Reconstitution of cells by fusion of cell fragments. I. Myogenic expression after fusion of minicells from rat myoblasts (L6) with mouse fibroblast (A9) cytoplasm

A novel method for somatic cell nuclear transfer to mouse embryonic stem cells

Nuclear reprogramming by somatic cell nuclear transfer (SCNT) provides a practical approach for generating autologous pluripotent cells from adult somatic cells. It has been shown that murine somatic cells can also be reprogrammed to a pluripotent-like state by fusion with embryonic stem (ES) cells. Typically, the first step in SCNT involves enucleation of the recipient cell. However, recent evidence suggests that enucleated diploid ES cells may lack reprogramming capabilities. Here we have developed methods whereby larger tetraploid ES cells are first generated by fusion of two mouse ES cell lines transfected with plasmids carrying different antibiotic-resistance cassettes, followed by double antibiotic selection. Tetraploid ES cells grown on tissue culture disks or wells can be efficiently enucleated (up to 99%) using a combination of cytochalasin B treatment and centrifugation, with cytoplasts generated from these cells larger than those obtained from normal diploid ES cells. Also, we show that the enucleation rate is dependent on centrifugation time and cell ploidy. Further, we demonstrate that normal diploid ES cells can be fused to tetraploid ES cells to form heterokaryons, and that selective differential centrifugation conditions can be applied where the tetraploid nucleus is removed while the diploid donor nucleus is retained. This technology opens new avenues for generating autologous, diploid pluripotent cells, and provides a dynamic model for studying nuclear reprogramming in ES cells.

Techniques for nuclear transfer to mouse embryonic stem cells

In this chapter, methods are described that permit the enucleation of mouse embryonic stem (ES) cells and the transfer of donor nuclei to these cells before or after enucleation has taken place. The small size and high nucleus-to-cytoplasm volume ratio of ES cells poses a challenge to their enucleation. The first step describes the production of lines of larger, polyploid ES cells, which are more suited to enucleation than diploid ES cells. In a second step, a simple centrifugal enucleation technique is described that allows efficient bulk production of ES cell cytoplasts and karyoplasts. Finally, techniques for nuclear transfer to ES cells are described, involving either transfer of karyoplasts to cytoplasts or the formation of heterokaryons between donor and recipient cells followed by the selective elimination of the polyploid nucleus. These methods have potential applications in the generation of autologous, diploid pluripotent cells from donor somatic cells. Also, they provide a novel dynamic model for studying nucleocytoplasmic interactions in ES cells.

Position-dependent nuclear accumulation of the retinoblastoma (RB) protein during in vitro myogenesis

The expression of the retinoblastoma (RB) protein has been studied during in vitro muscle differentiation by immunofluorescence staining with three different antibodies against RB protein. Proliferating mononucleate L6 rat myoblasts showed a low level of expression. As cells began to enter a nonreplicating G0 state, the cell population became heterogeneous. Some nonreplicating cells showed a high level of expression. Nuclei at the two ends of myotubes were strongly positive, whereas centrally located nuclei showed low RB expression. Overexpression of the human RB protein in rat L6 myotubes from a Semliki forest virus (SFV)-based, transient expression vector produced a similar picture. Terminally located nuclei expressed human RB at a much higher level than did the centrally located nuclei. The results suggest that individual nuclei with a multinucleated syncytium may undergo position-dependent specialization.

Direct DNA injection into mouse tongue muscle for analysis of promoter function in vivo

The striated muscle of the tongue provides a readily accessible site for the introduction of DNA expression vectors. Parameters were established to use the striated muscle of the tongue as a model system for the examination of gene expression following the direct injection of DNA constructs bearing gene promoter sequences controlling the expression of reporter genes. Plasmid expression vectors were used that contained either constitutive or muscle-specific promoters directing the transcription of reporter genes. Chloramphenicol acetyltransferase (CAT), luciferase, and beta-galactosidase (lacZ) were used as the reporter genes to detect the promoter-specific expression of the injected DNA. The expression of the injected plasmids was directly correlated with the mass of injected DNA and the time of incubation following the injection. Maximal levels of reporter gene expression were observed seven days after the injection, and the expression was maintained for more than two months following injection. Simultaneous injection of two individual expression vectors bearing either CAT or luciferase reporter genes resulted in a dose-dependent level of expression for each of the plasmids. The linearity of the coexpression provided a means to normalize DNA uptake and analyze promoter efficiency. The troponin C-fast enhancer linked to its own promoter directed significantly more CAT expression than an enhancerless SV40 promoter-CAT plasmid, demonstrating that different promoter strengths could be determined in the mouse tongue muscle in vivo. This model system represents a convenient means to approach the functional analysis of muscle gene promoters in vivo.

