The sex chromatin in five species of hamsters

The hamster species of the genus Mesocricetus, like mammals in general, display a sexual dimorphism of sex chromatin bodies. Cricetulus griseus and Cricetus cricetus do not show such nuclear sex dimorphism, probably because of the fact that the duplications in the sex chromosomes stem from translocations of autosomal segments, which resulted in the reduction of the size differences between X and Y. In the Mesocricetus species, a relatively high frequency of nuclei with two sex-chromatin bodies of different size, resulting probably from heterochromatinization of one whole X chromosome, and of half of its homologue.     

Acridine-orange differential fluorescence of fast- and slow-reassociating chromosomal DNA after in situ DNA denaturation and reassociation

A cytological technique based on heat denaturation of in situ chromosomal DNA followed by differential reassociation and staining with acridine orange was developed. Mouse nuclei and chromosomes in fixed cytological preparations show a red-orange fluorescence after thermal DNA denaturation (2–4 minutes at 100° C), and fluoresce green if denaturation is followed by a total DNA reassociation (two minutes or more at 65–66°C). — A reassociation time between a few and 60–90 seconds demonstrates the centromeric heterochromatin of chromosomes (which sometimes aggregate in the form of clusters) and the interphase chromocenters in green, the chromosomal arms fluorescing red-orange. Under the same conditions, the Y chromosome presents a pale green or yellow-green fluorescence along its chromatids, but its centromeric region fluoresces weakly. — The interpretation is suggested that the fast-reassociating chromosomal DNA (as detected by AO in centromeric heterochromatin and interphase chromocenters), represents repetitive DNA.     

Characterization of heterochromatin in Schistocerca gregaria by C- and N-banding methods

Mitotic and meiotic chromosomes of Schistocerca gregaria were C-, mild N- and strong N-banded. After C-banding, three out of eleven autosomes show, in addition to the centromeric C-bands, a second C-band. — The mild N-banding method produces a single N-band in each of only four chromosomes. With the exception of one N-band these mild N-bands correspond to the non-centromeric, second C-bands, indicating the heterochromatic character of at least three mild N-band regions. — The strong N-banding technique produces bands both at the C- and mild N-band positions and additionally a third band in one chromosome (M₈), not present after C- or mild N-banding. — The N-bands do not correspond to the nucleolus organizer regions. Because of the mechanisms of the N-banding methods, it is concluded that the centromeric heterochromatin, as well as the non-centromeric N-band regions, contain high quantities of non-histone proteins. Presumably a specific difference exists between the non-histone proteins in the centromeric and non-centromeric N-band regions because the centromeres are banded by the strong N-banding technique, but not after mild N-banding. It is concluded that the N-band regions (two exceptions) contain a heterochromatin type which has the following features in common with the -heterochromatin of Drosophila: C- as well as N-banding positive, high nonhistone protein content, repetitive and late replicating DNA. It is discussed whether the N-banded heterochromatin regions of Schistocerca contain that DNA fraction which is, like the Drosophila -heterochromatin, underreplicated in polyploid nuclei.     

Assignment of snRNA gene sequences to the large chromosomes of rat kangaroo and Chinese hamster isolated by flow cytometric sorting

Chromosomes from a rat kangaroo (Potorous tridactylus) cell line (PtK2) and from a Chinese hamster (Cricetulus griseus) cell line (CHV79) were isolated by means of fluorescence activated flow cytometric sorting. DAPI (4-6-diamino-2-phenylindole) was used as the DNA specific fluorescent dye. The karyotype of the PtK2 cells which exhibits 13 chromosomes was separated into 6, and the 22 chromosomes of the CHV79 cells were resolved into 11 fractions. DNA extracted from these chromosomal fractions was used for restriction enzyme digestion and blotting on nitrocellulose filters. The blots were challenged with gene probes corresponding to ribosomal RNA (18S and 28S) and small nuclear RNA (U1-snRNA) genes. The rRNA genes were exclusively assigned to chromosomes containing the nucleolus organizing region (in PtK2: X chromosome; in CHV79: chromosomes 4, 5, 6, and 11). — Solely the largest chromosomes in both cell lines hybridized with U1-snRNA indicating that these gene sequences are located on those chromosomes only. Further possible genetic and biochemical applications of this experimental system are discussed.     

