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.     

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.     

Intracellular location of unoccupied 1,25-dihydroxyvitamin D receptors: a nuclear-cytoplasmic equilibrium

In order to investigate the subcellular distribution of unoccupied 1,25-dihydroxyvitamin D3 receptors, highly purified cytoplasts and nucleoplasts were prepared from two kidney cell lines (PK1 and MDBK). This was accomplished utilizing the technique of enucleation by cytochalasin B and density gradient centrifugation. Unoccupied 1,25-dihydroxyvitamin D3 receptors were found in both the nuclear and cytosolic compartments, with approximately 70% of the receptors localized in the cytoplasm. When cells were pretreated with 1,25-[3H]dihydroxyvitamin D, prior to enucleation, it was found that 90% of the receptor-hormone complex was associated with nucleoplasts, thus demonstrating that cytochalasin B treatment does not alter the high-affinity association of the receptor-hormone complex with the nucleus. The ratio of unoccupied receptor/protein was found to be the same in whole cells, cytoplasts, and nucleoplasts for both cell types. The ratio of unoccupied receptor/DNA was highest in cytoplasts and lowest in nucleoplasts. Taken together, these data indicate that the unoccupied 1,25-dihydroxyvitamin D receptor is generally associated with cell proteins and not specifically associated with cell DNA. We therefore propose, at least for these cells, that the unoccupied 1,25-dihydroxyvitamin D receptor exists in equilibrium between the nuclear and cytosolic compartments of the whole cell, and receptor-hormone binding shifts this equilibrium to favor nuclear localization.     

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.     

Cytoplasmic regulation of two G1-specific temperature-sensitive functions

tsAF8 and ts13 cells are temperature-sensitive (ts) mutants of BHK cells that specifically arrest, at nonpermissive temperature, in the G1 phase of the cell cycle. These two mutants can complement each other. Both cell lines can be made quiescent by serum deprivation (G0). When subsequently stimulated by serum, they can enter S phase at 34 degrees C but not at 39.5 degrees-40.6 degrees C. We have used these mutants to determine whether the nucleus is needed during the G0 leads to S transition for the expression of the G1 ts functions. For this purpose, we fused cytoplasts of G0-tsAF8 with whole ts13 cells in G0, and cytoplasts of G0-ts13 with whole tsAF8 cells in G0. Serum stimulation at the nonpermissive temperature induced DNA synthesis in both types of such fusion products. No DNA synthesis was induced by serum stimulation at the nonpermissive temperature in fusion products constructed between either G0-tsAF8 cytoplasts and whole G0-tsAF8 cells or G0-ts13 cytoplasts and whole G0-ts13 cells. These results demonstrate that the information for these two ts functions, which are required for entry of serum-stimulated cells into the S phase, are already present in the cytoplasm of G0 cells--that is, before serum stimulation commits them to the transition from the nonproliferating to the proliferating state.     

Pigmentation and tumorigenicity of reconstituted, cybrid and hybrid mouse cells

Cybrid, reconstituted and hybrid cells were formed by fusing cytoplasts with whole cells, cytoplasts with nucleoplasts, or whole cells with whole cells, respectively. The cells or cellular fragments were derived from murine melanomas expressing melanocytic functions and from tumorigenic or non-tumorigenic fibroblasts. The cybrids and reconstituted cells resembled the nuclear donor parent in the expression of melanocytic activity and tumorigenicity. The hybrid cells resembled the fibroblastic parent when comparable numbers of chromosomes were present from each parent. A ratio of 1.5:1 in favor of the melanoma genome resulted in hybrids of either phenotype. The expression and extinction of melanocytic functions and the expression and suppression of tumorigenicity were transmitted only through the nucleus. The stable expression of A-type viral particles, on the other hand, may have been inherited also by cytoplasmic transfer.     

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.     

Energy-dependent accumulation of daunorubicin into subcellular compartments of human leukemia cells and cytoplasts.

