Fluorescent heterochromatin staining in primate chromosomes

Recently, in addition to quinacrine staining, fluorochrome techniques have been developed which brilliantly stain other heterochromatic regions. Two of these staining techniques are Distamycin/DAPI (DA/DAPI) and D287/170. We stained the chromosomes of all species of great apes and 14 species of primates (48 individuals) using these three fluorochrome techniques. Only african apes and man show brilliant quinacrine staining while, man and all the great apes show brilliant DA/DAPI staining and only species belonging to the hominoidea (including the siamang) showed bright D287/170 staining. In the lower primates a medium level of DA/DAPI fluorescence was found in some species with large amount of pericentromeric heterochromatin. Brilliant DA/DAPI staining could represent a derived trait linking all great apes and humans, while D287/170 may link all hominoidea. Fluorochrome staining is believed to be correlated with some satellite DNA sequences. However, data available on the chromosome location of satellite DNAs in non-human primates were derived from buoyant density fractions resulting in cross hybridization and now are not considered reliable. Before making any correlation between fluorochrome staining and satellite DNAs in non human primates there is need of data onin situ hybridization with cloned DNA sequences on primate chromosomes. These data would help clarify the evolution and relationship of satellite DNAs and heterochromatin in primates.     

Organization of a repetitive human 1.8 kb KpnI sequence localized in the heterochromatin of chromosome 15

We have isolated a repetitive 1.8 kb Kpnl DNA sequence which is amplified in the homogeneously staining regions of a human melanoma cell line. Under low stringency conditions this sequence (D15Z1) hybridized in situ to the centromeric heterochromatin of chromosomes 1, 9, 15p, 16, and distal Yq as well as to the the short arms of the other acrocentric chromosomes. Under conditions of high stringency, labelling was predominantly on the short arm of chromosome 15. D15Z1 was shown to be present at approximately 3,000 copies per haploid genome and organized in long tandem arrays showing restriction site heterogeneity. Sequences homologous to D15Z1 were highly enriched in the less dense shoulder region of a Ag⁺—Cs₂SO₄ gradient. Analysis of D15Z1 indicated that this sequence is composed of tandemly arranged imperfect repeats of the consensus 5 AATGG 3 similar to previously identified satellite III sequences. Digestion of D15Z1 with HinfI resulted in a series of restriction fragments making up a subset of the HinfI ladder components of satellites III and IV. These data suggest that D15Z1 represents a chromosome 15 specific domain of human satellites III or IV and that it makes up the major fraction of the heterochromatin of this chromosome. Possible relationships between this sequence and the cytochemical staining properties of human chromosomes with distamycin A/DAPI, D280/170, and antiserum to 5-methylcytosine are discussed.     

Characterization of human chromosomal constitutive heterochromatin

The constitutive heterochromatin of human chromosomes is evaluated by various selective staining techniques, i.e., CBG, G-11, distamycin A plus 4,6-diamidino-2-phenylindole-2-HCl (DA/DAPI), the fluorochrome D287/170, and Giemsa staining following the treatments with restriction endonucleases AluI and HaeIII. It is suggested that the constitutive heterochromatin could be arbitrarily divided into at least seven types depending on the staining profiles expressed by different regions of C-bands. The pericentromeric C-bands of chromosomes 1, 5, 7, 9, 13-18, and 20-22 consist of more than one type of chromatin, of which chromosome 1 presents the highest degree of heterogeneity. Chromosomes 3 and 4 show relatively less consistent heterogeneous fractions in their C-bands. The C-bands of chromosomes 10, 19, and the Y do not have much heterogeneity but have characteristic patterns with other methods using restriction endonucleases. Chromosomes 2, 6, 8, 11, 12, and X have homogeneous bands stained by the CBG technique only. Among the chromosomes with smaller pericentric C-bands, chromosome 18 shows frequent heteromorphic variants for the size and position (inversions) of the AluI resistant fraction of C-band. The analysis of various types of heterochromatin with respect to specific satellite and nonsatellite DNA sequences suggest that the staining profiles are probably related to sequence diversity.     

