Karyoplast-cytoplast volume ratio in bovine nuclear transfer embryos: Effect on developmental potential

To evaluate the effect of karyoplast-cytoplast ratio on the development of nuclear transfer embryos, karyoplasts from day 4, day 5, and day 6 embryos were transferred to oocytes enucleated with different volumes of cytoplasm: Type 1, removal of a small volume of cytoplasm equivalent to the first polar body, Type 2, removal of a volume of cytoplasm approximately equal to the volume of the respective karyoplast, and Type 3, removal of half of the oocyte volume. In addition, the effect of experimental reduction of karyoplast cytoplasm was investigated in day 4 and day 5 karyoplasts. Intact day 4 karyoplasts fused to Type 3 cytoplasts did not support development to blastocysts, whereas these karyoplasts yielded blastocysts in combination with Type 1 (7%) and Type 2 cytoplasts (12%). After experimental reduction of cytoplasmic volume in day 4 karyoplasts, blastocysts (10%) were also obtained after fusion with Type 3 cytoplasts, probably due to reduction of cytoplasmic chimerism. With day 5 karyoplasts, blastocyst rate was higher in combination with Type 2 (34%) than with Type 1 (19%) and Type 3 cytoplasts (16%; P < 0.05). The use of day 6 intact karyoplasts resulted in a significantly (P < 0.05) higher proportion of blastocysts when fused with Type 2 (38%) or Type 1 cytoplasts (34%) than with Type 3 cytoplasts (16%). These results suggest that enucleation of oocytes with a volume similar to that of the respective karyoplast creates better conditions for cell cycle interactions with all types of karyoplasts than enucleation with minimal or large volume of cytoplasm. Mol. Reprod. Dev. 48:332–338, 1997. © 1997 Wiley-Liss, Inc.     

Microsurgical removal of centrosomes blocks cell reproduction and centriole generation in BSC-1 cells

We have removed the centrosome from cultured BSC-1 cells by microsurgery, leaving enough cytoplasm with the nucleated cell fragment (karyoplast) to ensure survival and growth. In each experiment, we followed the fate of the karyoplast as well as the anucleate cell fragment (cytoplast) containing the original pair of centrioles. Experimental karyoplasts reestablish a juxtanuclear microtubule-organizing center, an astral array of microtubules, and a compact Golgi apparatus. They enter and presumably complete S phase, and they grow beyond the size of an average BSC-1 cell. However, they do not regenerate centrioles in time periods equivalent to more than 10 cell cycles and do not undergo cell division. Control-operated cells with centrosomes left in the karyoplast progress through the cell cycle, duplicate the centrosome, and form clonal cell colonies. We conclude that the removal of centrioles uncouples cell growth from cell reproduction and impedes centriole biogenesis and centrosome duplication.     

Programmed macromolecular synthesis in regenerating karyoplasts.

Conditions for the preparation, purification, and maintenance of karyoplasts which could regenerate to reform whole viable cells were defined. Results of biochemical analyses of such karyoplasts at various times during regeneration indicated that a reproducible biosynthetic program was followed. Thus, an examination of the polypeptides made during regeneration by two-dimensional gel electrophoresis showed that the pattern of radiolabeled polypeptides synthesized at each time studied was specific and was significantly different from that observed at other times during regeneration. Polypeptides associated with three major cellular fractions--nuclear, cytoskeletal-microtrabecular, and soluble--were among the most dramatically regulated molecules. Other polypeptides, such as the major components of microfilaments and intermediate filaments, were synthesized at relatively constant rates and were assembled into structures throughout regeneration. Likewise, microtubules appeared to be reformed throughout regeneration, even in the absence of identifiable centriole-associated organizing centers. Finally, analysis of DNA synthesis by autoradiography showed that, even when prepared from whole cells synchronized at the G1/S interface, karyoplasts could not begin making DNA until they had regenerated an almost complete complement of cytoplasm.     

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.     

The preparation and properties of cytoplasts from Ehrlich ascites tumor cells

A method is described in which cytochalasin B is used to fractionate Ehrlich ascites tumor cells into cytoplasts and (nucleated) karyoplasts. The plasma membrane and cytoplasm are selectively removed from these cells by this method such that the cytoplasts rarely contain membranous organelles (e.g., mitochondria) which are retained in the karyoplast during fractionation. ATP concentrations similar to those found in whole cells and glycolytic activity were measured in cytoplasts in the presence but not the absence of glycose. Cytoplasts also actively transport Na⁺, K⁺, and α-aminoisobutyric acid to steadystate distribution ratios similar to those found in whole cells. It was concluded that these cytoplasts are a simplified model system for the study of active transport in Ehrlich cells.     

