Chimeric deubiquitinase engineering reveals structural basis for specific inhibition of USP30 and a framework for DUB ligandability

Nafizul Haque Kazi; Nikolas Klink; Kai Gallant; Gian-Marvin Kipka; Malte Gersch

doi:10.1101/2024.09.22.613429

Chimeric deubiquitinase engineering reveals structural basis for specific inhibition of USP30 and a framework for DUB ligandability

Nafizul Haque Kazi
, Nikolas Klink
, Kai Gallant
, Gian-Marvin Kipka
, Malte Gersch (Lead / Corresponding author)

MRC PPU

Research output: Working paper/Preprint › Preprint

Abstract

The mitochondrial deubiquitinase USP30 negatively regulates Pink1/Parkin-driven mitophagy. Whether enhanced mitochondrial quality control through inhibition of USP30 can protect dopaminergic neurons is currently explored in a clinical trial for Parkinson’s disease. However, the molecular basis for specific inhibition of USP30 by small molecules has remained elusive. Here, we report the crystal structure of human USP30 in complex with a specific inhibitor, enabled by chimeric protein engineering. Our study uncovers how the inhibitor extends into a cryptic pocket facilitated by a compound-induced conformation of the USP30 switching loop. Our work underscores the potential of exploring induced pockets and conformational dynamics to obtain specific deubiquitinase inhibitors and identifies underlying USP30-specific residues. More broadly, we delineate a conceptual framework for specific USP deubiquitinase inhibition based on a common ligandability hotspot in the Leu73-Ubiquitin binding site and on diverse compound extensions. Collectively, our work establishes a generalizable chimeric protein engineering strategy to aid deubiquitinase crystallization and enables structure-based drug design with relevance to neurodegeneration.

Original language	English
Publisher	BioRxiv
Number of pages	18
DOIs	https://doi.org/10.1101/2024.09.22.613429
Publication status	Published - 22 Sept 2024

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10.1101/2024.09.22.613429Licence: CC BY-NC

Chimeric deubiquitinase engineering reveals structural basis for specific inhibition of the mitophagy regulator USP30
Kazi, N. H., Klink, N., Gallant, K., Kipka, G.-M. & Gersch, M. (Lead / Corresponding author), Sept 2025, In: Nature Structural and Molecular Biology. 32, 9, p. 1776-1786 11 p.
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abstract = "The mitochondrial deubiquitinase USP30 negatively regulates Pink1/Parkin-driven mitophagy. Whether enhanced mitochondrial quality control through inhibition of USP30 can protect dopaminergic neurons is currently explored in a clinical trial for Parkinson{\textquoteright}s disease. However, the molecular basis for specific inhibition of USP30 by small molecules has remained elusive. Here, we report the crystal structure of human USP30 in complex with a specific inhibitor, enabled by chimeric protein engineering. Our study uncovers how the inhibitor extends into a cryptic pocket facilitated by a compound-induced conformation of the USP30 switching loop. Our work underscores the potential of exploring induced pockets and conformational dynamics to obtain specific deubiquitinase inhibitors and identifies underlying USP30-specific residues. More broadly, we delineate a conceptual framework for specific USP deubiquitinase inhibition based on a common ligandability hotspot in the Leu73-Ubiquitin binding site and on diverse compound extensions. Collectively, our work establishes a generalizable chimeric protein engineering strategy to aid deubiquitinase crystallization and enables structure-based drug design with relevance to neurodegeneration.",

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AU - Kipka, Gian-Marvin

AU - Gersch, Malte

PY - 2024/9/22

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N2 - The mitochondrial deubiquitinase USP30 negatively regulates Pink1/Parkin-driven mitophagy. Whether enhanced mitochondrial quality control through inhibition of USP30 can protect dopaminergic neurons is currently explored in a clinical trial for Parkinson’s disease. However, the molecular basis for specific inhibition of USP30 by small molecules has remained elusive. Here, we report the crystal structure of human USP30 in complex with a specific inhibitor, enabled by chimeric protein engineering. Our study uncovers how the inhibitor extends into a cryptic pocket facilitated by a compound-induced conformation of the USP30 switching loop. Our work underscores the potential of exploring induced pockets and conformational dynamics to obtain specific deubiquitinase inhibitors and identifies underlying USP30-specific residues. More broadly, we delineate a conceptual framework for specific USP deubiquitinase inhibition based on a common ligandability hotspot in the Leu73-Ubiquitin binding site and on diverse compound extensions. Collectively, our work establishes a generalizable chimeric protein engineering strategy to aid deubiquitinase crystallization and enables structure-based drug design with relevance to neurodegeneration.

AB - The mitochondrial deubiquitinase USP30 negatively regulates Pink1/Parkin-driven mitophagy. Whether enhanced mitochondrial quality control through inhibition of USP30 can protect dopaminergic neurons is currently explored in a clinical trial for Parkinson’s disease. However, the molecular basis for specific inhibition of USP30 by small molecules has remained elusive. Here, we report the crystal structure of human USP30 in complex with a specific inhibitor, enabled by chimeric protein engineering. Our study uncovers how the inhibitor extends into a cryptic pocket facilitated by a compound-induced conformation of the USP30 switching loop. Our work underscores the potential of exploring induced pockets and conformational dynamics to obtain specific deubiquitinase inhibitors and identifies underlying USP30-specific residues. More broadly, we delineate a conceptual framework for specific USP deubiquitinase inhibition based on a common ligandability hotspot in the Leu73-Ubiquitin binding site and on diverse compound extensions. Collectively, our work establishes a generalizable chimeric protein engineering strategy to aid deubiquitinase crystallization and enables structure-based drug design with relevance to neurodegeneration.

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Chimeric deubiquitinase engineering reveals structural basis for specific inhibition of USP30 and a framework for DUB ligandability

Abstract

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Research output

Chimeric deubiquitinase engineering reveals structural basis for specific inhibition of the mitophagy regulator USP30

Cite this