DNA Damage Reversal (Homo sapiens)
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Description
DNA damage can be directly reversed by dealkylation (Mitra and Kaina 1993). Three enzymes play a major role in reparative DNA dealkylation: MGMT, ALKBH2 and ALKBH3. MGMT dealkylates O-6-methylguanine in a suicidal reaction that inactivates the enzyme (Daniels et al. 2000, Rasimas et al. 2004, Duguid et al. 2005, Tubbs et al. 2007), while ALKBH2 and ALKBH3 dealkylate 1-methyladenine, 3-methyladenine, 3-methylcytosine and 1-ethyladenine (Duncan et al. 2002, Dango et al. 2011).
View original pathway at:Reactome.
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Bibliography
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- Trewick SC, Henshaw TF, Hausinger RP, Lindahl T, Sedgwick B.; ''Oxidative demethylation by Escherichia coli AlkB directly reverts DNA base damage.''; PubMed Europe PMC Scholia
- Feng C, Liu Y, Wang G, Deng Z, Zhang Q, Wu W, Tong Y, Cheng C, Chen Z.; ''Crystal structures of the human RNA demethylase Alkbh5 reveal basis for substrate recognition.''; PubMed Europe PMC Scholia
- Duncan T, Trewick SC, Koivisto P, Bates PA, Lindahl T, Sedgwick B.; ''Reversal of DNA alkylation damage by two human dioxygenases.''; PubMed Europe PMC Scholia
- Dango S, Mosammaparast N, Sowa ME, Xiong LJ, Wu F, Park K, Rubin M, Gygi S, Harper JW, Shi Y.; ''DNA unwinding by ASCC3 helicase is coupled to ALKBH3-dependent DNA alkylation repair and cancer cell proliferation.''; PubMed Europe PMC Scholia
- Sundheim O, Vågbø CB, Bjørås M, Sousa MM, Talstad V, Aas PA, Drabløs F, Krokan HE, Tainer JA, Slupphaug G.; ''Human ABH3 structure and key residues for oxidative demethylation to reverse DNA/RNA damage.''; PubMed Europe PMC Scholia
- Zhao X, Yang Y, Sun BF, Zhao YL, Yang YG.; ''FTO and obesity: mechanisms of association.''; PubMed Europe PMC Scholia
- Moore MH, Gulbis JM, Dodson EJ, Demple B, Moody PC.; ''Crystal structure of a suicidal DNA repair protein: the Ada O6-methylguanine-DNA methyltransferase from E. coli.''; PubMed Europe PMC Scholia
- Frayling TM, Timpson NJ, Weedon MN, Zeggini E, Freathy RM, Lindgren CM, Perry JR, Elliott KS, Lango H, Rayner NW, Shields B, Harries LW, Barrett JC, Ellard S, Groves CJ, Knight B, Patch AM, Ness AR, Ebrahim S, Lawlor DA, Ring SM, Ben-Shlomo Y, Jarvelin MR, Sovio U, Bennett AJ, Melzer D, Ferrucci L, Loos RJ, Barroso I, Wareham NJ, Karpe F, Owen KR, Cardon LR, Walker M, Hitman GA, Palmer CN, Doney AS, Morris AD, Smith GD, Hattersley AT, McCarthy MI.; ''A common variant in the FTO gene is associated with body mass index and predisposes to childhood and adult obesity.''; PubMed Europe PMC Scholia
- Dina C, Meyre D, Gallina S, Durand E, Körner A, Jacobson P, Carlsson LM, Kiess W, Vatin V, Lecoeur C, Delplanque J, Vaillant E, Pattou F, Ruiz J, Weill J, Levy-Marchal C, Horber F, Potoczna N, Hercberg S, Le Stunff C, Bougnères P, Kovacs P, Marre M, Balkau B, Cauchi S, Chèvre JC, Froguel P.; ''Variation in FTO contributes to childhood obesity and severe adult obesity.''; PubMed Europe PMC Scholia
- Chen B, Liu H, Sun X, Yang CG.; ''Mechanistic insight into the recognition of single-stranded and double-stranded DNA substrates by ABH2 and ABH3.''; PubMed Europe PMC Scholia
- Duguid EM, Rice PA, He C.; ''The structure of the human AGT protein bound to DNA and its implications for damage detection.''; PubMed Europe PMC Scholia
