Preferential fluorescent staining of heterochromatic regions in human chromosomes 9, 15, and the Y by D 287/170

Summary The utility of a newly synthesized chemical variation of DAPI (4-6-diamidino-2-phenyl-indole), D 287/170, for differential staining of constitutive heterochromatin in man is demonstrated. Direct staining of human chromosomes with D 287/170 results in brilliant fluorescence of the paracentromeric C-band of chromosome 9, of a proximal short-arm segment of chromosome 15 and of certain heterochromatic regions in the Y. Bright, but less conspicuous fluorescence is occassionally seen at the centromeres of other chromosomes. The staining differentiation obtained by D 287/170 is very distinct, and the intensity of the fluorescent light is unusually high. The new fluorochrome should prove particularly useful for detecting and analyzing human chromosome 9 heterochromatin at various stages of the cell cycle in normal and structurally altered chromosomes.     

Proteomic comparison between interphase and metaphase of isolated chloroplasts of Cyanidioschyzon merolae (Cyanidiophyceae,Rhodophyta)

With the completion of the Cyanidioschyzon merolae genome project, detailed analysis of organelle proteins with mass spectrometry has now become possible. Chloroplasts of the unicellular red alga Cyanidioschyzon merolae De Luca, Taddei et Varano (Rhodophyta, Cyanidiophyceae) were isolated from synchronized culture and the chloroplast lysates of both interphase and metaphase cells were prepared and subjected to 2D‐polyacrylamide gel electrophoresis. A total of 355 spots (170 identical spots) were recognized and quantified and then analyzed using mass spectrometry. A total of 105 proteins were identified, including 18 proteins for posttranslational functions, 17 photosynthesis‐related proteins, 10 carbohydrate‐related proteins, 15 proteins of unknown functions, and eight proteins predicted to be contaminated from other organelles. On the basis of spot quantity, photosynthesis‐related proteins were most dominant (45.3% in interphase and 56.4% in metaphase). In particular, the proteins forming phycobilisomal complexes were abundant. Comparison of interphase with metaphase revealed that CMG086C (aminomethyltransferase) notably increased in interphase. CMN235C (similar to chlorophyll a/b‐binding protein, CP24) increased in metaphase in agreement with a previously performed microarray analysis. Both CMQ295C (cell division protein FtsH) and CMS004C (plastid division protein FtsZ) increased in interphase. Seven proteins were detected to be interphase‐specific, and 12 proteins were metaphase‐specific. Proteins of unknown functions were poorly characterized by homology search, although thioredoxin‐like domains were predicted in several proteins.     

Heterochromatin in the chromosomes of the gorilla: characterization with distamycin A/DAPI, D287/170, chromomycin A3, quinacrine, and 5-azacytidine

The chromosomes of the gorilla were extensively studied with various staining techniques labeling the different classes of heterochromatin. The chromosomal distribution of distamycin A/DAPI-, D287/170-, quinacrine-, and chromomycin A3-positive heterochromatic regions, as well as the nucleolus organizer regions, is described and compared with the karyotypes of other hominoid species. Lymphocyte cultures were treated with low doses of 5-azacytidine during the last hours of culture. This cytidine analog induces distinct undercondensation in 37 heterochromatic regions in the 24 gorilla chromosomes. The 5-azacytidine-induced undercondensations are localized not only in most of the distamycin A/DAPI-bright heterochromatic regions but also in many telomeric C-bands of the chromosomes. Furthermore, 5-azacytidine preserves the somatic pairing between heterochromatic regions from the interphase nuclei into the metaphase stage. The homeologies and differences in the chromosomal localization of the various classes of heterochromatin, 5-azacytidine-sensitive regions, 5-methylcytosine-rich DNA sequences, and satellite DNAs in the gorilla, chimpanzee, orangutan, and man are discussed.     

