The Role of Dbf4-Dependent Protein Kinase in DNA Polymerase ζ-Dependent Mutagenesis in Saccharomyces cerevisiae

The yeast Dbf4-dependent kinase (DDK) (composed of Dbf4 and Cdc7 subunits) is an essential, conserved Ser/Thr protein kinase that regulates multiple processes in the cell, including DNA replication, recombination and induced mutagenesis. Only DDK substrates important for replication and recombination have been identified. Consequently, the mechanism by which DDK regulates mutagenesis is unknown. The yeast mcm5-bob1 mutation that bypasses DDK’s essential role in DNA replication was used here to examine whether loss of DDK affects spontaneous as well as induced mutagenesis. Using the sensitive lys2ΔA746 frameshift reversion assay, we show DDK is required to generate “complex” spontaneous mutations, which are a hallmark of the Polζ translesion synthesis DNA polymerase. DDK co-immunoprecipitated with the Rev7 regulatory, but not with the Rev3 polymerase subunit of Polζ. Conversely, Rev7 bound mainly to the Cdc7 kinase subunit and not to Dbf4. The Rev7 subunit of Polζ may be regulated by DDK phosphorylation as immunoprecipitates of yeast Cdc7 and also recombinant Xenopus DDK phosphorylated GST-Rev7 in vitro. In addition to promoting Polζ-dependent mutagenesis, DDK was also important for generating Polζ-independent large deletions that revert the lys2ΔA746 allele. The decrease in large deletions observed in the absence of DDK likely results from an increase in the rate of replication fork restart after an encounter with spontaneous DNA damage. Finally, nonepistatic, additive/synergistic UV sensitivity was observed in cdc7Δ pol32Δ and cdc7Δ pol30-K127R,K164R double mutants, suggesting that DDK may regulate Rev7 protein during postreplication “gap filling” rather than during “polymerase switching” by ubiquitinated and sumoylated modified Pol30 (PCNA) and Pol32.     

The Exonuclease Activity of the Yeast Mitochondrial DNA Polymerase γ Suppresses Mitochondrial DNA Deletions Between Short Direct Repeats in Saccharomyces cerevisiae

The importance of mitochondrial DNA (mtDNA) deletions in the progeroid phenotype of exonuclease-deficient DNA polymerase γ mice has been intensely debated. We show that disruption of Mip1 exonuclease activity increases mtDNA deletions 160-fold, whereas disease-associated polymerase variants were mostly unaffected, suggesting that exonuclease activity is vital to avoid deletions during mtDNA replication.     

Suppressors of thermosensitive mutations in the DNA polymerase δ gene of Saccharomyces cerevisiae

DNA polymerases (Pol) α, δ and ε are necessary for replication of nuclear DNA. Po1δ interacts permanently or transiently with numerous accessory proteins whose identification may shed light on the function(s) of Po18. In vitro mutagenesis was used to induce thermosensitive (ts) mutations in the DNA polymerase δ gene (POL3). We have attempted to clone two recessive extragenic suppressors of such is mutants (sdp1 for mutation pol3-14 and sdp5-1 for mutation pol3-11) by transforming thermoresistant haploid strains pol3-14 sdpl and pol3-11 sdp5-1 with wild-type genomic libraries in singlecopy or multicopy vectors. None of the thermosensitive transformants so obtained was identified as being sdp1 or sdp5-1. Instead, three genes were cloned whose products interfere with the activity of suppressors. One of them is the type 1 protein phosphatase gene, D1S2. Another is a novel gene, ASM4, whose gene product is rich in asparagine and glutamine residues.     

