DNS-Replikation und Morphologie der X-Chromosomen während der Syntheseperiode bei Microtus agrestis

X-chromosome behaviour of female Microtus agrestis in interphase nuclei with and without large chromocenters was examined in cultured epithelial and fibroblast cells. By means of pulse-labeling, the configuration of the X-chromosomes in these nuclei can be illustrated; staining with pararosaniline-methylgreen seems to be most suitable. According to the replication behaviour, three types of chromatin can be discerned in the X-chromosomes: early replicating euchromatin, late replicating sex chromatin, and very late replicating heterochromatin. In fibroblasts only the sex chromatin forms a single, small chromocenter; in epithelial cells both the sex chromatin and the remaining heterochromatin form large chromocenters. Both types of heterochromatin replicate their DNA in the condensed state. It seems likely that the late replicating segments of the X-chromosomes (sex chromatin and remaining heterochromatin) are condensed in every cell, but they may not always be configurated or even visible as typical chromocenters; these segments could be distributed over a wide range of compact to more or less diffuse superstructures.     

Reaction of human heterochromatin and euchromatin to spermine]

The frequency of occurrence of cell nuclei with X-chromatin and Y-chromatin, as well as with diffuse and coarse chromatin network was studied, using cultured human fibroblasts 47XXY and 47XYY, after treatment of the cell with spermin. This treatment failed to change the percentage of the nuclei with the X- and Y-bodies, but significantly increased the frequency of occurrence of the nuclei, with coarse chromatin. The heterochromatic chromosomal segments retarded in metaphase condensation after the action of 5-bromdesoxyuridine increased the length and number when spermin was added to 5-bromdesoxyuridine. The data obtained were attributed to the different sensitivity of euchromatin to the condensating action of spermin and to inertness of heterochromatin.     

The phosphorylation of high mobility group proteins 14 and 17 and their distribution in chromatin

The phosphorylation of the high mobility group (HMG) proteins has been investigated in mouse Ehrlich ascites, L1210 and P388 leukemia cells, human colon carcinoma cells (HT-29), and Chinese hamster ovary cells. HMG 14 and 17, but not HMB 1 and 2, were phosphorylated in the nuclei of all cell lines with a serine being the site of modification for both proteins in Ehrlich ascites cells. Phosphorylation of HMG 14 and 17 was greatly reduced in cultured cells at plateau phase in comparison to log phase cells, suggesting that modification of HMG 14 and 17 is growth-associated. However, phosphorylation was not linked to DNA synthesis, since incorporation of 32P did not vary through G1 and S phase in synchronized Chinese hamster ovary cells. Treatment of HT-29 or Ehrlich ascites cells with sodium butyrate reduced HMG phosphorylation by 30 and 70%, respectively. The distribution of the phosphorylated HMG proteins in chromatin was examined using micrococcal nuclease and DNase I. 32P-HMG 14 and 17 were preferentially associated with micrococcal nuclease-sensitive regions as demonstrated by the release of a substantial fraction of the phosphorylated forms of these proteins under conditions which solubilized less than 3% of the DNA. Short digestions with DNase I did not show a marked release of 32P-HMG 14 or 17.     

Giant cell formation produced by laser microbeam irradiation of chromatin in Chinese hamster cells

A pulsed laser microbeam of wavelength 532 nm was used to produce visible small lesions in the nucleoplasm or in the cytoplasm of V79 Chinese hamster cells. Transmission electron microscopy (TEM) of microirradiated nuclei showed that the lesions were produced within the nucleus and comprised between 0.2 and 0.5% of the total chromatin. Serial sections above and below the lesion site did not reveal any detectable chromatin damage, indicating that a visible lesion was restricted to the focal point of the beam. Whereas cells microirradiated anywhere in the cytoplasm showed normal clonal growth with few exceptions, the cells containing nuclear lesions did not enter mitosis at the time of unirradiated controls. Instead they formed giant cells in a high percentage of cases ($\text{72}\text{99}$). The DNA content of these cells was considerably increased suggesting polyploidization. In some cases, division of giant cells was observed resulting in non-viable daughter cells containing micronuclei. Further evidence that the induction of giant cell formation depends on chromatin damage was obtained by microirradiation of chromosomes in anaphase. Here, giant cell formation was observed in the daughter cell which received microirradiated chromatin, whereas microirradiation of cytoplasm between the moving sets of chromosomes did not affect subsequent divisions of both daughter cells. Our data point out that loss of reproductive integrity and giant cell formation can be induced by damage at many sites of the chromosome complement.     

