Chromosome numbers of some Indian moths

Cytological investigations in forty-five species of Indian moths belonging to ten families (Tinaeidae, Limacodidae, Thyrididae, Pyralididae, Lasiocampidae, Saturnidae, Sphingidae, Noctuidae, Lymantriidae, Hypsidae) of Lepidoptera revealed haploid chromosome numbers varying from 12 to 31, the latter number being predominant (in 26 species). Their haploid chromosome numbers at metaphase I and II are stated in a table.     

Karyotype evolution and sex chromosome differentiation in schistosomes (Trematoda,Schistosomatidae)

The morphology of C-banded metaphase chromosomes has been studied in two hermaphroditic and ten gonochoristic digenetic trematodes (schistosomes). Comparison of numbers and morphology of chromosomes indicates that the karyotype of primitive trematodes probably was composed of 10 (or 11) pairs of telocentric or subtelocentrie chromosomes, and reduction of chromosome numbers in advanced species resulted from centromeric fusion rather than elimination of chromosomes. Observation of heteromorphic chromosomes in a hermaphroditic trematode (Spirorchis) suggested a differentiation of pre-sex chromosomes in species ancestral to dioecious trematodes which possess distinctly differentiated sex chromosomes. Our results indicate that differentiation of Z and W chromosomes in the gonochoristic trematodes resulted from: (a) partial constitutive heterochromatinization of the W chromosome (Schistosoma mansoni and S. haematobium complexes, African schistosomes), (b) deletion of part of the W (S. japonicum and S. mekongi, Asian schistosomes), and (c) translocation of part of one sex chromosome onto another (Schistosomatium douthitti and Heterobilharzia americana, American schistosomes) with subsequent heterochromatinization of the W in H. americana.     

Evolutionary dynamics of rDNA clusters on chromosomes of moths and butterflies (Lepidoptera)

We examined chromosomal distribution of major ribosomal DNAs (rDNAs), clustered in the nucleolar organizer regions (NORs), in 18 species of moths and butterflies using fluorescence in situ hybridization with a codling moth (Cydia pomonella) 18S rDNA probe. Most species showed one or two rDNA clusters in their haploid karyotype but exceptions with 4–11 clusters also occurred. Our results in a compilation with previous data revealed dynamic evolution of rDNA distribution in Lepidoptera except Noctuoidea, which showed a highly uniform rDNA pattern. In karyotypes with one NOR, interstitial location of rDNA prevailed, whereas two-NOR karyotypes showed mostly terminally located rDNA clusters. A possible origin of the single interstitial NOR by fusion between two NOR-chromosomes with terminal rDNA clusters lacks support in available data. In some species, spreading of rDNA to new, mostly terminal chromosome regions was found. The multiplication of rDNA clusters without alteration of chromosome numbers rules out chromosome fissions as a major mechanism of rDNA expansion. Based on rDNA dynamics in Lepidoptera and considering the role of ordered nuclear architecture in karyotype evolution, we propose ectopic recombination, i.e., homologous recombination between repetitive sequences of non-homologous chromosomes, as a primary motive force in rDNA repatterning.     

Maximum likelihood inference implies a high, not a low, ancestral haploid chromosome number in Araceae, with a critique of the bias introduced by 'x'

Background and Aims

For 84 years, botanists have relied on calculating the highest common factor for series of haploid chromosome numbers to arrive at a so-called basic number, x. This was done without consistent (reproducible) reference to species relationships and frequencies of different numbers in a clade. Likelihood models that treat polyploidy, chromosome fusion and fission as events with particular probabilities now allow reconstruction of ancestral chromosome numbers in an explicit framework. We have used a modelling approach to reconstruct chromosome number change in the large monocot family Araceae and to test earlier hypotheses about basic numbers in the family.

Methods

Using a maximum likelihood approach and chromosome counts for 26 % of the 3300 species of Araceae and representative numbers for each of the other 13 families of Alismatales, polyploidization events and single chromosome changes were inferred on a genus-level phylogenetic tree for 113 of the 117 genera of Araceae.

