Hybridization between subterranean tuco-tucos (Rodentia, Ctenomyidae) with contrasting phylogenetic positions

Bruno Busnello Kubiak,Thales Renato Ochotorena De Freitas,Jorge C Pereira,Leonardo Trindade Leipnitz,Thamara Santos De Almeida,Leandro Rodrigues Borges,Daniel Galiano,Renan Maestri,Edivaldo Herculano Corrêa De Oliveira,Malcolm A Ferguson-Smith,Rafael Kretschmer

doi:10.1038/s41598-020-58433-5

Abstract

Reproductive compatibility usually decreases according to increasing genetic difference and the time of divergence between species. However, the amount of modification required to influence hybridization may vary in different species. Thus, it is extremely important to conduct studies that seek to understand what and how variables influence the reproductive isolation of species. We have explored a system involving two species of subterranean rodents that present morphological, karyotypic, and evolutionary history differences and are capable of generating hybrids. To gain insight into the karyotype organization of genus Ctenomys, we examined the chromosome evolution by classical and molecular cytogenetics of both parental species and hybrids. Furthermore, we have used different approaches to analyze the differences between the parental species and the hybrids, and determined the origin of the hybrids. The results of our work demonstrate unequivocally that some species that present extensive differences in chromosome organization, phenotype, evolutionary history, sperm morphology and genetic, which are usually associated with reproductive isolation, can generate natural hybrids. The results also demonstrate that females of both species are able to generate hybrids with males of the other species. In addition, the chromosome-specific probes prepared from Ctenomys flamarioni provide an invaluable tool for comparative cytogenetics in closely related species.

Highlights

The number of reports of hybrid animals has increased over the years[1]
The chromosome number and structure for C. minutus (2n = 46) and C. flamarioni (2n = 48) confirm previous studies[16,24]. Hybrid individuals between these two species were identified for the first time and present a diploid number of 47, which is the sum of the haploid karyotypes of C. minutus (n = 23) and C. flamarioni (n = 24) (Fig. 1)
Mitochondrial DNA analyses placed hybrid individuals within both species, providing evidence of bidirectional gene flow because females may belong to either species; microsatellite analysis revealed that the genetic makeup of the hybrid population was the result of admixture between the two parental species

Summary

Introduction

The number of reports of hybrid animals has increased over the years[1]. Reproductive compatibility usually decreases according to increasing genetic difference and the time of divergence between species[2]. It is expected that mammals with distinct karyotypes are not capable of giving birth to hybrids; this is what is found in the majority of cases[6] While this may be considered the normal pattern for Ecologia, Universidade Federal do Rio Grande do Sul, Av. Bento Gonçalves 9500, 91501-970, Porto Alegre, Brazil. Cross-species chromosome painting (Zoo-FISH) allows a more accurate assessment of chromosomal rearrangements (e.g. translocations, tandem fusions and centric fusions or fissions) than traditional karyotype comparative techniques[29]. These chromosomal rearrangements are most likely to produce reproductive barriers when they cause problems at meiosis in heterozygotes, leading to reduced fertility[30]. We suggest that the chromosome-specific DNA probes for C. flamarioni generated here could become an invaluable tool for comparative cytogenetics in closely related species

Methods

Results

Discussion

Conclusion