- Rasimas JJ, Dalessio PA, Ropson IJ, Pegg AE, Fried MG.; ''Active-site alkylation destabilizes human O6-alkylguanine DNA alkyltransferase.''; PubMed Europe PMC Scholia
- Tubbs JL, Pegg AE, Tainer JA.; ''DNA binding, nucleotide flipping, and the helix-turn-helix motif in base repair by O6-alkylguanine-DNA alkyltransferase and its implications for cancer chemotherapy.''; PubMed Europe PMC Scholia
- Lindahl T, Demple B, Robins P.; ''Suicide inactivation of the E. coli O6-methylguanine-DNA methyltransferase.''; PubMed Europe PMC Scholia
- Jia G, Fu Y, Zhao X, Dai Q, Zheng G, Yang Y, Yi C, Lindahl T, Pan T, Yang YG, He C.; ''N6-methyladenosine in nuclear RNA is a major substrate of the obesity-associated FTO.''; PubMed Europe PMC Scholia
- Han Z, Niu T, Chang J, Lei X, Zhao M, Wang Q, Cheng W, Wang J, Feng Y, Chai J.; ''Crystal structure of the FTO protein reveals basis for its substrate specificity.''; PubMed Europe PMC Scholia
- Xu C, Liu K, Tempel W, Demetriades M, Aik W, Schofield CJ, Min J.; ''Structures of human ALKBH5 demethylase reveal a unique binding mode for specific single-stranded N6-methyladenosine RNA demethylation.''; PubMed Europe PMC Scholia
- Aas PA, Otterlei M, Falnes PO, Vågbø CB, Skorpen F, Akbari M, Sundheim O, Bjørås M, Slupphaug G, Seeberg E, Krokan HE.; ''Human and bacterial oxidative demethylases repair alkylation damage in both RNA and DNA.''; PubMed Europe PMC Scholia
- Merkestein M, Sellayah D.; ''Role of FTO in Adipocyte Development and Function: Recent Insights.''; PubMed Europe PMC Scholia
- Zheng G, Dahl JA, Niu Y, Fedorcsak P, Huang CM, Li CJ, Vågbø CB, Shi Y, Wang WL, Song SH, Lu Z, Bosmans RP, Dai Q, Hao YJ, Yang X, Zhao WM, Tong WM, Wang XJ, Bogdan F, Furu K, Fu Y, Jia G, Zhao X, Liu J, Krokan HE, Klungland A, Yang YG, He C.; ''ALKBH5 is a mammalian RNA demethylase that impacts RNA metabolism and mouse fertility.''; PubMed Europe PMC Scholia
- Mitra S, Kaina B.; ''Regulation of repair of alkylation damage in mammalian genomes.''; PubMed Europe PMC Scholia
- Daniels DS, Mol CD, Arvai AS, Kanugula S, Pegg AE, Tainer JA.; ''Active and alkylated human AGT structures: a novel zinc site, inhibitor and extrahelical base binding.''; PubMed Europe PMC Scholia
- Vora RA, Pegg AE, Ealick SE.; ''A new model for how O6-methylguanine-DNA methyltransferase binds DNA.''; PubMed Europe PMC Scholia
History
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External references
DataNodes
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Annotated Interactions
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Source | Target | Type | Database reference | Comment |
---|---|---|---|---|
1-etA-dsDNA | R-HSA-5657642 (Reactome) | |||
1-etA-dsDNA | R-HSA-5657649 (Reactome) | |||
1-meA-dsDNA | R-HSA-5657637 (Reactome) | |||
1-meA-dsDNA | R-HSA-5657641 (Reactome) | |||
2OG | R-HSA-112118 (Reactome) | |||
2OG | R-HSA-112120 (Reactome) | |||
2OG | R-HSA-112121 (Reactome) | |||
2OG | R-HSA-112123 (Reactome) | |||
2OG | R-HSA-112124 (Reactome) | |||
2OG | R-HSA-112125 (Reactome) | |||
3-meC-dsDNA | R-HSA-5657617 (Reactome) | |||
3-meC-dsDNA | R-HSA-5657665 (Reactome) | |||
6-OMeG-dsDNA | R-HSA-5657651 (Reactome) | |||
ALKBH2:Fe2+:1-etA-dsDNA | Arrow | R-HSA-5657649 (Reactome) | ||
ALKBH2:Fe2+:1-etA-dsDNA | R-HSA-112121 (Reactome) | |||
