The origin and evolution of parthenogenesis in Heteronotia binoei (Gekkonidae)

Within Australia, the gekkonid lizard Heteronotia binoei exists as diploid bisexual and triploid all-female populations. Three bisexual cytotypes and three triploid clones can be described on the basis of the morphology of gross karyotypes. This paper reports the results of a C-banding analysis that revealed both intrapopulation polymorphism and interpopulation polytypic variation within the most widespread bisexual cytotype (A6). A C-band variant that defined a ZW sex chromosome system in populations from the MacDonnell Ranges in central Australia was also identified. Silver staining confirmed that in all populations the nucleolus organising region always occurred distally on chromosome 6. Examination of C-banding and silver-staining patterns of triploid populations provided strong support for a hybrid origin of the parthenogens that involved the central and western A6 populations. It is proposed that the hybridisation of these populations with the other chromosomally distinct bisexual cytotypes (SM6) resulted in the triploid clones. At present, seven clones have been karyotypically defined, and all the chromosomal variants that were present in the triploids can be accounted for by multiple hybridisation events between the bisexual populations. The analysis also provided evidence that rare sterile tetraploid females are the result of insemination of the triploid parthenogens by male H. binoei. This paper is dedicated to the memory of M.J.D. White (1910–1983)     

The chromosome banding pattern in two cytotypes (2n = 36 and 38) of blind mole rats from Turkey (Mammalia: Spalaxidae)

Two cytotypes (2n = 36 and 38) of blind mole rats, Nannospalax xanthodon (Nordmann, 1840), from the Ayd?n and Manisa provinces in Turkey were investigated. Conventional chromosome staining, Ag-NOR staining and C-banding analysis were carried out. From the cytogenetic point of view, the particular phylogenetic position of these populations is supported by their low diploid numbers only, and the Cbanding pattern and the NORs distribution seem generally similar to populations with higher chromosome numbers. Several autosomal pairs with centromeric dark Cbands were observed in the 2n=36 cytotype. One autosomal pair possessed an interstitial dark C-band on the short arm; another pair possessed an interstitial dark Cband on the long arm. Whole C-heterochromatic short arms were observed in three subtelocentric autosomal pairs in the 2n=38 cytotype. Most of the other autosomal pairs possessed centromeric dark C-bands. Distinct dark C-bands were observed also in the presumed X chromosomes of both the cytotypes. The Ag-NOR regions were found on three autosomal pairs of both the cytotypes. These sites were located in telomeric areas of the short arms of two subtelocentric and one submetacentric pair.     

Genome size variation and C-band polymorphism inAlstroemeria aurea, A. ligtu andA. magnifica (Alstroemeriaceae)

Among a total of 43 accessions ofAlstroemeria aurea, A. ligtu andA. magnifica nuclear DNA amounts (2C-values) showed significant intraspecific variation, 1.09, 1.21 and 1.15 fold, respectively, when determined through flow cytometric measurements of fluorescence of propidium iodide (PI) stained nuclei. After staining with another fluorochrome, 4,6-diamidino-2-phenylindole (DAPI), an intraspecific variation of 1.10, 1.11 and 1.12 fold, respectively, was found. C-band polymorphisms were present among and within the accessions of all three species. In some cases only very small differences in C-banding pattern were observed. In other cases, however, differences were more prominent. Besides C-band polymorphism, there were also instances of chromosome length polymorphism, which concerned the total chromosome complement or single chromosomes. The variation in nuclear DNA amount inA. aurea andA. ligtu was more or less continuous, except for one accession ofA. ligtu subsp.simsii. Artificial selection and possibly introgression of chromosomes from other species may have moulded the karyotypes of some of the accessions ofA. aurea, a species that has been under cultivation for more than 160 years. The variation as observed inA. magnifica subsp.magnifica was discontinuous and could be due to a broad species concept.     

A pericentric-inversion polymorphism and s ZZ/ZW sex-chromosome system in Varanus acanthurus Boulenger analyzed by G- and C-banding and Ag staining

A chromosomal analysis of the monitor Varanus acanthurus Boulenger has been made using G- and C-banding and silver-staining techniques. This species has two cytotypes, one of which has a pericentric-inversion polymorphism, whereas the other is chromosomally monomorphic. A ZZ/ZW sex-chromosome system is also present in both cytotypes of this species. The banding patterns of these mechanisms are described and their evolution is discussed.     

