Ultrastructure of chick erythrocyte nuclei undergoing reactivation in heterokaryons and enucleated cells

The reactivation of chick erythrocyte nuclei after Sendai virus induced fusion of chick erythrocytes with intact or anucleate rat myoblasts or rat epithelial cells was studied by electron microscopy. Both in heterokaryons and in reconstituted cells formed by the fusion of chick red cells with anucleate rat L6 myoblasts the amount of highly condensed chromatin in the chick nuclei decreased with time after fusion at the same time as the proportion of dispersed chromatin increased. Nuclear organelles, typical of active nuclei but absent in the nuclei of unfused erythrocytes, appeared during reactivation. The percentage of chick nuclei containing a nucleolus was low 24 h after fusion but increased so that almost all nuclei contained one or more nucleoli 120 h after fusion. In reconstituted cells the frequency of nucleoli was much lower than in heterokaryons. In other respects, the erythrocyte nuclei introduced into anucleate rat cells underwent a normal reactivation and appeared to be well integrated with the cytoplasm. Thus, the nuclear envelope consisted of two normal leaflets in direct contact with the cytoplasm. Nuclear pores were observed in front of interchromatin channels. A normal cytoplasmic geometry appeared to be re-established since the Golgi apparatus occupied a position close to the poles of the chick nucleus.     

Intracellular antigen migration in interspecific myoblast heterokaryons

Intracellular migration of species-specific nuclear antigens was studied in chick-rat heterokaryons. These cells were produced by virus-induced or spontaneous fusion of different chick cells with rat myoblasts or myotubes. Chick erythrocyte nuclei introduced into rat myogenic cells increased in volume and were reactivated to synthesize RNA. As the chick erythrocyte nuclei enlarged, they rapidly accumulated rat nuclear antigens. Rat nucleolar and nucleoplasmic antigens assumed a distribution in the chick nuclei corresponding to that in rat nuclei. In hybrid myotubes formed by the spontaneous fusion of chick myoblasts and rat myoblasts antigen exchange was at a much lower level. Some exchange of both rat and chick nuclear antigens could, however, be detected also in this system. Thus chick nuclear envelope and nucleolar antigens migrated into the rat myoblast nuclei and assumed an intranuclear localization analogous to that in chick nuclei. On the basis of these results it appears that antigenic nuclear macromolecules are constantly exchanged between the rat and chick nuclear compartments and the cytoplasm of the heterokaryon. During the rapid nuclear swelling which occurs when chick erythrocyte nuclei are activated in rat myoblast heterokaryons, the inward migration of rat nuclear antigens into the chick erythrocyte nucleus is more impressive than the migration of chick antigens into the rat nuclei.     

Reactivation of chick erythrocyte nuclei in young and senescent WI38 cells

The chromatin of the dormant chick nucleus is dispersed in the heterokaryons made by Sendai virus fusion of phase II WI38 cells with chick erythrocyte nuclei. The erythrocyte nucleus resumes RNA synthesis and enters into DNA synthesis with the host nucleus. In the heterokaryons of phase III WI38 cells and chick erythrocytes, the nuclear chromatin is not dispersed and RNA synthesis occurs at a reduced rate. The differences in the physiological state of the young and senescent cells measured by [³H]uridine incorporation into nuclear RNA is reflected in the extent of reactivation of the chick erythrocyte nuclei in the cytoplasm of these cells. The reactivation of the chick nucleus in enucleated fibroblasts parallels the nucleated cells. The results of these studies are interpreted as evidence that there is a specific loss of nuclear function in the senescent cells.     

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 tissuespecific 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.     

