Clonal isolation and characterization of myoblast-like reconstituted cells formed by fusion of karyoplasts from mouse teratocarcinoma cells with rat myoblast cytoplasts

To examine the roles of the cytoplasms of differentiated somatic cells on nuclear gene expression, reconstituted cells (RC-cells) were isolated clonally by fusing karyoplasts (isolated nuclei) from neomycin-resistant mouse teratocarcinoma PCC4-neor cells with cytoplasts (isolated cytoplasms) of chloramphenicol (CAP)-resistant rat myoblasts L6TG.CAPr cells, and after double selection in the medium containing 400 micrograms/ml of neomycin and 100 micrograms/ml of CAP (G418 plus CAP medium). The RC-cells were characterized by the presence of two genetic markers, neomycin- and CAP-resistance, by the absence of latex beads which had incorporated into karyoplast donor PCC4-neor cells as a cytoplasmic physical marker, and by the similar karyotypes as that of parental PCC4-neor cells. In contrast to the teratocarcinoma cybrids previously isolated, all the isolated RC-clones expressed myoblast-like morphologies of three types. The phenotypic expression of these RC-cells was compared with that of PCD-1 cells, a teratocarcinoma-derived myoblast line. RC-cells and PCD-1 cells did not express alkaline phosphatase (ALPase) activity while parental PCC4-neor expressed it strongly. After induction of myogenic differentiation by treatments with excess thymidine and conditioned medium, two clones were capable of forming short multinucleated cells. The protein synthetic patterns of RC-cells analysed by two-dimensional polyacrylamide gel were different from PCC4-neor cells, and quite resembled those of PCD-1 cells. Particularly, multinucleated RC-clones expressed alpha-tropomyosin, and contained 10 nm filaments, characteristic markers of early myogenic cells. These results suggest that the RC-cells are myoblast-like cells, that a few of them maturate to partially differentiated myogenic cells, that the rat myoblast cytoplasm contains regulatory factor(s) able to determine the myogenic cell lineage of the undifferentiated stem cells, and that this factor is continuously expressed in these myoblasts.     

Cloned mice derived from embryonic stem cell karyoplasts and activated cytoplasts prepared by induced enucleation

Our objective was to induce enucleation (IE) of activated mouse oocytes to yield cytoplasts capable of supporting development following nuclear transfer. Fluorescence microscopy for microtubules, microfilaments, and DNA was used to evaluate meiotic resumption after ethanol activation and the effect of subsequent transient treatments with 0.4 micro g/ml of demecolcine. Using oocytes from B6D2F1 (C57BL/6 x DBA/2) donors, the success of IE of chromatin into polar bodies (PBs) was dependent on the duration of demecolcine treatment and the time that such treatment was initiated after activation. Similarly, variations in demecolcine treatment altered the proportions of oocytes exhibiting a reversible compartmentalization of chromatin into PBs. Treatment for 15 min begun immediately after activation yielded an optimized IE rate of 21% (n = 80) when oocytes were evaluated after overnight recovery in culture. With this protocol, 30-50% of oocytes were routinely scored as compartmentalized when assessed 90 min postactivation. No oocytes could be scored as such following overnight recovery, with 66% of treated oocytes cleaving to the 2-cell stage (n = 80). Activated cytoplasts were prepared by mechanical removal of PBs from oocytes whose chromatin had undergone IE or compartmentalization. These cytoplasts were compared with mechanically enucleated, metaphase (M) II cytoplasts whose activation was delayed in nuclear transfer experiments using HM-1 embryonic stem cells. Using oocytes from either B6D2F1 or B6CBAF1 (C57BL/6 x CBA) donors, the in vitro development of cloned embryos using activated cytoplasts was consistently inferior to that observed using MII cytoplasts. Live offspring were derived from both oocyte strains using the latter, whereas a single living mouse was cloned from activated B6CBAF1 cytoplasts.     

