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. 2025 Apr 17;188(8):2267-2287.e21.
doi: 10.1016/j.cell.2025.02.021. Epub 2025 Mar 20.

Turnover atlas of proteome and phosphoproteome across mouse tissues and brain regions

Wenxue Li  1 Abhijit Dasgupta  2 Ka Yang  2 Shisheng Wang  3 Nisha Hemandhar-Kumar  4 Surendhar R Chepyala  2 Jay M Yarbro  2 Zhenyi Hu  5 Barbora Salovska  1 Eugenio F Fornasiero  6 Junmin Peng  7 Yansheng Liu  8
Affiliations

Turnover atlas of proteome and phosphoproteome across mouse tissues and brain regions

Wenxue Li et al. Cell. .

Abstract

Understanding how proteins in different mammalian tissues are regulated is central to biology. Protein abundance, turnover, and post-translational modifications such as phosphorylation are key factors that determine tissue-specific proteome properties. However, these properties are challenging to study across tissues and remain poorly understood. Here, we present Turnover-PPT, a comprehensive resource mapping the abundance and lifetime of 11,000 proteins and 40,000 phosphosites in eight mouse tissues and various brain regions using advanced proteomics and stable isotope labeling. We reveal tissue-specific short- and long-lived proteins, strong correlations between interacting protein lifetimes, and distinct impacts of phosphorylation on protein turnover. Notably, we discover a remarkable pattern of turnover changes for peroxisome proteins in specific tissues and that phosphorylation regulates the stability of neurodegeneration-related proteins, such as Tau and α-synuclein. Thus, Turnover-PPT provides fundamental insights into protein stability, tissue dynamic proteotypes, and functional protein phosphorylation and is accessible via an interactive web-based portal at https://yslproteomics.shinyapps.io/tissuePPT.

Keywords: DIA-MS; TMT; brain regions; mouse tissues; protein lifetime; protein phosphorylation; protein turnover; proteomics; pulse SILAC.

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Conflict of interest statement

Declaration of interests The authors declare no competing interests.

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