Very low cadmium concentrations stimulate DNA synthesis and cell growth

Uptake of cadmium into cultured cells and its effects on cell growth and DNA synthesis are measured over a range of Cd concentrations of seven orders of magnitude. Cd uptake is found to be proportional to the external Cd concentration and to incubation time over a very broad range of concentrations. At least 200 mmol cadmium per kg dry weight of cells can be accumulated in this way, leading to exhaustion of the major intracellular Cd binding sites before cell death. On the other hand, very low cadmium concentrations down to 100 pM stimulate cell growth and DNA synthesis significantly. Stimulation is found in all three mammalian cell types examined: namely L6J1, a rat permanent myoblast cell line, LLC-PK1 porcine renal epithelial cells, and a primary rat chondrocyte culture. Cd acts as a cofactor with serum in L6J1 cultures, but is stimulatory only in serum-free cultures of chondrocytes. Stimulation occurs at Cd concentrations too low to result in a measurable induction of metallothionein. This might implicate the action of response amplifiers in the chain of events leading to Cd-stimulated DNA replication and cell growth.

Structure and myofiber-specific expression of the rat muscle regulatory gene MRF4

We have cloned an 11.3-kb rat genomic DNA fragment encompassing the muscle regulatory factor 4 (MRF4) protein-coding sequence, 8.5 kb of 5'-flanking sequence, and 1.0 kb of 3'-flanking sequence. In order to study MRF4 gene expression, the rat myogenic cell line, L6J1-C, which expresses the endogenous MRF4 gene only in differentiated myofibers, was transfected stably with the full-length genomic clone and various 5' deletions. RNase protection assays demonstrated that MRF4 genes containing as little as 430 bp of 5'-flanking sequence exhibited an increase in expression as the cells differentiated into myofibers, indicating that elements responsible for fiber-specific expression are contained within this cloned DNA fragment. Similar up-regulation was observed with genes containing 1.5 kb of 5'-flanking sequence. Interestingly, MRF4 genes containing 5.0 kb and 8.5 kb of 5'-flanking sequence were up-regulated to even higher levels, suggesting that additional myofiber-specific regulatory elements located between 1.5 and 5.0 kb upstream from the coding region play a role in regulating the expression of this muscle-specific gene.

Expression of the muscle regulatory factor MRF4 during somite and skeletal myofiber development

The muscle regulatory factors MRF4, myogenin, myf-5, and MyoD constitute a family of proteins that can function as muscle-specific transcriptional activators. Although this gene family has been extensively studied, a specific role for each factor during myogenesis remains to be determined. Understanding how these factors function requires a detailed analysis of their expression patterns during development. Toward this goal, we examined the temporal pattern of expression of MRF4 and the other factors in the rat myogenic cell line L6J1-C, in newborn rat primary muscle cell cultures and in fetal and postnatal rat limb muscle. Our results demonstrate that MyoD, myogenin, and myf-5 transcripts accumulate maximally at various stages of myoblast differentiation and decline to low expression levels in adult muscle tissue. In contrast, MRF4 transcript accumulation is restricted to cell cultures containing multinucleate myofibers, and its expression in vivo increases sharply during late fetal muscle development. This level of MRF4 expression is maintained in the adult which, together with decreased expression of the other three muscle regulatory factors, makes MRF4 the predominant factor in adult muscle. In situ hybridization of mouse embryo tissue sections indicates that MRF4 transcripts accumulate in the limb beginning 13.5 days post coitum, which is 2 days later than the initial appearance of myogenin and MyoD transcripts. Hybridization to earlier stages of development reveals, however, that MRF4 mRNA initially is present in the myotomal compartment of the somites, just after myogenin but 2 days prior to MyoD expression. Unlike myogenin and MyoD, MRF4 expression declines in the myotomes at the time that multinucleate axial muscles begin to form in this region, although during later development MRF4 is expressed in the myofibers of axial muscles at levels comparable to those in the limb. Differences in the expression patterns for MRF4, myogenin, myf-5 and MyoD between myotomal and other skeletal muscle development suggest that the relative timing of expression for each muscle regulatory factor may control the distinct phenotypes associated with myotomal myocytes and multinucleate myofibers.

