Deletion of the DEF1 gene does not confer UV-immutability but frequently leads to self-diploidization in yeast Saccharomyces cerevisiae.

In yeast Saccharomyces cerevisiae, the DEF1 gene is responsible for regulation of many cellular processes including ubiquitin-dependent degradation of DNA metabolism proteins. Recently it has been proposed that Def1 promotes degradation of the catalytic subunit of DNA polymerase δ at sites of DNA damage and regulates a switch to specialized polymerases and, as a consequence, DNA-damage induced mutagenesis. The idea was based substantially on the severe defects in induced mutagenesis observed in the def1 mutants. We describe that UV mutability of def1Δ strains is actually only moderately affected, while the virtual absence of UV mutagenesis in many def1Δ clones is caused by a novel phenotype of the def1 mutants, proneness to self-diploidization. Diploids are extremely frequent (90%) after transformation of wild-type haploids with def1::kanMX disruption cassette and are frequent (2.3%) in vegetative haploid def1 cultures. Such diploids look "UV immutable" when assayed for recessive forward mutations but have normal UV mutability when assayed for dominant reverse mutations. The propensity for frequent self-diploidization in def1Δ mutants should be taken into account in studies of the def1Δ effect on mutagenesis. The true haploids with def1Δ mutation are moderately UV sensitive but retain substantial UV mutagenesis for forward mutations: they are fully proficient at lower doses and only partially defective at higher doses of UV. We conclude that Def1 does not play a critical role in damage-induced mutagenesis.

Defect of Fe-S cluster binding by DNA polymerase δ in yeast suppresses UV-induced mutagenesis, but enhances DNA polymerase ζ - dependent spontaneous mutagenesis.

Eukaryotic genomes are duplicated by a complex machinery, utilizing high fidelity replicative B-family DNA polymerases (pols) α, δ and ε. Specialized error-prone pol ζ, the fourth B-family member, is recruited when DNA synthesis by the accurate trio is impeded by replication stress or DNA damage. The damage tolerance mechanism dependent on pol ζ prevents DNA/genome instability and cell death at the expense of increased mutation rates. The pol switches occurring during this specialized replication are not fully understood. The loss of pol ζ results in the absence of induced mutagenesis and suppression of spontaneous mutagenesis. Disruption of the Fe-S cluster motif that abolish the interaction of the C-terminal domain (CTD) of the catalytic subunit of pol ζ with its accessory subunits, which are shared with pol δ, leads to a similar defect in induced mutagenesis. Intriguingly, the pol3-13 mutation that affects the Fe-S cluster in the CTD of the catalytic subunit of pol δ also leads to defective induced mutagenesis, suggesting the possibility that Fe-S clusters are essential for the pol switches during replication of damaged DNA. We confirmed that yeast strains with the pol3-13 mutation are UV-sensitive and defective in UV-induced mutagenesis. However, they have increased spontaneous mutation rates. We found that this increase is dependent on functional pol ζ. In the pol3-13 mutant strain with defective pol δ, there is a sharp increase in transversions and complex mutations, which require functional pol ζ, and an increase in the occurrence of large deletions, whose size is controlled by pol ζ. Therefore, the pol3-13 mutation abrogates pol ζ-dependent induced mutagenesis, but allows for pol ζ recruitment for the generation of spontaneous mutations and prevention of larger deletions. These results reveal differential control of the two major types of pol ζ-dependent mutagenesis by the Fe-S cluster present in replicative pol δ.

Mutator effects and mutation signatures of editing deaminases produced in bacteria and yeast.

