Marine ecosystems are rich in "omega-3" long-chain (C20-24) polyunsaturated fatty acids (LC-PUFA). Their production has been historically accepted to derive mostly from marine microbes. This long-standing dogma has been challenged recently by the discovery that numerous invertebrates, mostly with an aquatic life-style, have the enzyme machinery necessary for the de novo biosynthesis of polyunsaturated fatty acids (PUFA) and, from them, LC-PUFA. The key breakthrough was the detection in these animals of enzymes called "methyl-end desaturases" enabling PUFA de novo biosynthesis. Moreover, other enzymes with pivotal roles in LC-PUFA biosynthesis, including front-end desaturases and elongation of very long- chain fatty acids proteins, have been characterised in several non-vertebrate animal phyla. This review provides a comprehensive overview of the complement and functions of these gene/protein families in aquatic animals, particularly invertebrates and fish. Therefore, we expand and re-define our previous revision of the LC-PUFA biosynthetic enzymes present in chordates to animals as a whole, discussing how key genomic events have determined the diversity and distribution of desaturase and elongase genes in different taxa. We conclude that both invertebrates and fish display active, but markedly different, LC-PUFA biosynthetic gene networks that result from a complex evolutionary path combined with functional diversification and plasticity.
Clupeiformes, such as sardines and herrings, represent an important share of worldwide fisheries. Among those, the European sardine (Sardina pilchardus, Walbaum 1792) exhibits significant commercial relevance. While the last decade showed a steady and sharp decline in capture levels, recent advances in culture husbandry represent promising research avenues. Yet, the complete absence of genomic resources from sardine imposes a severe bottleneck to understand its physiological and ecological requirements. We generated 69 Gbp of paired-end reads using Illumina HiSeq X Ten and assembled a draft genome assembly with an N50 scaffold length of 25,579 bp and BUSCO completeness of 82.1% (Actinopterygii). The estimated size of the genome ranges between 655 and 850 Mb. Additionally, we generated a relatively high-level liver transcriptome. To deliver a proof of principle of the value of this dataset, we established the presence and function of enzymes (Elovl2, Elovl5, and Fads2) that have pivotal roles in the biosynthesis of long chain polyunsaturated fatty acids, essential nutrients particularly abundant in oily fish such as sardines. Our study provides the first omics dataset from a valuable economic marine teleost species, the European sardine, representing an essential resource for their effective conservation, management, and sustainable exploitation.