Detection of human and chick nuclear antigens in nuclei of chick erythrocytes during reactivation in heterokaryons with HeLa cells

Reprogramming somatic gene activity by fusion with pluripotent cells

Fertilized eggs and early blastomeres, that have the potential to develop to fetuses when placed into a uterus, are totipotent. Those cells in the embryo, that can give rise to all cell types of an organism, but not to an organism itself, are pluripotent. Embryonic stem (ES), embryonic carcinoma (EC), and embryonic germ (EG) cells are powerful in vitro artifacts derived from different embryonic stages and are pluripotent. Totipotent and pluripotent cells have the potential to greatly benefit biological research and medicine. One powerful feature is that the genetic program of somatic cells can be converted into that of totipotent or pluripotent cells, as shown by nuclear transfer or cell fusion experiments. During reprogramming by cell fusion various features of pluripotent cells are acquired. These include the typical morphology of the respective pluripotent fusion partner, a specific epigenetic state, a specific gene profile, inactivation of tissue-specific genes expressed in the somatic fusion partner, and the developmental as well as differentiation potential of pluripotent cells. In this review, we will discuss what is known about the reprogramming process mediated by cell fusion and the potential use of fusion-induced reprogramming for therapeutic applications.

Cell-cell fusion as a means to establish pluripotency

Embryonic stem cells (ESCs), embryonic germ cells (EGCs), and embryonic carcinoma cells (ECCs) are three types of pluripotent cells derived from mammalian embryos. The three cell types are capable not only of self-renewal, but also of having the potential to give rise to cells of all tissue types in the fetal and adult body. In several reports, ESCs, ECCs, and EGCs have been described to reprogram somatic cells in vitro. After reprogramming caused by fusion, somatic cells exhibit various features of pluripotent cells: expression of pluripotency markers (e.g., Oct4, nanog, and Rex-1), absence of tissue-specific gene expression, reactivation of inactive X chromosome of female somatic cells, demethylation, as well as histone modification. An activity in pluripotent stem cells appears to be capable of inducing the global changes inherent in the reprogramming of somatic cells. Investigations involving pluripotent stem cells will yield substantial insight into various fundamental biological processes, such as cellular differentiation and de-differentiation. Most importantly for the public, however, is that such studies might lead into cell-based therapies and as such have the potential to change regenerative medicine.

Biological implications of cell fusion

Until recently, cells were thought to be integral and discrete components of tissues, and their state was determined by cell differentiation. However, under some conditions, stem cells or their progeny can fuse with cells of other types, mixing cytoplasmic and even genetic material of different (heterotypic) origins. The fusion of heterotypic cells could be of central importance for development, repair of tissues and the pathogenesis of disease.

Adult stem cells--reprogramming neurological repair?

Much excitement has surrounded recent breakthroughs in embryonic stem-cell research. Of lower profile, but no less exciting, are the advances in the field of adult stem-cell research, and their implications for cell therapy. Clinical experience from use of adult haemopoietic stem cells in haematology will facilitate and hasten transition from laboratory to clinic--indeed, clinical trials using adult human stem cells are already in progress in some disease states, including myocardial ischaemia. Here, with particular reference to neurology, we review processes that might underlie apparent changes in adult cell phenotype. We discuss implications these processes might have for the development of new therapeutic strategies using adult stem cells.