Carcinogenic nickel silences gene expression by chromatin condensation and DNA methylation: a new model for epigenetic carcinogens.

A transgenic gpt+ Chinese hamster cell line (G12) was found to be susceptible to carcinogenic nickel-induced inactivation of gpt expression without mutagenesis or deletion of the transgene. Many nickel-induced 6-thioguanine-resistant variants spontaneously reverted to actively express gpt, as indicated by both reversion assays and direct enzyme measurements. Since reversion was enhanced in many of the nickel-induced variant cell lines following 24-h treatment with the demethylating agent 5-azacytidine, the involvement of DNA methylation in silencing gpt expression was suspected. This was confirmed by demonstrations of increased DNA methylation, as well as by evidence indicating condensed chromatin and heterochromatinization of the gpt integration site in 6-thioguanine-resistant cells. Upon reversion to active gpt expression, DNA methylation and condensation are lost. We propose that DNA condensation and methylation result in heterochromatinization of the gpt sequence with subsequent inheritance of the now silenced gene. This mechanism is supported by direct evidence showing that acute nickel treatment of cultured cells, and of isolated nuclei in vitro, can indeed facilitate gpt sequence-specific chromatin condensation. Epigenetic mechanisms have been implicated in the actions of some nonmutagenic carcinogens, and DNA methylation changes are now known to be important in carcinogenesis. This paper further supports the emerging theory that nickel is a human carcinogen that can alter gene expression by enhanced DNA methylation and compaction, rather than by mutagenic mechanisms.     

Quantitative investigation of reproduction of condensed chromatin of sex chromosomes during trophoblast cell polyploidization and endoreduplication in the East European field vole Microtus rossiaemeridionalis

Simultaneous measurement of DNA content in cell nuclei and condensed chromatin bodies formed by heterochromatized regions of sex chromosomes (gonosomal chromatin bodies, GCB) has been performed in two trophoblast cell populations of the East-european field vole Microtus rossiaemeridionalis, namely in the proliferative population of trophoblast cells of the junctional zone of placenta and in the secondary giant trophoblast cells. One or two gonosomal chromatin bodies have been observed in trophoblast cell nuclei of all embryos studied (perhaps both male and female), In the proliferative trophoblast cell population, characterized by low ploidy levels (2c-16c), and in the highly polyploid population of secondary giant trophoblast cells (16c-256c), the total DNA content in GCB increased proportionally to the ploidy level. In separate bodies, the DNA content rose also in direct proportion with the ploidy level seen in the nuclei with both one and two GCBs in the two trophoblast cell populations. A certain increase in percentage of the nuclei with 2-3 GCBs was shown in the nuclei of the junctional zone of placenta; this may be accounted for by genome multiplication via uncompleted mitoses. In the secondary giant trophoblast cell nuclei (16c-256c), the number of GCBs did not exceed 2, and the share of nuclei with two GCBs did not increase, thus suggesting the polytene nature of sex chromosome in these cells. At different poloidy levels, the ratio of DNA content in the nucleus to the total DNA content in GCB did not change significantly giving evidence of a regular replication of sex chromosomes in each cycle of genome reproduction. In all classes of ploidy, the mean total DNA content in trophoblast cell nuclei with single heterochromatic body was less than in the nuclei with two and more GCBs. This may indicate that a single GCB in many cases does not derive from the fusion of two GCBs. To put it another way, in the nuclei with one GCB and in those with two or more GCBs, different chromosome regions may undergo heterochromatization. The regularities observed here are, most probably, associated with the peculiarities in the structure of X- and Y-chromosomes in a range of species of Microtus (M. agrestis, M. rossiaemeridionalis, M. transcaspicus). As a result, gonosomal chromatin bodies may include large blocks of both constitutive heterochromatin of X- and Y-chromosomes (in male and female embryos) and inactivated euchromatin of "lyonized" X-chromosome in female embryos. Therefore the presence of two or more GCBs in trophoblast cells of M. rossiaemeridionalis may be accounted for by both polyploidy and functional state of the nucleus, in which gonosomal constitutive heterochromatin and inactivated euchromatin form two large chromocenters rather than one. The differences in DNA content in GCBs in the nuclei with one and two GCBs seem to be an indirect indication that the two chromocenters may be formed by two different gonosomes, with the extent of their heterochromatization being higher than that in the nuclei with one GCB. GCBs in the trophoblast cells of M. rossiaemeridionalis are observed not only at the early developmental stages, as it was observed in rat at the first half of pregnancy (Zybina and Mosjan, 1967), but also at the later stages, up to the 17th day of gestation. At these stages, the nuclei with non-classical polytene chromosomes rearrange to those with a great number of endochromosomes, probably because of disintegration of chromosomes into oligotene fibrils. However, it does not seem unlikely that this process may involve heterochromatized gonosomal bodies, since only one or two large GCBs can be seen in the nuclei as before. The presence of prominent blocks of constitutive heterochromatin seems to favor a closer association of sister chromatids in polytene chromosomes, which prevents their dissociation into endochromosomes with the result that polyteny of sex chromosomes in the field vole trophoblast is probably retained during a longer period of embryonic development.     