C-band polymorphisms in exotic inbred strains of mice: a method for mapping centromeric ends of chromosomes.

The major satellite DNA of Mus musculus appears as a pericentromeric heterochromatin block in all chromosomes but the Y. While C-banding readily reveals the presence of this heterochromatin block, there is considerable polymorphism in C-band size among the chromosomes and among different subspecies. We have studied the distribution of C-band size differences in the chromosomes of 15 exotic inbred laboratory strains and substrains derived from wild populations of different subspecies of M. musculus. The variation in C-band size among these inbred strains can serve as a useful codominant cytological marker for estimating recombinational distances between the centromere and proximal genes in linkage crosses.     

Molecular genetics of Rhabdomys pumilio subspecies boundaries: mtDNA phylogeography and karyotypic analysis by fluorescence in situ hybridization

The phylogeography of the African four-striped mouse, Rhabdomys pumilio, was investigated using complete sequences of the mtDNA cytochrome b gene (1140 bp) and a combination of fluorescence in situ hybridization (FISH) and conventional cytogenetic banding techniques (G- and C-banding). Two cytotypes (2n=46 and 2n=48) were identified by cytogenetic analysis. There is no evidence of diploid number variation within populations, difference in gross chromosome morphology or of subtle interchromosomal rearrangements at levels detected by ZOO-FISH. Analysis of the mtDNA cytochrome b resulted in two major lineages that correspond roughly to the xeric and mesic biotic zones of southern Africa. One mtDNA clade comprises specimens with 2n=48 and the other representatives of two cytotypes (2n=48 and 2n=46). The mean sequence divergence (12%, range 8.3–15.6%) separating the two mtDNA clades is comparable to among-species variation within murid genera suggesting their recognition as distinct species, the prior names for which would be R. dilectus and R. pumilio. Low sequence divergences and the diploid number dichotomy within the mesic lineage support the recognition of two subspecies corresponding to R. d. dilectus (2n=46) and R. d. chakae (2n=48). Our data do not support subspecific delimitation within the nominate, R. pumilio. Molecular dating places cladogenesis of the two putative species at less than five million years, a period characterised by extensive climatic oscillations which are thought to have resulted in habitat fragmentation throughout much of the species range.     

Giemsa C-banded karyotypes of two subspecies ofHordeum brevisubulatum from China

C-banding patterns ofH. brevisubulatum subsp.brevisubulatum (2x) and subsp.turkestanicum (4x) had conspicuous telomeric C-bands in at least one chromosome arm with a minor difference in average band size between subspecies. Other conspicuous bands were few in number as in other taxa of the species complex. The C-banded area of the chromosomes was estimated to be 7 to 8 and 6 per cent, respectively. C-banding- and SAT-chromosome polymorphisms were observed in both subspecies. The latter and previous observations indicate that the number of SAT-chromosomes is a less reliable diagnostic character. Nucleolar organizer region polymorphisms were demonstrated through silver nitrate staining of nucleoli. C-banding patterns corroborated that tetra- and hexaploid cytotypes of subsp.turkestanicum form an autopolyploid series. Reliable identification ofH. brevisubulatum taxa based on cytological criteria should include the simultaneous use of C-banding patterns, and number and morphology of marker chromosomes.     

Population cytogenetics of Atractomorpha similis

Atractomorpha similis (2 n=19 ♂, 20 ♀) is a hygrophilous, tropical to temperate, species of pyrgomorphine grasshopper. We have sampled 70 populations covering the known distributional range of this species within Australia. All of them proved to be polymorphic for heterochromatin content as revealed by C-band analysis of embryonic neuroblasts. This polymorphism affects all ten members of the basic haploid set and includes variants involving differences in either the presence or the amount of procentric, interstitial and terminal C-blocks, as well as variation in the occurrence and nature of short arms on otherwise telocentric chromosomes. A majority of these variants appear to result from heterochromatin addition since the presumptive sibling, Atractomorpha australis, like other species of the genus that have been C-banded, is generally depauperate in heterochromatin. The net result of this extraordinary polymorphism is that each chromosome of A. similis exists in 10–50 distinct morphs. Consequently, there is a high level of chromosomal heterozygosity in all populations in terms of the number of heterozygous pairs present within a complement and an even higher level in terms of the total range of karyomorph patterns. There is also a wide range of total heterochromatin content, as measured by the percent of the total chromosome area occupied by C-band material, with values ranging from 13% to 44%. Specific marker chromosomes which predominate in particular geographical areas serve to distinguish six major cytotypes within A. similis. The two most southerly of these cytotypes show a narrower range of heterochromatin content but with higher values which reflect the more general occurrence of substantial terminal C-blocks within them. Finally, the populations from Fraser Island constitute a particularly distinctive cytotype characterised by the least number of morphs, the lowest level of chromosomal heterozygosity and a restricted range of heterochromatin content confined to the lower end of the known distributional spectrum.     

