A Cryptic Clonal Line of the Loach Misgurnus anguillicaudatus (Teleostei: Cobitidae) Evidenced by Induced Gynogenesis, Interspecific Hybridization, Microsatellite Genotyping and Multilocus DNA Fingerprinting

Morishima, Kagayaki; Horie, Shin; Yamaha, Etsuro; Arai, Katsutoshi

doi:10.2108/zsj.19.565

Cited by 80 publications

(123 citation statements)

References 32 publications

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“…In the present paper, we performed sibship analyses with 15 co-dominant microsatellite loci to evaluate genome-wide clonal (males absent), restricted to reptiles [7,8]; Sperm-dependent parthenogenesis (i.e. gynogenesis): clonal, embryogenesis requires trigger from allospecific sperm that is not incorporated (rare 'paternal leakage' might incorporate subgenomic amounts of paternal DNA), occurs in teleost fishes and urodelan amphibians [9]; Kleptogenesis: females acquire full or partial genomes from their mates by a not fully understood mechanism, allowing them to purge genomes from deleterious alleles (here BB); described from urodelan amphibians [10]; Unnamed form of hybridogenesis: clonal diploid eggs are fertilized by sperm from a recombining sexual species that can be diploid or triploid (as in meiotic hybridogenesis); occurs in anuran amphibians and teleost fishes [11][12][13]; Meiotic hybridogenesis: may occur in triploid males and/or females; found in teleost fishes and anuran amphibians [14,15]; ploidy elevation of the diploid offspring, which might produce diploid hybrid gametes, can occur in the next generation (becoming then e.g. ABB 0 ) to restore triploidy (similar to preceding form of hybridogenesis); Pre-equalizing hybrid meiosis: occurring in Batura toads: Both sexes are triploid and exhibit Mendelian segregation and recombination in the B genomes (equivalent to NORþ; this paper), while the A genome (i.e.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous Mendelian and clonal genome transmission in a sexually reproducing, all-triploid vertebrate

et al. 2011

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Meiosis in triploids faces the seemingly insuperable difficulty of dividing an odd number of chromosome sets by two. Triploid vertebrates usually circumvent this problem through either asexuality or some forms of hybridogenesis, including meiotic hybridogenesis that involve a reproductive community of different ploidy levels and genome composition. Batura toads (Bufo baturae; 3n ¼ 33 chromosomes), however, present an all-triploid sexual reproduction. This hybrid species has two genome copies carrying a nucleolus-organizing region (NORþ) on chromosome 6, and a third copy without it (NOR2). Males only produce haploid NORþ sperm, while ova are diploid, containing one NORþ and one NOR2 set. Here, we conduct sibship analyses with co-dominant microsatellite markers so as (i) to confirm the purely clonal and maternal transmission of the NOR2 set, and (ii) to demonstrate Mendelian segregation and recombination of the NORþ sets in both sexes. This new reproductive mode in vertebrates ('pre-equalizing hybrid meiosis') offers an ideal opportunity to study the evolution of non-recombining genomes. Elucidating the mechanisms that allow simultaneous transmission of two genomes, one of Mendelian, the other of clonal inheritance, might shed light on the general processes that regulate meiosis in vertebrates.

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Section: Introductionmentioning

confidence: 99%

Simultaneous Mendelian and clonal genome transmission in a sexually reproducing, all-triploid vertebrate

et al. 2011

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“…In wild populations of Japan, most individuals are bisexually reproducing diploid with 2n = 50 chromosomes, but a small number of gynogenetically reproducing clonal diploid individuals have been detected in a few localities by experimental reproduction and molecular genetic analyses (Morishima et al 2002(Morishima et al , 2008. The occurrence of natural triploid and diploid-triploid mosaic individuals has also been recorded at low frequencies in a few localities in Japan (Zhang and Arai 1999;Arai 2003;Morishima et al 2004;Yoshikawa et al 2007).…”

Section: Introductionmentioning

confidence: 99%

Chromosome banding and FISH with rDNA probe in the diploid and tetraploid loach Misgurnus anguillicaudatus

Tian

Zhang

et al. 2010

Ichthyol Res

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The chromosomes of diploid and tetraploid loach, Misgurnus anguillicaudatus, were analyzed by staining with Ag, Chromomycin A 3 (CMA 3 )/Distamycin A (DA), and DA/4',6-diamidino-2-phenylindole (DAPI), and fluorescence in situ hybridization (FISH) with 5.8S + 28S rDNA as a probe. Nucleolus organizing regions (NORs) were mapped to the telomeric region of the short arms of the largest (first) metacentric chromosome pair in diploid loach with 2n = 50 and the homologous quartet in tetraploid loach with 4n = 100. The NORs were positive at the same region of the first metacentric chromosome for Ag-and CMA 3 /DA-stainings, but negative for DA/DAPI-staining. Four signals at the homologues within the same quartet suggest the duplication of entire genome from diploid to tetraploid status. However, size difference was detected among rDNA signals by FISH and CMA 3 -banding.

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“…In the latter case, diploid females (2n ¼ 50) spawn genetically identical, unreduced diploid eggs, most of which develop gynogenetically. However, some eggs produce triploid (3n ¼ 75) progeny following the accidental incorporation of a haploid sperm nucleus after fertilization (Morishima et al, 2002;Itono et al, 2006Itono et al, , 2007. The relationship between atypical reproduction and hybridization is uncertain in the loach because Japanese M. anguillicaudatus has been taxonomically identified as a single species entity (Saitoh, 1989).…”

Section: Introductionmentioning

confidence: 99%

Meiotic hybridogenesis in triploid Misgurnus loach derived from a clonal lineage

2008

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Triploid loaches Misgurnus anguillicaudatus are derived from unreduced diploid gametes produced by an asexual clonal lineage that normally undergoes gynogenetic reproduction. Here, we have investigated the reproductive system of two types of triploids: the first type carried maternally inherited clonal diploid genomes and a paternally inherited haploid genome from the same population; the second type had the same clonal diploid genomes but a haploid genome from another, genetically divergent population. The germinal vesicles of oocytes from triploid females (3n ¼ 75) contained only 25 bivalents, that is, 50 chromosomes. Flow cytometry revealed that the majority of the progeny resulting from fertilization of eggs from triploid females with normal haploid sperm were diploid. This indicates that triploid females mainly produced haploid eggs. Microsatellite analyses of the diploid progeny of triploid females showed that one allele of the clonal genotype was not transmitted to haploid eggs. Moreover, the identity of the eliminated allele differed between the two types of triploids. Our results demonstrate that there is preferential pairing of homologous chromosomes as well as the elimination of unmatched chromosomes in the course of haploid egg formation, that is, meiotic hybridogenesis. Two distinct genomes in the clone suggest its hybrid origin.

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A Cryptic Clonal Line of the Loach Misgurnus anguillicaudatus (Teleostei: Cobitidae) Evidenced by Induced Gynogenesis, Interspecific Hybridization, Microsatellite Genotyping and Multilocus DNA Fingerprinting

Cited by 80 publications

References 32 publications

Simultaneous Mendelian and clonal genome transmission in a sexually reproducing, all-triploid vertebrate

Simultaneous Mendelian and clonal genome transmission in a sexually reproducing, all-triploid vertebrate

Chromosome banding and FISH with rDNA probe in the diploid and tetraploid loach Misgurnus anguillicaudatus

Meiotic hybridogenesis in triploid Misgurnus loach derived from a clonal lineage

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