Structural and Kinetic Analysis of Nucleoside Triphosphate Incorporation Opposite an Abasic Site by Human Translesion DNA Polymerase η

The most common lesion in DNA is an abasic site resulting from glycolytic cleavage of a base. In a number of cellular studies, abasic sites preferentially code for dATP insertion (the “A rule”). In some cases frameshifts are also common. X-ray structures with abasic sites in oligonucleotides have been reported for several microbial and human DNA polymerases (pols), e.g. Dpo4, RB69, KlenTaq, yeast pol ι, human (h) pol ι, and human pol β. We reported previously that hpol η is a major pol involved in abasic site bypass (Choi, J.-Y., Lim, S., Kim, E. J., Jo, A., and Guengerich, F. P. (2010 J. Mol. Biol. 404, 34–44). hpol η inserted all four dNTPs in steady-state and pre-steady-state assays, preferentially inserting A and G. In LC-MS analysis of primer-template pairs, A and G were inserted but little C or T was inserted. Frameshifts were observed when an appropriate pyrimidine was positioned 5′ to the abasic site in the template. In x-ray structures of hpol η with a non-hydrolyzable analog of dATP or dGTP opposite an abasic site, H-bonding was observed between the phosphate 5′ to the abasic site and water H-bonded to N1 and N6 of A and N1 and O6 of G nucleoside triphosphate analogs, offering an explanation for what appears to be a “purine rule.” A structure was also obtained for an A inserted and bonded in the primer opposite the abasic site, but it did not pair with a 5′ T in the template. We conclude that hpol η, a major copying enzyme with abasic sites, follows a purine rule, which can also lead to frameshifts. The phenomenon can be explained with H-bonds.     

Cloning and Characterization of the Human Mitochondrial DNA Polymerase, DNA Polymerase γ

The nuclear-encoded DNA polymerase γ (DNA POLγ) is the sole DNA polymerase required for the replication of the mitochondrial DNA. We have cloned the cDNA for human DNA POLγ and have mapped the gene to the chromosomal location 15q24. Additionally, the DNA POLγ gene fromDrosophila melanogasterand a partial cDNA for DNA POLγ fromGallus gallushave been cloned. The predicted human DNA POLγ polypeptide is 1239 amino acids, with a calculated molecular mass of 139.5 kDa. The human amino acid sequence is 41.6, 43.0, 48.7, and 77.6% identical to those ofSchizosaccharomyces pombe, Saccharomyces cerevisiae, Drosophila melanogaster,and the C-terminal half ofG. gallus,respectively. Polyclonal antibodies raised against the polymerase portion of the protein reacted specifically with a 140-kDa protein in mitochondrial extracts and immunoprecipitated a protein with DNA POLγ like activity from mitochondrial extracts. The human DNA POLγ is unique in that the first exon of the gene contains a CAG₁₀trinucleotide repeat.     

Crystal Structure of Yeast DNA Polymerase ε Catalytic Domain

DNA polymerase ε (Polε) is a multi-subunit polymerase that contributes to genomic stability via its roles in leading strand replication and the repair of damaged DNA. Here we report the ternary structure of the Polε catalytic subunit (Pol2) bound to a nascent G:C base pair (Pol2_G:C). Pol2_G:C has a typical B-family polymerase fold and embraces the template-primer duplex with the palm, fingers, thumb and exonuclease domains. The overall arrangement of domains is similar to the structure of Pol2_T:A reported recently, but there are notable differences in their polymerase and exonuclease active sites. In particular, we observe Ca²⁺ ions at both positions A and B in the polymerase active site and also observe a Ca²⁺ at position B of the exonuclease site. We find that the contacts to the nascent G:C base pair in the Pol2_G:C structure are maintained in the Pol2_T:A structure and reflect the comparable fidelity of Pol2 for nascent purine-pyrimidine and pyrimidine-purine base pairs. We note that unlike that of Pol3, the shape of the nascent base pair binding pocket in Pol2 is modulated from the major grove side by the presence of Tyr431. Together with Pol2_T:A, our results provide a framework for understanding the structural basis of high fidelity DNA synthesis by Pol2.     

