Matthew Hogg scite author profile

Abasic sites are common DNA lesions, which are strong blocks to replicative polymerases and are potentially mutagenic when bypassed. We report here the 2.8 Å structure of the bacteriophage RB69 replicative DNA polymerase attempting to process an abasic site analog. Four different complexes were captured in the crystal asymmetric unit: two have DNA in the polymerase active site whereas the other two molecules are in the exonuclease mode. When compared to complexes with undamaged DNA, the DNA surrounding the abasic site reveals distinct changes suggesting why the lesion is so poorly bypassed: the DNA in the polymerase active site has not translocated and is therefore stalled, precluding extension. All four molecules exhibit conformations that differ from the previously published structures. The polymerase incorporates dAMP across the lesion under crystallization conditions, indicating that the different conformations observed in the crystal may be part of the active site switching reaction pathway.

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Structural basis for processive DNA synthesis by yeast DNA polymerase ɛ

Hogg

Osterman

Bylund

et al. 2013

Nat Struct Mol Biol

163

194

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DNA polymerase ɛ (Pol ɛ) is a high-fidelity polymerase that has been shown to participate in leading-strand synthesis during DNA replication in eukaryotic cells. We present here a ternary structure of the catalytic core of Pol ɛ (142 kDa) from Saccharomyces cerevisiae in complex with DNA and an incoming nucleotide. This structure provides information about the selection of the correct nucleotide and the positions of amino acids that might be critical for proofreading activity. Pol ɛ has the highest fidelity among B-family polymerases despite the absence of an extended β-hairpin loop that is required for high-fidelity replication by other B-family polymerases. Moreover, the catalytic core has a new domain that allows Pol ɛ to encircle the nascent double-stranded DNA. Altogether, the structure provides an explanation for the high processivity and high fidelity of leading-strand DNA synthesis in eukaryotes.

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Lesion Bypass Activity of DNA Polymerase θ (POLQ) Is an Intrinsic Property of the Pol Domain and Depends on Unique Sequence Inserts

Hogg¹,

Seki²,

Wood

et al. 2011

Journal of Molecular Biology

159

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POLQ (polθ) is a large, multi-domain DNA polymerase0020encoded in higher eukaryotic genomes. It is important for maintaining genetic stability in cells and helping protect cells from DNA damage caused by ionizing radiation. POLQ contains an N-terminal helicase-like domain, a large central domain of indeterminate function, and a C-terminal polymerase domain with sequence similarity to the A-family of DNA polymerases. The enzyme has several unique properties, including low fidelity and the ability to insert and extend past abasic sites and thymine glycol lesions. It is not known whether the abasic site bypass activity is an intrinsic property of the polymerase domain, or whether helicase activity is also required. Three “insertion” sequence elements present in POLQ are not found in any other A-family DNA polymerase and it has been proposed that they may lend some unique properties to POLQ. In this work we analyzed the activity of the DNA polymerase in the absence of each sequence insertion. We find that the pol domain is capable of highly efficient bypass of abasic sites in the absence of the helicase-like or central domains. Insertion 1 increases the processivity of the polymerase but has little, if any, bearing on the translesion synthesis properties of the enzyme. However, removal of insertions 2 and 3 reduces activity on undamaged DNA and completely abrogates the ability of the enzyme to bypass abasic sites or thymine glycol lesions.

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A structural rationale for stalling of a replicative DNA polymerase at the most common oxidative thymine lesion, thymine glycol