Suppressive effect of protease inhibitors on heterokaryons containing chick erythrocyte nuclei

Nuclei of active cells (HeLa, mouse fibroblasts) partnered with chick erythrocyte nuclei in heterokaryons are suppressed, as judged by a decreased rate of ³H-uridine incorporation and diminished nuclear binding of ³H-actinomycin D. The extent to which active partner nuclei are suppressed, the extent to which erythrocyte nuclei are reactivated, and the degree of sensitivity of heterokaryons towards certain inhibitors of proteolytic enzymes, all correlate strongly with the ratios of erythrocyte nuclei to active nuclei. Thus, reactivation of individual erythrocyte nuclei is reduced progressively and active nuclei are suppressed progressively as the ratio of erythrocyte nuclei per active nucleus in heterokaryons increases. This erythrocyte nuclear-dose dependent suppression is markedly amplified when heterokaryons are grown in the presence of protease inhibitors. The protease inhibitors found to affect heterokaryons are low molecular weight (<400) inhibitors of trypsin-like enzymes: -1-tosylamide-2-leucyl chloromethyl ketone (TLCK), N-α-tosyl- -arginine methyl ester (TAME) and N-benzoyl- -arginine amide (BAA). They affect heterokaryons at concentrations comparable to the minimal concentrations at which they inhibit trypsin. Nonfused HeLa cells, mouse fibroblasts, or their homokaryons are refractory to protease inhibitors at these concentrations.Reactivation of chick erythrocyte nuclei in a heterokaryon may involve release of suppressors ordinarily confined to the erythrocyte nucleus, with subsequent redistribution of suppressor among all the nuclei of the heterokaryon. Under these circumstances the state of nuclear activity will depend on the quantity of suppressor per individual nucleus; within the erythrocyte nucleus the suppressors will decrease its rate of reactivation, when they migrate into an active nucleus they will suppress it. These suppressors, either in transit between the nuclei, or within the nuclei, may be hydrolysed by intracellular proteases.     

Nucleo-cytoplasmic protein migration during the activation of chick erythrocyte nuclei in heterokaryons

The reactivation of the chick erythrocyte nucleus was studied after erythrocytes were induced to fuse with rat epithelial cells in the presence of Sendai virus. The chick nucleus swells, shows an increase in dry mass and protein content and resumes RNA synthesis. Nucleoplasmic antigens characteristic of the rat cell are found to migrate into the erythrocyte nucleus. The rate of uptake of these molecules, which are believed to be proteins, appears to be directly related to increases in nuclear size, ³H-uridine incorporation and RNA polymerase activity. The polymerase activity which increases during the first days after cell fusion is sensitive to α-amanitin but relatively resistant to actinomycin D. At later time points there is an increase in α-amanitin resistant polymerase activity which probably reflects the appearance of ribosomal RNA synthesis.When heterokaryons containing different proportions of rat: chick nuclei are compared, reactivation is found to proceed most rapidly in those containing a high rat: chick nuclear ratio. As the number of erythrocyte nuclei in heterokaryons increases, the rate of reactivation in the individual nuclei is progressively reduced suggesting that the erythrocyte nuclei compete with each other for macromolecules of specific importance for the activation process.     

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.     

Failure of reactivation of chick erythrocytes after fusion with temperature-sensitive mutants of mammalian cells arrested in G1

Two temperature-sensitive (ts) mutants of mammalian cell lines (AF8 and cs4D3) that arrest in G1 at the nonpermissive temperature were fused with chick erythrocytes and the induction of DNA synthesis was studied in the resulting heterokaryons. While both AF8 and cs4D3 could induce DNA synthesis in chick nuclei at the permissive temperature, they both failed to do so when arrested in G1 at the nonpermissive temperature. When S phase AF8 cells were fused with chick erythrocytes, chick nuclei were reactivated even if the heterokaryons were incubated at the temperature nonpermissive for AF8. A third ts mutant, ts111, that is blocked in cytokinesis but continues to synthesize DNA, reactivated chick nuclei at both permissive and nonpermissive temperature. It is concluded that chick erythrocyte reactivation depends on the presence of S phase-specific factors.     

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.     

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.     

