Abstract
Membrane fatty acid desaturases are a diverse superfamily of enzymes that catalyze the introduction of double bonds into fatty acids. They are essential in a range of metabolic processes, such as the production of omega-3 fatty acids. However, our structure–function understanding of this superfamily is still developing and their range of activities and substrate specificities are broad, and often overlapping, which has made their systematic characterization challenging. A central issue with characterizing these proteins has been the lack of a structural model, which has been overcome with the recent publication of the crystal structures of two mammalian fatty acid desaturases. In this work, we have used sequence similarity networks to investigate the similarity among over 5000 related membrane fatty acid desaturase sequences, leading to a detailed classification of the superfamily, families and subfamilies with regard to their function and substrate head-group specificity. This work will facilitate rapid prediction of the function and specificity of new and existing sequences, as well as forming a basis for future efforts to manipulate the substrate specificity of these proteins for biotechnology applications.
Highlights
In contrast to soluble fatty acid desaturases (FADs), which are acyl– acyl carrier protein specific [1,2], membrane FADs are a diverse family of proteins that display a range of lipid substrate preferences including acyl-CoAs, sphingolipids (SP), phospholipids (PL) and galactolipids (GL) [3,4]
Because of the high commercial value of the front-end desaturases (FEs) desaturases in the production of poly-unsaturated fatty acids, such as ω3-LCPUFAs [14], a more in-depth analysis of this family was performed. These results provide new directions for the future engineering membrane FADs
In order to characterize the sequence and functional diversity in the membrane FADs, the substrate head-group specificity, 5245 sequences were collected using the PFAM fatty acid desaturase family PF00487 as seed sequence clusters within the length range of 350 aa to 550 aa
Summary
In contrast to soluble fatty acid desaturases (FADs), which are acyl– acyl carrier protein (acyl-ACP) specific [1,2], membrane FADs are a diverse family of proteins that display a range of lipid substrate preferences including acyl-CoAs, sphingolipids (SP), phospholipids (PL) and galactolipids (GL) [3,4]. The acyl chains of these substrates can, in general, be quite similar, but the “head-groups” of these lipids differ and contribute to the different physiological roles (Fig. 1). Acyl-ACPs are important intermediates for a number of different metabolic pathways, including lipid biosynthesis [5], whereas PL and GL are important structural lipids, and play essential roles in different cellular signalling pathways [6]. Acyl-CoA substrates are especially important for the production of unusual lipids such as docosahexaenoic acid and eicosapentaenoic acid [14,20]
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