Genome multiplication of extravillous trophoblast cells in human placenta in the course of differentiation and invasion into endometrium and myometrium. II. Mechanisms of polyploidization

Peculiarities of the structure of interphase nuclei, mitotic activity, and Ki-67 protein intranuclear immunolocalization were studied to elucidate mechanisms of genome multiplication in proliferative and differentiating invasive extravillous trophoblast cells in the human placenta. The presence of numerous chromocenters was shown to be a characteristic feature of proliferative cell nuclei of both villous and extravillous trophoblast. At the beginning of extravillous trophoblast cell differentiation, i.e. in the proximal part of cell columns, some amount of cells with large nuclei containing enlarged chromocenters were found. DNA content was measured simultaneously with counting the number of chromocenters in similarly looking nuclei of squash preparations of placental villi. The increase in the ploidy level up to 4c-8c, accompanied by a slight increase in the number of chromocenters being not proportional to the ploidy level and not exceeding the diploid number of chromosomes of the human genome, was demonstrated. This suggests that genome multiplication of extravillous trophoblast cells may be accomplished by endoreduplication. In addition, pictures of endomitosis were seen at early steps of differentiation of EVT cells. The lack of polyploid mitotic figures or any obvious polyploidizing or restitutional mitoses suggests that these are not of considerable importance in genome multiplication of human EVT cells. However, the prevalence of metaphases at the boundary of the distal part of cell columns suggests that restitutional mitoses may be involved, even partly, in human trophoblast cell polyploidization. At later steps of differentiation, i.e. in the distal part of cell columns, the nuclear structure obviously changes, with a uniform "network" chromatin arrangement prevailing, whereas numerous chromocenters and features of endomitosis are no longer seen. The pattern of Ki-67 protein immunolocalization is also changing along the invasive pathway. In the proliferating stem cells and trophoblast cells of the proximal part of cell columns, Ki-67 was localized in the karyoplasm, chromocenters and numerous small nucleoli, whereas in the distal part of cell columns this protein was detected predominantly in 1-2 large nucleoli. The comparative analysis of the literature data on Ki-67 localization at different stages of cell cycle provided another evidence that EVT cells in the course of invasion may switch to the endoreduplication cycle. In agreement with the relevant report on rodent placentation, our present data suggest that acquirement of an invasive phenotype of EVT cells is accompanied by switching from mitotic division to endoreduplication cycle.     

