PROPHASING OF INTERPHASE NUCLEI AND INDUCTION OF NUCLEAR ENVELOPES AROUND METAPHASE CHROMOSOMES IN HELA AND CHINESE HAMSTER HOMO- AND HETEROKARYONS

Fusing human HeLa metaphase cells with HeLa interphase cells resulted within 30 min in either of two phenomena in the resultant binucleate cell: either prophasing of the interphase nucleus or formation of a normal-appearing nuclear envelope around the metaphase chromosomes. The frequency of either occurrence was strongly dependent on environmental pH. At pH's of 6.6–8.0, prophasing predominated; at pH 8.5 nuclear envelope formation predominated. Additionally, the frequencies of the two events in multinucleate cells depended on the metaphase/interphase ratio. When the ratio was 0.33 nuclear envelope formation predominated; when it was 2.0 prophasing predominated. In their general features, the results with fused HeLa cells resembled those reported earlier with fused Chinese hamster Don cells. However, the results provided an indication that between pH 6.6 and 8.0 the HeLa metaphase cells possessed a much greater capacity than the Don metaphase cells to induce prophasing. Fusion of Don metaphase cells with HeLa interphase cells or of Don interphase cells with HeLa metaphase cells at pH 8.0 resulted in nuclear envelope formation or prophasing in each kind of heterokaryon. As in the homokaryons, the frequencies of the two events in the heterokaryons depended on the metaphase/interphase ratio. The statistics of prophasing and nuclear envelope formation in the homo- and heterokaryon populations were consistent with the notion that disruption or formation of the nuclear envelope depends on the balance attained between disruptive and formative processes.     

Detection by means of cell fusion of macromolecular synthesis involved in the reconstruction of the nuclear envelope in mitosis

Using the cultured Chinese hamster cell line Don, G1 or S or a mixture of late-S/G2 cells were prepared by release from metaphase arrest. Metaphase (M) cells were also obtained by mitotic arrest of log-phase cultures with Colcemid and held in metaphase; such M cells remained untreated with any other compound and were termed standard M cells. When interphase (I) cells were fused at pH 8.0 and 37 degrees C with standard cells in the presence of Colcemid by means of UV-inactivated Sendai virus, binucleate interphase-metaphase (I-M) cells were obtained. In a given I-M cell there occurred within 30 min after fusion either prophasing of the I nucleus or formation of a nuclear envelope (NE) around the chromosomes. About 20% of early G1 cells, 35% of cells at the G1/S boundary, 50% of S cells, and 70% of late S/G2 cells could induce NE formation. If, before fusion, cycloheximide (CHE), an inhibitor of protein synthesis, was present during release from M arrest, the cells entered G1 but not S. About 20% of such early G1 cells, like the untreated early G1 cells, had the capacity to induce NE formation during subsequent fusion. If the cells were blocked in S with 5 mM thymidine (TdR), At least 80% of these cells could induce NE formation during subsequent fusion, but in the presence of both TdR and CHE only 35% could do so. It appeared, therefore, that protein synthesis in interphase was required for NE formation. Experiments with actinomycin D indicated that RNA synthesis was also necessary for acquisition of NE-inducing capacity. About 35% of G1 cells from confluent monolayers had the NE-inducing capacity, but prolonged exposure to CHE reduced their number to 8% . Removal of CHE restored the ability while the cells still remained in G1. This result indicated that continuing protein synthesis in the G1 cell was needed for NE formation subsequent to fusion. The fact that macromolecular synthesis must occur in the I cell before fusion if NE formation was to occur in the fused I-M cell lends further support to evidence adduced earlier that this phenomenon is a normal mitotic event. Prophasing of the I nucleus in I-M cells did not appear to be dependent on macromolecular synthesis in the I cell; earlier results from this laboratory showed, however, that protein synthesis in the prior G2 period of the M cell of the I-M pair was required for prophasing.     