Induction of direct repeat recombination by psoralen–DNA adducts in Saccharomyces cerevisiae: Defects in DNA repair increase gene copy number variation

Psoralen photoreaction produces covalent monoadducts and interstrand crosslinks in DNA. The interstrand DNA crosslinks are complex double strand lesions that require the involvement of multiple pathways for repair. Homologous recombination, which can carry out error-free repair, is a major pathway for crosslink repair; however, some recombination pathways can also produce DNA rearrangements. Psoralen photoreaction-induced recombination in yeast was measured using direct repeat substrates that can detect gene conversions, a form of conservative recombination, as well as deletions and triplications, which generate gene copy number changes. In repair-proficient cells the major products of recombination were gene conversions, along with substantial fractions of deletions. Deficiencies in DNA repair pathways increased non-conservative recombination products. Homologous recombination-deficient rad51, rad54, and rad57 strains had low levels of crosslink-induced recombination, and most products were deletions produced by single strand annealing. Nucleotide excision repair-deficient rad1 and rad2 yeast had increased levels of triplications, and rad1 cells had lower crosslink-induced recombination. Deficiencies in post-replication repair increased crosslink-induced recombination and gene copy number changes. Loss of REV3 function, in the error-prone branch, and of RAD5 and UBC13, in the error-free branch, produced moderate increases in deletions and triplications; rad18 cells, deficient in both post-replication repair sub-pathways, exhibited hyperrecombination, with primarily non-conservative products. Proper functioning of all the DNA repair pathways tested was required to maintain genomic stability and avoid gene copy number variation in response to interstrand crosslinks.     

Temperature dependency of induction of sexual agglutinability by α pheromone in the yeast Saccharomyces cerevisiae

When pheromone-pretreated cells of an inducible a strain of Saccharomyces cerevisiae carrying the inducible gene saa1 were incubated in a growth medium at 28°C, induction of sexual agglutinability began after a 10 min lag period. If the cells were incubated at 38°C during the lag period, no induction occurred even after incubation at 28°C. Contrary to this, if the cells were incubated at 28°C during the lag period, almost complete induction occurred, even after transfer to 38°C. Temperature shift experiments revealed that 5 min incubation at 28°C was necessary for the initiation of the temperature-sensitive period and further 5 min incubation for the completion of the period. The temperature-sensitive period was sensitive to phenylmethylsulfonyl fluoride.Non-common abbreviations PBS 10^-2 M phosphate buffer solution, pH 5.5 - PMSF phenylmethylsulfonyl fluoride     

Regulation of β-exoglucanase activity production by Saccharomyces cerevisiae in batch and continuous culture

The rate of synthesis and secretion of exo-1–3--glucanase activity closely paralleled the specific rate of growth in exponentially growing Saccharomyces cerevisiae cells in batch culture. When the stationary phase was reached both synthesis and secretion stopped. No activity was synthesized when the cells were maintained in carbon sources that did not allow them to grow. Studies in continuous culture indicate a strong relationship between the synthesis of exoglucanase activity and the specific growth rate. These results are taken as evidence of an essential role of this activity during the yeast budding cycle.Non-standard abbreviations p-NPG p-nitrophenyl--d-glucopyranoside - S_r glucose concentration in the sterile reservoir; , glucose concentration at the steady state - biomass density at the steady state - G glucanase activity - Q _g specific exoglucanase synthesis rate     

Diversification of Paralogous α-Isopropylmalate Synthases by Modulation of Feedback Control and Hetero-Oligomerization in Saccharomyces cerevisiae

Production of α-isopropylmalate (α-IPM) is critical for leucine biosynthesis and for the global control of metabolism. The budding yeast Saccharomyces cerevisiae has two paralogous genes, LEU4 and LEU9, that encode α-IPM synthase (α-IPMS) isozymes. Little is known about the biochemical differences between these two α-IPMS isoenzymes. Here, we show that the Leu4 homodimer is a leucine-sensitive isoform, while the Leu9 homodimer is resistant to such feedback inhibition. The leu4Δ mutant, which expresses only the feedback-resistant Leu9 homodimer, grows slowly with either glucose or ethanol and accumulates elevated pools of leucine; this phenotype is alleviated by the addition of leucine. Transformation of the leu4Δ mutant with a centromeric plasmid carrying LEU4 restored the wild-type phenotype. Bimolecular fluorescent complementation analysis showed that Leu4-Leu9 heterodimeric isozymes are formed in vivo. Purification and kinetic analysis showed that the hetero-oligomeric isozyme has a distinct leucine sensitivity behavior. Determination of α-IPMS activity in ethanol-grown cultures showed that α-IPM biosynthesis and growth under these respiratory conditions depend on the feedback-sensitive Leu4 homodimer. We conclude that retention and further diversification of two yeast α-IPMSs have resulted in a specific regulatory system that controls the leucine–α-IPM biosynthetic pathway by selective feedback sensitivity of homomeric and heterodimeric isoforms.     