Enucleation and reconstruction of murine L-cell fibroblasts

Two types of teflon chambers are suggested for the procedures of enucleation and reconstruction of cells cultivated in the monolayer. The first chamber simplifies the enucleation and permits performing it on the standard cover glasses with a small volume of medium with cytochalasin B. The second chamber permits purifying the karyoplast fraction from intact cells by their adhesion on the cover glasses. Then the karyoplasts are sedimented by centrifugation on cytoplasts located on the cover glasses. This procedure promotes sticking of fragments and their subsequent fusion in the presence of polyethylene glycol. In total the number of reconstructed cells increases many times.     

Enucleation of human endometrial cells: nucleo-cytoplasmic distribution of DNA polymerase alpha and estrogen receptor

Nucleo-cytoplasmic distribution of estrogen receptors and DNA polymerase alpha activity in human endometrial adenocarcinoma cells (HEC-50 line) was evaluated after separation of nuclei following either homogenization or enucleation with cytochalasin B. About 30% of the estrogen receptor was found in the nuclear fraction after homogenization whereas 86% was found in the karyoplasts after enucleation. The total amounts of estrogen receptor per cell after homogenization and enucleation were not significantly different (14,000-17,000 binding sites/cell). Receptor measurements were carried out using the hydroxylapatite method after labeling with [3H]estradiol (5 nM [3H]E2 +/- 500 nM E2) at 30 degrees C for 3 h. About 20% of the DNA polymerase alpha activity was found in the nuclear fraction after homogenization, whereas 96% was found in the karyoplasts after enucleation. The average total activity (0.84 Units/10(6) cells) in homogenized cells was about 1/8 of the activity in karyoplasts. These results indicate that estrogen receptor and DNA polymerase alpha activity reside in the nucleus in intact HEC-50 cells. DNA polymerase alpha is translocated to the cytoplasmic fraction and inactivated after homogenization.     

Interconversion of metaphase and interphase microtubule arrays, as studied by the injection of centrosomes and nuclei into Xenopus eggs

We have designed experiments that distinguish centrosomal , nuclear, and cytoplasmic contributions to the assembly of the mitotic spindle. Mammalian centrosomes acting as microtubule-organizing centers were assayed by injection into Xenopus eggs either in a metaphase or an interphase state. Injection of partially purified centrosomes into interphase eggs induced the formation of extensive asters. Although centrosomes injected into unactivated eggs (metaphase) did not form asters, inhibition of centrosomes is not irreversible in metaphase cytoplasm: subsequent activation caused aster formation. When cytoskeletons containing nuclei and centrosomes were injected into the metaphase cytoplasm, they produced spindle-like structures with clearly defined poles. Electron microscopy revealed centrioles with nucleated microtubules. However, injection of nuclei prepared from karyoplasts that were devoid of centrosomes produced anastral microtubule arrays around condensing chromatin. Co-injection of karyoplast nuclei with centrosomes reconstituted the formation of spindle-like structures with well-defined poles. We conclude from these experiments that in mitosis, the centrosome acts as a microtubule-organizing center only in the proximity of the nucleus or chromatin, whereas in interphase it functions independently. The general implications of these results for the interconversion of metaphase and interphase microtubule arrays in all cells are discussed.     

Degradation of nuclear proteins: studies on transplanted B82 cell karyoplast proteins

Karyoplasts were prepared from B82 cells (thymidine kinase deficient mouse L cells) by cytochalasin B mediated enucleation. Morphological measurements show that the nucleus constitutes 89% of a karyoplast by volume. Homokaryons were obtained by Sendai virus mediated karyoplast-B82 cell fusion. Transplanted nuclei were not destroyed catastrophically but were maintained intracellularly for at least 140 h. Transplanted nuclear proteins were degraded with an average half-life of 84 +/- 7 h by processes partially sensitive to inhibition by NH4Cl (50%) and leupeptin (30%). The data therefore suggest that some nuclear proteins are translocated to the cytoplasm for lysosomal degradation.     

Most iodinatable fibroblast surface proteins accompany the cytoplast membrane during cytochalasin B-mediated enucleation of chick embryo fibroblasts

