Identification of intergenomic recombinations in unisexual salamanders of the genus Ambystoma by genomic in situ hybridization (GISH)

Unisexual salamanders in the genus Ambystoma (Amphibia, Caudata) are endemic to eastern North America and are mostly all-female polyploids. Two to four of the bisexual species, A. laterale, A. jeffersonianum, A. texanum and A. tigrinum, contribute to the nuclear genome of unisexuals and more than 20 combinations that range from diploid to pentaploid have been identified in this complex. Because the karyotypes of the four bisexual species are similar, homologous and homoeologous chromosomes in the unisexuals can not be distinguished by conventional or banded karyotypes. We chose two widespread unisexual genomic combinations (A.laterale-2 jeffersonianum [or LJJ] and A. 2 laterale-jeffersonianum [or LLJ]) and employed genomic in situ hybridization (GISH) to identify the genomes in these unisexuals. Under optimum conditions, GISH reliably distinguishes the respective chromosomes attributed to both A.laterale and A. jeffersonianum. Of four populations examined, two were found to have independently evolved homoeologous recombinants that persist in both LJJ and LLJ individuals. Our results refute the previous hypothesis of clonal integrity and independent evolution of the genome combinations in these unisexuals. Our data provide evidence for intergenomic interactions between maternal chromosomes during meiosis in unisexuals and help to explain previously observed non-homologous bivalents and/or quadrivalents among lampbrush chromosomes that were possibly initiated by partial homosequential pairing among the homo(eo)logues. To explore the utility of GISH in other members of the complex, probes developed from A. laterale were also applied to unisexuals that contained A. tigrinum and A. texanum genomes. GISH is an effective tool that can be used to identify and to quantify genomic constituents and to investigate intergenomic interactions in unisexual salamanders. GISH also has potential application to examine possible genomic evolution in other unisexuals.     

The prevalence of genome replacement in unisexual salamanders of the genus <Emphasis Type="Italic">Ambystoma</Emphasis>(Amphibia,Caudata) revealed by nuclear gene genealogy

Background  

Unisexual salamanders of the genus Ambystoma exemplify the most ancient lineage of unisexual vertebrates and demonstrate an extremely flexible reproductive system. Unisexual Ambystoma interact with and incorporate genomes from two to four sexual species (A. laterale, A. jeffersonianum, A. texanum, and A. tigrinum), to generate more than 20 genome compositions or biotypes. Unisexual ploidy levels range from diploid to pentaploid, but all contain at least one A. laterale (L) genome. Replacement of nuclear genomes might be responsible for the evolutionary longevity of unisexual Ambystoma but direct evidence for the prevalence of genome replacement in natural populations is absent. Two major puzzling questions have remained unanswered over the last few decades: 1) is genome replacement a common reproductive method in various unisexual populations and, 2) is there an ancient "L" genome that persists in various unisexual genome compositions.     

A nonlethal method of identification of Ambystoma laterale,A. jeffersonianum and sympatric unisexuals

Unisexual salamanders in the genus Ambystoma live in obligate sympatry with the sexual species Ambystoma laterale or Ambystoma jeffersonianum, from which they are not easily distinguished. Because the sexual species are protected in many parts of their range, accurate identification of sexual and unisexual individuals is required for conservation purposes. Unisexual individuals are currently identified using isozyme electrophoresis, which requires sacrificing the animal. Here we present a nonlethal method of identification for members of the A. laterale–jeffersonianum part of the Ambystoma complex utilizing genome‐specific microsatellites with or without the addition of flow cytometry.     

Intergenomic translocations in unisexual salamanders of the genus Ambystoma (Amphibia, Caudata)

Intergenomic interactions that include homoeologous recombinations and intergenomic translocations are commonly observed in plant allopolyploids. Homoeologous recombinations have recently been documented in unisexual salamanders in the genus Ambystoma and revealed exchanged chromosomal segments between A. laterale and A.jeffersonianum genomes in individual unisexuals. We discovered intergenomic translocations in two widespread unisexual triploids A.laterale--2 jeffersonianum (or LJJ) and its tetraploid derivative A.laterale--3 jeffersonianum (or LJJJ) by genomic in situ hybridization (GISH). Two different types of intergenomic translocations were observed in two unisexual populations and one contained novel chromosomes generated by an intergenomic reciprocal translocation. We also observed chromosome deletions in several individuals and these chromosome fragmentations were all derived from the A. jeffersonianum genome. These observed intergenomic reciprocal translocations are believed to be caused by non-homologous pairing during meiosis followed by breakage-rejoining events. Genomes of unisexual Ambystoma undergo complicated structural changes that include various intergenomic exchanges that offer unisexuals genetic and phenotypic complexity to escape their evolutionary demise. Unisexual Ambystoma have persisted as natural nuclear genomic hybrids for about four million years. These unisexuals provide a vertebrate model system to examine the interaction of distinct genomes and to evaluate the corresponding genetic, developmental and evolutionary implications of intergenomic exchanges. Intergenomic translocations and homoeologous recombinations appear to be frequent chromosome reconstruction events among unisexual Ambystoma.     

