Beata Rozenblut-Kościsty

Sex reversal assessments reveal different vulnerability to endocrine disruption between deeply diverged anuran lineages

Multiple anthropogenic stressors cause worldwide amphibian declines. Among several poorly investigated causes is global pollution of aquatic ecosystems with endocrine disrupting compounds (EDCs). These substances interfere with the endocrine system and can affect the sexual development of vertebrates including amphibians. We test the susceptibility to an environmentally relevant contraceptive, the artificial estrogen 17α-ethinylestradiol (EE2), simultaneously in three deeply divergent systematic anuran families, a model-species, Xenopus laevis (Pipidae), and two non-models, Hyla arborea (Hylidae) and Bufo viridis (Bufonidae). Our new approach combines synchronized tadpole exposure to three EE2-concentrations (50, 500, 5,000 ng/L) in a flow-through-system and pioneers genetic and histological sexing of metamorphs in non-model anurans for EDC-studies. This novel methodology reveals striking quantitative differences in genetic-male-to-phenotypic-female sex reversal in non-model vs. model species. Our findings qualify molecular sexing in EDC-analyses as requirement to identify sex reversals and state-of-the-art approaches as mandatory to detect species-specific vulnerabilities to EDCs in amphibians.

Sex-chromosome differentiation parallels postglacial range expansion in European tree frogs (Hyla arborea)

Occasional XY recombination is a proposed explanation for the sex‐chromosome homomorphy in European tree frogs. Numerous laboratory crosses, however, failed to detect any event of male recombination, and a detailed survey of NW‐European Hyla arborea populations identified male‐specific alleles at sex‐linked loci, pointing to the absence of XY recombination in their recent history. Here, we address this paradox in a phylogeographic framework by genotyping sex‐linked microsatellite markers in populations and sibships from the entire species range. Contrasting with postglacial populations of NW Europe, which display complete absence of XY recombination and strong sex‐chromosome differentiation, refugial populations of the southern Balkans and Adriatic coast show limited XY recombination and large overlaps in allele frequencies. Geographically and historically intermediate populations of the Pannonian Basin show intermediate patterns of XY differentiation. Even in populations where X and Y occasionally recombine, the genetic diversity of Y haplotypes is reduced below the levels expected from the fourfold drop in copy numbers. This study is the first in which X and Y haplotypes could be phased over the distribution range in a species with homomorphic sex chromosomes; it shows that XY‐recombination patterns may differ strikingly between conspecific populations, and that recombination arrest may evolve rapidly (<5000 generations).

Maintenance of Ancestral Sex Chromosomes in Palearctic Tree Frogs: Direct Evidence from Hyla orientalis

Contrasting with the situation found in birds and mammals, sex chromosomes are generally homomorphic in poikilothermic vertebrates. This homomorphy was recently shown to result from occasional X-Y recombinations (not from turnovers) in several European species of tree frogs (Hyla arborea, H. intermedia and H. molleri). Because of recombination, however, alleles at sex-linked loci were rarely diagnostic at the population level; support for sex linkage had to rely on multilocus associations, combined with occasional sex differences in allelic frequencies. Here, we use direct evidence, obtained from anatomical and histological analyses of offspring with known pedigrees, to show that the Eastern tree frog (H. orientalis) shares the same pair of sex chromosomes, with identical patterns of male heterogamety and complete absence of X-Y recombination in males. Conservation of an ancestral pair of sex chromosomes, regularly rejuvenated via occasional X-Y recombination, seems thus a widespread pattern among Hyla species. Sibship analyses also identified discrepancies between genotypic and phenotypic sex among offspring, associated with abnormal gonadal development, suggesting a role for sexually antagonistic genes on the sex chromosomes.