Some comments regarding chromosome pulverization (premature chromosome condensation or PCC, prophasing).

Premature chromosome pulverization (PCC) or prophasing is a much misunderstood cytological entity. It must be separated from chromosome damage caused by a number of chemical, physical and biological agents. Prophasing is observed in fused cells in which one of the constituent cells must be in metaphase and another in interphase. The morphology of the "pulverized" interphase nucleus will depend on the phase of the cell cycle in which the interphase cell was in when exposed to a substance present in the cytoplasm of the metaphase cell leading to "prophasing". Prophasing is a normal cellular phenomenon occurring prematurely or under abnormal conditions (fusion of cells) and its demonstration in human cells or tumors may be indicative of the presence of a virus (or its products) which leads to cell fusion, but does not play a role in prophasing.     

INDUCTION OF PROPHASE IN INTERPHASE NUCLEI BY FUSION WITH METAPHASE CELLS

Fusion of an interphase cell with a metaphase cell results in profound changes in the interphase chromatin that have been called "chromosome pulverization" or "premature chromosome condensation" In addition to the usual light microscopy, the nature of the changes has been investigated in the present study with electron microscopy and biochemical techniques Metaphase and interphase cells were mixed and fused at 37°C by means of ultraviolet-inactivated Sendai virus. After cell fusion, morphological changes in interphase nuclei occurred only in binucleate cells which contained one intact set of metaphase chromosomes Irrespective of the nuclear stage at the time of cell fusion, the morphologic changes that occurred 5–20 min later simulated very closely a sequence of events that characterizes the normal G₂-prophase transition. Radioautography revealed that, late in the process, substantial amounts of RNA and probably protein were transferred from the interphase nucleus into the cytoplasm of fused cells. Thus, the findings indicate the existence in metaphase cells of factor(s) which are capable of initiating biochemical and morphological events in interphase nuclei intrinsic to the normal mitotic process.     

Nuclear Membrane Dynamics and Reassembly in Living Cells: Targeting of an Inner Nuclear Membrane Protein in Interphase and Mitosis

The mechanisms of localization and retention of membrane proteins in the inner nuclear membrane and the fate of this membrane system during mitosis were studied in living cells using the inner nuclear membrane protein, lamin B receptor, fused to green fluorescent protein (LBR–GFP). Photobleaching techniques revealed the majority of LBR–GFP to be completely immobilized in the nuclear envelope (NE) of interphase cells, suggesting a tight binding to heterochromatin and/or lamins. A subpopulation of LBR–GFP within ER membranes, by contrast, was entirely mobile and diffused rapidly and freely (D = 0.41 ± 0.1 μm²/s). High resolution confocal time-lapse imaging in mitotic cells revealed LBR–GFP redistributing into the interconnected ER membrane system in prometaphase, exhibiting the same high mobility and diffusion constant as observed in interphase ER membranes. LBR–GFP rapidly diffused across the cell within the membrane network defined by the ER, suggesting the integrity of the ER was maintained in mitosis, with little or no fragmentation and vesiculation. At the end of mitosis, nuclear membrane reformation coincided with immobilization of LBR–GFP in ER elements at contact sites with chromatin. LBR–GFP–containing ER membranes then wrapped around chromatin over the course of 2–3 min, quickly and efficiently compartmentalizing nuclear material. Expansion of the NE followed over the course of 30–80 min. Thus, selective changes in lateral mobility of LBR–GFP within the ER/NE membrane system form the basis for its localization to the inner nuclear membrane during interphase. Such changes, rather than vesiculation mechanisms, also underlie the redistribution of this molecule during NE disassembly and reformation in mitosis.     