Using chromosomal data in the phylogenetic and molecular dating framework: karyotype evolution and diversification in Nierembergia (Solanaceae) influenced by historical changes in sea level

Karyotype data within a phylogenetic framework and molecular dating were used to examine chromosome evolution in Nierembergia and to infer how geological or climatic processes have influenced in the diversification of this solanaceous genus native to South America and Mexico. Despite the numerous studies comparing karyotype features across species, including the use of molecular phylogenies, to date relatively few studies have used formal comparative methods to elucidate chromosomal evolution, especially to reconstruct the whole ancestral karyotypes. Here, we mapped on the Nierembergia phylogeny one complete set of chromosomal data obtained by conventional staining, AgNOR‐, C‐ and fluorescent chromosome banding, and fluorescent in situ hybridisation. In addition, we used a Bayesian molecular relaxed clock to estimate divergence times between species. Nierembergia showed two major divergent clades: a mountainous species group with symmetrical karyotypes, large chromosomes, only one nucleolar organising region (NOR) and without centromeric heterochromatin, and a lowland species group with asymmetrical karyotypes, small chromosomes, two chromosomes pairs with NORs and centromeric heterochromatin bands. Molecular dating on the DNA phylogeny revealed that both groups diverged during Late Miocene, when Atlantic marine ingressions, called the ‘Paranense Sea’, probably forced the ancestors of these species to find refuge in unflooded areas for about 2 Myr. This split agrees with an increased asymmetry and heterochromatin amount, and decrease in karyotype length and chromosome size. Thus, when the two Nierembergia ancestral lineages were isolated, major divergences occurred in chromosomal evolution, and then each lineage underwent speciation separately, with relatively minor changes in chromosomal characteristics.     

Kinetochores of grasshoppers with Robertsonian chromosome fusions

The pachytene karyotypes of three grasshopper species with 2 and 3 Robertsonian fusions were constructed from electron micrographs of serially sectioned spermatocyte nuclei. Tracings of the synaptonemal complexes permitted identification of each bivalent and its centromeric region. Chromosomes with the centromere in a terminal position have a knob of centric heterochromatin on the synaptonemal complex where it ends at the nuclear envelope. In Chorthippus and in Chloealtis the submetacentric Robertsonian fusion chromosomes each have a single centric knob in the appropriate place. In Neopodismopsis each of the 2 submetacentric chromosomes have a centric knob which is double in size and structure. In spermatogonial metaphases the submetacentric chromosomes of Neopodismopsis have 70–80 microtubules per kinetochore while the telocentric chromosomes have 30–40 tubules per kinetochore. These observations are correlated with evidence from light microscopy that Robertsonian fusions may produce mono- or dicentric chromosomes.     

Chromosome preparations from hepatocytes and bone marrow of Chinese hamsters: A direct method

This report describes a method for the direct preparation of chromosomes from the hepatocytes and bone marrow of the same Chinese hamster (Cricetulus griseus). The technique is a modification of that described by Becker et al. (J. natl. Ca. Inst. 46: 1261–69, 1971) for rat hepatocytes, with the following significant differences: (1) a less extensive partial hepatectomy is employed to initiate hepatocyte regeneration, (2) the use of a larger initial dose of colchicine (4 mg/K) 46–48 hours after hepatectomy instead of 1 mg/K 24 hours after hepatectomy, (3) the use of 0.075 M KCl as hypotonic solution instead of fetal calf serum diluted 1 : 7 with distilled water and (4) flame or blaze drying of chromosome preparations instead of air drying. The combination of the above modifications gave abundant, clear and well-spread chromosomes.     

