Distribution of c-myc, c-myb, and Ki-67 antigens in interphase and mitotic human cells evidenced by immunofluorescence staining technique

Using specific antibodies and the immunofluorescence staining technique we found a similar subcellular distribution pattern of the cellular proto-oncogene proteins c-myc and c-myb in interphase and mitotic HL60 and Molt4 cells. Antibodies against c-myc as well as those against c-myb protein gave rise to a nuclear staining excluding the nucleoli. In mitotic cells both proteins are apparently not associated with the chromatin of the condensed chromosomes, but appear diffusely distributed throughout the cytoplasm. In contrast, immunostaining using the proliferation marker antibody Ki-67 yielded in both cell lines several prominent specks in the nucleus and a weak finely dispersed staining throughout the nucleoplasm. No fluorescence was detectable in the cytoplasm. In dividing cells Ki-67 immunofluorescence was found to be associated with the surface of the chromosomes. The functional significance of the different localizations of the proteins is discussed in light of what is currently known about nuclear antigens.     

Chromatin association and DNA binding properties of the c-fos proto-oncogene product.

As a first step in the analysis of the molecular function of the nuclear c-fos proto-oncogene product we have studied its subnuclear localization in serum-stimulated mouse fibroblasts where it forms a non-covalent, apparently monodisperse complex with another nuclear protein, p39. The c-fos/p39 complex is almost quantitatively released from intact nuclei by DNasel or micrococcus nuclease treatment under conditions where only a minor fraction of DNA and nuclear proteins is released. In gel filtration experiments, c-fos/p39 comigrates with chromatin and seems to be associated with regions of increased DNasel accessibility. c-fos/p39 is bound to chromatin by electrostatic forces of moderate strength since greater than 90% of the complex can be eluted from nuclei at 0.4 M NaCl. In vitro, the c-fos/p39 complex in nuclear extracts binds to double- and single-stranded calf thymus DNA, suggesting that the association of c-fos/p39 with chromatin is at least in part due to its interaction with DNA. In agreement with this conclusion, c-fos/p39 is released from nuclei by incubation with tRNA, presumably due to competition for binding sites. Our observations are compatible with the hypothesis that c-fos may play a role in the regulation of gene expression.     

UV micro-irradiation of the Chinese hamster cell nucleus and caffeine post-treatment immunocytochemical localization of DNA photolesions in cells with partial and generalized chromosome shattering

UV micro-irradiation of a small part of the Chinese hamster nucleus and caffeine post-incubation often results in shattered chromosomes at the first post-irradiation mitosis. In some of these mitotic cells, chromosome shattering is restricted to a few chromosomes spatially related in a small area of the metaphase spread; in others, shattering includes the whole chromosome complement. These 2 types of damage have been called partial and generalized chromosome shattering (PCS and GCS).Using antisera that specifically react with UV-irradiated DNA, we identified micro-irradiated chromatin in interphase nuclei and in mitotic cells with PCS or GCS by indirect immunofluorescence microscopy. In PCS, immunofluorescence staining was found in the damaged area, while the surrounding intact chromosomes were not stained. In GCS, staining was also restricted to a small region of the shattered chromosome complement. In other experiments, cells synchronized in G1 were micro-irradiated in the nucleus, pulse-labelled with [³H]thymidine and post-incubated with caffeine. Autoradiographs of cells with GCS showed unscheduled DNA synthesis restricted to a small chromatin region.Our data present direct evidence that the distribution of DNA photolesions does not coincide with the sites of chromosomal damage in GCS. As a working hypothesis, we propose that an indirect mechanism is involved in the induction of GCS by which DNA photolesions in a small nuclear segment induce shattering of both micro-irradiated and non-irradiated chromosomes.     

The myc proteins are not associated with chromatin in mitotic cells.

The protein products of cellular and viral myc oncogenes are detected in nuclei by immunofluorescence. No myc fluorescence is found in nucleoli. In mitotic cells the myc antigens are not found associated with metaphase chromosomes, but are diffusely distributed throughout the cytoplasm. Cytoplasmic myc fluorescence is first observed when chromatin begins to condense in early prophase. Granular nuclear myc fluorescence is again discerned in telophase cells, when the nuclear envelope is formed and becomes more prominent upon cytokinesis; concomitantly the diffuse cytoplasmic myc staining is lost. These results suggest that myc proteins not only bind to DNA or chromatin, but are also associated with other structural systems in the nuclei.     