Requirement for Lamin B Receptor and Its Regulation by Importin β and Phosphorylation in Nuclear Envelope Assembly during Mitotic Exit

Lamin B receptor (LBR), a chromatin and lamin B-binding protein in the inner nuclear membrane, has been proposed to target the membrane precursor vesicles to chromatin mediated by importin β during the nuclear envelope (NE) assembly. However, the mechanisms for the binding of LBR with importin β and the membrane targeting by LBR in NE assembly remain largely unknown. In this report, we show that the amino acids (aa) 69–90 of LBR sequences are required to bind with importin β at aa 45–462, and the binding is essential for the NE membrane precursor vesicle targeting to the chromatin during the NE assembly at the end of mitosis. We also show that this binding is cell cycle-regulated and dependent on the phosphorylation of LBR Ser-71 by p34^cdc2 kinase. RNAi knockdown of LBR causes the NE assembly failure and abnormal chromatin decondensation of the daughter cell nuclei, leading to the daughter cell death at early G₁ phase by apoptosis. Perturbation of the interaction of LBR with importin β by deleting the LBR N-terminal spanning region or aa 69–73 also induces the NE assembly failure, the abnormal chromatin decondensation, and the daughter cell death. The first transmembrane domain of LBR promotes the NE production and expansion, because overexpressing this domain is sufficient to induce membrane overproduction of the NE. Thus, these results demonstrate that LBR targets the membrane precursor vesicles to chromatin by interacting with importin β in a LBR phosphorylation-dependent manner during the NE assembly at the end of mitosis and that the first transmembrane domain of LBR promotes the LBR-bearing membrane production and the NE expansion in interphase.     

Nuclear lamins during prophasing and telophasing in heterophasic HeLa and Chinese hamster homokaryons

We have perturbed the dynamics of the nuclear lamins by means of cell fusion between mitotic and interphase cells and have studied redistribution of lamins in fused cells as a function of extracellular pH levels. We show here that in heterophasic M-1 HeLa homokaryons disassembly of interphase lamins predominates at low pH levels between 7.0 to 7.3, whereas deposition of cytoplasmic lamins around condensed metaphase chromosomes was observed at pH 8.0. In HeLa homokaryons lamina disassembly and lamina deposition around chromosomes are mutually exclusive. Using heterophasic M-1 homokaryons of the Chinese hamster cell line DON we observed that disassembly of interphase lamins and deposition of lamins around condensed chromosomes coexisted in the same homokaryon kept at pH 7.0. Disassembly of lamins developed synchronously with premature chromosome condensation (PCC) whereas lamina deposition around the condensed M-chromosomes was followed by telophasing. In fusions kept at pH 8.0 cytoplasmic lamins were exclusively deposited around mitotic chromosomes. The results are interpreted as showing that pH regulates the lamina dynamics in homokaryons of mitotic and interphase cells.     

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.     

Early chromosome condensation without cell fusion. I. Preliminary results with allogeneic and xenogeneic cells.

Early chromatin condensation in interphase cells (G1) of human peripheral blood lymphocytes has been induced without virus or cell fusion by exposure to allogeneic or xenogeneic mitotic cells. The event, although similar in some ways to the phenomenon described as "premature chromosome condensation," "chromosome pulverization," and "prophasing," differs in that it does not require the presence of viruses and cell fusion before mitosis proceeds in the G1 cell. Early chromatin condensation in interphase cells induced by mitotic cells only, consists of chromatids in the early or late G1 phase of the cell cycle that are not pulverized or fragmented at mitosis. Some of the chromosomes are twice as long as the metaphase chromosomes and exhibit natural bands. Almost twice as many of these bands are produced as by trypsin treatment of metaphase chromosomes. The nuclear membrane is intact and nucleoli are present, to which some chromosomes are attached. The DNA content of the precocious chromosomes in G1 is half the amount of the metaphase complement.     

