Discovery and mechanism of K63-linkage-directed deubiquitinase activity in USP53

Kim Wendrich; Kai Gallant; Sarah Recknagel; Stavroula Petroulia; Nafizul Haque Kazi; Jan Andre Hane; Siska Fuehrer; Karel Bezstarosti; Rachel O'Dea; Jeroen Demmers; Malte Gersch

doi:10.1038/s41589-024-01777-0

Discovery and mechanism of K63-linkage-directed deubiquitinase activity in USP53

Kim Wendrich
, Kai Gallant
, Sarah Recknagel
, Stavroula Petroulia
, Nafizul Haque Kazi
, Jan Andre Hane
, Siska Fuehrer
, Karel Bezstarosti
, Rachel O'Dea
, Jeroen Demmers
, Malte Gersch^*

^*Corresponding author for this work

Biochemistry

Research output: Contribution to journal › Article › Academic › peer-review

14 Citations (Web of Science)

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Abstract

Ubiquitin-specific proteases (USPs) represent the largest class of human deubiquitinases (DUBs) and comprise its phylogenetically most distant members USP53 and USP54, which are annotated as catalytically inactive pseudoenzymes. Conspicuously, mutations within the USP domain of USP53 cause progressive familial intrahepatic cholestasis. Here, we report the discovery that USP53 and USP54 are active DUBs with high specificity for K63-linked polyubiquitin. We demonstrate how USP53 mutations abrogate catalytic activity, implicating loss of DUB activity in USP53-mediated pathology. Depletion of USP53 increases K63-linked ubiquitination of tricellular junction components. Assays with substrate-bound polyubiquitin reveal that USP54 cleaves within K63-linked chains, whereas USP53 can en bloc deubiquitinate substrate proteins in a K63-linkage-dependent manner. Biochemical and structural analyses uncover underlying K63-specific S2 ubiquitin-binding sites within their catalytic domains. Collectively, our work revises the annotation of USP53 and USP54, provides reagents and a mechanistic framework to investigate K63-linked polyubiquitin decoding and establishes K63-linkage-directed deubiquitination as a new DUB activity. (Figure presented.)

Original language	English
Article number	524
Pages (from-to)	746-757
Number of pages	12
Journal	Nature Chemical Biology
Volume	21
Issue number	5
Early online date	25 Nov 2024
DOIs	https://doi.org/10.1038/s41589-024-01777-0
Publication status	Published - May 2025

Bibliographical note

Publisher Copyright:
© The Author(s) 2024.

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Cite this

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title = "Discovery and mechanism of K63-linkage-directed deubiquitinase activity in USP53",

abstract = "Ubiquitin-specific proteases (USPs) represent the largest class of human deubiquitinases (DUBs) and comprise its phylogenetically most distant members USP53 and USP54, which are annotated as catalytically inactive pseudoenzymes. Conspicuously, mutations within the USP domain of USP53 cause progressive familial intrahepatic cholestasis. Here, we report the discovery that USP53 and USP54 are active DUBs with high specificity for K63-linked polyubiquitin. We demonstrate how USP53 mutations abrogate catalytic activity, implicating loss of DUB activity in USP53-mediated pathology. Depletion of USP53 increases K63-linked ubiquitination of tricellular junction components. Assays with substrate-bound polyubiquitin reveal that USP54 cleaves within K63-linked chains, whereas USP53 can en bloc deubiquitinate substrate proteins in a K63-linkage-dependent manner. Biochemical and structural analyses uncover underlying K63-specific S2 ubiquitin-binding sites within their catalytic domains. Collectively, our work revises the annotation of USP53 and USP54, provides reagents and a mechanistic framework to investigate K63-linked polyubiquitin decoding and establishes K63-linkage-directed deubiquitination as a new DUB activity. (Figure presented.)",

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AU - Recknagel, Sarah

AU - Petroulia, Stavroula

AU - Kazi, Nafizul Haque

AU - Hane, Jan Andre

AU - Fuehrer, Siska

AU - Bezstarosti, Karel

AU - O'Dea, Rachel

AU - Demmers, Jeroen

AU - Gersch, Malte

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AB - Ubiquitin-specific proteases (USPs) represent the largest class of human deubiquitinases (DUBs) and comprise its phylogenetically most distant members USP53 and USP54, which are annotated as catalytically inactive pseudoenzymes. Conspicuously, mutations within the USP domain of USP53 cause progressive familial intrahepatic cholestasis. Here, we report the discovery that USP53 and USP54 are active DUBs with high specificity for K63-linked polyubiquitin. We demonstrate how USP53 mutations abrogate catalytic activity, implicating loss of DUB activity in USP53-mediated pathology. Depletion of USP53 increases K63-linked ubiquitination of tricellular junction components. Assays with substrate-bound polyubiquitin reveal that USP54 cleaves within K63-linked chains, whereas USP53 can en bloc deubiquitinate substrate proteins in a K63-linkage-dependent manner. Biochemical and structural analyses uncover underlying K63-specific S2 ubiquitin-binding sites within their catalytic domains. Collectively, our work revises the annotation of USP53 and USP54, provides reagents and a mechanistic framework to investigate K63-linked polyubiquitin decoding and establishes K63-linkage-directed deubiquitination as a new DUB activity. (Figure presented.)

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Discovery and mechanism of K63-linkage-directed deubiquitinase activity in USP53

Abstract

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