Anthracycline accumulation was evaluated by flow cytometry or radiolabeled drug assays in cells and cytoplasts (enucleated cells) prepared from parental and multidrug-resistant human K562 leukemia cells. Treatment with energy inhibitors, such as dinitrophenol (DNP) or sodium azide/deoxyglucose, led to a marked decrease in daunorubicin accumulation in parental cells and cytoplasts. Another ionophore, monensin, also caused a significant decrease in daunorubicin accumulation; however, ATPase inhibitors ouabain, vanadate, and N-ethylamaleimide had little or no effect. The lysosomatropic agents chloroquine and methylamine caused a moderate decrease in anthracycline accumulation. Fluorescence microscopy showed that the DNP-sensitive daunorubicin uptake occurred in a nonnuclear subcellular compartment. Studies using increasing daunorubicin concentrations demonstrated fluorescence quenching that occurred in the nonnuclear, DNP-sensitive compartment. The effect of inhibitors on the accumulation of rhodamine 123 and acridine orange strongly implicated lysosomes as the principal compartment of this inhibitable daunorubicin accumulation. Cytoplasts from P-glycoprotein containing multidrug-resistant K562 cells demonstrated a verapamil-reversible, decreased daunorubicin accumulation that was observed in resistant whole cells. Verapamil pretreatment of cytoplasts from resistant cells revealed the subcellular DNP-sensitive uptake present in parental cytoplasts. These studies demonstrate that cytoplasts are an effective means to study drug transport in mammalian cells without nuclear drug binding. Parental K562 cells and cytoplasts exhibit an energy-dependent accumulation of daunorubicin into cytoplasmic organelles that is also present in resistant cells and cytoplasts when P-glycoprotein mediated efflux is inhibited.     

Functional activity of enucleated human polymorphonuclear leukocytes

Enucleated human polymorphonuclear leukocytes (PMN) were prepared by centrifuging isolated, intact PMN over a discontinuous Ficoll gradient that contained 20 microM cytochalasin B. The enucleated cells (PMN cytoplasts) contained about one-third of the plasma membrane and about one-half of the cytoplasm present in intact PMN. The PMN cytoplasts contained no nucleus and hardly any granules. The volume of the PMN cytoplasts was about one-fourth of that of the original PMN. Greater than 90% of the PMN cytoplasts had an "outside-out" topography of the plasma membrane. Cytoplasts prepared from resting PMN did not generate superoxide radicals (O2-) or hydrogen peroxide. PMN cytoplasts incubated with opsonized zymosan particles or phorbol-myristate acetate induced a respiratory burst that was qualitatively (O2 consumption, O2- and H2O2 generation) and quantitatively (per unit area of plasma membrane) comparable with that of intact, stimulated PMN. Moreover, at low ratios of bacteria/cells, PMN cytoplasts ingested opsonized Staphylococcus aureus bacteria as well as did intact PMN. At higher ratios, the cytoplasts phagocytosed less well. The killing of these bacteria by PMN cytoplasts was slower than by intact cells. The chemotactic activity of PMN cytoplasts was very low. These results indicate that the PMN apparatus for phagocytosis, generation of bactericidal oxygen compounds, and killing of bacteria, as well as the mechanism for recognizing opsonins and activating PMN functions, are present in the plasma membrane and cytosol of these cells.     

Radial-organized microtubules provide cell shape support and more effective intercellular transport then free microtubules