Six different proteins are found to be reproducibly exposed on the cell surface of chicken embryo fibroblasts (CEF) by the criterion of lactoperoxidase-catalyzed iodination (250,000, 185,000, 130,000, 100,000, 87,000, and 75,000 daltons). We wondered whether cell enucleation might lead to a differential partition of these surface proteins with the karyoplast or cytoplast membrane. We found that there is a marked enrichment of most iodinatable cell surface proteins in the cytoplast after cytochalasin-mediated enucleation of cell monolayers. Nearly all the iodinatable fibronectin remains with the cytoplast. Of the six labeled proteins, the karyoplast membrane contains a small amount of the 130 kdalton protein as well as trace levels of the 100-, 85-, and 75-kdalton proteins. Proteolysis or selective shedding of membrane proteins were not significant factors in the relative exclusion of iodinatable membrane proteins from the karyoplast. The cytoplast could replace some exposed membrane proteins after removal by trypsinization; however, fibronectin was not detectable within 10 h. That the karyoplast was not capable of membrane protein synthesis and/or insertion was suggested by the lack of any change in the labeling pattern of karyoplasts up to 8-h incubation after enucleation. A variety of control studies indicated that the surface proteins identified in this report were cell-derived and not adsorbed serum components. That some of the iodinatable proteins are intrinsic membrane proteins was suggested by their resistance to removal by conditions thought to extract extrinsic membrane proteins (i.e., low salt, high salt, and NaOH washes). lack of effect of cytoskeletal disrupting agents (preliminary evidence) suggests the nonrandom partition of membrane proteins may depend on anchoring of membrane proteins by a system(s) in the cytoplast other than intact microtubules and microfilaments.     

Localization of the deoxyribonucleotide biosynthetic enzymes ribonucleotide reductase and thymidylate synthase in mouse L cells

Two different approaches were used to define the intracellular localization in mouse L929 cells of two deoxyribonucleotide biosynthetic enzymes: ribonucleoside diphosphate reductase (EC1.17.4.1) and thymidylate synthase (EC2.1.1.45). The first involved treatment with saponins, which render the plasma membrane permeable to proteins without disrupting intracellular organelles. Under conditions where nuclear DNA synthesis and the activity of the nuclear enzyme NMN adenylyltransferase were unaffected, the entire cellular complements of a cytosolic enzyme, glucose-6-phosphate dehydrogenase, and of ribonucleotide reductase and thymidylate synthase were released at the same rate and with similar dependence on saponin concentration. The second approach involved centrifugal enucleation of cells treated with cytochalasin B (CB) and measurement of the distribution of enzyme activities in the resulting cytoplast and karyoplast fractions. Whereas most NMN adenylyltransferase activity remained with the karyoplasts, glucose-6-phosphate dehydrogenase, ribonucleotide reductase, and thymidylate synthase were almost exclusively associated with the enucleated cytoplasts. These results indicate that, under conditions where nuclear DNA synthesis is apparently unperturbed, the intracellular distribution of the deoxyribonucleotide biosynthetic enzymes studied is the same as that of glucose-6-phosphate dehydrogenase, a typical cytosol enzyme, and clearly differs from that of NMN adenylyltransferase, a nuclear enzyme.     

Cellular aging studied by the reconstruction of replicating cells from nuclei and cytoplasms isolated from normal human diploid cells

Cytochalasin B (CB) was used to enucleate cells (cytoplasts) and to obtain karyoplasts (nuclei) from the human diploid fetal lung fibroblast strain WI-38. Fusion of cytoplasts and nuclei from young and old cells was accomplished with the aid of inactivated Sendai virus. Viable nuclei may be obtained from the karyoplast pellet after passage through a layer of bovine albumin which retains any contamination cytoplasts. The majority of successful fusions forming “whole cells” occurred when cytoplast from “old” cultures (PDL 40–51) and karyoplasts from “young” cultures were used (PDL 12–22), but almost always resulted in limited division of the viable reconstructed cells. When successful fusion occurred between “young” cytoplasts and “young” karyoplasts the number of cell divisions obtained was comparable to control cells kept under similar conditions.     

The ultrastructure of the centrosome in cytoplasts and its alteration under the action of ouabain]

It has been shown that after enucleation of the PE cells with cytochalasin D the centrioles remain in approximately 80% of cytoplasts. Some cytoplasts contain only single centriole, either a mother (active) of a daughter (inactive) one. 20% cytoplasts have no centrioles. 2h after enucleation the centrosome structure in the cytoplasts did not differ from that in normal cells. 14-16 h after enucleation in many cytoplasts large secondary lysosomes and lipid droplets appeared around the centrosome. At this time in some cytoplasts in the centrosome we observed free microtubule convergence foci. 14-16 h after the enucleation, some cytoplasts have doubling centrioles. Under the influence of ouabain (30 min), the number of active centrioles oriented perpendicularly to the substrate plane in the cytoplasts increased. We suggest that the preferentially perpendicular orientation of centrioles to the substrate plane does not depend on the nuclear activity.     

Interaction of vinblastine with the secretagogue action of db-cAMP in the rat exocrine pancreas,.

Developmentally pluripotent embryonal carcinoma cells isolated from mouse teratocarcinomas were fused to whole cells, to cytoplasts, and to karyoplasts of 3T3 fibroblasts. The cybrids (cell X cytoplast fusion product) retained the developmental potency of the embryonal carcinoma cell parent. On the other hand, the karyobrids (cell X karyoplast fusion product) and the hybrids resembled the fibroblast parent cell and were incapable of differentiation. These experiments, therefore, failed to reveal the presence of cytoplasmic regulators of nuclear gene expression.     