Cytogenetics of the South American Akodont rodents (Cricetidae) X. Akodon mollis: a species with XY females and B chromosomes

The morphology, G- and C-banding pattern of the Akodon mollis chromosome complement is analysed. Over a total of 14 males and 10 females studied, 8 males and 7 females had a modal chromosome number of 22, while 6 males and 3 females showed a modal number of 23 chromosomes. In the animals with 23 chromosomes the odd element was considered a B chromosome on the basis of: (a) its small size, (b) the lack of an homologous chromosome and the subsequent formation of univalents at diakinesis and metaphase I from testes, (c) the weak or null genetic action as evidenced by the lack of any obvious variation in the phenotype of carriers.Four females exhibited a sex-pair dimorphism indistinguishable from that observed in males. The G-banding analysis showed homology between the pattern found in the Y chromosome and that detected in the short arm of the X. The study of C-band distribution showed that several autosome pairs and the X chromosomes had small masses of centromeric heterochromatin. On the other hand, the Y and B chromosomes were C-band negative. The Y-like chromosome in females with dimorphism of the sex pair was also C-band negative. Accordingly these females were considered to be XY and not Xx (the x being an extensively deleted X chromosome).This work was supported by grants from UNESCO, OEA, CONICET and CIC. Requests for reprints should be addressed to N.O. Bianchi.     

Recovery of dissected C-band regions in Crepis chromosomes

Summary Chromosome samples were prepared on a plastic coverslip covered with a polyester membrane and were subjected to the C-banding treatment. The C-band pattern was obtained after Giemsa staining. The C-band positive regions of the Crepis chromosomes were identified, dissected out by irradiation with a micro-laser beam and recovered in Eppendorf tubes.     

Infraspecific variation in C-banded karyotype and chiasma frequency inCucumis sativus (Cucurbitaceae)

Infraspecific cytogenetical variation was studied in a diverse collection of five non-cultivated and cultivatedCucumis sativus accessions. The individual chromosomes of different accessions could be identified by the C-banding pattern and chromosome measurements. About 40–50% of the genomic area are made up of heterochromatin inC. sativus. The non-cultivated accessions exhibit more heterochromatin and lower chiasma frequencies per pollen mother cell than cultivated accessions. There is infraspecific variation in C-banding pattern, karyomorphology and multinucleolate cells. The use of C-banding in infraspecific classification is discussed.     

Photosynthetic characteristics of three ploidy levels of Allium oleraceum L. (Amaryllidaceae) differing in ecological amplitude

To elucidate the mechanisms of the adaptive advantages of polyploidy, there is a need to identify physiological traits that participate in the success of polyploids. We studied selected photosynthetic characteristics, stomatal density, and specific leaf area of three ploidy levels (2n = 4x, 5x, 6x) of the geophyte Allium oleraceum that partially differ in their ecological niches. Although the cytotypes were on average similar with regard to most of the measured photosynthetic traits, the hexaploids showed more rapid initial photosynthetic induction and a tendency for a higher maximum photosynthetic rate per unit area. The stomatal density was not affected by ploidy, though the specific leaf area was reduced for the hexaploids compared to the other cytotypes. A lower intracytotype variation was found for most of the studied photosynthetic and anatomical traits for the hexaploids compared to the large variation found within other cytotypes. A comparison of the photosynthetic traits between the cytotypes showed that the ecological differentiation between cytotypes is only weakly related to the characteristics of their photosynthetic apparatus. However, contrasting ranges of variability in the measured traits between the cytotypes can be related to previously observed differences between cytotypes with regard to the ranges of intracytotype genetic variation, genome size variation, and niche breadth. A higher variability of photosynthetic traits in tetraploids and pentaploids may be related to the existence of a spectrum of types adapted to different environmental conditions. Hexaploids may represent a recently formed cytotype adapted to open environmental conditions.     

