Cytogenetics of the parthenogenetic grasshopper Warramaba virgo and its bisexual relatives

A study of the chromosomal location and genomic organization of the ribosomal RNA cistrons in the genus Warramaba, involving in situ hybridization and restriction enzyme analysis as well as C- and N-banding and silver staining, has confirmed that the parthenogenetic species W. virgo has two phylads. These phylads appear to have originated independently by hybridization between the precursors of the present day bisexual species P169 and P196. The clones of the Standard phylad of W. virgo have their 18S+26S rDNA cistrons located in C-bands 4, 44 and 49, while those of the Boulder-Zanthus phylad have them in C-bands 50, 74 and 87.5. The relative numbers of the ribosomal genes at the different sites vary greatly from clone to clone and are closely correlated with the width of the corresponding C- and N-bands. Site 49 of the ribosomal cistrons is present as a separate band in the eastern race A of P196 but has been incorporated into band 50 in the western race B of this species. The former race is assumed to be ancestral to the Standard phylad of W. virgo, the latter to the Boulder-Zanthus phylad, but there has been loss of the 74 and 87.5 sites in the the Standard phylad and the 4 and 44 sites in the Boulder-Zanthus clones. The ribosomal cistrons in W. picta, a species with a primitive karyotype, occur in several sites, only some of which have counterparts in P169 and P196. The 5S rDNA cistrons are located in bands 59.5, 69 and 72.5 in the Standard phylad of W. virgo. — The genomic organization of the 18S+26S rDNA cistrons, as shown by restriction enzyme analysis, is different in the two W. virgo phylads and there are also differences in organization between P196A and P196B. The pattern in P196B and that in the Boulder-Zanthus phylad suggest that they are related. As in the in situ analyses, the genomic organizations of the ribosomal cistrons in both W. virgo phylads are not simply the additive products of those in any known populations of P169 and P196. New repeat lengths indicative of segmental amplification events occur in particular clones of W. virgo. — Throughout the genus Warramaba the N-banding technique stains all bands containing 18S+26S and 5S rDNA cistrons. The Olert silver technique stains band 72.5 in the Standard phylad, but does not correlate with the locations of 18S+26S ribosomal genes.     

ELECTROPHORETIC VARIATION IN THE PARTHENOGENETIC GRASSHOPPER WARRAMABA VIRGO AND ITS SEXUAL RELATIVES

Allozyme variation was examined within and between parthenogenetic clones of Warramabo virgo and the sexual ancestors, undescribed species P196 and P169. Both sexual species can be separated into northern and southern races using six loci, and the separate hybrid origin for the two major groups of parthenogenetic clones (the Standard Phylad and the Boulder-Zanthus Phylad) is substantiated by the racial variation in the sexual ancestors. Heterozygosity values in the parthenogenetic species are 6–9 times higher than those in the sexual species, and there is evidence for the accumulation of new variation subsequent to the hybrid origin of both phylads. The new variation is the result of either new mutations, recombination, or both. Three loci in the Standard Phylad clones reveal “orphan” alleles not found in the sexual ancestors; these alleles probably arose subsequent to hybridization but prior to the dispersal of the parthenogenetic clones. These data, in combination with those from other genetic studies, suggest that new variation may arise as a consequence of hybridization. Collectively, the allozyme, chromosome, molecular, and morphological data suggest that the Standard Phylad clones are of a more ancient but restricted origin, with clonal variation being the result of multiple hybridizations between individuals of P196 and P169.     