Eight new polymorphic microsatellite loci for genetic analyses in the endangered common hamster (Cricetus cricetus L.)

We developed primers for eight polymorphic microsatellite loci in the endangered common hamster (Cricetus cricetus L.). Population genetic parameters were analysed on the basis of 70 adult individuals captured from a single population. Allele numbers per locus ranged from eight to 17. Expected and observed heterozygosities per locus ranged from 0.67 to 0.91 and from 0.41 to 0.8, respectively.     

Cytogenetics of the European plethodontid salamanders of the genus Hydromantes (Amphibia,Urodela)

A karyological analysis was carried out on different European species of the genus Hydromantes (Plethodontidae). All the species examined share the same chromosome number (2n=28) and, with the exception represented by pair XIV, morphologically similar karyotypes. While the karyotypes display a similar distribution — mainly centromeric and pericentric — of C-heterochromatin, quantitative variations in pericentric heterochromatin are observed among species. In the continental species Hydromantes italicus and ambrosii as well as in the eastern Sardinian species imperialis, flavus and specie nova, pair XIV consists of heteromorphic sex chromosomes of the XX/XY type. It is proposed that the differentiation of the Y might have taken place through the occurrence of a structural rearrangement, such as a pericentric inversion, starting from a hypothetical, homomorphic pair XIV. A sex-related heteromorphism is not found in the western Sardinian species H. genei. A further karyological differentiation among these species concerns the position of the nucleolus organizing region (NOR), which is located on chromosome XII (H. italicus and ambrosii) or on chromosome X, close to the centromere (H. genei, H. imperialis and H. specie nova), or in an intercalary position (H. flavus). The location and the number of the 5 S DNA sites have been conserved during species divergence. On the basis of these karyological data, as well as of results obtained through a preliminary restriction enzyme analysis of the ribosomal and genomic DNAs, the phyletic relationships among the European Hydromantes species are discussed.     

Constitutive heterochromatin variation in two species of rattus with apparently similar karyotypes

Rattus blanfordi and R. cutchicus medius both have a chromosome complement of 2n=36 and all chromosomes except the submetacentric Y of R. blanfordi are acrocentric. The apparently similar karyotypes of the two species, however, show variations in the nature and quantity of C-band-positive constitutive heterochromatin (C-heterochromatin) as revealed by C- and G-banding and Hoechst 33258 fluorescence. R. blanfordi with large-sized X and Y chromosomes and conspicuously larger centromeric heterochromatin in all the autosomes as compared to that of R. cutchicus medius has much more C-heterochromatin in its genome than the latter. The variation in the quantity of C-heterochromatin has been accomplished without altering the morphology of the acrocentric chromosomes unlike other mammals in which variations have been reported to result generally in the addition or deletion of a totally heterochromatic second arm.     

Heterochromatin and disproportionate chromosome replication in Anatopynia dyari (Diptera: Chironomidae)

Salivary gland chromosomes from four populations of Anatopynia dyari were examined together with mitotio and meiotic chromosomes from one of the sites. Both mitotic and meiotic cells possess large blocks of heterochromatin, some of which fluoresce brightly after quinacrine staining. Mitotic figures show twelve chromosomes consisting of a graded size series with 5 meta- and submetacentric pairs and one small telocentric pair. — Salivary gland chromosomes have a loose chromocentre and three distinct size classes of chromosomes. The size classes include 1 long metacentric, 4 medium acrocentrics and 1 very small telocentric which is also twice the thickness of the rest of the complement. Quinacrine staining produces bright fluorescence of the centromeric third of chromosome VI, some ectopically paired regions of the chromocentre, basal bands and the telomeres of some chromosomes. — The discrepancy between arm ratios and relative lengths of mitotic and polytene chromosomes is explained by under-replication of nonfluorescing heterochromatin in the latter case. Brightly fluorescing heterochromatin behaves in an anomalous manner suggesting that it is either over, or else not severely under-replicated in salivary glands. The extra thickness of chromosome VI also suggests that it undergoes an extra round of replication. — A common complex rearrangement was found in the long arm of chromosome III in three of the populations. In the one population tested it was in Hardy Weinberg equilibrium.     