Enzymatic deamination of bases in DNA or RNA leads to an alteration of flow of genetic information. Adenosine deaminases edit RNA (ADARs, TADs). Specialized cytidine deaminases are involved in RNA/DNA editing in lipid metabolism (APOBEC1) and in innate (APOBEC3 family) and humoral (AID) immunity. APOBEC2 is required for proper muscle development and, along with AID, was implicated in demethylation of DNA. The functions of APOBEC4, APOBEC5, and other deaminases recently discovered by bioinformatics approaches are unknown. What is the basis for the diverse biological functions of enzymes with similar enzyme structure and the same principal enzymatic reaction? AID, APOBEC1, lamprey CDA1, and APOBEC3G enzymes cause uracil DNA glycosylase-dependent induction of mutations when overproduced ectopically in bacteria or yeast. APOBEC2, on the contrary, is nonmutagenic. We studied the effects of the expression of various deaminases in yeast and bacteria. The mutagenic specificities of four deaminases, hAID, rAPOBEC1, hAPOBEC3G, and lamprey CDA1, are strikingly different. This suggests the existence of an intrinsic component of deaminase targeting. The expression of yeast CDD1 and TAD2/TAD3, human APOBEC4, Xanthomonas oryzae APOBEC5, and deaminase encoded by Micromonas sp. gene MICPUN_56782 was nonmutagenic. A lack of a mutagenic effect for Cdd1 is expected because the enzyme functions in the salvage of pyrimidine nucleotides, and it is evolutionarily distant from RNA/DNA editing enzymes. The reason for inactivity of deaminases grouped with APOBEC2 is not obvious from their structures. This can not be explained by protein insolubility and peculiarities of cellular distribution and requires further investigation.

Evidence that errors made by DNA polymerase alpha are corrected by DNA polymerase delta.

Eukaryotic replication begins at origins and on the lagging strand with RNA-primed DNA synthesis of a few nucleotides by polymerase alpha, which lacks proofreading activity. A polymerase switch then allows chain elongation by proofreading-proficient pol delta and pol epsilon. Pol delta and pol epsilon are essential, but their roles in replication are not yet completely defined . Here, we investigate their roles by using yeast pol alpha with a Leu868Met substitution . L868M pol alpha copies DNA in vitro with normal activity and processivity but with reduced fidelity. In vivo, the pol1-L868M allele confers a mutator phenotype. This mutator phenotype is strongly increased upon inactivation of the 3' exonuclease of pol delta but not that of pol epsilon. Several nonexclusive explanations are considered, including the hypothesis that the 3' exonuclease of pol delta proofreads errors generated by pol alpha during initiation of Okazaki fragments. Given that eukaryotes encode specialized, proofreading-deficient polymerases with even lower fidelity than pol alpha, such intermolecular proofreading could be relevant to several DNA transactions that control genome stability.

In vivo consequences of putative active site mutations in yeast DNA polymerases alpha, epsilon, delta, and zeta.

Several amino acids in the active site of family A DNA polymerases contribute to accurate DNA synthesis. For two of these residues, family B DNA polymerases have conserved tyrosine residues in regions II and III that are suggested to have similar functions. Here we replaced each tyrosine with alanine in the catalytic subunits of yeast DNA polymerases alpha, delta, epsilon, and zeta and examined the consequences in vivo. Strains with the tyrosine substitution in the conserved SL/MYPS/N motif in region II in Pol delta or Pol epsilon are inviable. Strains with same substitution in Rev3, the catalytic subunit of Pol zeta, are nearly UV immutable, suggesting severe loss of function. A strain with this substitution in Pol alpha (pol1-Y869A) is viable, but it exhibits slow growth, sensitivity to hydroxyurea, and a spontaneous mutator phenotype for frameshifts and base substitutions. The pol1-Y869A/pol1-Y869A diploid exhibits aberrant growth. Thus, this tyrosine is critical for the function of all four eukaryotic family B DNA polymerases. Strains with a tyrosine substitution in the conserved NS/VxYG motif in region III in Pol alpha, -delta, or -epsilon are viable and a strain with the homologous substitution in Rev3 is UV mutable. The Pol alpha mutant has no obvious phenotype. The Pol epsilon (pol2-Y831A) mutant is slightly sensitive to hydroxyurea and is a semidominant mutator for spontaneous base substitutions and frameshifts. The Pol delta mutant (pol3-Y708A) grows slowly, is sensitive to hydroxyurea and methyl methanesulfonate, and is a strong base substitution and frameshift mutator. The pol3-Y708A/pol3-Y708A diploid grows slowly and aberrantly. Mutation rates in the Pol alpha, -delta, and -epsilon mutant strains are increased in a locus-specific manner by inactivation of PMS1-dependent DNA mismatch repair, suggesting that the mutator effects are due to reduced fidelity of chromosomal DNA replication. This could result directly from relaxed base selectivity of the mutant polymerases due to the amino acid changes in the polymerase active site. In addition, the alanine substitutions may impair catalytic function to allow a different polymerase to compete at the replication fork. This is supported by the observation that the pol3-Y708A mutation is recessive and its mutator effect is partially suppressed by disruption of the REV3 gene.