The evolution of sexual and parthenogenetic Warramaba: a window onto Plio–Pleistocene diversification processes in an arid biome

Environmental changes over the Plio‐Pleistocene have been key drivers of speciation patterns and genetic diversification in high‐latitude and mesic environments, yet comparatively little is known about the evolutionary history of species in arid environments. We applied phylogenetic and phylogeographic analyses to understand the evolutionary history of Warramaba grasshoppers from the Australian arid zone, a group including sexual and parthenogenetic lineages. Sequence data (mitochondrial COI) showed that the four major sexual lineages within Warramaba most likely diverged in the Pliocene, around 2–7 million years ago. All sexual lineages exhibited considerable phylogenetic structure. Detailed analyses of the hybrid parthenogenetic species W. virgo and its sexual progenitors showed a pattern of high phylogenetic diversity and phylogeographic structure in northern lineages, and low diversity and evidence for recent expansion in southern lineages. Northern sexual lineages persisted in localized refugia over the Pleistocene, with sustained barriers promoting divergence over this period. Southern parts of the present range became periodically unsuitable during the Pleistocene, and it is into this region that parthenogenetic lineages have expanded. Our results strongly parallel those for sexual and parthenogenetic lineages of the gecko Heteronotia from the same region, indicating a highly general effect of Plio‐Pleistocene environmental change on diversification processes in arid Australia.     

Cytogenetics of the parthenogenetic grasshopper Warramaba (formerly Moraba) virgo and its bisexual relatives

The distribution of late-replicating segments along the chromosomes of five clones of W. virgo is described. Some, but not all of these segments correspond to C-bands. In general, the autoradiographic profiles (histograms of linear grain density along the length of chromosomes labeled with tritiated thymidine in late S-phase) show strong resemblances throughout the five clones. However, some significant differences exist, and these are particularly marked in the case of the Boulder clone, which is anomalous in many other respects. — A similar study has also been carried out on the two bisexual species of Warramaba (P169 and P196) that gave rise, by hybridization more than half a million years ago, to the parthenogenetic W. virgo. In the case of P169, the autoradiographic profiles of the three large chromosomes (X+A, B+5, CD) which it has contributed to the W. virgo karyotype are extremely similar to those of the corresponding chromosomes in the virgo clones we have studied. In the case of P196 there is likewise, in most instances, a close resemblance of the autoradiographic profiles of the AB, X₁ and CD chromosomes to those of the same chromosomes in the virgo clones, but that of the X₁ shows no particular resemblance to the anomalous profile of the X₁ in the Boulder clone, in which the X₁ has undergone a structural reorganisation. The autoradiographic profile of the P196 CD chromosome does, however, show a much closer resemblance to that of the corresponding chromosome in the Boulder clone than to those of the CD₁₉₆ in the other four virgo clones studied. These investigations confirm the considerable evolutionary stability of DNA replication patterns.     

Cytogenetics of the parthenogenetic grasshopper Warramaba (formerly Moraba) virgo and its bisexual relatives

Hybrids of both sexes were obtained from the reciprocal crosses, carried out in the laboratory, between the species believed to have given rise, by hybridization some thousands of years ago, to the parthenogenetic species W. virgo. All males with a Y-chromosome derived from P196 died before reaching the adult stage, but two males from the reciprocal cross (i.e., with a Y from P169) survived up to the adult stage. Their testes were small but normal in structure and histology. At the first meiotic division almost all the chromosomes were univalents, 0–2 bivalents being formed. Some chiasmata between non-homologous chromosomes were present. Segregation at first anaphase is irregular so that sperms with 3–15 chromosomes are formed. Such hybrids appear to be entirely sterile.     

The origin and evolution of parthenogenesis in theHeteronotia binoei complex: Synthesis