Satellite DNA associated with heterochromatin in Rhynchosciara

The DNA of Rhynchosciara hollaenderi was examined using isopycnic centrifugation in neutral CsCl. Two low density minor bands (collectively termed satellite DNA) were detected in addition to the main band DNA. Main band DNA has a buoyant density of 1.695 g/cm³. The larger of the two minor bands has a buoyant density of 1.680 g/cm³ while the smaller of the two minor bands has a buoyant density of about 1.675 g/cm³. Thermal denaturation studies have confirmed the presence of the two minor classes of DNA.—The satellite and main band DNAs were isolated in relatively pure form and were transcribed in vitro using DNA-dependent RNA polymerase from Escherichia coli. Annealing of the two complementary RNAs (cRNAs) with main band and satellite DNA was examined using filter hybridization techniques.—The chromosomal distribution of the satellite DNA was determined by in situ molecular hybridization of satellite-cRNA with Rhynchosciara salivary gland chromosomes. Satellite-cRNA hybridized with the centromeric heterochromatin of each of the four chromosomes (A, B, C, and X) and with certain densely staining bands in the telomere regions of the A and C chromosomes. Main band-cRNA annealed with many loci scattered throughout the chromosomes including areas containing satellite DNA.     

Heterochromatin and nucleolus-organizer-region behaviour at male pachytene of Sus scrofa domestica

In the domestic pig (2n=38) two types of constitutive heterochromatin can be differentiated by fluorescence counterstaining techniques. All 24 biarmed autosomes and the X chromosome have chromomycin A₃-positive centromeric C-bands, whereas all 12 acrocentric chromosomes exhibit DA-DAPI-positive centromeric heterochromatin. Fluorescence analysis of male pachytene nuclei revealed that the DA-DAPI-positive C-bands form one or two large chromocentres per cell, while the chromomycin A₃-bright C-material is well scattered. Hence, the bivalents formed by the acrocentric chromosome pairs are centromerically associated, whilst the submetacentric bivalents are not. —Counce-Meyer spreading techniques were used to study the structure of synaptonemal complexes (SCs) both by light and electron microscopy. In general, the SCs of the domestic pig resemble those described for other mammals. The SC formed by the X and the Y may include up to 94.5% of the Y chromosome. In silver-stained microspreads each of the bivalents (nos. 8 and 10) bearing the nucleolus-organizer-regions (NORs) is connected to a pair of nucleoli, indicating that all four NORs are active during early meiotic stages. By contrast, in the majority of mitotic metaphases of phytohaemagglutinin-stimulated lymphocytes only one pair (no. 10) exhibited Ag-NOR staining. — The significance of the chromosome disposition in the pachytene nucleus is discussed with regard to heterochromatin composition and karyotype evolution.This paper is dedicated to Prof. Hans Bauer on the occasion of his 80th birthday     

Localization of Drosophila nasutoides satellite DNAs in metaphase chromosomes

Metaphase chromosomes of D. nasutoides were hybridized situ with ³H-cRNA synthesized from the four satellites which make up 50–60% of the total DNA of this species. All four satellites were localized in the large, metacentric, heterochromatic chromosome four. They did not, however, appear to hybridize to centromeric or other constitutive heterochromatin, nor did they, with the exception of satellite I, seem to hybridize in the specific regions of chromosome four which, on the basis of C, Q, and H banding and AT contents, were predicted to contain some of these satellites. —Comparison of grain patterns with the results of fluorescent staining indicated that satellite-bearing heterochromatin was not always associated with other fractions of constitutive heterochromatin in interphase nuclei and was, at least partially, decondensed in some larger nuclei.     