Key Results

The previously inferred basic numbers x = 14 and x = 7 are rejected. Instead, maximum likelihood optimization revealed an ancestral haploid chromosome number of n = 16, Bayesian inference of n = 18. Chromosome fusion (loss) is the predominant inferred event, whereas polyploidization events occurred less frequently and mainly towards the tips of the tree.

Conclusions

The bias towards low basic numbers (x) introduced by the algebraic approach to inferring chromosome number changes, prevalent among botanists, may have contributed to an unrealistic picture of ancestral chromosome numbers in many plant clades. The availability of robust quantitative methods for reconstructing ancestral chromosome numbers on molecular phylogenetic trees (with or without branch length information), with confidence statistics, makes the calculation of x an obsolete approach, at least when applied to large clades.     

B chromosome variation in Euphydryas colon (Lepidoptera: Nymphalidae)

Cytogenetic analysis of an Idaho population of the checkerspot butterfly, Euphydryas colon, has revealed considerable inter- and intra-individual variation in chromosome number which turns out to be a classic case of B chromosome variation. The basic chromosome complement of the species is n (, )=31. The A chromosomes were aligned equatorially at mitotic metaphase and metaphase II, and axially at metaphase I, indicating a restriction of centric activity at the first meiotic division. No failure of pairing between homologous A chromosomes was observed and, although a marked asynchrony of chromatid separation was found to be characteristic of mitotic telophase and telophase II, the frequency of macrospermatid formation was low. The B chromosomes were at least partly heterochromatic but exhibited some variation in both pycnosity and size. Mitotically stable B-containing individuals showed a preponderance of unpaired Bs at first metaphase and these divided at either first or second anaphase. The presence of Bs was associated with a heightened production of abnormal spermatids particularly in individuals with high numbers of B chromosomes. Among the 25 individuals sampled, 21 carried from 1–6 B chromosomes, and of these 14 were mitotically stable. In all 7 unstable individuals the mean number of B chromosomes per cell exceeded the modal number. Assuming that the modal number represents the zygotic number, these results suggest that a mechanism to boost the number of B chromosomes exists in males of E. colon.     

A comparative chromosome study of twenty killifish species of the genus Fundulus (Teleostei: Cyprinodontidae)

Female karyotypes from ovarian cell cultures of 20 species of killifish (Fundulus) ranged in diploid number from 32 to 48, but in arm number (NF) from 48 to 52. The small F chromosomes, which constituted the fundamental elements in the karyotype, were evenly graded in length. The large biarmed chromosomes (L), which were about twice the length of the average Fs, characterized only those species with 2N less than 48 chromosomes. And among these species, an increase in complement by a pair of L's was always accompanied by a decrease of two pairs of A's, indicating Robertsonian changes by the centric fusion of two A's to form one L chromosome. Other diagnostic chromosome characters included: the number and structure of biarmed and satellited F chromosomes and the percentage of F's with relatively short short-arms (SSA). Besides centric fusion, mechanisms of chromosomal evolution in Fundulus probably included pericentric inversion, producing biarmed F chromosomes from acrocentric F's and partial loss of a chromosome segment producing smaller biarmed F chromosomes from larger ones. The percentage of SSA chromosomes generally decreases from relatively primitive to specialized species. The presumably most primitive species have only SSA type acrocentric F chromosomes. The 20 Fundulus species were classified into 2 major groups according to the percentage of SSA chromosomes: the SSA group, including 3 subgroups, had more than 50% SSA's; the LSA group, including 2 subgroups, had fewer than 50% SSA's. This classification based only on karyotypic characters generally agreed with others based on gross morphological characters. A possible evolutionary scheme is proposed to account for the derived killifish karyotypes.     

