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. 2025 Apr 7;224(4):e202405042.
doi: 10.1083/jcb.202405042. Epub 2025 Feb 14.

An S-acylated N-terminus and a conserved loop regulate the activity of the ABHD17 deacylase

Sydney Holme #  1   2 Jennifer Sapia #  3 Michael Davey  2 Stefano Vanni  3   4 Elizabeth Conibear  1   2
Affiliations

An S-acylated N-terminus and a conserved loop regulate the activity of the ABHD17 deacylase

Sydney Holme et al. J Cell Biol. .

Abstract

The dynamic addition and removal of long-chain fatty acids modulate protein function and localization. The α/β hydrolase domain-containing (ABHD) 17 enzymes remove acyl chains from membrane-localized proteins such as the oncoprotein NRas, but how the ABHD17 proteins are regulated is unknown. Here, we used cell-based studies and molecular dynamics simulations to show that ABHD17 activity is controlled by two mobile elements-an S-acylated N-terminal helix and a loop-that flank the putative substrate-binding pocket. Multiple S-acylation events anchor the N-terminal helix in the membrane, enabling hydrophobic residues in the loop to engage with the bilayer. This stabilizes the conformation of both helix and loop, alters the conformation of the binding pocket, and optimally positions the enzyme for substrate engagement. S-acylation may be a general feature of acyl-protein thioesterases. By providing a mechanistic understanding of how the lipid modification of a lipid-removing enzyme promotes its enzymatic activity, this work contributes to our understanding of cellular S-acylation cycles.

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Conflict of interest statement

Disclosures: The authors declare no competing interests exist.

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