The chromosome periphery during mitosis

A complex structure, visible by electron microscopy, surrounds each chromosome during mitosis. The organization of this structure is distinct from that of the chromosomes and the cytoplasm. It forms a perichromosomal layer that can be isolated together with the chromosomes. This layer covers the chromosomes except in centromeric regions. The perichromosomal layer includes nuclear and nucleolar proteins as well as ribonucleoproteins (RNPs). The list of proteins and RNAs identified includes nuclear matrix proteins (perichromin, peripherin), nucleolar proteins (perichro-monucleolin, Ki-67 antigen, B23 protein, fibrillarin, p103, p52), ribosomal proteins (S1) and snRNAs (U3 RNAs). Only limited information is available about how and when the perichromosomal layer is formed. During early prophase, the proteins extend from the nucleoli towards the periphery of the nucleus. Thin cordon-like structures reach the nuclear envelope delimiting areas in which chromosomes condense. At telophase, the proteins are associated with the part of the chromosomes remaining condensed and accumulate in newly formed nucleoli in regions where chromatin is already decondensed. The perichromosomal layer contains several different classes of proteins and RNPs and it has been attributed various roles: (1) in chromosome organization, (2) as a barrier around the chromosomes, (3) involvement in compartmentation of the cells in prophase and telophase and (4) a binding site for chromosomal passenger proteins necessary to the early process of nuclear assembly.     

Electron Microscopic Studies on the Silver-stained Nucleolar Cycle of Physarum polycephalum

The dynamic changes of nucleolar ultrastructure in the cell cycle of Physarum polycephalum Schw. were studied by an en bloc silver-staining method. The results showed that the nucleolus was large in size and situated in the center of the nucleus in late G2-phase, and the fibrillar centers, dense fibrillar components and granular components could be observed in the nucleolus. During prophase, the nucleolus moved towards the periphery of the nucleus and in late prophase disintegrated near the nuclear envelope. In metaphase, the disintegrated nucleolar components were dispersed in masses and located at the periphery of the chromosomal region of the nucleus. No specifically silver-stained area and argentophilic protein sheath were observed on the chromosomes, but there were some big dispersed silver particles within the chromosomes. During telophase the nucleolar components moved towards the two poles along with the chromosomes and co-existed with the decondensing chromatin in daughter nuclei. The nucleolar components then gradually converged with one another and separated from the chromatin. A big nucleolus was formed in the nucleus about 120 min after the completion of mitosis.     

Identification and characterization of a new set of nucleolar ribonucleoproteins which line the chromosomes during mitosis.

We investigated the perichromosomal architecture established during mitosis. Entry into mitosis brings about a dramatic reorganization of both nuclear and cytoplasmic structures in preparation for cell division. While the nuclear envelope breaks down, nuclear proteins are redistributed during chromosome condensation. Some of these proteins are found around the chromosomes, but little is known concerning their nature and function. Ten autoimmune sera were used to study the microenvironment of chromosomes and, in particular, the chromosome periphery. They were selected for their anti-nucleolar specificity and were found to recognize three nucleolar proteins that coat the chromosomes during mitosis. The distribution of these antigens was followed through the cell cycle by confocal laser scanning microscopy. The antigens dispersed very early during prophase and simultaneously with the chromosome condensation suggesting a correlation between these two processes. The antigens have apparent molecular weights of 53, 66, and 103 kDa on SDS-PAGE migration. Elution of the antibodies and immunopurification showed that they are RNA-associated proteins. The coimmunoprecipitating RNA moiety involved in these RNPs appeared to be U3, but the antigens are not related to the fibrillarin family. Therefore, small nucleolar RNPs follow the same distribution during mitosis as that described for small nuclear RNPs. Possible functions for these antigens are discussed.     

Differential chromosomal radiosensitivity within the first G1-phase of the cell cycle of early-dividing human leukocytes in vitro after stimulation with PHA

Summary Human leukocyte cultures were irradiated with 200 R X-rays before the addition of phytohemagglutinin (PHA) in the G₀-stage and at different times up to 25 h within the first G₁-phase of the cell cyle after the addition of PHA. The results of the analysis of chromosomal aberrations show that the frequencies of dicentric chromosomes increase significantly when leukocytes leave the G₀-stage, reaching a maximum yield of aberrations about halfway through the first G₁-phase. After that, toward the end of the G₁-phase, the frequencies of dicentric chromosomes decrease again, to a level similar to that found in the G₀-stage. Different possible explanations for the differential chromosomal radiosensitivity of human leukocytes within the first poststimulation G₁-phase are discussed.     

