Abstract

Extant genes can be modified, or ‘tinkered with’, to provide new roles or new characteristics of these genes. At the genetic level, this often involves gene duplication and specialization of the resulting genes into particular functions. We investigate how ligand-receptor partnerships evolve after gene duplication. While significant work has been conducted in this area, the examination of additional models should help us better understand the proposed models and potentially reveal novel evolutionary patterns and dynamics. We use bioinformatics, comparative genomics and phylogenetic analyses to show that preproghrelin and prepromotilin descended from a common ancestor and that a gene duplication generated these two genes shortly after the divergence of amphibians and amniotes. The evolutionary history of the receptor family differs from that of their cognate ligands. GPR39 diverges first, and an ancestral receptor gives rise to receptors classified as fish-specific clade A, GHSR and MLNR by successive gene duplications occurring before the divergence of tetrapods and ray-finned fish. The ghrelin/GHSR system is maintained and functionally conserved from fish to mammals. Motilin-MLNR specificity must have arisen by ligand-receptor coevolution after the MLN hormone gene diverged from the GHRL gene in the amniote lineage. Conserved molecular machinery can give rise to new neuroendocrine response mechanisms by the co-option of duplicated genes. Gene duplication is both parsimonious and creative in producing elements for evolutionary tinkering and plays a major role in gene co-option, thus aiding the evolution of greater biological complexity.

Highlights

  • Extant genes can be modified, or ‘tinkered with’, to provide new roles or new characteristics of these genes

  • TBlastN [12] was used to search for GHRL/maturation of prepromotilin (MLN)-like and growth hormone secretagogue receptor (GHSR)-like sequences in genome sequences for chimpanzee (Pan troglodytes) panTro2, orangutan (Pongo pygmaeus abelii) ponAbe2, rhesus (Macaca mulatta) rheMac2, marmoset (Callithrix jacchus) calJac1, mouse (Mus musculus) mm9, rat (Rattus norvegicus) rn4, guinea pig (Cavia porcellus) cavPor3, cat (Felis catus) felCat3, dog (Canis lupus familiaris) canFam2, horse (Equus caballus) equCab2, cow (Bos taurus) bosTau4, opossum (Monodelphis domestica) monDom4, platypus (Ornithorhynchus anatinus) ornAna1, chicken (Gallus gallus) galGal3, lizard (Anolis carolinensis) anoCar1, X. tropicalis (Xenopus tropicalis) xenTro2, zebrafish (Danio rerio) danRer5, tetraodon (Tetraodon nigroviridis) tetNig1, fugu (Takifugu rubripes) fr2, stickleback (Gasterosteus aculeatus) gasAcu1 and medaka (Oryzias latipes) oryLat2, with the previously known genes used as queries

  • When we compared the genomic neighborhoods of the GHRL and MLN genes, we found no similarities

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Summary

Introduction

Extant genes can be modified, or ‘tinkered with’, to provide new roles or new characteristics of these genes. This often involves gene duplication and specialization of the resulting genes into particular functions. Conserved molecular machinery can give rise to new neuroendocrine response mechanisms by the co-option of duplicated genes. Gene duplication is both parsimonious and creative in producing elements for evolutionary tinkering and plays a major role in gene co-option, aiding the evolution of greater biological complexity. Ghrelin is a circulating peptide hormone derived by posttranslational cleavage from preproghrelin (GHRL). It is mainly secreted by the stomach. Do the ligands motilin and ghrelin show structural similarity, but their receptors have marked sequence similarity with an overall identity of 44%, which rises to 87% in the transmembrane regions. There is no evidence for cross-reactivity of the ligands, which is consistent with the different activities of the peptides [6]

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