Neurokinin A induces c-fos, c-jun, and c-myc expression in L6 rat myoblasts

Neurokinin A (NKA), a neuropeptide belonging to the tachykinin family, induced c-fos proto-oncogene mRNA expression in serum-deprived L6J1 rat skeletal myoblasts in vitro. The marked increase reached maximal levels after 15 to 30 min. In contrast to this, c-jun and c-myc proto-oncogene expression were only slightly induced, with peak levels after 30 min. NKA did not stimulate DNA synthesis or cell proliferation in serum-deprived L6J1 myoblasts. We demonstrate a relationship between NKA treatment and induction of c-fos, c-jun and c-myc mRNA expression in serum-deprived L6J1 rat myoblasts. The results on DNA synthesis and cell proliferation indicate that the induced proto-oncogene expression alone is not enough to induce a cellular response to NKA. Possible mechanisms of action are discussed.

Molecular cloning and characterization of rat liver catechol-O-methyltransferase

The coding sequence of rat liver catechol-O-methyl-transferase (COMT; EC 2.1.1.6) was determined from rat cDNA and genomic libraries were screened with DNA probes and specific antiserum. The open reading frame consisted of 663 nucleotides coding for a 221-amino acid (aa) polypeptide with a deduced Mr of 24,747. No obvious hydrophobic signal sequence, membrane-spanning domains, or potential N-glycosylation sites were found in this sequence. The identity of the clone and the accuracy of the sequence was verified by direct aa sequencing of the tryptic peptides derived from the purified rat liver enzyme. Primer extension analysis showed that the transcription start point of the rat liver COMT mRNA was 450 bp upstream from the translation start codon. A putative polyadenylation signal (ATTAAA) was found in the 3'-noncoding region. The predicted size of the COMT transcript was 1.8-2.0 kb, which could be confirmed from Northern hybridization analyses of the isolated rat liver mRNA. One polypeptide of 25 kDa, could be immunoprecipitated with anti-COMT antibody from in vitro translation of rat liver mRNA. Employing the DNA blot analysis only one COMT-encoding gene was found in the rat genome.

Negative control of the helix-loop-helix family of myogenic regulators in the NFB mutant

We have characterized a nondifferentiating mouse muscle cell line, NFB, that represses the activity of the helix-loop-helix (HLH) family of myogenic regulators, yet expresses sarcomeric actins. The NFB MyoD gene is silent, but can be activated upon transfection of a long terminal region-controlled chicken MyoD cDNA, resulting in myogenesis. When NFB cells are fused with H9c2 rat muscle cells in heterokaryons, the level of rat MyoD transcripts declines. Thus, the stoichiometry of MyoD and the putative repressor controls myogenesis. Although NFB cells express myogenin and Myf-5 transcripts, the activity of these regulators is also repressed:myogenesis is not induced in 10T1/2 fibroblasts and is repressed in L6 muscle cells upon fusion with NFB cells. We conclude that the myogenic HLH regulators are not required for sarcomeric actin gene activation and that myogenesis is subject to dominant-negative control.

Intracellular distribution of the c-fos antigen during the cell cycle

The subcellular localization of the c-fos proto-oncogene product was studied in the G1, S, G2, and mitotic phases of the cell cycle by indirect immunofluorescence. For these analyses c-fos transfected L6J1 rat skeletal myoblasts and adult rat aortic smooth muscle cells in secondary culture, and c-fos- and c-myc co-transfected mouse Swiss 3T3 fibroblasts were used. During G1, S, and G2, the c-fos protein was evenly distributed in the nucleus, with exclusion of the nucleoli. In mitotic prophase the c-fos antigen was dissociated from the condensed chromosomes and became diffusely distributed in the cell cytoplasm, where it remained until telophase, when, again, it appeared to be associated with chromatin in the re-assembling nucleus. When comparing the subnuclear distribution of the c-fos product with that of densely packed DNA, stained with the fluorochrome Hoechst, an inverse relationship was found. Dispersed chromatin regions with weak Hoechst DNA fluorescence showed a stronger fos immunofluorescence than regions that contained a higher concentration of DNA. The localization of c-fos antigen partially overlapped with that of antigens typical of small nuclear ribonucleoprotein complexes participating in transcription and splicing. To examine if the c-fos protein would bind preferentially to specific interphase chromosomes the nucleus was fragmented into micronuclei containing single, or groups of, chromosomes. Immunofluorescence analysis showed that the majority of micronuclei were fos-positive. Possible roles of the c-fos proto-oncogene product are discussed in relation to other nuclear antigens.

