AlkBprotein is a protein found in E. coli, induced during an adaptive response and involved in the direct reversal of alkylation damage. AlkB specifically removes alkylation damage to single strandedDNA caused by SN2 type of chemical agents. It efficiently removes methyl groups from 1-methyl adenines, 3-methyl cytosines in SS DNA. AlkB is an alpha-ketoglutarate-dependent hydroxylase, a superfamily non-haem iron-containing proteins. It oxidatively demethylates the DNA substrate. Demethylation by AlkB is accompanied with release of CO2, succinate, and formaldehyde.
ABH3, like E. coli AlkB, is specific for SS DNA and RNAwhereas ABH2 has higher affinity for damages in double-stranded DNA. ALKBH8 has a RNA recognition motif, a methyltransferase domain, and an AlkB-like domain. The methyltransferase domain generates the wobble nucleoside 5-methoxycarbonylmethyluridine from its precursor 5-carboxymethyluridine. The AlkB-like domain generates -5-methoxycarbonylhydroxymethyluridine in Gly-tRNA-UCC. FTO, which is associated with obesity in humans, is the first identified RNAdemethylase. It demethylates N6-methyladenosine in mRNA. There is also another very different protein called AlkB or alkane hydroxylase. It is the catalytic subunit of a non-heme diiron protein, catalyzing the hydroxylation of alkanes, in aerobic bacteria that are able to utilize alkanes as a carbon source.
Functions
AlkB has since been shown to have an ever expanding range of substrates since its initial discovery by Sedgwick, Lindahl, Seeberg and Falnes. Not only does it remove alkylation damage from the positively charged 1-methyl adenines and 3-methyl cytosines, but also from the neutral bases of 1-methyl guanine and 3-methyl thymine. AlkB has been shown as the first example of a DNA repair enzyme converting one type of DNA damage that blocks DNA replication, to another type of damage that the DNA polymerase can traverse with ease. This was seen for the cyclic lesion ethanoadenine, which upon hydroxylation by AlkB, affords an N6-acetaldehyde lesion, thus affording an 'adenine' hydrogen-bonding face. In contrast to the previous types of alkylation damage removed by AlkB via a hydroxylation mechanism, AlkB has been shown to epoxidize the double bond of ethenoadenine, which is hydrolyzed to a diol, and ultimately released as the dialdehyde glyoxal, thus restoring the undamaged adenine in the DNA.
