Differential regulation of DNA synthesis in heterokaryons between chicken erythrocytes and culture cells with various proliferative potentials

The regulation of DNA synthesis in heterokaryons between chicken erythrocytes and culture cells of various proliferative potential was studied. The following regularities were found: 1) Both immortalized and non-immortalized cells can efficiently reactivate DNA synthesis in erythrocyte nuclei. 2) Erythrocytes drastically inhibit the entry of non-malignant culture cell nuclei into the S-period, not acting upon DNA synthesis. 3) The inhibitory action is characteristic of erythrocytes from different stages of chicken ontogenesis (from 5-day-old embryos to the adult bird). 4) Malignant cells are completely refractory to the inhibitory action of erythrocytes. The ability of erythrocytes to inhibit the onset of replication in heterokaryons may be connected with the mechanisms of maintaining these terminally differentiated cells in a non-proliferating state.     

Fusion of fibroblasts with differentiated and nondifferentiated leukemia cells resulting in blockage of DNA synthesis

We have investigated the regulation of DNA synthesis in the heterokaryons of HL60 human myelomonocytic leukemia cells and NIH3T3 mouse fibroblasts to examine if the differentiated leukemia cells contained a replication inhibiting activity. Cell fusions were performed either by exposing a suspension of mixed cells to an electric pulse or by the polyethylene glycol method. To identify the origin of the nuclei in a heterokaryon, one set of partner cells was prelabeled with [3H]thymidine before fusion. DNA synthetic activity after fusion was then revealed immunohistochemically by bromodeoxyuridine incorporation. DNA synthesis in the nuclei of 3T3 was inhibited in the heterokaryons of 3T3 and in either one of the two differentiated forms of HL60, i.e., the macrophage-like or the granulocyte-like. The result supports that a negative regulator of DNA synthesis exists in the differentiated HL60. Surprisingly, we have also found that DNA synthesis was inhibited in the nuclei of both 3T3 and nondifferentiated, proliferating HL60 when these two cells were fused. When unfused, proliferating cells were eliminated with cytosine arabinoside; these nonreplicating heterokaryons survived for at least 5 days, and 15% of them showed alpha-naphthylacetate esterase activity, a trait of the macrophage differentiation. The blockage of DNA synthesis in both partner nuclei was also observed in the heterokaryons of NIH3T3 cells and nondifferentiated human promonocytic leukemia cells U937, and in nondifferentiated HL60 and human diploid fibroblasts WI38. However, this effect was not found in the heterokaryons of NIH3T3 cells and human B lymphoma WI-729-HF2 cells. This is the first demonstration of the inhibition of DNA synthesis upon fusion of two proliferating cells.     

The control of DNA replication in hybrids between neutrophils and fibroblasts

Abstract. DNA synthesis regulation in heterokaryons between mouse neutrophils and cultured cells of various proliferative potentials has been studied. The following features have been found. Both immortalized and non-immortalized cells can reactivate DNA synthesis in neutrophil nuclei. The reactivation ability of cultured cells increases after immortalization and is not changed by further transformation. Neutrophils inhibit the entry of cultured cell nuclei into S phase and have no effect on ongoing DNA synthesis. Malignant cells are much less sensitive to the inhibitory action of neutrophils than non-malignant ones. Non-malignant immortalized cells are as sensitive to this effect as non-immortalized cells. Neutrophil karyoplasts do not influence DNA synthesis in partner cultured cell nuclei. Cycloheximide pretreatment of neutrophils drastically diminishes their inhibitory effect.     

DNA synthesis in heterokaryons obtained by the fusion of polymorphonuclear leukocytes and cultured cells possessing different proliferative potentials

Heterokaryons between terminally differentiated polymorphonuclear leukocytes (PL) and culture cells of different proliferative potentials: mouse and rat embryo fibroblasts (EFM, EFR); immortal cells NIH 3T3 and E2; malignant cells NCC2, L929, He239 and SV 3T3,--were obtained by means of electrofusion. Radioautographic study of 3H-thymidine incorporation in the nuclei of heterokaryons showed that all the cells taken for fusion were able to induce reactivation of DNA synthesis in PL nuclei, however, with different rates: 7-37% for EFM and NIH 3T3 and 20-40% for malignant cells. The presence of oncogenes Elan in E2 cells and ras in NCC2 cells increased the rate of PL reactivation approximately twice as compared with the cells of original lines (EFR and NIH 3T3, correspondingly). In parallel to reactivation of DNA synthesis in PL nuclei inhibition of the synthesis in culture cell nuclei in the same heterokaryons was found. The rate of inhibition was about 70% for non-malignant and 23, 40 and 18% for NCC2, L and SV 3T3 cells, respectively. He239 cells, transformed by a temperature-dependent mutant of virus SV40 showed at permissive temperature the increased capacity of inducing reactivation of PL nuclei, though He239 cells susceptibility to inhibitory action of PL nuclei did not change with temperature. According to the behaviour in heterokaryons PL were found to be similar to chick erythrocytes, but differing from them by a pronounced inhibiting effect upon DNA synthesis in the nuclei of malignant cells.     