Nuclear matrix proteins (with molecular masses of 38 and 50 kDa) are transported by chromosomes in mitosis

Using the immunofluorescence method, sera M-68 and K-43 from patients with autoimmune diseases were shown to stain interphase nuclei and the periphery of mitotic chromosomes of pig embryo kidney cells. Western blotting revealed a polypeptide with a molecular mass of 50 kDa in M-68 serum and polypeptide with a molecular mass 38 kDa in K-43 serum. In the nuclear protein matrix, the antibodies to protein with a molecular mass of 38 kDa stained only the nucleolar periphery, while the antibodies to protein with a molecular mass of 50 kDa stained not only the nucleolar periphery, but also all interphase nuclei. It was shown that, among all components of the nuclear protein matrix (lamina, internuclear network, residual nucleoli), only the nucleolar periphery contained the 38-kDa protein, while the 50-kDa protein was part of the residual nucleolar periphery and participated in the formation of a nuclear-protein network. Both proteins in interphase cell in situ were located in nuclei, but one of them with a molecular mass of 50 kDa was in the form of small, clearly outlined granules, while the other protein (38 kDa) was in the form of small, bright granules on a background of a diffusely stained nucleus. Both proteins also were revealed as a continuous rim around the nucleolar periphery. During all mitotic stages, the 50-kDa protein was seen over the whole chromosomal periphery as a sheath, while the 38-kDa protein formed individual fragments and granules around them. After the decondensation of the nucleus and chromosomes induced by hypotonic treatment, both antibodies stained interphase nuclei diffusely, whereas, in mitotic cells, they stained the surfaces of swollen chromosomes. Polypeptide with a molecular mass of 50 kDa maintained a strong connection with the periphery of the chromosome in the norm during decondensation induced by hypotonic treatment and during subsequent recondensation in isotonic medium, while, during recondensation, protein with a molecular mass of 38 kDa partially lost contact with the chromosome and, at the same time, appeared in the form of granules in the cytoplasm. The obtained data allow one to conclude that nuclear matrix proteins can be transferred with peripheral chromosomal material; similar to the main nucleolar proteins (fibrillarin, B-23, nucleolin, et al.) and some non-nucleolar components of the nuclear protein matrix, they can also have connections of different stabilities with chromosomal periphery.     

Ultrastructural Features of Mitosis in Anisonema sp. (Euglenida)1

The fine structure of stages in mitosis in a colorless euglenoid, Anisonema sp., reveals that chromosomes remain condensed throughout the life cycle and are attached to the nuclear envelope at interphase. The onset of mitosis is marked by the anterior migration of the nucleus towards the base of the reservoir and by elongation of the nucleolus. The nuclear envelope persists throughout mitosis. Microtubules are generated in the peripheral nucleoplasm adjacent to the envelope and attach to the chromosomes while they are still associated with the envelope. The region of microtubular contact develops into a distinct layered kinetochore as the developing spindle with attached chromosomes separates from the nuclear envelope and moves into the nucleoplasm. The mature spindle consists of a number of subspindles each containing about 8–10 microtubules and a few associated chromosomes. Both chromosomal and non-chromosomal microtubules are present in each subspindle and extend towards the envelope terminating at or near the nuclear pores. Chromosomal segregation is concomitant with nuclear elongation. By late division, an interzonal spindle develops in the dumbbell-shaped nucleus and nucleolar separation occurs. Continued invagination of the nuclear envelope in the region of the interzonal spindle eventually separates the daughter nuclei. A remnant of the interzonal spindle persists in the cytoplasm until cytokinesis.     