CELL CYCLE-SPECIFIC CHANGES IN HISTONE PHOSPHORYLATION ASSOCIATED WITH CELL PROLIFERATION AND CHROMOSOME CONDENSATION

Preparative polyacrylamide gel electrophoresis was used to examine histone phosphorylation in synchronized Chinese hamster cells (line CHO). Results showed that histone f1 phosphorylation, absent in G₁-arrested and early G₁-traversing cells, commences 2 h before entry of traversing cells into the S phase. It is concluded that f1 phosphorylation is one of the earliest biochemical events associated with conversion of nonproliferating cells to proliferating cells occurring on old f1 before synthesis of new f1 during the S phase. Results also showed that f3 and a subfraction of f1 were rapidly phosphorylated only during the time when cells were crossing the G₂/M boundary and traversing prophase. Since these phosphorylation events do not occur in G₁, S, or G₂ and are reduced greatly in metaphase, it is concluded that these two specific phosphorylation events are involved with condensation of interphase chromatin into mitotic chromosomes. This conclusion is supported by loss of prelabeled ³²PO₄ from those specific histone fractions during transition of metaphase cells into interphase G₁ cells. A model of the relationship of histone phosphorylation to the cell cycle is presented which suggests involvement of f1 phosphorylation in chromatin structural changes associated with a continuous interphase "chromosome cycle" which culminates at mitosis with an f3 and f1 phosphorylation-mediated chromosome condensation.     

Telomere erosion-induced mitotic catastrophe in continuously grown chinese hamster don cells

We have previously reported that telomere erosion is the earliest chromatin modification in cells entering the apoptotic pathway. The purpose of this investigation was to determine whether loss of telomeric DNA was involved in inducing mitotic catastrophe and death in Chinese hamster Don cells. Don, a male Chinese hamster-derived cell line which requires daily subculturing to remain diploid, was grown without subculturing for 1-4 days at 37 degrees C and analyzed cytologically. Our results indicated that (1) the frequency of metaphase chromosomes with structural anomalies was significantly higher in 3-day continuously grown cells than in 1-day control cells (8.2% vs 5.7%; P < 0.01), (2) the mitotic index was considerably lower in 3-day continuously grown cells (0.13%) than in control cells (3.64%), (3) cells grown for 3 days continuously showed a higher incidence (7.6%) of endoreduplicated metaphase chromosomes than did control cells (4.9%), (4) 4-day continuously grown Don cells showed significantly smaller amounts of telomeric DNA in interphase nuclei than did control cells, and (5) apoptotic cells were more frequent in 4-day cell cultures (40.6%) than in control cells (4.3%). These results support our earlier observations and contribute additional support for our hypothesis that telomere reduction is the cause of mitotic catastrophe and that cell death in continuously grown Don cells occurs because of the loss of telomeric DNA.     

Comparative studies on the structural organization of membrane-depleted nuclei and metaphase chromosomes

Interphase membrane-depleted nuclei and metaphase chromosomes were prepared in parallel with a nonionic detergent lysis procedure at low ionic strength. By flow microfluorometry we showed for the first time that cell lysates contain all stages of the cell cycle in the same proportions as the starting cell population. Morphologically intact membrane-depleted nuclei and metaphase chromosomes were isolated as non-aggregated structures on sucrose gradients. When analysed in the electron microscope, membrane-depleted nuclei that had been treated with 2M NaCl appeared as residual structures containing the pore complex-lamina layer attached to a halo of DNA filaments. In contrast, no distinct high salt-resistant structure was found with metaphase chromosomes. They formed a highly fragile network which disintegrated easily into small complexes connected with DNA filaments. High salt-resistant DNA-protein complexes were purified by Metrizamide density gradient centrifugation. The main difference in the protein composition of interphase and metaphase residual complexes was the presence in interphase of a protein triplet in the 60–75 kilodalton molecular weight range and its absence in metaphase. This protein triplet most likely corresponds to the lamins A, B, and C of the nuclear lamina. The combined results suggest that the main difference in the structural organization of interphase nuclei and metaphase chromosomes is the presence or absence of the pore complex-lamina layer.     