Kinetics,Structure, and Mechanism of 8-Oxo-7,8-dihydro-2′-deoxyguanosine Bypass by Human DNA Polymerase η

DNA damage incurred by a multitude of endogenous and exogenous factors constitutes an inevitable challenge for the replication machinery. Cells rely on various mechanisms to either remove lesions or bypass them in a more or less error-prone fashion. The latter pathway involves the Y-family polymerases that catalyze trans-lesion synthesis across sites of damaged DNA. 7,8-Dihydro-8-oxo-2′-deoxyguanosine (8-oxoG) is a major lesion that is a consequence of oxidative stress and is associated with cancer, aging, hepatitis, and infertility. We have used steady-state and transient-state kinetics in conjunction with mass spectrometry to analyze in vitro bypass of 8-oxoG by human DNA polymerase η (hpol η). Unlike the high fidelity polymerases that show preferential insertion of A opposite 8-oxoG, hpol η is capable of bypassing 8-oxoG in a mostly error-free fashion, thus preventing GC→AT transversion mutations. Crystal structures of ternary hpol η-DNA complexes and incoming dCTP, dATP, or dGTP opposite 8-oxoG reveal that an arginine from the finger domain assumes a key role in avoiding formation of the nascent 8-oxoG:A pair. That hpol η discriminates against dATP exclusively at the insertion stage is confirmed by structures of ternary complexes that allow visualization of the extension step. These structures with G:dCTP following either 8-oxoG:C or 8-oxoG:A pairs exhibit virtually identical active site conformations. Our combined data provide a detailed understanding of hpol η bypass of the most common oxidative DNA lesion.     

The C-terminal Domain of the DNA Polymerase Catalytic Subunit Regulates the Primase and Polymerase Activities of the Human DNA Polymerase α-Primase Complex

The initiation of DNA synthesis during replication of the human genome is accomplished primarily by the DNA polymerase α-primase complex, which makes the RNA-DNA primers accessible to processive DNA pols. The structural information needed to understand the mechanism of regulation of this complex biochemical reaction is incomplete. The presence of two enzymes in one complex poses the question of how these two enzymes cooperate during priming of DNA synthesis. Yeast two-hybrid and direct pulldown assays revealed that the N-terminal domain of the large subunit of primase (p58N) directly interacts with the C-terminal domain of the catalytic subunit of polα (p180C). We found that a complex of the C-terminal domain of the catalytic subunit of polα with the second subunit (p180C-p70) stimulated primase activity, whereas the whole catalytically active heterodimer of polα (p180ΔN-p70) inhibited RNA synthesis by primase. Conversely, the polα catalytic domain without the C-terminal part (p180ΔN-core) possessed a much higher propensity to extend the RNA primer than the two-subunit polα (p180ΔN-p70), suggesting that p180C and/or p70 are involved in the negative regulation of DNA pol activity. We conclude that the interaction between p180C, p70, and p58 regulates the proper primase and polymerase function. The composition of the template DNA is another important factor determining the activity of the complex. We have found that polα activity strongly depends on the sequence of the template and that homopyrimidine runs create a strong barrier for DNA synthesis by polα.     

Structural and Functional Elucidation of the Mechanism Promoting Error-prone Synthesis by Human DNA Polymerase �� Opposite the 7,8-Dihydro-8-oxo-2��-deoxyguanosine Adduct