Behaviour of nucleolus during mitosis

The aim of the present work was to study the distribution and the behaviour of the silver-staining nucleolar organizer region (Ag-NOR) proteins at the ultrastructural level during interphase and mitosis in five human and murine cancerous cell lines each characterized by a typical nucleolar morphology. During interphase the Ag-NOR proteins are restricted to the fibrillar centres (F.C.) and/or to the dense fibrillar component (D.F.C.). During prophase the silver-staining components come into close contact with some chromosomes and are arranged with a typical polarity: chromosome, F.C. and D.F.C. Then F.C. and D.F.C. together form roundish silver-stained structures and integrate in part within indentations at the periphery of the metaphase chromosomes. During anaphase and telophase large and small spherical silver-staining structures may be seen. They correspond respectively to the metaphase NORs and to numerous structures which appear de novo within ribonucleoprotein (RNP) material localized between the chromosomes. During late telophase the number of the small silver-staining structures decreases whereas the size of the larger ones increases. Then the interphase nucleoli recover their typical shape. These results suggest that when rRNA synthesis is impaired during mitosis the inactive NORs assume a structure and a localization which are not typical of the cell line. In contrast the F.C. and D.F.C. are probably two aspects of the NORs whose typical distribution, relative to the other nucleolar components, gives the interphasic nucleolus its characteristic morphology.     

Effects of Hoechst 33258 on condensation patterns of hetero- and euchromatin in mitotic and interphase nuclei of Drosophila nasuta

Embryonic and third instar larval brain cells of D. nasuta were cultured in vitro in the presence of Hoechst 33258 (H) and H + 5-bromodeoxyuridine (BUdR) for periods varying from 2 to 24 h at 24 °C. Air-dried chromosome preparations were made with and without hypotonic pretreatment and stained with Giemsa. Metaphase chromosomes from H-treated (2 h) embryonic preparations show typical inhibition of condensation of the A-T-rich heterochromatin as in mouse. Presence of BUdR with H causes inhibition of condensation in fewer embryonic metaphase cells, but in the affected metaphases the degree of inhibition is more severe. In larval brains, however, even a 24 h H or H + BUdR treatment does not cause any significant inhibition of heterochromatin condensation. It is suggested that the differences in H effect on metaphase chromosomes of embryos and larval brains is related to differences in chromosome organization in the two cell types. Exposure of H-treated embryonic as well as larval brain cells to a hypotonic salt solution prior to fixation causes a ‘supercondensation’ of the heterochromatic chromocentre in most interphase nuclei. Presence of BUdR along with H reduces the frequency of cells showing such ‘supercondensed’ chromocentre. The euchromatin region in H-treated interphase nuclei is, on the other hand, slightly more diffuse than in control nuclei. Apparently, H-binding to DNA affects the nucleoprotein organization in hetero- and euchromatic regions of interphase nuclei in specific ways.     

Visualization of centriole-bodies using silver stain

Duplicate staining of human metaphase chromosomes, first with Giemsa followed by silver, revealed the presence of two small silver-stained bodies not seen in the Giemsa stained metaphases. Similar bodies were subsequently found in the metaphases of several animal groups. The size, structure, spatial relationships to the nucleus, behavior throughout the cell cycle, and apparent universal presence of these bodies suggest that they are either centrioles or associated centriolar structures. These centriole-bodies can be seen throughout the cell cycle, even in hypotonically spread C-metaphase chromosome plates. The silver stain procedure allows enough resolution to distinguish parent and daughter centriole-bodies at interphase, thus permitting visualization of the replication, maturation and separation stages of these bodies with the light microscope.     

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.     

Rapid metaphase and interphase detection of radiation-induced chromosome aberrations in human lymphocytes by chromosomal suppression in situ hybridization

Chromosomal in situ suppression (CISS)-hybridization of biotinylated phage DNA-library inserts from sorted human chromosomes was used to decorate chromosomes 1 and 7 specifically from pter to qter and to detect structural aberrations of these chromosomes in irradiated human peripheral lymphocytes. In addition, probe pUC1.77 was used to mark the 1q12 subregion in normal and aberrant chromosomes 1. Low LET radiation (60Co-gamma-rays; 1.17 and 1.33 MeV) of lymphocyte cultures was performed with various doses (D = 0, 2, 4, 8 Gy) 5 h after stimulation with phytohaemagglutinin. Irradiated cells were cultivated for an additional 67 h before Colcemid arrested metaphase spreads were obtained. Aberrations of the specifically stained chromosomes, such as deletions, dicentrics, and rings, were readily scored after in situ hybridization with either the 1q12 specific probe or DNA-library inserts. By the latter approach, translocations of the specifically stained chromosomes could also be reliably assessed. A linear increase of the percentage of specifically stained aberrant chromosomes was observed when plotted as a function of the square of the dose D. A particular advantage of this new approach is provided by the possibility to delineate numerical and structural chromosome aberrations directly in interphase nuclei. These results indicate that cytogenetic monitoring of ionizing radiation may be considerably facilitated by CISS-hybridization.     

