Post‐translational modification: nature's escape from genetic imprisonment and the basis for dynamic information encoding

Abstract

We discuss protein post‐translational modification (PTM) from an information processing perspective. PTM at multiple sites on a protein creates a combinatorial explosion in the number of potential ‘mod‐forms’, or global patterns of modification. Distinct mod‐forms can elicit distinct downstream responses, so that the overall response depends partly on the effectiveness of a particular mod‐form to elicit a response and partly on the stoichiometry of that mod‐form in the molecular population. We introduce the ‘mod‐form distribution’—the relative stoichiometries of each mod‐form—as the most informative measure of a protein's state. Distinct mod‐form distributions may summarize information about distinct cellular and physiological conditions and allow downstream processes to interpret this information accordingly. Such information ‘encoding’ by PTMs may facilitate evolution by weakening the need to directly link upstream conditions to downstream responses. Mod‐form distributions provide a quantitative framework in which to interpret ideas of ‘PTM codes’ that are emerging in several areas of biology, as we show by reviewing examples of ion channels, GPCRs, microtubules, and transcriptional co‐regulators. We focus particularly on examples other than the well‐known ‘histone code’, to emphasize the pervasive use of information encoding in molecular biology. Finally, we touch briefly on new methods for measuring mod‐form distributions. WIREs Syst Biol Med 2012, 4:565–583. doi: 10.1002/wsbm.1185 This article is categorized under: Models of Systems Properties and Processes > Mechanistic Models Laboratory Methods and Technologies > Proteomics Methods Biological Mechanisms > Regulatory Biology