ALKBH2:Fe2+:1-etA-dsDNA | mim-catalysis | R-HSA-112121 (Reactome) | ||
ALKBH2:Fe2+:1-meA-dsDNA | Arrow | R-HSA-5657641 (Reactome) | ||
ALKBH2:Fe2+:1-meA-dsDNA | R-HSA-112118 (Reactome) | |||
ALKBH2:Fe2+:1-meA-dsDNA | mim-catalysis | R-HSA-112118 (Reactome) | ||
ALKBH2:Fe2+:3-meC-dsDNA | Arrow | R-HSA-5657665 (Reactome) | ||
ALKBH2:Fe2+:3-meC-dsDNA | R-HSA-112120 (Reactome) | |||
ALKBH2:Fe2+:3-meC-dsDNA | mim-catalysis | R-HSA-112120 (Reactome) | ||
ALKBH2:Fe2+ | Arrow | R-HSA-112118 (Reactome) | ||
ALKBH2:Fe2+ | Arrow | R-HSA-112120 (Reactome) | ||
ALKBH2:Fe2+ | Arrow | R-HSA-112121 (Reactome) | ||
ALKBH2:Fe2+ | R-HSA-5657641 (Reactome) | |||
ALKBH2:Fe2+ | R-HSA-5657649 (Reactome) | |||
ALKBH2:Fe2+ | R-HSA-5657665 (Reactome) | |||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:1-etA-dsDNA | Arrow | R-HSA-5657642 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:1-etA-dsDNA | R-HSA-112125 (Reactome) | |||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:1-etA-dsDNA | mim-catalysis | R-HSA-112125 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:1-meA-dsDNA | Arrow | R-HSA-5657637 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:1-meA-dsDNA | R-HSA-112123 (Reactome) | |||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:1-meA-dsDNA | mim-catalysis | R-HSA-112123 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:3-meC-dsDNA | Arrow | R-HSA-5657617 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:3-meC-dsDNA | R-HSA-112124 (Reactome) | |||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3:3-meC-dsDNA | mim-catalysis | R-HSA-112124 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3 | Arrow | R-HSA-112123 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3 | Arrow | R-HSA-112124 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3 | Arrow | R-HSA-112125 (Reactome) | ||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3 | R-HSA-5657617 (Reactome) | |||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3 | R-HSA-5657637 (Reactome) | |||
ALKBH3:Fe2+:ASCC1:ASCC2:ASCC3 | R-HSA-5657642 (Reactome) | |||
CH2O | Arrow | R-HSA-112118 (Reactome) | ||
CH2O | Arrow | R-HSA-112120 (Reactome) | ||
CH2O | Arrow | R-HSA-112123 (Reactome) | ||
CH2O | Arrow | R-HSA-112124 (Reactome) | ||
CH3CHO | Arrow | R-HSA-112121 (Reactome) | ||
CH3CHO | Arrow | R-HSA-112125 (Reactome) | ||
CO2 | Arrow | R-HSA-112118 (Reactome) | ||
CO2 | Arrow | R-HSA-112120 (Reactome) | ||
CO2 | Arrow | R-HSA-112121 (Reactome) | ||
CO2 | Arrow | R-HSA-112123 (Reactome) | ||
CO2 | Arrow | R-HSA-112124 (Reactome) | ||
CO2 | Arrow | R-HSA-112125 (Reactome) | ||
MGMT:Zn2+:6-OMeG-dsDNA | Arrow | R-HSA-5657651 (Reactome) | ||
MGMT:Zn2+:6-OMeG-dsDNA | R-HSA-73892 (Reactome) | |||
MGMT:Zn2+:6-OMeG-dsDNA | mim-catalysis | R-HSA-73892 (Reactome) | ||
MGMT:Zn2+ | R-HSA-5657651 (Reactome) | |||
MetC-MGMT:Zn2+ | Arrow | R-HSA-73892 (Reactome) | ||
O2 | R-HSA-112118 (Reactome) | |||
O2 | R-HSA-112120 (Reactome) | |||
O2 | R-HSA-112121 (Reactome) | |||
O2 | R-HSA-112123 (Reactome) | |||
O2 | R-HSA-112124 (Reactome) | |||
O2 | R-HSA-112125 (Reactome) | |||
R-HSA-112118 (Reactome) | ALKBH2 catalyzes the removal of the methyl group from 1-methyladenine (1-meA) in a reaction that depends on oxygen, alpha-ketoglutarate and Fe2+. ALKBH2 thus directly reverses alkylation damage of DNA in the form of 1-meA, releasing formaldehyde. ALKBH2 is ~4-fold more active on dsDNA containing 1-methyladenine than 3-methylcytosine (Duncan et al. 2002). | |||