Isolation of an Arabidopsis thaliana casein kinase II β subunit by complementation in Saccharomyces cerevisiae

Casein kinase II is thought to play an essential role in the control of cell division and differentiation in all eukaryotes. Through complementation of a defective casein kinase II catalytic subunit gene from Saccharomyces cerevisiae, we isolated an Arabidopsis thaliana casein kinase II regulatory subunit homologue, CKB1. A second regulatory subunit was identified by low-stringency hybridization with CKB1.Casein kinase II from S. cerevisiae is composed of two catalytic () and two regulatory () subunits. Simultaneous disruption of the genes for the and subunits, CKA1 and CKA2, respectively, is lethal. Strain YDH8 has disruptions of CKA1 and CKA2; its viability depends on a temperature-sensitive allele of CKA2, cka2–8, carried on a centromeric plasmid. We screened an A. thaliana cDNA library, whose inserts are under the control of the galactose-inducible GAL10 promoter, for cDNAs which enabled YDH8 cells to grow at the restrictive temperature. One cDNA, CKB1, was isolated by this screen which had homology to cDNAs of casein kinase II subunits. A second cDNA, CKB2, was isolated by hybridization and was also able to suppress the YDH8 mutant phenotype.The proteins encoded by CKB1 and CKB2 are 80% identical. The carboxy-terminal two thirds of both proteins is ca. 54% identical to the regulatory subunits of casein kinase II from other species. The amino termini are unrelated to any other known proteins. CKB1 and CKB2 lack the conserved autophosphorylation site characteristic of animal subunits, but have potential casein kinase II phosphorylation sites in the same region. Suppression of the cka1 cka2–8 mutant phenotype occurs by interaction of CKB1 with the defective, cka2–8-encoded, catalytic subunit. Cells with disruptions in CKA1 and CKA2 are not rescued by expression of CKB1.     

Analysis of CPD Ultraviolet Lesion Bypass in Chicken DT40 Cells: Polymerase η and PCNA Ubiquitylation Play Identical Roles

Translesion synthesis (TLS) provides a mechanism of copying damaged templates during DNA replication. This potentially mutagenic process may operate either at the replication fork or at post-replicative gaps. We used the example of T-T cyclobutane pyrimidine dimer (CPD) bypass to determine the influence of polymerase recruitment via PCNA ubiquitylation versus the REV1 protein on the efficiency and mutagenic outcome of TLS. Using mutant chicken DT40 cell lines we show that, on this numerically most important UV lesion, defects in polymerase η or in PCNA ubiquitylation similarly result in the long-term failure of lesion bypass with persistent strand gaps opposite the lesion, and the elevation of mutations amongst successful TLS events. Our data suggest that PCNA ubiquitylation promotes CPD bypass mainly by recruiting polymerase η, resulting in the majority of CPD lesions bypassed in an error-free manner. In contrast, we find that polymerase ζ is responsible for the majority of CPD-dependent mutations, but has no essential function in the completion of bypass. These findings point to a hierarchy of access of the different TLS polymerases to the lesion, suggesting a temporal order of their recruitment. The similarity of REV1 and REV3 mutant phenotypes confirms that the involvement of polymerase ζ in TLS is largely determined by its recruitment to DNA by REV1. Our data demonstrate the influence of the TLS polymerase recruitment mechanism on the success and accuracy of bypass.     