NuMA: an unusually long coiled-coil related protein in the mammalian nucleus

A bank of 892 autoimmune sera was screened by indirect immunofluorescence on mammalian cells. Six sera were identified that recognize an antigen(s) with a cell cycle-dependent localization pattern. In interphase cells, the antibodies stained the nucleus and in mitotic cells the spindle apparatus was recognized. Immunological criteria indicate that the antigen recognized by at least one of these sera corresponds to a previously identified protein called the nuclear mitotic apparatus protein (NuMA). A cDNA which partially encodes NuMA was cloned from a lambda gt11 human placental cDNA expression library, and overlapping cDNA clones that encode the entire gene were isolated. DNA sequence analysis of the clones has identified a long open reading frame capable of encoding a protein of 238 kD. Analysis of the predicted protein sequence suggests that NuMA contains an unusually large central alpha-helical domain of 1,485 amino acids flanked by nonhelical terminal domains. The central domain is similar to coiled-coil regions in structural proteins such as myosin heavy chains, cytokeratins, and nuclear lamins which are capable of forming filaments. Double immunofluorescence experiments performed with anti-NuMA and antilamin antibodies indicate that NuMA dissociates from condensing chromosomes during early prophase, before the complete disintegration of the nuclear lamina. As mitosis progresses, NuMA reassociates with telophase chromosomes very early during nuclear reformation, before substantial accumulation of lamins on chromosomal surfaces is evident. These results indicate that the NuMA proteins may be a structural component of the nucleus and may be involved in the early steps of nuclear reformation during telophase.     

NUCLEAR ENVELOPE-ASSOCIATED RESUMPTION OF RNA SYNTHESIS IN LATE MITOSIS OF HELA CELLS

The restitution of RNA synthesis in cultures progressing from metaphase into interphase (G₁) has been investigated in synchronized HeLa S₃ cells by using inhibitors of macro-molecular synthesis and the technique of electron microscope autoradiography. The rate of incorporation of radioactive uridine into RNA approached interphase levels in the absence of renewed protein synthesis. In contrast, maintenance of this rate in G₁ was dependent upon renewed protein synthesis. Restoration of synthesis of heterogeneous nuclear RNA occurred under conditions that inhibited production of ribosomal precursor RNA. In autoradiographs of individual cells exposed to radioactive uridine, silver grains were first detected after nuclear envelope reformation at the periphery of the chromosome mass but before chromosomal decondensation. These data are consistent with the following interpretation. Multiple RNA polymerase activities persist through mitosis and are involved in the initiation of RNA synthesis in early telophase at sites on the nuclear envelope.     

Mitosis in the Hemoflagellate Trypanosoma cyclops*

SYNOPSIS. The ultrastructure of interphase and mitotic nuclei of the epimastigote form of Trypanosoma cyclops Weinman is described. In the interphase nucleus the nucleolus is located centrally while at the periphery of the nucleus condensed chromatin is in contact with the nuclear envelope. The nucleolus fragments at the onset of mitosis, but granular material of presumptive nucleolar origin is often recognizable in the mitotic nucleus. Peripheral chromatin is in contact with the nuclear envelope throughout mitosis, and it seems reasonable to assume that the nuclear envelope is involved in its segregation to the daughter nuclei. Spindle microtubules extend between the poles of the dividing nucleus and terminate close to the nuclear envelope. The basal body and kinetoplast divide before the onset of mitosis and do not appear to have any morphologic involvement in that process. Spindle pole bodies, kinetochores, and chromosomal microtubules have not been observed.     

RNA B is the major nucleolar trimethylguanosine-capped small nuclear RNA associated with fibrillarin and pre-rRNAs in Trypanosoma brucei.

RNA B is one of three abundant trimethylguanosine-capped U small nuclear RNAs (snRNAs) of Trypanosoma brucei which is not strongly identified with other U snRNAs by sequence homology. We show here that RNA B is a highly diverged U3 snRNA homolog likely involved in pre-rRNA processing. Sequence identity between RNA B and U3 snRNAs is limited; only two of four boxes of homology conserved between U3 snRNAs are obvious in RNA B. These are the box A homology, specific for U3 snRNAs, and the box C homology, common to nucleolar snRNAs and required for association with the nucleolar protein, fibrillarin. A 35-kDa T. brucei fibrillarin homolog was identified by using an anti-Physarum fibrillarin monoclonal antibody. RNA B and fibrillarin were localized in nucleolar fractions of the nucleus which contained pre-rRNAs and did not contain nucleoplasmic snRNAs. Fibrillarin and RNA B were precipitated by scleroderma patient serum S4, which reacts with fibrillarins from diverse organisms; RNA B was the only trimethylguanosine-capped RNA precipitated. Furthermore, RNA B sedimented with pre-rRNAs in nondenaturing sucrose gradients, similarly to U3 and other nucleolar snRNAs, suggesting that RNA B is hydrogen bonded to rRNA intermediates and might be involved in their processing.     

