The roles of HMGB1-produced DNA gaps in DNA protection and aging biomarker reversal
The endogenous DNA damage triggering an aging progression in the elderly is prevented in the youth, probably by naturally occurring DNA gaps. Decreased DNA gaps are found during chronological aging in yeast. So we named the gaps “Youth-DNA-GAPs.” The gaps are hidden by histone deacetylation to preve...
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th-mahidol.837282023-06-18T23:47:22Z The roles of HMGB1-produced DNA gaps in DNA protection and aging biomarker reversal Yasom S. Mahidol University Biochemistry, Genetics and Molecular Biology The endogenous DNA damage triggering an aging progression in the elderly is prevented in the youth, probably by naturally occurring DNA gaps. Decreased DNA gaps are found during chronological aging in yeast. So we named the gaps “Youth-DNA-GAPs.” The gaps are hidden by histone deacetylation to prevent DNA break response and were also reduced in cells lacking either the high-mobility group box (HMGB) or the NAD-dependent histone deacetylase, SIR2. A reduction in DNA gaps results in shearing DNA strands and decreasing cell viability. Here, we show the roles of DNA gaps in genomic stability and aging prevention in mammals. The number of Youth-DNA-GAPs were low in senescent cells, two aging rat models, and the elderly. Box A domain of HMGB1 acts as molecular scissors in producing DNA gaps. Increased gaps consolidated DNA durability, leading to DNA protection and improved aging features in senescent cells and two aging rat models similar to those of young organisms. Like the naturally occurring Youth-DNA-GAPs, Box A-produced DNA gaps avoided DNA double-strand break response by histone deacetylation and SIRT1, a Sir2 homolog. In conclusion, Youth-DNA-GAPs are a biomarker determining the DNA aging stage (young/old). Box A-produced DNA gaps ultimately reverse aging features. Therefore, DNA gap formation is a potential strategy to monitor and treat aging-associated diseases. 2023-06-18T16:47:22Z 2023-06-18T16:47:22Z 2022-06-01 Article FASEB BioAdvances Vol.4 No.6 (2022) , 408-434 10.1096/fba.2021-00131 25739832 2-s2.0-85127256668 https://repository.li.mahidol.ac.th/handle/123456789/83728 SCOPUS |
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Biochemistry, Genetics and Molecular Biology Yasom S. The roles of HMGB1-produced DNA gaps in DNA protection and aging biomarker reversal |
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The endogenous DNA damage triggering an aging progression in the elderly is prevented in the youth, probably by naturally occurring DNA gaps. Decreased DNA gaps are found during chronological aging in yeast. So we named the gaps “Youth-DNA-GAPs.” The gaps are hidden by histone deacetylation to prevent DNA break response and were also reduced in cells lacking either the high-mobility group box (HMGB) or the NAD-dependent histone deacetylase, SIR2. A reduction in DNA gaps results in shearing DNA strands and decreasing cell viability. Here, we show the roles of DNA gaps in genomic stability and aging prevention in mammals. The number of Youth-DNA-GAPs were low in senescent cells, two aging rat models, and the elderly. Box A domain of HMGB1 acts as molecular scissors in producing DNA gaps. Increased gaps consolidated DNA durability, leading to DNA protection and improved aging features in senescent cells and two aging rat models similar to those of young organisms. Like the naturally occurring Youth-DNA-GAPs, Box A-produced DNA gaps avoided DNA double-strand break response by histone deacetylation and SIRT1, a Sir2 homolog. In conclusion, Youth-DNA-GAPs are a biomarker determining the DNA aging stage (young/old). Box A-produced DNA gaps ultimately reverse aging features. Therefore, DNA gap formation is a potential strategy to monitor and treat aging-associated diseases. |
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Mahidol University |
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Mahidol University Yasom S. |
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Article |
| author |
Yasom S. |
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Yasom S. |
| title |
The roles of HMGB1-produced DNA gaps in DNA protection and aging biomarker reversal |
| title_short |
The roles of HMGB1-produced DNA gaps in DNA protection and aging biomarker reversal |
| title_full |
The roles of HMGB1-produced DNA gaps in DNA protection and aging biomarker reversal |
| title_fullStr |
The roles of HMGB1-produced DNA gaps in DNA protection and aging biomarker reversal |
| title_full_unstemmed |
The roles of HMGB1-produced DNA gaps in DNA protection and aging biomarker reversal |
| title_sort |
roles of hmgb1-produced dna gaps in dna protection and aging biomarker reversal |
| publishDate |
2023 |
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https://repository.li.mahidol.ac.th/handle/123456789/83728 |
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