Heterozygous fitness effects of clonally transmitted genomes in waterfrogs

The European waterfrog Rana esculenta (RL‐genotype) is a natural hybrid between R. ridibunda (RR) and R. lessonae (LL) and reproduces by hybridogenesis, i.e. it eliminates the L‐genome from the germline and produces gametes only containing the clonally transmitted R‐genome. Because of the lack of recombination, R‐genomes are prone to accumulate spontaneous deleterious mutations. The homozygous effects of such mutations become evident in matings between hybrids: their offspring possess two clonal R‐genomes and are generally inviable. However, the evolutionary fate of R. esculenta mainly depends on the heterozygous effects of mutations on the R‐genome. These effects may be hidden in the hybrid R. esculenta because it has been shown to benefit from spontaneous heterosis. To uncouple clonal inheritance from hybridity, I crossed R. esculenta with R. ridibunda to produce nonhybrid offspring with one clonal and one sexual R‐genome, and compared their survival and larval performance with normal, sexually produced R. ridibunda tadpoles. Because environmental stress can enhance the negative effects of mutation accumulation, I measured the performance at high and low food levels. There was no indication that tadpoles with a clonal genome performed worse at either food level, suggesting that at least in the larval stage, R. esculenta benefits from heterosis without incurring any costs because of heterozygous effects of deleterious mutations on the clonally transmitted R‐genome.     

FIXATION OF DELETERIOUS MUTATIONS IN CLONAL LINEAGES: EVIDENCE FROM HYBRIDOGENETIC FROGS

Abstract The hemiclonal waterfrog Rana esculenta (RL genotype), a bisexual hybrid between R. ridibunda (RR) and R. lessonae (LL), eliminates the L genome from its germline and clonally transmits the R genome (hybridogenesis). Matings between hybrids produce R. ridibunda offspring, but they generally die at an early larval stage. Mortality may be due to fixed recessive deleterious mutations in the clonally inherited R genomes that were either acquired through the advance of Muller's ratchet or else frozen in these genomes at hemiclone formation. From this hypothesis results a straightforward prediction: Matings between different hemiclones, that is, between R. esculenta possessing different R genomes of independent origin, should produce viable R. ridibunda offspring because it is unlikely that different clonal lineages have become fixed for the same mutations. I tested this prediction by comparing survival and larval performance of tadpoles from within‐ and between‐population crossings using R. esculenta from Seseglio (Se) in southern, Alpnach (Al) in central, and Elliker Auen (El) in northern Switzerland, respectively. Se is isolated from the other populations by the Alps. Enzyme electrophoresis revealed that parents from Se belonged to a single hemiclone that was different from all hemiclones found north of the Alps. Parents from Al also belonged to one hemiclone, but parents from El belonged to three hemiclones, one of which was indistinguishable from the one in Al. Rana esculenta from Se produced inviable tadpoles when crossed with other hybrids of their own population, but when crossed with R. esculenta from Al and El, tadpoles successfully completed metamorphosis, supporting the hypothesis I tested. Within‐population crosses from Al were also inviable, but some within‐population crosses from El, where three hemiclones were present, produced viable offspring. Only part of the crosses between Al and El were viable, but there was no consistent relationship between hemiclone combination and tadpole survival. When backcrossed with the parental species R. ridibunda, hybrids from all source populations produced viable offspring. Performance of these tadpoles with a sexual and a clonal genome was comparable to that of normal, sexually produced R. ridibunda tadpoles. Thus, in the heterozygous state, the deleterious mutations on the clonal R genomes did not appear to reduce tadpole fitness.     

Premeiotic chromosome doubling after genome elimination during spermatogenesis of the species hybrid Rana esculenta

Summary Gamete production in the hybridogenetic species hybrid Rana esculenta (Rana ridibunda X Rana lessonae) is preceded by a premeiotic elimination of the R. lessonae genome and subsequent duplication of the remaining R. ridibunda genome, so that only ridibunda chromosomes enter a quasi normal meiosis, and only ridibunda gametes are formed. This is demonstrated by differences in genome specific centromere fluorescence and electrophoretic patterns between somatic and gonadal tissue.     

