Assessment of mitochondrial function in the surviving cytoplasts of cultured cells of pig embryonic kidney by using ethylrhodamine

A study was made of the functional state of chondriome in cytoplasts previously cultivated for a long time under vital staining with fluorescent dye ethylrhodamine (10 micrograms/ml) which is known to accumulate preferentially in mitochondria. The energization was estimated by the intensity of mitochondrial fluorescence. It was realized that 30 minutes after enucleation cytoplasts retained the same fluorescence as did the untreated cells, and that the mitochondrial distribution within the cell was very similar. Such a high intensity of fluorescence seen within one day after enucleation gives a strong evidence on the high degree of independence on the cell nucleus of organelles that provide the energy to metabolic processes. In the course of survival in the cultivation medium for 1-4 days the intensity of fluorescence is shown to fall, especially on the second day after enucleation. All these changes coincide with the changes in cytoplast shape: originally well spread bodies transform into squeezed, ball-shaped or strongly deformed ones. The adhesive ability is going down, and in result only single units of cytoplast can hardly be found on the cover slips by the 4th day after enucleation. These changes give evidence on the enhanced degeneration of cultured cytoplasts.     

Modification of a method of cell enucleation using cytochalasin B and the study of cytoplast viability

The modification of Prescott's (Prescott et al., 1972) method of enucleation in vitro was described. A special teflon chamber faciliatating the enucleation of monolayer cultured cells to produce cytoplasts and karyoplasts was constructed. Mouse L-cells were enucleated by exposing to cytochalasine B (10 gamma/ml) followed by centrifugation. The fraction of cells enucleated in the chamber was about 98%. The life time of cytoplasts in cultural medium after their enucleation was 48 hours (sometimes 56-72 hours) as tested by vital neutral red staining. The cytoplasts that survived were shown to accumulate large lysosomes, and the evidence of appearing ring-like fibrillar structures was provided using a simple technique of cytoskeleton observation under light microscope.     

Purification of cybrids by fluorescence-activated cell sorting

A general method to isolate and purify substantial numbers of viable cybrids from cultured mammalian cells immediately following cytoplast-cell fusion is described. This method uses cytoplasts whose mitochondria are selectively stained in vivo by the cationic fluorescent rhodamine dye, rhodamine 123. Large numbers of highly purified, rhodamine-stained cytoplasts are fused to appropriate recipient cell lines and then the fusion mixture is sorted based on forward angle scatter and fluorescence parameters. Plating the positively sorted population in culture for as short as 12 h eliminates contaminating cytoplasts which, lacking a nucleus, are unable to adhere or survive. The resultant population, based on an analysis of genetic markers, is 75-100% cybrids, an enrichment of 1000- to 10,000-fold over the initial fusion mixture. Cybrids purified by cell sorting may be useful for detailed molecular studies of mitochondrial DNA gene expression and in the specific induction of new mitochondrial DNA mutants.     

Reproduction of murine encephalomyocarditis virus in enucleated Krebs 2 ascitic carcinoma cells]

Enucleated cells of ascites carcinoma Krebs 2 (cytoplasts) were prepared. The cells were centrifugated for this purpose in a discontinuous Ficoll density gradient containing cytochalasine B. The cytoplasts formed turbid bands in Phycol solution at the density of 1.037--1.053 g/ml. The cytoplasts failed to synthesize RNA, but proteins were synthesized for several hours. Encephalomyocarditis virus replicated in the ascites carcinoma cytoplasts, but its yield was 10 to 100-fold lower as compared to that in the intact cells. Apparently the reduction of the virus yield was not due to the low efficiency of early stages of the virus-cytoplast interaction. Viral infection resulted in inhibition of the synthesis of cellular proteins in the cytoplasts as well as in the intact cells.     

Use of cell enucleation in studying the stability of cytoplasmic organelles and cytoplasm organization

A study was made of the viability and ultrastructure of cytoplasts produced by enucleation of cytochalasin-induced A9 cells in suspension. These cytoplasts are in general as viable as cells enucleated in the monolayer. The organization of the cytoplasm, i.e. a specific distribution of cytoplasmic organelles, is conserved for at least 24 hours in the absence of the nucleus. This fact may reflect a high degree of autonomy of the cytoskeleton.     