Arrangement of centromeres in mouse cells

Applying a staining procedure which reveals constitutive heterochromatin to cytological preparations of the mouse (Mus musculus), one detects heterochromatin pieces at the centromeric areas of all chromosomes except the Y. The Y chromosome is somewhat heteropyenotic in general but possesses no intensely stained centromeric heterochromatin. The arrangement of the centromeric heterochromatin in interphase cells is apparently specific for a given cell type. In meiotic prophase, centromeric heterochromatin may form clusters among bivalents. From the location of the centromeric heterochromatin of the X chromosome in the sex bivalent, it is concluded that the association between the X and Y (common end) in meiosis is limited to the distal portions of the sex elements.     

Observations on centromeric heterochromatin and satellite DNA in salamanders of the genus Plethodon

DNA from Plethodon cinereus cinereus separates into two fractions on centrifugation to equilibrium in neutral CsCl. The smaller of these fractions has been described as a high-density satellite. It represents about 2% of nuclear DNA from this species, and it has a density of 1.728 g/cm³. It is cytologically localized near the centromeres of all 14 chromosomes of the haploid set. In P. c. cinereus the heavy satellite DNA constitutes about 1/4 of the DNA in centromeric heterochromatin. The nature of the rest of the DNA in centromeric heterochromatin is unknown. The number of heavy satellite sequences clustered around the centromeres in a chromosome from P. c. cinereus is roughly proportional to the size of the chromosome, as determined by in situ hybridization with satellite-complementary RNA, and autoradiography. Likewise the amount of contromeric heterochromatin, as identified by its differential stainability with Giemsa, shows a clear relationship to chromosome size. — The heavy satellite sequences identified in DNA from P. c. cinereus are also present in smaller amounts in other closely related forms of Plethodon. Plethodon cinereus polycentratus and P. richmondi have approximately half as many of these sequences per haploid genome as P. c. cinereus. P. hoffmani and P. nettingi shenandoah have about 1/3 as many of these sequences as P. c. cinereus. P. c. cinereus, P. c. polycentratus, and P. richmondii all have detectable heavy satellites with densities of 1.728 g/cm³. Among these forms, satellite size as determined by optical density measurements, and number of satellite sequences as determined from hybridization studies, vary co-ordinately. P. c. cinereus heavy satellite sequences are not detectable in P. nettingi, P. n. hubrichti, or P. dorsalis. The latter species has a heavy satellite with a density of 1.718 g/cm³, representing about 8% of the genomic DNA, and two light satellites whose properties have not been investigated. The heavy satellite of P. dorsalis is cytologically localized in the centromeric heterochromatin of this species. — These observations are discussed in relation to the function and evolution of highly repetitive DNA sequences in the centromeric heterochromatin of salamanders and other organisms.     

Banding patterns in newt chromosomes by the giemsa stain

Specific banding patterns can be produced on the mitotic chromosomes of the newt species Triturus vulgaris meridionalis and T. italicus by using the Giemsa stain technique. These bands are most useful cytogenetic markers in karyotyping, since they facilitate identification of the individual elements of the complements. Evaluation of the shape of chromosomes as well as of the banding patterns produced by the Giemsa stain indicates that the karyotypes of T. vulgaris meridionalis and T. italicus are differentiated: hence the specific distinction of the two Salamandrids, still debated by taxonomists, appears supported by chromosome evidence. — Most of the bands seem to correspond to the heterochromatic tracts observable on mitotic chromosomes from embryos and larvae either untreated or submitted to cold treatment. Besides, the comparison of mitotic karyotypes and lampbrush maps shows that the bands located near the centromeric regions of mitotic chromosomes probably correspond to the so-called bars visible on either side of centromeres of lampbrush chromosomes, while some of the subterminal bands may correspond to the sphere.This work was financially supported by C. N. R., Roma.     

