Molecular evolution of the proopiomelanocortin system in Barn owl species.

Karin Löw,Luis M San-Jose,Anne-Lyse Ducrest,Nabil G Seidah,Céline Simon,Vera Uva,Alexandre Roulin,Stefan Kunz,Antonella Pasquato

doi:10.1371/journal.pone.0231163

Karin Löw, Luis M San-Jose + Show 7 more

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https://doi.org/10.1371/journal.pone.0231163

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Abstract

Examination of genetic polymorphisms in outbred wild-living species provides insights into the evolution of complex systems. In higher vertebrates, the proopiomelanocortin (POMC) precursor gives rise to α-, β-, and γ-melanocyte-stimulating hormones (MSH), which are involved in numerous physiological aspects. Genetic defects in POMC are linked to metabolic disorders in humans and animals. In the present study, we undertook an evolutionary genetic approach complemented with biochemistry to investigate the functional consequences of genetic polymorphisms in the POMC system of free-living outbred barn owl species (family Tytonidae) at the molecular level. Our phylogenetic studies revealed a striking correlation between a loss-of-function H9P mutation in the β-MSH receptor-binding motif and an extension of a poly-serine stretch in γ3-MSH to ≥7 residues that arose in the barn owl group 6–8 MYA ago. We found that extension of the poly-serine stretches in the γ-MSH locus affects POMC precursor processing, increasing γ3-MSH production at the expense of γ2-MSH and resulting in an overall reduction of γ-MSH signaling, which may be part of a negative feedback mechanism. Extension of the γ3-MSH poly-serine stretches ≥7 further markedly increases peptide hormone stability in plasma, which is conserved in humans, and is likely relevant to its endocrine function. In sum, our phylogenetic analysis of POMC in wild living owls uncovered a H9P β-MSH mutation subsequent to serine extension in γ3-MSH to 7 residues, which was then followed by further serine extension. The linked MSH mutations highlight the genetic plasticity enabled by the modular design of the POMC gene.

Highlights

In higher vertebrates, the melanocortin system is involved in numerous physiological aspects such as energy homeostasis, steroidogenesis, exocrine secretion, sexual function, and pigmentation [1,2,3]
A preliminary comparative analysis of POMC sequences across Strigiformes showed that owl species from the Strigidae family carry 3 serine residues in the homologous γ3-melanocyte-stimulating hormones (MSH) position and β-MSH histidine in position 9 (H9) wild-type alleles. This includes the tawny owl Strix aluco (SA), used as a comparative outgroup to Tytonidae in this study (Fig 1). These observations suggested that the polymorphisms in the γ3- and β-MSH loci found in Swiss barn owls may be restricted to Tytonidae, which prompted us to investigate the evolution of the POMC sequence throughout the phylogeny of this family
Our genetic studies in wild-living owl populations revealed a striking association between a H9P mutation in β-MSH and an extension of the poly-serine stretch in γ3-MSH to 7 to 24 residues in the Tytonidae family (Fig 7A)

Summary

Introduction

The melanocortin system is involved in numerous physiological aspects such as energy homeostasis, steroidogenesis, exocrine secretion, sexual function, and pigmentation [1,2,3]. The evolutionarily conserved melanocortin system comprises corticotropin. 310030_170108 of the Swiss National Science Foundation (www.snf.ch) to S.K., and Grants 31003A_173178 and 31003A_153467 of the Swiss National Science Foundation (www.snf.ch) to AR. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript

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