Diversification of the Wnt gene family on the ancestral lineage of vertebrates

Abstract

Diversification of the Wnt genes, a family of powerful developmental regulator molecules, is inferred by molecular evolutionary analyses. Fifty-five recently determined partial sequences from a variety of vertebrates and invertebrates, together with 17 published sequences, mostly from the mouse and Drosophila melanogaster, are analyzed. Wnt-1 through -7 originated before the last common ancestor of arthropods and deuterostomes lived. Another round of gene duplication, involving Wnt-3, -5, -7, and -10, occurred after the echinoderm lineage arose, on the ancestral lineage of jawed vertebrates. Increased constraints were imposed on the Wnt genes when jawed vertebrates originated, as indicated by an overall 4-fold lower rate of amino acid replacements in jawed vertebrates compared with invertebrates and jawless vertebrates. The Wnt genes are thus inferred to have undergone a disproportionately high amount of structural and functional evolution in the relatively short time (approximately 100 million years) between the origin of the echinoderm lineage and the first diversification of jawed vertebrates. A model is presented for the relationship of functional diversification of developmental regulators and their rates of amino acid replacement.