Recurrent co-option and recombination of cytokine and three finger proteins in multiple reproductive tissues throughout salamander evolution

Abstract

AbstractThe proteomic composition of amphibian gametes is largely a molecular mystery, particularly for Urodeles (salamanders and newts) which have few genomic-scale resources. Lungless salamanders (family Plethodontidae) include approximately two thirds of all extant salamander species and are classic models of vertebrate mating behavior. As part of an extended, multi-stage courtship ritual, male plethodontid salamanders deliver rapidly evolving protein pheromones that modify female behavior and improve male reproductive success. Despite great interest in this set of pre-mating reproductive barriers, limited characterization of plethodontid gametes has prohibited investigation of post-mating pre-zygotic barriers such as sperm-egg recognition. In this study, we performed transcriptomic analyses of testis and ovary using long-read PacBio sequencing and proteomic analyses of sperm using mass spectrometry for two evolutionary divergent plethodontid species, Plethodon shermani and Desmognathus ocoee. In both species, many of the most abundant sperm proteins were paralogs of the courtship pheromones Plethodontid Receptivity Factor (PRF), Plethodontid Modulating Factor (PMF), and Sodefrin Precursor-like Factor (SPF). Sperm-specific paralogs of PMF and SPF are likely the most abundant secreted proteins in P. shermani and D. ocoee, respectively. In contrast, sperm PRF lacks a signal peptide and may be expressed in cytoplasm. PRF pheromone genes evolved independently multiple times through repeated gene duplication of sperm PRF genes and signal peptides recovered by recombination with PMF genes. Phylogenetic analysis of courtship pheromones and their sperm paralogs support that each protein family evolved for these two reproductive contexts at distinct evolutionary time points between 17 and 360 million years ago. As the first molecular characterization of salamander gametes, this study expands our knowledge of amphibian fertilization beyond frogs and provides novel insight into the evolutionary processes by which new, rapidly evolving reproductive proteins may evolve.