The stage of chromosome duplication in the cell cycle as revealed by X-ray breakage and 3H-thymidine labeling

By means of combined experiments of X-irradiation and ³H-thymidine labeling of the chromosomes which are in the phase of synthesis, and the subsequent analysis at metaphase on the autoradiographs of the chromosomal damage induced during interphase, it was shown that in somatic cells from a quasi-diploid Chinese hamster line cultured in vitro the chromosomes change their response to radiation from single (chromosome type aberrations) to double (chromatid type aberrations) in late G₁. These results are interpreted to indicate that the chromosome splits into two chromatids in G₁, before DNA replication. — By extending the observations at the second metaphase after irradiation, it was also seen that cells irradiated while in G₂ or late S when they reach the second post-irradiation mitosis still exhibit, beside chromosome type aberrations, many chromatid exchanges, some of which are labeled. Two hypotheses are suggested to account for this unexpected reappearance of chromatid aberrations at the second post-irradiation division. The first hypothesis is that they arise from half-chromatid aberrations. The second hypothesis, which derives from a new interpretation of the mechanisms of production of chromosome aberrations recently forwarded by Evans, is that they arise from gaps or achromatic lesions which undergo, as the cells go through the next cycle, a two-step repair process culminating in the production of aberrations.This work was supported in part by grant No. RH-00304 from the Division of Radiological Health, Bureau of State Services, Public Health Service, U.S.A.     

Cytotoxic effects of GM1 ganglioside and amyloid β-peptide on mouse embryonic neural stem cells

AD (Alzheimer’s disease) is a neurodegenerative disease and the most common form of dementia. One of the pathological hallmarks of AD is the aggregation of extracellular Aβs (amyloid β-peptides) in senile plaques in the brain. The process could be initiated by seeding provided by an interaction between G_M1 ganglioside and Aβs. Several reports have documented the bifunctional roles of Aβs in NSCs (neural stem cells), but the precise effects of G_M1 and Aβ on NSCs have not yet been clarified. We evaluated the effect of G_M1 and Aβ-(1–40) on mouse NECs (neuroepithelial cells), which are known to be rich in NSCs. No change of cell number was detected in NECs cultured in the presence of either G_M1 or Aβ-(1–40). On the contrary, a decreased number of NECs were cultured in the presence of a combination of G_M1 and Aβ-(1–40). The exogenously added G_M1 and Aβ-(1–40) were confirmed to incorporate into NECs. The Ras–MAPK (mitogen-activated protein kinase) pathway, important for cell proliferation, was intact in NECs simultaneously treated with G_M1 and Aβ-(1–40), but caspase 3 was activated. NECs treated with G_M1 and Aβ-(1–40) were positive in the TUNEL (terminal deoxynucleotidyl transferase-mediated dUTP nick-end labelling) assay, an indicator of cell death. It was found that G_M1 and Aβ-(1–40) interacted in the presence of cholesterol and sphingomyelin, components of cell surface microdomains. The cytotoxic effect was found also in NSCs prepared via neurospheres. These results indicate that Aβ-(1–40) and G_M1 co-operatively exert a cytotoxic effect on NSCs, likely via incorporation into NEC membranes, where they form a complex for the activation of cell death signalling.     

Effects of divalent cations and glucose on mitotic-like events in fused interphase-metaphase cells