DNA synthesis in permeabilized karyoplasts from cytochalasin B-enucleated mouse L cells

DNA synthesis was examined in karyoplasts permeabilized by hypotonic buffer or lysolecithin. DNA synthesis was not affected by the omission of a single deoxyribonucleated triphosphate but was greatly reduced in the absence of three of the deoxyribonucleotide triphosphates. The rate of DNA synthesis was linear for 40 min and continued for up to 2–3 h. The DNA synthesized in the permeabilized karyoplasts was a continuation of semi-conservative replication occurring in the intact cell.     

Isolation of viable mouse primordial germ cells by antibody-directed flow sorting

The germ line represents a cell type of unique interest in mammals because it retains complete genotypic totipotency while undergoing significant phenotypic differentiation. Analysis of the mechanism that underlies the maintenance of this totipotency requires the ability to isolate and study all stages of the germ cell lineage. The primordial germ cells (PGC) are the earliest identifiable germ cells in the embryo. It has not previously been possible to isolate PGC in sufficient numbers and purity to facilitate biochemical and/or molecular analysis. We report here that the use of a monoclonal antibody in combination with flow cytometry does permit the isolation of reasonably large and pure yields of viable mouse PGC.     

Immortalization of human lymphocytes by fusion with cytoplasts of transformed mouse L cells

Fusion of mouse L929 cytoplasts with human peripheral blood lymphocytes induced lymphocyte proliferation that gave rise to lymphoid cell lines of B and T cell origin with unlimited growth potential. The immortalized cell lines were routinely grown in standard medium supplemented with fetal calf serum. Furthermore these cell lines could be propagated in chemically defined serum-free media. Each establishment of lymphoid cell lines was preceded by a proliferation phase 2 wk after cytoplast/cell fusion, which appears to be a necessary step in the immortalization process. The immortalized cells have a nearly normal human karyotype, do not form colonies in soft agar medium, and are not tumorigenic in nude mice. Cloned B cell lines produced human immunoglobulins of heavy and light chain types. No cross-reaction with DNA of herpes simplex virus, human cytomegalovirus, human T cell leukemia/lymphoma virus I and II, or polyoma virus was detected in the genome of immortalized cell lines by Southern blot hybridization. Furthermore B and T cell lines were established that appear to be free of Epstein-Barr virus genome.     

Isolation and characterization of cytoplasts and miniprotoplasts derived from protoplasts of cultured cells

We have isolated and partially characterized subprotoplasts containing nuclei, i.e. miniprotoplasts, and enucleated subprotoplasts, i.e. cytoplasts, from freshly isolated protoplasts of cultured cells from Hyoscyamus muticus, Nicotiana tabacum and especially Zea mays . Protoplasts were fragmentated by centrifugation through discontinuous iso-osmotic density gradients containing colloidal silaca gel (Percoll), calcium chloride and mannitol. Using this method metabolically active miniprotoplasts and highly purified cytoplast fractions with less than 4% contamination with nucleated protoplasts were obtained. The cytoplasts prepared by our method are suitable for use in fusion experiments aimed at transferring nuclear and cytoplasmic genetic information separately.     

Isolation and characterization of cytoskeletons from cotton fiber cytoplasts

Summary Over the last 25 yr, success in characterizing the individual protein components of animal cytoskeletons was possible, in part, due to technical advances in the isolation and purification of anucleate cytoskeletons from animal cells. As a step towards characterizing protein components of the plant cytoskeleton, we have isolated cytoskeletons from cytoplasts (anucleate protoplasts) prepared from cotton fiber cells grown in ovule culture. Cytoplasts isolated into a hypertonic, Ca²⁺-free medium at pH 6.8 retained internal structures after extraction with the detergent, Triton X-100. These structures were shown to include microtubule and microfilament arrays by immunofluorescence and electron microscopy. Actin and tubulin were the only abundant proteins in these preparations, suggesting that microfilaments and microtubules were the major cytoskeleta elements in the isolated cytoskeletons. The absence of additional, relatively abundant proteins suggests that (a) other cytoskeletal arrays potentially present in fiber cells (e.g., intermediate filaments) were either lost during detergent extraction or were minor components of the fiber cell cytoskeleton; and (b) high ratios of individual cytoskeletal-associated proteins relative to actin and tubulin were not required to maintain microtubules and microfilaments in organized structures.     