Patterns of protein synthesis in oocytes and early embryos of Rana esculenta complex

Summary We have used isotopic labelling and both one-and two-dimensional electrophoretic procedures to analyse the protien synthesis patterns in oocytes and early embryos of three phenotypes of the European green frogs. The results demonstrated that protein patterns of Rana ridibunda and R. esculenta are identical, but that they differ from those of R. lessonae. Progeny of the lethal cross R. esculenta × R. esculenta showed a distinct delay in the appearance of stage-specific proteins during early embryogenesis. The heat-shock response of R. ridibunda and R. esculenta oocytes was found to be identical, but different from that of Xenopus laevis. The implications of these findings, with respect to hybridogenesis in R. esculenta complex and variations in the regulations of heat shock genes in different amphibian species, are discussed.     

ASYMMETRIC COMPETITION IN MIXED POPULATIONS OF TADPOLES OF THE HYBRIDOGENETIC: RANA ESCULENTA COMPLEX

Hybridogenetic Rana esculenta tadpoles display tolerance to extreme environmental conditions and fit criteria of the “general-purpose” genotype. A trade-off between generality and competitive ability is assumed to occur in asexual species, but the evidence remains unclear. The purpose of my experiment was to test the competitive ability of hemiclonal hybrid Rana esculenta tadpoles relative to the parental species Rana lessonae. Mixed and single genotype populations of R. esculenta and R. lessonae tadpoles were reared at three densities in artificial ponds. Survival of R. esculenta was higher than for R. lessonae tadpoles, but did not differ among densities. Body size at metamorphosis was the same between genotypes, but decreased with increasing density. Larval period was not affected by density, but R. esculenta tended to metamorphose earlier than R. lessonae. Percentage of individuals metamorphosing was higher for R. esculenta at both medium and high densities, but the same as R. lessonae at the low density. The difference in survival, body size, and larval period between tadpoles reared in single and mixed genotype populations was unaffected by genotype or density. The difference in the percentage of metamorphs, however, was strongly affected. The percentage of hybrids metamorphosing was 9% above the responses of single genotype populations at the highest density. Conversely, the percentage of R. lessonae metamorphosing was 12% below the responses of single genotype populations at the same density. Hybrid success in this experiment further supports the criterion of a “general-purpose” genotype without assumptions of reduced competitive ability.     

A genetic mechanism of species replacement in European waterfrogs?

Introduced Rana ridibunda currentlyreplace the native waterfrogs R. lessonaeand R. esculenta in several areas ofcentral Europe. The unusual reproductive systemin waterfrogs of the Rana esculentacomplex suggests that this replacement may bedriven by a genetic mechanism: Ranaesculenta, a hybrid between R. ridibundaand R. lessonae, eliminates the lessonae genome from the germline and clonallytransmits the ridibunda genome(hybridogenesis). Hybrids form mixedpopulations with R. lessonae (L-E-system)in which they persist by backcrossing with theparental species. Matings between hybrids areunsuccessful, because their ridibundagenomes contain fixed recessive deleteriousmutations. When introduced into a L-E-system,R. ridibunda can mate with both nativetaxa, producing R. ridibunda offspringwith R. esculenta, and R. esculentaoffspring with R. lessonae (primaryhybridizations). If primary hybrids arehybridogenetic, they produce viable R.ridibunda offspring in matings with otherhybrids, because their clonal genomes areunlikely to share the deleterious allelespresent in the ancient clones. Thus, R.ridibunda will increase in the population atthe expense of both native taxa, eventuallyleaving a pure R. ridibunda population.We provide three lines of evidence for thisprocess from a currently invaded population inSwitzerland: (1) Primary hybridizations takeplace, as roughly 10% of hybrids in thepopulation possess ridibunda genomesderived from the introduced frogs. (2)Hybridogenesis occurs in primary hybrids,although at a low frequency. (3) Many hybrid ×hybrid matings in the population indeed produceviable offspring. Hence, the proposed geneticmechanism appears to contribute to the speciesreplacement, although its importance may belimited.     

Variation in Sex Ratio and Evolutionary Rate of Hemiclonal Rana esculenta Populations