ANDROGENETICS AND TRIPLOIDS FROM AN INTERACTING PARTHENOGENETIC HYBRID AND ITS ANCESTORS IN STICK INSECTS

Populations of unisexual organisms are often assumed to be genetically invariant (clones) and destined to a short existence on an evolutionary timescale. Unisexual organisms are most often obligate parthenogens and, by definition, ought to be completely isolated reproductively from related bisexual organisms. The assumption of complete reproductive isolation between amphimictic ancestors and thelytokous hybrids is common to most hypotheses on the evolution of sex and its adaptive significance. Stick insects of the genus Bacillus however provide evidence for reproductive interactions between allodiploid parthenogens and their ancestors, because pure species progeny (androgenetics) and triploid descendants are produced. These findings demonstrate that, through androgenesis, offspring of parthenogenetic hybrid females can contribute specimens of both sexes to the fathering species when fertilized by syntopic ancestral males and the parthenogenetic egg of strictly clonal females, when fertilized, allows a third genome to be added to the allodiploid chromosome set. These triploid genomes promote further genetic diversification and evolution of the unisexual populations through the formation of new clones by recombination during the changed maturation mode of allotriploid eggs. All this argues for much more complex breeding systems and evolutionary pathways than are usually assumed for hybrid unisexual organisms.     

A single nucleotide polymorphism assay for the identification of unisexual Ambystoma salamanders

Unisexual (all female) salamanders in the genus Ambystoma are animals of variable ploidy (2N‐5N) that reproduce via a unique system of ‘leaky’ gynogenesis. As a result, these salamanders have a diverse array of nuclear genome combinations from up to five sexual species: the blue‐spotted (A. laterale), Jefferson (A. jeffersonianum), smallmouth (A. texanum), tiger (A. tigrinum) and streamside (A. barbouri) salamanders. Identifying the genome complement, or biotype, is a critical first step in addressing a broad range of ecological and evolutionary questions about these salamanders. Previous work relied upon genome‐related differences in allele size distributions for specific microsatellite loci, but overlap in these distributions among different genomes makes definitive identification and ploidy determination in unisexuals difficult or impossible. Here, we develop the first single nucleotide polymorphism assay for the identification of unisexual biotypes, based on species‐specific nucleotide polymorphisms in noncoding DNA loci. Tests with simulated and natural unisexual DNA samples show that this method can accurately identify genome complement and estimate ploidy, making this a valuable tool for assessing the genome composition of unisexual samples.     

Cytogenetics of diploid and triploid salamanders of the Ambystoma jeffersonianum complex

Analysis of C-band heterochromatin (CBH) and cold-induced secondary constrictions (CICs) indicates that gynogenetic triploidy in the Ambystoma jeffersonianum complex is a cytogenetic consequence of hybridization between the two diploid species, A. jeffersonianum and A. laterale. The key feature in the history of this complex was the apparent proclivity for germ-line chromosome reduplication, and incidental production of chromosomally unreduced ova, allowing the circumvention of meiotic difficulties in diploid hybrid females. Chromosome structure, in terms of CBH and CICs, the mechanism of sex determination (dominant W, female heterogametic), and a recognizable WZ female/ZZ male sex chromosome heteromorphism in the diploid species A. laterale, are cytogenetic factors that allow reconstruction of the probable evolutionary history of the complex. The constitution of the triploid karyotypes suggests that the putative ancestral hybrid diploid females resulted from a mating between female A. jeffersonianum and male A. laterale, and that when such a hybrid female backcrossed to normal males of A. jeffersonianum and A. laterale, both kinds of allotriploids, A. platineum and A. tremblayi respectively, were produced. Karyological differentiation in each triploid species suggests that their origin was relatively recent and virtually simultaneous. It is conceivable that only one such hybrid female gave rise to both kinds of allotriploids in just one or two breeding seasons, and that present geographic distributions are due to persistent post-glaciation migrations of the resulting triploid clones. All offspring from such a back-cross carried a jeffersonianum W-chromosome and hence were female as well as triploid, and probably continued to produce chromosomally unreduced (triploid) ova by the same mechanism that operated in their hybrid mother. Sperm rejection resulting in gynogenesis in the allotriploids can be viewed as a physiological response to pseudopolyspermy by the chromosomally unreduced triploid ova. Evidence is presented that one of the triploid species, A. platineum, may produce a high percentage of diploid offspring with karyotypes identical to A. jeffersonianum. Diploids have not been detected among the offspring of A. tremblayi, but tetraploids are occasionally produced.Dedicated to my mentor and valued friend, James Kezer     