Increasing glutathione formation by functional expression of the γ-glutamylcysteine synthetase gene in Saccharomyces cerevisiae

A recombinant plasmid, pGMF, containing a gamma-glutamylcysteine synthetase gene (GSH-I) from Saccharomyces cerevisiae, was constructed with a copper-resistance gene as the selection marker and was introduced into S. cerevisiae YSF-31. The glutathione content of the recombinant strain was 1.5-fold (13.1 mg g dry cells(-1)) of that in the host strain.     

Induction of ϱ− mutants in Saccharomyces cerevisiae by guanidine hydrochloride: I. Genetic analysis

Guanidine hydrochloride (GuHCl) induced in Saccharomyces cerevisiae cytoplasmic petite mutants (ϱ⁻) of the suppressive type. However, it was unable to induce the neutral type, even after prolonged incubation or increased drug concentration. No correlation was found between the degree of suppressiveness and the time of incubation of yeast cells with guanidine hydrochloride. The suppressiveness of ϱ⁻ induced was not altered by further treatment with GuHCl, whereas it was reduced upon treatment with ethidium bromide (EtBr). Some mitochondrial genetic information was lacking in the ϱ⁻ mutants induced by GuHCl, as demonstrated by the loss of the gene for erythromycin resistance and by reduced buoyant density of mitochondrial DNA of some ϱ⁻. There was no correlation between the degree of suppressiveness of the ϱ⁻ induced by GuHCl and the bouyant density of the mutant mitochondrial DNA.     

¹³C-metabolic enrichment of glutamate in glutamate dehydrogenase mutants of Saccharomyces cerevisiae

Glutamate dehydrogenases (GDH) interconvert α-ketoglutarate and glutamate. In yeast, NADP-dependent enzymes, encoded by GDH1 and GDH3, are reported to synthesize glutamate from α-ketoglutarate, while an NAD-dependent enzyme, encoded by GDH2, catalyzes the reverse. Cells were grown in acetate/raffinose (YNAceRaf) to examine the role(s) of these enzymes during aerobic metabolism. In YNAceRaf the doubling time of wild type, gdh2Δ, and gdh3Δ cells was comparable at ～4 h. NADP-dependent GDH activity (Gdh1p+Gdh3p) in wild type, gdh2Δ, and gdh3Δ was decreased ～80% and NAD-dependent activity (Gdh2p) in wild type and gdh3Δ was increased ～20-fold in YNAceRaf as compared to glucose. Cells carrying the gdh1Δ allele did not divide in YNAceRaf, yet both the NADP-dependent (Gdh3p) and NAD-dependent (Gdh2p) GDH activity was ～3-fold higher than in glucose. Metabolism of [1,2-(13)C]-acetate and analysis of carbon NMR spectra were used to examine glutamate metabolism. Incorporation of (13)C into glutamate was nearly undetectable in gdh1Δ cells, reflecting a GDH activity at <15% of wild type. Analysis of (13)C-enrichment of glutamate carbons indicates a decreased rate of glutamate biosynthesis from acetate in gdh2Δ and gdh3Δ strains as compared to wild type. Further, the relative complexity of (13)C-isotopomers at early time points was noticeably greater in gdh3Δ as compared to wild type and gdh2Δ cells. These in vivo data show that Gdh1p is the primary GDH enzyme and Gdh2p and Gdh3p play evident roles during aerobic glutamate metabolism.     