Cytological dissection of sex chromosome heterochromatin of Drosophila hydei

Prophase chromosomes of Drosophila hydei were stained with 0.5 g/ml Hoechst 33258 and examined under a fluorescence microscope. While autosomal and X chromosome heterochromatin are homogeneously fluorescent, the entirely heterochromatic Y chromosome exhibits an extremely fine longitudinal differentiation, being subdivided into 18 different regions defined by the degree of fluorescence and the presence of constrictions. Thus high resolution Hoechst banding of prophase chromosomes provides a tool comparable to polytene chromosomes for the cytogenetic analysis of the Y chromosome of D. hydei. — D. hydei heterochromatin was further characterized by Hoechst staining of chromosomes exposed to 5-bromodeoxyuridine for one round of DNA replication. After this treatment the pericentromeric autosomal heterochromatin, the X heterochromatin and the Y chromosome exhibit numerous regions of lateral asymmetry. Moreover, while the heterochromatic short arms of the major autosomes show simple lateral asymmetry, the X and the Y heterochromatin exhibit complex patterns of contralateral asymmetry. These observations, coupled with the data on the molecular content of D. hydei heterochromatin, give some insight into the chromosomal organization of highly and moderately repetitive heterochromatic DNA.     

An early stage of ZW/ZZ sex chromosome differentiation in Poecilia sphenops var. melanistica (Poeciliidae,Cyprinodontiformes)

The mitotic and meiotic chromosomes of the American cyprinodont fish Poecilia sphenops var. melanistica were analysed. All 46 chromosomes are telocentric. By specific staining of the constitutive heterochromatin with C-banding and various AT-specific fluorochromes, the homomorphic chromosome pair 1 could be identified as sex chromosomes of the ZW/ZZ type. All female animals exhibit a W chromosome with a large region of telomeric heterochromatin that is not present in the Z chromosome. These sex chromosomes cannot be distinguished by conventional staining; they represent the first demonstration of sex chromosomes in fishes in an early stage of morphological differentiation. The W heterochromatin and the telomeric heterochromatin in the two autosomes 18 show a very bright fluorescence when stained with AT-specific fluorochromes. This allows the direct identification of the chromosomal sex by examining the interphase nuclei: females exhibit three, males only two brightly fluorescent heterochromatic chromocenters in their nuclei. The significance of these ZW/ ZZ sex chromosomes and their specific DNA sequences, the dose compensation of the Z-linked genes, and the experimental possibilities using sex-reversed ZW males are discussed.     

Characterization of constitutive heterochromatin in Cebus apella (Cebidae, Primates) and Pan troglodytes (Hominidae, Primates): comparison to human chromosomes.

Using G bands, some homologies between the chromosomes of Cebus apella (CAP) and human chromosomes are difficult to establish. To solve this problem, we analyzed these homologies by fluorescence in situ hybridization using human whole chromosome probes (ZOO-FISH). The results indicated that 1) the human probe for chromosome 2 partially hybridizes with CAP chromosomes 13 and 5, 2) the human probe for chromosome 3 partially hybridizes with CAP chromosomes 18 and 20, 3) the human probe for chromosome 9 partially hybridizes with CAP chromosome 19, and 4) the human probe for chromosome 14 hybridizes with the p-terminal and q-terminal regions of CAP chromosome 6. However, none of the human probes employed hybridized with the heterochromatic regions of CAP chromosomes. For this reason, we characterized the heterochromatic regions of CAP chromosomes and of the chromosomes of Pan troglodytes (PTR), to allow comparison between CAP, PTR, and human chromosomes using in situ digestion of fixed chromosomes with the restriction enzymes AluI, HaeIII, and RsaI and by fluorescent staining with DA/DAPI. The results show that 1) centromeric heterochromatin is heterogeneous in the three species studied and 2) noncentromeric heterochromatin is homogeneous within each of the three species, but is different for each species. Thus, centromeric heterochromatin undergoes a higher degree of variability than noncentromeric heterochromatin.     