Mitotic chromatin condensation in vitro using somatic cell extracts and nuclei with variable levels of endogenous topoisomerase II

We report the development of a new method for producing mitotic extracts from tissue culture cells. These extracts reproducibly promote the condensation of chromatin in vitro when incubated with purified interphase nuclei. This condensation reaction is not species specific, since nuclei from chicken, human, and hamster cell lines all undergo chromatin condensation upon incubation with the extract. We have used this extract to investigate the role of DNA topoisomerase II (topo II) in the chromosome condensation process. Chromatin condensation does not require the presence of soluble topo II in the mitotic extract. However, the extent of formation of discrete chromosome-like structures correlates with the level of endogenous topo II present in the interphase nuclei. Our results further suggest that chromatin condensation in this extract may involve two processes: chromatin compaction and resolution into discrete chromosomes.     

A new system for high-resolution DNA sequence mapping interphase pronuclei

Cosmid clones containing human or hamster inserts have been hybridized in situ and localized with fluorescent reporter molecules in interphase nuclei (pronuclei) obtained after fusion of hamster eggs with either human or hamster sperm. Hamster egg cytoplasm processes the tightly packaged sperm DNA into large diffuse networks of chromatin fiber bundles, providing hybridization targets more extended than those available in somatic interphase cell nuclei. Pronuclear physical distances between hybridization signals were measured in micrometers and correlated to genomic distances determined by restriction fragment analyses, using cosmids from the Chinese hamster DHFR region and from the human Factor VIII/color vision pigment gene region (Xq28). The mean pronuclear distances between hybridization sites were about three times as large as those measured in somatic interphase cells for equivalent genomic distances. The relationship between physical and genomic distances was linear from less than 50 kb to at least 800 kb. The results show that physical distance in the sperm-egg system promises to extend the mapping range obtainable in somatic interphase nuclei below 50 kb and up to at least 800 kb.     

The triploid endosperm genome of Arabidopsis adopts a peculiar, parental-dosage-dependent chromatin organization

The endosperm is a seed tissue unique to flowering plants. Due to its central role in nourishing and protecting the embryo, endosperm development is subject to parental conflicts and adaptive processes, which led to the evolution of parent-of-origin-dependent gene regulation. The role of higher-order chromatin organization in regulating the endosperm genome was long ignored due to technical hindrance. We developed a combination of approaches to analyze nuclear structure and chromatin organization in Arabidopsis thaliana endosperm. Endosperm nuclei showed a less condensed chromatin than other types of nuclei and a peculiar heterochromatin organization, with smaller chromocenters and additional heterochromatic foci interspersed in euchromatin. This is accompanied by a redistribution of the heterochromatin mark H3K9me1 from chromocenters toward euchromatin and interspersed heterochromatin. Thus, endosperm nuclei have a specific nuclear architecture and organization, which we interpret as a relaxed chromocenter-loop model. The analysis of endosperm with altered parental genome dosage indicated that the additional heterochromatin may be predominantly of maternal origin, suggesting differential regulation of maternal and paternal genomes, possibly linked to genome dosage regulation.     

Resistance of Chinese hamster ovary cell chromatin to endonuclease digestion. I. Reversal by cAMP

A portion of the DNA within intact nuclei of a spontaneously transformed Chinese hamster ovary cell line (CHO-Kl) is relatively resistant to digestion by pancreatic deoxyribonuclease, as compared to nuclei from primary cultures of Chinese hamster ovary fibroblasts. Treatment of CHO-Kl cells with derivatives of 3',5' cyclic AMP (cAMP) under conditions which effect the reverse transformation (RT) of these cells, results in restoration of the increased sensitivity of their DNA to hydrolysis by pancreatic deoxyribonuclease, to the level characteristic of an untransformed, morphologically normal Chinese hamster fibroblast cell line. Dibutyryl (db-)cAMP and 8-bromo-cAMP (Br-cAMP) yielded similar results. The cAMP derivatives employed had no effect on the normal fibroblasts.     

