication of template (CAG)(n)sequences by DNA polymerases. To monitor loss of triplet codons, we inserted (CAG)(9)and (CAG)(17)repeats into the lacZ sequence in M13mp2 and changed one repeat to a TAG codon to yield DNA substrates with colorless plaque phenotypes. Templates containing these inserts within gaps were copied and errors were scored as blue plaque Lac revertants whose DNA was sequenced to determine if loss of the TAG codon resulted from substitutions or deletions. DNA synthesis by either DNA polymerase beta or exonuclease-deficient T7 DNA polymerase produced deletions involving loss of from 1 to 8 of 9 or 15 of 17 repeats. Thus, these polymerases utilize misaligned template-primers containing from 3 to 45 extra template strand nucleotides. Deletion frequencies were much higher than substitution frequencies at the TAG codon in certain repeats, indicating that triplet repeats are at high risk for mutation in the absence of error correction. Proofreading-proficient T7 DNA polymerase generated deletions at 2- to 10-fold lower frequencies than did its exonuclease-deficient derivative. This suggests that misaligned triplet repeat sequences are subject to proofreading, but at reduced efficiency compared to editing of single-base mismatches.     

DNA polymerase III proofreading mutants enhance the expansion and deletion of triplet repeat sequences in Escherichia coli

The influence of mutations in the 3' to 5' exonucleolytic proofreading epsilon-subunit of Escherichia coli DNA polymerase III on the genetic instabilities of the CGG.CCG and the CTG.CAG repeats that cause human hereditary neurological diseases was investigated. The dnaQ49(ts) and the mutD5 mutations destabilize the CGG.CCG repeats. The distributions of the deletion products indicate that slipped structures containing a small number of repeats in the loop mediate the deletion process. The CTG.CAG repeats were destabilized by the dnaQ49(ts) mutation by a process mediated by long hairpin loop structures (>/=5 repeats). The mutD5 mutator strain stabilized the (CTG.CAG)(175) tract, which contained two interruptions. Since the mutD5 mutator strain has a saturated mismatch repair system, the stabilization is probably an indirect effect of the nonfunctional mismatch repair system in these strains. Shorter uninterrupted tracts expand readily in the mutD5 strain, presumably due to the greater stability of long CTG.CAG tracts (>100 repeats) in this strain. When parallel studies were conducted in minimal medium, where the mutD5 strain is defective in exonucleolytic proofreading but has a functional MMR system, both CTG.CAG and CGG.CCG repeats were destabilized, showing that the proofreading activity is essential for maintaining the integrity of TRS tracts. Thus, we conclude that the expansion and deletion of triplet repeats are enhanced by mutations that reduce the fidelity of replication.     

Spontaneously arising mutL mutators in evolving Escherichia coli populations are the result of changes in repeat length

Over the course of thousands of generations of growth in a glucose-limited environment, 3 of 12 experimental populations of Escherichia coli spontaneously and independently evolved greatly increased mutation rates. In two of the populations, the mutations responsible for this increased mutation rate lie in the same region of the mismatch repair gene mutL. In this region, a 6-bp repeat is present in three copies in the gene of the wild-type ancestor of the experimental populations but is present in four copies in one of the experimental populations and two copies in the other. These in-frame mutations either add or delete the amino acid sequence LA in the MutL protein. We determined that the replacement of the wild-type sequence with either of these mutations was sufficient to increase the mutation rate of the wild-type strain to a level comparable to that of the mutator strains. Complementation of strains bearing the mutator mutations with wild-type copies of either mutL or the mismatch repair gene uvrD rescued the wild-type mutation rate. The position of the mutator mutations-in the region of MutL known as the ATP lid-suggests a possible deficiency in MutL's ATPase activity as the cause of the mutator phenotype. The similarity of the two mutator mutations (despite the independent evolutionary histories of the populations that gave rise to them) leads to a discussion of the potential adaptive role of DNA repeats.     

In vivo study of fidelity of DNA double-strand break repair in bacteriophage T4

A method for in vivo studying the fidelity of DNA double-strand break (DSB) repair in bacteriophage T4 has been developed. The frequency of reversion of rII mutations to the wild phenotype was measured in i segC+ x i ets 1 segCDelta crosses, where ets 1 is an insertion in the initial part of the rII gene carrying a sequence recognized by SegC endonuclease; i designates a rIIB or rIIA mutation located at some distance from ets 1, and segCDelta is a deletion in the segC gene. In such cross, a DSB occurs in the site of ets 1. Their repair involves genetic recombination and DNA replication in the neighborhood of ets 1. In parallel, the frequency of reversion of the same i mutant in the absence of DSBs is measured in i x i self-crosses. Reversions of different types (base substitutions, deletions, insertions) can be studied with the use of structurally different i mutations located at varying distances from ets 1. The reversion frequencies were determined for three rIIB mutations and one rIIA mutation. The results obtained suggest that DSB repair in bacteriophage T4 is a process of high fidelity with the rate of errors that does not essentially exceed that in the case of usual phage multiplication.     

Roles of RecA protein in spontaneous mutagenesis in Escherichia coli

To verify the extent of contribution of spontaneous DNA lesions to spontaneous mutagenesis, we have developed a new genetic system to examine simultaneously both forward mutations and recombination events occurring within about 600 base pairs of a transgenic rpsL target sequence located on Escherichia coli chromosome. In a wild-type strain, the recombination events were occurring at a frequency comparable to that of point mutations within the rpsL sequence. When the cells were UV-irradiated, the recombination events were induced much more sharply than point mutations. In a recA null mutant, no recombination event was observed. These data suggest that the blockage of DNA replication, probably caused by spontaneous DNA lesions, occurs often in normally growing E. coli cells and is mainly processed by cellular functions requiring the RecA protein. However, the recA mutant strain showed elevated frequencies of single-base frameshifts and large deletions, implying a novel mutator action of this strain. A similar mutator action of the recA mutant was also observed with a plasmid-based rpsL mutation assay. Therefore, if the recombinogenic problems in DNA replication are not properly processed by the RecA function, these would be a potential source for mutagenesis leading to single-base frameshift and large deletion in E. coli. Furthermore, the single-base frameshifts induced in the recA-deficient cells appeared to be efficiently suppressed by the mutS-dependent mismatch repair system. Thus, it seems likely that the single-base frameshifts are derived from slippage errors that are not directly caused by DNA lesions but made indirectly during some kind of error-prone DNA synthesis in the recA mutant cells.