哺乳动物细胞去核产物(胞质体及核体)的结构与功能研究

1967年Carter发现细胞松弛素可以诱发组织培养细胞的自发排核之后,Prescott(1972)借助细胞松弛素存在下的离心处理,使这一排核现象普遍化,从而确立了体外细胞去核的标准方法。经过不断改进(croce et al., 1974;Veomett et al., 1976;Lucas etal., 1976;Wigler et al., 1975),现在,这一技术已广泛应用于细胞学研究的各个重要领域(Mc Burney et al., 1979;Goldman et al., 1974;du Bols et al., 1980)。细胞去核技术及其应用的研究在我国已有初步开展(陈瑞铭等,1979;沈鼎武等,1980)。本实验对二种上皮型传代细胞系进行了去核手术,用扫描电镜和透射电镜对所获得的胞质体     

Nuclear control of tumorigenicity in cells reconstructed by PEG-induced fusion of cell fragments

The techniques of somatic cell hybridization have provided a valuable means of studying mechanisms of regulation of mammalian cell differentiation and transformation. Most previous studies have indicated that fusions between tumorigenic and nontumorigenic cells result in hybrid cells that are usually tumorigenic. In recent years it has been demonstrated that the phenotypic expression of tumorigenicity is at least partially due to the extensive chromosome loss that occurs in most interspecific and some intraspecific hybrid cells. In the present study we have utilized enucleation techniques that permit cells to be divided into nuclear (karyoplast) and cytoplasmic (cytoplast) cell fragments. Even though these nuclear and cytoplasmic fragments are metabolically stable for short periods of time, in our hands they ultimately degenerate. Viable cells can be reconstructed by PEG-induced fusion of karyoplasts to cytoplasts. Since reconstructed cells apparently do not segregate chromosomes, they may provide a clearer understanding of the interactions between the nucleus and the cytoplasm in the control of the expression of tumorigenicity. We have reconstructed cells using karyoplasts from the tumorigenic Y-1 cell line and cytoplasts from a nontumorigenic cell line, A-MT-BU-A1. In addition we have reconstructed cells containing Y-1 cytoplasts and A-MT-BU-A1 karyoplasts. The reconstructed cells porduced were assayed for tumorigenicity by their ability to grow in soft agar and in nude mice. The results of these experiments indicate that the reconstructed cells containing a tumorigenic nucleus and a nontumorigenic cytoplasm ultimately are tumorigenic and conversely the reconstructed cells containing a nontumorigenic nucleus and a tumorigenic cytoplasm are nontumorigenic. These experiments support the concept that with these cell lines the nucleus (karyoplast) is sufficient to control the phenotypic expression of tumorigenicity.     

Mitochondrial RNA and protein synthesis in enucleated African green monkey cells

The behavior of extramitochondrial protein synthesis and of mitochondrial RNA and protein synthesis was examined in the cytoplasts of African green monkey kidney cells (TC-7 subline) at different times following enucleation by cytochalasin B. The rate of incorporation of [³H]isoleucine into protein of the soluble cytoplasmic fraction decreased in an approximately exponential fashion, with a half-life of about five hours, during the first 26 hours after enucleation. Discrete mitochondrial 16 S, 12 S and 4 S RNA components were identified among the products of cytoplast RNA synthesis. The rates of [³H]uridine incorporation into the 16 and 12 S RNA components as well as into total RNA declined progressively after enucleation to a barely detectable level by the 20th hour. By contrast, the rate of chloramphenicol-sensitive [³H]isoleucine incorporation into protein (due to mitochondrial protein synthesis) did not undergo a substantial decline for at least 20 hours in TC-7 cytoplasts; instead, a reproducible transient stimulation occurred in the first hours following enucleation. The products of mitochondrial protein synthesis pulse-labeled in nucleated cells and in cytoplasts 24 hours after enucleation exhibited similar electrophoretic profiles.     