Microtubules take part in various cell processes, including cell polarization, migration, intercellular transport, and some others. Therefore, the spatial organization of microtubules is crucial for normal cell behavior. Fibroblasts have radial microtubule arrays that consist of microtubules that run from the centrosome. Two components compose this microtubule array, i.e., (1) minus ends attached to the centrosome microtubules with their plus ends radiating to the cell periphery and (2) free microtubules with ends not attached to the centrosome. Distinctions in the dynamic properties, intercellular organization, and structure of centrosome-attached and free microtubules allow us to assume that their cellular functions are also different. To study centrosome-attached and free microtubules functions, we used cytoplasts, i.e., nucleus-lacking cellular fragments that, under certain conditions, also lose their centrosomes. In these cytoplasts, there are only free microtubules. The shape, general morphology, and size of cytoplasts that retain their centrosomes differ only slightly from whole cells. Cytoplasts who have lost their centrosomes have an extremely thin network of microtubules located in their central region; furthermore, they lose the shape that is typical for fibroblast and become rough lamellae with protrusions. The internal architecture of the cytoplasm and organoid arrangement are also broken. Saltatory movements in cytoplasts with centrosomes are similar to those in whole cells; in cytoplasts without centrosomes, saltatory movements occur with velocities that are twofold less and by shorter distances. Saltatory movements of granules in centrosome-lacking cytoplasts took place basically in the central region of cytoplast and were less ordered than in whole cells and in cytoplasts with centrosomes. We believe that radial organized microtubules ensure the effective transport and dynamical interaction of microtubule plus ends with cellular cortical structures, which is sufficient to support the common fibroblast-like shape, whereas the disorganized free microtubules are not able to maintain the external fibroblast shape and its intercellular organization.     

Similarities in ornithine decarboxylase regulation in intact and enucleated 3T3 cells

The role of the cytoplasm in the regulation of ornithine decarboxylase (ODC) has been examined in enucleated 3T3 cells (cytoplasts). ODC activity can be increased 15–25-fold by a cytoplasmic mechanism(s) in enucleates prepared from growing cells by treatment which lead to 50–75-fold increases in intact growing cells. Since the enzyme activity simultaneously becomes less stable in these cytoplasts as in whole cells, it appears this increase is due either to activation of pre-existing enzyme or increased synthesis. A biphasic increase during the first 20 h after stimulus is seen in cytoplasts prepared from growing cells which have been stimulated for the prior 5 h. The second increase in activity does not appear to be due to decreased degradation or conversion to a more active form. These results are analogous to those reported previously for intact growing cells in experiments which employed metabolic inhibitors, and similarly suggest that there is cytoplasmic control of ODC synthesis. Medium polyamines reduce ODC activity in cytoplasts with kinetics and characteristics similar to those previously reported for intact cells. These data are also most consistent with regulation of synthesis at the translational level.     

The Na+ gradient hypothesis in cytoplasts derived from Ehrlich ascites tumor cells

The concentration gradients of Na⁺ and the non-metabolizable amino acid, α-aminoisobutyric acid, and the membrane potential were measured in cytoplasts derived from Ehrlich ascites tumor cells in order to test the Na⁺ gradient hypothesis for the active transport of neutral amino acids in animal cells. According to this hypothesis, the Na⁺ electrochemical gradient and the amino acid activity gradient should be equal at the steady state. It has been difficult to measure the Na⁺ electrochemical gradient in intact Ehrlich cells because Na⁺ may be sequestered in the nuclei of these cells. This problem is avoided with cytoplasts derived from Ehrlich cells because they do not contain internal compartments where Na⁺ could be sequestered. Since these cytoplasts also maintain steady state concentrations of Na⁺, K⁺, and α-aminoisobutyric acid similar to those found in whole Ehrlich cells, they are uniquely suited for testing the Na⁺ gradient hypothesis. Assuming the activity coefficients of external and cytoplasmic Na⁺ are equal, the energy in the Na⁺ electrochemical gradient of cytoplasts was 90% of that in the α-aminoisobutyric acid concentration gradient at the steady state. If the Na⁺ gradient hypothesis is correct, the 10% difference between these two gradients cannot be explained in terms of the sequestration of Na⁺ in the nucleus because cytoplasts do not contain internal compartments.     

Nucleus-dependent regulation of tyrosine aminotransferase degradation in hepatoma tissue culture cells.