Reactivation of rat peritoneal leukocyte and mast cell nuclei in heterokaryons with actively growing mouse cells

Leukocytes and mast cells of rat peritoneal exudate (PE) were fused in vitro with actively growing mouse cells. Segmented ring-shaped nuclei of granulocytes undergo drastic changes which result in dispersion of tightly condensed chromatin and gradual disappearance of the opening in the centre of the nucleus. These changes are paralleled by a resumption of RNA and DNA synthesis, as shown by autoradiography with [3H]uridine and [3H]thymidine. Solid inactive nuclei of mast cells, lymphocytes, monocytes and macrophages also resume DNA replication and high level of RNA synthesis. Fusion of thymidine kinase-deficient 3T3-4E cells with PE cells results in the incorporation of [3H]thymidine into the nuclei of heterokaryons. This may be considered evidence of the phenotypic expression of rat thymidine kinase gene in heterokaryons. A similar way in which segmented and non-segmented dormant nuclei undergo reactivation suggests that the reversibility of nuclear inactivation is a common feature of differentiated somatic cells.     

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.     

Endogenous polyamines are intimately associated with highly condensed chromatin in vivo. A fluorescence cytochemical and immunocytochemical study of spermine and spermidine during the cell cycle and in reactivated nuclei

Polyamines are low molecular weight aliphatic polycations essential for cell proliferation and differentiation. By immunocytochemistry, as well as by two independent fluorescence cytochemical methods, we show that polyamines are associated with highly condensed chromatin in nucleated erythrocytes and in metaphase and anaphase chromosomes. In other cells, polyamines mainly occur in cytoplasm. The association between polyamines and DNA in condensed chromatin is so close that DNase treatment is necessary for making polyamines available for reaction with antibodies. Studies of chick/HeLa cell heterokaryons reveal that polyamines disappear from the chick erythrocyte nuclei concomitantly with DNA decondensation and initiation of RNA synthesis. Our data strongly suggest that polyamines are important for chromatin condensation in vivo.     

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.     

Chicken erythrocyte chromatin and nuclear envelope antigens

Chromatin and inner layer nuclear envelope were isolated from chicken erythrocyte nuclei. Two antisera against dehistonized chromatin and nuclear envelope of chicken erythrocytes were obtained. Using the antiserum against dehistonized chromatin of erythrocytes we found: the presence of the antigens at approximate mol. wts of 56,000 and 77,000 tightly bound with DNA and characteristic of only erythrocyte chromatin; localized antigens at approximate mol. wts of 63,000, 68,000 and 92,000 tightly bound with DNA and common only for chromatin and nuclear envelope of chicken erythrocytes; heterogeneity of the antigens tightly bound with DNA. Using the antiserum against inner layer nuclear envelope we did not find antigens specific only for nuclear envelope and absent in erythrocyte chromatin. Some of the antigens were present in the control preparations of chicken liver chromatin and may be regarded as being species specific.     

Reactivation of chick erythrocyte nuclei in heterokaryons with temperature-sensitive Chinese hamster cells.

Chinese hamster cell line K12 is temperature-sensitive for the initiation of DNA synthesis. K12 cells synchronized by serum deprivation were collected in early G1(G0). Heterokaryons were formed by fusing chick erythrocytes with serum-starved K12 cells through the use of UV-irradiated Sendai virus. At the permissive temperature (36.5 degrees C), erythrocyte nuclei in heterokaryons enlarged, the chromatin dispersed, and erythrocyte nuclei synthesized DNA at about the same time as the K12 nuclei. At the restrictive temperature (41 degrees C), erythrocyte nuclei enlarged, but neither erythrocyte nor K12 nuclei initiated DNA synthesis. When erythrocyte nuclei were fused with Wg-1A cells, the wild-type parent for ts K12 cells, both kinds of nuclei synthesized DNA at 36.5 degrees C and 41 degrees C. Activation of erythrocyte nuclei was inefficient in heterokaryons incubated in low-serum medium. The results indicate that serum factors and a cellular function defined by the K12 mutation are required for activation of chick erythrocyte nuclear 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.