Induction of diplochromosomes in mammalian cells by inhibitors of topoisomerase II

Diplochromosomes, consisting of four chromatids lying side-by-side, instead of the normal two, are produced when cells go through two rounds of DNA replication without separation of chromatids. They are thus an indication of the failure of the normal chromosome separation mechanism. In the present experiments, induction of diplochromosomes by inhibitors of topoisomerase II (Topo II) was used to provide further evidence that Topo II is required for separation of daughter chromosomes. Actively growing cultures of CHO cells were treated with Colcemid, and separated into metaphase and interphase fractions, each of which was treated for 2 h with the Topo II inhibitor being tested. The cells were then cultivated in fresh medium without inhibitor for periods of between 18 and 44 h, and metaphase cells once again accumulated by treatment with Colcemid. Chromosome preparations were made in the standard way and stained with Giemsa. Up to 2,000 metaphases were counted from each culture, and the proportion with diplochromosomes calculated. At appropriate concentrations, the Topo II inhibitors etoposide and mitoxantrone induced substantial levels of metaphases with diplochromosomes in cultures that had been treated when the cells were in interphase (up to 30% and 11%, respectively). Amsacrine, however, only produced a smaller proportion (4.7%) of metaphases with diplochromosomes after a much longer culture period following treatment. All the inhibitors caused severe chromosome damage. When used to treat metaphase cells, mitoxantrone and amsacrine only induced diplochromosomes after prolonged culture, although a small number of diplochromosomes were seen after etoposide treatment and a shorter period of culture. Results with cells treated in metaphase might indicate that Topo II is, in fact, not required for anaphase chromosome separation, although it is clearly important for segregation of newly replicated DNA. Received: 8 August 1998 / Accepted: 13 September 1998     

ADP-ribosylation in permeable HeLa S3 cells

ADP-ribosylation in permeabilized metaphase and interphase cells using [32P]NAD at pH 8.0 have been compared. Incorporation into trichloroacetic acid insoluble material was 4-5-times greater in metaphase cells. 17-22% was in the soluble fraction which contained material released from the cells, 16-22% in the 0.2 M HCl extract (histones) of the cell ghosts and the remaining activity in the residual fraction. Fractions were analyzed using dodecylsulphate/polyacrylamide gel electrophoresis at pH 6.0. The soluble fractions from metaphase and interphase cells exhibited three common unidentified ADP-ribosylated proteins corresponding to 78 000, 54 000 and 36 000 Da. In addition metaphase cells contained several other ADP-ribosylated proteins not present in interphase cells. The 0.2 M HCl extracts gave from metaphase cells radioactivity in the 32 000-39 000-Da region suggesting ADP-ribosylation of histone H1 with up to 10 residues of ADP-ribose and in the 17 000-20 000-Da region indicating ADP-ribosylation of core histones. The pattern of ADP-ribosylation of core histone in metaphase and interphase cells was qualitatively similar whereas the number of ADP-ribose residues per H1 molecule was higher in metaphase cells. The residual fraction contained free poly(ADP-ribose) and oligo(ADP-ribose). The results do not lend support to a special function of ADP-ribosylated histones in the mitotic event while certain ADP-ribosylated non-histone proteins may be specific for metaphase cells.     

Chromosomal in situ suppression hybridization of human gonosomes and autosomes and its use in clinical cytogenetics