Uniparental chromosome elimination at mitosis and interphase in wheat and pearl millet crosses involves micronucleus formation, progressive heterochromatinization, and DNA fragmentation

Complete uniparental chromosome elimination occurs in several interspecific hybrids of plants. We studied the mechanisms underlying selective elimination of the paternal chromosomes during the development of wheat (Triticum aestivum) x pearl millet (Pennisetum glaucum) hybrid embryos. All pearl millet chromosomes were eliminated in a random sequence between 6 and 23 d after pollination. Parental genomes were spatially separated within the hybrid nucleus, and pearl millet chromatin destined for elimination occupied peripheral interphase positions. Structural reorganization of the paternal chromosomes occurred, and mitotic behavior differed between the parental chromosomes. We provide evidence for a novel chromosome elimination pathway that involves the formation of nuclear extrusions during interphase in addition to postmitotically formed micronuclei. The chromatin structure of nuclei and micronuclei is different, and heterochromatinization and DNA fragmentation of micronucleated pearl millet chromatin is the final step during haploidization.     

Isolation of monoclonal antibodies to chromatin and preliminary characterization of target antigens

This paper describes the isolation of monoclonal antibodies to chromatin-associated protein antigens and their use in the characterization of such proteins by indirect immunofluorescence. Hybridomas were derived by fusion of the mouse myeloma Ag8653 with spleen cells from mice immunized with chromatin from human liver, rat liver or a human lymphoblastoid cell line. Hybrids were screened by solid-phase radioimmunoassay. The proportion of positive hybrids varied with the immunizing chromatin as follows: human liver 55/83, human lymphoblast 8/183 and rat liver 2/82. Fifteen antibodies derived from these fusions (7, 7 and 1 respectively) were subjected to further analysis. Most of these (11/13) were IgM and recognized both human and rat chromatin (12/15). Most of the target antigens were protease sensitive (8/13) and nuclease resistant. In fact the binding of five antibodies to lymphoblast chromatin was more than doubled by preincubation with DNAase I. The subcellular location of target antigens was examined by indirect immunofluorescence. Seven antibodies stained at least one of several cultured cell lines tested. Three gave staining patterns consistent with the in vivo association of the target antigen with chromatin recognizing, respectively, the interphase nucleus and metaphase chromosomes, the nuclear periphery and the mitotic spindle and other microtubule-containing structures. The remaining four all recognized antigens associated with the intermediate filament network.     

Changes in distribution of nuclear matrix antigens during the mitotic cell cycle

We examined the distribution of nonlamin nuclear matrix antigens during the mitotic cell cycle in mouse 3T3 fibroblasts. Four monoclonal antibodies produced against isolated nuclear matrices were used to characterize antigens by the immunoblotting of isolated nuclear matrix preparations, and were used to localize the antigens by indirect immunofluorescence. For comparison, lamins and histones were localized using human autoimmune antibodies. At interphase, the monoclonal antibodies recognized non-nucleolar and nonheterochromatin nuclear components. Antibody P1 stained the nuclear periphery homogeneously, with some small invaginations toward the interior of the nucleus. Antibody I1 detected an antigen distributed as fine granules throughout the nuclear interior. Monoclonals PI1 and PI2 stained both the nuclear periphery and interior, with some characteristic differences. During mitosis, P1 and I1 were chromosome-associated, whereas PI1 and PI2 dispersed in the cytoplasm. Antibody P1 heavily stained the periphery of the chromosome mass, and we suggest that the antigen may play a role in maintaining interphase and mitotic chromosome order. With antibody I1, bright granules were distributed along the chromosomes and there was also some diffuse internal staining. The antigen to I1 may be involved in chromatin/chromosome higher-order organization throughout the cell cycle. Antibodies PI1 and PI2 were redistributed independently during prophase, and dispersed into the cytoplasm during prometaphase. Antibody PI2 also detected antigen associated with the spindle poles.     

Use of immunogold electron microscopy and monoclonal antibodies in the identification of nuclear substructures

A cytochemical technique for the ultrastructural localization of unique nuclear antigens is reported. Using a post-embedding indirect immunogold labeling procedure, nuclear antigens in electron-dense regions of the nucleus are localized with a minimum of nonspecific staining. Using this technique and indirect immunofluorescence, a panel of antinuclear monoclonal antibodies is shown to recognize preferentially cell cycle-dependent nuclear substructures. The antigenic domains recognized include specific regions in condensed chromatin, interchromatin granules, euchromatin, and chromosomes. The specificity of antigen recognition is demonstrated with qualitative and quantitative immunogold electron microscopy and immunoblot analysis. These results reveal the existence of previously undefined supramolecular organization within the nucleus and demonstrate the utility of the immunogold procedure when monoclonal antibodies are used.     