In many plant and animal taxa mutation rates are higher in males than in females. As a result, the evolutionary speed of genes depends on how much time they spend in either sex. Usually, this time differs between genes located on sex chromosomes but not between those on autosomes. Here we present an unusual system with a partially sex-linked inheritance of autosomes: the hemiclonal frog Rana esculenta (E) which is originally a hybrid between the sexual species R. lessonae (L) and R. ridibunda (R). Rana esculenta excludes the L genome prior to meiosis, produces eggs or sperm containing an unrecombined R genome and restores hybridity by mating with R. lessonae (‘hybridogenesis’). Matings between L males and E females result in offspring with an even sex ratio, whereas the reverse combination produces only daughters. The extent of the resulting female bias and the proportion that R alleles have spent in either sex depend on the relative survival (b) and the relative reproductive contribution (a) of E males vs. E females. In this paper, we analyze mathematically how different combinations of a and b influence the sex ratio in R. esculenta populations and, combined with the male/female mutation rate ratio (α), the evolutionary rate of the clonally transmitted R genome. We find that this rate is higher than in an asexual population and lower than in a sexual one. Hence, clonal diversity through new mutations is more easily achievable than in purely asexual species. In contrast, the occurrence and accumulation of deleterious mutations is lower than in a comparable sexual species. We conclude that these intermediate mutation rates improve the ecological and evolutionary potential of hemiclonal organisms, and we draw attention to the implications for the use of microsatellites. Co-ordinating editor: L. Hurst     

Geographical and ecological distributions of frog hemiclones suggest occurrence of both 'General-Purpose Genotype' and 'Frozen Niche Variation' clones

Asexuals often occupy broad geographical and ecological ranges. Two models have been proposed to explain the ubiquity of asexuals: the General‐Purpose Genotype (GPG) and the Frozen Niche Variation (FNV) model. According to these models, asexuals differ in their ecological niche width and may occupy narrow specialist niches or ubiquitous niches. A thousand water frogs from 37 different populations located in France in different habitats were studied, and two (hemi)clonal hybrid types were identified genetically, Rana esculenta and R. grafi. Altogether, 13 hemiclones were identified both in R. grafi and R. esculenta. Three of these were geographically and ecologically widely distributed, and usually very common in populations. In contrast, the remaining 10 hemiclones had small geographical ranges and were restricted to special habitat types, suggesting ecological niche specialization. The results suggest that in hybridogenetic water frogs GPG and FNV hemiclones coexist.     

Microsatellite DNA markers for the Chinese wood frog (Rana chensinensis) and tests for their cross-utility in 15 ranid frog species

We developed 22 microsatellite markers for the Chinese wood frog (Rana chensinensis) to study the impact of landscape features on its population structure. Thirty‐four individuals from one breeding site were examined and 14 loci were polymorphic. The number of alleles, expected heterozygosity and observed heterozygosity varied from two to 14, from 0.0833 to 0.9118, and from 0.1376 to 0.8667, respectively. Cross‐species amplification was tested for 15 ranid frog species. The Plateau brown frog, Rana kukunoris (n = 23), was successfully amplified at 18 loci, and 15 were polymorphic with number of alleles varying from two to 18. Ten other species were also amplified at a limited number of loci.     

Apolipoproteins and their electrophoretic pattern throughout the reproductive cycle in the green frog Rana esculenta

Lipoprotein fractions in Rana esculenta were separated using the same salt intervals currently applied for human lipoproteins. Very low density lipoproteins (VLDL), low density lipoproteins (LDL) and high density lipoproteins (HDL) were analyzed with reference to the electrophoretic pattern. The lipoprotein electrophoretic pattern in males and females throughout the reproductive cycle showed minor differences. In general, each fraction was characterized by a specific apolipoprotein content. VLDL and LDL fractions were dominated by a high molecular weight (MW) band, most likely the counterpart of human Apolipoprotein B (apo B). The apo B in R. esculenta cross reacted, although weakly, with antibodies raised against chicken apo B. The HDL fraction showed a band with an apparent MW of 29 kDa. The electrophoretic mobility of the protein moiety of HDL was similar to human apolipoprotein A-I (apo A-I). However, HDL apolipoprotein of R. esculenta did not cross react with antibodies against chicken apo A-I under either denaturing or native conditions. The HDL apolipoprotein of R. esculenta was purified by DEAE-Sephacel chromatography followed by HPLC. Its amino acid composition showed a moderate correlation with trout, salmon, chicken and human apo A-I.     