Variation in highly repetitive DNA composition of heterochromatin in rye studied by fluorescence in situ hybridization.

The molecular characterization of heterochromatin in six lines of rye has been performed using fluorescence in situ hybridization (FISH). The highly repetitive rye DNA sequences pSc 119.2, pSc74, and pSc34, and the probes pTa71 and pSc794 containing the 25S-5.8S-18S rDNA (NOR) and the 5S rDNA multigene families, respectively, were used. This allowed the individual identification of all seven rye chromosomes and most chromosome arms in all lines. All varieties showed similar but not identical patterns. A standard in situ hybridization map was constructed following the nomenclature system recommended for C-bands. All FISH sites observed appeared to correspond well with C-band locations, but not all C-banding sites coincided with hybridization sites of the repetitive DNA probes used. Quantitative and qualitative differences between different varieties were found for in situ hybridization response at corresponding sites. Variation between plants and even between homologous chromosomes of the same plant was found in open-pollinated lines. In inbred lines, the in situ pattern of the homologues was practically identical and no variation between plants was detected. The observed quantitative and qualitative differences are consistent with a corresponding variation for C-bands detected both within and between cultivars.     

Molecular genetics of Rhabdomys pumilio subspecies boundaries: mtDNA phylogeography and karyotypic analysis by fluorescence in situ hybridization

The phylogeography of the African four-striped mouse, Rhabdomys pumilio, was investigated using complete sequences of the mtDNA cytochrome b gene (1140 bp) and a combination of fluorescence in situ hybridization (FISH) and conventional cytogenetic banding techniques (G- and C-banding). Two cytotypes (2n=46 and 2n=48) were identified by cytogenetic analysis. There is no evidence of diploid number variation within populations, difference in gross chromosome morphology or of subtle interchromosomal rearrangements at levels detected by ZOO-FISH. Analysis of the mtDNA cytochrome b resulted in two major lineages that correspond roughly to the xeric and mesic biotic zones of southern Africa. One mtDNA clade comprises specimens with 2n=48 and the other representatives of two cytotypes (2n=48 and 2n=46). The mean sequence divergence (12%, range 8.3-15.6%) separating the two mtDNA clades is comparable to among-species variation within murid genera suggesting their recognition as distinct species, the prior names for which would be R. dilectus and R. pumilio. Low sequence divergences and the diploid number dichotomy within the mesic lineage support the recognition of two subspecies corresponding to R. d. dilectus (2n=46) and R. d. chakae (2n=48). Our data do not support subspecific delimitation within the nominate, R. pumilio. Molecular dating places cladogenesis of the two putative species at less than five million years, a period characterised by extensive climatic oscillations which are thought to have resulted in habitat fragmentation throughout much of the species range.     

Chromosomes of Australian lygosomine skinks (Lacertilia: Scincidae)

The karyotypes of 25 species from the scincid genera Egernia, Corucia and Tiliqua have been investigated using C-banding, silver staining of nucleolar organiser regions (NORs) and Hoechst 33258 induced condensation inhibition. At least one member from each of the species groups of Egernia recognised by Storr et al. (1981) was studied. The three genera have very similar conventionally stained karyotypes of 32 chromosomes. Some species show departures from this basic karyotype but these are due to additions of C-band positive material. Silver stained. NOR patterns are variable but most species have a silver staining site on a pair of larger microchromosomes. All specimens studied except one have a proximal C-band on the acrocentric ninth pair, which shows failure to condense following treatment with the fluorochrome Hoechst 33258. Heterogamety was not observed in any species. Mabuya multifasciata, proposed as a relative of the Egernia group, while having 32 chromosomes does not share the C-band marker on pair nine, unique to the Egernia group. Tribolonotus gracilis, sometimes allied with the Egernia group, has 32 chromosomes and a similiar karyotype, but prominent procentric C-bands on all chromosome pairs obscure the detection of the proximal C-band marker on pair nine.     