The nature of a proliferation block in differentiated cells with heterokaryons as a model: various types of absence of proliferation in cells in terminal differentiation

Heterokaryons obtained by fusion of proliferating and terminally differentiated cells were studied. The data obtained suggest that mechanisms of proliferation arrest are different in macrophages on one hand and nucleate erythrocytes and polymorph leukocytes on the other. Macrophages appeared to be devoid of factors preventing replication in nontransformed and spontaneously immortalized cells. Inhibition of proliferation was probably due to certain modifications of macrophage genome which arise during differentiation and can be compensated by the effect of "immortalizing" oncogenes. On the contrary, nucleate erythrocytes and polymorphs evidently contain some factors mediating negative control of proliferation. For reactivation of DNA synthesis in these cell types after fusion with other cells the latter did not have to be immortalized. After cell fusion macrophages specifically inhibit DNA synthesis in cells containing active oncogenes.     

DNA synthesis in the heterokaryons of non-dividing differentiated cells and culture cells with various proliferative potentials

Resident peritoneal mouse macrophages (non-dividing differentiated cells) were fused with mouse embryo fibroblasts (cells with a limited lifespan), NIH 3T3 and C3H 10T 1/2 cells ('immortal' cell lines) and SV 3T3 cells (a malignant cell line). DNA synthesis was investigated in the resultant heterokaryons. No inhibitory effect upon the transition of NIH 3T3 and mouse embryo fibroblasts nuclei to the S-phase was observed. C3H 10T 1/2, NIH 3T3 and SV 3T3 cells induced the reactivation of DNA synthesis in the macrophage nuclei in the heterokaryons. At the same time, no replication was detected in the macrophage nuclei after fusion with mouse embryo fibroblasts.     

Haploid genome reactivation and recovery by cell hybridization

DNA replication in haploid spermatid nuclei has been induced by hybridization of mouse early spermatids to proliferating HeLa cells. Use of polyethylene glycol rather than inactivated Sendai virus as the cell fusion agent was found to be essential to the production of large numbers of heterokaryons containing spermatid nuclei. DNA replication was detected in the heterokaryons by autoradiography. Density of silver grains over spermatid nuclei closely approximated the grain density over labelled HeLa nuclei in the same heterokaryons. Mouse centromeric heterochromatin appeared to be labelled last during the spermatid DNA synthetic period. On the average, HeLa nuclei in heterokaryons began DNA synthesis before spermatid nuclei. Results indicated, however, that DNA synthesis by HeLa nuclei might not be a prerequisite for spermatid DNA synthesis. These experiments demonstrate induction of DNA synthesis in spermatid nuclei, the first major step toward reactivation and recovery of their haploid genome by cell hybridization.     

Hepatocytes in heterokaryons do not retard the nuclei of stimulated fibroblasts entering the S period]

Serum-deprived (0.2%) resting and serum-stimulated (10%) proliferating NIH 3T3 mouse fibroblasts were fused with hepatocytes from intact, regenerating and embryonic mouse livers to elucidate mechanisms of liver cell proliferation, DNA synthesis being investigated in nuclei of heterokaryons and non-fused cells using radioautography. Hepatocytes in heterokaryons were found to have no inhibitory effect on the entry of stimulated fibroblast nuclei into the S-period, but on the contrary they were involved in DNA synthesis. In addition, the nuclei in heterokaryons mutually stimulated each other to enter the S-period. In their turn, the resting fibroblasts did not prevent the proliferating hepatocytes from the regenerating and embryonic livers to enter the S-period. Possible reasons of the absence of inhibitory effect of differentiated cells in heterokaryons are discussed. The data obtained enable us to conclude that the mechanism of proliferative process control in resting immortalized cells differs from that in differentiated cells where proliferation seems to be stopped without affecting the endogenous inhibitor postulated for the resting and ageing fibroblasts.     

Immortalized phenotype and the presence of active oncogenes correlate with the capacity of culture cells to induce reactivation of DNA synthesis in macrophage nuclei in heterokaryons

Several types of culture cells with limited life span (rat embryo fibroblasts, rat chondrocytes and mouse premacrophages) were found to be unable to induce the reactivation of DNA synthesis in the nuclei of non-dividing differentiated cells (mouse peritoneal resident macrophages) in heterokaryons. By contrast, malignant HeLa cells have this ability. In heterokaryons formed by fusion of mouse macrophages with HE239 cells (Syrian hamster fibroblasts transformed with a ts mutant of the SV40 virus), DNA synthesis in macrophage nuclei is reactivated only at the permissive temperature (33° C), at which viral T antigen is stable. Immortalization of rat chondrocytes by transfection with p53 gene enables to induce DNA synthesis in macrophage nuclei upon fusion. All the evidence indicates that the function of immortalizing oncogenes is necessary for the resumption of the DNA synthesis in macrophage nuclei in heterokaryons.     