Host-Specific Replication of BK Virus DNA in Mouse Cell Extracts Is Independently Controlled by DNA Polymerase α-Primase and Inhibitory Activities

The activation of the human polyomavirus BK causes polyomavirus-associated nephropathy in immunocompromised humans. Studies of the virus have been restricted since the virus DNA replication is species specific. Cell-based and cell-free DNA replication systems, including the BK virus (BKV) monopolymerase DNA replication system using purified proteins, reproduce the species specificity (28). Therefore, the major host proteins comprising this assay, DNA polymerase α-primase (Pol-prim) and replication protein A (RPA), were intensively studied here. We demonstrate that Pol-prim plays a major role in the species specificity of BKV DNA replication. Both large subunits p180 and p68 of the enzyme complex have central functions in modulating the host specificity. Recently, an inhibitory activity of BKV DNA replication was described (C. Mahon, B. Liang, I. Tikhanovich, J. R. Abend, M. J. Imperiale, H. P. Nasheuer, and W. R. Folk, J. Virol. 83:5708-5717, 2009), but neither mouse Pol-prim nor mouse RPA diminishes cell-free BKV DNA replication. However, the inhibition of BKV DNA replication in mouse extracts depends on sequences flanking the core origin. In the presence of human Pol-prim, the inhibitory effect of mouse cell factors is abolished with plasmid DNAs containing the murine polyomavirus early promoter region, whereas the late enhancer region and the core origin are supplied from BKV. Thus, BKV replication is regulated by both Pol-prim, as a core origin species-specific factor, and inhibitory activities, as origin-flanking sequence-dependent factor(s).BK virus (BKV) is a human polyomavirus that was first isolated in the 1970s (15). Up to 90% of adults have serologic evidence of exposure to BKV, but in most humans the virus remains latent (25, 26). Almost all disease accompanied by BKV reactivation has been found in immunocompromised patients (22). In recent years, BKV has been associated with nephropathy (polyomavirus-associated nephropathy, or PVAN) in up to 10% of renal transplant patients. Once established, the disease results in allograft loss in 45 to 70% of the patients (18). Importantly, BKV preferentially replicates in human cells and less well in cells of other primates, and the virus is highly tumorigenic in rodents (21, 41, 44). This fact and the lack of sustainable viral replication in rodents or other convenient, experimental animal models have been an enormous setback to the study of PVAN.As with other members of the Polyomaviridae family, BKV virions are nonenveloped icosahedral particles with a diameter of 45 nm that contain a circular double-stranded DNA genome of 5.3 kb (1). In BKV and in other polyomaviruses, three genomic areas have been distinguished: (i) a noncoding control region including the origin of viral DNA replication, (ii) the early genes encoding large and small T antigens (TAgs), and (iii) the late genes which code for the capsid proteins VP-1, VP-2, and VP-3 and the agnoprotein (22).BKV DNA replication is similar to that of all other members of the Polyomaviridae family and requires only one viral protein, the multifunctional large TAg, whereas all other replication factors are supplied by the host (13, 14, 28, 39, 47). As the first step, TAg binds to the core origin, which contains the early palindrome, an AT-rich sequence, and the TAg binding site II, which consists of two pairs of G(G/A)GGC pentanucleotides. In the presence of ATP, TAg forms a double hexamer and partially melts the early palindrome (EP) and untwists the AT-rich sequence of the BKV core origin (5, 6, 14). Then the TAg double hexamers bidirectionally unwind the viral replication origin, which requires ATP hydrolysis. In the following process the two hexamers remain associated with each other, with the separated single-stranded DNA (ssDNA) threading through the hexameric channels (14). The viral core origin is sufficient to constitute a functional replication origin, but the presence of auxiliary domains increases its activity 5- to 100-fold in vivo (16, 30). After the viral TAg unwinds the core origin and its flanking sequences, replication protein A (RPA), the main eukaryotic ssDNA-binding protein, covers the resulting stretches of ssDNA, whereas topoisomerase I releases the resulting torsional stress and enhances initiation of DNA replication (5, 7, 43). Then, DNA polymerase α-primase (Pol-prim) is loaded onto this TAg-RPA-topoisomerase 1-DNA complex, yielding a functional initiation complex. In the following step, Pol-prim synthesizes short RNA primers at the origin, and these RNA primers are elongated by the DNA polymerase function of the enzyme complex (9, 35, 47). After a polymerase switch from Pol-prim to DNA polymerase δ (Pol δ) with the help of RPA, replication factor C (RFC), and proliferating cell nuclear antigen (PCNA), processive DNA synthesis is completed by Pol δ in association with PCNA, the sliding clamp, on the leading strand (38, 51, 54, 59). Lagging-strand synthesis is discontinuous, and multiple initiation events catalyzed by Pol-prim must take place. Again, after the elongation of the RNA primers by Pol-prim, DNA synthesis is switched to Pol δ, which then synthesizes the complete Okazaki fragments. The maturation of these Okazaki fragments requires the collaboration of RNase H, PCNA, flap endonuclease 1 (Fen-1), Pol δ, and DNA ligase I to establish a continuous strand also on the lagging strand (9, 19, 20, 51, 55).TAg functions in infected cells rely heavily on specific associations with host proteins; for example, TAg interacts with RPA, Pol-prim, and topoisomerase I to replicate viral DNA. Selective interactions with the host p180 and p48 subunits of Pol-prim were shown to be responsible for species-specific replication of simian virus 40 (SV40) and murine polyomavirus (mPyV) DNAs, respectively (8, 47, 50). The subunits of Pol-prim are highly conserved since 88, 80, 89, and 90% of the amino acids are identical between human and murine p180, p68, p58, and p48, respectively. Biochemical studies have shown that TAg interacts independently with all four subunits of Pol-prim (8, 12, 57). Moreover, the p180, p58, and p48 subunits of Pol-prim also physically bind to RPA (7, 11, 57). RPA and TAg binding sites in the Pol-prim complex are essential for SV40 DNA replication in vitro since the presence of an excess of these purified binding peptides diminishes viral DNA replication in vitro (52, 53). Interestingly, species specificity requires the viral origin of DNA replication, whereas physical protein-protein interactions of purified protein complexes are not host specific in the absence of viral origin DNA (29, 42).Consistent with other polyomaviruses, analyses of BKV TAg-dependent DNA replication recently revealed that BKV DNA cannot be replicated in murine cells and that cell extracts are able to mimic this behavior (28). Furthermore, a BKV DNA replication system with the purified human proteins Pol-prim, RPA, topoisomerase I, and BKV TAg was inhibited by murine extracts, whereas SV40 DNA replication was not. Further investigations revealed that the presence of inhibitory activities (IAs) in extracts from murine cells blocks BKV DNA replication at an early step of TAg-mediated unwinding of the BKV origin of replication. Detailed analyses using the BKV monopolymerase DNA replication system, which we report here, show that Pol-prim functions as a species-specific factor associated with core origin functions. In addition, we reveal that the inhibitory activities in murine extracts, which are associated with origin-flanking sequence-dependent factor(s), regulate BKV DNA replication in murine cell extracts in a Pol-prim-independent manner.     