Locomotion of CV-1 cytoplasts with or without a centrosome

The movement of cultured cells along the substratum is a convenient model for studying cell movement in the organism, occurring during embryogenesis, angiogenesis, metastasis, wound closure, etc. The moving cells must control their pseudopodial activity along the perimeter, regulate the attachment and reattachment to the substratum, and pull their body following pseudopodium during their movement along the substratum. As proven by numerous investigations, these processes directly depend on the actomyosin system of cells. The role of microtubules as components of cytoskeleton in cell locomotion still remains obscure. The role of microtubules in cell movement is commonly investigated using microtubule-destructive drugs. Therefore in the final results the accessory drug effect on, for example, signal cascades cannot be excluded. Another mode of action on the microtubule dynamics is centrosome removal from the cells, which is easily realized by their removal together with the nucleus. It has been shown that in cytoplasts of centrosome containing fibroblasts, dynamic instability of microtubules remains. Unlike, in non-centriolar cytoplasts tread milling is observed. Some literature evidence suggests that cytoplasts of cultured cells move along the substratum not worse that intact cells do. In this study cytoplasts with and without centrosome were obtained and identified, and parameters of movement along the substratum (speed, direction) were registered for both these two populations of cytoplasts, and for control intact cells and cells involved in the experiment. The model of experimental wound of monolayer was used, because it guaranteed cell synchronization in respect to movement direction and speed. Centrosome-containing CV-1 cytoplasts displayed radial microtubule array, and centrosome-lacking cytoplasts exhibited chaotic distribution of microtubules, which is characteristic of microtubule tread milling. In addition, both kinds of cytoplasts appeared to move along the substratum much slower than the whole cells. No difference was found is speed and keeping direction between centriolar and non-centriolar cytoplasts.     

Role of the centrosome in organizing the interphase microtubule array: properties of cytoplasts containing or lacking centrosomes

To study the role of the centrosome in microtubule organization in interphase cells, we developed a method for obtaining cytoplasts (cells lacking a nucleus) that did or did not contain centrosomes. After drug- induced microtubule depolymerization, cytoplasts with centrosomes made from sparsely plated cells reconstituted a microtubule array typical of normal cells. Under these conditions cytoplasts without centrosomes formed only a few scattered microtubules. This difference in degree of polymerization suggests that centrosomes affect not only the distribution but the amount of microtubules in cells. To our surprise, the extent of microtubules assembled increased with the cell density of the original culture. At confluent density, cytoplasts without centrosomes had many microtubules, equivalent to cytoplasts with centrosomes. The additional microtubules were arranged peripherally and differed from the centrosomal microtubules in their sensitivity to nocodazole. These and other results suggest that the centrosome stabilizes microtubules in the cell, perhaps by capping one end. Microtubules with greater sensitivity to nocodazole arise by virtue of change in the growth state of the cell and may represent free or uncapped polymers. These experiments suggest that the spatial arrangement of microtubules may change by shifting the total tubulin concentration or the critical concentration for assembly.     

DNA synthesis in the nuclei of resting and proliferating cells of the NIH 3T3 line in monokaryons, homo- and heterodikaryons

Serum-deprived (0.5%) resting NIH 3T3 mouse fibroblasts were fused with stimulated cells taken at 2 hour intervals after changing the medium to the one containing 10% serum, and DNA synthesis was investigated in monokaryons, homodikaryons, and heterodikaryous using radioautography with double-labeling technique. The presence of the resting nucleus in the common cytoplasm has an inhibitory effect on the entry of the stimulated nucleus into the S period in the medium containing either 0.5 or 10% serum, but DNA synthesis continues. After a 24 hour stay in the common cytoplasm with resting nuclei the stimulated nuclei return into the state of rest. When resting cells are stimulated by 10% serum, their inhibitory effect on stimulated nuclei in heterodikaryons still persists for at least 2 hours following stimulation. Preincubation of resting cells with cycloheximide for 4 hours abolishes their ability to suppress DNA synthesis in stimulated nuclei. The data suggest that the resting cells produce an endogenous inhibitor of cell proliferation whose formation depends upon the synthesis of protein(s). When stimulated, cell can proliferate only upon decreasing the level of this inhibitor. The obtained results are consistent with the idea of a negative control of cell proliferation.     