The effects of Ca²⁺, Mg²⁺ and glucose on the mitotic-like events of prophasing and telophasing were studied in Sendai virus-fused interphase-metaphase (I-M) Chinese hamster binucleate cells. At normal extracellular ion concentrations and neutral pH, about 80–90% of I-M binucleates show prophasing (nuclear envelope dissolution and chromatin condensation) of the I nucleus and 10–15% show telophasing (nuclear envelope reformation and chromatin decondensation) of the M nucleus. To study the effects of cellular divalent cations, cells, depleted of about 77 % of exchangeable cell Ca²⁺ as determined by ⁴⁵Ca²⁺ studies, were incubated in different concentrations of Ca²⁺ or Mg²⁺ for 30 min prior to cell fusion. We found that relatively high concentrations of Ca²⁺ or Mg²⁺ (0.84 mM) were essential for prophasing and that in the presence of 10-fold less Ca²⁺ or Mg²⁺ (0.084 mM) the majority of binucleates showed telophasing. In contrast to a differential effect of divalent cations on the nuclear changes, we found that glucose metabolism was required for both prophasing and telophasing. Additionally, interruption of glucose metabolism in the M cell, but not in the I cell, prior to cell fusion depressed the prophasing frequency about 70%. Although we do not know how divalent cations and glucose function in prophasing and telophasing, we will discuss evidence which suggests that the effects are not mediated through secondary effects on membrane potential, by changes in intracellular concentrations of Na⁺ or K⁺, by simple osmotic changes, or through inhibition of protein synthesis.     

Nivalenol and Deoxynivalenol Affect Rat Intestinal Epithelial Cells: A Concentration Related Study

The integrity of the gastrointestinal tract represents a crucial first level defence against ingested toxins. Among them, Nivalenol is a trichotecenes mycotoxin frequently found on cereals and processed grains; when it contaminates human food and animal feed it is often associated with another widespread contaminant, Deoxynivalenol. Following their ingestion, intestinal epithelial cells are exposed to concentrations of these trichothecenes high enough to cause mycotoxicosis. In this study we have investigated the effects of Nivalenol and Deoxynivalenol on intestinal cells in an in vitro model system utilizing the non-tumorigenic rat intestinal epithelial cell line IEC-6. Both Nivalenol and Deoxynivalenol (5–80 µM) significantly affected IEC-6 viability through a pro-apoptotic process which mainly involved the following steps: (i) Bax induction; (ii) Bcl-2 inhibition, and (iii) caspase-3 activation. Moreover, treatment with Nivalenol produced a significant cell cycle arrest of IEC-6 cells, primarily at the G₀/G₁ interphase and in the S phase, with a concomitant reduction in the fraction of cells in G₂. Interestingly, when administered at lower concentrations (0.1–2.5 µM), both Nivalenol and Deoxynivalenol affected epithelial cell migration (restitution), representing the initial step in gastrointestinal wound healing in the gut. This reduced motility was associated with significant remodelling of the actin cytoskeleton, and changes in expression of connexin-43 and focal adhesion kinase. The concentration range of Nivalenol or Deoxynivalenol we have tested is comparable with the mean estimated daily intake of consumers eating contaminated food. Thus, our results further highlight the risks associated with intake of even low levels of these toxins.     

The first 238 amino acids of the human lamin B receptor are targeted to the nuclear envelope in plants

In plants, the nuclear envelope (NE) is one of the least characterized cellular structures. In particular, little is known about its dynamics during the cell cycle. This is due to the absence of specific markers for in vivo studies. To generate such an in vivo marker, the suitability of the human lamin B receptor (LBR) was tested. When the first 238 amino acids of the LBR, fused to the green fluorescent protein (GFP), were expressed in tobacco plants, fluorescence accumulated only at the NE of leaf epidermal cells. This was confirmed by electron microscopy. The protein was shown to be membrane-integral by phase separation. Distribution of fluorescence was compared with two ER markers, GFP-calnexin and GFP-HDEL. While co-localization of all three markers was noted at the NE, only LBR-GFP was specific to the NE, while the other two also showed fluorescence of the cortical ER. These results suggest that common targeting mechanisms to those in animals and fungi exist in plants to direct and locate proteins to the NE. This chimaeric construct is the first available fluorescent integral membrane protein marker to be targeted exclusively to the plant NE and it provides a novel opportunity to investigate the dynamics of this membrane system in vivo. With it, the cell cycle was followed in tobacco BY-2 cells stably expressing the fusion protein. The interphase labelling of the NE altered in metaphase into an ER-like meshwork, suggesting the dispersal of the NE to ER as in animal cells. Finally, the meshwork of fluorescent membranes was lost and new fluorescent NE formed around the daughter nuclei.     