Mutator effects of overproducing DNA polymerase eta (Rad30) and its catalytically inactive variant in yeast.

DNA polymerase eta synthesizes DNA in vitro with low fidelity. Based on this, here we report the effects of deletion or increased expression of yeast RAD30 gene, encoding for polymerase eta (Pol eta), on spontaneous mutagenesis in vivo. Deletion of RAD30 did not affect spontaneous mutagenesis. Overproduction of Rad30p was slightly mutagenic in a wild-type yeast strain and moderately mutagenic in strains with inactive 3'-->5'-exonuclease of DNA polymerase epsilon or DNA mismatch repair. These data suggest that excess Rad30p reduces replication fidelity in vivo and that the induced errors may be corrected by exonucleolytic proofreading and DNA mismatch repair. However, the magnitude of mutator effect (only up to 10-fold) suggests that the replication fork is protected from inaccurate synthesis by Pol eta in the absence of DNA damage. Overproduction of catalytically inactive Rad30p was also mutagenic, suggesting that much of the mutator effect results from indirect perturbation of replication rather than from direct misincorporation by Pol eta. Moreover, while excess wild-type Pol eta primarily induced base substitutions in the msh6 and pms1 strains, excess inactive Rad30p induced both base substitutions and frameshifts. This suggests that more than one mutagenic mechanism is operating when RAD30 is overexpressed.

Stationary-phase mutations in proofreading exonuclease-deficient strains of the yeast Saccharomyces cerevisiae.

In order to understand the role of yeast polymerases in spontaneous mutagenesis in non-growing cells we have studied the effects of mutations that impair the 3'--> 5' exonuclease function of polymerases delta (pol3-01) and epsilon (pol2-4) on the spontaneous reversion frequency of the frameshift mutation his7-2 in cells starved for histidine. We showed that for each exonuclease-deficient mutant the rate of reversion per viable cell per day observed in stationary-phase cells remained constant up to the 9th day of starvation (while the number of viable cells dropped), and was very similar to that observed in the same mutants during the growth phase. These data suggest that both DNA polymerases are involved in the control of mutability in non-growing cells.

Somatic mutation hotspots correlate with DNA polymerase eta error spectrum.

Mutational spectra analysis of 15 immunoglobulin genes suggested that consensus motifs RGYW and WA were universal descriptors of somatic hypermutation. Highly mutable sites, "hotspots", that matched WA were preferentially found in one DNA strand and RGYW hotspots were found in both strands. Analysis of base-substitution hotspots in DNA polymerase error spectra showed that 33 of 36 hotspots in the human polymerase eta spectrum conformed to the WA consensus. This and four other characteristics of polymerase eta substitution specificity suggest that errors introduced by this enzyme during synthesis of the nontranscribed DNA strand in variable regions may contribute to strand-specific somatic hypermutagenesis of immunoglobulin genes at A-T base pairs.

Mutagenic specificity of the base analog 6-N-hydroxylaminopurine in the LYS2 gene of yeast Saccharomyces cerevisiae.

We used the LYS2 gene mutational system to study mutation specificity of the base analog 6-N-hydroxylaminopurine (HAP) in yeast. We characterized phenotypes of mutations using codon-specific nonsense suppressors and the test employing inactivation of the release factor Sup35 due to overexpression and formation of prion-like derivative [PSI]. We have shown that HAP induces predominantly nonsense mutations. While the tests using codon-specific nonsense-suppressors allowed to identify only about 50% of nonsense-mutations, all the nonsense-mutations were identified in the test with defective Sup35. We determined and analyzed the spectrum of HAP-induced nucleotide changes in two regions of the gene. HAP induces predominantly GC-->AT transitions in a hotspots of a central position of trinucleotide GGA or AGG. Directionality of these transitions is consistent with the idea that initial dHAPMP incorporation in the leading strand is more genetically dangerous than in lagging DNA strand. We revealed a specific context inhibitory for HAP mutagenesis, a "T" in -1 position to mutation site.

