Genotypic Males Play an Important Role in the Creation of Genetic Diversity in Gynogenetic Gibel Carp.

Xin Zhao,Ming-Tao Wang,Chun Miao,Li Zhou,Tao Wang,Miao Ding,Xi-Yin Li,Yang Wang,Jian-Fang Gui,Zhi Li,Zhong-Wei Wang,Xiao-Juan Zhang,Wen-Xuan Du

doi:10.3389/fgene.2021.691923

Abstract

Unisexual lineages are commonly considered to be short-lived in the evolutionary process as accumulation of deleterious mutations stated by Muller’s ratchet. However, the gynogenetic hexaploid gibel carp (Carassius gibelio) with existence over 0.5 million years has wider ecological distribution and higher genetic diversity than its sexual progenitors, which provides an ideal model to investigate the underlying mechanisms on countering Muller’s ratchet in unisexual taxa. Unlike other unisexual lineages, the wild populations of gibel carp contain rare and variable proportions of males (1–26%), which are determined via two strategies including genotypic sex determination and temperature-dependent sex determination. Here, we used a maternal gibel carp from strain F to be mated with a genotypic male from strain A+, a temperature-dependent male from strain A+, and a male from another species common carp (Cyprinus carpio), respectively. When the maternal individual was mated with the genotypic male, a variant of gynogenesis was initiated, along with male occurrence, accumulation of microchromosomes, and creation of genetic diversity in the offspring. When the maternal individual was mated with the temperature-dependent male and common carp, typical gynogenesis was initiated that all the offspring showed the same genetic information as the maternal individual. Subsequently, we found out that the genotypic male nucleus swelled and contacted with the female nucleus after fertilization although it was extruded from the female nucleus eventually, which might be associated with the genetic variation in the offspring. These results reveal that genotypic males play an important role in the creation of genetic diversity in gynogenetic gibel carp, which provides insights into the evolution of unisexual reproduction.

Highlights

Compared with the prevalence in unicellular eukaryotes, plants and invertebrates (Roach et al, 2014), unisexual reproduction is rare in vertebrates (Avise, 2015; Burke and Bonduriansky, 2017; Li and Gui, 2018)
In the family derived from A+♂ of genotypic sex determination (GSD), 73.2% female and 26.8% male offspring were observed and the genotypic male-specific marker (GMM) (Li et al, 2016) was present in all sampled male offspring and the paternal A+♂ of GSD, which was absent in all female offspring and maternal F♀ (Figure 1A)
The offspring derived from A+♂ of TSD was composed of all females and the GMM was absent in all the female offspring and parental individuals (Figure 1B), which was the same as the typical gynogenetic family stimulated by Cc♂ (Figure 1C)

Summary

Introduction

Compared with the prevalence in unicellular eukaryotes, plants and invertebrates (Roach et al, 2014), unisexual reproduction is rare in vertebrates (Avise, 2015; Burke and Bonduriansky, 2017; Li and Gui, 2018). Since Amazon molly (Poecilia formosa) was first described to reproduce unisexually (Hubbs and Hubbs, 1932), about 100 taxa of vertebrates have been revealed (Avise, 2015) to have. Some unisexual taxa, such as Amazon molly (P. formosa) (Loewe and Lamatsch, 2008; Warren et al, 2018), salamanders (Ambystoma) (Bi and Bogart, 2010; Bogart, 2019), and gibel carp (Carassius gibelio) (Liu et al, 2017a,b), have wider ecological distribution than their relative sexual progenitors and have outlived their predicted time of extinction. Illustration of the underlying mechanisms how these unisexual lineages adapt to changing environment and live for a long time will provide insights on the evolution of reproduction modes

Methods

Results

Conclusion