Human polymerase kappa (hPol κ) is one of four eukaryotic Y-class DNA polymerases and may be an important element in the cellular response to polycyclic aromatic hydrocarbons such as benzo[a]pyrene, which can lead to reactive oxygenated metabolite-mediated oxidative stress. Here, we present a detailed analysis of the activity and specificity of hPol κ bypass opposite the major oxidative adduct 7,8-dihydro-8-oxo-2′-deoxyguanosine (8-oxoG). Unlike its archaeal homolog Dpo4, hPol κ bypasses this lesion in an error-prone fashion by inserting mainly dATP. Analysis of transient-state kinetics shows diminished “bursts” for dATP:8-oxoG and dCTP:8-oxoG incorporation, indicative of non-productive complex formation, but dATP:8-oxoG insertion events that do occur are 2-fold more efficient than dCTP:G insertion events. Crystal structures of ternary hPol κ complexes with adducted template-primer DNA reveal non-productive (dGTP and dATP) alignments of incoming nucleotide and 8-oxoG. Structural limitations placed upon the hPol κ by interactions between the N-clasp and finger domains combined with stabilization of the syn-oriented template 8-oxoG through the side chain of Met-135 both appear to contribute to error-prone bypass. Mutating Leu-508 in the little finger domain of hPol κ to lysine modulates the insertion opposite 8-oxoG toward more accurate bypass, similar to previous findings with Dpo4. Our structural and activity data provide insight into important mechanistic aspects of error-prone bypass of 8-oxoG by hPol κ compared with accurate and efficient bypass of the lesion by Dpo4 and polymerase η.DNA damage incurred by a multitude of endogenous and exogenous factors constitutes an inevitable challenge for the replication machinery, and various mechanisms exist to either remove the resulting lesions or bypass them in a more or less mutation-prone fashion (1). Error-prone polymerases are central to trans-lesion synthesis across sites of damaged DNA (2, 3). Four so-called Y-class DNA polymerases have been identified in humans, Pol η,⁴ Pol ι, Pol κ, and Rev1, which exhibit different activities and abilities to replicate past a flurry of individual lesions (4, 5). Homologs have also been identified and characterized in other organisms, notably DinB (Pol IV) in Escherichia coli (6–8), Dbh in Sulfolobus acidocaldarius (9, 10), and Dpo4 in Sulfolobus solfataricus (11, 12). A decade of investigations directed at the structural and functional properties of bypass polymerases have significantly improved our understanding of this class of enzymes (5, 13). A unique feature of Y-class polymerases, compared with the common right-handed arrangement of palm, thumb, and finger subdomains of high fidelity (i.e. A-class) DNA polymerases (14), is a “little finger” or “PAD” (palm-associated domain) subdomain that plays a crucial role in lesion bypass (12, 15–21). In addition to the little finger subdomain at the C-terminal end of the catalytic core, both Rev1 and Pol κ exhibit an N-terminal extension that is absent in other translesion polymerases. The N-terminal extension in the structure of the ternary (human) hPol κ·DNA·dTTP complex folds into a U-shaped tether-helix-turn-helix “clasp” that is located between the thumb and little finger domains, allowing the polymerase to completely encircle the DNA (18). Although the precise role of the clasp for lesion bypass by hPol κ remains to be established, it is clear that this entity is functionally important, because mutant enzymes with partially or completely removed clasps exhibit diminished catalytic activity compared with the full-length catalytic core (hPol κ N1–526) or a core lacking the N-terminal 19 residues (hPol κ N19–526; the construct used for crystal structure determination of the ternary complex (18)).7,8-Dihydro-8-oxo-2′-deoxyguanosine (8-oxoG), found in both lower organisms and eukaryotes, is a major lesion that is a consequence of oxidative stress. The lesion is of relevance not only because of its association with cancer (22, 23), but also in connection with aging (24), hepatitis (25), and infertility (26). It is far from clear which DNA polymerases bypass 8-oxoG most often in a cellular context, but given the ubiquitous nature of the lesion it seems likely that more than one enzyme could encounter the lesion. Replicative polymerases commonly insert dATP opposite template 8-oxoG, with the lesion adopting the preferred syn conformation (e.g. 27, 28). It was recently found that the translesion polymerase Dpo4 from S. solfataricus synthesizes efficiently past 8-oxoG, inserting ≥95% dCTP > dATP opposite the lesion (29, 30). The efficient and low error bypass of the 8-oxoG lesion by Dpo4 is associated to a large extent with an arginine residue in the little finger domain (17). In the crystal structure of the ternary Dpo4·DNA·dCTP complex, the side chain of Arg-332 forms a hydrogen bond to the 8-oxygen of 8-oxoG, thus shifting the nucleoside conformational equilibrium toward the anti state and enabling a Watson-Crick binding mode with the incoming dCTP (30). The efficient and accurate replication of templates bearing 8-oxoG by yeast Pol η (31, 32) may indicate similarities between the bypass reactions catalyzed by the archaeal and eukaryotic enzymes. In contrast, bypass synthesis opposite 8-oxoG by human Pol κ is error-prone, resulting in efficient incorporation of A (33–35). The inaccurate bypass of 8-oxoG is thought to contribute to the deleterious effects associated with the lesion. These observations indicate different behaviors of the eukaryotic trans-lesion Pol κ and its archaeal “homolog” Dpo4 vis-à-vis the major oxidative stress lesion 8-oxoG. A mechanistic understanding of human DNA polymerases that bypass 8-oxoG in an error-prone fashion, such as hPol κ, is therefore of great interest.To elucidate commonalities and differences between the trans-8-oxoG syntheses of S. solfataricus Dpo4, yeast Pol η, and hPol κ, we carried out a comprehensive analysis of the bypass activity for the latter with template·DNA containing the 8-oxoG lesion, including pre-steady-state and steady-state kinetics of primer extension opposite and beyond 8-oxoG and LC-MS/MS assays of full-length extension products. We determined crystal structures of ternary hPol κ-(8-oxoG)DNA-dGTP and hPol κ-(8-oxoG)DNA-dATP complexes, apparently the first for any complex with adducted DNA for the κ enzyme reported to date. Our work demonstrates clear distinctions between genetically related translesion polymerases and provides insights into the origins of the error-prone reactions opposite 8-oxoG catalyzed by Y-family DNA polymerases.     