Prematurely condensed human sperm chromosomes after in vitro fertilization (IVF)

Summary During an in vitro fertilization (IVF) program 122 inseminated eggs showing polar body extrusion, but neither formation of pronuclei nor cell cleavage were analysed cytogenetically. Nine of these eggs showed prematurely condensed sperm chromosomes of the G₁-phase (G₁-PCC) besides the haploid set of maternal metaphase II chromosomes. This phenomenon can be explained by the permanent arrest of the oocytes at metaphase II after sperm penetration and hence the continuing presence of cytoplasmic chromosome condensing factors which lead to the induction of PCC in the sperm nucleus. The overall frequency of this aberrant type of fertilization was calculated to be in the order of 3–4% of all in vitro fertilized eggs.     

INDUCTION OF NUCLEAR ENVELOPES AROUND METAPHASE CHROMOSOMES AFTER FUSION WITH INTERPHASE CELLS

The process of cellular fusion induced by Sendai virus in Chinese hamster cells (Don line) afforded us the opportunity to study nuclear envelope formation around metaphase sets in the presence of interphase nuclei, when chromosome pulverization failed to occur in such multinucleate cells. Morphologically, the enveloped metaphase chromosomes resembled a normal telophase nucleus, though minor differences prompted us to call it telophase-like. Electron microscopic observations demonstrated that the membranes enveloping the chromosomes appeared to be identical with a normal nuclear envelope. The longer the cells were incubated with Colcemid before fusion, the higher was the number of cells with telophase-like nuclei and the lower the percentage of cells with pulverizations. Furthermore, the number of pulverizations bore a somewhat direct relationship to the ratio of metaphase to interphase nuclei in multinucleate cells, and the number of telophase-like nuclei was inversely proportional to this ratio. A hypothesis is advanced in which a balance between the activities of a chromosome pulverization factor and a nuclear envelope formation factor, the former in metaphase cells and the latter in interphase cells, is decisive as to the nature of morphologic events observed in virus-induced fused cells.     

Three Distinct Mechanisms for Translocation and Activation of the δ Subspecies of Protein Kinase C

We expressed δ subspecies of protein kinase C (δ-PKC) fused with green fluorescent protein (GFP) in CHO-K1 cells and observed the movement of this fusion protein in living cells after three different stimulations. The δ-PKC–GFP fusion protein had enzymological characteristics very similar to those of the native δ-PKC and was present throughout the cytoplasm in CHO-K1 cells. ATP at 1 mM caused a transient translocation of δ-PKC–GFP to the plasma membrane approximately 30 s after the stimulation and a sequent retranslocation to the cytoplasm within 3 min. A tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol 13-acetate (TPA; 1 μM), induced a slower translocation of δ-PKC–GFP, and the translocation was unidirectional. Concomitantly, the kinase activity of δ-PKC–GFP was increased by these two stimulations, when the kinase activity of the immunoprecipitated δ-PKC–GFP was measured in vitro in the absence of PKC activators such as phosphatidylserine and diacylglycerol. Hydrogen peroxide (H₂O₂; 5 mM) failed to translocate δ-PKC–GFP but increased its kinase activity more than threefold. δ-PKC–GFP was strongly tyrosine phosphorylated when treated with H₂O₂ but was tyrosine phosphorylated not at all by ATP stimulation and only slightly by TPA treatment. Both TPA and ATP induced the translocation of δ-PKC–GFP even after treatment with H₂O₂. Simultaneous treatment with TPA and H₂O₂ further activated δ-PKC–GFP up to more than fivefold. TPA treatment of cells overexpressing δ-PKC–GFP led to an increase in the number of cells in G₂/M phase and of dikaryons, while stimulation with H₂O₂ increased the number of cells in S phase and induced no significant change in cell morphology. These results indicate that at least three different mechanisms are involved in the translocation and activation of δ-PKC.