R-HSA-112120 (Reactome) | ALKBH2 catalyzes removal of the methyl group from 3-methylcytosine (3-meC) in a reaction that depends on oxygen, alpha-ketoglutarate and Fe2+. ALKBH2 thus directly reverses alkylation damage of DNA in the form of 3-meC, releasing formaldehyde (Duncan et al. 2002). | |||
R-HSA-112121 (Reactome) | ALKBH2 catalyzes removal of the ethyl group from 1-ethyladenine (1-etA) in a reaction that depends on oxygen, alpha-ketoglutarate and Fe2+. ALKBH2 thus directly reverses alkylation damage of DNA in the form of 1-etA, releasing acetaldehyde (Duncan et al. 2002). | |||
R-HSA-112123 (Reactome) | ALKBH3, a homolog of E.coli AlkB (Trewick et al. 2002), removes the methyl group from 1-methyladenine (1-meA) in a reaction dependent on alpha-ketoglutarate, oxygen and Fe2+. ALKBH3 directly reverses alkylating damage of DNA in the form of 1-meA that is accompanied with the release of formaldehyde (Duncan et al. 2002). The reversal of alkylating damage of dsDNA by ALKBH3 requires the presence of DNA helicase ASCC3, a component of the activating signal co-integrator complex (Dango et al. 2011). ALKBH3 can also repair methylated RNA (Aas et al. 2003). | |||
R-HSA-112124 (Reactome) | ALKBH3, a homolog of E.coli AlkB (Trewick et al. 2002), removes the methyl group from 3-methylcytosine (3-meC) in a reaction dependent on alpha-ketoglutarate, oxygen and Fe2+. ALKBH3 directly reverses the alkylating damage of DNA in the form of 3-meC, releasing formaldehyde (Duncan et al. 2002). The reversal of alkylating damage of dsDNA by ALKBH3 requires the presence of DNA helicase ASCC3, a component of the activating signal co-integrator complex (Dango et al. 2011). ALKBH3 can also repair methylated RNA (Aas et al. 2003). | |||
R-HSA-112125 (Reactome) | ALKBH3, a homolog of E.coli AlkB (Trewick et al. 2002), removes the ethyl group from 1-ethyladenine (1-etA) in a reaction dependent on alpha-ketoglutarate, oxygen and Fe2+. ALKBH3 directly reverses alkylating damage of DNA in the form of 1-etA, releasing acetaldehyde (Duncan et al. 2002). The reversal of alkylating damage of dsDNA by ALKBH3 requires the presence of DNA helicase ASCC3, a component of the activating signal co-activator complex (Dango et al. 2011). ALKBH3 can also repair methylated RNA (Aas et al. 2003). | |||
R-HSA-5657617 (Reactome) | ALKBH3 (ABH3) has a preference for binding single strand DNA or RNA containing alkylation damage. ALKBH3 associates with dsDNA containing 3-methylcytosine (3-meC-dsDNA) alkylation damage in the presence of ASCC3 DNA helicase. ASCC3 is a part of ASCC1:ASCC2:ASCC3 activating signal co-integrator complex, which unwinds dsDNA, providing an appropriate substrate for ALKBH3 (Duncan et al. 2002, Sundheim et al. 2006, Chen et al. 2010, Dango et al. 2011). ALKBH3 requires iron (Fe2+) for its catalytic activity (Duncan et al. 2002, Sundheim et al. 2006). ALKBH3 is ~2-fold more active on DNA containing 3-methylcytosine than 1-methyladenine (Duncan et al. 2002). | |||
R-HSA-5657637 (Reactome) | ALKBH3 (ABH3) has a preference for binding single strand DNA or RNA containing alkylation damage. ALKBH3 associates with dsDNA containing 1-methyladenine alkylation damage (1-meA-dsDNA) in the presence of ASCC3 DNA helicase. ASCC3 is a part of ASCC1:ASCC2:ASCC3 activating signal co-integrator complex, which unwinds dsDNA, providing an appropriate substrate for ALKBH3 (Duncan et al. 2002, Sundheim et al. 2006, Chen et al. 2010, Dango et al. 2011). ALKBH3 requires iron (Fe2+) for its catalytic activity (Duncan et al. 2002, Sundheim et al. 2006). | |||
