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The chaperone code refers to the combinatorial array of posttranslational modifications - i.e. phosphorylation, acetylation, ubiquitination, methylation, etc - that target molecular chaperones to modulate their activity. Molecular chaperones are proteins specialized in folding and unfolding of the other cellular proteins and assembly and dismantling of protein complexes, thereby orchestrating the dynamic organization of the proteome. As a consequence, a limited number of chaperones must be able to act on a very large number of substrates in a highly regulated manner.
The chaperone code concept posits that combinations of posttranslational modifications at the surface of chaperones, including phosphorylation, acetylation, methylation, ubiquitination, etc, control protein folding/unfolding and protein complex assembly/disassembly by stipulating substrate specificity, activity, subcellular localization and co-factor binding. This conclusion emerges from the analysis of nearly two hundred reports in the literature <ref>Cloutier and Coulombe 2013 Biochim Biophys Acta; doi:pii: S1874-9399(13)00042-4. 10.1016/j.bbagrm.2013.02.010.</ref>, including a key article published in 2013 reporting on the discovery of a novel family of methyltransferases that preferentially target and regulate molecular chaperones <ref>Cloutier et al 2013 PLoS Genetics 9, e1003210.</ref>
A large number of diseases, including degenerative neuromuscular disorders and cancer, are associated with dysfunction of molecular chaperones. Decrypting and reprogramming the chaperone code represents a gigantic initiative that generates new hopes for the development of therapeutics for degenerative diseases.
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