TheHeteronotia binoei complex includes several cryptic species of sexually reproducing lizards and parthenogenetic lineages derived from them. This paper synthesizes analyses of distribution and variation of allozymes, chromosomes, mitochondrial DNA and ribosomal DNA genes in order to make inferences about the origins of the parthenogenetic lineages, the extent and source of their genetic diversity, their current and historical biogeography and their ecological properties. The parthenogens appear to have arisen recently (relative to geographic differentiation within the sexual taxa) via episodes of repetitive hybridization between two of the sexual taxa. These events probably occurred within one or two small geographic areas of western Australia, after which some of the parthenogenetic lineages rapidly expanded their ranges to central Australia. The parthenogenetic form has extraordinarily high genetic diversity, mostly derived from the repetitive origins, but with some contribution from mutation and biased gene conversion/recombination being apparent. The rapid and extensive range expansion of the parthenogenetic lineages from western to central Australia attests to the short-term success of this reproductive strategy, in this case perhaps reinforced by the parthenogenetic females having higher fecundity than their smaller sexual relatives. However, the parthenogens are orders of magnitude more susceptible to infection by ectoparasitic mites, suggesting that they could be at a long-term disadvantage. The detailed characterization of this system provides a basis for critical evaluation of hypotheses about the evolutionary advantage of sexual reproduction derived from broad comparative studies.     

The material ancestry and approximate age of parthenogenetic species of Caucasian rock lizards (Lacerta: Lacertidae)

Restriction enzymes were used to assay variation among mitochondrial DNAs from parthenogenetic and sexual species of Lacerta. This permitted identification of the sexual species that acted as the maternal parent of the various hybrid-parthenogenetic lineages. Lacerta mixta was the maternal parent for both L. dahli and L. armeniaca, L. valentini was the maternal parent for L. uzzelli, and L. raddei was the maternal parent of L. rostombekovi. The maternal ancestry of L. unisexualis is not as clear. The sample of L. nairensis was very similar to one from a population of L. raddei and either species could be the maternal parent of L. unisexualis. The parthenogenetic species all had very low nucleotide diversity in absolute terms and in comparison to their sexual relatives. The close similarity between mtDNAs from the parthenogenetic species and their respective sexual maternal ancestor species provides strong evidence for the recent origin of the parthenogens. The low diversity of the parthenogens indicates that few females were involved in their origins; the maternal parents of L. dahli and L. armeniaca could have come from a single population. The patterns of mtDNA variation in Lacerta are very similar to those in Cnemidophorus and Heteronotia, establishing recent and geographically restricted origins as a general feature of parthenogenetic lizards.     

Functional rare males in diploid parthenogenetic Artemia

Functional males that are produced occasionally in some asexual taxa – called ‘rare males’ – raise considerable evolutionary interest, as they might be involved in the origin of new parthenogenetic lineages. Diploid parthenogenetic Artemia produce rare males, which may retain the ability to mate with females of related sexual lineages. Here, we (i) describe the frequency of male progeny in populations of diploid parthenogenetic Artemia, (ii) characterize rare males morphologically, (iii) assess their reproductive role, using cross‐mating experiments with sexual females of related species from Central Asia and characterize the F1 hybrid offspring viability and (iv) confirm genetically both the identity and functionality of rare males using DNA barcoding and microsatellite loci. Our result suggests that these males may have an evolutionary role through genetic exchange with related sexual species and that diploid parthenogenetic Artemia is a good model system to investigate the evolutionary transitions between sexual species and parthenogenetic strains.     

Cytogenetics of the parthenogenetic grasshopper Warramaba (formerly Moraba) virgo and its bisexual relatives

The karyotypes of Warramaba virgo and the two bisexual species which gave rise to it, by hybridization, have been studied by the C- and G-banding techniques. W. virgo consists of a number of clones which differ by a limited number of inversions, translocations and fusions and also in C-banding pattern. In general, each local population consists of a single clone, although instances are known where two clones exist at the same locality. A total of fifteen cytological clones are here recognised and described. Some of these are known from single localities, while others have been found at several collecting sites in the same general area. The differences between them in banding pattern are relatively minor, i.e. the architecture of the karyotype has been highly conserved. A total of 50 C-bands have been recognised in W. virgo, but some of these are only present in a single clone and most clones have 39–40 bands. Most of these are centromeric or interstitial; a few are terminal (telomeric) in the short arms. There are three types of bands, dark-staining centromeric ones, intermediate ones that are somewhat less densely staining, and lighter ones that appear grey even after successful C-banding. The C-banding pattern of W. virgo provides additional evidence for its origin by hybridization between the bisexual species P196 and P169. It is possible that W. virgo arose only once (i.e. from one or more matings between P196 and P169 individuals in the same deme, within a few generations). However, two clones (Zanthus and Boulder), which are themselves closely similar, differ so much in banding pattern from all others that they may have arisen independently.     