Chromosomes initiate spindle assembly upon experimental dissolution of the nuclear envelope in grasshopper spermatocytes

Chromosomes are known to enhance spindle microtubule assembly in grasshopper spermatocytes, which suggested to us that chromosomes might play an essential role in the initiation of spindle formation. Chromosomes might, for example, activate other spindle components such as centrosomes and tubulin subunits upon the breakdown of the nuclear envelope. We tested this possibility in living grasshopper spermatocytes. We ruptured the nuclear envelope during prophase, which prematurely exposed the centrosomes to chromosomes and nuclear sap. Spindle assembly was promptly initiated. In contrast, assembly of the spindle was completely inhibited if the nucleus was mechanically removed from a late prophase cell. Other experiments showed that the trigger for spindle assembly is associated with the chromosomes; other constituents of the nucleus cannot initiate spindle assembly in the absence of the chromosomes. The initiation of spindle assembly required centrosomes as well as chromosomes. Extracting centrosomes from late prophase cells completely inhibited spindle assembly after dissolution of the nuclear envelope. We conclude that the normal formation of a bipolar spindle in grasshopper spermatocytes is regulated by chromosomes. A possible explanation is an activator, perhaps a chromosomal protein (Yeo, J.-P., F. Alderuccio, and B.-H. Toh. 1994a. Nature (Lond.). 367: 288-291), that promotes and stabilizes the assembly of astral microtubules and thus promotes assembly of the spindle.     

ULTRASTRUCTURE OF THE NUCLEOLUS DURING THE CHINESE HAMSTER CELL CYCLE

Changes in the structure of the nucleolus during the cell cycle of the Chinese hamster cell in vitro were studied. Quantitative electron microscopic techniques were used to establish the size and volume changes in nucleolar structures. In mitosis, nucleolar remnants, "persistent nucleoli," consisting predominantly of ribosome-like granular material, and a granular coating on the chromosomes were observed. Persistent nucleoli were also observed in some daughter nuclei as they were leaving telophase and entering G₁. During very early G₁, a dense, fibrous material characteristic of interphase nucleoli was noted in the nucleoplasm of the cells. As the cells progressed through G₁, a granular component appeared which was intimately associated with the fibrous material. By the middle of G₁, complete, mature nucleoli were present. The nucleolar volume enlarged by a factor of two from the beginning of G₁ to the middle of S primarily due to the accumulation of the granular component. During the G₂ period, there was a dissolution or breakdown of the nucleolus prior to the entry of the cells into mitosis. Correlations between the quantitative aspects of this study and biochemical and cytochemical data available in the literature suggest the following: nucleolar reformation following division results from the activation of the nucleolar organizer regions which transcribe for RNA first appearing in association with protein as a fibrous component (45S RNA) and then later as a granular component (28S and 32S RNA).     

Centrosome-kinetochore interaction in multinucleate cells

The interaction between centrosomes and kinetochores was studied in multinucleate cells induced by Colcemid treatment or by random cell fusion. Except for prematurely condensed chromosomes (PCC) of the G₂-phase, PCCs do not develop their own spindle area. Perhaps the maturation promoting factor (MPF) fails to activate these centrosomes. In such PCCs, the kinetochore-centrosome interaction was found to be non-specific: sometimes only a few chromosomes of a group could establish connections with centrosomes, sometimes chromosomes from the same PCC group developed microtubule (MT) attachment with different centrosomes (not the pair), and sometimes kinetochores of PCC groups failed to interact with MTs. These findings explain the abnormal mitotic behaviour of PCCs as seen in the light microscope. These PCCs develop micronuclei or normal nuclei by nuclear re-formation in telophase. All the different PCC groups revealed kinetochores with kinetochore plates. It was shown that transformation of presumptive kinetochores to a trilaminar kinetochore does not depend on nuclear envelope breakdown or on the degree of chromosome condensation. This may be induced by the MPF which may initiate different events like chromosome condensation, nuclear envelope breakdown and kinetochore transformation by secondary factors. Other observations like establishment of connections by different chromosome groups to a common centrosome, kinetochore attachment of PCCs to different centrosomes, interaction of one kinetochore with two centrosomes, kinetochores being stretched and bent to receive microtubules and finally the failure of some kinetochores to develop MT attachment, all strongly suggest that the kinetochores serve as the point of termination rather than the nucleation sites of kinetochore MTs.     

