Abstract

Acyl chain remodeling in lipids is a critical biochemical process that plays a central role in disease. However, remodeling remains poorly understood, despite massive increases in lipidomic data. In this work, we determine the dynamic network of ethanolamine glycerophospholipid (PE) remodeling, using data from pulse-chase experiments and a novel bioinformatic network inference approach. The model uses a set of ordinary differential equations based on the assumptions that (1) sn1 and sn2 acyl positions are independently remodeled; (2) remodeling reaction rates are constant over time; and (3) acyl donor concentrations are constant. We use a novel fast and accurate two-step algorithm to automatically infer model parameters and their values. This is the first such method applicable to dynamic phospholipid lipidomic data. Our inference procedure closely fits experimental measurements and shows strong cross-validation across six independent experiments with distinct deuterium-labeled PE precursors, demonstrating the validity of our assumptions. In constrast, fits of randomized data or fits using random model parameters are worse. A key outcome is that we are able to robustly distinguish deacylation and reacylation kinetics of individual acyl chain types at the sn1 and sn2 positions, explaining the established prevalence of saturated and unsaturated chains in the respective positions. The present study thus demonstrates that dynamic acyl chain remodeling processes can be reliably determined from dynamic lipidomic data.

Highlights

  • Lipids are fundamental building blocks of cellular membranes and are essential for signal transduction, energy homeostasis, and many other cellular processes

  • These assumptions, which are based on previous findings on acyl remodeling of phosphatidylethanolamine, phosphatidylcholine and cardiolipin [19,20,26], allowed us to model the system using a simplified framework with a small number of parameters

  • We have presented the first method for inferring the processes and kinetic parameters of phospholipid remodeling from lipidomic data

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Summary

Introduction

Lipids are fundamental building blocks of cellular membranes and are essential for signal transduction, energy homeostasis, and many other cellular processes. Recent advances in massspectrometry have made large-scale quantification of lipidomes possible [1,2] and have revealed an unprecedented diversity of lipid species [3,4,5] Such lipidomics data provide an enormous amount of information, which should eventually lead to understanding of the mechanisms underlying lipid homeostasis and its impact on cellular functions. It was recently shown that obesity increases arachidonic acid in membrane phospholipids, and that subsequent lipid remodeling retargets arachidonic acid to ether lipids. This process is believed to make adipocytes more vulnerable to inflammation [14]

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