Variations in the Mitochondrial Genome of a Goldfish-Like Hybrid [Koi Carp (♀) × Blunt Snout Bream (♂)] Indicate Paternal Leakage.

Yude Wang,Huifang Tan,Shaojun Liu,Xu Huang,Wenzhen Sun,Chun Zhang,Qinbo Qin,Qianhong Gu,Jiajun Yao,Min Tao

doi:10.3389/fgene.2020.613520

Abstract

Previously, a homodiploid goldfish-like fish (2n = 100; GF-L) was spontaneously generated by self-crossing a homodiploid red crucian carp-like fish (2n = 100; RCC-L), which was in turn produced via the distant hybridization of female koi carp (Cyprinus carpio haematopterus, KOC, 2n = 100) and male blunt snout bream (Megalobrama amblycephala, BSB, 2n = 48). The phenotypes and genotypes of RCC-L and GF-L differed from those of the parental species but were similar to diploid red crucian carp (2n = 100; RCC) and goldfish (2n = 100; GF), respectively. We sequenced the complete mitochondrial DNAs (mtDNAs) of the KOC, BSB, RCC-L, GF-L, and subsequent generations produced by self-crossing [the self-mating offspring of RCC-L (RCC-L-F2) to the self-mating offspring of RCC-L-F2 (RCC-L-F3) and the self-mating offspring of GF-L (GF-L-F2)]. Paternal mtDNA fragments were stably embedded in the mtDNAs of both lineages, forming chimeric DNA fragments. In addition to these chimeras, several nucleotide positions in the RCC-L and GF-L lineages differed from the parental bases, and were instead identical with RCC and GF, respectively. Moreover, RCC-L and GF-L mtDNA organization and nucleotide composition were more similar to those of RCC and GF, respectively, compared to parental mtDNA. Finally, phylogenetic analyses indicated that RCC-L and GF-L clustered with RCC and GF, not with the parental species. The molecular dating time shows that the divergence time of KOC and GF was about 21.26 Mya [95% highest posterior density (HPD): 24.41–16.67 Mya], which fell within the period of recent. The heritable chimeric DNA fragments and mutant loci identified in the mtDNA of the RCC-L and GF-L lineages provided important evidence that hybridizations might lead to changes in the mtDNA and the subsequent generation of new lineages. Our findings also demonstrated for the first time that the paternal mtDNA was transmitted into the mtDNA of homodiploid lineages (RCC-L and GF-L), which provided evidence that paternal DNA plays a role in inherited mtDNA. These evolutionary analyses in mtDNA suggest that GF might have diverged from RCC after RCC diverged from koi carp.

Highlights

Hybridization in plants is better studied than hybridization in animals, animal hybrids may be more common than previously thought (Baack and Rieseberg, 2007)
We obtained a diploid goldfish-like fish (GF-L) fish with twin tails (2n = 100) by selfcrossing an red crucian carp-like fish (RCC-L) fish, where red crucian carp (RCC)-L was itself derived from the distant crossing of female koi carp and male blunt snout bream (Wang et al, 2018)
Our previous analyses of microsatellite pattern (SSR) and 5S rDNA sequences indicated that GF-L and RCC-L were genetically similar to GF and RCC, respectively (Talavera and Castresana, 2007)

Summary

Introduction

Hybridization in plants is better studied than hybridization in animals, animal hybrids may be more common than previously thought (Baack and Rieseberg, 2007). Hybridization may accelerate diversification through adaptive infiltration, possibly even leading to nearly instantaneous speciation (Abbott et al, 2013). Such hybridization events are accompanied by rapid genomic changes, including chromosome recombination, genome amplification, differential gene expression, and gene silencing (Hirsch et al, 2012). Significant genomic changes may generate beneficial new phenotypes and reproductive traits, possibly increasing fertility and adaptability (Baack and Rieseberg, 2007; Mlynarcikova et al, 2016)

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