Cytogenetics of the parthenogenetic grasshopper Warramaba virgo and its bisexual relatives

Combinations of DNA-binding fluorescent dyes and counterstains that enhance selectivity and contrast in primary stain fluorescence were used to differentiate types of C-bands in the genus Warramaba. Chromomycin A₃ (in conjunction with two A-T binding counterstains), which identifies chromosome segments enriched in G-C base pair clusters, stains only a minority of the C-bands in Warramaba species, but these include all those known to contain 18S + 26S rRNA cistrons and most of those containing 5S rRNA genes. DAPI/actinomycin D fluorescent staining is positive for a very few bands, including two (in the Standard phylad of W. virgo) that are at or adjacent to sites containing 5S rRNA cistrons. One of the latter regions is also positively stained by DAPI/distamycin A which, in addition, highlights some centromeric bands. The fluorescent staining patterns of the Standard and Boulder-Zanthus phylads of W. virgo are significantly different, confirming their independent origin by hybridization between different races of the ancestral species “P169” and “P196”.     

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.     

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

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.     

Cytogenetics of the grasshopper Moraba scurra

Summary The cytology of a male individual of the grasshopper Moraba scurra which was heterozygous for a complex translocation involving breaks in four different, non-homologous, chromosomes, is described. Chains of up to eight chromosomes occur at first metaphase. Certain chromosomes which never normally show more than a single chiasma form two chiasmata with a fairly high frequency in this individual.Supported by Public Health Service Grant No. RG7212-Cl, from the Division of General Medical Sciences, U.S. National Institutes of Health.     

Speciation in the Artemia genus: Mitochondrial DNA analysis of bisexual and parthenogenetic brine shrimps

From the cloned mitochondrial DNAs (mtDNAs) isolated from two bisexual species, one Mediterranean, Artemia salina, and one American, Artemia franciscana, and two parthenogenetic (diploid and tetraploid) strains of Artemia parthenogenetica collected in Spain, physical maps have been constructed and compared. They are extremely different among themselves, much more than the differences between Drosophila melanogaster and D. yakuba and in the same range of different mammalian species such as mouse/rat or man/cow. The nucleotide sequences of two regions of mtDNA encoding parts of the cytochrome c oxidase subunit I (COI) and cytochrome b (Cytb) genes have been determined in the two bisexual species and the two parthenogenetic strains. Comparisons of these sequences have revealed a high degree of divergence at the nucleotide level, averaging more than 15%, in agreement with the differences found in the physical maps. The majority of the nucleotide changes are silent and there is a strong bias toward transitions, with the CT substitutions being highly predominant. The evolutionary distance between the two Artemia parthenogenetica is high and there is no clear relationship with any of the bisexual species, including the one present nowadays in Spain. Using a combination of molecular (mtDNA) and morphological markers it is possible to conclude that all of these Artemia isolates should be actually considered as belonging to different species, even the two Artemia parthenogenetica diploidica and tetraploidica.On sabbatical leave from Departamento de Bioquímica, Facultad de Veterinaria, Universidad Complutense de Madridearly Italian artemiologists to designate the Medi-Beatriz Batuecas died in an accident during the Christmas holy days of 1988 after she had initiated this workCorrespondence to: R. Garesse     

Lower fecundity in parthenogenetic geckos than sexual relatives in the Australian arid zone

Theoretical models of the advantage of sexual reproduction typically assume that reproductive output is equal in sexual and parthenogenetic females. We tested this assumption by comparing fecundity between parthenogenetic and sexual races of gekkonid lizards in the Heteronotia binoei complex, collected across a 1200 km latitudinal gradient through the Australian arid zone. Under laboratory conditions, parthenogenetic geckos had approximately 30% lower fecundity when compared with their sexual progenitors, irrespective of body size. Reflecting clutch-size constraints in gekkonids, this fecundity difference was mainly because of fewer clutches over a shorter period. When parthenogens were compared more broadly with all coexisting sexual races across the latitudinal gradient, parthenogens had lower fecundity than sexuals only when corrected for body size. Differences in fecundity between parthenogens and coexisting sexual races depended on which sexual race was considered. There was no significant relationship between fecundity and parasite (mite) load, despite significantly higher mite loads in parthenogens than in sexual races.     

Finding of Bov-B LINE retroelement in parthenogenetic and bisexual lizard species of the genus Darevskia (Lacertidae)

The Bov-B LINE retrotransposon was first discovered in Ruminantia and was long considered to be specific for this order. Later, this mobile element was described in snakes and some lizard species. Analysis of phylogenetic relationships of Bov-B LINE elements from different ruminants, snakes, and lizard species led to the suggestion on horizontal transfer of this retrotransposon from Squamata to Ruminantia. In the Squamata group, Bov-B LINE element was found in all snakes and some lizard species examined. The element was not detected in the genomes of some species of the genera Lacerta and Podarcis. In the present study, using PCR amplification and sequencing of PCR products, Bov-B LINE element was identified in the genomes of parthenogenetic and bisexual species of the genus Darevskia (Lacertidae), as well as in such species as Lacerta agilis and Zootoca vivipara, where this retrotransposon had not been not detected before.     