Nuclear-cytoplasmic relationships in human cells in tissue culture. III. Auto-radiographic study of interrelation of nuclear and cytoplasmic ribonucleic acid

The movement of ribonucleic acid (RNA) from nucleus to cytoplasm has been studied, by autoradiographic techniques, in cells of the human amnion grown in tissue culture. Cells were exposed to cytidine-H(3) for 1 hour after which time only the RNA of the nuclei was labelled. After this 1 hour exposure the cells were placed in a medium containing an excess amount of unlabelled cytidine. Periodically, cells from this medium were fixed. Autoradiographs showed that there was a progressive movement of the label from nucleus to cytoplasm, such that after 24 hours essentially all the label was in the RNA of the cytoplasm. A study of the incorporation of the cytidine-H(3) in deoxyribonucleic acid (DNA), in the same population of cells at the same times, indicated that the presence of excess amounts of unlabelled cytidine almost instantaneously inhibited further utilization of cytidine-H(3). It is concluded that RNA moves from nucleus to cytoplasm as a complex polynucleotide structure.     

Role of mevalonate in regulation of cholesterol synthesis and 3-hydroxy-3-methylglutaryl coenzyme A reductase in cultured cells and their cytoplasts

H4-II-E-C3 hepatoma cells in culture respond to lipid-depleted media and to mevinolin with increased sterol synthesis from [14C]acetate and rise of 3-hydroxy-3-methylglutaryl coenzyme A reductase levels. Mevalonate at 4 mM concentration represses sterol synthesis and the reductase, and completely abolishes the effects of mevinolin. Mevalonate has little or no effect on sterol synthesis or reductase in enucleated hepatoma cells (cytoplasts) or on reductase in cytoplasts of cultured Chinese hamster ovary (CHO) cells. The sterol-synthesizing system of hepatoma cell cytoplasts and the reductase in the cytoplasts of CHO cells were completely stable for at least 4 hr. While reductase levels and sterol synthesis from acetate followed parallel courses, the effects on sterol synthesis--both increases and decreases--exceeded those on reductase. In vitro translation of hepatoma cell poly(A)+RNAs under various culture conditions gave an immunoprecipitable polypeptide with a mass of 97,000 daltons. The poly(A)+RNA from cells exposed for 24 hr to lipid-depleted media plus mevinolin (1 microgram/ml) contained 2.8 to 3.6 times more reductase-specific mRNA than that of cells kept in full-growth medium, or cells exposed to lipid-depleted media plus mevinolin plus mevalonate. Northern blot hybridization of H4 cell poly(A)+RNAs with [32P]cDNA to the reductase of CHO cells gave two 32P-labeled bands of 4.6 and 4.2 K-bases of relative intensities 1.0, 0.61-1.1, 2.56, and 1.79 from cells kept, respectively, in full-growth medium, lipid-depleted medium plus mevinolin plus mevalonate, lipid-depleted medium plus mevinolin, and lipid-depleted medium. These values approximate the reductase levels of these cells. We conclude that mevalonate suppresses cholesterol biosynthesis in part by being a source of a product that decreases the level of reductase-specific mRNA.     

Effect of cycloheximide on the ultrastructure and several metabolic processes of the cells of an SPEV culture. II

The action of cyclohexamide (in doses of 1 and 10 mkg/ml in the course of 24 hours) on porcine embryo kidney cells in culture is accompanied by a powerful suppression of protein and DNA synthesis, mitotic activity, a weaker suppression of RNA synthesis, a lowering of the activity of succinate-, lactate- and alpha-glycerophosphate-dehydrogenase, which leads to disorders in the ultrastructure of the cells. After incubation of cells in a fresh medium (in the course of 18, 24 hours) there occurs a total restoration of the ultrastructure of the nuclei, granular endoplasmatic reticulum, mitochondria, due to the repairing and strong intensification of synthetic processes, respiration and glycolysis, mitotic activity of the cells.     

