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Protein diagram

Investigating the function and substrate interaction network of ABHD16A, a novel regulator of protein S-acylation

Funder

Academy of Medical Sciences Springboard Award

Value

£99,992

Team

Dr Jennifer Greaves (Principal Investigator, Coventry University), Professor Nicholas Tomkinson (University of Strathclyde), and Dr Vania Moreira (University of Strathclyde). 

Dates

January 2021 to December 2022

Project overview

Dynamic protein S-acylation, the reversible post-translational addition of fatty-acyl moieties to proteins, is an essential process in human (patho)physiology. Changes in S-acylation, often in response to cellular signalling, regulates the trafficking, localisation and function of numerous, diverse proteins. S-acylation is catalysed by the opposing actions of two distinct enzyme families – ‘zDHHC’ family S-acyltransferases and metabolic Serine hydrolase family Acyl Protein Thioesterases (APTs). Although critical components of the S-acylation machinery, our understanding of how the APTs contribute to S-acylation dynamics is poorly understood. This study aims to characterise the molecular mechanisms and functions of a novel APT, ABHD16A.

Project objectives

ABHD16A, a known phosphatatidylserine-lipase involved in neuroimmunological function, was recently identified as a novel, selective APT. Using established biochemical, chemical- and cell-biological techniques, the objectives of this research are to:

  1. determine the molecular basis for ABHD16A-substate specificity;
  2. identify novel ABHD16A substrates; and
  3. ascertain functional roles of ABHD16A.

Impact

The importance of the APTs for normal physiology is highlighted in published research demonstrating altered APT function is associated with conditions such as Parkinson’s disease, cancer, vascular disease and obesity. By characterising the APT function of ABHD16A, this research will:

  1. facilitate our understanding of how the APTs control S-acylation;
  2. uncover new avenues of research leading to improved future health outcomes through increased understanding of mechanisms of human (patho)physiology; and,
  3. explore the potential of ABHD16A and other APTs to serve as a novel therapeutic targets for the treatment of human diseases.

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University of the year shortlisted
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