Cryoinjury in human granulocytes and cytoplasts.

Although most isolated cells can be successfully cryopreserved, human granulocytes have little functional recovery after cryopreservation, even under optimized conditions. Cytoplasts, which are vesicles created from human granulocytes by depletion of organelles including granules and the nucleus, can carry out some of the complex functions of the parent granulocyte such as phagocytosis of bacteria, even after cryopreservation. Human granulocytes and cytoplasts were used in this comparative study of low-temperature responses to assess the relative importance of the plasma membrane and the granules in cryoinjury to human granulocytes. Boyle-van't Hoff plots of cell volume as a function of the reciprocal of osmolality showed that granulocytes and cytoplasts have similar osmometric behavior and equivalent osmotically inactive fractions. The hydraulic conductivities were also similar, indicating that the osmotic properties of the plasma membrane and cytoplasm were retained during preparation of the cytoplasts. Assessment of membrane integrity using fluorescein diacetate after graded freezing stresses showed that the low-temperature responses of cytoplasts were similar to those of human lymphocytes and hamster fibroblasts, with recoveries much higher than those of human granulocytes, particularly after post-thaw incubation at 37 degrees C. The results indicate that the plasma membrane is not the primary site of injury to granulocytes during freezing and thawing, and suggest that activation of cytoplasmic elements, such as granules, may constitute the early events in cryoinjury to human granulocytes. These studies have significance in approaches to the cryopreservation of granulocytes and other types of cells, such as platelets, with increased sensitivity to the conditions encountered during freezing and thawing.     

Isolation and purification of viable Ureaplasma urealyticum cells free from medium components

A procedure was devised to produce Ureaplasma urealyticum preparations free of adsorbed components of the growth medium, which contains high concentrations of serum. The ureaplasmas were cultivated in a medium containing PPLO-serum fraction as a replacement for horse serum. High titres of ureaplasmas (greater than 10(7) c.f.u. ml-1) were obtained. Harvested cells were then purified by Urografin density gradient centrifugation. By use of 3H-labelled ureaplasma cells and 125I-labelled medium components, a distinct band of viable cells devoid of serum constituents was demonstrated. The absence of medium components was verified by immunoblotting cells from this band with antiserum to medium components. Medium components that had been present before the purification procedure were undetectable in the purified cell fraction obtained. The viability of the purified ureaplasma cells represented an 85% recovery rate and their antigenicity, examined with anti-serotype specific antiserum, remained intact. This easy and reproducible procedure can be used to prepare purified ureaplasmas for investigation of ureaplasmal antigens and their expression and/or role in disease.     

Isolation of a concanavalin A receptor from mouse L cells.

A cell surface glycoprotein receptor for concanavalin A (Con A) has been isolated from mouse L cells. The isolation procedure involved dissolving whole L cells in 0.3 M lithium diiodosalicylate and extracting with aqueous phenol. The Con A receptor, which was found in the aqueous phase of this extract, was further purified by affinity chromatography on a column of Con A-Sepharose; the receptor was adsorbed to Con A-Sepharose and eluted with 0.1 M methyl alpha-D-glucopyranoside or with 0.1 M methyl alpha-D-mannopyranoside, but not with other monosaccharides. The cell surface location of the Con A receptor purified in this way was confirmed by showing that it can be isolated from purified L cell plasma membranes and by demonstrating that it can be labeled from the exterior surface of intact L cells by the nonpenetrating galactose oxidase-KB3H4 system. Biochemical studies of the Con A receptor have shown that it migrates on sodium dodecyl sulfate-polyacrylamide gels as a single component having an apparent molecular weight of approximately 100,000. Its N-terminal amino acid is valine and it has carbohydrate attached at several (at least five) different sites along the polypeptide chain.     