Visualization of chromatin distribution in living PTO cells by Hoechst 33342 fluorescent staining

Chromatin distribution was visualized in living cells with the selective DNA fluorochrome Hoechst 33342. This dye was shown to be non-toxic on the rat kangaroo PTO cell line by measuring the labelled cell growth rate. The aim of this work was firstly to visualize chromatin distribution without fixation or dehydration and secondly to demonstrate that quantitative determination of DNA content was possible under these non-toxic labelling conditions. During interphase, condensed, decondensed and thin network chromatin configurations were visualized. In nucleolar regions the fluorochrome revealed well-defined chromocentres. During mitosis, fluorescent chromosome banding was observed in vital conditions and chromocentres on fixed chromosomes. Chromatin segregation was visualized after micronucleation, which induced chromosomal set distribution in individual micronuclei. By this means, we demonstrated that the chromocentres observed in interphase nuclei were part of nuclear organizer region (NOR)-bearing chromosomes. This vital staining of chromatin was shown to be compatible with the quantitative determination of DNA content, both in living PTO cells and in isolated nuclei.     

Localization of the loosely bound nuclear proteins of rat brain: an immunocytochemical ultrastructural study

Antibodies against the loosely bound subnuclear protein fraction (0.35 M NaCl-extractable subnuclear fraction) of rat brain were raised in rabbits, and the ultrastructural distribution of the antigenic determinants in rat cerebellum was studied using the unlabeled antibody peroxidase-antiperoxidase (PAP) method. A localization restricted to the nucleus was observed. Both neuronal and neuroglial nuclei exhibited antigens, whereas nuclei of pericytes and endothelial cells did not. The immunoreaction product was homogeneously distributed in dispersed chromatin and was absent from condensed chromatin, suggesting that the antigens were confined to the active regions of the genoma. The outer nuclear membrane and the nucleolus appeared to be free of the antigens, while a perinucleolar ring of immunoreaction was detectable. Liver preparations showed a nuclear reaction markedly weaker than the one for brain nuclei. Adsorption of the serum with isolated liver nuclei nullified the reactivity in liver tissue, whereas a sharp reaction was still observed in the cerebellum, indicating the subcellular reaction under examination to contain antigens specifically concentrated in the nervous system or unique to the brain.     

Immunocytochemical localization of chromatin regions UV-microirradiated in S phase or anaphase. Evidence for a territorial organization of chromosomes during cell cycle of cultured Chinese hamster cells

Chinese hamster cells (M3-1 line) in S phase were laser-UV-microirradiated (lambda, 257 nm) at a small site of the nucleus. Cells were fixed either immediately thereafter or in subsequent stages of the cell cycle, including prophase and metaphase. The microirradiated chromatin was visualized by indirect immunofluorescence microscopy using antibodies specific for UV-irradiated DNA. During the whole post-incubation period (4-15 h) immunofluorescent labelling was restricted to a small part of the nucleus (means, 4.5% of the total nuclear area). In mitotic cells segments of a few chromosomes only were labelled. Following microirradiation of chromosome segments in anaphase, immunofluorescent labelling was observed over a small part of the resulting interphase nucleus. A territorial organization of interphase chromosomes, i.e. interphase chromosomes occupying distinct domains, has previously been demonstrated by our group for the nucleus of Chinese hamster cells in G1. Our present findings provide evidence that this organization pattern is maintained during the entire cell cycle.     

Monoclonal antibodies specific for tight-binding human chromatin antigens reveal structural rearrangements within the nucleus during the cell cycle

The class of nonhistone chromosomal proteins that remains bound to DNA in chromatin in the presence of 2.5 M NaCl-5 M urea has proven refractile to biochemical analysis. In order to study its role in chromatin organization, we have produced monoclonal antibodies that are specific for the HeLa DNA-protein complex that remains after extraction of chromatin with high salt and urea. The antibody-producing clones were identified with an ELISA assay. Of the six clones selected, five were stabilized by limiting dilution. All clones are IgG producers. None cross-react significantly with native DNA, core histones, or the high-mobility group nonhistone proteins. All antibodies are specific for nuclear or juxtanuclear antigens. Indirect immunofluorescence shows that three antibodies, which are nonidentical, stain three different nuclear networks. Available evidence indicates that two of these networks are the nuclear matrix. A fourth antibody reveals structures reminiscent of chromocenters. A fifth antibody, AhNA-1, binds to interphase HeLa chromatin and specifically decorates metaphase chromosomes. AhNA-1 similarly recognizes rat chromosomes. Each of these monoclonal antibodies also reveals a changing pattern of nuclear staining as cells progress through the cell cycle. Presumably, this reflects the rearrangement of the cognate antigens.     