Karyological and serological studies in Rana lessonae,R. ridibunda and in their hybrid R. ‘esculenta’ (Amphibia,Anura)

The karyotypes of the three water frog forms: Rana lessonae, R. ridibunda and R. esculenta were analysed from bone marrow cell preparations of animals captured in several localities of the GDR. In the three forms chromosome morphology was similar (5 large and 8 small pairs), although differences in the relative length of most elements were found; R. esculenta chromosomes were always intermediate.One of the small pairs (Chr. 12) was found to be metacentric in R. lessonae and submetacentric in R. ridibunda. Most R. esculenta individuals examined had one meta-and one submetacentric 12th element, indicating the hybrid nature of this form. However 16.6% esculenta proved to be homozygous for either the metacentric or the submetacentric chromosome 12, while 13% lessonae individuals and 7.7% ridibunda were heterozygous for this element.By starch gel electrophoresis an analysis was undertaken of serum proteins from water frogs coming from regions in which the forms occur together (sympatric populations) and from zones in which only one of them lives (allopatric populations).In Rana lessonae, where only one allele had been previously described, two different alleles were found in animals coming from the GDR.If genetic polymorphism is excluded, between 6.1% and 9.1% individuals from sympatric lessonae and ridibunda populations showed introgression of an albumin allele. No gene introgression was found in allopatric lessonae populations from the Leningrad region or in ridibunda from Alma Ata and southern Bulgaria.     

Ecology of the Hybridogenetic Rana esculenta Complex: Differential Oxygen Requirements of Tadpoles

Because of intrinsic demographic load induced by hybridogenesis (infertility of homotypic hybrid matings), the maintenance of hybrid lineages supposes that they present better performances (heterosis) than their host species which allows them to coexist on a long-term basis. However, this necessity of high fitness can be relaxed if a relative niche partitioning occurs between the taxa, each of them differing in their ecological optima. In the waterfrog hybridogenetic complex (Rana esculenta complex), recent studies have revealed that hybrids show intermediate distribution between parental species across a gradient of river influence (that is related to a gradient of oxygen levels), and intermediate performances of their tadpoles with regard to oxygen availability (hypoxia). In investigating oxygen consumption rates, survival time in anoxia, and metabolite contents in the three forms of the complex, the present study confirms intermediate characteristics of hybrid tadpoles (R. esculenta) when compared to both parental lineages (R. lessonae and R. ridibunda). Whereas R. ridibunda tadpoles were the most sensitive to anoxia, R. lessonae tadpoles were the most tolerant. Because oxygen requirements of the hybrid proved to be intermediate, no heterosis was detected. These results confirm the hypothesis of the intermediate niche hypothesis to explain the coexistence of R. lessonae and R. esculenta and the success of the hybridogens.     

A comparative study of physiological and structural changes at the myoneural junction in two species of frog after transection of the motor nerve

Summary Structural and functional behaviour of motor end-plates after transection of the motor nerve has been studied in two species of frog: Rana esculenta and Rana temporaria. The physiological results show that in both species there is a transient cessation of spontaneous activity followed by a resumption of miniature end-plate potentials (min. e.p.p.s.) after denervation. The characteristics of these potentials (frequency, distribution of amplitudes, time-course) are similar in the two species. However, some differences have been observed: Firstly, the period of silence lasts for 2–4 days in the case of Rana temporaria whereas it is prolonged to about 15 days in Rana esculenta. Secondly, the resumption of min. e.p.p.s. is gradual and after the 10th day of denervation remains constant in Rana temporaria. It is inconstant independent of the period of denervation in Rana esculenta. The morphological results show that the Schwann cell is constantly in contact with the post-synaptic membrane after about 6 days of denervation in both species. It is suggested that either the Schwann cell is capable of functioning for a limited period of time in Rana esculenta or is activated to produce min. e.p.p.s. only in certain cases.     

Different patterns of expression of five neuropeptides in the adrenal gland and kidney of two species of frog

The aim of this study was to demonstrate in the adrenocortical and renal tissues of two species of frog, Rana italica and Rana esculenta, the presence and distribution of five neuropeptides: atrial natriuretic peptide (ANP), Leu-enkephalin (Leu-ENK), neuropeptide Y (NPY), substance P (SP) and vasoactive intestinal peptide (VIP).In anurans, the adrenal medulla is the site for the synthesis, storage and secretion of not only catecholamines but also various peptides. These peptides should not be regarded only as neurotransmitters or modulators for the secretion of catecholamines, but also as hormonal substances that induce systemic effects.All the peptides studied (ANP, Leu-ENK, NPY, SP and VIP) are present in both organs. However, different patterns of expression were observed for some of the peptides in two frogs.Immunopositivity to ANP was found in small clusters of chromaffin cells in both frogs whereas a clear strong positivity was present only in Rana esculenta kidney. Large clusters of chromaffin cells were immunoreactive to Leu-ENK in Rana italica but there were approximately 25% fewer compared to the positive cells present in Rana esculenta. Epithelial cells of renal tubules showed strong immunopositivity to Leu-ENK in Rana esculenta but not in Rana italica. A large number of adrenal cells (70–80%) were immunoreactive to NPY in Rana italica, while in Rana esculenta this peptide was localized in small clusters of chromaffin cells. Both frogs showed many NPY-positive cells in kidney. Many chromaffin cells were found positive to SP and VIP. A strong positivity was also observed in kidney in both frogs. These observations suggest a possible role of these peptides in the control of the physiological functions of adrenal glands and kidney of the two species of frogs studied.     