Karyotypanalyse an Hand des Färbungsmusters der Metaphasechromosomen von Cypripedium debile und Trillium kamtschaticum

The somatic metaphase chromosomes of Cypripedium debile and Trillium kamtschaticum are stained differentially by treatment with an acetic orcein-hydrochloric acid mixture: In Cypripedium, the heterochromatic segments stain densely whereas the euchromatic segments are unstained. In Trillium, in contrast, the heterochromatic segments are unstained and euchromatin is stained. Such an inconsistency in stain patterns is considered to stem from different species-specific reactivity of heterochromatin and euchromatin to hydrochloric acid in the staining medium.—In metaphase chromosomes of Cypripedium stained with fast green (Alfert and Geschwind, 1953), the euchromatic segments are stained positively, whereas the heterochromatin, as well as the chromocenters, are unstained. In Trillium, all heterochromatin, euchromatin and chromocenter are stained homogeneously by this method. These results indicate that the heterochromatic segments and chromocenters in Cypripedium are associated with non-histon type proteins, whereas the euchromatic segments in Cypripedium, as well as two different types of the segments and the chromocenters in Trillium, are all bound to histon type proteins. — From these findings, it is concluded that two types of heterochromatin occur in plant materials, though it remains unsettled whether they correspond to - and -heterochromatin as found in Dipteran giant chromosomes.—Karyotype analysis is made on the basis of the differential staining pattern of chromosomes revealed by means of acetic orcein-hydrochloric procedure.     

GIEMSA C-BANDED KARYOTYPES OF SEVEN NORTH AMERICAN SPECIES OF ALLIUM

The karyotypes of seven North American Allium species were studied by Giemsa C-banding technique. Two species (A. shoenoprasum and A. tricoccum) were diploids with 2n = 16 chromosomes. Three species (A. cernuum, A. douglasii and A. geyeri) were also diploids but with 2n = 14 chromsomes. Diploid and tetraploid populations of A. textile (2n = 14, 28) were studied. The population of A. canadense studied here was a tetraploid (2n = 28). All these North American species, except A. geyeri, possessed centromeric bands in all their chromosomes and nucleolar constriction bands in their satellited chromosomes. Allium shoenoprasum contained telomeric bands in most of its chromosomes but the other species had them only in a small number of chromsomes. Only three species (A. shoenoprasum, A. textile and A. tricoccum) were found to have intercalary bands in some chromosomes. The heterochromatin distribution in B chromosomes of three species was also observed. In A. cernuum, the heterochromatin occupied most of the length of all its Bs, but in A. shoenoprasum, heterochromatin was concentrated in the centromeric region. One population of A. textile (CC1179) was found to have a B chromosome in which very little heterochromatin existed.     

Reciprocal chromosome painting between three laboratory rodent species

The laboratory mouse (Mus musculus, 2n = 40), the Chinese hamster (Cricetulus griseus, 2n = 22), and the golden (Syrian) hamster (Mesocricetus auratus, 2n = 44) are common laboratory animals, extensively used in biomedical research. In contrast with the mouse genome, which was sequenced and well characterized, the hamster species has been set aside. We constructed a chromosome paint set for the golden hamster, which for the first time allowed us to perform multidirectional chromosome painting between the golden hamster and the mouse and between the two species of hamster. From these data we constructed a detailed comparative chromosome map of the laboratory mouse and the two hamster species. The golden hamster painting probes revealed 25 autosomal segments in the Chinese hamster and 43 in the mouse. Using the Chinese hamster probes, 23 conserved segments were found in the golden hamster karyotype. The mouse probes revealed 42 conserved autosomal segments in the golden hamster karyotype. The two largest chromosomes of the Chinese hamster (1 and 2) are homologous to seven and five chromosomes of the golden hamster, respectively. The golden hamster karyotype can be transformed into the Chinese hamster karyotype by 15 fusions and 3 fissions. Previous reconstructions of the ancestral murid karyotype proposed diploid numbers from 2n = 52 to 2n = 54. By integrating the new multidirectional chromosome painting data presented here with previous comparative genomics data, we can propose that syntenies to mouse Chrs 6 and 16 were both present and to hypothesize a diploid number of 2n = 48 for the ancestral Murinae/Cricetinae karyotype.