DNA content of microcells prepared from rat kangaroo and mouse cells

Enucleation of animal cells in which nuclear fragmentation (micronucleation) has been induced by treatment with mitotic inhibitors results in the formation of subdiploid microcells consisting of one or several micronuclei, some cytoplasm and surrounded by a plasma membrane. Microcells were prepared from rat kangaroo cells (12 chromosomes) and a polyoma virus transformed mouse cell line (61 chromosomes) and analysed for DNA content. Microspectrophotometric DNA measurements and the appearance of micronuclei at mitosis show that small micronuclei contain genetic information equivalent to single chromosomes. A large proportion of the micronuclei and the microcells, however, contains DNA corresponding to several chromosomes. Heterogeneous mixtures of microcells can be fractionated by a unit gravity sedimentation procedure so as to isolate the small microcells. These can afterwards be fused with intact normal or mutant cells.     

Fanconi anemia proteins localize to chromatin and the nuclear matrix in a DNA damage- and cell cycle-regulated manner

Fanconi anemia (FA) is a genetic disease characterized by congenital defects, bone marrow failure, and cancer susceptibility. Cells from patients with FA exhibit genomic instability and hypersensitivity to DNA cross linking agents such as mitomycin C. Despite the identification of seven complementation groups and the cloning of six genes, the function of the encoded gene products remains elusive. The FancA (Fanconi anemia complementation group A), FancC, and FancG proteins have been detected within a nuclear complex, but no change in level, binding, or localization has been reported as a result of drug treatment or cell cycle. We show that in immunofluorescence studies, FancA appears as a non-nucleolar nuclear protein that is excluded from condensed, mitotic chromosomes. Biochemical fractionation reveals that the FA proteins are found in nuclear matrix and chromatin and that treatment with mitomycin C results in increase of the FA proteins in nuclear matrix and chromatin fractions. This induction occurs in wild-type cells and mutant FA-D (Fanconi complementation group D) cells but not in mutant FA-A cells. Immunoprecipitation of FancA protein in chromatin demonstrates the coprecipitation of FancA, FancC, and FancG, showing that the FA proteins move together as a complex. Also, fractionation of mitotic cells confirms the lack of FA proteins in chromatin or the nuclear matrix. Furthermore, phosphorylation of FancG was found to be temporally correlated with exit of the FA complex from chromosomes at mitosis. Taken together, these findings suggest a role for FA proteins in chromatin and nuclear matrix.     

DNA labeling in living cells.

BACKGROUND: Live cell fluorescence microscopy experiments often require visualization of the nucleus and the chromatin to determine the nuclear morphology or the localization of nuclear compartments. METHODS: We compared five different DNA dyes, TOPRO-3, TOTO-3, propidium iodide, Hoechst 33258, and DRAQ5, to test their usefulness in live cell experiments with continuous imaging and photobleaching in widefield epifluorescence and confocal laser scanning microscopy. In addition, we compared the DNA stainings with fluorescent histones as an independent fluorescent label to mark chromatin. RESULTS: From the dyes tested, only Hoechst and DRAQ5 could be used to stain DNA in living cells. However, DRAQ5 had several advantages, namely low photobleaching, labeling of the chromatin compartments comparable to that of H2B-GFP fusion proteins, and deep red excitation/emission compatible with available genetically encoded fluorescent proteins such as C/G/YFP or mRFP. CONCLUSIONS: The DNA dye DRAQ5 is well suited for chromatin visualization in living cells and can easily be combined with other fluorophores with blue to orange emission.     