Variation of plastic responses to oxygen availability within the hybridogenetic Rana esculenta complex

The hypothesis of superiority of hybrid phenotype to explain the maintenance of hybridogenesis (exclusion of one parental genome in the germline before meiosis) was investigated in the Rana esculenta complex. Survival and growth of progenies from each parental and hybrid lineages were compared across contrasted conditions of oxygen availability (this factor is suspected to influence habitat utilization of each form of the complex). Whereas growth and development were strongly affected by constant hypoxic conditions in the R. ridibunda lineage, they were not altered in the R. lessonae lineage. Because the performance of the hybrid (R. esculenta) lineage proved to be intermediate between the parental species, no heterosis effect was detected. These results supported the intermediate niche hypothesis as an alternative to the heterotic hybrid superiority hypothesis. The ecological and evolutionary implications are then discussed.     

On the biology of Amphibia in the ecosystem of Lake Glubokoe

In Lake Glubokoe, the Amphibia are represented by five species. Two numerous species, Rana temporaria L. and Bufo bufo L., spawn in the lake and appear to be a significant component of its ecosystem. Thus, in autumn R. temporaria is a common food for predatory fish (pike, perch). During their wintering R. temporaria participate in the consumption of oxygen from the water. They may be a source of dangerous infections. Their tadpoles and those of B. bufo feed in the lake and annually remove substances from it. Adult R. temporaria in autumn, and the young of the year of R. temporaria and of B. bufo influence the population numbers of small littoral invertebrates. Several dozen pairs of Rana terrestris Andrzejw are observed to spawn regularly. Rana esculenta L. and Rana ridibunda Pallas are scarce. The influence of introducing a nature preserve on the numbers of Amphibia in Lake Glubokoe is discussed.     

ADAPTIVE GENETIC VARIATION IN GROWTH AND DEVELOPMENT OF TADPOLES OF THE HYBRIDOGENETIC RANA ESCULENTA COMPLEX

The distribution and proportion of the sexual species Rana lessonae to the hemiclonal hybrid R. esculenta among natural habitats suggests that these anurans may differ in adaptive abilities. I used a half-sib design to partition phenotypic and quantitative genetic variation in tadpole responses at two food levels into causal variance components. Rana lessonae displays strong phenotypic variation across food levels. Growth rate is strictly determined by environmental factors and includes weak maternal effects. Larval period and body size at metamorphosis both contain moderate levels of additive genetic variance. The sire x food interactions and the lack of environmental correlations indicate that adaptive phenotypic plasticity is present in both of these traits. In contrast, R. esculenta displays less phenotypic variation across food levels, especially for larval period. Variation in body size at metamorphosis is underlain by genetic variation as shown by high levels of additive genetic variance, yet growth rate and larval period are not. Significant environmental correlations between larval period at high food level and growth, larval period, and body size at low food, indicate phenotypic plasticity is absent. A positive phenotypic correlation between body size at metamorphosis and larval period for R. lessonae at both food levels suggests a trade-off between growing large and metamorphosing quickly to escape predation or pond drying. The lack of a similar correlation for R. esculenta at the high food level suggests it may be less constrained. Different levels of adaptive genetic variation among larval traits suggest that the sexual species and the hybridogenetic hemiclone differ in their abilities to cope with temporally and spatially heterogeneous environments.     