The Human Lagging Strand DNA Polymerase δ Holoenzyme Is Distributive

Polymerase δ is widely accepted as the lagging strand replicative DNA polymerase in eukaryotic cells. It forms a replication complex in the presence of replication factor C and proliferating cell nuclear antigen to perform efficient DNA synthesis in vivo. In this study, the human lagging strand holoenzyme was reconstituted in vitro. The rate of DNA synthesis of this holoenzyme, measured with a singly primed ssM13 DNA substrate, is 4.0 ± 0.4 nucleotides. Results from adenosine 5′-(3-thiotriphosphate) tetralithium salt (ATPγS) inhibition experiments revealed the nonprocessive characteristic of the human DNA polymerase (Pol δ) holoenzyme (150 bp for one binding event), consistent with data from chase experiments with catalytically inactive mutant Pol δ^AA. The ATPase activity of replication factor C was characterized and found to be stimulated ∼10-fold in the presence of both proliferating cell nuclear antigen and DNA, but the activity was not shut down by Pol δ in accord with rapid association/dissociation of the holoenzyme to/from DNA. It is noted that high concentrations of ATP inhibit the holoenzyme DNA synthesis activity, most likely due to its inhibition of the clamp loading process.     

NMR Structure and Dynamics of the C-Terminal Domain from Human Rev1 and Its Complex with Rev1 Interacting Region of DNA Polymerase η

Rev1 is a translesion synthesis (TLS) DNA polymerase essential for DNA damage tolerance in eukaryotes. In the process of TLS stalled high-fidelity replicative DNA polymerases are temporarily replaced by specialized TLS enzymes that can bypass sites of DNA damage (lesions), thus allowing replication to continue or postreplicational gaps to be filled. Despite its limited catalytic activity, human Rev1 plays a key role in TLS by serving as a scaffold that provides an access of Y-family TLS polymerases polη, ι, and κ to their cognate DNA lesions and facilitates their subsequent exchange to polζ that extends the distorted DNA primer-template. Rev1 interaction with the other major human TLS polymerases, polη, ι, κ, and the regulatory subunit Rev7 of polζ, is mediated by Rev1 C-terminal domain (Rev1-CT). We used NMR spectroscopy to determine the spatial structure of the Rev1-CT domain (residues 1157-1251) and its complex with Rev1 interacting region (RIR) from polη (residues 524-539). The domain forms a four-helix bundle with a well-structured N-terminal β-hairpin docking against helices 1 and 2, creating a binding pocket for the two conserved Phe residues of the RIR motif that upon binding folds into an α-helix. NMR spin-relaxation and NMR relaxation dispersion measurements suggest that free Rev1-CT and Rev1-CT/polη-RIR complex exhibit μs-ms conformational dynamics encompassing the RIR binding site, which might facilitate selection of the molecular configuration optimal for binding. These results offer new insights into the control of TLS in human cells by providing a structural basis for understanding the recognition of the Rev1-CT by Y-family DNA polymerases.     