Structural mutants of the W chromosome in Ephestia (Insecta,Lepidoptera)

In a search for genetic markers of W-chromosome-autosome fusions in Ephestia, two closely linked autosomal markers, ml and Us, were found to show sex linkage in several families of chromosome mutant strains. In these families, the wild-type allelomorphs, ml ⁺ and US ⁺, label the autosome that is translocated to the W chromosome. With ml (musterlos) a sex dimorphic strain could be established in which males (ml/ml) have patternless wings and females (ml ⁺/ml) have the normal wing pattern.—Using these genetic markers, stability of the fusion chromosome was studied. Recurrence to autosomal inheritance of the marker occurs at a considerable rate. In two chromosome fusion strains, a cytogenetically detectable breakage of the fusion giving rise to a wild-type-like W chromosome was the predominant cause for the recurrence of the marker to autosomal inheritance. In a third strain a more complicated chromosome rearrangement was the predominant cause: the translocated autosome was replaced by a non-homologous one, presumably after a cytogenetically undetectable breakage event of the original fusion. — The high rate of breakage suggests that the fusion chromosomes are dicentrics, a situation not compatible with a typical holokinetic organization of Lepidoptera chromosomes.     

Genetic and cytological characterisation of fusion chromosomes of Dictyostelium discoideum

Abnormally large chromosomes which appear to result from the fusion of 2 chromosomes of the normal karyotype have been found in diploids of Dictyostelium discoideum formed by parasexual fusion of haploid strains HU483 (n=7) and HU245 (n=7). These fusion chromosomes appear to be the products of the tandem translocation of most, if not all, of one acrocentric chromosome to the telomere of a second acrocentric. Thus the chromosome number of the diploids is reduced from the normal 2n=14 to 2n=13 with the formation of an abnormally large acrocentric fusion chromosome. Experimental haploidisation of such diploids results in two types of products, those with a normal 7 chromosome karyotype and those with an abnormal 6 chromosome karyotype which contains the fusion chromosome. Genetic analysis of haploid segregants indicates that linkage groups II and VII are involved in this fusion. Phenotypes of recombinant diploids obtained following mitotic crossing-over establishes that linkage group II is proximal to linkage group VII. Cytological examination of the karyotypes of haploid strains bearing the fusion chromosome suggest that chromosome 2 may correspond to linkage group II and chromosome 3 to linkage group VII. Haploid strains bearing the fusion chromosome grow and develop normally so little or no genetic information can have been lost in the fusion event. While the nature of this event is unknown it may have involved aberrant recombinational DNA repair since the parental haploid strain HU483 bears the radB13 DNA repair mutation.     

Heteromorphic sex chromosomes of lizardfish (Synodontidae): focus on the ZZ-ZW1W2 system in Trachinocephalus myops

The karyotype and DNA content of four lizardfish species (family Synodontidae), that is, Saurida elongata, Synodus ulae, Synodus hoshinonis and Trachinocephalus myops, were analyzed. The karyotype of T. myops significantly differed from that of the other three species having diploid chromosome number of 48 with mainly acrocentric chromosomes and the ZZ-ZW sex chromosome system. The chromosome number of male T. myops was 2n=26, while that of female T. myops was 2n=27. The karyotype consisted of 11 pairs of metacentrics, one pair of acrocentrics and, in addition, two large metacentrics in the male and a single large metacentric, a distinctly small subtelocentric and a microchromosome in the female. C-banding demonstrated that in the female the subtelocentric chromosome and the microchromosome were heterochromatic. The karyotype of T. myops was thought to be derived from a 48 chromosome type synodontid fish through the involvement of Robertsonian rearrangement; the rearrangement of the sex chromosomes proceeded during karyotype evolution. Among the chromosomes, the large metacentrics were determined to be neo-Z (a fusion of the original Z and an autosome), the microchromosomes the W₁ (originally W), and the subtelocentric chromosomes the W₂ (derived from an autosome pair). The miniaturization of W₁ and W₂ chromosomes and their heterochromatinization suggested that sex chromosomes in this species have been already highly differentiated. The findings on DNA content implied that the karyotype of T. myops evolved by centric fusion events without loss in DNA amount.     