Hypersensitivity of Escherichia coli Delta(uvrB-bio) mutants to 6-hydroxylaminopurine and other base analogs is due to a defect in molybdenum cofactor biosynthesis.

We have shown previously that Escherichia coli and Salmonella enterica serovar Typhimurium strains carrying a deletion of the uvrB-bio region are hypersensitive to the mutagenic and toxic action of 6-hydroxylaminopurine (HAP) and related base analogs. This sensitivity is not due to the uvrB excision repair defect associated with this deletion because a uvrB point mutation or a uvrA deficiency does not cause hypersensitivity. In the present work, we have investigated which gene(s) within the deleted region may be responsible for this effect. Using independent approaches, we isolated both a point mutation and a transposon insertion in the moeA gene, which is located in the region covered by the deletion, that conferred HAP sensitivity equal to that conferred by the uvrB-bio deletion. The moeAB operon provides one of a large number of genes responsible for biosynthesis of the molybdenum cofactor. Defects in other genes in the same pathway, such as moa or mod, also lead to the same HAP-hypersensitive phenotype. We propose that the molybdenum cofactor is required as a cofactor for an as yet unidentified enzyme (or enzymes) that acts to inactivate HAP and other related compounds.

Multiple antimutagenesis mechanisms affect mutagenic activity and specificity of the base analog 6-N-hydroxylaminopurine in bacteria and yeast.

Base analog 6-N-hydroxylaminopurine is a potent mutagen in variety of prokaryotic and eukaryotic organisms. In the review, we discuss recent results of the studies of HAP mutagenic activity, genetic control and specificity in bacteria and yeast with the emphasis to the mechanisms protecting living cells from mutagenic and toxic effects of this base analog.

Overexpression of the yeast HAM1 gene prevents 6-N-hydroxylaminopurine mutagenesis in Escherichia coli.

The base analogue 6-N-hydroxylaminopurine (HAP) is a potent mutagen in a variety of prokaryotic and eukaryotic organisms. Mutations in the yeast ham1 gene render the cells hypersensitive to the mutagenic effect of HAP. We have found that this gene has homologues in a variety of organisms from bacteria to man. We have overexpressed yeast Ham1p in E. coli. We demonstrate that under conditions when this protein constitutes approximately 30% of cellular protein, the host strain is protected both from toxic and mutagenic effects of HAP. This result indicates that sole Ham1p activity might be sufficient for destruction of HAP or its metabolites in bacterial cells.

Base analog N6-hydroxylaminopurine mutagenesis in Escherichia coli: genetic control and molecular specificity.

We have studied the molecular specificity of the base analog N6-hydroxylaminopurine (HAP) in the E. coli lacI gene, as well as the effects of mutations in DNA repair and replication genes on HAP mutagenesis. HAP induced base substitutions of the two transition types (A . T-->G . C and G . C-->A . T) at equal frequency. This bi-directional transition specificity is consistent with in vitro primer extension experiments with the Klenow fragment of DNA polymerase I in which we observed that either dTTP or dCTP were incorporated opposite HAP in an oligonucleotide template. The spectrum of HAP-induced transitions was different from the spontaneous transitions in either a wild-type or a mismatch-repair-defective (mutL) strain. Mutations in genes controlling excision repair, exonucleolytic proofreading, mismatch correction, error-prone (SOS) repair and 8-oxo-guanine repair did not affect HAP-induced mutagenesis substantially. However, an extensive deletion of several genes in the uvrB-bio region conferred supersensitivity to the lethal and mutagenic effects of HAP, perhaps due to an effect on HAP metabolism. dnaE antimutator alleles reduced HAP-forward mutagenicity in allele-specific manner: dnaE911 reduced it several fold, while dnaE915 abolished it almost completely. The results obtained are consistent with the idea that HAP is mutagenic in E. coli via a pathway generating replication errors.

Base analog 6-N-hydroxylaminopurine mutagenesis in the yeast Saccharomyces cerevisiae is controlled by replicative DNA polymerases.