Electron-radioautographic analysis of 3H-thymidine distribution in the cell nuclei of the Chinese hamster

Three types of the label localization in the nuclei of Chinese hamster fibroblasts, growing for 9 and 13 hours with 3H-thymidine, were detected using electron microscopic autoradiography: 1. The label is relatively evenly distributed throughout the karyoplasm. 2. Silver grains are concentrated as stripes through the nucleus; a high label density is also found in the nuclear periphery and around the nucleolus. 3. The label is mainly concentrated over the condensed chromatin adjacent to the nuclear membrane. The cells labeled in the first half of S-phase and selected with colchicine in postsynthetic phase of the 1st and the 2nd cycles are characterized by the second and third types of label distribution. In the cell nuclei fixed in the postsynthetic period of the second cycle, the label localization in stripes is discontinuous. The results indicate that during cell transition from S to G2 the newly-synthetized DNA changes its localization in the nucleus. It is suggested that the second type of label distribution depends on the interphase chromosome concentration in definite zones of the nuclear volume after S-phase termination, and the third type label localization is connected with the formation of prophase chromosomes.     

Aspects of Interaction of Putative Anchorosomal Protein p68 with the Nuclear Envelope during the Cell Cycle

In the interphase nucleus, the chromatin associated with the nuclear envelope is represented by a layer of anchorosomes, granules with a diameter of 20–25 nm. Biochemically, the fraction of chromatin directly associated with the nuclear envelope is characterized by resistance against decondensing influences, a low level of DNA methylation, and presence of specific acid-soluble proteins. However, the mechanisms lying at the base of chromatin-nuclear envelope interaction have been insufficiently studied. Specifically, it is unknown whether anchorosomes are constant structures or subject to reversible disassembly, when the contacts between chromatin and nuclear envelope are destroyed. We obtained immune serum recognizing a 68 kDa protein from the nuclear envelopes fraction and studied the localization of this protein in interphase and mitotic cells. We show that this protein, present in the NE/anchorosomal fraction, does not remain bound with chromosomes during mitosis. It dissociates from chromosomes at the beginning of the prophase and then can be identified again at the periphery of the newly forming nuclei in the telophase.     

应用HeLa细胞染色体(簇)和蛙卵提取物进行细胞核体外重建试验

将HeLa细胞中期染色体(簇)、非洲爪蟾卵提取物和ATP再生体系混合温育,能够促使细胞核自发重建。在此非细胞体系中重建的细胞核处于一般细胞核大小范围,具有典型的双层核膜,核孔复合体、染色质、核纤层、核骨架等结构,核重建具有一个明显的过程;发现环形片层通过与核膜融合方式参与核膜和核孔复合体组装。     

Nuclear and mitotically enhanced epitope.

Salt-extracted proteins of taxol-stabilized microtubules from Chinese hamster ovary cells arrested at mitosis were used to immunize mice for hybridoma production. From a group of related monoclonal antibodies (MAbs), one, C9, recognized an epitope on antigens localized by immunofluorescence microscopy to interphase centrosomes and nuclei. The availability of the nuclear antigen was cell cycle-dependent; however, permeabilization of cells before fixation revealed that the antigen was present throughout the cell cycle. The nuclear antigen was exposed during prophase and was released from the nucleus upon nuclear envelope breakdown filling the cytoplasm of the mitotic cell. Antigenic material re-accumulated at daughter nuclei and was concealed during G1 phase. Detergent extraction of the cytoplasmic antigen from mitotic cells enabled localization of antigens to centrosomes, kinetochores, and the furrowing region/midbody. Immunoblot analysis of cells of a variety of species of origin identified an approximate 250 kD polypeptide as corresponding to the nuclear antigen, whereas polypeptides of 107/117 kD as well as approximately 250 kD accounted for the mitotic cytoplasmic antigens. No polypeptides could be associated with antigens at centrosomes, kinetochores, or midbodies. This MAb joins the antibody preparations previously reported that describe nuclear antigens, or epitopes on antigens, enhanced at mitosis.     

Protein domains involved in nuclear transport of Fos.

The protein encoded by the proto-oncogene c-fos is constitutively nuclear in most cell types analyzed. It has a predicted molecular weight of about 55 kDa. Proteins with a molecular weight above 40 kDa cannot enter the nucleus passively. Our interest was to study which regions in the protein are involved in the nuclear transport. We prepared a series of deletions and point mutations of the protein and cloned the mutated genes into a eukaryotic expression vector. Cos-1 cells were used to express the mutants transiently. Using indirect immunofluorescence we studied the subcellular localization, analyzing the percentage of cells containing the protein in the nucleus, the cytoplasm, or both locations. Our studies showed that the Fos protein contains several regions which can act independently to translocate the protein into the nucleus.