CHROMOSOME NUMBERS IN THE HYPOCREALES 1. NUCLEAR DIVISION IN THE ASCUS OF NECTRIA PEZIZA

El -Ani , Arif S. (Columbia U., New York, N. Y.) Chromosome numbers in the Hypocreales. 1. Nuclear division in the ascus of Nectria peziza. Amer. Jour. Bot. 46(6): 412–417. Illus. 1959.—The 4 nuclear divisions in the ascus of Nectria peziza were studied with the aid of acetoorcein and aceto-carmine techniques. The ascus was found to arise by crozier formation. Synapsis takes place while the chromosomes are still contracted and elongation of chromosomes continues throughout the pachytene phase. The haploid complement was found to consist of 5 chromosomes, the second of which is the nucleolus-organizing chromosome. This chromosome number which had never been reported in the Hypocreales was also found in several other species of this group of fungi. Chromosome numbers in the Hypocreales are discussed with regard to the species concept in the imperfect genus Fusarium.     

Meiosis in polyhaploid Hordeum: hemizygous ineffective control of diploid-like behaviour in a hexaploid?

Meiotic chromosome behaviour was studied in the hexaploid Hordeum parodii (2n=6x=42) and in six haploids (2n=3x=21) obtained from a cross between H. parodii and H. bulbosum (2n=2x=14) whereby all bulbosum chromosomes were selectively eliminated. The alloploid nature of H. parodii was evident from the exclusive bivalent formation at the hexaploid level and the low and variable number of bivalents in its haploid derivatives. In haploids, both nonhomologous (intragenomic) and homoeologous (intergenomic) chromosomes paired at prophase. Foldbacks in single chromosomes, bivalents and trivalents were observed at prophase and metaphase I. At diakinesis, the associations involved a maximum of 20 chromosomes which decreased to 12 by metaphase I. This decrease was attributed to the failure of the non-homologous associations to persist until metaphase I. A hemizygous-ineffective control for the diploid-like behaviour of the hexaploid parodii is proposed to explain the homeologous chromosome pairing in its haploid derivatives.     

Cytogenetic Characterization and AFLP-Based Genetic Linkage Mapping for the Butterfly Bicyclus anynana,Covering All 28 Karyotyped Chromosomes

Background

The chromosome characteristics of the butterfly Bicyclus anynana, have received little attention, despite the scientific importance of this species. This study presents the characterization of chromosomes in this species by means of cytogenetic analysis and linkage mapping.

Methodology/Principal Findings

Physical genomic features in the butterfly B. anynana were examined by karyotype analysis and construction of a linkage map. Lepidoptera possess a female heterogametic W-Z sex chromosome system. The WZ-bivalent in pachytene oocytes of B. anynana consists of an abnormally small, heterochromatic W-chromosome with the Z-chromosome wrapped around it. Accordingly, the W-body in interphase nuclei is much smaller than usual in Lepidoptera. This suggests an intermediate stage in the process of secondary loss of the W-chromosome to a ZZ/Z sex determination system. Two nucleoli are present in the pachytene stage associated with an autosome and the WZ-bivalent respectively. Chromosome counts confirmed a haploid number of n = 28. Linkage mapping had to take account of absence of crossing-over in females, and of our use of a full-sib crossing design. We developed a new method to determine and exclude the non-recombinant uninformative female inherited component in offspring. The linkage map was constructed using a novel approach that uses exclusively JOINMAP-software for Lepidoptera linkage mapping. This approach simplifies the mapping procedure, avoids over-estimation of mapping distance and increases the reliability of relative marker positions. A total of 347 AFLP markers, 9 microsatellites and one single-copy nuclear gene covered all 28 chromosomes, with a mapping distance of 1354 cM. Conserved synteny of Tpi on the Z-chromosome in Lepidoptera was confirmed for B. anynana. The results are discussed in relation to other mapping studies in Lepidoptera.

Conclusions/Significance

This study adds to the knowledge of chromosome structure and evolution of an intensively studied organism. On a broader scale it provides an insight in Lepidoptera sex chromosome evolution and it proposes a simpler and more reliable method of linkage mapping than used for Lepidoptera to date.     