Spontaneous fusion of cells between species yields transdifferentiation and retroviral transfer in vivo

Human cells can fuse with damaged or diseased somatic cells in vivo. Whether human cells fuse in vivo in the absence of disease and with cells of disparate species is unknown. Such a question is of current interest because blood exchanges between species through direct physical contact, via insect vectors or parasitism, are thought to underlie the transmission of zoonotic agents. In a model of human-pig chimerism, we show that some human hematopoietic stem cells engrafted in pigs contain both human and porcine chromosomal DNA. These hybrid cells divide, express human and porcine proteins, and contribute to porcine nonhematopoietic tissues. In addition, the hybrid cells contain porcine endogenous retroviral DNA sequences and are able to transmit this virus to uninfected human cells in vitro. Thus, spontaneous fusion can occur in vivo between the cells of disparate species and in the absence of disease. The ability of these cell hybrids to acquire and transmit retroviral elements together with their ability to integrate into tissues could explain genetic recombination and generation of novel pathogens. * differentiation * fusion * retrovirus

Plasticity of cell fate: insights from heterokaryons

Experiments with somatic cell hybrids and stable heterokaryons have demonstrated that differentiated cells exhibit a remarkable capacity to change. Heterokaryons have been particularly useful in determining the extent to which the differentiated state of a cell is plastic. Cell fate can be altered by a change in the balance of positive and negative trans-acting regulators. Although a single regulator may be sufficient in certain environments to trigger a change in cell fate, that regulator may be ineffective in other cell contexts where it encounters a different composition of regulators.

Reactivation of DNA replication in nuclei from terminally differentiated cells: nuclear membrane permeabilization is required for initiation in Xenopus egg extract

We have used Xenopus egg extract to investigate the requirements for reactivation of DNA replication in nuclei isolated from terminally differentiated chicken erythrocytes. Previous work has shown that reactivation of erythrocyte nuclei in egg extract is accompanied by chromatin decondensation, nuclear envelope reformation, and the accumulation of egg lamin, LIII. However, in those studies, erythrocyte nuclei were prepared by methods that were not designed to maintain the selective permeability of the nuclear membrane, and as such, it is not clear if loss of nuclear membrane integrity played a role in the reactivation process. Therefore, the purpose of this study was to determine if changes in nuclear membrane permeability are required for reactivation of erythrocyte nuclei in egg extract. Nuclei with intact nuclear membranes were prepared from erythrocytes with streptolysin O and permeable nuclei by treatment of intact nuclei with the detergent Nonidet-P40. Like permeable nuclei, most intact nuclei decondensed, imported nuclear protein, and accumulated lamin LIII from the extract. However, unlike permeable nuclei, which replicated extensively in the extract, few intact nuclei initiated replication under the same conditions. These data demonstrate that permeabilization of the nuclear membrane is required for reactivation of DNA replication in terminally differentiated erythrocyte nuclei by egg extract and suggest that loss of nuclear membrane integrity may be a general requirement for replication of quiescent cell nuclei by this system.

Conservative mutations in the putative metal-binding region of human immunodeficiency virus tat disrupt virus replication

The tat trans-activator proteins of the primate immunodeficiency viruses contain a highly conserved cysteine-rich domain. In human immunodeficiency virus type 1 tat there are seven cysteines located between residues 22 and 37 that are thought to form a metal-nucleic acid-binding structure. Most of the previous mutagenesis studies had demonstrated that these residues are essential for tat activity and virus expression. Here we show that potentially conserved cysteine-histidine substitutions within the proposed tetrahedral structure still eliminate tat activity and virus expression. Consistent with previous studies, one cysteine-to-histidine mutation (amino acid 31) had little effect on trans-activation. We have studied the functional properties, stability and subcellular localization of several tat protein mutants. Most of the mutants are stable and properly localized to the nucleus and/or nucleolus. However, cysteine-to-glycine at position 34 affected tat stability. Our studies with the histidine mutants suggest that tat does not assume the prototype "zinc finger" structure for metal binding.

Histone acetylation: a step in gene activation

Cellular ageing appears to consist mainly in a loss of adaptability and a progressive decrease in the capacity of the cell to maintain homeostasis. Such age related phenomenon can be the result of stochastic or of programmed events, and may occur through changes in the base pairs or coding of the DNA, through increasing levels of error in transcription and finally through alterations at the translation step of proteins synthesis. The purpose of this chapter is to present histone acetylation as a key event in the control of chromatin structure and transcription.

