Differential staining of polytene chromosome bands in Chironomus by Giemsa banding methods

Two Giemsa banding methods (C banding and RB banding) are described which selectively stain the centromere bands of polytene salivary gland chromosomes in a number of Chironomus species. — By the C banding method the polytene chromosome appearance is changed grossly. Chromosome bands, as far as they are identifiable, are stained pale with the exception of the centromere bands and in some cases telomeres, which then are intensely stained reddish blue. — By the RB method the centromere bands are stained bright blue, whereas the remainder of the polytene bands stain red to red-violet. — Contrary to all other species examined, in Chironomus th. thummi numerous interstitial polytene chromosome bands, in addition to the centromere regions, are positively C banded and blue stained by RB banding. In the hybrid of Ch. th. thummi x Ch. th. piger only those interstitial thummi bands which are known to have a greater DNA content than their homologous piger bands are C banding positive and blue stained by the RB method whereas the homologous piger bands are C banding negative and red stained by RB banding. Ch. thummi and piger bands with an equal amount of DNA both show no C banding and stain red by RB banding. — It seems that the Giemsa banding methods used are capable of demonstrating, in addition to centromeric heterochromatin, heterochromatin in those interstitial polytene chromosome bands whose DNA content has been increased during chromosome evolution.     

The late replication banding patterns of chromosomes are highly conserved in the genera Rana,Hyla, and Bufo (Amphibia: Anura)

Late replication banding and C-banding analyses were performed on the metaphase chromosomes of six species and one subspecies of Palearctic water frogs, genus Rana. Although C-banding patterns showed interspecific or intersubspecific variation, late replication banding patterns of all 13 chromosome pairs of these species were homologous. Minor differences of banding patterns were observed only in chromosomes 2, 7 and 13. Close comparison of the late replication banding patterns with those of three non-water frog species of Rana, and one each of Hyla and Bufo, provided important information on interspecific and intergeneric variability. In the Rana species, the banding patterns of all 13 pairs were homologous except for those some regions of 8 pairs. In one species each of Hyla and Bufo that was examined, the six large chromosome pairs (Nos. 1-6) showed banding homologies. Furthermore, among the Rana, Hyla and Bufo species the four large chromosome pairs (Nos. 1-3, 5 of Rana and Hyla, and Nos. 1, 3–5 of Bufo) shared banding homologies. These results show that the large chromosomes have been highly conserved in the evolutionary history of the three genera.     

Replication banding in the chromosomes of the European eel (Anguilla anguilla)

The chromosomes of the European eel Anguilla anguilla have been analyzed with a replication banding technique from lymphocyte cultures treated with 5-BrdU. This technique allows us to identify with high resolution the individual chromosome pairs and to differentiate classes of chromatin by the order of replication. The replication banding obtained on the chromosomes of European eel can be related with the structural bands described in this species.     

Fine characterization of turbellarian chromosomes I. Giemsa and quinacrine banding in Dugesia polychroa (O. Schmidt)

Giemsa and quinacrine banding was routinely produced in metaphase spreads of the freshwater triclad Dugesia polychroa. The techniques reported here may help eliminate the problems in chromosome banding which have prevented the application of differential chromosome banding in karyological studies of this taxon. More detailed karyological and phylogenetic comparisons with other species now seems possible.     

Giemsa C-banded karyotypes and taxonomic relationships of some North AmericanAllium species and their relationship to Old World species (Liliaceae)

The somatic karyotypes of six North AmericanAllium species and the EuropeanA. scorzonerifolium have been investigated using a Giemsa C-banding technique. All species have a chromosome number of 2n = 14. InA. scorzonerifolium and the three North American speciesA. dichlamydeum, A. fibrillum andA. unifolium C-bands are restricted to two pairs of nucleolar chromosomes. Each chromosome has a band proximal to the nucleolar constriction and a positively banded satellite. InA. acuminatum, in addition to the bands associated with the nucleolar constrictions, all chromosomes also have pericentromeric bands.A. cernuum exhibits a distinctive banding style: two chromosome pairs with bands adjacent to the nucleolar constrictions and four pairs with telomeric bands on their short arms. In the karyotype ofA. geyeri neither C-bands nor nucleolar chromosomes were found.—A comparison of the banding styles together with other cytological and morphological characters of these species with old world members ofAllium reveals:A. cernuum closely resembles species within subgenusRhizirideum, whereas the other species studies exhibit many similarities with subgenusMolium. Their sectional grouping and their relationships with Old World species are discussed.     

