Role of Protein Methylation in Regulation of Transcription

doi:10.1210/er.2004-0008

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Role of Protein Methylation in Regulation of Transcription

David Y. Lee, Catherine Teyssier, Brian D. Strahl, and Michael R. Stallcup^*

Departments of Biochemistry and Molecular Biology (D.Y.L., M.R.S.) and Pathology (C.T., M.R.S.), University of Southern California, Los Angeles, California 90089; and Department of Biochemistry and Biophysics (B.D.S.), University of North Carolina School of Medicine, Chapel Hill, North Carolina 27599

^* To whom correspondence should be addressed. E-mail: stallcup{at}usc.edu.

In the last few years, the discovery of lysine and argininemethylation in histones and other proteins and the enzymes thatcarry out these posttranslational modifications has added anew dimension to the signal transduction field. In particular,there has been a huge surge in our understanding of how methylationof nucleosomal histones at specific lysine or arginine residuesaffects chromatin conformations and either facilitates or inhibitstranscription from neighboring genes. It appears that the responsiblemethyltransferases can be targeted in some cases to specificgenes and in other cases to broader regions of euchromatin orheterochromatin. Methylation of histones is mechanisticallylinked to other types of histone modifications, such as acetylation,phosphorylation, and monoubiquitylation; combinations of thesemodifications cooperate to regulate chromatin structure andtranscription by stimulating or inhibiting binding of specificproteins. Although lysine methylation has thus far been observedalmost exclusively on histones, arginine methylation has beenobserved on a variety of other proteins associated with generegulation, including DNA-binding transcriptional activators,transcriptional coactivators, and many RNA binding proteinsinvolved in RNA processing, transport, and stability. Thus,lysine and arginine methylation of proteins, like many othertypes of posttranslational modifications, are regulated stepsof many specific signaling pathways.

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