Evolutionary conservation of the insulin gene structure in invertebrates: cloning of the gene encoding molluscan insulin-related peptide III from Lymnaea stagnalis

doi:10.1677/jme.0.0110103

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Journal of Molecular Endocrinology (1993) 11, 103-113 DOI: 10.1677/jme.0.0110103
© 1993 Society for Endocrinology

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Evolutionary conservation of the insulin gene structure in invertebrates: cloning of the gene encoding molluscan insulin-related peptide III from Lymnaea stagnalis

A B Smit, A van Marle, R van Elk, J Bogerd, H van Heerikhuizen and W P M Geraerts

Although insulins and structurally related peptides are foundin vertebrates as well as in invertebrates, it is not clearwhether the genes encoding these hormones have emerged froma single ancestral (insulin)-type of gene or, alternatively,have arisen independently through convergent evolution fromdifferent types of gene. To investigate this issue, we clonedthe gene encoding the molluscan insulin-related peptide III(MIP III) from the freshwater snail, Lymnaea stagnalis. Thepredicted MIP III preprohormone had the overall organizationof preproinsulin, with a signal peptide and A and B chains,connected by two putative C peptides. Although MIP III was foundto share key features with vertebrate insulins, it also hadunique structural characteristics in common with the previouslyidentified MIPs I and II, thus forming a distinct class of MIPpeptides within the insulin superfamily. MIP III is synthesizedin neurones in the brain. It is encoded by a gene with the overallorganization of the vertebrate insulin genes, with three exonsand two introns, of which the second intron interrupts the codingregion of the C peptides. Our data therefore demonstrate thatin the Archaemetazoa, the common ancestor of the vertebratesand invertebrates, a primordial peptide with a two-chain insulinconfiguration encoded by a primordial insulin-type gene musthave been present.

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