Hoechst 33258 banding of Drosophila nasutoides metaphase chromosomes

Hoechst 33258 banding of D. nasutoides metaphase chromosomes is described and compared with Q and C bands. The C band positive regions of the euchromatic autosomes, the X and the Y fluoresce brightly, as is typical of Drosophila and other species. The fluorescence pattern of the large heterochromatic chromosome is atypical, however. Contrary to the observations on other species, the C negative bands of the large heterochromatic chromosome are brightly fluorescent with both Hoechst 33258 and quinacrine. Based on differences in the various banding patterns, four classes of heterochromatin are described in the large heterochromatic chromosome and it is suggested that each class may correspond to an AT-rich DNA satellite.     

Cold-sensitive chromosome regions and heterochromatin inCestrum (Solanaceae):C. strigillatum,C. fasciculatum,andC. elegans

Cold-induced mitotic under-condensation of certain chromosome segments is a rare phenomenon in plants. There are about 11 genera of monocotyledons and only 3 of dicotyledons, where species are known to have such cold-sensitive regions (CSRs). The molecular causes of cold-induced undercondensation are not clear, and no consistent cytochemical characteristics of CSRs are known. Recently we have presented a chromosome banding analysis on CSRs and their relation to constitutive heterochromatin inCestrum parqui (Solanaceae), a species of sect.Cestrum. The present study is concerned with a similar analysis inC. strigillatum of sect.Cestrum, and inC. fasciculatum andC. elegans of sect.Habrothamnus. Chromomycin/DAPI fluorescent double staining, sequential C-banding, and sequential silver impregnation were applied. The species differ in detail but are similar qualitatively. Four classes of heterochromatin can be discriminated. (1) CSRs, with banding properties indicating AT-rich constitutive heterochromatin. After cold-treatment CSR heterochromatin can be silver-impregnated from interphase, as chromocentres, to metaphase, as undercondensed segments. CSRs are subject to frequent heteromorphy. (2) Nucleolar organizers. Two pairs were identified in the karyotypes. Banding properties indicate GC-rich heterochromatin. The nucleolar organizing regions are less evident and their silver-reducing capability reduces during metaphase. (3) Non-nucleolar CMA-positively fluorescing bands. These are minute, polymorphic, positively C-stained, and restricted to one or a few sites in the karyotypes. (4) Indifferently fluorescing, positively C-stained bands. They occur on centromeres, some chromosome ends, and clustered over the chromosome arms. They are mostly very delicate and do not resist harsh banding treatments. — The species investigated here andC. parqui resemble each other qualitatively in heterochromatin classes (1), (2), and (3), but differ much in banding properties of class (4). Therefore, heterochromatin characteristics in the genus are not so uniform as the present results inC. strigillatum, C. fasciculatum, andC. elegans appear to show.     

Heterochromatic banding patterns in the chromosomes ofBrimeura (Liliaceae)

The two species of the genusBrimeura (Liliaceae),B. amethystina andB. fastigiata, show a strikingly disjunct geographical distribution. Both species have a bimodal chromosome complement, 2n = 28, which includes 10 large (L) and 18 small (S) chromosomes. Most of the L-chromosomes possess heterochromatic segments which show enhanced quinacrine fluorescence. The resulting banding patterns are species-specific. Two triploid plants have been found inB. fastigiata.     

Chromosome Differentiated Populations of Cruzii: Evidence for a Third Sibling Species

Anopheles cruziiis the most common species of mosquito in Southeast Brazil and a vector of human and monkey malaria. The banding pattern of the ovarian polytene chromosomes and the frequencies of paracentric inversions of individuals from two populations were studied. A new sequence of bands on the sex chromosome, defined as form C, was disclosed. In both populations where forms A (considered as standard) and C are sympatric no heterozygotes were detected. A sequence of events that could account for the observed changes in the banding sequences of the X chromosome forms was proposed. The frequencies of 22 paracentric inversions were used to assess panmixia and the results indicated the presence of two distinct genetic pools in each population. We consider these results as evidence of another sibling species in the taxon cruzii, characterized by a distinctive form of the X chromosome and provisionally designated Anopheles cruziispecies C.     