Expression of PDGF A-chain and beta-receptor genes during rat myoblast differentiation

L6J1 rat myoblasts and rat skeletal muscle were studied for expression of mRNAs encoding PDGF A-chain, PDGF B-chain, PDGF alpha-receptor, and PDGF beta-receptor during in vitro and in vivo myoblast differentiation. RNA blot hybridizations demonstrated expression of the PDGF A-chain gene and the PDGF beta-receptor gene in L6J1 myoblasts and in crude muscle tissue isolated from developing rats. Transcripts of the PDGF A-chain were identified at all examined stages of in vitro and in vivo myogenic differentiation. Expression of the PDGF beta-receptor gene decreased in differentiated myotubes of L6J1 cells and in rat adult muscle tissue. Receptor binding assays demonstrated specific binding of PDGF-BB, but not -AA, to exponentially proliferating L6J1 myoblasts and to terminally differentiated L6J1 myotubes. The binding per cell nucleus was higher in exponentially proliferating myoblasts than in differentiated L6J1 myotubes. In serum free medium PDGF-BB was shown to increase c-fos protooncogene immunoreactivity in L6J1 myoblasts. In the presence of 0.5% FCS, PDGF-BB increased DNA synthesis in L6J1 myoblasts, while PDGF-AA showed no such effect. Differentiation, as monitored by myotube formation, was reduced in PDGF-BB-treated cultures. The possible role of PDGF in myoblast proliferation and differentiation is discussed.

c-fos reduces growth factor requirements for mitogenic stimulation of L6 rat myoblasts

Addition of fetal calf serum (FCS) to serum-deprived L6J1 rat myoblasts increases fos-like immunoreactivity. The nuclear immunoreactivity reached a maximum 2 h after serum addition. Effects of the c-fos protein on myoblast proliferation were analyzed in L6J1 rat myoblasts transfected with the murine c-fos gene under control of a metallothionein promoter. L6J1 myoblasts with elevated expression of transfected c-fos reached higher cell densities than neo transfected control myoblasts when approaching a stationary phase in normal culture conditions (5% FCS). The differences in cell densities were even more pronounced at low serum concentrations (0.5% FCS). c-fos transfected cells also had a faster growth rate than did control cells in serum-free medium supplemented with calcium chloride, lithium chloride, sodium selenite, hydrocortisone, and insulin. The cell morphology of c-fos transfected L6J1 myoblasts was not affected compared to control myoblasts. These results suggest that c-fos protein expression in L6J1 myoblasts is activated by serum and that mitogenic stimulation of L6J1 myoblasts is facilitated by the presence of elevated amounts of c-fos protein.

Expression of three stage-specific transcripts of AMP deaminase during myogenesis

AMP deaminase, a ubiquitous enzyme in eucaryotes, plays a central role in energy metabolism. In the present study, RNase protection analyses and immunoprecipitation with tissue-specific antisera were used to examine the transcripts and peptides of AMP deaminase produced during myogenesis in vivo and during myocyte differentiation in vitro. In embryonic muscle and undifferentiated myoblasts, a 3.4-kilobase (kb) transcript encoded a 78-kilodalton (kDa) AMP deaminase peptide that cross-reacted with antisera raised to the AMP deaminase isoform purified from kidney of the adult animal. In perinatal muscle and myocytes at an intermediate stage of differentiation in vitro, a 2.5-kb transcript was produced, and it encoded a 77.5-kDa AMP deaminase peptide that cross-reacted with antisera to the isoform purified from adult heart muscle. At about the time of birth, another 2.5-kb AMP deaminase transcript that encoded an 80-kDa peptide became detectable. This peptide cross-reacted with antisera to the predominant isoform purified from adult skeletal muscle.

Expression of three stage-specific transcripts of AMP deaminase during myogenesis

AMP deaminase, a ubiquitous enzyme in eucaryotes, plays a central role in energy metabolism. In the present study, RNase protection analyses and immunoprecipitation with tissue-specific antisera were used to examine the transcripts and peptides of AMP deaminase produced during myogenesis in vivo and during myocyte differentiation in vitro. In embryonic muscle and undifferentiated myoblasts, a 3.4-kilobase (kb) transcript encoded a 78-kilodalton (kDa) AMP deaminase peptide that cross-reacted with antisera raised to the AMP deaminase isoform purified from kidney of the adult animal. In perinatal muscle and myocytes at an intermediate stage of differentiation in vitro, a 2.5-kb transcript was produced, and it encoded a 77.5-kDa AMP deaminase peptide that cross-reacted with antisera to the isoform purified from adult heart muscle. At about the time of birth, another 2.5-kb AMP deaminase transcript that encoded an 80-kDa peptide became detectable. This peptide cross-reacted with antisera to the predominant isoform purified from adult skeletal muscle.