Bidirectional mitochondrial introgression between Korean cobitid fish mediated by hybridogenetic hybrids

Genomic introgression through interspecific hybridization has been observed in some species of the freshwater fish family Cobitidae. Within this family, a Cobitis hankugensis–Iksookimia longicorpa diploid–triploid hybrid species complex on the Korean peninsula is unique in displaying hybridogenesis, a unisexual reproduction mode that allows hybrids to mediate the transfer of mitochondrial DNA (but not nuclear DNA) between the two parent species. However, populations of the parental species in the wild have never been examined for the potential effect of introgression on their genomes. To address the genetic consequences of unisexual hybridization on the parental species, we examined genetic structure of the two parental species, C. hankugensis and I. longicorpa, in three independent natural habitats where they coexist with their hybrid complex using DNA sequence data of one mitochondrial gene and three nuclear genes. We found that mitochondrial introgression between the two species was extensive in all the examined localities, while there was no evidence of nuclear introgression across the species boundary. This result indicates that the hybridogenetic individuals mediate mitochondrial introgression from one species to the other, producing mito‐nuclear mosaic genomes such as C. hankugensis nuclear genomes associated with I. longicorpa mitochondrial DNA and the reverse. The direction and degree of introgression varied among the three localities, but the underlying mechanisms for this observation proved elusive. Introgression might depend on which species serves as the predominant sperm or ovum donor or the environmental conditions of the localities. The present study suggests that introgressive hybridization between pure C. hankugensis and I. longicorpa species is highly likely where the two species co‐occur with hybridogenetic individuals, but the consequence of introgression could be variable due to the history and environmental characteristics of particular populations across the parental species’ ranges.     

Gamete production patterns and mating systems in water frogs of the hybridogenetic Pelophylax esculentus complex in north‐eastern Ukraine

Hybridization and polyploidy play an important role in animal speciation. European water frogs of the Pelophylax esculentus complex demonstrate unusual genetic phenomena associated with hybridization, clonality and polyploidy which presumably indicate an initial stage of reticulate speciation. The Seversky Donets River drainage in north‐eastern Ukraine is inhabited by both sexes of the diploid and triploid hybrid P. esculentus and only one parental species Pelophylax ridibundus. Based on the presence of various types of hybrids, all populations studied can be divided into three geographical groups: I) P. ridibundus–P. esculentus without triploids; II) P. ridibundus–P. esculentus without diploid hybrids; and III) P. ridibundus–P. esculentus with a mixture of diploids and triploids. A study of gametogenesis revealed that diploid P. esculentus in populations of the first type usually produced haploid gametes of P. ridibundus and a mixture of haploid gametes that carried one or another parental genome (hybrid amphispermy). In populations of the second type, hybrids are derived from crosses of P. ridibundus males with triploid hybrid females producing haploid eggs with a genome of P. lessonae. Therefore, we suggest that clonal genome duplication in these eggs might be the result of suppression of second polar body formation or extra precleavage endoreduplication. In populations of the third type, some diploid females can produce diploid gametes. Fertilization of these eggs with haploid sperm can result in triploid hybrids. Other hybrids here produce haploid gametes with one or another parental genome or their mixture giving rise to new diploid hybrids.     

Electrophoretic evidence for the origin ofDryopteris yakusilvicola (Dryopteridaceae)

To investigate the origin of the triploid agamosporous speciesD. yakusilvicola, an electrophoretic analysis was made for five enzymes of theD. sparsa complex.Dryopteris yakusilvicola showed a monomorphic banding pattern for the five enzymes and was heterozygous in all six gene loci coding them. Comparison of enzyme banding patterns suggests that the genome ofD. yakusilvicola was derived through hybridization betweenD. sabaei and either a sexual tetraploid or an agamosporous triploid ofD. sparsa. Cytological evidence (Darnaediet al., 1989) supports the idea that of the two types ofD. sparsa the sexual tetraploid is a parent. The monomorphic pattern implies thatD. yakusilvicola originated from a single hybrid between the parental species, and that it is a neo-endemic of Yakushima Island.     