Origin and Genetic Diversity of Diploid Parthenogenetic Artemia in Eurasia

There is wide interest in understanding how genetic diversity is generated and maintained in parthenogenetic lineages, as it will help clarify the debate of the evolution and maintenance of sexual reproduction. There are three mechanisms that can be responsible for the generation of genetic diversity of parthenogenetic lineages: contagious parthenogenesis, repeated hybridization and microorganism infections (e.g. Wolbachia). Brine shrimps of the genus Artemia (Crustacea, Branchiopoda, Anostraca) are a good model system to investigate evolutionary transitions between reproductive systems as they include sexual species and lineages of obligate parthenogenetic populations of different ploidy level, which often co-occur. Diploid parthenogenetic lineages produce occasional fully functional rare males, interspecific hybridization is known to occur, but the mechanisms of origin of asexual lineages are not completely understood. Here we sequenced and analysed fragments of one mitochondrial and two nuclear genes from an extensive set of populations of diploid parthenogenetic Artemia and sexual species from Central and East Asia to investigate the evolutionary origin of diploid parthenogenetic Artemia, and geographic origin of the parental taxa. Our results indicate that there are at least two, possibly three independent and recent maternal origins of parthenogenetic lineages, related to A. urmiana and Artemia sp. from Kazakhstan, but that the nuclear genes are very closely related in all the sexual species and parthenogegetic lineages except for A. sinica, who presumable took no part on the origin of diploid parthenogenetic strains. Our data cannot rule out either hybridization between any of the very closely related Asiatic sexual species or rare events of contagious parthenogenesis via rare males as the contributing mechanisms to the generation of genetic diversity in diploid parthenogenetic Artemia lineages.     

Extensive variation in chromosome number and genome size in sexual and parthenogenetic species of the jumping‐bristletail genus Machilis (Archaeognatha)

Parthenogenesis in animals is often associated with polyploidy and restriction to extreme habitats or recently deglaciated areas. It has been hypothesized that benefits conferred by asexual reproduction and polyploidy are essential for colonizing these habitats. However, while evolutionary routes to parthenogenesis are manifold, study systems including polyploids are scarce in arthropods. The jumping‐bristletail genus Machilis (Insecta: Archaeognatha) includes both sexual and parthenogenetic species, and recently, the occurrence of polyploidy has been postulated. Here, we applied flow cytometry, karyotyping, and mitochondrial DNA sequencing to three sexual and five putatively parthenogenetic Eastern‐Alpine Machilis species to investigate whether (1) parthenogenesis originated once or multiply and (2) whether parthenogenesis is strictly associated with polyploidy. The mitochondrial phylogeny revealed that parthenogenesis evolved at least five times independently among Eastern‐Alpine representatives of this genus. One parthenogenetic species was exclusively triploid, while a second consisted of both diploid and triploid populations. The three other parthenogenetic species and all sexual species were diploid. Our results thus indicate that polyploidy can co‐occur with parthenogenesis, but that it was not mandatory for the emergence of parthenogenesis in Machilis. Overall, we found a weak negative correlation of monoploid genome size (Cx) and chromosome base number (x), and this connection is stronger among parthenogenetic species alone. Likewise, monoploid genome size decreased with elevation, and we therefore hypothesize that genome downsizing could have been crucial for the persistence of alpine Machilis species. Finally, we discuss the evolutionary consequences of intraspecific chromosomal rearrangements and the presence of B chromosomes. In doing so, we highlight the potential of Alpine Machilis species for research on chromosomal and genome‐size alterations during speciation.     