Isolation and separation of highly enriched fractions of viable mouse gastric parietal cells by velocity sedimentation

Methods of tissue dissociation and cell separation have been modified to obtain highly enriched fractions of mouse gastric parietal cells. Suspension of gastric mucosal cells are prepared by pronase digestion of the glandular portion of the stomach from adult mice. By utilizing the velocity sedimentation technique to separate cells of different sizes it is possible to recovery parietal cells, which are larger than the other cell types, in fractions with purity of 75-95%. The homogeneity of cell fractions has been assessed by light and electron microscopy. The ability of the isolated cells to exclude the dye trypan blue, to incorporate labeled substrate, to consume oxygen, and to retain their structural integrity indicates that they are viable and still capable of functional activity.     

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.     

Hoechst fluorescence intensity can be used to separate viable bromodeoxyuridine-labeled cells from viable non-bromodeoxyuridine-labeled cells

BACKGROUND: 5-Bromo-2'-deoxyuridine (BrdU) is a powerful compound to study the mitotic activity of a cell. Most techniques that identify BrdU-labeled cells require conditions that kill the cells. However, the fluorescence intensity of the membrane-permeable Hoechst dyes is reduced by the incorporation of BrdU into DNA, allowing the separation of viable BrdU positive (BrdU+) cells from viable BrdU negative (BrdU-) cells. METHODS: Cultures of proliferating cells were supplemented with BrdU for 48 h and other cultures of proliferating cells were maintained without BrdU. Mixtures of viable BrdU+ and viable BrdU- cells from the two proliferating cultures were stained with Hoechst 33342. The viable BrdU+ and BrdU- cells were sorted into different fractions from a mixture of BrdU+ and BrdU- cells based on Hoechst fluorescence intensity and the ability to exclude the vital dye, propidium iodide. Subsequently, samples from the original mixture, the sorted BrdU+ cell population, and the sorted BrdU- cell population were immunostained using an anti-BrdU monoclonal antibody and evaluated using flow cytometry. RESULTS: Two mixtures consisting of approximately 55% and 69% BrdU+ cells were sorted into fractions consisting of greater than 93% BrdU+ cells and 92% BrdU- cells. The separated cell populations were maintained in vitro after sorting to demonstrate their viability. CONCLUSIONS: Hoechst fluorescence intensity in combination with cell sorting is an effective tool to separate viable BrdU+ from viable BrdU- cells for further study. The separated cell populations were maintained in vitro after sorting to demonstrate their viability.     

Cytogenetic analysis of reconstituted one-cell mouse embryos derived from nuclear transfer of fetal male germ cells.

Micromanipulation techniques were used to produce reconstituted one-cell mouse embryos after the fusion of fetal male germ cells 15.5 day post coitum with enucleated secondary oocytes. At this stage of development, male fetal germ cells are arrested at G1 of mitotic interphase. Two distinct populations of germ cells, differing in size and ploidy, were isolated from the genital ridge of a mid-term fetus. Oocytes that had received male germ cells from the population of smaller (mononuclear) germ cells developed as diploid one-cell reconstituted embryos. When the same procedures were used to produce reconstituted one-cell embryos using male fetal germ cells from a population of larger (multinucleate) cells, they exhibited ploidy of either 4x, 6x or 8x at metaphase of the first cell division. Although most reconstituted embryos (90 and 96%) developed to the two-cell stage, the proportion of embryos receiving small germ cells developed to blastocysts was much higher (62%) than that receiving large germ cells (4%). These studies indicate that not all fetal germ cells are diploid before the onset of meiosis and have identified procedures to produce reconstituted embryos from fetal germ cells that do not carry genome or chromosome anomalies.     