Elevated c-fos expression inhibits differentiation of L6 rat myoblasts

Expression of c-fos is induced by a number of signals in several cell systems. Although the exact function of the c-fos product is unknown, it has been implicated to be of importance for both cell growth and differentiation (Verma and Sassone-Corsi, 1987). To analyze how c-fos expression relates to in vitro myogenic differentiation, the kinetics of c-fos mRNA expression during spontaneous in vitro differentiation of L6J1 myoblasts was examined; c-fos transcripts were most abundant at day 4 of the differentiation process. Multinucleated myotubes and expression of alpha-actin and myosin heavy chain (MHC) mRNA appeared later, at day 6 or 7, and increased to maximal levels after 10 days in culture. To analyze further the relation between c-fos expression and L6J1 myogenic differentiation, L6J1 myoblasts were transfected with expression vectors containing the murine c-fos gene driven by a metallothionein promoter. The growth rate of c-fos-transfected L6J1 cells did not differ from that of control cells. However, formation of myotubes was significantly reduced in c-fos-transfected L6J1 cultures compared with neo-transfected controls. Myotube formation and expression of the myogenic markers alpha-actin and MHC were reduced in subclones expressing high levels of c-fos, but not in subclones with lower levels of c-fos expression. These results indicate that a marked elevation of c-fos expression at least partially inhibits L6J1 myogenic differentiation.

Density-dependent arrest of DNA replication is accompanied by decreased levels of c-myc mRNA in myogenic but not in differentiation-defective myoblasts

Myoblasts from primary rat cultures and established mouse (Cl10) and rat (L6, Ama 420) cell lines were examined for c-oncogene expression during exponential growth and under conditions which allowed myogenic differentiation. The abundance of c-Ki-ras transcripts in mRNA from confluent, quiescent cultures was reduced to 15-40% of that in mRNA from exponentially growing cells. This reduction was found both in primary myoblast cultures, myoblast lines that formed myotubes (L6 and Cl10) and in a differentiation defective subline (Ama 420). The level of c-myc transcripts was lowered when myogenic rat L6 myoblasts reached a high cell density, stopped DNA synthesis and formed myotubes. At the same cell density, growth arrested myoblasts of differentiation defective Ama 420 cells maintained a high level of c-myc expression. This shows that DNA replication and c-myc expression are independently regulated. All myoblast lines also showed expression of c-abl during exponential growth phase. Reduced expression was seen in differentiated L6 and Cl10 cultures. No expression was detected when mRNA from multiplying and differentiating myoblasts cultures were probed for c-myb, c-erbA, c-erbB, c-mos, c-fes, and c-src. The observations are consistent with a role for c-Ki-ras in myoblast proliferation and suggest that a reduction in c-myc expression may be a necessary prerequisite for terminal myogenic differentiation.

DNA replication and H5 histone exchange during reactivation of chick erythrocyte nuclei in heterokaryons

Fusion of terminally differentiated chick erythrocytes (CE) with replicating quail myoblasts or established L6J1 rat myoblasts results in reactivation of DNA synthesis in the dormant CE nuclei and in suppression of DNA synthesis in the myoblast nuclei. The nuclei of primary quail myoblasts are more effectively inhibited than the nuclei of established rat myoblasts. Inhibition of DNA replication occurs not only by preventing G1 nuclei from entering S-phase but also by blocking nuclei in S-phase and by delaying nuclei in G2 from undergoing mitosis and starting a new DNA replication cycle. No inhibition of DNA synthesis could be observed when mouse erythrocytes, i.e., erythrocytes lacking nuclei, were fused with rat myoblasts to generate mouse-globin-containing L6J1 cybrids.--Reactivation of CE nuclei is associated with a loss of the tissue-specific H5 histone variant. Complete elimination of H5 histone, however, does not seem to be a necessary prerequisite for the initiation or completion of DNA replication in CE nuclei since H5 antigens are found on reactivated G1, S, and G2 nuclei.

Changes in nuclear antigens during reactivation of chick erythrocyte nuclei in heterokaryons

Reactivation of dormant chick erythrocyte (CE) nuclei was studied by fusing chick red cells with rat myoblasts, HeLa cells, and chick fibroblasts. Heterokaryons representing different stages of nuclear reactivation were fixed and examined for nuclear antigens using polyclonal patient autoantisera reacting with mammalian (human, mouse, and rat) nuclear envelope, nucleoplasm, and chromatin (DNA) antigens. Reactivation of CE nuclei was associated with marked changes in nuclear antigenicity. In rat myoblast and HeLa heterokaryons the CE nuclei acquired mammalian nucleoplasmic and nuclear envelope antigens in the corresponding nuclear subcompartments. Drastic changes in nuclear antigenicity were noted also in heterokaryons stained with DNA antisera. The compact chromatin of nuclei in mature chick erythrocytes showed little binding of DNA antibodies. Isolated nuclei on the other hand gave a strong immunofluorescence. CE nuclei in heterokaryons were strongly positive during the early stages of nuclear reactivation but then exhibited decreased reactivity. An unexpected finding was a marked reduction in the capacity of mammalian nuclei in heterokaryons to bind DNA-antibodies. This observation is discussed in relation to the previous finding that in CE-heterokaryons these nuclei often show reduced transcription and replication. The present results indicate that in heterokaryons both types of nuclei exchange macromolecules of regulatory importance via the common cytoplasm.