Cytogenetics of the parthenogenetic grasshopper Moraba virgo and its bisexual relatives

An undescribed bisexual grasshopper species closely related to the all-female parthenogenetic Moraba virgo has an X₁X₂Y sex chromosome mechanism which incorporates 7 chromosomes of the ancestral karyotype (the original X and three pairs of autosomes). Apparently three separate chromosomal fusions have occurred, one of these being a tandem fusion followed by a crossover which stabilized it in the sex chromosome system. M. virgo probably arose from an ancestor which had X₁X₂Y males but lacked the tandem fusion present in the new species, the females of virgo having the constitution X₁X₁X₂O.Supported by Public Health Service Grant GM-07212 from the Division of General Medical Sciences, U.S. National Institutes of Health, and by a grant from the Australian Research Grants Committee.     

DNA elements modulating the <Emphasis Type="Italic">KARS12</Emphasis> chromosomal replicator in <Emphasis Type="Italic">Kluyveromyces lactis</Emphasis>

Eukaryotic chromosomal DNA replication is initiated by a highly conserved set of proteins that interact with cis-acting elements on chromosomes called replicators. Despite the conservation of replication initiation proteins, replicator sequences show little similarity from species to species in the small number of organisms that have been examined. Examination of replicators in other species is likely to reveal common features of replicators. We have examined a Kluyeromyces lactis replicator, KARS12, that functions as origin of DNA replication on plasmids and in the chromosome. It contains a 50-bp region with similarity to two other K. lactis replicators, KARS101 and the pKD1 replication origin. Replacement of the 50-bp sequence with an EcoRI site completely abrogated the ability of KARS12 to support plasmid and chromosomal DNA replication origin activity, demonstrating this sequence is a common feature of K. lactis replicators and is essential for function, possibly as the initiator protein binding site. Additional sequences up to 1 kb in length are required for efficient KARS12 function. Within these sequences are a binding site for a global regulator, Abf1p, and a region of bent DNA, both of which contribute to the activity of KARS12. These elements may facilitate protein binding, protein/protein interaction and/or nucleosome positioning as has been proposed for other eukaryotic origins of DNA replication.     

DNA EVIDENCE FOR NONHYBRID ORIGINS OF PARTHENOGENESIS IN NATURAL POPULATIONS OF VERTEBRATES

Naturally occurring unisexual reproduction has been documented in less than 0.1% of all vertebrate species. Among vertebrates, true parthenogenesis is known only in squamate reptiles. In all vertebrate cases that have been carefully studied, the clonal or hemiclonal taxa have originated through hybridization between closely related sexual species. In contrast, parthenogenetic reproduction has arisen in invertebrates by a variety of mechanisms, including likely cases of “spontaneous” (nonhybrid) origin, a situation not currently documented in natural populations of vertebrates. Here, we present molecular data from the Neotropical night lizard genus Lepidophyma that provides evidence of independent nonhybrid origins for diploid unisexual populations of two species from Costa Rica and Panama. Our mitochondrial and nuclear phylogenies are congruent with respect to the unisexual taxa. Based on 14 microsatellite loci, heterozygosity (expected from a hybrid origin) is low in Lepidophyma reticulatum and completely absent in unisexual L. flavimaculatum. The unique value of this system will allow direct comparative studies between parthenogenetic and sexual lineages in vertebrates, with an enormous potential for this species to be a model system for understanding the mechanisms of nonhybrid parthenogenesis.     