Banding of unfixed mitotic chromosomes in suspension after release from human lymphocytes and fibroblasts

Summary Combined application during chromosome isolation of the non- or weakly fluorescent DNA-intercalators 4-aminomethyl-4,5, 8-trimethylpsoralen and daunomycin as stabilizers of mitotic chromosome structure, and the non-intercalating DNA-binding fluorochromes DAPI and D287/170 as producers of a visible banding pattern, resulted in clearly banded unfixed floating chromosomes. Chromosomes stabilized by intercalation appeared to be sufficiently stable to allow the reproduction of distamycin A/DAPI or netropsin/DAPI staining in suspension, thus highlighting specific heterochromatic regions on the floating chromosomes. The results of this study demonstrate that the inducibility of bands is an inherent characteristic of mitotic chromosome organization. Possible practical applications of these results in flow cytometry are discussed.     

Comparison of areas of quinacrine mustard fluorescence and modified Giemsa staining in human metaphase chromosomes

The methods of quinacrine mustard fluorescence and modified Giemsa staining were compared in view of the structural details revealed in human mitotic chromosomes derived from the peripheral blood of normal healthy humans. Over the chromatids both techniques produced a crossbanding pattern where larger segments of heavy staining in the latter technique and the fluorescing bands in the former occurred at similar locations. The centromeric heterochromatin, intensely stained with Giemsa was, however, negative in fluorescence, except for chromosome no. 3 and less often no. 6. The regularly occurring secondary constrictions in chromosomes 1, 9, and 16 behaved generally like areas of centromeric heterochromatin. The area of secondary constriction in the Y chromosome as also that of chromosome 9 in the ASG modification of the Giemsa technique was both non-fluorescent and non-staining.     

Counterstained enhancement of TaqI resistant sites after distamycin A/diamidinophenylindole treatment

Numerous selective and differential staining techniques have been used to investigate the hierarchical organisation of the human genome. This investigation demonstrates the unique characteristics that are produced on fixed human chromosomes when sequential procedures involving restriction endonuclease TaqI, distamycin A (DA) and 4,6-diamidino-2-phenylindole (DAPI) are employed. TaqI produces extensive gaps in the heterochromatic regions associated with satellite II and III DNAs of human chromosomes 1, 9, 15, 16 and Y. DA/DAPI selectively highlights, as brightly fluorescent C-bands, the heterochromatin associated with the alpha, beta, satellite II and III DNAs of these chromosomes. When DA and DAPI are used on chromosomes before TaqI digestion, and then stained with Giemsa, the centromeric regions appear to be more resistant, producing a distinct C-banding pattern and gaps in the heterochromatin regions. Sequential use of the DA/DAPI technique after TaqI treatment produces a bright fluorescence on the remaining pericentromeric regions of chromosomes 1, 9, 16 and Y, which also displayed a cytochemically unique banding pattern. This approach has produced specific enhanced chromosomal bands, which may serve as tools to characterize genomic heterochromatin at a fundamental level.     

Longitudinal differentiation of metaphase chromosomes of Indian muntjac as studied by restriction enzyme digestion,in situ hybridization with cloned DNA probes and distamycin A plus DAPI fluorescence staining