Speciation by genome duplication: Repeated origins and genomic composition of the recently formed allopolyploid species Mimulus peregrinus

Whole genome duplication (polyploidization) is a mechanism of “instantaneous” species formation that has played a major role in the evolutionary history of plants. Much of what we know about the early evolution of polyploids is based upon studies of a handful of recently formed species. A new polyploid hybrid (allopolyploid) species Mimulus peregrinus, formed within the last 140 years, was recently discovered on the Scottish mainland and corroborated by chromosome counts. Here, using targeted, high‐depth sequencing of 1200 genic regions, we confirm the parental origins of this new species from M. x robertsii, a sterile triploid hybrid between the two introduced species M. guttatus and M. luteus that are naturalized and widespread in the United Kingdom. We also report a new population of M. peregrinus on the Orkney Islands and demonstrate that populations on the Scottish mainland and Orkney Islands arose independently via genome duplication from local populations of M. x robertsii. Our data raise the possibility that some alleles are already being lost in the evolving M. peregrinus genomes. The recent origins of a new species of the ecological model genus Mimulus via allopolyploidization provide a powerful opportunity to explore the early stages of hybridization and genome duplication in naturally evolved lineages.     

DIPLOID-TRIPLOID MOSAICS AMONG UNISEXUAL HYBRIDS OF THE MINNOWS PHOXINUS EOS AND PHOXINUS NEOGAEUS

Diploid-triploid mosaics are rarely found in vertebrates, and until now they were known to be common in only two vertebrate species complexes. Here we report that diploid-triploid mosaics are widespread among unisexual hybrids of the minnows Phoxinus eos and Phoxinus neogaeus, a complex already known to contain diploid and triploid forms. Using chromosome counts and flow cytometry, we show that the mosaics occur throughout the known range of the unisexuals and are abundant in many of these natural populations. The mosaics are highly heterogeneous, showing individual variation in the ratio of diploid to triploid cells, and as a group they appear to form a continuum between the pure diploid and triploid forms. Tissue-graft analysis shows that the third genome present in the triploid cells of a mosaic is expressed, because grafts made from the mosaics show an incidence of rejection intermediate between that of the diploid (clonal) and triploid (nonclonal) biotypes.     

Novel Jefferson salamander,Ambystoma jeffersonianum,microsatellite DNA markers detect population structure and hybrid complexes

Twenty polymorphic microsatellite DNA markers were isolated and characterized in Ambystoma jeffersonianum collected from three vernal pools in the mid‐Atlantic region of the U.S. These markers revealed a high degree of genetic diversity (7–23 alleles per locus), heterozygosity (46.7% to 100%), and allelic heterogeneity (96% of comparisons were statistically significant). Genetic distances were greatest in comparisons between collections, intermediate within collections, and least among sibling pairs. Six markers were trisomic in A. jeffersonianum‐A. laterale hybrids. These microsatellite DNA loci should allow delineation of genetic structure within and among populations of the diploid A. jeffersonianum and provide an effective method for identification of triploid hybrid individuals.     

Gamete production patterns,ploidy, and population genetics reveal evolutionary significant units in hybrid water frogs (Pelophylax esculentus)

The European water frog Pelophylax esculentus is a natural hybrid between P. lessonae (genotype LL) and P. ridibundus (RR). It reproduces through hybridogenesis, eliminating one parental genome from its germline and producing gametes containing the genome of the other parental species. According to previous studies, this elimination and transmission pattern is very diverse. In mixed populations, where only diploid hybrids (LR) live in sympatry and mate with one or both parental species, the excluded genome varies among regions, and the remaining genome is transmitted clonally to haploid gametes. In all‐hybrid populations consisting of diploid (LR) and triploid (LLR and/or LRR) frogs, diploid individuals also produce gametes clonally (1n in males, 2n in females), whereas triploids eliminate the genome they have in single copy and produce haploid gametes containing the recombined other genome. However, here, too, regional differences seem to exist, and some triploids have been reported to produce diploid gametes. In order to systematically study such regional and genotype differences in gamete production, their potential origin, and their consequences for the breeding system, we sampled frogs from five populations in three European countries, performed crossing experiments, and investigated the genetic variation through microsatellite analysis. For four populations, one in Poland, two in Germany, and one in Slovakia, our results confirmed the elimination and transmission pattern described above. In one Slovakian population, however, we found a totally different pattern. Here, triploid males (LLR) produce sperm with a clonally transmitted diploid LL genome, rather than a haploid recombined L genome, and LR females clonally produce haploid R eggs, rather than diploid LR eggs. These differences among the populations in gamete production go along with differences in genomotype composition, breeding system (i.e., the way triploids are produced), and genetic variation. These differences are strong evidence for a polyphyletic origin of triploids. Moreover, our findings shed light on the evolutionary potential inherent to the P. esculentus complex, where rare events due to untypical gametogenetic processes can lead to the raise, the perpetuation, and the dispersion of new evolutionary significant lineages which may also deserve special conservation measures.     

