A Systematic Protein Turnover Map for Decoding Protein Degradation

Abstract

Protein degradation is mediated by an expansive and complex network of protein modification and degradation enzymes. Matching degradation enzymes with their targets and determining globally which proteins are degraded by the proteasome or lysosome/vacuole has been a major challenge. Further, an integrated view of protein degradation for cellular pathways has been lacking. Here we present a novel analytical platform that combines systematic gene deletions with quantitative measures of protein turnover to deconvolve protein degradation pathways forS. cerevisiae. The resulting turnover map (T-MAP) reveals target candidates of nearly all E2 and E3 ubiquitin ligases and identifies the primary degradation routes for most proteins. We further mined this T-MAP to identify new substrates of ER-associated Degradation (ERAD) involved in sterol biosynthesis and to uncover novel regulatory nodes for sphingolipid biosynthesis. The T-MAP approach should be broadly applicable to the study of other cellular processes and systems, including mammalian systems.One Sentence SummaryA systematic, global map of protein turnover for a large set of yeast mutants reveals scope and specificity of degradation pathways and identifies novel regulatory nodes for lipid metabolism.