Sex Chromosome Conservation, DMRT1 Phylogeny and Gonad Morphology in Diploid Palearctic Green Toads (Bufo viridis Subgroup)

Due to the prevailing sex chromosome homomorphy and large genome size, the knowledge on sex determination systems, sex chromosomes and sex-determining genes in amphibians remains scarce. Using 3 cross-amplifying sex-linked microsatellite markers, we uncover sex determination systems and sex chromosomes in purebred, diploid Palearctic green toads (Bufo viridis subgroup), which had so far only been characterized in laboratory-bred hybrids. Our data support an XY system in B. balearicus, B. viridis and B. variabilis. While females show recombination, it is strongly suppressed (or not detectable) in males. Markers corroborate the largest chromosome pair 1 (homologous to linkage group 1 of Xenopus tropicalis) to represent the sex chromosomes in diploid species of the B. viridis subgroup (B. siculus, B. shaartusiensis, B. balearicus, B. turanensis, B. variabilis, B. viridis, and probably B. boulengeri). This chromosome harbors DMRT1, a key gene of the sexual pathway in deeply divergent animal taxa. However, our phylogenetic analysis of a 600-bp fragment of that gene in diploid green toad taxa reveals that X and Y alleles cluster by species and not by gametolog. This suggests that XY-sequence similarity stems from occasional XY recombination within DMRT1, and we preliminarily reject its role as the master sex determination gene, pending future extension of this evidence to the entire DMRT1 gene. We further create a chain of evidence, which supports the hypothesis that linkage group 1 of X. tropicalis appears to be maintained as the largest chromosome (1), and thus is homologous in anuran karyotype evolution from pipid to hylid, bufonid and ranid anurans.

Prespermatogenesis and early spermatogenesis in frogs

Spermatogenesis in frogs was for the first time divided into two phases: prespermatogenesis, when gonocytes proliferate in developing tadpole testes, and active spermatogenesis when spermatogonial stem cells (i.e. descendants of gonocytes), either self-renew or enter into meiotic cycles within cysts formed by Sertoli cells. We argue that amphibian larval gonocytes are homologues to mammalian gonocytes, whereas spermatogonial stem cells (SSCs) in adult frogs are homologous to mammalian single spermatogonia (As). Gonocytes constitute sex cords, i.e. the precursors of seminiferous tubules; they are bigger than SSCs and differ in morphology and ultrastructure. The nuclear envelope in gonocytes formed deep finger-like invaginations absent in SSCs. All stages of male germ cells contained lipid droplets, which were surrounded by glycogen in SSCs, but not in gonocytes. Mitochondria in gonocytes had enlarged edges of cristae, and in SSCs also lamellar mitochondria appeared. Minimal duration of prespermatogenesis was 46days after gonadal sex differentiation, but usually it lasted longer. SSCs give rise to secondary spermatogonia (equal to mammalian A, In, and B). Their lowest number inside a cyst was eight and this indicated the minimal number of cell cycles (three) of secondary spermatogonia necessary to enter meiosis. We sorted them according to the number of cell cycles (from 8 to 256 cells). This number is similar to that recorded for mammals as the result of a single As proliferation. The number of secondary spermatogonia correlates with the volume of a cyst. The general conclusion is that spermatogenesis in amphibians and mammals follows basically the same scheme.

The frequency of degenerating germ cells in the ovaries of water frogs ( Pelophylax esculentus complex)

Pelophylax esculentus is the fertile hybrid of P. ridibundus and P. lessonae. During gametogenesis, one of the parental genomes is removed from the germ line cells, whereas the other one is clonally transmitted to the gametes. In hybrids, development of gonads is delayed in comparison with parental species. This may result from complex processes of genome elimination in female tadpoles at Gosner stages 28–46, potentially responsible for increased degeneration of germ cells in developing gonads from the very beginning of sexual differentiation to ovaries with diplotene oocytes, respectively. In this work, we revealed that germ cells died by apoptosis, as detected by expression of active caspase-3 using immunohistochemical method. The main group of degenerating germ cells was primary oogonia, however, in P. lessonae and P. ridibundus also secondary oogonia and diplotene oocytes were found. The number of degenerating germ cells was significantly higher in ovaries of P. esculentus. In hybrids, positive correlations were demonstrated between Gosner stage and gonadal volume, Gosner stage and the number of degenerating germ cells, gonadal volume and number of degenerating germ cells. These observations suggest that increased rate of apoptosis in germ cells, probably as the result of improper genome elimination, may be responsible for delayed maturation of ovaries in P. esculentus.