ELECTROPHORETIC CONFIRMATION OF INTERSPECIFIC HYBRIDIZATION IN AESCULUS (HIPPOCASTANACEAE) AND THE GENETIC STRUCTURE OF A BROAD HYBRID ZONE

Within a broad (>200 km wide) hybrid zone involving three parapatric species of Aesculus, we observed coincident clines in allele frequency for 6 of 14 electrophoretic loci. The cooccurrence of alleles characteristic of A. pavia, A. sylvatica, and A. flava was used to estimate genetic admixtures in 48 populations involving various hybrids between these taxa in the southeastern United States. High levels of allelic polymorphism (up to 40% greater than the parental taxa) were observed in hybrid populations and also in some populations bordering the hybrid zone. A detailed analysis of a portion of the hybrid zone involving A. pavia and A. sylvatica revealed a highly asymmetrical pattern of gene flow, predominantly from Coastal Plain populations of A. pavia into Piedmont populations of A. sylvatica. Computer simulations were used to generate expected genotypic arrays for parental, F₁; and backcross individuals, which were compared with natural populations using a character index scoring system. In these comparisons, hybrid individuals could be distinguished from either parent, but F₁ and backcross progeny could not be distinguished from each other. Most hybrid populations were found to include hybrids and one of the parental taxa, but never both parents. Three populations appeared to be predominantly hybrids with no identifiable parental individuals. Hybrids occurred commonly at least 150 km beyond the range of A. pavia, but usually not more than 25 km beyond the range of A. sylvatica. Introgression, suggested by genetically hybrid individuals and significant gene admixtures of two or more species in populations lacking morphological evidence of hybridization, may extend the hybrid zone further in both directions. The absence of one or both parental species from hybrid populations implies a selective disadvantage to parentals in the hybrid zone and/or that hybridization has occurred through long-distance gene flow via pollen, primarily from A. pavia into A. sylvatica. Long-distance pollen movement in plants may generate hybrid zones of qualitatively different structure than those observed in animals, where gene flow involves dispersal of individuals.     

Genetic structure of silver Prussian carp <Emphasis Type="Italic">Carassius</Emphasis> (Superspecies <Emphasis Type="Italic">auratus</Emphasis>) (Linnaeus, 1758) colonies from the Middle Dnieper Basin

Population genetic structure of silver Prussian carp from the Middle Dnieper basin was established by means of biochemical gene marking and cytometric analysis. In addition to diploid goldfish Carassius auratus, which was the basic species of bisexual colonies, a number of biotypes of triploid silver Prussian carp C. gibelio were identified. These biotypes either formed isolated unisexual populations, or were an admixture to the bisexual colonies. In addition, in bisexual colonies, triploid females of non-clonal origin were identified. Despite the fact that all forms of C. gibelio reproduced by means of gynogenesis, some of them (C. gibelio-1) formed isolated unisexual populations, while the others (C. gibelio-2, -3, and -4) usually coexisted with C. auratus.     

Optional Endoreplication and Selective Elimination of Parental Genomes during Oogenesis in Diploid and Triploid Hybrid European Water Frogs

Incompatibilities between parental genomes decrease viability of interspecific hybrids; however, deviations from canonical gametogenesis such as genome endoreplication and elimination can rescue hybrid organisms. To evaluate frequency and regularity of genome elimination and endoreplication during gametogenesis in hybrid animals with different ploidy, we examined genome composition in oocytes of di- and triploid hybrid frogs of the Pelophylax esculentus complex. Obtained results allowed us to suggest that during oogenesis the endoreplication involves all genomes occurring before the selective genome elimination. We accepted the hypothesis that only elimination of one copied genome occurs premeiotically in most of triploid hybrid females. At the same time, we rejected the hypothesis stating that the genome of parental species hybrid frogs co-exist with is always eliminated during oogenesis in diploid hybrids. Diploid hybrid frogs demonstrate an enlarged frequency of deviations in oogenesis comparatively to triploid hybrids. Typical for hybrid frogs deviations in gametogenesis increase variability of produced gametes and provide a mechanism for appearance of different forms of hybrids.     