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.

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.

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.

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.

Fanconi's anemia: anomaly of enzyme passage through the nuclear membrane? Anomalous intracellular distribution of topoisomerase activity in placental extracts in a case of Fanconi's anemia

In cells of Fanconi's anemia (FA) spontaneous breakage of chromosomes was first recognized by Schroeder et al. (1964). Sensitivity to bivalent alkylants has been found to be a constant feature, whereas low levels of several repair-related enzymes have been described in different FA cell lines. In a family with known FA, during a further pregnancy the prenatal diagnosis of the disease was made by cytogenetic analysis of amniotic cells. After birth the fresh placenta was extracted for further enzymologic analysis. An unusual distribution of DNA topoisomerase activity was noted: high in the cytoplasm and only a little activity in the nuclear sap. This contrasts with findings in normal placentae. Since amniotic cells, lymphocytes, and fibroblasts of this child exhibited both high spontaneous breakage of chromosomes and sensitivity to the bivalent alkylant, diepoxybutane, a correlation between the findings on cytogenetic and enzymologic levels is assumed. Whereas in other published cases, a true reduction of activities of enzymes involved in DNA replication and repair has been found, the present results suggest the interpretation that in our patient the genetic anomaly does not affect the level of synthesis of the enzyme itself, but the passage of the enzyme from the place of synthesis (the cytoplasm) to the substrate (inside the nucleus). A genetic anomaly of the nuclear membrane might be a possible explanation, or alternatively, a structural mutation of the enzyme at a site not affecting the catalytic activity, but affecting the membrane passage or intranuclear accumulation. Meanwhile, placentae of two other cases gave similar results, thus supporting our findings.

Restoration of metabolic cooperation in heterokaryons between HGPRT-deficient mouse A9 fibroblasts and chick embryo erythrocytes

Genetic determinants of metabolic cooperation were studied by fusing chick erythrocytes to HGPRT- mammalian cells. Heterokaryons were then tested for their ability to incorporate [3H]hypoxanthine and to transfer radioactive material to HGPRT- recipient cells. Chick erythrocytes (CE) have nuclei which are inactive but contain the HGPRT gene and some cytoplasmic HGPRT enzyme activity. They are unable, however, to cooperate with HGPRT- cells. Of the two mammalian cell lines used, the human GM29 line is HGPRT- and capable of functioning as a receptor cell in cooperation experiments with HGPRT+ cells. The HGPRT- mouse A9 line on the other hand is unable to cooperate. Immediately after fusion, both types of heterokaryons incorporated [3H]hypoxanthine, indicating the presence of some chick HGPRT enzyme contributed by the erythrocyte partner at the time of fusion. While the CE-GM29 heterokaryons participated in metabolic cooperation shortly after fusion, the CE-A9 heterokaryons did not. However, four days after fusion, i.e., at a time when the erythrocyte nucleus had been reactivated, the CE-A9 heterokaryons did cooperate. This suggests that in CE-A9 heterokaryons the genes required for metabolic cooperation are expressed by the previously dormant chick erythrocyte nucleus.

Fibronectin expression is determined by the genotype of the transformed parental cells in heterokaryons between normal and transformed fibroblasts

The expression of fibronectin, a cell surface-associated transformation-sensitive glycoprotein, was studied in hetero- and homokaryons of normal and SV40-transformed human fibroblasts. In immunofluorescence, fibroblast homokaryons had an intense surface-associated and intracelluar fibronectin fluorescence similar to that of normal fibroblasts. Transformed cells and their homokaryons had a minimal surface-associated and a weak intracellular fibronectin fluorescence. In heterokaryons formed between transformed and normal fibroblasts, the expression of fibronectin fell within 24 h to the level of the transformed cell homokaryons. The change was detectable already at 3 h after fusion and was gene-dose dependent. These results show that the transformed genotype determines fibronectin expression in the heterokaryons.