Genetic control of mutagenesis by the base analog 6-N-hydroxylaminopurine (HAP) was studied in a set of isogenic yeast strains carrying null or point mutations in DNA repair and replication genes. Null alleles of the PMS1, RAD6, REV3 and RAD52 genes did not affect HAP mutagenesis. Defects in 3'- > 5' exonucleases associated with DNA polymerases epsilon and delta led to 2- to 3-fold increases in HAP-induced forward Can(r) mutant frequency. A similar increase was observed for FOAr mutants but only in the strain with a defective exonuclease of the polymerase epsilon (mutation pol2-4). The polymerase epsilon mutations, pol2-9 and pol2-18, which lead to temperature-sensitivity, and pol2-1 (insertion of URA3 at the position coding for amino acid 1134 in the POL2 gene) substantially reduced HAP mutagenesis. The polymerase delta mutation, cdc2-2, slightly reduced HAP mutagenesis. Enhanced proofreading was not the cause of the antimutator effect in the pol2-18 bearing strain, inasmuch as antimutator effect was observed in the pol2-4,18 mutant strain lacking proofreading. From the data obtained, we conclude that both DNA polymerase epsilon and delta participate in mutation generation by HAP.

3'-->5' exonucleases of DNA polymerases epsilon and delta correct base analog induced DNA replication errors on opposite DNA strands in Saccharomyces cerevisiae.

The base analog 6-N-hydroxylaminopurine (HAP) induces bidirectional GC-->AT and AT-->GC transitions that are enhanced in DNA polymerase epsilon and delta 3'-->5' exonuclease-deficient yeast mutants, pol2-4 and pol3-01, respectively. We have constructed a set of isogenic strains to determine whether the DNA polymerases delta and epsilon contribute equally to proofreading of replication errors provoked by HAP during leading and lagging strand DNA synthesis. Site-specific GC-->AT and AT-->GC transitions in a Pol+, pol2-4 or pol3-01 genetic background were scored as reversions of ura3 missense alleles. At each site, reversion was increased in only one proofreading-deficient mutant, either pol2-4 or pol3-01, depending on the DNA strand in which HAP incorporation presumably occurred. Measurement of the HAP-induced reversion frequency of the ura3 alleles placed into chromosome III near to the defined active replication origin ARS306 in two orientations indicated that DNA polymerases epsilon and delta correct HAP-induced DNA replication errors on opposite DNA strands.

HAM1, the gene controlling 6-N-hydroxylaminopurine sensitivity and mutagenesis in the yeast Saccharomyces cerevisiae.

The ham1 mutant of yeast Saccharomyces cerevisiae is sensitive to the mutagenic and lethal effects of the base analog, 6-N-hydroxylaminopurine (HAP). We have isolated a clone from a centromere-plasmid-based genomic library complementing HAP sensitivity of the ham1 strain. After subcloning, a 3.4 kb functional fragment was sequenced. It contained three open reading frames (ORFs) corresponding to proteins 353, 197 and 184 amino acids long. LEU2+ disruptions of the promoter and N-terminal part of the gene coding 197 amino acids long protein led to moderate and strong sensitivity to HAP, respectively, and were allelic to the original ham1-1 mutation. Thus this ORF represents the HAM1 gene. The deduced amino acid sequence of HAM1 protein was not similar to any protein sequence of the SwissProt database. The HAM1 gene was localized on the right arm of chromosome X between cdc8 and cdc11. Spontaneous mutagenesis was not affected by the ham1::LEU2 disruption mutation.

The fidelity of the human leading and lagging strand DNA replication apparatus with 8-oxodeoxyguanosine triphosphate.

A product of oxidative metabolism, 8-oxodeoxyguanosine triphosphate (8-O-dGTP), readily pairs with adenine during DNA replication, ultimately causing A.T-->C.G transversions. This study utilized 8-O-dGTP as a probe to examine the fidelity of the leading and lagging strand replication apparatus in extracts of HeLa cells. Simian virus (SV) 40 T antigen-dependent DNA replication reactions were performed with two M13mp2 vectors with the SV40 origin located on opposite sides of the lacZ alpha sequence used to score replication errors. The presence of 8-O-dGTP at equimolar concentration with each of the 4 normal dNTPs resulted in a > 46-fold increase in error rate for A.T-->C.G transversion over that observed in the absence of 8-O-dGTP. A similar average error rate was observed on the (+) and (-) strands in both vectors, suggesting that the fidelity of replication by leading and lagging strand replication proteins is similar for the dA.8-O-dGMP mispair. Replication fidelity in the presence of 8-O-dGTP was reduced on both strands when an inhibitor of exonucleolytic proofreading (dGMP) was added to the reaction. These data suggest that the majority of dA.8-O-dGMP mispairs are proofread by both leading and lagging strand replication proteins.

