Targeting of human DNA polymerase iota to the replication machinery via interaction with PCNA.

Human DNA polymerase iota (hPoliota) promotes translesion synthesis by inserting nucleotides opposite highly distorting or noninstructional DNA lesions. Here, we provide evidence for the physical interaction of hPoliota with proliferating cell nuclear antigen (PCNA), and show that PCNA, together with replication factor C (RFC) and replication protein A (RPA), stimulates the DNA synthetic activity of hPoliota. In the presence of these protein factors, on undamaged DNA, the efficiency (V(max)/K(m)) of correct nucleotide incorporation by hPoliota is increased approximately 80-150-fold, and this increase in efficiency results from a reduction in the apparent K(m) for the nucleotide. PCNA, RFC, and RPA also stimulate nucleotide incorporation opposite the 3'-T of the (6) thymine-thymine (T-T) photoproduct and opposite an abasic site. The interaction of hPoliota with PCNA implies that the targeting of this polymerase to the replication machinery stalled at a lesion site is achieved via this association.

Physical and functional interactions of human DNA polymerase eta with PCNA.

Human DNA polymerase eta (hPoleta) functions in the error-free replication of UV-damaged DNA, and mutations in hPoleta cause cancer-prone syndrome, the variant form of xeroderma pigmentosum. However, in spite of its key role in promoting replication through a variety of distorting DNA lesions, the manner by which hPoleta is targeted to the replication machinery stalled at a lesion site remains unknown. Here, we provide evidence for the physical interaction of hPoleta with proliferating cell nuclear antigen (PCNA) and show that mutations in the PCNA binding motif of hPoleta inactivate this interaction. PCNA, together with replication factor C and replication protein A, stimulates the DNA synthetic activity of hPoleta, and steady-state kinetic studies indicate that this stimulation accrues from an increase in the efficiency of nucleotide insertion resulting from a reduction in the apparent K(m) for the incoming nucleotide.

Interaction with PCNA is essential for yeast DNA polymerase eta function.

In both yeast and humans, DNA polymerase (Pol) eta functions in error-free replication of ultraviolet-damaged DNA, and Poleta promotes replication through many other DNA lesions as well. Here, we present evidence for the physical and functional interaction of yeast Poleta with proliferating cell nuclear antigen (PCNA) and show that the interaction with PCNA is essential for the in vivo function of Poleta. Poleta is highly inefficient at inserting a nucleotide opposite an abasic site, but interaction with PCNA greatly stimulates its ability for nucleotide incorporation opposite this lesion. Thus, in addition to having a pivotal role in the targeting of Poleta to the replication machinery stalled at DNA lesions, interaction with PCNA would promote the bypass of certain DNA lesions.

Role of DNA polymerase eta in the bypass of a (6-4) TT photoproduct.

UV light-induced DNA lesions block the normal replication machinery. Eukaryotic cells possess DNA polymerase eta (Poleta), which has the ability to replicate past a cis-syn thymine-thymine (TT) dimer efficiently and accurately, and mutations in human Poleta result in the cancer-prone syndrome, the variant form of xeroderma pigmentosum. Here, we test Poleta for its ability to bypass a (6-4) TT lesion which distorts the DNA helix to a much greater extent than a cis-syn TT dimer. Opposite the 3' T of a (6-4) TT photoproduct, both yeast and human Poleta preferentially insert a G residue, but they are unable to extend from the inserted nucleotide. DNA Polzeta, essential for UV induced mutagenesis, efficiently extends from the G residue inserted opposite the 3' T of the (6-4) TT lesion by Poleta, and Polzeta inserts the correct nucleotide A opposite the 5' T of the lesion. Thus, the efficient bypass of the (6-4) TT photoproduct is achieved by the combined action of Poleta and Polzeta, wherein Poleta inserts a nucleotide opposite the 3' T of the lesion and Polzeta extends from it. These biochemical observations are in concert with genetic studies in yeast indicating that mutations occur predominantly at the 3' T of the (6-4) TT photoproduct and that these mutations frequently exhibit a 3' T-->C change that would result from the insertion of a G opposite the 3' T of the (6-4) TT lesion.

Roles of yeast DNA polymerases delta and zeta and of Rev1 in the bypass of abasic sites.