Chromosome numbers in representative myxomycetes: a cytogenetic study

Myxomycetes are also called plasmodial slime molds, due to one of their characteristic features, the occurrence of the plasmodium. However, most of the distinguishing characters of the five orders currently recognised are based on the morphology of fruiting bodies and spores. Although a few myxomycetes have become widely used model organisms for genetic and cytological studies, complete information relating to the number of chromosomes in haploid cells (n) is lacking thus far. Only two species of the order Physarales have been examined with respect to chromosome numbers. Here, we present a complete data set on the numbers of chromosomes in ten species of myxomycetes that are members of all five orders. Our analysis indicates that n?=?21 is the evolutionary ancient chromosome number that occurs in the morphologically simple orders Liceales and Ceratiomyxales. More derived taxa, such as the Physarales, have significantly higher chromosome numbers (n?=?30). These data shed light on the phylogenetic relationships within the myxomycetes.     

Chromosome number variation within Philaethria butterflies (Lepidoptera: Nymphalidae,Heliconiini)

The haploid chromosome number of the South American butterfly Philaethria dido varies from 12 to 88. Eight different numbers have been found in this species complex. The related Ph. pygmalion and Ph. wernickei usually show only n=29, a very frequent number in the Lepidoptera; numbers of n=15 and n=21 for these species need confirmation. The most common chromosome number for Ph. dido is also the highest, n=88, and is found in many parts of northern and central Brazil on the Amazon river and its tributaries, as well as adjacent parts of other countries. The other numbers were observed mainly in northern South America and along the east coast. Two very different numbers were found together in four localities. We did not find specimens with meiotic features suggesting hybridization between individuals with different chromosome numbers. The diverse numbers in Ph. dido may belong to good sibling species, distinguishable externally by very minor characters. Since Ph. dido is a very primitive species in the tribe Heliconiini, dating probably from the early Tertiary, it probably has had many opportunities to undergo divergent chromosome evolution in isolation. Its strong, high flight and broad ecological valence would then permit rapid spreading out and coexistence of different chromosome forms, which in some cases have been noted to show diverse behaviour in the field.Dedicated to Professor Hans Bauer on the occasion of his eightieth birthday     

A chromosome study ofSchistocephalus solidus (Müller, 1776) (Cestoda: Pseudophyllidea)

Analysis of Giemsa-stained metaphase plates of plerocercoids ofSchistocephalus solidus revealed the mode diploid number of chromosomes for this species as 2n=18. Chromosome pairs 1, 5, 6, 8 and 9 are metacentric, pairs 2, 4 and 7 are subtelocentric, and pair 3 is subtelocentric to acrocentric. The karyotype is characterised by mean absolute chromosome length between 1.9 and 5.9 m and a total chromosome length of the haploid complement of 32 m. A comparison with other known karyotypes of related species of pseudophyllidean cestodes was made.     

Characterization of pig-mink cell hybrids: assignment of the TK1 and UMPH2 genes to pig chromosome 12

By fusion of thymidine kinase-deficient mink cells with pig leukocytes, a new type of cell hybrid was produced. It was demonstrated that pig chromosomes segregate in pig-mink hybrids and that hybrid cells contain no cytologically visible rearrangements between the chromosomes of parental species, or chromosome fragmentation. With a set of subclones of two primary hybrid clones, the genes for thymidine kinase-1 (TK1) and uridine 5-monophosphate hydrolase-2 (UMPH2) were assigned to pig Chromosome (Chr) 12. A cell line with a single pig Chr 8 on the background of mink chromosomes was established. This clone could serve as a source of DNA for building a chromosome-specific library of pig Chr 8. The data obtained suggest that pig-mink cell hybrids can be used for mapping of pig chromosomes.     

