Background: Insulin is evolutionarily related to the insulin-like growth factors (IGFs) and like the latter stimulates a receptor tyrosine kinase (RTK) that transfers the extracellular hormonal signal into an intracellular response. Other hormones related to insulin, such as relaxin, do not use an RTK, but a G-protein coupled receptor (GPCR). This is unusual since evolutionarily related hormones typically either use the same or paralogous receptors. In arthropods three different IGF-related peptides likely evolved from a gene triplication, as in several species genes coding these three peptides are located next to one another on the same chromosomal fragment. Of these three hormones one, an IGF-like hormone, acts through an RTK, while the other two use a GPCR. This suggests that the ancestral IGF-like peptide may have used both types of receptors. These arthropod insulin-like peptides have homologs in vertebrates, which suggests that the initial gene triplication was perhaps already present in the last common ancestor of deuterostomes and protostomes. It would be interesting to know whether this is indeed so and to establish how insulin and other insulin-like peptides might be related to this trio of IGF-related hormones.
Methodology: Genes coding insulin and related peptides as well as their putative receptors were identified in genomes and transcriptomes from echinoderms and hemichordates.
Results: A similar triplet of genes coding insulin-like peptides is also found in some hemichordates and echinoderms. Two of the three ambulacrarian peptides are orthologs of arthropod IGF and Drosophila insulin-like peptide 7 (dilp7), while the third one looks like an ortholog of the arthropod peptide gonadulin. In echinoderms two novel insulin-like peptides emerged, gonad stimulating substance (GSS) and multinsulin, likely from gene duplications of the IGF and dilp7-like genes respectively. However, no novel receptors for insulin-like peptides evolved. If IGF were to act through both a GPCR and an RTK it would suggest that GSS acts on only one of the two receptors, possibly the RTK. The evolution of GSS from IGF may represent a pattern, where IGF gene duplications lead to novel genes coding shorter peptides that have lost their ability to activate a GPCR. It is likely this is how insulin and the insect neuroendocrine insulin-like peptides evolved independently from IGF.
Conclusion: The local gene triplication previously described from arthropods that yielded three genes coding IGF-related peptides was already present in the last common ancestor of protostomes and deuterostomes. It seems plausible that insulin and other insulin-like peptides, such as those produced by neuroendocrine cells in the brain of insects and echinoderm GSS evolved independently from IGF and thus are not true orthologs, but the result of convergent evolution.
EXPERIMENTAL INVESTIGATION ON CARBACETAM INFLUENCE ON HYPOTHALAMUS TISSUE IN BRAIN INJURY