Interspecific interactions and learning variability jointly drive geographic differences in mate preferences

Co‐occurrence of closely related species can cause behavioral interference in mating and increase hybridization risk. Theoretically, this could lead to the evolution of more species‐specific mate preferences and sexual signaling traits. Alternatively, females can learn to reject heterospecific males, to avoid male sexual interference from closely related species. Such learned mate discrimination could also affect conspecific mate preferences if females generalize from between species differences to prefer more species‐specific mating signals. Female damselflies of the banded demoiselle (Calopteryx splendens) learn to reject heterospecific males of the beautiful demoiselle (C. virgo) through direct premating interactions. These two species co‐occur in a geographic mosaic of sympatric and microallopatric populations. Whereas C. virgo males have fully melanized wings, male C. splendens wings are partly melanized. We show that C. splendens females in sympatry with C. virgo prefer smaller male wing patches in conspecific males after learning to reject heterospecific males. In contrast, allopatric C. splendens females with experimentally induced experience with C. virgo males did not discriminate against larger male wing patches. Wing patch size might indicate conspecific male quality in allopatry. Co‐occurrence with C. virgo therefore causes females to prefer conspecific male traits that are more species specific, contributing to population divergence and geographic variation in female mate preferences.     

Genetic distinctness of parthenogenetic forms of European Polydrusus weevils of the subgenus Scythodrusus

Abstract Among eight species of Polydrusus weevils which belong to subgenus Scythodrusus, at least two possess parthenogenetic forms: P. (S.) inustus and P. (S.) pilifer. Both of these species consist of dioecious populations in the Caspian area and of parthenogenetic populations in Eastern Europe (P. (S.) inustus), the Caucasus region (both species) and Middle Asia (P. (S.) pilifer). The origin of parthenogenesis in this subgenus is unresolved; however some data suggest that the parthenogenetic forms are of hybrid ancestry. The genetic distinctness of parthenogenetic Scythodrusus was assessed on the basis of COII, ITS2, EF1‐α and Wolbachiawsp, 16S ribosomal DNA, ftsZ and hcpA sequence comparisons. Both taxa turned out to be monophyletic for all markers, which is an evidence against hybridization of their dioecious ancestors. On the other hand, a high frequency of heterozygous P. (S.) inustus females suggests an origin resulting from hybridization between genetically distinct dioecious representatives of this species. Very similar strains of Wolbachia supergroup A were found in both species, indicating that they have been either inherited from a common ancestor or were transmitted between parthenogenetic Scythodrusus weevils and probably spread randomly across their ranges.     

Listening when there is no sexual signalling? Maintenance of hearing in the asexual bushcricket <Emphasis Type="Italic">Poecilimon intermedius</Emphasis>

Unisexual reproduction is a widespread phenomenon in invertebrates and lower vertebrates. If a former sexual reproducing species becomes parthenogenetic, we expect traits that were subject to sexual selection to diminish. The bushcricket Poecilimon intermedius is one of the few insect species with obligate but diploid parthenogenetic reproduction. We contrasted characters that are involved in mating in a sexually sibling species with the identical structures in the parthenogenetic P. intermedius. Central for sexual communication are male songs, while receptive females approach the males phonotactically. Compared to its sister-species P. ampliatus, the morphology of the hearing organs (acoustic spiracle, crista acustica) and the function of hearing (acoustic threshold) are reduced in P. intermedius. Nonetheless, hearing is clearly maintained in the parthenogenetic females. Natural selection by acoustic hunting bats, pleiotropy or a developmental trap may explain the well maintained hearing function.     

Genus specificity and extensive methylation of the W chromosome-specific repetitive DNA sequences from the domestic fowl,Gallus gallus domesticus

