Abstract
Repair of oxidized base lesions in the human genome, initiated by DNA glycosylases, occurs via the base excision repair pathway using conserved repair and some non-repair proteins. However, the functions of the latter noncanonical proteins in base excision repair are unclear. Here we elucidated the role of heterogeneous nuclear ribonucleoprotein-U (hnRNP-U), identified in the immunoprecipitate of human NEIL1, a major DNA glycosylase responsible for oxidized base repair. hnRNP-U directly interacts with NEIL1 in vitro via the NEIL1 common interacting C-terminal domain, which is dispensable for its enzymatic activity. Their in-cell association increases after oxidative stress. hnRNP-U stimulates the NEIL1 in vitro base excision activity for 5-hydroxyuracil in duplex, bubble, forked, or single-stranded DNA substrate, primarily by enhancing product release. Using eluates from FLAG-NEIL1 immunoprecipitates from human cells, we observed 3-fold enhancement in complete repair activity after oxidant treatment. The lack of such enhancement in hnRNP-U-depleted cells suggests its involvement in repairing enhanced base damage after oxidative stress. The NEIL1 disordered C-terminal region binds to hnRNP-U at equimolar ratio with high affinity (K(d) = ∼54 nm). The interacting regions in hnRNP-U, mapped to both termini, suggest their proximity in the native protein; these are also disordered, based on PONDR (Predictor of Naturally Disordered Regions) prediction and circular dichroism spectra. Finally, depletion of hnRNP-U and NEIL1 epistatically sensitized human cells at low oxidative genome damage, suggesting that the hnRNP-U protection of cells after oxidative stress is largely due to enhancement of NEIL1-mediated repair.
Highlights
Oxidized bases in mammalian genome are repaired via base excision repair (BER) process that utilizes both common repair and noncanonical proteins
We detected a significant number of foci with NEIL1-heterogeneous nuclear ribonucleoprotein-U (hnRNP-U), whereas such signal was essentially absent when the primary Abs for NEIL1 or hnRNP-U were replaced with normal IgGs (Fig. 1A)
We tested for the presence of hnRNP-U in NEIL1 IP from HEK293 cells stably transfected with NEIL1-FLAG or empty-FLAG expression plasmid
Summary
Oxidized bases in mammalian genome are repaired via base excision repair (BER) process that utilizes both common repair and noncanonical proteins. Using eluates from FLAG-NEIL1 immunoprecipitates from human cells, we observed 3-fold enhancement in complete repair activity after oxidant treatment The lack of such enhancement in hnRNP-U-depleted cells suggests its involvement in repairing enhanced base damage after oxidative stress. Repair of oxidized bases in the mammalian genome is initiated with their excision by one of five DNA glycosylases (DGs): OGG1, NTH1, and NEIL 1–3 [10, 11]. Unlike NEIL2, NEIL1 is up-regulated during the S-phase and interacts functionally with DNA replication proteins, including proliferating cell nuclear antigen (PCNA), replication protein A (RPA), FEN-1, and Werner helicase (WRN), etc Based on these results, we have proposed that NEIL1 is preferentially involved in replication-coordinated BER (20 –23). We have documented the physical and functional interaction of NEIL1 with hnRNP-U, which enhances cell survival after oxidative stress by increasing NEIL1-mediated oxidized base repair
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