Subcellular recruitment of fibrillarin to nucleoplasmic proteasomes: implications for processing of a nucleolar autoantigen

A prerequisite for proteins to interact in a cell is that they are present in the same intracellular compartment. Although it is generally accepted that proteasomes occur in both, the cytoplasm and the nucleus, research has been focusing on cytoplasmic protein breakdown and antigen processing, respectively. Thus, little is known on the functional organization of the proteasome in the nucleus. Here we report that within the nucleus 20S and 26S proteasomes occur throughout the nucleoplasm and partially colocalize with splicing factor-containing speckles. Because proteasomes are absent from the nucleolus, a recruitment system was used to analyze the molecular fate of nucleolar protein fibrillarin: Subtoxic concentrations of mercuric chloride (HgCl(2)) induce subcellular redistribution of fibrillarin and substantial colocalization (33%) with nucleoplasmic proteasomes in different cell lines and in primary cells isolated from mercury-treated mice. Accumulation of fibrillarin and fibrillarin-ubiquitin conjugates in lactacystin-treated cells suggests that proteasome-dependent processing of this autoantigen occurs upon mercury induction. The latter observation might constitute the cell biological basis of autoimmune responses that specifically target fibrillarin in mercury-mouse models and scleroderma.     

Study on oocyte maturation and activation of the common prawn palaemon serratus (Pennant): Relationship between oocyte maturation and the molt cycle cytological aspects

A detailed chronology of the cytological events related to maturation that take place within the reproduction molt cycle has been established. It has been shown that oocytes, initially arrested at prophase I, resume meiosis when approaching stage D₁? of the molt cycle, ie, 4–5 days before molting. The following steps characterize this premolt period of oocyte maturation: nuclear envelope folding, nucleolar dissociation, condensation of the chromosomes, and beginning of the breakdown of the nuclear envelope (GVBD). At the ultrastructural level, it has been confirmed that GVBD actually takes place at the D₁??D₂ stage transition, when the germinal vesicle still occupies a central position in the oocyte. The migration of the chromosome takes only a few hours and begins approximately 4 hr before molting. It is only 1–2 hr before molting that the divalent chromosomes that are not yet organized in a metaphase plate become visible at the surface of the oocyte. They lay in a nucleoplasmic area no longer limited by the nuclear envelope. Metaphase I is reached a few minutes after molting. A second meiotic block appears at this stage, which persists until spawning, ie, for about 24 hr. Fertilization occurs at the moment of spawning. In vitro fertilization experiments demonstrated that fertilization normally triggers the release of the second meiotic block. Extrusion of the two polar bodies can be easily observed using a method for clearing and staining the oocytes in toto.     

The nucleoli matrix proteins with molecular masses 40 and 27 kDa are transported as peripheral chromosomal material

Using immunofluoresence method, sera M-311 and K-30 obtained from patients with autoimmune disease were shown to stain interphase nuclei and the periphery of chromosomes. Western blotting revealed a polypeptide with mol. mass 27 kDa in serum K-30. Both proteins were localized in the karyoplasm. One of them (27 kDa) has a diffuse form and contains small granules, while the other (40 kDa) is in the form of small clearly outlined granules. Both proteins are also revealed around the nucleolar periphery, making a continental ring, while the main part of the nucleolus remains unstained. During pro- and metaphase, these proteins were associated with the chromosomal periphery: 27 kDa protein formed separate groups, and 40 kDa protein was seen over the whole chromosomal periphery. After nuclear and chromosomal decondensation, induced by hypotonic treatment (15% of culture medium solution), both antibodies stain diffusively interphase nuclei, but in mitotic cells they stained the surface of the swollen chromosomes. After chromatin recondensation in isotonic medium these proteins were localized similarly as in normal cells. Thus, both proteins maintained their association with the periphery of chromosomes. To reveal the nuclear protein matrix, cells were treated with 2M NaCl, DNAase and RNAase A. After this procedure, the antibodies stained only the nucleolar periphery, and no fluorescence in the karyoplasm was seen. It shows that of all the components of the nuclear protein matrix (lamina, internuclear network, residual nucleoli) only 27 and 40 kDa proteins are contained in the nucleolar rim. The data allow to suggest that the nucleolar matrix proteins may be transported to new cell nuclei as part of the peripheral chromosomal material likely as other nucleolar (fibrillarin, B-23, and others) or some non-nuclear components of the nuclear protein matrix are transported.     