C,Q and H-banding in the analysis of Y chromosome rearrangements in Lucilia cuprina (Wiedemann) (Diptera: Calliphoridae)

In Lucilia cuprina C-banding produces procentric bands on all autosomes and deep staining over most of the X and Y chromosomes which conciderably facilitates the analysis of complex Y chromosome rearrangements. The Y chromosome is generally darkly C-banded throughout while in the X chromosome a pale staining segment is found in the distal portion of the long arm. Modulation of the banding reaction results in grey areas in both X and Y. When C-banding is compared with allocycly it is clear that not all heteropycnotic regions in the sex chromosomes C-band to the same extent. Secondary constrictions in the short arms of both X and Y chromosomes are clearly revealed by C-banding, the X satellite being polymorphic for size.— Q-banding results in a brightly fluorescing band in the short arm of structurally normal Y chromosomes. This band loses its fluorescence in some translocations, probably through a position effect. Hoechst 33258 staining does not produce any brightly fluorescing bands.     

Heterochromatin diversity and cyclic responses to selective silver staining in Aedes aegypti (L.)

In interphase cells of Aedes aegypti (L.) (2n=4+ XX/XY), only the nucleolus responded to selective silver staining. The secondary constriction on chromosome 3 remained unresponsive at all times but the six centromeres were identified throughout mitosis from early prophase as well as those stages of meiosis subsequent to diplotene. The centromeric blocks were not synonymous with the pericentric heterochromatin revealed by C-banding. X chromosomes without an intercalary C-band were newly discovered in Ae. aegypti in the Bangalore strain. Sequential Q-or Hoechst 33258/C-banding in this and the Trinidad-30 strain revealed intercalary heterochromatin diversity within and between strains and also differences between intercalary and pericentric heterochromatin.     

Giemsa C-banding patterns in Aedes (Stegomyia) mosquitoes

Chromosomes from gonads of 14–24 h old pupae of nine species of Stegomyia mosquitoes have been examined using the Giemsa C-banding technique. The species studied were Aedes albopictus, A. polynesienis, A. scutellaris, A. alcasidi, A. seatoi, A. pseudalbopictus, A. melallicus, A. annandalei and A. vittatus. The diploid chromosome number of all species is six. All species possess C-bands in the centromeric regions of each of the three pairs of chromosomes. Besides, an intercalary C-band is present on the female determining (=m) chromosome but absent from the male—determining (= M) chromosome of all species except A. vittatus. In A. vittatus, the m and M chromosomes possess a terminal C-band. Thus, the nine species of Aedes analysed showed two distinct patterns of C-banding. —The evolution of heterochromatin patterns in various species is also discussed. The Giemsa C-banding technique should prove useful in studies of chromosomal speciation in culicine mosquitoes.     

FLAVONOID RACES OF CLAYTONIA VIRGINICA (PORTULACACEAE)

Four flavonoid races have been found in the Claytonia virginica aneuploid complex, differing from one another in the accumulation of 12 kaempferol and quercetin 3-glycosides. Each of these races has a distinctive geographical distribution within the overall range of the species. The three major diploid cytotypes of C. virginica each belong to different races, two of which also include polyploids; a fourth race consists entirely of polyploids. An examination of biosynthetic pathways indicates that a small number of genetic changes are responsible for the observed variation; polyploidy per se does not appear to have contributed significantly to the production of novel compounds. Flavonoid data also suggest strongly that polyploidy within rather than between modern chemical races has been responsible for the bulk of chromosome number variation in the species.     

The evolution of a highly variable sex chromosome in Gehyra purpurascens (Gekkonidae)

A karyotypic survey of the gekkonid lizard Gehyra purpurascens revealed a distinctive sex chromosome system. G-banding showed that the Z Chromosome of males is derived from a tandem fusion of two acrocentric chromosomes of a presumed ancestral Gehyra with 2n=44. Through the application of G-; N- and C-banding, a total of six morphs of the W chromosome were identified. These differ by paracentric and pericentric inversions and, in one case, by a centric shift. The possible reasons for such extensive variation in the W chromosome are considered, and it is suggested that increased mutability of the W chromosome may be a causal factor. In contrast to earlier speculations, this example demonstrates that sex chromosomes can evolve without significant changes in the amount of C-band heterochromatin.