Adams R L
Department of Biochemistry, University of Glasgow, U.K.
Biochem J. 1990 Jan 15;265(2):309-20. doi: 10.1042/bj2650309.
DNA methylation is found almost ubiquitously in nature and the methyltransferases show evidence of a common evolutionary origin. It will be a fascinating study in protein evolution to follow the ways in which the structures of the various enzymes have developed. Although methylation may have a direct effect on DNA structure the evidence for the importance of this in vivo is accumulating only slowly. In contrast, there is now abundant evidence that methylation of DNA affects DNA-protein interactions and so may have a function in all processes in which such interactions occur. The binding of nucleases is affected in the processes of mismatch repair, DNA restriction and possibly demethylation during differentiation in vertebrates. The binding of transcription factors is affected by DNA methylation and the association of DNA with packaging and segregation proteins may play a part in the control of transcription and replication. The interplay of these effects makes DNA methylation a complex but rewarding area for study. Perhaps we should no longer refer to methylcytosine and methyladenine as minor bases, but rather as key bases which help regulate the functions of DNA.
DNA甲基化在自然界中几乎无处不在,甲基转移酶显示出共同进化起源的证据。追踪各种酶的结构是如何发展的,将是蛋白质进化领域一项引人入胜的研究。尽管甲基化可能对DNA结构有直接影响,但体内这种影响重要性的证据积累得很缓慢。相比之下,现在有大量证据表明,DNA甲基化会影响DNA与蛋白质的相互作用,因此可能在所有发生这种相互作用的过程中发挥作用。在错配修复、DNA限制以及脊椎动物分化过程中可能的去甲基化过程中,核酸酶的结合会受到影响。转录因子的结合受DNA甲基化影响,DNA与包装和分离蛋白的结合可能在转录和复制的控制中起作用。这些效应的相互作用使DNA甲基化成为一个复杂但值得研究的领域。也许我们不应再将甲基胞嘧啶和甲基腺嘌呤称为次要碱基,而应称它们为有助于调节DNA功能的关键碱基。