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.     

Interaction of human and chick DNA repair functions in UV-irradiated xeroderma pigmentosum-chick erythrocyte heterokaryons

Fusion of chick erythrocytes with human primary fibroblasts results in the formation of heterokaryons in which the inactive chick nuclei become reactivated. The expression of chick DNA repair functions was investigated by the analysis of the DNA repair capacity after exposure to ultraviolet (UV) irradiation of such heterokaryons obtained after fusion of chick erythrocytes with normal human or xeroderma pigmentosum (XP) cells of complementation groups A, B, C and D. Unscheduled DNA synthesis (UDS) in normal human nuclei in these heterokaryons is suppressed during the first 2–4 days after fusion. The extent and duration of this suppression is positively correlated with the number of chick nuclei in the heterokaryons. Suppression is absent in heterokaryons obtained after fusion of chicken embryonic fibroblasts with XP cells (complementation group A and C).Restoration of DNA repair synthesis is found after fusion in XP nuclei of all complementation groups studied. It occurs rapidly in XP group A nuclei, starting one day after fusion and reaching near normal human levels after 5–8 days. In nuclei of the B, C and D group increased levels of UDS are found 5 days after fusion. At 8 days after fusion the UDS level is about 50% of that found in normal human nuclei. The pattern of UDS observed in the chick nuclei parallels that of the human counterpart in the fusion. A fast complementation pattern is also observed in chick fibroblast-XP group A heterokaryons resulting within 24 h in a UDS level comparable with that in chick fibroblast-normal human heterokaryons. In heterokaryons obtained after fusion of chick fibroblasts with XP group C cells UDS remains at the level of chick cells. These data suggest that reactivation of chick erythrocyte nuclei results in expression of repair functions which are able to complement the defects in the XP complementation groups A, B, C and D.     

Enucleation of mammalian cells by cytochalasin B. II. Formation of hybrid cells and heterokaryons by fusion of anucleate and nucleated cells

The development of methods for the formation of hybrid cells and heterokaryons by virus-induced fusion of chemically-enucleated cells and nucleated cells has been described. Heterokaryons and hybrid cells formed by fusion of anucleate mouse peritoneal macrophages (MPM) and nucleated mouse L and human HEp-2 cells were identified by mixed haemadsorption, by their sensitivity to trypsin and by their capacity to ingest antibody-coated sheep red blood cells. The expression of macrophage markers in these cells declined rapidly after fusion. Hybrid cell and heterokaryon formation was identified in mixed cultures of anucleate L cells and nucleated MPM, and was accompanied by the reactivation of DNA synthesis in the macrophage nuclei. Other hybrids and heterokaryons were formed by virus-induced fusion of anucleate MPM and nucleated chick embryo erythrocytes and anucleate L cells and nucleated HEp-2 cells. The value of anucleate-nucleate cell hybrids in the study of metabolic and genetic regulation in mammalian cells is discussed.     

Inhibition of DNA synthesis in proliferating human diploid fibroblasts by fusion with senescent cytoplasts

Cytoplasts were prepared from senescent human diploid fibroblasts. The cytoplasts were fused to young human diploid fibroblasts and DNA synthesis was analyzed in the fusion products. DNA synthesis was inhibited (greater than or equal to 40%) in the senescent cytoplast fusion products when compared to unfused young cells or young cytoplasts fused with young cells. These results are consistent with previous experiments that have shown the blockage of DNA synthesis in both nuclei of heterokaryons from fusions of senescent and young human diploid fibroblast cells. Furthermore, these results support the postulate that senescent cells synthesize a specific substance(s), which is present in the cytoplasm of the senescent cell that inhibits DNA synthesis.     

Preparation and characterization of chick erythrocyte nuclei from heterokaryons

A method for the isolation of reactivated chick erythrocyte nuclei from heterokaryons was developed. The heterokaryons were produced by fusing chick erythrocytes with HeLa or L cells in the presence of inactivated Sendai virus. At various time intervals after fusion nuclei were isolated directly from the monolayer by treatment with an acidic detergent solution. Chick erythrocyte nuclei were then separated from other nuclei (HeLa or L cell) by centrifugation on sucrose gradients. The purified preparation of reactivated chick erythrocyte nuclei was shown to be free from other nuclei and cytoplasmic contamination. By using L cells which had been labelled with ³H-leucine before fusion or heterokaryons labelled after fusion it was demonstrated that labelled mouse proteins migrate from the cytoplasm of the heterokaryons into the reactivating chick erythrocyte nuclei. ³H-uridine labelling of heterokaryons made by fusing UV-irradiated chick erythrocytes with L cells failed to reveal any significant migration of mouse RNA into the chick erythrocyte nuclei.     