Vaccinia Virus Replication I. Requirement for the Host-Cell Nucleus

Using cytochalasin B-induced enucleation techniques, we examined the ability of vaccinia virus to replicate in the absence of the host-cell nucleus in several mammalian cell lines. It was found that virus-infected enucleated cells (cytoplasts) prepared from BSC-40, CVC, and L cells were incapable of producing infectious progeny virus. The nature of this apparent nuclear involvement was studied in detail in BSC-40 cells. Modulations designed to maximize cytoplast integrity and longevity, such as reduction of the growth temperature and initial multiplicity of infection, did not improve virus growth in cytoplasts. Sodium dodecyl sulfate-polyacrylamide gel analysis of the [(35)S]methionine pulse-labeled proteins synthesized in vaccinia virus-infected cytoplasts demonstrated that both early and late viral gene products were being expressed at high levels and with the proper temporal sequence. Vaccinia virus cytoplasmic DNA synthesis, as measured by [(3)H]thymidine incorporation, peaked at 3 h postinfection and was 70 to 90% of control levels in cytoplasts. However, in the cytoplasts this DNA was not converted to a DNase-resistant form late in infection, which was consistent with the failure to isolate physical particles from infected cytoplasts. Treatment of vaccinia virus-infected cells with 100 mug of rifampin/ml from 0 to 8 h to increase the pools of viral precursors, followed by subsequent removal of the drug, resulted in a threefold increase virus yield. This treatment had no effect on virus-infected cytoplasts. Finally, vaccinia virus morphogenesis was studied under an electron microscope in thin sections of virus-infected cells and cytoplasts which had been prepared at various times during a single-step growth cycle. It was apparent that, although early virus morphogenetic forms appeared, there was no subsequent DNA condensation or particle maturation in the cytoplasts. These results suggest that vaccinia virus requires some factor or function from the host-cell nucleus in order to mature properly and produce infectious progeny virus.     

Bid-induced release of AIF from mitochondria causes immediate neuronal cell death

Mitochondrial dysfunction and release of pro-apoptotic factors such as cytochrome c or apoptosis-inducing factor (AIF) from mitochondria are key features of neuronal cell death. The precise mechanisms of how these proteins are released from mitochondria and their particular role in neuronal cell death signaling are however largely unknown. Here, we demonstrate by fluorescence video microscopy that 8-10 h after induction of glutamate toxicity, AIF rapidly translocates from mitochondria to the nucleus and induces nuclear fragmentation and cell death within only a few minutes. This markedly fast translocation of AIF to the nucleus is preceded by increasing translocation of the pro-apoptotic bcl-2 family member Bid (BH3-interacting domain death agonist) to mitochondria, perinuclear accumulation of Bid-loaded mitochondria, and loss of mitochondrial membrane integrity. A small molecule Bid inhibitor preserved mitochondrial membrane potential, prevented nuclear translocation of AIF, and abrogated glutamate-induced neuronal cell death, as shown by experiments using Bid small interfering RNA (siRNA). Cell death induced by truncated Bid was inhibited by AIF siRNA, indicating that caspase-independent AIF signaling is the main pathway through which Bid mediates cell death. This was further supported by experiments showing that although caspase-3 was activated, specific caspase-3 inhibition did not protect neuronal cells against glutamate toxicity. In conclusion, Bid-mediated mitochondrial release of AIF followed by rapid nuclear translocation is a major mechanism of glutamate-induced neuronal death.     

Nuclear-Cytoplasmic Relationships in Human Cells in Tissue Culture : III. Autoradiographic Study of Interrelation of Nuclear and Cytoplasmic Ribonucleic Acid

The movement of ribonucleic acid (RNA) from nucleus to cytoplasm has been studied, by autoradiographic techniques, in cells of the human amnion grown in tissue culture. Cells were exposed to cytidine-H³ for 1 hour after which time only the RNA of the nuclei was labelled. After this 1 hour exposure the cells were placed in a medium containing an excess amount of unlabelled cytidine. Periodically, cells from this medium were fixed. Autoradiographs showed that there was a progressive movement of the label from nucleus to cytoplasm, such that after 24 hours essentially all the label was in the RNA of the cytoplasm. A study of the incorporation of the cytidine-H³ in deoxyribonucleic acid (DNA), in the same population of cells at the same times, indicated that the presence of excess amounts of unlabelled cytidine almost instantaneously inhibited further utilization of cytidine-H³. It is concluded that RNA moves from nucleus to cytoplasm as a complex polynucleotide structure.