The longitudinal differentiation of metaphase chromosomes of the Indian muntjac was studied by digestion with restriction enzymes, in situ hybridization with cloned DNA probes and distamycin A plus DAPI (4-6-diamidino-2-phenylindole) fluorescence staining. The centromeric regions of chromosomes 3 and 3 + X of a male Indian muntjac cell line were distinct from each other and different from those of other chromosomes. Digestion with a combination of EcoRI^* and Sau3A revealed a pattern corresponding to that of C-banding. Digestion with AluI, EcoRII or RsaI yielded a band specific to the centromeric region only in chromosomes 3 and 3 + X. Furthermore, HinfI digestion yielded only a band at the centromeric region of chromosome 3, whereas DA-DAPI staining revealed a single band limited to the extreme end of the C-band heterochromatin of the short arm of 3 + X. These results suggest that centromeres of Indian muntjac chromosomes contain at least four different types of repetitive DNA. Such diversity in heterochromatin was also confirmed by in situ hybridization using specific DNA probes isolated and cloned from highly repetitive DNA families. Heterozygosity between chromosome homologs was revealed by restriction enzyme banding. Evidence is presented for the presence of nucleolus organizer regions (NORs) on the long arm of chromosome 1 as well as on the secondary constrictions of 3 and 3 + X.Abbreviations DA distamycin A - DAPI 4-6-diamidino-2-phenylindole - NOR(s) nucleolus organizer region(s) - PBS phosphate-buffered saline - PI propidium iodide     

Antibodies to defined histone epitopes reveal variations in chromatin conformation and underacetylation of centric heterochromatin in human metaphase chromosomes

Unfixed metaphase chromosome preparations from human lymphocyte cultures were immunofluorescently labelled using antibodies to defined histone epitopes. Both mouse monoclonal antibody HBC-7, raised against the N-terminal region of H2B, and rabbit serum R5/12, which recognizes H4 acetylated at Lys-12, gave non-uniform labelling patterns, whereas control antibodies against total histone fractions H4 and H1 produced homogeneous fluorescence. HBC-7 bound approximately uniformly to the bulk of the chromosomes, but the major heterochromatic domains of chromosomes 1, 9, 15, 16 and the Y showed significantly brighter fluorescence. Serum R5/12 indicated an overall reduction in acetylation of H4 in metaphase chromosomes compared with interphase nuclei, although some specific chromosomal locations had considerably elevated acetylation levels. Acetylation levels in the major heterochromatic domains appeared extremely low. To investigate further the differences noted in heterochromatin labelling, metaphases from cultures grown in the presence of various agents known to induce undercondensation of the major heterochromatic domains were similarly immunolabelled. Decondensed heterochromatin no longer exhibited higher than normal immunofluorescence levels with HBC-7. The higher resolution afforded by stretching the centromeric heterochromatin of chromosomes 1, 9 and 16 confirmed the low level of H4 acetylation in these domains. We consider the implications of these observations in relation to chromatin conformation and activity.by W.C. Earnshaw     

Characterization of heterochromatin by sequential counterstain-enhanced fluorescence in three domestic bird species: Meleagris gallopavo, Columba livia domestica, and Anser anser L

The karyotypes of three avian species--Meleagris gallopavo, Anser anser L., and Columba livia domestica--were investigated by means of counterstain-enhanced fluorescence techniques (chromomycin A3/distamycin A/DAPI followed by DAPI/actinomycin D staining). A heterochromatin characterization of macro- and microchromosomes was performed. CMA3-positive (GC-rich) regions in the turkey included the telomeres of chromosomes 1, 3, 4, and Z. In the goose, the chromosome 2 was also CMA3-bright at the telomeres. The W chromosome possessed large amounts of CMA3-bright material on the short arm in both the turkey and the goose. Two types of centromeric heterochromatin were distinguished on acro- to telocentric chromosomes 6 to 14 in the pigeon. The microchromosomal heterochromation of the turkey and goose was GC-rich but had a high degree of variation. In the pigeon, several microchromosomes possessed predominantly AT-rich heterochromatin.     