R-HSA-5657641 (Reactome) | ALKBH2 binds alkylated DNA containing 1-methyladenine (1-meA). ALKBH2 preferentially binds double strand DNA (dsDNA) (Duncan et al. 2002, Aas et al. 2003, Chen et al. 2010). Iron (Fe2+) is needed for the catalytic activity of ALKBH2 (Duncan et al. 2002). | |||
R-HSA-5657642 (Reactome) | ALKBH3 (ABH3) has a preference for binding single strand DNA or RNA containing alkylation damage. ALKBH3 associates with dsDNA containing 1-ethyladenine alkylation damage (1-etA-dsDNA) in the presence of ASCC3 DNA helicase. ASCC3 is a part of ASCC1:ASCC2:ASCC3 activating signal co-integrator complex, which unwinds dsDNA, providing an appropriate subrate for ALKBH3 (Duncan et al. 2002, Sundheim et al. 2006, Chen et al. 2010, Dango et al. 2011). ALKBH3 requires iron (Fe2+) for its catalytic activity (Duncan et al. 2002, Sundheim et al. 2006). | |||
R-HSA-5657649 (Reactome) | ALKBH2 binds alkylated DNA containing 1-ethyladenine (1-etA). ALKBH2 preferentially binds double strand DNA (dsDNA) (Duncan et al. 2002, Aas et al. 2003, Chen et al. 2010). Iron (Fe2+) is needed for the catalytic activity of ALKBH2 (Duncan et al. 2002). | |||
R-HSA-5657651 (Reactome) | MGMT recognizes and binds DNA containing 6-O-methylguanine in a manner consistent with a helix-loop-wing DNA binding model, where guanine is flipped out in order to bring the methylated oxygen atom close to MGMT active site (Vora et al. 1998, Daniels et al. 2000). Weakened or distorted base-pairs formed by 6-O-methylguanine probably aid in the substrate recognition by MGMT (Duguid et al. 2005). MGMT is stabilized by Zn2+ binding (Daniels et al. 2000). | |||
R-HSA-5657665 (Reactome) | ALKBH2 binds alkylated DNA containing 3-methylcytosine (3-meC). ALKBH2 preferentially binds double strand DNA (dsDNA) (Duncan et al. 2002, Aas et al. 2003, Chen et al. 2010). Iron (Fe2+) is needed for the catalytic activity of ALKBH2 (Duncan et al. 2002). | |||
R-HSA-73892 (Reactome) | MGMT, just like its E.coli homolog Ada, is an O-6-methylguanine transferase (Lindahl et al. 1983, Moore et al. 1994) that removes the methyl group from the guanine and transfers it to the cysteine residue at position 145 on the protein itself. MGMT thus methylated is not regenerated, as the S-methylcysteine is very stable. This is an energetically expensive approach to DNA repair as one entire protein molecule is sacrificed per lesion that is corrected in this manner (Rasimas et al. 2004, Tubbs et al. 2007, Mitra and Kaina 1993). | |||
SUCCA | Arrow | R-HSA-112118 (Reactome) | ||
SUCCA | Arrow | R-HSA-112120 (Reactome) | ||
SUCCA | Arrow | R-HSA-112121 (Reactome) | ||
SUCCA | Arrow | R-HSA-112123 (Reactome) | ||
SUCCA | Arrow | R-HSA-112124 (Reactome) | ||
SUCCA | Arrow | R-HSA-112125 (Reactome) | ||
dsDNA | Arrow | R-HSA-112118 (Reactome) | ||
dsDNA | Arrow | R-HSA-112120 (Reactome) | ||
dsDNA | Arrow | R-HSA-112121 (Reactome) | ||
dsDNA | Arrow | R-HSA-112123 (Reactome) | ||
dsDNA | Arrow | R-HSA-112124 (Reactome) | ||
dsDNA | Arrow | R-HSA-112125 (Reactome) | ||
dsDNA | Arrow | R-HSA-73892 (Reactome) |