A novel variant of DNA polymerase ζ, Rev3ΔC,highlights differential regulation of Pol32 as a subunit of polymerase δ versus ζ in Saccharomyces cerevisiae

Unrepaired DNA lesions often stall replicative DNA polymerases and are bypassed by translesion synthesis (TLS) to prevent replication fork collapse. Mechanisms of TLS are lesion- and species-specific, with a prominent role of specialized DNA polymerases with relaxed active sites. After nucleotide(s) are incorporated across from the altered base(s), the aberrant primer termini are typically extended by DNA polymerase ζ (pol ζ). As a result, pol ζ is responsible for most DNA damage-induced mutations. The mechanisms of sequential DNA polymerase switches in vivo remain unclear. The major replicative DNA polymerase δ (pol δ) shares two accessory subunits, called Pol31/Pol32 in yeast, with pol ζ. Inclusion of Pol31/Pol32 in the pol δ/pol ζ holoenzymes requires a [4Fe–4S] cluster in C-termini of the catalytic subunits. Disruption of this cluster in Pol ζ or deletion of POL32 attenuates induced mutagenesis. Here we describe a novel mutation affecting the catalytic subunit of pol ζ, rev3ΔC, which provides insight into the regulation of pol switches. Strains with Rev3ΔC, lacking the entire C-terminal domain and therefore the platform for Pol31/Pol32 binding, are partially proficient in Pol32-dependent UV-induced mutagenesis. This suggests an additional role of Pol32 in TLS, beyond being a pol ζ subunit, related to pol δ. In search for members of this regulatory pathway, we examined the effects of Maintenance of Genome Stability 1 (Mgs1) protein on mutagenesis in the absence of Rev3–Pol31/Pol32 interaction. Mgs1 may compete with Pol32 for binding to PCNA. Mgs1 overproduction suppresses induced mutagenesis, but had no effect on UV-mutagenesis in the rev3ΔC strain, suggesting that Mgs1 exerts its inhibitory effect by acting specifically on Pol32 bound to pol ζ. The evidence for differential regulation of Pol32 in pol δ and pol ζ emphasizes the complexity of polymerase switches.     