The fine structure of chickpea (Cicer arietinum L.) chromosomes as revealed by pachytene analysis

A standard pachytene karyotype of chickpea (Cicer arietinum L.) is presented for the first time. Individual pachytene chromosomes were identified and described in detail. An idiogram was prepared on the basis of chromosome length, arm ratio, and distribution of heterochromatin and euchromatin. Chickpea pachytene chromosomes belong to the differentiated type with darker staining heterochromatin proximal to and lighter staining euchromatin distal to the centromeres. Chromosomes were numbered from 1 to 8 following a descending order of length. The total length of the chromosome complement at pachytene was 335.33 , and chromosome size ranged from 58.05 to 30.53 .     

Cytogenetics of the chinese giant salamander,Andrias davidianus (Blanchard): the evolutionary significance of cryptobranchoid karyotypes

Cytogenetic aspects of the cryptobranchid salamander Andrias davidianus of western China have been studied, including chromosome number and morphology, C-band patterns, meiosis, and the chromosomal localization of ribosomal 5S RNA genes. Our data regarding chromosome number (2n=60) and general chromosome morphology largely confirm the results of Morescalchi et al. (1977). The karyotype consists of 16 pairs of macrochromosomes that decrease gradually in relative length to 14 pairs of microchromosomes. Telocentric chromosomes are a conspicuous feature of the karyotype, representing more than half the genome. Differential staining reveals that all of the chromosomes, except four pairs of microchromosomes, have C-band heterochromatin in their centromeric regions, the amount varying irrespective of chromosome size. Faint bands of interstitial and telomeric C-band heterochromatin are found in mitotic chromosomes but are not seen in meiotic preparations. In C-banded mitotic preparations from a female, one of the smallest macrochromosome pairs is heteromorphic in respect to C-band heterochromatin and centromere position. In situ hybridization of an iodinated 5S RNA probe to meiotic chromosome preparations reveals that this repeated gene is clustered near the telomeric region of chromosome 7, a medium size telocentric, a location corresponding to a band of heterochromatin. Studies of spermatocytes indicate that the process of meiosis in A. davidianus closely resembles that of more advanced salamanders, and that the microchromosomes are meiotically stable. The significance of microchromosomes and chromosome morphology in the reorganization of salamander genomes during evolution is discussed on the basis of cytogenetic data available for A. davidianus and various other primitive and advanced salamanders.     

Meiotic and synaptonemal complex studies in 45 subfertile males

Summary Somatic interphase cells from males and females with normal karyotypes and with variants of the heterochromatic regions on chromosomes 9 and Y were stained with the fluorochrome D287/170. The results showed that only 9h retained the ability to stain with D 287/170 in the interphase state, whereas 15ph and Yqh lost the specific staining pattern seen in metaphase. The number and size of the specific stained interphase bodies correlated with the ploidy of the cell population and the size of the 9h as seen in metaphase.     

Structural organization of the heterochromatic region of human chromosome 9

Giemsa-11, G-banding and Lateral Asymmetry staining techniques were used to define the substructure of the C-band heterochromatin of human chromosome 9, in a sample of 108 different chromosomes 9, from 54 individuals. In this sample, the juxtacentromeric portion of the C-band region stained positive by the G-banding technique while Giemsa-11 delineated a more distally located block. Examination of the pericentric inversions generally revealed that the entire C-band region is changed with the substructural organization left intact; i.e. the G-band is proximal, the G-11 distal to the centromere. The partial pericentric inversions were found to have larger than average amounts of G-band heterochromatin on the short arm. The G-11 staining was in its usual position on the long arm with none on the short arm. Such apparent inversions therefore may not represent true inversions. — Long heterochromatic regions frequently had a segmented appearance when stained with G-11; there was a dark G-band within the pale heterochromatic region when stained with the G-banding technique which corresponded in location to the achromatic gap produced by G-11. This extra G-band may have been derived from the juxtacentromeric G-band by processes analogous to unequal crossing over. — Simple lateral asymmetry was consistently present only in the G-band heterochromatin of those chromosomes 9 containing large blocks of G-band positive material. Examination of the portion of the C-band which would correspond to the G-11 positive material revealed no consistent patterns of asymmetry. Usually both strands were heavily stained and symmetrical but occasionally there were light areas present on one strand suggestive of compound lateral asymmetry.     