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.     

Immunolocalization of myosin and tropomyosin in cells undergoing ciliogenesis during regeneration of rat tracheal epithelium

During the regeneration of the mucociliary lining of the respiratory airways, many cells differentiate into ciliated cells. Early stages of ciliogenesis in these cells is characterized morphologically by appearance of MTOC, filosomes and centrioles throughout the apical cytoplasm. Tracheas removed during the period of ciliated cell differentiation which occurs 50-60 hr after minor mechanical injury were paraformaldehyde fixed and specific affinity sites for antitropomyosin and antimyosin antibodies were demonstrated by an indirect immunoperoxidase technique. The epithelium, after development of the osmiophilic reaction product, was embedded in epoxy and observed unstained with an electron microscope. Both antibodies had similar and specific binding sites in filosomes, MTOCs, microfilaments and on the microtubule triplets and foot processes of centrioles. Such localization suggests that these mechanochemical proteins may in addition to microfilament stabilization and contraction serve a specialized function in ciliogenesis.     

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     

Effect of a food ration with a low-protein content on the processes of liver parenchyma recovery in rats after tetrachloromethane damage

Male Wistar rats weighing 190-200 g were fed a low protein diet. Atrophy of cytoplasm was observed after a 3-week malnutrition. In early periods of liver regeneration (6 hr after CCl4 poisoning), an increase in DNA synthesis was accompanied by an increase in summary concentration of organelle membranes. Though their ploidy was higher than in the control, volume of hepatocytes and summary area of organelles surface membrane was smaller than in standard diet. These data show a reduced capacity for realization of genetic program during the regeneration period in protein-deficient rats.     

A reliable, noninvasive technique for spindle imaging and enucleation of mammalian oocytes

Factors affecting the efficiency of animal cloning remain to be elucidated. Enucleation of recipient oocytes is a critical step in cloning procedures and typically is performed by aspirating a portion of the cytoplasm underlying the first polar body. Enucleation is evaluated using epifluorescence after Hoechst staining for DNA, which may disrupt functions of the cytoplast, especially mitochondria. Mitochondrial DNA in Dolly and other cloned sheep has been shown to derive exclusively from recipient oocytes. Not only might evaluation of the aspirated karyoplast portion inadequately reflect the state of the cytoplast, it is also time consuming. Here we report a reliable, noninvasive technique for spindle imaging and enucleation of oocytes using a new microscope, the Pol-Scope. The efficiency of enucleation was 100%, and only 5.5% of the oocytes' mitochondria entered the karyoplast upon Pol-Scope-directed removal of the spindle. Moreover, Pol-Scope imaging of spindles and micromanipulation did not compromise the developmental competence of reconstituted oocytes and cytoplasts.     

Telophase enucleation: An improved method to prepare recipient cytoplasts for use in bovine nuclear transfer

The enucleation of oocytes to be used as host cytoplasts for embryo reconstruction by nuclear transfer is an important limiting step when cloning mammals. We propose an enucleation technique based on the removal of chromatin after oocyte activation, at the telophase stage, by aspirating the second polar body and surrounding cytoplasm. In a preliminary experiment to determine an optimal activation protocol, oocytes were matured for 26 and 30 hr and exposed for 5 min to 7% ethanol and/or for 3 hr at either 25 or 4°C. Relative to most activation treatments tested, oocytes matured for 30 hr and exposed to ethanol alone showed highest activation rates, as determined by low levels of H1 kinase activity within 90 min from exposure and high pronuclear formation (82%) after 12 hr of culture. No synergistic effect on activation rates was observed when oocytes also were exposed to reduced temperature after ethanol treatment. Microsurgical removal of the telophase-stage chromatin in a small volume of cytoplasm adjacent to the second polar body was significantly more effective in enucleating than aspiration of a larger cytoplasm volume surrounding the first polar body of metaphase-arrested oocytes (98% versus 59%; P < 0.01). Moreover, compared with a nuclear transfer protocol based on enucleation of metaphase-arrested oocytes followed by aging and cooling, more (38% versus 16%; P < 0.001) and better-quality blastocytes (126 versus 84 nuclei per blastocyst; P < 0.02) were obtained from embryos reconstructed using the telophase procedure. Higher development potential of embryos reconstructed by the telophase procedure may be attributed to (1) the selection of oocytes that activate and respond by extruding the second polar body, (2) avoiding the use of DNA dyes and ultraviolet irradiation, and (3) the limited removal of cytoplasm during enucleation. The ease with which telophase enucleation can be performed is likely to render this technique widely useful for research and practice on mammalian cloning. Mol. Reprod. Dev. 49:29–36, 1998. © 1998 Wiley-Liss, Inc.