Abstract

This study reports on a putative eicosanoid biosynthesis pathway in Drosophila melanogaster and challenges the currently held view that mechanistic routes to synthesize eicosanoid or eicosanoid-like biolipids do not exist in insects, since to date, putative fly homologs of most mammalian enzymes have not been identified. Here we use systematic and comprehensive bioinformatics approaches to identify most of the mammalian eicosanoid synthesis enzymes. Sensitive sequence analysis techniques identified candidate Drosophila enzymes that share low global sequence identities with their human counterparts. Twenty Drosophila candidates were selected based upon (a) sequence identity with human enzymes of the cyclooxygenase and lipoxygenase branches, (b) similar domain architecture and structural conservation of the catalytic domain, and (c) presence of potentially equivalent functional residues. Evaluation of full-length structural models for these 20 top-scoring Drosophila candidates revealed a surprising degree of conservation in their overall folds and potential analogs for functional residues in all 20 enzymes. Although we were unable to identify any suitable candidate for lipoxygenase enzymes, we report structural homology models of three fly cyclooxygenases. Our findings predict that the D. melanogaster genome likely codes for one or more pathways for eicosanoid or eicosanoid-like biolipid synthesis. Our study suggests that classical and/or novel eicosanoids mediators must regulate biological functions in insects–predictions that can be tested with the power of Drosophila genetics. Such experimental analysis of eicosanoid biology in a simple model organism will have high relevance to human development and health.

Highlights

  • The eicosanoids are a family of biologically active lipids that have been implicated in various signaling pathways, with a central role in mammalian immunity and inflammation [1,2,3]

  • The canonical eicosanoid biosynthesis pathway begins with the release of fatty acids, primarily arachidonic acid (AA), from membrane phospholipids when phospholipase A2 is activated [4,5]

  • Using a more sensitive approach based on iterative HMMER searches, we uncovered potential D. melanogaster candidates that may function as eicosanoid synthesis enzymes

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Summary

Introduction

The eicosanoids are a family of biologically active lipids that have been implicated in various signaling pathways, with a central role in mammalian immunity and inflammation [1,2,3]. The canonical eicosanoid biosynthesis pathway begins with the release of fatty acids, primarily arachidonic acid (AA), from membrane phospholipids when phospholipase A2 is activated [4,5]. The canonical pathway diverges, depending on whether the fatty acid substrate is processed by a cyclooxygenase (COX), lipoxygenase (LOX), or a P450 epoxygenase (P450E). The P450 epoxygenase pathway yields epoxyeicosatrienoic acids (EETs) [12]. These downstream products regulate diverse signaling pathways and biological processes [2,3,12,13,14]

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