Expression of myoblast and myocyte antigens in relation to differentiation and the cell cycle

Cell cycle parameters and expression of myoblast and myocyte antigens were investigated during exponential growth and during the differentiation phase of rat L8( E63 ) myoblasts by an integrated approach involving microspectrophotometry with DNA fluorochromes, [3H]thymidine autoradiography, and immunofluorescent staining with monoclonal antibodies. In addition to the majority of cells which are recruited into myotubes, two distinct populations of mononucleate cells were resolved in cultures of rat myoblasts undergoing differentiation. These mononucleate cells consist of (1) a population of proliferating cells with a prolonged G1 transit time; (2) a population of non-proliferating cells which remain arrested in G1 for more than 72 h. The latter group was examined with respect to the expression of two marker antigens recognized by two monoclonal antibodies: antibody B58 reacts with a macromolecular component present in undifferentiated myoblasts but not in mature myotubes, and antibody XMlb reacts with a muscle-specific isoform of myosin. All four possible combinations of expression of these antigens by single cells were found: B58 +XM1b -, B58 +XM1b +, B58 - XM1b -, and B58 - XMlb +. The implication of these findings with respect to the transition from the proliferative to the differentiative phase of myogenesis is discussed.

Migration of rat RNA polymerase I into chick erythrocyte nuclei undergoing reactivation in chick-rat heterokaryons

Transcriptionally inactive chick erythrocyte nuclei were reactivated by Sendai virus-induced fusion of erythrocytes with rat L6J1 myoblasts. We used antibodies to trace the appearance of a specific protein engaged in transcription of a defined class of genes, those coding for rRNA, during reactivation. Using immunofluorescence microscopy, we found increasing amounts of rat RNA polymerase I to appear, during a certain period of time after fusion, in the reforming nucleoli of the chick nuclei. Amounts of rat RNA polymerase I sufficient to be detected by immunofluorescence microscopy had accumulated in the newly developed chick nucleoli 72-190 h after fusion was initiated. This time interval coincides with the time when chick rRNA synthesis can first be detected. The results raise the possibility that during these stages of the reactivation process chick rRNA genes are transcribed by heterologous RNA polymerase I molecules of rat origin.

Analysis of muscle protein expression in polyethylene glycol-induced chicken: rat myoblast heterokaryons

Heterokaryons derived from polyethylene glycol-mediated fusion of myoblasts at different stages of development were used to investigate the transition of cells in the skeletal muscle lineage from the determined to the differentiated state. Heterokaryons were analyzed by immunofluorescence, using rabbit antibodies against the skeletal muscle isoforms of chicken creatine kinase and myosin, and a mouse monoclonal antibody that cross-reacts with chicken and rat skeletal muscle myosin. When cytochalasin B-treated rat L8(E63) myocytes (Konieczny S.F., J. McKay, and J. R. Coleman, 1982, Dev. Biol., 91:11-26) served as the differentiated parental component and chicken limb myoblasts from stage 23-26 or 10-12-d embryos were used as the determined, undifferentiated parental cell, heterokaryons exhibited a progressive extinction of rat skeletal muscle myosin during a 4-6-d culture period, and no precocious expression of chicken differentiated gene products was detected. In the reciprocal experiment, 85-97% of rat myoblast X chicken myocyte heterokaryons ceased expression of chicken skeletal muscle myosin and the M subunit of chicken creatine kinase within 7 d of culture. Extinction was not observed in heterokaryons produced by fusion of differentiated chicken and differentiated rat myocytes and thus is not due to species incompatibility or to the polyethylene glycol treatment itself. The results suggest that, when confronted in a common cytoplasm, the regulatory factors that maintain myoblasts in a proliferating, undifferentiated state are dominant over those that govern expression of differentiated gene products.