Aller

Rould

Hogg³

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

133

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Thymine glycol (Tg) is a common product of oxidation and ionizing radiation, including that used for cancer treatment. Although Tg is a poor mutagenic lesion, it has been shown to present a strong block to both repair and replicative DNA polymerases. The 2.65-Å crystal structure of a binary complex of the replicative RB69 DNA polymerase with DNA shows that the templating Tg is intrahelical and forms a regular Watson-Crick base pair with the incorporated A. The C5 methyl group protrudes axially from the ring of the damaged pyrimidine and hinders stacking of the adjacent 5 template guanine. The position of the displaced 5 template guanine is such that the next incoming nucleotide cannot be incorporated into the growing primer strand, and it explains why primer extension past the lesion is prohibited even though DNA polymerases can readily incorporate an A across from the Tg lesion.oxidative DNA damage ͉ structure ͉ DNA replication T hymine glycol (5,6-dihydro-5,6-dihydroxythymine; Tg), the most common oxidation product of thymine, is produced endogenously as a consequence of aerobic metabolism or via exogenous factors such as chemical oxidants or ionizing radiation (Fig. 1). It is estimated that 400 Tgs are formed per cell per day (1, 2), and the presence of Tg in DNA has been used as a marker for oxidative stress (1, 3). Moreover, Tg is one of the predominant types of base modifications produced by ionizing radiation (4, 5), including that used in cancer therapy.Of the oxidatively modified DNA bases retaining an intact ring, Tg is thought to induce the most distortion in the regular structure of DNA. Even though there are DNA repair enzymes specialized in excising Tg from the genome, such as human , statistically a few of the damaged bases will evade repair, which means that DNA polymerases will encounter these lesions during replication. Although Tg is a poor mutagenic lesion because it generally pairs with A (9), it has been shown to be a very effective block to DNA replication (10-13). When Tg is encountered as a templating base by replicative or repair polymerases, termination of primer extension occurs immediately past the lesion site with A inserted opposite the Tg. Even in the presence of proofreading, extension proceeds no further. This finding contrasts with the situation observed when the lesion is an abasic site, where, in the presence of proofreading, termination sites are observed one base before the lesion (14). Therefore, it is extension past the Tg⅐adenine pair, rather than insertion across Tg, that constitutes the block to the replicative polymerases. Because Tg is a strong block to repair and replicative DNA polymerases in vitro (10-13), not surprisingly, it is a lethal lesion in vivo (9,(15)(16)(17)(18).Unlike normal DNA bases, Tg is nonplanar because of the loss of aromatic character that accompanies the addition of hydroxyl groups at the 5 and 6 positions of the ring (19). Computational simulations (20,21) predict that the axial orientation of the methyl group with respect to the pyrimidine r...

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Structural and Biochemical Investigation of the Role in Proofreading of a β Hairpin Loop Found in the Exonuclease Domain of a Replicative DNA Polymerase of the B Family

Hogg

Aller

Konigsberg

et al. 2007

Journal of Biological Chemistry

120

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Replicative DNA polymerases, as exemplified by the B family polymerases from bacteriophages T4 and RB69, not only replicate DNA but also have the ability to proofread misincorporated nucleotides. Because the two activities reside in separate protein domains, polymerases must employ a mechanism that allows for efficient switching of the primer strand between the two active sites to achieve fast and accurate replication. Prior mutational and structural studies suggested that a ␤ hairpin structure located in the exonuclease domain of family B polymerases might play an important role in active site switching in the event of a nucleotide misincorporation. We show that deleting the ␤ hairpin loop in RB69 gp43 affects neither polymerase nor exonuclease activities. Single binding event studies with mismatched primer termini, however, show that the ␤ hairpin plays a role in maintaining the stability of the polymerase/DNA interactions during the binding of the primer DNA in the exonuclease active site but not on the return of the corrected primer to the polymerase active site. In addition, the deletion variant showed a more stable incorporation of a nucleotide opposite an abasic site. Moreover, in the 2.4 Å crystal structure of the ␤ hairpin deletion variant incorporating an A opposite a templating furan, all four molecules in the crystal asymmetric unit have DNA in the polymerase active site, despite the presence of DNA distortions because of the misincorporation, confirming that the primer strand is not stably bound within the exonuclease active site in the absence of the ␤ hairpin loop.

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Matthew Hogg

Crystallographic snapshots of a replicative DNA polymerase encountering an abasic site

Structural basis for processive DNA synthesis by yeast DNA polymerase ɛ

Lesion Bypass Activity of DNA Polymerase θ (POLQ) Is an Intrinsic Property of the Pol Domain and Depends on Unique Sequence Inserts

A structural rationale for stalling of a replicative DNA polymerase at the most common oxidative thymine lesion, thymine glycol

Structural and Biochemical Investigation of the Role in Proofreading of a β Hairpin Loop Found in the Exonuclease Domain of a Replicative DNA Polymerase of the B Family

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