Studying Epigenetic Complexes and Their Inhibitors with the Proteomics Toolbox

Overview

Journal Clin Epigenetics

Publisher Biomed Central

Specialty Genetics

Date 2016 Jul 21

PMID 27437033

Citations 8

Authors

David Weigt

Carsten Hopf

Guillaume Medard

Affiliations

Soon will be listed here.

Abstract

Some epigenetic modifier proteins have become validated clinical targets. With a few small molecule inhibitors already approved by national health administrations and many more in the pharmaceutical industry pipelines, there is a need for technologies that can promote full comprehension of the molecular action of these drugs. Proteomics, with its relatively unbiased nature, can contribute to a thorough understanding of the complexity of the megadalton complexes, which write, read and erase the histone code, and it can help study the on-target and off-target effect of the drugs designed to modulate their action. This review on the one hand gathers the published affinity probes able to decipher small molecule targets and off-targets in a close-to-native environment. These are small molecule analogues of epigenetic drugs conceived as protein target enrichment tools after they have engaged them in cells or lysates. Such probes, which have been designed for deacetylases, bromodomains, demethylases, and methyltransferases not only enrich their direct protein targets but also their stable interactors, which can be identified by mass spectrometry. Hence, they constitute a tool to study the epigenetic complexes together with other techniques also reviewed here: immunoaffinity purification with antibodies against native protein complex constituents or epitope tags, affinity matrices designed to bind recombinantly tagged protein, and enrichment of the complexes using histone tail peptides as baits. We expect that this toolbox will be adopted by more and more researchers willing to harness the spectacular advances in mass spectrometry to the epigenetic field.

Citing Articles

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Epigenetic Deregulation of Apoptosis in Cancers.

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Ganesan A, Arimondo P, Rots M, Jeronimo C, Berdasco M Clin Epigenetics. 2019; 11(1):174.

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