Identification of key regulated events early in the life of hybrid animal cells constructed by nuclear transplantation

Reconstituted cells were constructed by fusion of cytoplasts from the human diploid fibroblast cell strain Detroit 532 and karyoplasts from the mouse fibroblast cell line A9. Several cellular properties were examined during the first 48 hr after nuclear transplantation. (i) The overall morphology of the cells originally resembled that of the cytoplasmic donor, Detroit 532, but rapidly changed to approximate that of the nuclear donor, A9. However, definitive changes in the microfilament structure of the reconstituted cells were not seen until 24-48 hr after fusion. These observations support the idea that the presence or absence of an ordered array of microfilament bundles is not the sole determinant of cell shape. (ii) Although cytoplasts and karyoplasts were prepared from cultures of randomly growing cells, the first division of reconstituted cells occurred in a synchronous manner. However, the initiation of DNA synthesis was not synchronized. It thus appeared that, in their first cell cycle, the cells had a G2 period of variable length. The results further suggest that the cytoplasm of interphase fibroblasts contains the material necessary to initiate or support DNA synthesis in a transplanted nucleus but not entry into mitosis. (iii) A two-dimensional gel electrophoretic analysis of polypeptide synthesis in reconstituted cell cultures showed that synthesis directed by transplanted mouse nuclei could be detected as early as 3-6 hr after fusion. Some of the mouse polypeptides detected at the earliest time points studied were not among the major polypeptides synthesized by the parental A9 cells. By about 48 hr after fusion, the pattern of polypeptides produced by reconstituted cells was almost indistinguishable from that of the nuclear donor parent cells.

Analysis of myogenesis by somatic cell hybridization. II. Retention of myogenic competence and suppression of transformed properties in hybrids between differentiation competent and incompetent rat L6 myoblasts

This study describes the characteristics of hybrids between two closely related rat myoblast lines, which differ both in the ability to express their program of differentiation and in the expression of neoplastic properties. Myogenic, nonneoplastic L6J1-S cells were hybridized with nonmyogenic, neoplastic L6J1-N1 cells. Six hybrid clones were isolated and expanded for analysis of myogenic competence, and four of these clones were also evaluated for parameters of transformation, including tumorigenicity, ability to clone in agar, and surface fibronectin. In addition to our analysis of isolated clones, we also assessed myogenic differentiation in colonies representing 226 early hybrid clones. Results of all these analyses demonstrate that the myogenic phenotype is retained and that the tumorigenic/transformed phenotype is suppressed in the hybrids. Furthermore, our results indicate that when the programs for myogenesis and neoplastic transformation are confronted within a single cell, they are expressed as mutually exclusive alternatives. In contrast to these results on myogenic X nonmyogenic L6 hybrids, it has been reported that isolated clones of A9 X L6 exhibited extinction of myogenic competence and retention of transformed properties. We have evaluated myotube formation in over 300 early hybrid clones between A9 and either diploid or subtetraploid L8 rat myoblasts. Our results demonstrate that all of these hybrid clones exhibit extinction regardless of the ploidy of the myoblast parent, and they further indicate that extinction is not a consequence of chromosome loss. These results support the conclusion that in A9 X L6 hybrids, the nonmyogenic, transformed phenotype is dominant.

Pattern of chick gene activation in chick erythrocyte heterokaryons

The reactivation of chicken erythrocyte nuclei in chick-mammalian heterokaryons resulted in the activation of chick globin gene expression. However, the level of chick globin synthesis was dependent on the mammalian parental cell type. The level of globin synthesis was high in chick erythrocyte-rat L6 myoblast heterokaryons but was 10-fold lower in chick erythrocyte-mouse A9 cell heterokaryons. Heterokaryons between chick erythrocytes and a hybrid cell line between L6 and A9 expressed chick globin at a level similar to that of A9 heterokaryons. Erythrocyte nuclei reactivated in murine NA neuroblastoma, 3T3, BHK and NRK cells, or in chicken fibroblasts expressed less than 5% chick globin compared with the chick erythrocyte-L6 myoblast heterokaryons. The amount of globin expressed in heterokaryons correlated with globin mRNA levels. Hemin increased beta globin synthesis two- to threefold in chick erythrocyte-NA neuroblastoma heterokaryons; however, total globin synthesis was still less than 10% that of L6 heterokaryons. Distinct from the variability in globin expression, chick erythrocyte heterokaryons synthesized chick constitutive polypeptides in similar amounts independent of the mammalian parental cell type. Approximately 40 constitutive chick polypeptides were detected in heterokaryons after immunopurification and two-dimensional gel electrophoresis. The pattern of synthesis of these polypeptides was similar in heterokaryons formed by fusing chicken erythrocytes with rat L6 myoblasts, hamster BHK cells, or mouse neuroblastoma cells. Three polypeptides synthesized by non-erythroid chicken cells but less so by embryonic erythrocytes were conspicuous in heterokaryons. Two abundant erythrocyte polypeptides were insignificant in non-erythroid chicken cells and in heterokaryons.