Mitochondrial gene introgression between spined loaches via hybridogenesis

This report deals with an unusual mode of mitochondrial gene introgression between Cobitis hankugensis (C. sinensis) and C. longicorpus which is mediated by a unisexual hybridogenetic system of diploid-triploid C. hankugensis-longicorpus complex. Mitochondrial DNA sequences of 3329-3330bp encompassing from upstream ND6 to 12S rDNA indicated that mitochondrial genomes from the diploid hybrids, triploid hybrids, and their parental species are almost identical. Because triploid hybrids produce haploid ova with C. hankugensis chromosome set, normal diploid C. hankugensis regenerates upon insemination with C. hankugensis sperm. If the hybrid carries C. longicorpus mitochondrial genome, the regenerated C. hankugensis is a nucleo-cytoplasmic hybrid, thus accomplishing the unusual mode of mitochondrial gene introgression.     

Mode of hybridogenesis and habitat preferences influence population composition of water frogs (Pelophylax esculentus complex,Anura: Ranidae) in a region of sympatric occurrence (western Slovakia)

Coexistence of sperm‐dependent asexual hybrids with their sexual progenitors depends on genetic and ecological interactions between sexual and asexual forms. In this study, we investigate genotypic composition, modes of hybridogenetic gametogenesis and habitat preferences of European water frogs (Pelophylax esculentus complex) in a region of sympatric occurrence. Pelophylax esculentus complex comprises parental species P. ridibundus and P. lessonae, whose primary hybridization leads to hybridogenetic lineages of P. esculentus. Hybrids clonally transmit one parental genome and mate with the other parental species, forming a new generation of hybrids. In the region of western Slovakia, we found syntopic occurrence of diploid and triploid hybrids with P. lessonae, syntopic occurrence of all three taxa as well as the existence of pure P. ridibundus populations. All triploid hybrids were exclusively male possessing one ridibundus and two different lessonae genomes (RLL). Sex ratio in diploid hybrids was substantially female‐biased. Irrespective of the population composition, diploid hybrids excluded the lessonae genome from their germ line and produced ridibundus gametes. Contrarily, RLL males unequivocally eliminated the ridibundus genome and produced diploid lessonae sperms. Perpetuation of RLL males in studied populations is most likely achieved by their mating with diploid hybrid females. The composition of water frog populations is also shaped by taxon‐specific habitat preferences. While P. ridibundus preferred larger water bodies (gravelpits, fishery ponds, dead river arms), P. lessonae was most frequently found in marshes and smaller sandpits. Pelophylax esculentus occupied predominately similar habitats as its sexual host P. lessonae.     

The gynogenetic reproduction of diploid and triploid hybrid spined loaches (<Emphasis Type="Italic">Cobitis</Emphasis>: Teleostei), and their ability to establish successful clonal lineages—on the evolution of polyploidy in asexual vertebrates

Polyploidisation is assumed to have played a significant role in the evolution of hybrid asexual lineages. The virtual absence of natural asexual systems in which more than a single ploidy level successfully establishes successful independent clonal lineages is generally explained by the strong effects of polyploidisation on fitness. Experimental crosses were made between diploid and triploid asexual Cobitis elongatoides × C. taenia hybrids (female) and both parental spined loach species (male). Genotyping of the progeny using allozymes and multilocus DNA fingerprinting, along with flow cytometric measurement of ploidy level, demonstrated the occurrence of gynogenetic reproduction in both female biotypes. The incorporation of the sperm genome occurred in some progeny, giving rise to a higher ploidy level, but the rate of polyploidisation differed significantly between the diploid and triploid females. These outcomes are consistent with the existence of developmental constraints on tetraploidy, which determine the rarity of tetraploids in natural populations. No cases of ploidy level reduction were observed. Since diploid and triploid hybrid populations occur where the lack of potential progenitor excludes the possibility of de novo origin, it is probable that both diploid and triploid females can establish successful clonal lineages. Spined loaches represent a unique example, among asexual vertebrates, where more than one ploidy level can establish persistent clonal lineages, which are reproductively independent of one another.