Abasic (AP) sites are one of the most frequently formed lesions in DNA, and they present a strong block to continued synthesis by the replicative DNA machinery. Here we show efficient bypass of an AP site by the combined action of yeast DNA polymerases delta and zeta. In this reaction, Poldelta inserts an A nucleotide opposite the AP site, and Polzeta subsequently extends from the inserted nucleotide. Consistent with these observations, sequence analyses of mutations in the yeast CAN1s gene indicate that A is the nucleotide inserted most often opposite AP sites. The nucleotides C, G, and T are also incorporated, but much less frequently. Enzymes such as Rev1 and Poleta may contribute to the insertion of these other nucleotides; the predominant role of Rev1 in AP bypass, however, is likely to be structural. Steady-state kinetic analyses show that Polzeta is highly inefficient in incorporating nucleotides opposite the AP site, but it efficiently extends from nucleotides, particularly an A, inserted opposite this lesion. Thus, in eukaryotes, bypass of an AP site requires the sequential action of two DNA polymerases, wherein the extension step depends solely upon Polzeta, but the insertion step can be quite varied, involving not only the predominant action of the replicative DNA polymerase, Poldelta, but also the less prominent role of various translesion synthesis polymerases.

3'-phosphodiesterase and 3'-->5' exonuclease activities of yeast Apn2 protein and requirement of these activities for repair of oxidative DNA damage.

In Saccharomyces cerevisiae, the AP endonucleases encoded by the APN1 and APN2 genes provide alternate pathways for the removal of abasic sites. Oxidative DNA-damaging agents, such as H(2)O(2), produce DNA strand breaks which contain 3'-phosphate or 3'-phosphoglycolate termini. Such 3' termini are inhibitory to synthesis by DNA polymerases. Here, we show that purified yeast Apn2 protein contains 3'-phosphodiesterase and 3'-->5' exonuclease activities, and mutation of the active-site residue Glu59 to Ala in Apn2 inactivates both these activities. Consistent with these biochemical observations, genetic studies indicate the involvement of APN2 in the repair of H(2)O(2)-induced DNA damage in a pathway alternate to APN1, and the Ala59 mutation inactivates this function of Apn2. From these results, we conclude that the ability of Apn2 to remove 3'-end groups from DNA is paramount for the repair of strand breaks arising from the reaction of DNA with reactive oxygen species.

Inefficient bypass of an abasic site by DNA polymerase eta.

DNA polymerase eta (Pol eta) bypasses a cis-syn thymine-thymine dimer efficiently and accurately, and inactivation of Pol eta in humans results in the cancer-prone syndrome, the variant form of xeroderma pigmentosum. Also, Pol eta bypasses the 8-oxoguanine lesion efficiently by predominantly inserting a C opposite this lesion, and it bypasses the O(6)-methylguanine lesion by inserting a C or a T. To further assess the range of DNA lesions tolerated by Pol eta, here we examine the bypass of an abasic site, a prototypical noninstructional lesion. Steady-state kinetic analyses show that both yeast and human Pol eta are very inefficient in both inserting a nucleotide opposite an abasic site and in extending from the nucleotide inserted. Hence, Pol eta bypasses this lesion extremely poorly. These results suggest that Pol eta requires the presence of template bases opposite both the incoming nucleotide and the primer terminus to catalyze efficient nucleotide incorporation.

Replication past O(6)-methylguanine by yeast and human DNA polymerase eta.

O(6)-Methylguanine (m6G) is formed by the action of alkylating agents such as N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) on DNA. m6G is a highly mutagenic and carcinogenic lesion, and it presents a block to synthesis by DNA polymerases. Here, we provide genetic and biochemical evidence for the involvement of yeast and human DNA polymerase eta (Poleta) in the replicative bypass of m6G lesions in DNA. The formation of MNNG-induced mutations is almost abolished in the rad30Delta pol32Delta double mutant of yeast, which lacks the RAD30 gene that encodes Poleta and the Pol32 subunit of DNA polymerase delta (Poldelta). Although Poldelta can function in the mutagenic bypass of m6G lesions, our biochemical studies indicate that Poleta is much more efficient in replicating through m6G than Poldelta. Both Poleta and Poldelta insert a C or a T residue opposite from m6G; Poleta, however, is more accurate, as it inserts a C about twice as frequently as Poldelta. Alkylating agents are used in the treatment of malignant tumors, including lymphomas, brain tumors, melanomas, and gastrointestinal carcinomas, and the clinical effectiveness of these agents derives at least in part from their ability to form m6G in DNA. Inactivation of Poleta could afford a useful strategy for enhancing the effectiveness of these agents in cancer chemotherapy.