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.     

Genetic similarity and diversity of parthenogenetic and bisexual populations of the freshwater snail Melanoides tuberculata (Gastropoda: Prosobranchia)

Genetic variability and similarity were analysed in four parthenogenetic and five bisexual populations of the snail Melanoides tuberculata found in Israel. Electrophoretic studies of six enzymatic systems revealed 28 zones of activity. The average genetic identity between populations was low—0.725. A particularly low similarity (0.628) was obtained between parthenogenetic populations, compared to the average of 0.822 observed among the bisexual ones. The percentage of fixed electrophoretic bands in parthenogens was 53.9% compared to 12.5% observed in bisexual populations. The diversity of parthenogenetic populations was found to be lower than those of bisexual. The amount of electrophoretic diversity between populations of the parthenogenetic group was found to be 80%, whereas within the bisexual group the diversity between populations was only 42%.     

Cytogenetics of the hybrids of three members of the grasshopper genus Vandiemenella (Orthoptera: Eumastacidae: Morabinae)

Certain members of the grasshopper genus Vandiemenella (earlier referred to as the viatica group) form a group of chromosomally distinct taxa with contiguous distributions through south-eastern Australia. Meiosis of hybrids between three of the members that occur on Kangaroo Island, South Australia, was studied. The three members were the taxonomically undescribed form P24(XY) and two chromosomal races of V. viatica. Hybrids were either collected from narrow overlap zones (viatica₁₉-viatica₁₇, viatica₁₉-P24 (XY), P24(XY)-vitica₁₇) or were reared from grasshoppers collected from areas close to the overlap zones. — Chromosomal heterozygotes were found in all three overlap zones, but were frequent only in the overlap zone of P24(XY) and viatica₁₇. Male chromosomal heterozygotes of P24(XY) and viatica₁₉ and of viatica₁₇ and viatica₁₉ had abnormalities of meiosis, such as asynapsis (or desynapsis), which were generally associated with the chromosomes that distinguish the taxa. These abnormalities would be expected to lead to a reduction of fertility and so may contribute to reproductive isolation. Analysis of embryos from female heterozygotes of P24(XY) and viatica₁₇ indicated that similar abnormalities of meiosis occurred in these females. Very few meiotic abnormalities, however, were seen in the corresponding male hybrids. The structurally different X chromosomes of female hybrids of P24(XY) and viatica₁₇ were recovered in a distorted ratio in their embryos. The distortion was only slight and would not be expected to be of importance in the evolution of the group, particularly since the distortion favoured the original rather than the derived type of chromosome.     

Trichoderma stromaticum and its overseas relatives

Trichoderma stromaticum, T. rossicum and newly discovered species form a unique lineage in Trichoderma. Phylogenetic and phenotypic diversity in Trichoderma stromaticum are examined in the light of reported differences in ecological parameters and AFLP patterns. Multilocus phylogenetic analysis using 4 genes (tef1, rbp2, cal, chi18-5) did not reveal phylogenetic basis for the two reported divergent AFLP patterns or for ecological parameters; however, this analysis does indicate incomplete speciation with one supported clade derived from within T. stromaticum that corresponds to AFLP Group 2 of de Souza et al. (2006, Phytopathology 96:61–67). Trichoderma stromaticum is known only from tropical America and is typically found in association with Theobroma cacao infected with Moniliophthora perniciosa. It is reported here for the first time on pseudostromata of M. roreri in Peru. Strains of T. stromaticum also have been isolated as endophytes from stems of Theo. cacao. There are no recognized close relatives of T. stromaticum in tropical America. The closest relatives of T. stromaticum are collected in Africa and Thailand; somewhat more distantly related are T. rossicum and T. barbatum, both found in north temperate regions.     

Diet mixing and its effect on polyphagous grasshopper nymphs

We examined the effects of diet mixture on the nymphal performance of a polyphagous grasshopper Parapodisma subastris Huang by developing the first-stadium nymphs with either single or various combinations of plants occurring in their natural habitat. Intrinsic quality in terms of nymphal survival differed largely across the 16 plant species. However, even combinations of the six worst quality plants (survival 10% or less in each) greatly improved nymphal survival when compared to that of superior quality plants (more than 70% survival). In contrast, the addition of either of two inferior plants (more than 10% and less than 40% survival) to the superior plant affected neither the survival nor the adult mass. Thus, diet mixture can be particularly important when only low quality plants are available. The adaptive significance of diet mixture was discussed in relation to the habitat flora and foraging habits of the grasshopper in the present study.