Gonoid thelytoky in soft scale insects (Coccidae: Homoptera)

Cytological analysis of the thelytokous soft-scale insects Coccus hesperidum L. (2n=14) and Saissetia coffeae (Walker) (2n=16) revealed that while in both species the chromosomes did not pair during prophase I, meiosis consisted of two divisions, the chromosome number was reduced, and diploidy was restored by the fusion of the female pronucleus with the polar nucleus II. The difficulty of trying to classify this type of thelytoky as either automictic or apomictic led to the proposal that a new criterion and new terms be used to classify thelytoky (and parthenogenesis). The new criterion is whether the number of chromosome elements present in the first (or only) metaphase of oogenesis is the same as that present in the oogonia (gonoid thelytoky) or different from it (agonoid thelytoky). The new criterion is superior to the existing criteria because it is unambiguous, and because it groups together forms with a similar tendency towards heterozygosity (or homozygosity). The possible evolution of the forms analyzed as well as the two other thelytokous forms of each species described by Thomsen (1927) are discussed. Another soft-scale insect, Physokermes hemicryphus Dalam, consisted of a diploid (2n=18) and a triploid (3n=27) form, in both of which the chromosomes also did not pair. Each of the three species contained a strain in which only a single nucleolus was present per cell. In C. hesperidum some strains with two nucleoli differed in the size of the nucleoli.     

Karyotype evolution in Tilapia: mitotic and meiotic chromosome analysis of Oreochromis karongae and O. niloticus x O. karongae hybrids

The karyotype of Oreochromis species is considered to be highly conserved, with a diploid chromosome complement of 2n = 44. Here we show, by analysis of mitotic and meiotic chromosomes, that the karyotype of O. karongae, one of the Lake Malawi chambo species, is 2n = 38. This difference in chromosome number does not prevent the production of inter-specific hybrids between O. niloticus (2n = 44) and O. karongae (2n = 38). Analysis of the meiotic chromosomes of the O. niloticus × O. karongae hybrids indicates that three separate chromosome fusion events have occurred in O. karongae. Comparison of the O. karongae and O. niloticus karyotypes suggests that these consist of one Robertsonian fusion and two fusions of a more complex nature.     

Characterisation of the double genome structure of modern sugarcane cultivars (Saccharum spp.) by molecular cytogenetics

Cultivated sugarcane clones (Saccharum spp., 2n=100 to 130) are derived from complex interspecific hybridizations between the speciesS. officinarum andS. spontaneum. Using comparative genomic DNA in situ hybridization, we demonstrated that it is possible to distinguish the chromosomes contributed by these two species in an interspecific F1 hybrid and a cultivated clone, R570. In the interspecific F1 studied, we observed n+n transmission of the parental chromosomes instead of the peculiar 2n+n transmission usually described in such crosses. Among the chromosomes of cultivar R570 (2n=107–115) about 10% were identified as originating fromS. spontaneum and about 10% were identified as recombinant chromosomes between the two speciesS. officinarum andS. spontaneum. This demonstrated for the first time the occurrence of recombination between the chromosomes of these two species. The rDNA sites were located by in situ hybridization in these two species and the cultivar R570. This supported different basic chromosome numbers and chromosome structural differences between the two species and provided a first bridge between physical and genetical mapping in sugarcane.     

A new chromosome fluorescence banding technique combining DAPI staining with image analysis in plants

In this study, a new chromosome fluorescence banding technique was developed in plants. The technique combined 4,6-diamidino-2-phenylindole (DAPI) staining with software analysis including three-dimensional imaging after deconvolution. Clear multiple and adjacent DAPI bands like G-bands were obtained by this technique in the tested species including Hordeum vulgare L., Oryza officinalis, Wall & Watt, Triticum aestivum L., Lilium brownii, Brown, and Vicia faba L. During mitotic metaphase, the numbers of bands for the haploid genomes of these species were about 185, 141, 309, 456 and 194, respectively. Reproducibility analysis demonstrated that banding patterns within a species were stable at the same mitotic stage and they could be used for identifying specific chromosomes and chromosome regions. The band number fluctuated: the earlier the mitotic stage, the greater the number of bands. The technique enables genes to be mapped onto specific band regions of the chromosomes by only one fluorescence in situ hybridisation (FISH) step with no chemical banding treatments. In this study, the 45S and 5S rDNAs of some tested species were located on specific band regions of specific chromosomes and they were all positioned at the interbands with the new technique. Because no chemical banding treatment was used, the banding patterns displayed by the technique should reflect the natural conformational features of chromatin. Thus it could be expected that this technique should be suitable for all eukaryotes and would have widespread utility in chromosomal structure analysis and physical mapping of genes.