The perinuclear microtubule-organizing center and the synaptonemal complex of higher plants share a common antigen: its putative transfer and role in meiotic chromosomal ordering

Recognition of homologous chromosomes during meiotic prophase is associated in most cases with the formation of the synaptonemal complex along the length of the chromosome. Telomeres, located at the nuclear periphery, are preferential initiation sites for the assembly of the synaptonemal complex. In most eukaryotic cells, telomeres cluster in a restricted area, leading to the bouquet configuration in leptotene-zygotene, while this typical organization progressively disappears in late zygotene-pachytene. We wondered whether such striking changes in the intranuclear ordering and pairing of meiotic chromosomes during the progression of prophase I could be correlated with activity of the centrosome and/or microtubule-organizing center (MTOC). Plant cells may be used as a model of special interest for this study as the whole nuclear surface acts as an MTOC, unlike other cell types where MTOCs are restricted to centrosomes or spindle pole bodies. Using a monoclonal antibody (mAb 6C6) raised against isolated calf centrosomes we found that the 6C6 antigen is present over the entire surface of the plant meiotic nucleus, in early prophase I, before chromosomal pairing. At zygotene, short fragments of chromosomes become stained near the nuclear envelope and within the nucleus. At pachytene, after complete synapsis, the labeling specifically concentrates within the synaptonemal complexes, although the nuclear surface is no longer reactive. Ultrastructural localization using immunogold labeling indicates that the 6C6 antigen is colocalized with the synaptonemal complex structures. Later in metaphase I, the antigen is found at the kinetochores. Our data favor the idea that the 6C6 antigen may function as a particular chromosomal passenger-like protein. These observations shed new light on the molecular organization of the plant synaptonemal complex and on the redistribution of cytoskeleton-related antigens during initiation of meiosis. They suggest that antigens of MTOCs are relocated to chromosomes during the synapsis process starting at telomeres and contribute to the spatial arrangement of meiotic chromosomes. Such cytoskeleton-related antigens may acquire different functions depending on their localization, which is cell-cycle regulated.     

Entry into Mitosis in Vertebrate Somatic Cells Is Guarded by a Chromosome Damage Checkpoint That Reverses the Cell Cycle When Triggered during Early but Not Late Prophase

When vertebrate somatic cells are selectively irradiated in the nucleus during late prophase (<30 min before nuclear envelope breakdown) they progress normally through mitosis even if they contain broken chromosomes. However, if early prophase nuclei are similarly irradiated, chromosome condensation is reversed and the cells return to interphase. Thus, the G₂ checkpoint that prevents entry into mitosis in response to nuclear damage ceases to function in late prophase. If one nucleus in a cell containing two early prophase nuclei is selectively irradiated, both return to interphase, and prophase cells that have been induced to returned to interphase retain a normal cytoplasmic microtubule complex. Thus, damage to an early prophase nucleus is converted into a signal that not only reverses the nuclear events of prophase, but this signal also enters the cytoplasm where it inhibits e.g., centrosome maturation and the formation of asters. Immunofluorescent analyses reveal that the irradiation-induced reversion of prophase is correlated with the dephosphorylation of histone H1, histone H3, and the MPM2 epitopes. Together, these data reveal that a checkpoint control exists in early but not late prophase in vertebrate cells that, when triggered, reverses the cell cycle by apparently downregulating existing cyclin-dependent kinase (CDK1) activity.     

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.     

On the cell-free association of lamins A and C with metaphase chromosomes

Nuclear envelopes have previously been shown to assemble spontaneously around endogenous chromosomes in cell-free homogenates of mitotic Chinese hamster ovary cells. In order to further analyze the mechanisms underlying nuclear envelope reformation and the functions of the individual nuclear lamin polypeptides, a fractionated cell-free nuclear envelope reassembly system involving purified chromosomes and either a postchromosomal supernatant or a cytosol fraction from mitotic cells has been devised. Results obtained with this fractionated system show that lamins A and C will associate with the surfaces of chromosomes in the absence of lamin B and membranes, this association being inhibitable by ATP-gamma-S. However, in the absence of membranes chromatin decondensation never occurs. Using the reversible swelling of chromosomes in low ionic strength buffers lacking divalent cations as the basis of a simple assay, it is demonstrated that the association of lamins A and C with the surfaces of chromosomes has a pronounced and easily observable effect on chromatin organization.