Table 1.
The role of SIRT1 and its effects in response to DNA damage.
| Role of SIRT1 | Effects | Cell or Tissue Type | Reference |
|---|---|---|---|
| Protection against DNA damage | Absence of 6-4PP and Pt-GG in heterochromatin associated with SIRT1 | Human fibroblasts | [20] |
| Decreased levels of 8-OHdG after the increase in SIRT1 activity and mRNA level | Rat hippocampus | [64] | |
| Regulation of genomic stability and transcriptional changes | Relocalization of Sir2/3/4 and de-repression of epigenetically silencing genes in response to DNA damage | Yeast | [69] |
| Relocalization of SIRT1 to DSBs followed by transcriptional changes | Mammalian stem cells | [67] | |
| Recruitment of key epigenetic proteins (DNMTs, EZH2) to DNA damage site | Normal and cancer cells | [28,55,60,62,71] | |
| Deacetylation of HAT (hMOF) and E2F1 leading to downregulation of genes involved in DNA repair and genomic stability | Cancer cells | [48,74] | |
| Recruitment of DNA repair proteins contributing with viral activity, including gene transcription | Keratinocytes containing HPV episomes | [78] | |
| Modulation of DDR and DNA repair | Deacetylation of p53 interfering in cell death | Normal and cancer cells | reviewed in [41] |
| Deacetylation of γH2AX, Rad51, BRCA1 and NBS1, regulating the foci formation | MEFs | [52] | |
| Interaction with Ku70 protein belonging to NHEJ | Cancer cells | [88,89,90,91,92] | |
| Deacetylation of FOXO family favoring the expression of target repair genes, cell cycle arrest and resistance to oxidative stress | Normal cells | [81,82,83,84] | |
| Regulation of many important proteins to DDR and DNA repair, including ATM, NBS1, WRN, KAP1, XPA, MSH2, MSH6, APEX1 | Normal and cancer cells | [11,97,99,100,101,102,103,104,106] |