Comparative cytogenetics between the species Passiflora edulis and Passiflora cacaoensis

Passiflora edulis Sims is the most economically important species of the genus Passiflora. A new species was described recently, Passiflora cacaoensis Bernacci & Souza, which displayed morphologic characteristics very similar to P. edulis. Due to the need for delimitation of the two species, karyomorphological and banding analyses were carried out. Both species have 2n = 18, with the same karyotype formula 16 m + 2sm. There was variation between the species regarding the location of satellites and the width of chromosome pairs 2, 4 and 8. C banding revealed the presence of constitutive heterochromatin in the centromeric and telomeric regions of all chromosomes in both species. However, only in P. cacaoensis did chromosomes 3 and 9 have a large quantity of heterochromatin. Fluorochrome banding revealed CMA⁺ bands only in the satellites, but no DAPI⁺ bands. Fluorescence in situ hybridisation (FISH) showed that in P. cacaoensis the rDNA 5S probe is located in a single site in the subterminal position of the long arm of chromosome 5. However, for the rDNA 45S probe, two sites were detected in terminal positions of the long arms of chromosome 7, with a bigger and stronger signal, and of chromosome 9. According to the asymmetry index and the quantity of heterochromatin, P. cacaoensis is a more basal species than P. edulis. The cytogenetic data indicate that P. cacaoensis is closely related to P. edulis, but is a different species.     

Sex chromosome evolution in reptiles: divergence between two lizards long regarded as sister species,Lacerta vivipara andLacerta andreanskyi

Even if the common lizardLacerta vivipara and endemicLacerta andreanskyi from Moroccan Grand Atlas have the same mother species, the two species are definitely not closely related in present-day nature, whereL. vivipara stands at variance from all other lacertids in terms of cytogenetics. The use of replication banding, C-bands and R-bands has allowed for the identification of all chromosome pairs and two sex chromosomes inL. andreanskyi. Its karyotype is typical of Lacertidae. The W chromosome, characterized by late replication, is nevertheless of a type previously unknown in the family. The comparison of Z and W chromosomes by different methods of chromosome banding indicates little homology between them, if any. The replication study has shown that there is no dosage compensation for the Z chromosome in (homogametic) males. That genetic inactivation precedes chromosomal mutations in non-vivipara lacertid evolution of the odd sex chromosome is suggested.     

Chromosomes of thecercopithecus aethiops species group:C. aethiops (Linnaeus, 1758),C. cynosurus (Scopoli, 1786),C. pygerythrus (Cuvier, 1821), andC. sabaeus (Linnaeus, 1766)

The banded karyotypes of 34 monkeys of known geographic origin and belonging to the Cercopithecus aethiops group of species (C. aethiops, C. pygerythrus, C. cynosurus, C. sabaeus) show that chromosome evolution in this group is highly conservative. All species have 2n =60 chromosomes with very similar chromosome banding. However, differences were found both within and between species. A polymorphism of the NOR area of the “marked” chromosome pairs was found in all taxa (9 of 34 animals). All individuals referred to C. sabaeus,from both West Africa and the Barbados, are characterized by having highly positive G- and C- banded terminal sequences on chromosomes 7,10,12, and 14. Outgroup comparisons with other primates and a parsimony analysis suggest that these terminal bands are derived and are probably good taxonomic and phylogenetic indicators. Moreover, chromosome 18 is variable both between and within species in G banding and in short-arm length. The existence of within-species variation in karyotypes suggests that karyological comparisons must be based on adequate samples that include specimens coming from all the major geographic populations of the species concerned.     

Intraspecific polymorphism of sex chromosome heterochromatin in two species of the Anopheles gambiae complex

The Hoechst 33258 banding pattern of the mitotic chromosomes of several laboratory and natural populations of the sibling species A. gambiae and A. arabiensis has been analyzed. A clear intraspecific polymorphism of sex chromosome heterochromatin has been observed. Nevertheless in each species heterochromatic variations fall within a characteristic species-specific pattern. Moreover, while laboratory populations tend to be monomorphic for a given heterochromatic variant, natural populations exhibit a high degree of intrapopulation polymorphism. The possible role of sex chromosome heterochromatin in controlling fertility and mating behaviour of Anopheles mosquitoes is discussed.     

Banding studies on the polytene chromosomes of Rhynchosciara hollaenderi

C-, Q-, H-, and Ag-banding have been carried out on the polytene chromosomes of Rhynchosciara hollaenderi. The results of these techniques are presented and are correlated with the molecular data which exists for Rhynchosciara polytene chromosomes. By systematic organization of both banding and molecular data, we have attempted to give as complete a picture as possible of the characteristics of the differentially banding regions. This presents an organized method of approaching mechanisms of banding in terms of structural and functional aspects of the intact chromosome. Polytene chromosomes are particularly suited for this type of analysis and with them, both developmental and evolutionary changes can be conveniently utilized for additional insights into the functions of banding regions.     