Isolation of epiblast stem cells from preimplantation mouse embryos

Pluripotent stem cells provide a platform to interrogate control elements that function to generate all cell types of the body. Despite their utility for modeling development and disease, the relationship of mouse and human pluripotent stem cell states to one another remains largely undefined. We have shown that mouse embryonic stem (ES) cells and epiblast stem cells (EpiSCs) are distinct, pluripotent states isolated from pre- and post-implantation embryos respectively. Human ES cells are different than mouse ES cells and share defining features with EpiSCs, yet are derived from pre-implantation human embryos. Here we show that EpiSCs can be routinely derived from pre-implantation mouse embryos. The preimplantation-derived EpiSCs exhibit molecular features and functional properties consistent with bona fide EpiSCs. These results provide a simple method for isolating EpiSCs and offer direct insight into the intrinsic and extrinsic mechanisms that regulate the acquisition of distinct pluripotent states.     

Production of functional spermatids from mouse germline stem cells in ectopically reconstituted seminiferous tubules

Testicular germ cell transplantation into the seminiferous tubules is at present the only way to induce spermatogenesis from a given source of spermatogonial stem cells. Here we show an alternative method that harnesses the self-organizing ability of testicular somatic cells. The testicular cells of embryonic or neonatal mice or rats and of newborn pigs were dissociated into single cells. Each of them reorganized into a tubular structure following implantation into the subcutis of immunodeficient mice. When mouse germline stem (GS) cells derived from spermatogonial stem cells and expanded in culture were intermingled with testicular cells of rodents, they were integrated in the reconstituted tubules and differentiated beyond meiosis into spermatids. Normal offspring were produced by the microinjection of those spermatids into oocytes. This method could be applicable to various mammalian species and useful for producing functional gametes from GS cells in a xenoectopic environment.     

Calcium-binding protein from mouse Ehrlich ascites-tumour cells is homologous to human calcyclin.

A Ca2+-binding protein was purified from mouse Ehrlich ascites-tumour cells. The protein forms monomers and disulphide-linked dimers, which can be separated by reverse-phase h.p.l.c. A partial amino acid sequence analysis demonstrated that the protein has an EF-hand structure. A striking homology was found to rat and human calcyclin (a member of the S-100 protein family), which is possibly involved in cell-cycle regulation.     

Spontaneous cell transformation: karyoplasts derived from multinucleated cells produce new cell growth in senescent human epithelial cell cultures

Previously, it was shown that SV40-induced cell transformation of human diploid (2N), epithelial cells was a dynamic process of nuclear and cellular events. In this process, nuclei of polyploid (above 2N) cells broke down into multinucleated cells (MNCs) by amitotic division. An induced mass karyoplast (i.e., small cell with reduced amount of cytoplasm) budding process from the MNCs produced transformed cells with extended life span (EL) and altered morphology. In this study, without the use of SV40 and no induction of karyoplast budding, the same sequence of cellular events was found to occur spontaneously for the same type of cells at replicative senescence (no mitosis). These cell transformation events were followed by phase-contrast photography of living cell cultures. Primary, diploid, epithelial cell cultures grew for two to three passages and then entered senescence. Cells remaining in the cultures after widespread cell death (mortality stage 1; M1) developed the typical large, flat-cell morphology of senescence with increased cytoplasmic volume. Some of these cells were MNCs, mostly with two to four nuclei. Cytokinesis in MNCs and spontaneous karyoplast budding from MNCs were observed, and new, limited EL cell growth was present either in foci of cells or as prolonged cell growth over one to two passages. At the end of their replicative phase, the EL cells entered another death crisis (M2) from which no cells survived. In M2-crisis, rarely transformed cells appear with immortal cell growth characteristics (i.e., cell lines). Numerous examples of fragmentation or amitosis of polyploid nuclei in the production of multinucleated cells (MNCs) are presented. Such nuclear divisions produced nuclei with unequal sizes, which suggest unbalanced chromosomal segregations. The nuclear and cellular events in cell transformation are compared with a natural (no induction) occurrence of MNC-offspring cells in mammalian placentas. The possibility of a connection between these two processes is discussed. And finally the difference in the duration of EL cell growth from SV40-MNCs versus from senescent-MNCs is ascribed to increased mutational load in SV40-induced MNCs as compared with that in senescence MNCs.