Transcription of chick genes by mammalian RNA polymerase II in chick erythrocyte-mammalian cell heterokaryons

The introduction of chick erythrocyte nuclei into mammalian cell cytoplasms results in their reactivation as evidenced by the de novo transcription of chick genes and the synthesis of both globin and constitutive proteins. In the present study, chick erythrocytes have been fused to L6 rat myoblasts and to alpha-amanitin-resistant variants of L6 to determine whether the chick or the mammalian RNA polymerase II was responsible for transcription of chick genes. Heterokaryons formed by fusing chick erythrocytes with alpha-amanitin-resistant L6 myoblasts synthesize both chick globin and chick constitutive proteins in the continued presence of 5 micrograms/ml alpha amanitin ten days postfusion. Both the synthesis of globin and other chick polypeptides occurs at levels comparable to those observed for untreated heterokaryons. Synthesis occurs under conditions in which insignificant chick RNA polymerase II activity can be detected in wild-type heterokaryons by autoradiography. These results demonstrate that RNA polymerase II is one of the mammalian proteins that is selectively taken up by the chick nucleus during reactivation in the presence of alpha amanitin. Furthermore, the mammalian RNA polymerase II alone can account for the transcription of both differentiation specific and constitutive genes in the chick nucleus.

A general high-efficiency procedure for production of microcell hybrids

The relative efficiency of microcell-mediated chromosome transfer vs. somatic cell hybridization has been determined. The prolonged mitotic arrest generally used to micronucleate donor cells also reduced the fusion efficiency to 1/10th-1/5th of that in whole cell hybridizations. Here we report an alternative micronucleation protocol, involving sequential treatment of the donor cells with Colcemid and cytochalasin B, which yielded micronucleated cells that hybridized with the same efficiency as whole cells. The enucleation, purification, and fusion steps of the microcell procedure have also been refined. By using these modifications the practical yield of microcell hybrid clones can be increased 50- to 100-fold.

Reactivation of chicken erythrocyte nuclei in heterokaryons results in expression of adult chicken globin genes

Activation of chicken globin gene transcription has been demonstrated in chicken erythrocyte--rat L6 myoblast heterokaryons. The globin mRNA is polyadenylylated and is translated into adult chicken alpha A-, alpha D-, and beta-globin polypeptides. No fetal globin mRNA or globin polypeptides were detected. Heterokaryons between chicken erythrocytes and mouse neuroblastoma cells or hamster BHK cells also synthesized adult chicken globins.

Construction of viable mouse-human hybrid cells by nuclear transplantation

Viable interspecies cytoplasmic-nuclear hybrid cells were constructed by fusion of karyoplasts prepared from the highly tumorigenic A9 mouse fibroblast cell line and cytoplasts prepared from the Detroit 532 normal human diploid cell strain. The identity of the hybrid cells was ascertained using a variety of morphological, immunological, and genetic criteria, including: nuclear pattern of staining with the fluorochrome Hoechst 33258, appearance of the actin-myosin containing cytoskeleton, presence of fibronectin, and resistance to azaguanine and diphtheria toxin. About 90% of the hybrid cells were viable, that is, capable of division. Changes in the morphology of the hybrid cells, apparently nuclear directed, were observed before cell division occurred. Using the techniques described here, large numbers of interspecies hybrid cells suitable for many types of biochemical analyses can be routinely produced.

Ultrastructure and mechanical activity expressed by striated muscle in culture

Newly devised assay procedures for quantitating the mechanical capabilities of striated muscle fibers grown in cell culture have permitted the correlation of cytological features with the ability to respond mechanically to electrical and chemical stimuli during development. By developmental timing and by physiological characteristics, three distinct mechanical activities can be distinguished: : TWITCH, contracture and wave propagation (escalation). Parallel electron microscopy studies suggest that contracture and escalation require significantly greater internal membrane development than twitch. The assay procedures have revealed that fibers developed in culture from genetically dystrophic chick muscle cells display a heightened electrical threshold for a twich response, but are otherwise similar to normal fibers. Cultured chick fibers, whether of leg or breast origin, exhibit similar ultrastructural and mechanical properties; yet these are different from those of in vivo adult muscle and may represent the avian striated muscle archetype expressed in the absence of innervation. Primary or cell line cultures of rat muscle produce far fewer mechanically active fibers than do avian cell cultures. The influence of culture conditions and cell source, whether avian or mammalian, on the extent of differentiation expressed in culture is so great that our understanding of studies on cultured muscle fibers would benefit from some characterization of both morphological and contractile properties of the fibers being used.