Upon removal of the nucleus from rat hepatoma tissue culture cells, levels of the enzyme tyrosine aminotransferase no longer change in response to withdrawal of glucocorticoids. The rate of tyrosine aminotransferase degradation is drastically reduced in rat hepatoma tissue culture cytoplasts leading to stabilization of pre-existing levels of tyrosine aminotransferase. Moreover, the rate of synthesis of the enzyme in cytoplasts is very low near that observed in uninduced whole cells. These effects of enucleation occur very rapidly and appear to be specific for tyrosine aminotransferase and a small number of other unstable hepatoma proteins. A nuclear effect is thus directly involved in the control of tyrosine aminotransferase degradation and synthesis.     

Retention of autoregulatory control of tubulin synthesis in cytoplasts: demonstration of a cytoplasmic mechanism that regulates the level of tubulin expression

Virtually all animal cells rapidly and specifically depress synthesis of new alpha- and beta-tubulin polypeptides in response to microtubule inhibitors that increase the pool of depolymerized subunits, or in response to direct elevation of the cellular tubulin subunit content through microinjection of exogenous tubulin subunits. Collectively, these previous findings have documented the presence of an apparent eucaryotic, autoregulatory control mechanism that specifies the level of expression of tubulin in cultured animal cells. Mechanistically, this regulation of tubulin synthesis is achieved through modulation of tubulin mRNA levels. To dissect further the molecular pathway that underlies this autoregulatory phenomenon, we have now investigated whether enucleated cells still retain the requisite regulatory machinery with which to alter tubulin synthetic levels in response to fluctuations in the pool size of unpolymerized tubulin subunits. Using two-dimensional gel electrophoresis to analyze the patterns of new polypeptide synthesis, we have determined that such cytoplasts can indeed respond to drug-induced microtubule depolymerization by specific repression of new beta-tubulin synthesis. Moreover, the response of cytoplasts is, if anything, greater in magnitude than that of whole cells. We conclude that autoregulatory control of beta-tubulin gene expression must derive principally, if not exclusively, from a cytoplasmic control mechanism that modulates beta-tubulin mRNA stability. For alpha-tubulin, although the response of cytoplasts after drug-induced microtubule depolymerization is quantitatively less dramatic than that of whole cells, at least part of the regulatory machinery must also be activated through a cytoplasmic regulatory event.     

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.     

A staining procedure for identifying viable cell hybrids constructed by somatic cell fusion, cybridization, or nuclear transplantation

A general procedure for identifying viable hybrid cells was developed. One cell type was labeled by a brief incubation in the Kodak laser dye rhodamine 123, which accumulates in the mitochondria; a second cell type was labeled by a brief incubation in the Hoechst fluorochrome 33258, which binds to chromatin. The substances which are eventually lost from the organelles, appeared to be nontoxic; the plating efficiencies of numerous cell lines tested was unaffected. Either whole cells or cytoplasts labeled with rhodomine 123 were fused, using inactivated Sendai virus, to whole cells or karyoplasts labeled with Hoechst 33258. When living cells were illuminated with ultraviolet light, individual whole cell hybrids, cybrids or cytoplasmic- nuclear hybrid cells could be rapidly identified by the appropriate staining pattern.     

N-formylpeptide-receptor dynamics, cytoskeletal activation, and intracellular calcium response in human neutrophil cytoplasts