Food supply modifies the trade-off between past and future reproduction in a sexual parasite–host system (<Emphasis Type="Italic">Rana esculenta,Rana lessonae</Emphasis>)

Life history theory is concerned with the costs of survival, growth and reproduction under different ecological conditions and the allocation of resources to meet these costs. Typical approaches used to address these topics include manipulation of food resources, followed by measures of subsequent reproductive traits, and measures of the relationship between current and future reproductive investment. Rarely, however, do studies test for the interaction of past investment, present resource availability and future investment simultaneously. Here, we investigate this interaction in females of a sexual parasite–host system consisting of the hybridogenetic frog Rana esculenta (E) and one of its parental species Rana lessonae (L). We kept females from each of two groups (with or without previous reproduction) under two food treatments (low or high) and regularly recorded their growth as well as their body condition and hormone titres as measures of future reproductive condition. After keeping them in hibernation until the following spring, we exposed the females to males, recorded whether they spawned or not and related this response to their condition in the previous autumn. Past reproduction negatively affected growth during summer and condition during autumn which, in turn, reduced the following year’s reproductive output. These costs of previous reproduction were less pronounced under the high than under the low food treatment and lower in R. lessonae than in R. esculenta. Increasing food supply improved reproductive condition more in L than in E females. These species differences in reproductive costs and food requirements provide a mechanistic explanation for why E females skip annual reproduction almost twice as often as L females. Since R. esculenta is a sexual parasite that depends on R. lessonae for successful reproduction, these species-specific life history patterns not only affect individual fitness but also the spatial structure and temporal dynamics of mixed LE populations.     

Effects of Ca2+ and other divalent cations on K+-evoked force production of slow muscle fibers from Rana esculenta and Rana pipiens

Summary Slow muscle fibers were dissected from cruralis muscles of Rana esculenta and Rana pipiens. Isometric contractures were evoked by application of K⁺-rich Ringer's containing Ca²⁺, Ni²⁺, Co²⁺, Mn²⁺ or Mg²⁺. High (7.2 mmol/liter) external Ca²⁺ concentration raised, 0 Ca²⁺ lowered the K⁺ threshold. Replacing Ca²⁺ by Ni²⁺ or Co²⁺ had an effect similar to that of high Ca²⁺ Ringer's. In Mg²⁺ Ringer's the K⁺ concentration-response curve was flattened. These effects were observed already after short exposure times in both species of slow fibers. When Ca²⁺ was removed for long periods of time the slow fibers of R. esculenta lost their contractile response to application of high K⁺ concentrations much more quickly than those of R. pipiens, while the response to caffeine (20 mmol/liter) was maintained. Upon readmission of Ca²⁺ contractile ability was quickly restored in the slow fibers of both R. esculenta and R. pipiens, but the effects of Ni²⁺ (or Co²⁺, Mn²⁺ and Mg²⁺) were much larger in R. esculenta than in R. pipiens slow fibers. It is concluded that divalent cations have two different sites of action in slow muscle fibers. K⁺ threshold seems to be affected through binding to sites at the membrane surface; these sites bind Ni²⁺ and Co²⁺ more firmly than Ca²⁺. The second site is presumably the voltage sensor in the transverse tubular membrane, which controls force production, and where Ca²⁺ is the most effective species of the divalent cations examined.We are grateful to Mrs. S. Pelvay for technical assistance.     

Morphometric and DNA investigations into European water frogs (Rana kl. esculenta Synklepton (Anura, Ranidae)) from different population systems

The population specific variability of diploid and triploid R. kl. esculenta individuals was investigated by means of morphometric methods (canonical discriminant analysis, UPGMA cluster analysis) and DNA fingerprinting. As a result of the morphometric investigations, as well as of the DNA investigations, a clear separation of single populations was possible. However, no correlations between the morphometry and different population systems could be recognized. Clear morphometric differences could be seen between diploid ♀♀ and ♂♂ and triploid ♀♀ on the one hand, and triploid ♂♂ on the other. While the diploid ♀♀ and ♂♂ and the triploid ♀♀ were located in the intermediate area between the parental species R. lessonae and R. ridibunda according to their morphometric parameters, the triploid ♂♂ showed a great overlap with R. lessonae. Up to now, this phenomenon has not been explained. The first results of the DNA investigations provided further hints at the high inter-individual and population-specific variability of R. kl. esculenta. R. kl. esculenta individuals of the R. lessonae/esculenta population Toter See could be distinguished from conspecific individuals of the R. ridibunda/esculenta-♀♀ population Alte Oder according to their fingerprint patterns. Moreover, in the R. lessonae / esculenta population, the fingerprints or the diploid R. kl. esculenta-♀♀ and the investigated R. lessonae-♀ were very similar. Furthermore, in this population, many R. kl. esculenta genotypes resemble R. lessonae in their morphometric features. This finding suggests the occurrence of recombination in R. kl. esculenta. In general, every population seems to have its own genetic background. A classification of water-frog populations according to population systems is only possible under certain conditions.