Overexpression and secretion of cellulolytic enzymes by δ-sequence-mediated multicopy integration of heterologous DNA sequences into the chromosomes of Saccharomyces cerevisiae

Saccharomyces cerevisiae transformants which secrete high levels of cellulolytic enzymes, with chromosome-integrated multicopies of heterologous DNA sequences encoding the cellulolytic enzymes were constructed. An expression construct of β-glucosidase and carboxymethyl cellulase directed by the GAP promoter was integrated into the chromosomes of the haploid S. cerevisiae using the δ sequence-mediated integration system. Southern blot analysis of the chromosomes prepared from various integrants and separated by pulse-field gel electrophoresis demonstrated that the integration occurred mainly in a particular chromosome and the copy number of the integration was variable. The amount of enzymes secreted by the transformants correlated with the copy number of integration. For each enzyme, the highest activity was about 1.4-fold that produced by the transformant harboring the same expression cassette on a YEp-type plasmid. The δ-integrated exogenous DNA was mitotically stable in rich medium. A haploid double transformant which coexpresses and secretes β-glucosidase and carboxymethyl cellulase was further constructed by genetic crossing of the haploid transformant that produces a high level of the enzyme, followed by meiotic segregation of the resulting diploid strain. The haploid double transformant, but neither of the single transformant, could grow on a plate containing carboxymethyl cellulose as a sole carbon source. It is suggested that the δ-sequence-mediated integration system is a very useful means for the genetic engineering of yeast, especially when overproduction and secretion of multiple heterologous enzymes are desired.     

The 3′ → 5′ exonucleases of both DNA polymerases δ and ε participate in correcting errors of DNA replication in Saccharomyces cerevisiae

DNA polymerases II (ε) and III(δ) are the only nuclear DNA polymerases known to possess an intrinsic 3′ → 5′ exonuclease in Saccharomyces cerevisiae. We have investigated the spontaneous mutator phenotypes of DNA polymerase δ and ε 3′ → 5′ exonuclease-deficient mutants, pol3-01 and pol2-4, respectively. pol3-01 and pol2-4 increased spontaneous mutation rates by factors of the order of 10² and 10¹, respectively, measured as URA3 forward mutation and his7-2 reversion. Surprisingly, a double mutant pol2-4 pol3-01 haploid was inviable. This was probably due to accumulation of unedited errors, since a pol2-4/pol2-4 pol3-01/pol3-01 diploid was viable, with the spontaneous his7-2 reversion rate increased by about 2 × 10³-fold. Analysis of mutation rates of double mutants indicated that the 3′ → 5′ exonucleases of DNA polymerases δ and ε can act competitively and that, like the 3′ → 5′ exonuclease of DNA polymerase δ the 3′ → 5′ exonuclease of DNA polymerase ε acts in series with the PMS1 mismatch correction system. Mutational spectra at a URA3 gene placed in both orientations near to a defined replication origin provided evidence that the 3′ → 5′ exonucleases of DNA polymerases δ and ε act on opposite DNA strands, but were in sufficient to distinguish conclusively between different models of DNA replication.