Summary DNA libraries from sorted human gonosomes were used selectively to stain the X and Y chromosomes in normal and aberrant cultured human cells by chromosomal in situ suppression (CISS-) hybridization. The entire X chromosome was stained in metaphase spreads. Interphase chromosome domains of both the active and inactive X were clearly delineated. CISS-hybridization of the Y chromosome resulted in the specific decoration of the euchromatic part (Ypter-q11), whereas the heterochromatic part (Yq12) remained unlabeled. The stained part of the Y chromosome formed a compact domain in interphase nuclei. This approach was applied to amniotic fluid cells containing a ring chromosome of unknown origin (47,XY; +r). The ring chromosome was not stained by library probes from the gonosomes, thereby suggesting its autosomal origin. The sensitivity of CISS-hybridization was demonstrated by the detection of small translocations and fragments in human lymphocyte metaphase spreads after irradiation with ⁶⁰Co-gamma-rays. Lymphocyte cultures from two XX-males were investigated by CISS-hybridization with Y-library probes. In both cases, metaphase spreads demonstrated a translocation of Yp-material to the short arm of an X chromosome. The translocated Y-material could also be demonstrated directly in interphase nuclei. CISS-hybridization of autosomes 7 and 13 was used for prenatal diagnosis in a case with a known balanced translocation t(7;13) in the father. The same translocation was observed in amniotic fluid cells from the fetus. Specific staining of the chromosomes involved in such translocations will be particularly important, in the future, in cases that cannot be solved reliably by conventional chromosome banding alone.Dedicated to Professor Friedrich Vogel on the occasion of his 65th birthday     

Conservation of interphase chromatin nonhistone antigens as components of metaphase chromosomes

The degree of conservation of HeLa interphase chromatin nonhistone antigens among the nonhistones of isolated metaphase chromosomes was determined with immunological procedures. Proteins were separated on SDS-polyacrylamide gels and electrophoretically transferred to diazophenylthioether (DPT)-paper, which was then overlaid with antiserum to chromatin from interphase nuclei. The bound antibodies were detected with 125I-labeled protein A. Alternatively, polyacrylamide gels were directly overlaid with antiserum and with 125I-protein A. Densitometry of autoradiograms and stained gels revealed the degree of conservation of nonhistone antigenic determinants from interphase to metaphase to be over 90% for chromatin.     

Heterochromatin differentiation in Trillium kamtschaticum by ammoniacal silver reaction

The ammoniacal silver reaction for histones was applied to Trillium kamtschaticum chromosomes. In the brown-stained metaphase chromosome complement, the specific regions of the specific chromosome pairs, which were previously registered as Giemsa-positive and non-heterochromatic regions, were differentiated as prominently black segments. In interphase nucleus these black segments formed the black-stained chromocenters, distinct from other chromocenters which were stained brown.     

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.     

Photodynamic effects of Photofrin II on cell division in human NHIK 3025 cells

Human cervix carcinoma cells of the line NHIK 3025 were exposed to light after 18 h incubation with Photofrin II. After this photodynamic treatment cells in the interphase were retarded with respect to entry into mitosis for a period which increased with increasing light dose. Following the prolonged interphase, an increase in the mitotic index was observed, giving rise to a 3-fold higher level of mitotic cells compared to the control level. Staining of methanol-fixed cells with the DNA-specific dye mithramycin indicated that the increase in mitotic index was due to a prolongation of the metaphase. For all the light doses studied most of the metaphase cells could be characterized as three-group metaphases or c-metaphase-like structures for the first 8 h after treatment. An approximately 10-fold increase above the control level in the number of tripolar mitoses was also observed. A 2h incubation in a Photofrin II-free medium after the 18 h incubation with Photofrin II and before light exposure reduced the fluorescence of the cells by 30 per cent. However, this wash-out period had no effect on the increase in mitotic index after light exposure. A light dose corresponding to 80 per cent survival (as assayed on asynchronous cells) was given to cells in mitosis after Photofrin II incubation. This treatment delayed more than 90 per cent of the metaphase cells from entering the anaphase for at least 1 h. Cells photodynamically treated in the anaphase and telophase entered the interphase at a similar rate as control cells. These observations indicate a temporary block in the initiation of the anaphase and a prolongation of the metaphase. A microscopic study of cells immunologically stained for beta-tubulin 1 h after photodynamic treatment indicated that the organization of the spindle apparatus was disturbed by the photodynamic treatment. Such perturbations are suggested to be the cause of the observed accumulation of cells in mitosis.     