Changes in nuclear morphology associated with elevated DNA levels during gametogenesis in cyclopoid copepods with chromatin diminution

Abstract. Most species of freshwater cyclopoid copepods follow a conventional course of DNA replication during gametogenesis, but certain species regularly undergo chromatin diminution during early embryogenesis, a process that is accompanied by the exclusion of large amounts of heterochromatic DNA from progenitor somatic cells and selective retention of this DNA by primordial germ cells after their segregation from the soma. We have used scanning microdensitometry and image analysis cytometry of individual Feulgen-stained nuclei to determine the DNA levels of individual somatic cell nuclei, oocytes, spermatocytes, and sperm for seven species, including Acanthocyclops brevispinosus, Acanthocyclops vernalis, Ectocyclops phaleratus, Eucyclops agilis, Eucyclops ensifer, Macrocyclops albidus , and Thermocyclops decipiens . The oocyte nuclei of these species have twice the DNA content of their diploid somatic cell nuclei. In specimens of Cyclops strenuus, Mesocyclops edax, Mesocyclops longisetus, Mesocyclops longisetus curvatus , and Metacyclops mendocinus , marked increases in DNA levels were noted in both female and male germ cells before meiosis. The appearance of enlarged nuclei with densely stained chromocenters is a distinguishing feature of oocytes and spermatocytes of cyclopoid species that exhibit excessive accumulations of DNA during gametogenesis and subsequently undergo chromatin diminution. The net increase in DNA content of the prediminution nuclei is 6–10 times the DNA level of their somatic cell nuclei and is largely attributable to increases in the amount of DNA associated with their heterochromatic chromocenters. The identification of a morphologically distinctive type of germ cell and its dramatic accumulation of large amounts of DNA before meiosis are discussed in terms of the selective elimination of heterochromatin during early cleavage stages in these cyclopoid species.     

Cell cycle dependent changes of chromosomes in mouse fibroblasts.

Mouse fibroblast interphase nuclei stained with quinacrine dihydrochloride show distinctive differences in their fluorescent characteristics analogous to those which we have already observed in human and Syrian hamster cells. These patterns reflect the position of any given nucleus within the cell cycle. The brightly fluorescent chromocenters in the mouse nuclei were found to be in absolute aggreement with those stained by the C-banding technique, indicating that they represent centromeric heterochromatin. Furthermore, their number and size per nucleus were shown to vary in relation to the progress of the cell cycle.     

Structural repeat units of Chinese hamster ovary chromatin. Evidence for variations in repeat unit DNA size in higher eukaryotes.

DNA lengths in the structural repeat units of Chinese hamster ovary (CHO) and chicken erythrocyte chromatin were compared by analyzing the sizes of DNA fragments produced after treatment of nuclei with staphylococcal nuclease. The repeat length of CHO chromatin (173 +- 4 BP) is about 20 base pairs (BP) smaller than that of chicken erythrocyte chromatin (194 +- 8 BP). Repeat lengths of rat liver and calf thymus chromatin were found to be about 10 BP shorter than that of chicken erythrocyte chromatin. Thus significant variations occur in repeat units of chromatin of higher eukaryotes. These variations occur in the lengths of "spacer" (or "internucleosomal") DNA segments, not in "core particle" (or "nucleosomal") DNA lengths. The concept of spacer regions and the possible influence of H1 histones is discussed.     