T antigen and initiation of cell DNA synthesis in a temperature-sensitive mouse line transformed by an SV40tsA mutant and in heterokaryons of the transformed cells and chick erythrocytes

The role of SV40 gene A product in initiation of cellular DNA synthesis was investigated, using a mouse kidney line [mKSA207] transformed by SV40tsA207. mKSA207 cells were temperature sensitive for growth, lost SV40 T antigen (Tag) when incubated in low serum at 40degreeC, and accumulated Tag in the cytoplasm when fed 10% serum and incubated at the nonpermissive temperature (39.7degreeC). Following serum addition, the percentage of mKSA207 cells synthesizing DNA was essentially the same at nonpermissive (39.7 degrees C) and permissive temperatures (33.5degreeC). The cells entered S phase asynchronously at both temperatures, but most cells entered S within 16 h, and before Tag accumulated. mKSA207 synchronized by a double thymidine block also synthesized DNA at 39.7degreesC and entered a second S phase. Tag-depleted or Tag-synchronized mKSA207, when fused with chick erythrocytes (CE), activated CE DNA synthesis. At nonpermissive temperatures (39.7degreesC), 40% of CE nuclei in heterokaryons with Tag-depleted mKSA207 displayed 3H-thymidine--labeled nuclei 28--40 h after fusion, when only 12% of CE nuclei were Tag+. The experiments indicate that SV40 gene A product probably does not have a direct role as initiator of cellular DNA synthesis.

Initiation of DNA synthesis and uptake of T antigen by chick erythrocyte nuclei in hterokaryons with SV40-transformed human cells

Nonsynchronized and hydroxyurea (HU)-synchronized SV40-transformed human cells (W98VaD) were fused with chick embryo erythrocytes (CE). The uptake of T antigen by CE nuclei was compared with initiation of chick nuclear DNA synthesis. Uptake of T antigen by CE nuclei occurred at about the same time after fusion with asynchronous as with HU-synchronized cells. CE nuclei rapidly became T antigen-positive between 16 h and 28 h after fusion and usually almost all CE nuclei were T antigen-positive by 48 h after fusion. In contrast, initiation of chick nuclear DNA synthesis occurred as a function of time after reversal of the HU block, when the host cell nuclei were also synthesizing DNA. Chick nuclear DNA synthesis occurred in many heterokaryons before the CE nuclei became T antigen-positive by immunofluorescence.

Heterokaryons in the analysis of genes and gene regulation

Cytological and chemical analysis of heterokaryons, the immediate product of cell fusion, offer new possibilities for studying the factors responsible for genetic regulation in eukaryotic cells. In comparison with proliferating cell hybrids the heterokaryon state offers the important advantage that a heterokaryon contains two complete genomes since chromosome loss does not occur, but since segregation and recombination are absent, heterokaryons cannot be used for gene mapping in the same way as proliferating cell hybrids. However, if two cell types carrying different genetic defects are fused the analysis can be used for studies of gene complementation. The biological information obtained with heterokaryons has emphasized the role of the cytoplasm in the control of nuclear activity. When a G1 nucleus is brought into contact with the cytoplasm of an S phase cell the G1 nucleus is stimulated to synthesize DNA. If the nucleus is brought into a mitotic cell, the chromatin of the G1 nucleus is forced to condense into prematurely condensed chromosomes. Inactive nuclei such as the dormant chick erythrocyte nucleus will be stimulated to initiate RNA and DNA synthesis when brought into contact with an active cytoplasm by cell fusion. Specific nuclear proteins have been shown to be responsible for this process of reactivation. Other inactive nuclei such as the nuclei of macrophages and spermatozoa have likewise been shown to be reactivated by fusion with active cells. The degree of activation in all of these cases appears to be determined by the state of the active cell. Inactive nuclei are activated to the same level as the active nucleus but seldom beyond this level. If differentiated cells are fused with undifferentiated cells, usually the differentiated character is lost rapidly after fusion. This observation is in agreement with several studies on proliferating cell hybrids indicating some type of negative control of differentiated properties. In heterokaryons obtained by fusion of cells of a similar type of histotypic differentiation usually coexpression of the differentiated markers is observed.