虫草蝙蝠蛾的有丝分裂染色体特性

本文首次报道虫草蝠蛾(鳞翅目,蝙蝠蛾科,蝠蛾属)的有丝分裂染色体核型。应用醋酸分离和热干燥技术,研究了云南的两种虫草蝠蛾Hepialus zhayuensis Chu et Wang和Hepialus sp.的有丝分裂染色体,它们的染色体数目为2n=64。在有丝分裂的早中期染色体上清晰地呈现出散漫着丝粒。然而,分裂中期和较晚的中期阶段,每条染色体都具显著的初级着丝粒(即主缢痕)。它们的雄性中期核型中都有一对典型的异形性染色体,X染色体着色稍淡,且都具中或亚中着丝粒;Y染色体比X染色体长,染色很深。 在雄性的分裂间期细胞中,观察到异固缩性染色质体,此异固缩体是Y染色体。     

Compound kinetochores of the Indian muntjac

The chromosomes of the Indian muntjac (Muntiacus muntjak vaginalis) are unique among mammals due to their low diploid number (2N=6, 7) and large size. It has been proposed that the karyotype of this small Asiatic deer evolved from a related deer the Chinese muntjac (Muntiacus reevesi) with a diploid chromosome number of 2n= 46 consisting of small telocentric chromosomes. In this study we utilized a kinetochore-specific antiserum derived from human patients with the autoimmune disease scleroderma CREST as an immunofluorescent probe to examine kinetochores of the two muntjac species. Since CREST antiserum binds to kinetochores of mitotic chromosomes as well as prekinetochores in interphase nuclei, it was possible to identify and compare kinetochore morphology throughout the cell cycle. Our observations indicated that the kinetochores of the Indian muntjac are composed of a linear beadlike array of smaller subunits that become revealed during interphase. The kinetochores of the Chinese muntjac consisted of minute fluorescent dots located at the tips of the 46 telocentric chromosomes. During interphase, however, the kinetochores of the Chinese muntjac clustered into small aggregates reminiscent of the beadlike arrays seen in the Indian muntjac. Morphometric measurements of fluorescence indicated an equivalent amount of stained material in the two species. Our observations indicate that the kinetochores of the Indian muntjac are compound structures composed of linear arrays of smaller units the size of the individual kinetochores seen on metaphase chromosomes of the Chinese muntjac. Our study supports the notion that the kinetochores of the Indian muntjac evolved by linear fusion of unit kinetochores of the Chinese muntjac. Moreover, it is concluded that the evolution of compound kinetochores may have been facilitated by the nonrandom aggregation of interphase kinetochores in the nuclei of the ancestral species.     

Do individual allocyclic chromosomes in metaphase reflect their interphase domains?

Summary Individual S phase allocyclic chromosomes have been analyzed in Bloom syndrome lymphocytes, in cells with an r(9), and in hypotetraploid Ehrlich mouse ascites cells treated with 1-methyl-2-benzyl hydrazine. On the basis of the following observations, we conclude that such chromosomes more or less reflect their domains in interphase: (1) The S phase allocyclic chromosomes have the same structure as S phase prematurely condensed chromatin (PCC) in fused cells; in other words they form limited areas of chromatin dots; (2) the allocyclic chromosome is the only chromosome in a metaphase plate which synthesizes DNA simultanneously with interphase nuclei; (3) the size of the allocyclic chromosomes is related to the size of the corresponding metaphase chromosome; and (4) the S phase allocyclic chromosomes resemble closely the chromosome domains in interphase made visible with biotinylated human DNA. A variety of evidence shows that most allocyclic chromosomes are simply left behind in their cycle, which presumably is caused by a deletion or inactivation of a hypothetical coiling center situated on each chromosome arm.     

多头绒泡菌间期细胞核和中期染色体中的银染蛋白分析*

电镜原位观察结合图象分析研究了多头绒泡菌Physarum polycephalum Schw间期细胞核和中期染色体中银染蛋白的形状、大小和分布。结果看到,银染蛋白主要呈颗粒状存在于间期细胞核和中期染色体中。银粒的大小不一,分布不均匀。间期细胞核中存在众多直径在5~15nm的银粒,其中10nm以上的较大银粒主要分布于核仁,集缩染色质和核基质部分10nm以上银粒不多。中期细胞核内10nm以上的较大银粒主要分布于染色体中。染色体中除含有一些较大银粒外,多数银粒的直径为5~10nm。本文结果提示,构成染色体骨架的嗜银蛋白可能来自间期细胞核的染色质、核基质和核仁。