| Popis: |
In eukaryotes, 5-methylcytosine is the predominant DNA base modification, followed by N6-methyladenine. However, N4-methylcytosine (4mC) is confined to bacteria. Here we report that 4mC can serve as an epigenetic mark in eukaryotes. Bdelloid rotifers, freshwater invertebrates with transposon-poor genomes that are rich in foreign genes, lack C5-methyltransferases but encode an amino-methyltransferase, N4CMT, captured from bacteria >60 Mya. N4CMT introduces 4mC into DNA, and its chromodomain shapes the "histone-read-DNA-write" architecture together with a "DNA-read-histone-write" SETDB1/eggless H3K9me3 histone methyltransferase variant preferentially binding 4mC-DNA, to maintain 4mC and silent chromatin at transposons and tandem repeats. Our results bring the third base modification into the eukaryotic repertoire, demonstrate how non-native DNA methyl groups can reshape complex epigenetic systems to suppress transposon proliferation, and establish horizontal gene transfer as the source of regulatory innovation in eukaryotes. |