Cytoplasts (enucleated neutrophils which are depleted of dense granules) were prepared from human neutrophils with a modified procedure which employed dihydrocytochalasin B instead of cytochalasin B. These cytoplasts retained an activatable cytoskeletal network similar to cells in that filamentous actin polymerization in response to an N-formylpeptide (fluoresceinated N-formyl-nle-leu-phe-nle-tyr-lys, FLPEP) occurred with similar dose-response characteristics and was inhibitable by cytochalasin B and dihydrocytochalasin B. Cytoplasts had the same number of receptors per surface area as cells and binding constants and dissociation kinetics were the same for cells and cytoplasts. The conversion of receptors from a rapidly dissociating form to a slowly dissociating form was comparable in cells and cytoplasts. This conversion was not inhibited by cytochalasins and thus did not require actin polymerization. Cytoplasts were capable of internalizing 30% of bound FLPEP after 3 min of binding. Cytochalasins did not block this internalization which thus did not appear to require actin polymerization. After 5 min of binding, [3H]-N-formyl-met-leu-phe cosedimented with the Golgi marker enzymes when cytoplasts were fractionated on sucrose density gradients after N2 cavitation. These results indicate that the internalization mechanism is functional in cytoplasts. The Indo-1-detectable calcium response in cytoplasts had a ED50 similar to cells, though the maximum increase in Ca2+ concentration was about one-half that of cells. The response recovered with time after stimulation and the calcium detected was primarily from intracellular stores. The decay of responses after addition of formylpeptide antagonists was parallel for cells and cytoplasts, and leukotriene B4-induced responses in both cells and cytoplasts. Thus the regulation of the responses in cells and cytoplasts was analogous.     

An improved cellular enucleation method with extracellular matrix and colchicine facilitates the study of nucleocytoplasmic interaction

Enucleated mammalian cells (cytoplasts) have been widely used for studying differential roles of the cytoplasm and nucleus in various cellular processes. Here, we reported an improved enucleation protocol, in which cells were seeded in extracellular matrix (ECM)-coated 24-wells and spun at 4600 g and 35 °C for 60 min in the presence of cytochalasin B and colchicine. When glass-bottom wells were used, cellular structures and organelles in cytoplasts could be examined directly by confocal microscopy. Nuclear envelope rupture did not occur probably due to mild centrifugation conditions used in this study. Addition of paclitaxel or doxorubicin completely blocked proliferation of residual nucleated cells; however, to our surprise, paclitaxel dramatically prolonged the survival of cytoplasts. Results from Annexin V and Propidium Iodide staining showed that cytoplasts died predominantly by apoptosis, which was partially inhibited by ECM and further by paclitaxel. Mitochondria were mostly rod-shaped and formed a connected network in paclitaxel-treated cytoplasts, indicating lack of fusion and fission dynamics. Moreover, paclitaxel increased mitochondrial membrane potential, suggesting that perturbation of mitochondria might be critical to the survival of cytoplasts. In conclusion, we had established an efficient and fast procedure for enucleation of adherent animal cells, which could facilitate the investigation of nucleocytoplasmic interaction.     

Dependence of DNA synthesis and in vitro development of bovine nuclear transfer embryos on the stage of the cell cycle of donor cells and recipient cytoplasts

The effect of the stage of the cell cycle of donor cells and recipient cytoplasts on the timing of DNA replication and the developmental ability in vitro of bovine nuclear transfer embryos was examined. Embryos were reconstructed by fusing somatic cells with unactivated recipient cytoplasts or with recipient cytoplasts that were activated 2 h before fusion. Regardless of whether recipient cytoplasts were unactivated or activated, the embryos that were reconstructed from donor cells at the G0 phase initiated DNA synthesis at 6-9 h postfusion (hpf). The timing of DNA synthesis was similar to that of parthenogenetic embryos, and was earlier than that of the G0 cells in cell culture condition. Most embryos that were reconstructed from donor cells at the G1/S phase initiated DNA synthesis within 6 hpf. The developmental rate of embryos reconstructed by a combination of G1/S cells and activated cytoplasts was higher than the rates of embryos in the other combination of donor cells and recipient cytoplasts. The results suggest that the initial DNA synthesis of nuclear transfer embryos is affected by the state of the recipient oocytes, and that the timing of initiation of the DNA synthesis depends on the donor cell cycle. Our results also suggest that the cell cycles of somatic cells synchronized in the G1/S phase and activated cytoplasts of recipient oocytes are well coordinated after nuclear transfer, resulting in high developmental rates of nuclear transfer embryos to the blastocyst stage in vitro.