Eukaryotic polymerases iota and zeta act sequentially to bypass DNA lesions.

DNA lesions can often block DNA replication, so cells possess specialized low-fidelity, and often error-prone, DNA polymerases that can bypass such lesions and promote replication of damaged DNA. The Saccharomyces cerevisiae RAD30 and human hRAD30A encode Pol eta, which bypasses a cis-syn thymine-thymine dimer efficiently and accurately. Here we show that a related human gene, hRAD30B, encodes the DNA polymerase Pol iota, which misincorporates deoxynucleotides at a high rate. To bypass damage, Pol iota specifically incorporates deoxynucleotides opposite highly distorting or non-instructional DNA lesions. This action is combined with that of DNA polymerase Pol zeta, which is essential for damage-induced mutagenesis, to complete the lesion bypass. Pol zeta is very inefficient in inserting deoxynucleotides opposite DNA lesions, but readily extends from such deoxynucleotides once they have been inserted. Thus, in a new model for mutagenic bypass of DNA lesions in eukaryotes, the two DNA polymerases act sequentially: Pol iota incorporates deoxynucleotides opposite DNA lesions, and Pol zeta functions as a mispair extender.

Efficient and accurate replication in the presence of 7,8-dihydro-8-oxoguanine by DNA polymerase eta.

Oxidative damage to DNA has been proposed to have a role in cancer and ageing. Oxygen-free radicals formed during normal aerobic cellular metabolism attack bases in DNA, and 7, 8-dihydro-8-oxoguanine (8-oxoG) is one of the adducts formed. Eukaryotic replicative DNA polymerases replicate DNA containing 8-oxoG by inserting an adenine opposite the lesion; consequently, 8-oxoG is highly mutagenic and causes G:C to T:A transversions. Genetic studies in yeast have indicated a role for mismatch repair in minimizing the incidence of these mutations. In Saccharomyces cerevisiae, deletion of OGG1, encoding a DNA glycosylase that functions in the removal of 8-oxoG when paired with C, causes an increase in the rate of G:C to T:A transversions. The ogg1Delta msh2Delta double mutant displays a higher rate of CAN1S to can1r forward mutations than the ogg1Delta or msh2Delta single mutants, and this enhanced mutagenesis is primarily due to G:C to T:A transversions. The gene RAD30 of S. cerevisiae encodes a DNA polymerase, Poleta, that efficiently replicates DNA containing a cis-syn thymine-thymine (T-T) dimer by inserting two adenines across from the dimer. In humans, mutations in the yeast RAD30 counterpart, POLH, cause the variant form of xeroderma pigmentosum (XP-V), and XP-V individuals suffer from a high incidence of sunlight-induced skin cancers. Here we show that yeast and human POLeta replicate DNA containing 8-oxoG efficiently and accurately by inserting a cytosine across from the lesion and by proficiently extending from this base pair. Consistent with these biochemical studies, a synergistic increase in the rate of spontaneous mutations occurs in the absence of POLeta in the yeast ogg1Delta mutant. Our results suggest an additional role for Poleta in the prevention of internal cancers in humans that would otherwise result from the mutagenic replication of 8-oxoG in DNA.

Apurinic endonuclease activity of yeast Apn2 protein.

Abasic (apurinic/apyrimidinic; AP) sites are generated in vivo through spontaneous base loss and by enzymatic removal of bases damaged by alkylating agents and reactive oxygen species. In Saccharomyces cerevisiae, the APN1 and APN2 genes function in alternate pathways of AP site removal. Apn2-like proteins have been identified in other eukaryotes including humans, and these proteins form a distinct subfamily within the exonuclease III (ExoIII)/Ape1/Apn2 family of proteins. Apn2 and other members of this subfamily contain a carboxyl-terminal extension not present in the ExoIII/Ape1-like proteins. Here, we purify the Apn2 protein from yeast and show that it is a class II AP endonuclease. Deletion of the carboxyl terminus does not affect the AP endonuclease activity of the protein, but this protein is defective in the removal of AP sites in vivo. The carboxyl terminus may enable Apn2 to complex with other proteins, and such a multiprotein assembly may be necessary for the efficient recognition and cleavage of AP sites in vivo.