Human DNA Polymerase ν Catalyzes Correct and Incorrect DNA Synthesis with High Catalytic Efficiency

DNA polymerase ν (pol ν) is a low fidelity A-family polymerase with a putative role in interstrand cross-link repair and homologous recombination. We carried out pre-steady-state kinetic analysis to elucidate the kinetic mechanism of this enzyme. We found that the mechanism consists of seven steps, similar that of other A-family polymerases. pol ν binds to DNA with a K_d for DNA of 9.2 nm, with an off-rate constant of 0.013 s⁻¹and an on-rate constant of 14 μm⁻¹ s⁻¹. dNTP binding is rapid with K_d values of 20 and 476 μm for the correct and incorrect dNTP, respectively. Pyrophosphorylation occurs with a K_d value for PP_i of 3.7 mm and a maximal rate constant of 11 s⁻¹. Pre-steady-state kinetics, examination of the elemental effect using dNTPαS, and pulse-chase experiments indicate that a rapid phosphodiester bond formation step is flanked by slow conformational changes for both correct and incorrect base pair formation. These experiments in combination with computer simulations indicate that the first conformational change occurs with rate constants of 75 and 20 s⁻¹; rapid phosphodiester bond formation occurs with a K_eq of 2.2 and 1.7, and the second conformational change occurs with rate constants of 2.1 and 0.5 s⁻¹, for correct and incorrect base pair formation, respectively. The presence of a mispair does not induce the polymerase to adopt a low catalytic conformation. pol ν catalyzes both correct and mispair formation with high catalytic efficiency.     

Roles of Residues Arg-61 and Gln-38 of Human DNA Polymerase η in Bypass of Deoxyguanosine and 7,8-Dihydro-8-oxo-2′-deoxyguanosine

Like the other Y-family DNA polymerases, human DNA polymerase η (hpol η) has relatively low fidelity and is able to tolerate damage during DNA synthesis, including 7,8-dihydro-8-oxo-2′-deoxyguanosine (8-oxoG), one of the most abundant DNA lesions in the genome. Crystal structures show that Arg-61 and Gln-38 are located near the active site and may play important roles in the fidelity and efficiency of hpol η. Site-directed mutagenesis was used to replace these side chains either alone or together, and the wild type or mutant proteins were purified and tested by replicating DNA past deoxyguanosine (G) or 8-oxoG. The catalytic activity of hpol η was dramatically disrupted by the R61M and Q38A/R61A mutations, as opposed to the R61A and Q38A single mutants. Crystal structures of hpol η mutant ternary complexes reveal that polarized water molecules can mimic and partially compensate for the missing side chains of Arg-61 and Gln-38 in the Q38A/R61A mutant. The combined data indicate that the positioning and positive charge of Arg-61 synergistically contribute to the nucleotidyl transfer reaction, with additional influence exerted by Gln-38. In addition, gel filtration chromatography separated multimeric and monomeric forms of wild type and mutant hpol η, indicating the possibility that hpol η forms multimers in vivo.     

News & Notes: Primary Structure of the DNA Polymerase I Gene of an α-Proteobacterium, Rhizobium leguminosarum, and Comparison with Other Family A DNA Polymerases

The structural gene for DNA polymerase I of Rhizobium leguminosarum was determined. The rhizobium DNA polymerase I consists of 1016 amino acid residues with a calculated molecular weight of 111,491 Dalton. The amino acid sequence comparison with E. coli DNA polymerase I, Thermus aquaticus DNA polymerase I, and Rickettsia prowazekii DNA polymerase I showed that, although 5′-nuclease and DNA polymerase domains are highly conserved, 3′ to 5′ exonuclease domains are much less conserved. While both R. leguminosarum and R. prowazekii belong to the alpha subdivision of the Proteobacteria on the basis of 16S ribosomal RNA phylogeny, the primary structure of the DNA polymerase I is quite different; the rhizobium DNA polymerase I has 3′ to 5′ proofreading exonuclease, but the rickettsia DNA polymerase I does not. Received: 15 December 1998 / Accepted: 2 February 1999     

Characterization of a Natural Mutator Variant of Human DNA Polymerase λ which Promotes Chromosomal Instability by Compromising NHEJ

Background

DNA polymerase lambda (Polλ) is a DNA repair polymerase, which likely plays a role in base excision repair (BER) and in non-homologous end joining (NHEJ) of DNA double-strand breaks (DSB).