Impaired gonadal and somatic development corroborate vulnerability differences to the synthetic estrogen ethinylestradiol among deeply diverged anuran lineages

Amphibians are undergoing a global decline. One poorly investigated reason could be the pollution of aquatic habitats by endocrine disrupting compounds (EDCs). We tested the susceptibility to the synthetically stabilized estrogen 17α-ethinylestradiol (EE2) in three deeply diverged anuran species, differing in sex determination systems, types of gonadogenesis and larval ecologies. To understand whether data from the amphibian model Xenopus laevis (Pipidae) are analogous and applicable to only distantly related non-model amphibians, tadpoles of X. laevis, Hyla arborea (Hylidae) and Bufo viridis (Bufonidae) were simultaneously exposed to 50, 500 and 5000ng/L EE2 from hatching until completion of metamorphosis, using a flow-through-system under identical experimental conditions. Comparing molecularly established genetic with histologically assessed phenotypic sex in all species, we have recently shown that EE2 provoked numerous genetic-male-to-phenotypic-female sex reversals and mixed sex individuals, confirming overall its expected feminizing effect. In the present study, we focus on the influence of EE2 on gonadal and somatic development. Anatomy and histology revealed several species-specific effects. In both non-model species, H. arborea and B. viridis, high numbers of anatomically impaired gonads were observed. In H. arborea, exposed to 5000ng/L EE2, numerous underdeveloped gonads were detected. Whereas EE2 did not alter snout-to-vent length and body weight of X. laevis metamorphs, H. arborea showed a treatment-dependent decrease, while B. viridis exhibited an increase in body weight and snout-to-vent length. Apart from a concentration-dependent occurrence of yellowish skin color in several H. arborea, no organ-specific effects were detected. Since EE2 ubiquitously occurs in many aquatic ecosystems and affects sexual and somatic development, among EDCs, it may indeed contribute to amphibian decline. The inter-species variation in developmental EE2-effects corroborates species-specific vulnerability differences towards EDCs between deeply diverged amphibian groups.

The programmed DNA elimination and formation of micronuclei in germ line cells of the natural hybridogenetic water frog Pelophylax esculentus

DNA elimination is a radical form of gene silencing and occurs both in somatic and germ cells. The programmed DNA elimination occurs during gametogenesis in interspecies hybrids that reproduce by hybridogenesis (stick insects, fishes, and amphibians) and concerns removal of whole genomes of one of the parental species and production of clonal gametes propagating the genome of the other species. The cellular mechanisms differ considerably in hybridogenetic insects and fishes but remains unknown in edible frogs Pelophylax esculentus, natural hybrids between Pelophylax lessonae and Pelophylax ridibundus. Here we report DNA elimination mechanism in early developing gonads of diploid and triploid hybrid frogs, studied by TEM, immunofluorescence, and cytochemistry. In gonocytes of both sexes (primary oogonia and prespermatogonia), micronuclei emerge as detached nuclear buds formed during interphase. We found depletion of nuclear pore complexes in micronuclear membrane and chromatin inactivation via heterochromatinization followed by degradation of micronuclei by autophagy. Micronuclei formation does not lead to apoptotic cell death showing that genome elimination is a physiological process. Chromatin elimination via micronuclei in P. esculentus is unique among hybridogenetic animals and contributes to broadening the knowledge about reproductive modes in animals.

Amphibians of Wałbrzych

In the city of Walbrzych 67 water bodies (about 95% of all Walbrzych ponds) were investi-gated. Among them, 58 water bodies (86.57%) are of anthropogenic origin. In the studied area 9 amphibian species were recorded: Rana temporaria (present in 44.78% of studied water bodies), Bufo bufo (44.78%), Triturus vulgaris (17.91%), Trirutus alpestris (16.62%), water frogs of the Rana esculenta complex (Rana lessonae and Rana kl. esculenta, 10.45% altogether), Bufo viridis (10.45%), Bufo calamita (4.48%) and Triturus cristatus (4.48%). Amphibians were present in 48 ponds (71.64% of studied water bodies). Maximum number of species (six) was recorded in only 1 water body; minimum number of species (1) was recorded in 19 ponds. Surprisingly, the maximum number of species occurred in the pond located within dense urban area. One bank of this pond was a vertical brick wall and there is not much vegetation in the pond. In industrial areas of Walbrzych presence of only 5 amphibian species was noted, however on 7 sites there were no amphibians atall. Similar low number of amphibian species (five) was also noted in mini-ponds in the allotments.