Evidence for endogenous polypeptide-mediated inhibition of cell-cycle transit in human diploid cells

Previous studies have shown that the senescent phenotype is dominant with respect to DNA synthesis in fusions between late passage and actively replicating human diploid fibroblasts. Brief postfusion treatments with the protein synthesis inhibitor cycloheximide (CHX) or puromycin have been found to significantly delay (by 24-48 h) the inhibition of entry into DNA synthesis of young nuclei in heterokaryons after fusion with senescent cells. A significant fraction of the senescent nuclei incorporated tritiated thymidine in CHX-treated heterokaryons. The optimal duration of exposure to CHX was 1-3 h immediately after fusion, although treatments beginning as late as 9 h after fusion elevated the heterokaryon labeling index. Prefusion treatments with CHX were without a significant effect. These results are consistent with the interpretation that regulatory cell cycle inhibitor(s) which are dependent upon protein synthesis may be present in heterokaryons between senescent and actively replicating cells.     

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.     

The effect of cycloheximide on the entry into the S period of the nuclei in heterodikaryons]

Serum-deprived (0.2%) resting NIH 3T3 mouse fibroblasts were fused with serum-stimulated (10%) proliferating cells to elucidate mechanisms of entering into S-period operating in the nuclei of the heterokaryons under the effect of cycloheximide--an inhibitor of protein synthesis. Using radioautography DNA synthesis was investigated in mono-, homo- and heterodikaryons. After short (0.5-3.0 h) depressing of protein synthesis, the nuclei of stimulated cells in heterokaryons were found to enter into S-period. Under these conditions no induction of DNA synthesis was found in the nuclei of resting cells in heterodikaryons. In other experiments, resting cells were under the effect of cycloheximide during 2-4 h before the fusion, that led to a great induction of DNA synthesis in the nuclei of these cells in heterodikaryons. The data obtained are consistent with the idea of fibroblast transition to the rest under the action of labile proteins-repressors.     

Morphologic and radioautographic study of reactivation of peritoneal exudate cell nuclei in heterokarya]

The heterokaryons of undifferentiated mouse fibroblasts (L and 3T3-4E/TK-) and various cell elements of the rat peritoneal exudate were obtained under the treatment with inactivated Sendai virus. The reactivation of RNA and DNA synthesis in the nuclei of highly differentiated periotoneal exudate cells and the synthesis of thymidine kinase controlled by the nuclei of peritoneal exudate cells were shown to occur in the heterokaryons. During the process of reactivation, the ring-like nuclei of polymorphonuclear leucocytes acquired the form characteristic of the reactivated nuclei of mononuclears. The morphological changes of heparin-containing granules in the cytoplasm of the heterokaryons of mast cells and undifferentiated fibroblasts suggest the degeneration and breakdown of granules.     

Repair DNA synthesis in heterokaryons during reactivation of chick erythrocytes fused with human diploid fibroblasts or HeLa cells

Suppression of unscheduled DNA synthesis (UDS) after exposure to ultraviolet (UV) light in the human nuclei results when diploid human fibroblasts are fused with chick erythrocytes. The suppression is positively correlated with the number of erythrocyte nuclei in the heterokaryons, with a maximal effect at 36 h after fusion. Evidence is presented that this suppression is due to lowered levels of the enzymes involved in UDS as a result of inhibition of the RNA synthesis by chick components. No suppression of UDS is detected in the human nuclei of the HeLa-chick erythrocyte heterokaryons. In HeLa cells the rate of RNA synthesis is about 10 times higher than the rate in the normal diploid fibroblasts, and the relatively small inhibitory influence of the chick components will therefore not lead to a limitation of the enzymes involved in UDS in the HeLa-chick erythrocyte heterokaryons.     

DNA polymerase alpha and the regulation of entry into S phase in heterokaryons

We have previously reported that the DNA polymerase alpha activity/unit cellular protein is decreased in late-passage (senescent) human diploid fibroblast-like (HDFL) cultures due to the cellular enlargement associated with in vitro aging. In the studies described here, we have used cell fusion technology to investigate the formal kinetic relationship between the concentration of DNA polymerase alpha and the rate of reinitiation of DNA synthesis in nuclei from senescent cells. Heterokaryons were derived from the fusion of senescent cells to a series of actively dividing cell types with inherently different DNA polymerase alpha activities per cell. A kinetic analysis revealed a first-order relationship between the entry into S phase of senescent nuclei and the concentration of DNA polymerase alpha activity calculated to be in heterokaryons. This result suggests that increases in cell volume may be related to the decline in proliferative activity of late-passage HDFL cells, via "dilution" of factors essential for cellular replication.