Principal Findings

Here, we described a novel natural allelic variant of human Polλ (hPolλ) characterized by a single nucleotide polymorphism (SNP), C/T variation in the first base of codon 438, resulting in the amino acid change Arg to Trp. In vitro enzyme activity assays of the purified W438 Polλ variant revealed that it retained both DNA polymerization and deoxyribose phosphate (dRP) lyase activities, but had reduced base substitution fidelity. Ectopic expression of the W438 hPolλ variant in mammalian cells increases mutation frequency, affects the DSB repair NHEJ pathway, and generates chromosome aberrations. All these phenotypes are dependent upon the catalytic activity of the W438 hPolλ.

Conclusions

The expression of a cancer-related natural variant of one specialized DNA polymerase can be associated to generic instability at the cromosomal level, probably due a defective NHEJ. These results establish that chromosomal aberrations can result from mutations in specialized DNA repair polymerases.     

Human DNA Polymerase η Is Required for Common Fragile Site Stability during Unperturbed DNA Replication

Human DNA polymerase η (Pol η) modulates susceptibility to skin cancer by promoting translesion DNA synthesis (TLS) past sunlight-induced cyclobutane pyrimidine dimers. Despite its well-established role in TLS synthesis, the role of Pol η in maintaining genome stability in the absence of external DNA damage has not been well explored. We show here that short hairpin RNA-mediated depletion of Pol η from undamaged human cells affects cell cycle progression and the rate of cell proliferation and results in increased spontaneous chromosome breaks and common fragile site expression with the activation of ATM-mediated DNA damage checkpoint signaling. These phenotypes were also observed in association with modified replication factory dynamics during S phase. In contrast to that seen in Pol η-depleted cells, none of these cellular or karyotypic defects were observed in cells depleted for Pol ι, the closest relative of Pol η. Our results identify a new role for Pol η in maintaining genomic stability during unperturbed S phase and challenge the idea that the sole functional role of Pol η in human cells is in TLS DNA damage tolerance and/or repair pathways following exogenous DNA damage.Mutations in the POLH gene that encodes DNA polymerase η (Pol η) are responsible for the variant form of xeroderma pigmentosum (XP-V). XP-V is a rare autosomal recessive disorder characterized by extreme sensitivity to sunlight and a very high incidence of sunlight-induced skin cancer, as are the other forms of “classical” XP (17, 27). However, in contrast to the other nucleotide excision repair (NER)-defective XP complementation groups (XP-A to XP-G), XP-V cells have normal NER but cannot support translesion synthesis (TLS) past DNA-containing cyclobutane pyrimidine dimers (CPDs) (27). Purified Pol η, the TLS polymerase that is mutated in XP-V, is able to synthesize past this lesion with a high level of efficiency (28), and in a majority of cases it inserts the correct nucleotide, adenine, opposite the two thymines contained in the cyclobutane pyrimidine dimer ring (26).The ability to replicate efficiently past UV pyrimidine dimers has been the principal—or sole—function assigned thus far to Pol η. In the absence of Pol η, cells display an increased rate of UV-induced mutagenesis and carcinogenesis (23) that may reflect inefficient or error-prone synthesis by another polymerase. In mouse cells, this back-up polymerase may be Pol ι (12). Despite its ability to replicate past cyclobutane pyrimidine dimers, Pol η does not appear to be able to carry out TLS past the other major UV photoproduct, the pyrimidine (6-4) pyrimidone photoproduct [(6-4)PP] in vitro or in vivo. It can, however, replicate past a limited number of other types of DNA damage in vitro, albeit with a lower level of efficiency than past CPDs (21). Whether the bypass of these lesions is performed in vivo by Pol η is less clear. For example, XP-V cells are sensitive to cisplatin, suggesting that bypass of cisplatin lesions may depend on Pol η (1). Combined NER- and Pol η-mediated lesion bypass has also been suggested as the likely mechanism for repairing DNA interstrand cross-links formed by mitomycin C (46) and psoralen (32). In contrast, Pol η does not appear to play a role in replication past endogenous lesions such as 8-oxoguanine (3) or abasic sites (2).It has been difficult to visualize or identify sites of action of Pol η or any of the other TLS polymerases by immunofluorescence due to their low levels of expression. However, in cells that mildly overexpress Pol η, it has been possible to localize the polymerase to nuclear replication factories during S phase. This localization depends on several motifs located close to the C terminus of Pol η, including an NLS and a ubiquitin-binding zinc finger domain (7, 18). Localization of Pol η in replication factories may concentrate the polymerase near sites of replication to facilitate recruitment to carry out TLS. If cells cannot remove or synthesize through a lesion blocking the replication fork, then homology-dependent recombinational repair (HRR) may be used to restart the replication fork (11, 34). RAD51-mediated HRR has been shown to be important for the repair of DNA damage during replication in all organisms (20, 31, 42). Recent evidence has suggested that Pol η, in addition to its role in TLS, may participate in HRR. This has been suggested by analyses of gene conversion in chicken DT40 cells during immunoglobulin gene diversification (19), as well as by in vitro experiments showing that Pol η is capable of promoting extension of the invading strand in D-loop structures to facilitate RAD52-mediated second-end capture during recombination-mediated repair (29, 30). The functional importance of this observation is less clear. Recent evidence from yeast argues that the bulk of heteroduplex DNA strand extension during HRR is mediated by the preferential recruitment of a replicative DNA polymerase, Pol δ (25). Moreover, there is no obvious recombination deficit in XP-V patients or in XP-V cells beyond a modest elevation in the frequency of UV-induced sister chromatid exchanges (10).In order to better understand the functional roles and importance of Pol η in human cells, we used short hairpin RNAs (shRNAs) to selectively deplete Pol η from cells and then determined how the loss of Pol η affected cell cycle progression, DNA replication dynamics, and cell proliferation in otherwise unperturbed cells. These experiments revealed an unexpected role for Pol η in maintaining chromosomal stability and preventing common fragile site (CFS) breakage during unperturbed S phase. Our results thus broaden the functional role of Pol η in human cells to include the maintenance of genomic stability during unperturbed DNA replication in S phase.     