DNA replication fidelity with 8-oxodeoxyguanosine triphosphate.

Oxidative metabolism is known to generate mutagenic compounds within cells, among which is 8-oxodeoxyguanosine. Here the mutagenic potential of the triphosphate form of this base analog (8-O-dGTP) is investigated during replication in vitro of the lacZ alpha-complementation sequence in M13mp2 DNA. Adding 8-O-dGTP at equimolar concentration with the normal dNTPs to polymerization reactions decreases the fidelity of DNA synthesis by exonuclease-deficient Klenow, T4, and Thermus thermophilus DNA polymerases. Sequence analysis of mutants suggests that 8-O-dGMP is misincorporated opposite template adenines, yielding A-->C transversions. The degree of polymerase selectivity against this error is enzyme-dependent, with rates varying by > 25-fold. To determine if the A.8-O-dGMP mispair is proofread, a direct comparison of the fidelity of proofreading-proficient and proofreading-deficient Klenow and T4 DNA polymerases was made. Although the exonuclease activity of Klenow polymerase did not substantially reduce overall misincorporation of 8-O-dGMP, misincorporation was lower for the proofreading-proficient T4 enzyme as compared to its proofreading-deficient derivative. These data suggest that the A.8-O-dGMP mispair can be proofread. The mutagenic potential of 8-O-dGTP with eukaryotic systems was also examined. Misincorporation of 8-O-dGTP opposite adenine was observed during SV40 origin-dependent replication of double-stranded DNA in HeLa cell extracts. When present during replication at a concentration equal to the four normal dNTPs, 8-O-dGTP was at least 13-fold more mutagenic for A.T-->C.G transversions than was a 100-fold excess of normal dGTP.(ABSTRACT TRUNCATED AT 250 WORDS)

Transformation in the methylotrophic yeast Pichia methanolica utilizing homologous ADE1 and heterologous Saccharomyces cerevisiae ADE2 and LEU2 genes as genetic markers.

Development of transformation systems for methylotrophic yeasts is the starting point for research aimed at developing molecular genetics of these genera and will be the key to their further successful use in biotechnology. We transformed Pichia methanolica using selector genes ADE2 and LEU2 from Saccharomyces cerevisiae and ADE1 (homologue of S. cerevisiae ADE2 gene) from P. methanolica which was cloned and sequenced in our laboratory (Hiep et al., 1991). Lithium transformation of P. methanolica strains was inefficient with intact plasmids. Linearization of plasmids at a unique restriction site within the ADE1 gene prior to transformation substantially increased its frequency. Transformation with linear ADE1, ADE2 or LEU2 gene fragments was even more effective. Introduced DNA fragments either circularized in vivo, irrespective of the structures of their ends, giving unstable transformants; or integrated at different sites of the host genome. Using this transformation system, we obtained a disruption of the ADE1 gene on the chromosome by inserting the S. cerevisiae LEU2 gene. The disruption mutation ade1::LEU2 was used to study the mechanism of intragenic recombination in P. methanolica.

The 5-aminoimidazole ribonucleotide-carboxylase structural gene of the methylotrophic yeast Pichia methanolica: cloning, sequencing and homology analysis.

The ADE1 gene of the yeast Pichia methanolica encodes phosphoribosyl-5-aminoimidazole-carboxylase (AIRC, EC 4.1.1.21), which is involved in purine biosynthesis. The gene was cloned by complementation of an ade2 mutation in Saccharomyces cerevisiae and a 3077 nucleotide DNA fragment was sequenced. The sequence possessed a single open reading frame, corresponding to a 543 amino acid sequence. The sequence of this putative protein has been compared to the proteins of homologous genes from S. cerevisiae, Schizosaccharomyces pombe, Escherichia coli, chicken and man. The analysis revealed remarkable homology between yeast AIRCs, while for other proteins homology was limited to defined regions.