Chromosome banding patterns in Lettuce species (Lactuca sect.Lactuca,Compositae)

Chromosome banding patterns obtained with C- and N- banding, and AgNO₃ staining were studied in somatic metaphase complements of fourLactuca species.L. sativa andL. serriola have almost identical chromosome morphology, andL. saligna differs only slightly from them, butL. virosa is quite distinct from the other species. A gross comparison of the banded karyotypes suggests a closer relationship ofL. saligna toL. sativa/serriola than toL. virosa. Our data agree with the results of previous crossing experiments in these species but conflict partly with recent RFLP data which indicate a closer phenetic relationship ofL. saligna toL. virosa than toL. sativa/serriola. Such a discrepancy may be explained assuming that domestication ofL. sativa/serriola resulted in an increased selection pressure on unique DNA sequences as demonstrated by the RFLP data. Differential evolution of specific heterochromatin classes (and presumably of highly repetitive DNA classes), as revealed by chromosome banding techniques was not linked to domestication. Thus the disparity in conclusions about relationship (in terms of genetic similarity) as based on the different experimental approaches reflects a non-parallel evolution of highly repetitive vs. unique DNA classes.     

Chromosome mapping of Miller-Diecker,Smith-Magenis and RARA loci in non-human primates: implications in the evolution of human chromosome 17

Molecular cytogenetics allows to verify chromosomal homologies previously hypothesised on the base of banding pattern comparison in different species. So far only the chromosome painting technique has been extensively used in studies of chromosomal evolution. This technique allows to detect only interchromosomal rearrangements. Human and Great Apes chromosomes basically differ by intrachromosomal rearrangements, in particular inversions; with chromosome painting it has just been possible to confirm the origin by fusion of human chromosome 2 and a reciprocal translocation in Gorilla, involving the homologous of chromosome 5 and 17. In order to verify intrachromosomal rearrangements in human chromosomal evolution, chromosome mapping of human loci in non-human primates is a useful approach. We mapped Miller-Diecker, Smith-Magenis and RARA loci localised on human chromosome 17, in Gorilla gorilla, Pongo pygmaeus, Macaca fascicularis and Cercopithecus aethiops. On the base of the obtained results it was possible to verify chromosomal rearrangements previously identified by banding, to achieve new informations about the controversial evolution of human chromosome 17, and to detect the occurrence of a paracentric inversion in the homologous in Cercopithecus aethiops.     

Chromosome banding in the genusPinus

The chromosomes (2n=24) ofPinus densiflora Sieb. et Zucc. andP. thunbergii Parl. collected from several localities were analyzed on their fluorescent banding patterns by sequential staining with the base specifically binding fluorochromes, CMA and DAPI. In both species, the CMA-bands were localized at the proximal and/or interstitial regions of most of the chromosomes. The CMA-banding pattern was constant among the cells in a plant and was specific to respective species with a few variations. After the CMA and DAPI stainings each chromosome was identified individually. The fluorescent banding patterns of the two species were somewhat similar, but were diferent with respect to in some characters.Pinus thunbergii had two pairs of metacentric chromosomes without CMA-band and two pairs of metacentric chromosomes with an additional thin CMA-band at the interstitial region. The 10th and 11th pairs of chromosomes of both species, which showed similarity in interstitial CMA and DAPI banding and chromosome shape, had the proximal CMA-bands inP. densiflora and DAPI-band inP. thunbergii. The interspecific F₁ hybrid between the two species could easily be identified by the fluorescent banding method.     

High-resolution chromosome banding studies in Cebus apella,Cebus albifrons,and Lagothrix lagothricha: Comparison with the human karyotype

Karyotypes of three species of South American primates (Cebus apella, Cebus albifrons, and Lagothrix lagothricha) were studied using high-resolution banding techniques, and were compared to the human karyotype. The number of homologies was very high for the three species. Some of the breakpoints implicated in chromosome rearrangements corresponded with human fragile sites. The fragile sites in human chromosomes often correspond with the localization of latent centromeres in the platyrrhines or with large heterochromatic regions that may have been lost or newly added during evolution.