Identification of Critical Residues for the Tight Binding of Both Correct and Incorrect Nucleotides to Human DNA Polymerase λ

DNA polymerase λ (Pol λ) is a novel X-family DNA polymerase that shares 34% sequence identity with DNA polymerase β. Pre-steady-state kinetic studies have shown that the Pol λ-DNA complex binds both correct and incorrect nucleotides 130-fold tighter, on average, than the DNA polymerase β-DNA complex, although the base substitution fidelity of both polymerases is 10^− 4 to 10^− 5. To better understand Pol λ's tight nucleotide binding affinity, we created single-substitution and double-substitution mutants of Pol λ to disrupt the interactions between active-site residues and an incoming nucleotide or a template base. Single-turnover kinetic assays showed that Pol λ binds to an incoming nucleotide via cooperative interactions with active-site residues (R386, R420, K422, Y505, F506, A510, and R514). Disrupting protein interactions with an incoming correct or incorrect nucleotide impacted binding to each of the common structural moieties in the following order: triphosphate ? base > ribose. In addition, the loss of Watson-Crick hydrogen bonding between the nucleotide and the template base led to a moderate increase in K_d. The fidelity of Pol λ was maintained predominantly by a single residue, R517, which has minor groove interactions with the DNA template.     

Human satellite-III DNA: an example of a “macrosatellite” polymorphism

Summary Human satellite III DNA contains a complex polymorphism, which appears to be TaqI-specific. Its likely cause is a two-step point mutation in the pentameric repeat TTCCA, typical of satellite III. Hybridization of the satellite-III sequence-related probe that demonstrates this polymorphism is directly attributable to clusters of pure pentameric TTCCA repeats in the genome. The sites of such repeats include the 3.4-kb fragment specific to the Y chromosome and a limited number of autosomes. The polymorphism arises from the latter and is likely to include chromosomes containing so-called K domain satellite III sequences found, for example, in chromosomes 9 and 15. Segregation of the polymorphic fragments appears to follow orthodox genetics.