Heterochromatin is not an adequate explanation for close proximity of interphase chromosomes 1--Y, 9--Y, and 16--Y in human spermatozoa

Analysis of human spermatozoa and lymphocytes using C-banding techniques and in situ hybridization has shown a higher order packaging of the human genome. Chromosomes are not distributed entirely at random within the nucleus. In particular, chromosomes 1, 9, and 16, carrying large blocks of pericentromeric heterochromatin, and the Y chromosome, carrying heterochromatin in Yq12, are in close proximity to each other within the nucleus and are involved in somatic pairing with nonhomologous chromosomes. In order to determine whether the close proximity of these chromosomes in any way is attributable to the distribution of heterochromatin, double in situ hybridization was performed on chromosomes 1--Y, 9--Y, and 16--Y as well as on 1--X, 9--X, and 16--X-with chromosome X as the other gonosome carrying less heterochromatin-in human spermatozoa. Each pair was found to have a nonrandom spatial distribution. However, comparison of the arrangement of chromosomes 1--Y versus 1--X and 9--Y versus 9--X revealed that heterochromatin cannot be the only cause for the tendency of chromosome fusion, because only the results of the chromosome pair 1--Y/1--X could support this proposition. In conclusion, the heterochromatin effect cannot be, in itself, an adequate explanation for chromosome association, implicating as well other mechanisms.     

Localisation et signification des zones Q observées sur les chromosomes mitotiques de l'amphibien Pleurodeles waltlii Michah. après coloration par la moutarde de quinacrine

Metaphase plates from tailbuds of Pleurodeles waltlii embryos (stage 34) with or without preceding cold treatment were obtained by squashing followed by quinacrine mustard staining. In both cases, caryograms were established and sites of Q bands located. — Most of the secondary constrictions exhibit very high fluorescence. In general, it is the same for the centromeric parts, but their fluorescence is quenched very strongly by cold treatment. — The proximal part of the long arm of chromosome VII and satellites of chromosomes III and XI exhibit dull fluorescence. All these sites are compared with heterochromatin localization. The relation between banding and base composition or non-histone proteins interactions is discussed.

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Remerciements. Ce travail a été effectué dans le cadre d'un contrat D.G.B.S.T. n 73-1-1145.     

Localization of repetitive DNA in the chromosomes of <Emphasis Type="Italic">Microtus agrestis</Emphasis> by means of <Emphasis Type="Italic">in situ</Emphasis> hybridization

Heterochromatin in the European field vole, Microtus agrestis, was studied using a special staining technique and DNA/RNA in situ hybridization. The heterochromatin composed the proximal 1/4 of the short arm and the entire long arm of the X chromosome, practically the entire Y chromosome and the centromeric areas of the autosomes. By using the DNA/RNA in situ hybridization technique, repeated nucleotide sequences are shown to be in the heterochromatin of the sex chromosomes.     

5-Azacytidine-induced undercondensations in human chromosomes

Summary The cytosine analogue 5-azacytidine induces very distinct undercondensations in human chromosomes if applied to lymphocyte cultures. The number of induced undercondensations and their chromosomal localization can be varied by the 5-azacytidine dose and the treatment time. Pulverized chromosomes or undercondensations in the G-band-positive chromosome regions are produced with high doses and long treatment times. If applied in low doses during the last hours of culture, 5-azacytidine induces specific undercondensations in the heterochromatin of chromosomes 1, 9, 15, 16, and Y. Optimum conditions required for inducing the various types of undercondensation in the chromosomes were determined. Various examples of the use 5-azacytidine in the analysis of chromosome rearrangements involving heterochromatic regions are presented.