Brittney A. Manvilla scite author profile

The mammalian repair protein MBD4 (methyl-CpG-binding domain IV) excises thymine from mutagenic G·T mispairs generated by deamination of 5-methylcytosine (mC), and downstream base excision repair (BER) proteins restore a G·C pair. MBD4 is also implicated in active DNA demethylation, by initiating BER of G·T mispairs generated by a deaminase enzyme. The question of how mismatch glycosylases attain specificity for excising thymine from G·T but not A·T pairs remains largely unresolved. Here, we report a crystal structure of the glycosylase domain of human MBD4 (residues 427-580) bound to DNA containing an abasic nucleotide paired with guanine, providing a glimpse of the enzyme-product complex. The mismatched guanine remains intrahelical, nestled into a recognition pocket. MBD4 provides selective interactions with the mismatched guanine (N1H, N2H2) that are not compatible with adenine, which likely confer mismatch specificity. The structure reveals no interactions that would be expected to provide the MBD4 glycosylase domain with specificity for acting at CpG sites. Accordingly, we find modest 1.5- to 2.7-fold reductions in G·T activity upon altering the CpG context. In contrast, 37- to 580-fold effects were observed previously for TDG (thymine DNA glycosylase). These findings suggest that specificity of MBD4 for acting at CpG sites depends largely on its methyl-CpG-binding domain, which binds preferably to G·T mispairs in a methylated CpG site. MBD4 glycosylase cannot excise 5-formylcytosine (fC) or 5–carboxylcytosine (caC), intermediates in a Tet-initiated DNA demethylation pathway. Our structure suggests that MBD4 does not provide the electrostatic interactions needed to excise these oxidized forms of mC.

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Structure of human apurinic/apyrimidinic endonuclease 1 with the essential Mg²⁺cofactor

Manvilla

Pozharski

Toth

et al. 2013

Acta Crystallogr D Biol Cryst

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Apurinic/apyrimidinic endonuclease 1 (APE1) mediates the repair of abasic sites and other DNA lesions and is essential for base-excision repair and strand-break repair pathways. APE1 hydrolyzes the phosphodiester bond at abasic sites, producing 5 0 -deoxyribose phosphate and the 3 0 -OH primer needed for repair synthesis. It also has additional repair activities, including the removal of 3 0 -blocking groups. APE1 is a powerful enzyme that absolutely requires Mg 2+ , but the stoichiometry and catalytic function of the divalent cation remain unresolved for APE1 and for other enzymes in the DNase I superfamily. directly and two that bind inner-sphere water molecules are strictly conserved in the DNase I superfamily. This structure, together with a recent structure of the enzyme-product complex, inform on the stoichiometry and the role of Mg 2+ in APE1-catalyzed reactions.

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Functional Assessment of Population and Tumor-Associated APE1 Protein Variants

et al. 2013

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Apurinic/apyrimidinic endonuclease 1 (APE1) is the predominant AP site repair enzyme in mammals. APE1 also maintains 3′–5′ exonuclease and 3′-repair activities, and regulates transcription factor DNA binding through its REF-1 function. Since complete or severe APE1 deficiency leads to embryonic lethality and cell death, it has been hypothesized that APE1 protein variants with slightly impaired function will contribute to disease etiology. Our data indicate that except for the endometrial cancer-associated APE1 variant R237C, the polymorphic variants Q51H, I64V and D148E, the rare population variants G241R, P311S and A317V, and the tumor-associated variant P112L exhibit normal thermodynamic stability of protein folding; abasic endonuclease, 3′–5′ exonuclease and REF-1 activities; coordination during the early steps of base excision repair; and intracellular distribution when expressed exogenously in HeLa cells. The R237C mutant displayed reduced AP-DNA complex stability, 3′–5′ exonuclease activity and 3′-damage processing. Re-sequencing of the exonic regions of APE1 uncovered no novel amino acid substitutions in the 60 cancer cell lines of the NCI-60 panel, or in HeLa or T98G cancer cell lines; only the common D148E and Q51H variants were observed. Our results indicate that APE1 missense mutations are seemingly rare and that the cancer-associated R237C variant may represent a reduced-function susceptibility allele.

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NMR Studies Reveal an Unexpected Binding Site for a Redox Inhibitor of AP Endonuclease 1

et al. 2011

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AP endonuclease 1 (APE1) is a multi-faceted protein with essential roles in DNA repair and transcriptional regulation. APE1 (Ref-1) activates many transcription factors (TF), including AP-1 and NF-κB. While the mechanism of APE1 redox activity remains unknown, it may involve reduction of an oxidized Cys in the TF DNA-binding domain. Several small molecules inhibit APE1-mediated TF activation, including the quinone derivative E3330. It has been proposed some inhibitors bind near C65, a residue suggested to be important for TF activation, but the binding site has not been determined for any inhibitor. Remarkably, NMR and molecular docking studies here reveal E3330 binds in the DNA repair active site of APE1, far removed from C65. Accordingly, AP endonuclease activity is substantially inhibited by E3330 (100 μM), suggesting that E3330 may not selectively inhibit APE1 redox activity in cells, in contrast with previous proposals. A naphthoquinone analog of E3330, RN7-60, binds a site removed from both C65 and the repair active-site. While a detailed understanding of how these inhibitors work requires further studies into the mechanism of redox activity, our results do not support proposals that E3330 binds selectively (and slowly) to locally unfolded APE1, or that E3330 promotes formation of disulfide bonds in APE1. Rather, we suggest E3330 may suppress a conformational change needed for redox activity, disrupt productive APE1-TF binding, or block the proposed redox chaperone activity of APE1. Our results provide the first structural information for any APE1 redox inhibitor, and could facilitate development of improved inhibitors for research and perhaps clinical purposes.

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Coordination of MYH DNA glycosylase and APE1 endonuclease activities via physical interactions

et al. 2013

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MutY homologue (MYH) is a DNA glycosylase which excises adenine paired with the oxidative lesion 7,8-dihydro-8-oxoguanine (8-oxoG, or G°) during base excision repair (BER). Base excision by MYH results in an apurinic/apyrimidinic (AP) site in the DNA where the DNA sugar-phosphate backbone remains intact. A key feature of MYH activity is its physical interaction and coordination with AP endonuclease I (APE1), which subsequently nicks DNA 5' to the AP site. Because AP sites are mutagenic and cytotoxic, they must be processed by APE1 immediately after the action of MYH glycosylase. Our recent reports show that the interdomain connector (IDC) of human MYH (hMYH) maintains interactions with hAPE1 and the human checkpoint clamp Rad9-Rad1-Hus1 (9-1-1) complex. In this study, we used NMR chemical shift perturbation experiments to determine hMYH-binding site on hAPE1. Chemical shift perturbations indicate that the hMYH IDC peptide binds to the DNA-binding site of hAPE1 and an additional site which is distal to the APE1 DNA-binding interface. In these two binding sites, N212 and Q137 of hAPE1 are key mediators of the MYH/APE1 interaction. Intriguingly, despite the fact that hHus1 and hAPE1 both interact with the MYH IDC, hHus1 does not compete with hAPE1 for binding to hMYH. Rather, hHus1 stabilizes the hMYH/hAPE1 complex both in vitro and in cells. This is consistent with a common theme in BER, namely that the assembly of protein-DNA complexes enhances repair by efficiently coordinating multiple enzymatic steps while simultaneously minimizing the release of harmful repair intermediates.

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