Mapping the ubiquitin-binding domains in the p54 regulatory complex subunit of the Drosophila 26S protease.

Short-lived intracellular proteins, after being marked by multiubiquitination, are degraded by the 26S protease. This large ATP-dependent protease is composed of two multiprotein complexes: the regulatory complex and the 20S proteosome. The selective recognition of ubiquitinated proteins is ensured by the regulatory complex. Using an overlay assay a single 54-kDa multiubiquitin-chain-binding subunit was detected in the regulatory complex of the Drosophila 26S protease. Overlay assay with the recombinant p54 subunit confirmed its ubiquitin-binding property. The recombinant protein showed pronounced preference for higher ubiquitin multimers, in agreement with the known preference of the 26S protease for multiubiquitinated proteins as substrates. To map the ubiquitin-binding domain of the p54 subunit different segments of the recombinant protein were expressed in E. coli and tested by the overlay assay. The p54 subunit carries two independent ubiquitin-binding domains. The central domain carries two highly conserved sequence blocks: the FGVDP sequence (at position 207), which is 100% conserved from yeast till human, and the DPELALALRVSMEE sequence (at position 214), which is 100% conserved in higher eukaryotes with two amino acid changes in yeast. In the C-terminal ubiquitin-binding domain the GVDP sequence motif is repeated and 100% conserved in higher eukaryotes. This domain, however, due to the shorter size of the yeast multiubiquitin-binding subunit, is present only in higher eukaryotes.

Dissection of the regulator complex of the Drosophila 26S protease by limited proteolysis.

The 26S protease responsible for the selective degradation of ubiquitinated proteins is composed of a regulator complex and the 20S proteosome which is the catalytic core. In the absence of ATP the 26S protease dissociates to free regulator complex and 20S proteosome, and this process can be reversed in vitro in the presence of ATP. Trypsin, chymotrypsin or proteinase K digestion selectively removes several subunits of the free regulator complex of Drosophila 26S protease generating a well-defined new subparticle. Three subunits highly sensitive in the free regulator complex, however, were selectively protected within the in vitro reconstituted 26S protease, indicating that the ATP-dependent association of the 20S proteosome in the regulator complex selectively shields these subunits. In the same concentration range the 20S proteosome was completely resistant for proteolytic degradation.

Cloning and sequencing a non-ATPase subunit of the regulatory complex of the Drosophila 26S protease.

We have cloned and sequenced a non-ATPase subunit of the regulatory complex of the Drosophila 26S protease. The gene is present in a single copy in the Drosophila genome. By comparing the nucleotide sequence of the genomic and cDNA clones three exons and two introns were localized. Two transcription start sites were identified 9 bp apart. The deduced protein sequence shows no significant similarity to any other protein in the database. In Drosophila embryos where the 26S protease is present in high concentration, the pool of free subunits of the regulatory complex is very low. Among the free subunits of the regulatory complex the cloned subunit is present in very large excess. This observation raises the possibility that this subunit is in a dynamic equilibrium, exchanging between a free and a particle-bound form, which may have important implications concerning its function.

Spermidine-induced alteration in the gene-spacer discrimination of nucleases in protonated DNA.

The sequence preference of a Drosophila lysosomal DNase was studied on the Drosophila hsp 70 heat-shock and histone recombinants, which carry six different genes, and the surrounding spacer sequences. The distribution of cleavage sites was random in respect of the locations of gene and spacer sequences. However, in the presence of 10 mM spermidine, a major transition was observed: the coding sequences became more susceptible than the spacer regions to nuclease attack. A similar transition was induced in the sequence preference of DNase I if the digestion was performed in the presence of spermidine at pH 5.2. At pH 7.5, spermidine does not influence the sequence preference of DNase I, which indicates the involvement of DNA protonation in this transition. In the presence of spermidine, the distributions of preferred and protected sequences were almost indistinguishable for these nucleases, suggesting that the protonated DNA, and not the enzymes, is the target of spermidine. A Drosophila embryonal protein was detected and partially purified which induced the same transition as observed in the presence of spermidine. The purified protein preferentially protected the spacer DNA sequences against acid DNase or DNase I cleavage in the hsp 70 heat-shock and histone gene recombinants. The protection was concentration dependent and occurred only at pH 5.2. The transition of nuclease specificity is probably due to a conformational change in the protonated DNA, induced by the binding of either the embryonal protein or spermidine.