Condensed chromatin and its underreplication during root differentiation in leguminosae

Interphase nuclear structure was studied in 15 leguminous species. Eleven species showed chromocentric interphase nuclei while the remaining 4 had reticulate nuclei. The number of chromocenters appeared to be dependent on the number of chromosomes (2n). The total proportion of condensed chromatin as determined by planimetry was found to vary from 11–24% in chromocentric nuclei and 29–62% in reticulate nuclei. The condensed chromatin amount showed a direct correlation with the nuclear DNA content (2C). Though the interphase nuclear structure remained same in differentiated cells, the amount of condensed chromatin was considerably less than that in the meristematic cells, indicating underreplication of heterochromatin during differentiation. HCl-Giemsa method seems to be the simplest method for detection of underreplication in plants.1. NCL Communication No. 35942. To whom all the correspondence should be addressed     

Action of heparin on mammalian nuclei. II. Cell-cycle-specific changes in chromatin organization correlate temporally with histone H1 phosphorylation

The interaction of the polyanion heparin with the inner histones of chromatin has been used to detect changes in chromatin organization associated with cell-cycle traverse. Synchronized populations of Chinese hamster cells were obtained either in early G1 or near the G1/S boundary. The rate of interaction of heparin with chromatin-associated inner histones was measured using nuclei isolated from synchronized cell populations in different phases of the cell cycle. A G1-specific decrease in rate of interaction of heparin with inner histones was observed and found to be independent of the presence of hydroxyurea during traverse of G1. A further decrease in heparin-inner histone interaction occurred in late S and G2. These changes correlate temporally with the interphase phosphorylation(s) of histone H1. This correlation is discussed within the framework of current models of higher order chromatin structure (i.e. organization above the nucleosome level). Analysis of the cooperativity of interaction of heparin with inner histones was performed using the kinetic analog of the Hill equation. This analysis suggests that the organization of inner histones on chromatin does not undergo large variations during the cell cycle.     

Telomere length, chromatin structure and chromosome fusigenic potential

Telomeres are specialized structures at chromosome ends that are thought to function as buffers against chromosome fusion. Several studies suggest that telomere shortening may render chromosomes fusigenic. We used a novel quantitative fluorescence in situ hybridization procedure to estimate telomere length in individual mammalian chromosomes, and G-banding and chromosome painting techniques to determine chromosome fusigenic potential. All analysed Chinese hamster and mouse cell lines exhibited shorter telomeres at short chromosome arms than at long chromosome arms. However, no clear link between short telomeres and chromosome fusigenic potential was observed, i.e. frequencies of telomeric associations were higher in cell lines exhibiting longer telomeres. We speculate that chromosome fusigenic potential in mammalian cell lines may be determined not only by telomere length but also by the status of telomere chromatin structure. This is supported by the observed presence of chromatin filaments linking telomeres in Chinese hamster chromosomes and of multibranched chromosomes oriented end-to-end in the murine severe combined immunodeficient (SCID) cell line. Multibranched chromosomes are the hallmark of the human ICF (Immune deficiency, Centromeric instability, Facial abnormalities) syndrome, characterized by alterations in heterochromatin structure. Received: 13 June 1997; in revised form: 3 August 1997 / Accepted: 4 August 1997     

Epigenetic characterization of chromatin in cycling cells of pedunculate oak, Quercus robur L.

Cycling cells of Quercus robur have a simple nuclear organization where most of the heterochromatin is visible as DAPI-positive chromocenters, which correspond to DAPI bands at the (peri)centromeric region of each of the 24 chromosomes of the oak complement. Immunofluorescence using 5-mC revealed dispersed distribution of the signal throughout the interphase nucleus/chromosomes without enrichment within DAPI-positive chromocenters/bands, suggesting that DNA methylation was not restricted to constitutive heterochromatin, but was associated with both euchromatic and heterochromatic domains. While H3K9ac exhibited typical euchromatin-specific distribution, the distributional pattern of histone methylation marks H3K9me1, H3K27me2, and H3K4me3 showed some specificity. The H3K9me1 and H3K27me2, both heterochromatin-associated marks, were not restricted to chromocenters, but showed additional dispersed distribution within euchromatin, while H3K27me2 mark also clustered in foci that did not co-localize with chromocenters. Surprisingly, even though H3K4me3 was distributed in the entire chromatin, many chromocenters were enriched with this euchromatin-specific modification. We discuss the distribution of the epigenetic marks in the context of the genome composition and lifestyle of Q. robur.