Project Details
Description
Project Summary/Abstract
Environmental toxins or endogenous insults such as reactive oxygen species (ROS) result in oxidative
stress within cells, leading to different types of damage in DNA or RNA, including Apurinic/apyrimidinic
(AP) sites and single-strand breaks (SSBs). As the most common type of DNA damage, SSBs have been
implicated in association with tumorigenesis, aging, and neurodegenerative disorders. Molecular
understanding of SSB repair pathway remains unclear, largely due to the lack of tractable experimental
systems. We and others have demonstrated recently that APE2 resolves SSB damage in Xenopus and
budding yeast. Although APE1 has been found critical for including DNA repair, redox regulation of
transcription, and RNA processing, it remains unclear how APE2 plays important roles in DNA and RNA
metabolism. It is significant to determine how APE2 plays an essential role in SSB repair, and how exactly
APE2 maintains genome stability. Our substantial preliminary data suggest that APE2’s 3'-5' exonuclease
activity is regulated via its dynamic interactions with single-strand DNA (ssDNA) and its interacting proteins,
and that APE2 associates with RNA and RNA-containing structures such as R-loop. We will dissect the
molecular mechanism of APE2 in metabolism in nucleic acids via two Specific Aims: (1) determine the
mechanism of how APE2 interacts with and processes AP sites and SSBs in DNA structures in
reconstitution system with purified proteins and in Xenopus egg extracts, and (2) determine how APE2
recognizes and repairs AP site and SSBs in RNA or RNA-containing structures. Biochemical, cell biology,
and molecular biology approaches will be utilized to conduct this hypothesis-driven structure-function
analysis of APE2-mediated metabolism of nucleic acids in Xenopus egg extracts and reconstitution
systems with purified proteins. Anticipated results from this project will make a paradigm shift on APE2-
mediated SSB repair in DNA/RNA metabolism to maintain genome stability. Notably, our findings will
provide novel insights into new strategies for cancer chemotherapies such as modulating the distinct
regulatory mechanisms of APE2 for SSB repair in genome integrity.
Environmental toxins or endogenous insults such as reactive oxygen species (ROS) result in oxidative
stress within cells, leading to different types of damage in DNA or RNA, including Apurinic/apyrimidinic
(AP) sites and single-strand breaks (SSBs). As the most common type of DNA damage, SSBs have been
implicated in association with tumorigenesis, aging, and neurodegenerative disorders. Molecular
understanding of SSB repair pathway remains unclear, largely due to the lack of tractable experimental
systems. We and others have demonstrated recently that APE2 resolves SSB damage in Xenopus and
budding yeast. Although APE1 has been found critical for including DNA repair, redox regulation of
transcription, and RNA processing, it remains unclear how APE2 plays important roles in DNA and RNA
metabolism. It is significant to determine how APE2 plays an essential role in SSB repair, and how exactly
APE2 maintains genome stability. Our substantial preliminary data suggest that APE2’s 3'-5' exonuclease
activity is regulated via its dynamic interactions with single-strand DNA (ssDNA) and its interacting proteins,
and that APE2 associates with RNA and RNA-containing structures such as R-loop. We will dissect the
molecular mechanism of APE2 in metabolism in nucleic acids via two Specific Aims: (1) determine the
mechanism of how APE2 interacts with and processes AP sites and SSBs in DNA structures in
reconstitution system with purified proteins and in Xenopus egg extracts, and (2) determine how APE2
recognizes and repairs AP site and SSBs in RNA or RNA-containing structures. Biochemical, cell biology,
and molecular biology approaches will be utilized to conduct this hypothesis-driven structure-function
analysis of APE2-mediated metabolism of nucleic acids in Xenopus egg extracts and reconstitution
systems with purified proteins. Anticipated results from this project will make a paradigm shift on APE2-
mediated SSB repair in DNA/RNA metabolism to maintain genome stability. Notably, our findings will
provide novel insights into new strategies for cancer chemotherapies such as modulating the distinct
regulatory mechanisms of APE2 for SSB repair in genome integrity.
Status | Finished |
---|---|
Effective start/end date | 15/12/22 → 30/11/23 |
Links | https://projectreporter.nih.gov/project_info_details.cfm?aid=10578464 |
Funding
- National Cancer Institute: US$74,333.00
ASJC Scopus Subject Areas
- Genetics
- Molecular Biology
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