Reactivation of chick erythrocyte nuclei after fusion with enucleated cells

Inactivated Sendai virus was used to fuse nucleated chick erythrocytes with mouse L and A9 cells which had been enucleated by centrifugation in the presence of cytochalasinB. The enucleation step removed the nuclei from more than 99% of the cells. During the fusion step, chick erythrocyte nuclei were introduced into 20% of the enucleated mouse cytoplasms. This resulted in the formation of a large number of "reconstituted cells" where practically all the cytoplasm originated from the mouse cell while the nucleus was of chick origin. The chick erythrocyte nuclei appeared to become well integrated into the mouse cytoplasms since they increased dramatically in size and dry mass, formed nucleolus-like bodies, and resumed RNA synthesis. This, however, did not prevent a gradual decrease in the rate of protein synthesis in the cytoplasm after the removal of the mouse nucleus. Protein synthesis decayed at a similar rate in both reconstituted and enucleated cells. The majority of these "cells" died within 48 h and all of them within 5 days after enucleation/fusion. By contrast, the small number of L cells which failed to become enucleated multiplied rapidly. The results obtained suggest that the reactivation of the chick erythrocyte nuclei is not fast enough to rescue the enucleated mouse cytoplasms.

Chick-erythrocyte nucleus reactivation in heterokaryons: suppression by inhibitors of proteolytic enzymes

Reactivation of chick-erythrocyte nuclei in heterokaryons (obtained by Sendai virus-induced fusion of chick erythrocytes with HeLa cells) is suppressed by specific inhibitors of trypsin and trypsin-like enzymes. N-alpha-tosyl-L-lysyl-chloromethane and N-alpha-tosyl-L-arginine methylester inhibit erythrocyte nuclear enlargement and suppress RNA and DNA synthesis in nuclei of erythrocytes and HeLa cells in heterokaryons at concentrations that only minimally influence individual HeLa cells or HeLa homokaryons. Although other unknown mechanisms of action cannot be formally excluded, the data are interpreted as fitting best with an intracellular site of action of the protease inhibitors studied, and as suggesting a role for cellular proteases in reactivation of chick-erythrocyte nuclei in heterokaryons.

On the recovery of transcription after inhibition by actinomycin D

After pulse exposure to concentrations of actinomycin D (AMD) sufficient to abolish transcription, Vero cells recover RNA synthesis much more rapidly than most other cell types. This is only in part attributable to the remarkable capacity of Vero very promptly to excrete bound AMD, elimination of which, although necessary, is not a sufficient condition for resurgence of RNA synthesis. After elimination of higher concentrations of AMD from Vero, although over-all RNA synthesis resumes a normal rate within 24 hr, protein synthesis lags, and a long period of division-delay ensues. Division-delay lasting 2-3 days results from exposure of Vero to doses of AMD greater than those that suppress RNA synthesis by greater than 90% (e.g. 1 microg/ml for 2 hr) but not by lower doses, which permit almost immediate reentry into the cell cycle. In contrast, although L cells recover over-all RNA synthesis very slowly after pulse treatment with AMD, resumption of protein synthesis or cell division is not comparably delayed thereafter. These and other data suggest that the early restoration of RNA synthesis in Vero after relief of inhibition by AMD is qualitatively imperfect. The results reported herein are explainable by the hypothesis that the synthesis of those species of RNA which are involved, directly or indirectly, in reactivating the transcription of genes controlling progression in the cell cycle is relatively resistant to suppression by AMD. Decay of such RNA templates and their products, which differs in different cell types during inhibition by AMD, determines the duration of division-delay.