Two female-specific repeating DNA units of 0.6 kilobase pairs (kb) and 1.1 kb, produced by digesting the genomic DNA of the White Leghorn chicken with Xho I, were cloned by inserting them into the Xho I site of an Escherichia coli plasmid vector pACYC177. Two such recombinant plasmids, pAGD0601 and pAGD1101, containing a single 0.6-kb and 1.1-kb sequence, respectively, were used as molecular probes. In situ hybridization of the ³Hprobes to the metaphase chromosomes from the female White Leghorn embryos revealed their localization in the W chromosome. Semiquantitative Southern blot hybridization with ³²P-probes in excess indicated that the 0.6-kb unit and 1.1-kb unit were repeated approximately 14,000 and 6,000 times, respectively, in the W chromosome. The two units comprised about 46% of the W chromosomal DNA. These two repeating units were found in the female genomes of every line of Gallus g. domesticus tested and in the female genomes of three jungle fowl species (G. gallus, G. sonneratii, and G. varius) but not in three species belonging to other genera in the suborder Galli. Hha I sites in the 0.6-kb and 1.1-kb repeating units were shown to be extensively methylated and a significant fraction of the Hpa II sites in the 0.6-kb repeating units were also shown to be methylated in the female genome of the White Leghorn. Methylation patterns of Hpa II sites in or around the 0.6-kb repeating units examined by the Msp I digestion were similar in the various lines of domestic fowls and the two species of jungle fowls, but G. varius (black or green jungle fowl) produced a different pattern of digestion with Msp I.     

The parthenogenetic Marmorkrebs (Malacostraca: Decapoda: Cambaridae) is a triploid organism

There is a close association between parthenogenesis and polyploidy. For this reason, we undertook a karyological analysis to test whether the parthenogenetic Marmorkrebs, Procambarus fallax forma virginalis, possesses an enlarged set of chromosomes. For this purpose, we karyotyped the Marmorkrebs, the sexual form of P. fallax (together called P. fallax complex), and the closely related species P. alleni. The latter shows 94 chromosomes in the haploid condition. In contrast to this, we found a haploid set of 92 chromosomes in individuals of the P. fallax complex. However, in mitotic metaphases the sexual form shows 184 chromosomes, whereas the Marmorkrebs possesses 276 chromosomes. Hence, the parthenogenetic Marmorkrebs reveals a triple amount of the haploid chromosome number. In addition, we detected a strikingly large subtelocentric chromosome which appears once in haploid and twice in diploid cells of sexual individuals of the P. fallax complex. In the parthenogenetic Marmorkrebs, this prominent chromosome occurs thrice. All this clearly reveals that the Marmorkrebs is a triploid organism. The applicability of the used methods, the significance of polyploidy in evolution of Decapoda, putative pathways to parthenogenetic triploidy, a possible hybrid origin and the scientific and ecological consequences of an increased chromosome set in Marmorkrebs are discussed.     

Cytogenetics of the parthenogenetic grasshopper Warramaba (formerly Moraba) virgo and its bisexual relatives

Triploid hybrids have been obtained by crossing individuals of the diploid Warramaba virgo with males of two undescribed related species of Warramaba, P169 (neo-XY) and P196 (X₁X₂Y). In both cases, offspring which receive a Y-chromosome from the father are males, while those that receive a neo-X from P169 or an X₁ and an X₂ from P196 are females. The triploids can be distinguished from diploids, even in the earliest nymphal instars, by the larger size of their eye facets. Their gonads are undeveloped and abnormal so that they are mostly sterile (the males absolutely so). Nevertheless, in the case of female hybrids (both the ones between virgo and P169 and those between virgo and P196) a few oocytes do develop and it was possible to obtain a further generation of hybrids by parthenogenesis. These, which are all female, and have karyotypes identical to those of their mothers, are derived from eggs which have undergone the virgo type of meiosis, with a premeiotic doubling of the chromosome number, followed by synapsis restricted to sister chromosomes. — Some diploid hybrids have also been obtained between the bisexual species P169 () and P196 (). In this case the male offspring died in the embryonic stage or immediately after hatching. Female hybrids, on the other hand, were viable but had under-developed ovaries, so that they only laid very few eggs. Some of the latter developed into embryos with a karyotype identical to that of the mother, but the meiosis of these eggs has not yet been studied, so that it is not known whether it is of the virgo type. These hybridization experiments support the hypothesis that virgo originated as a hybrid between P196 and P169. — A single male hybrid between Warramaba picta () and P169 () was obtained; it had active spermatogenesis, but many meiotic abnormalities.