The expression of genetic information: a study with hybrid animal cells

Immunochemical detection of human enzymes in hybrid cells

Rabbit antisera have been produced against each of three purified human enzymes: a cytoplasmic form of NADP-linked isocitrate dehydrogenase (IDH, EC 1.1.1.42), phosphoglucose isomerase (PGI, EC 5.3.1.9), and hypoxanthine guanine phosphoribosyltransferase (HGPRT, EC 2.4.2.8), and they have been used for immunoprecipitation reactions to detect human-specific enzymes in various human-mouse somatic cell hybrids. Under optimal conditions, enzyme activity was eliminated from human cell lysate, but no reduction of enzyme activity was found in the mouse cell lysate. Differential enzyme precipitation by these human-specific antisera was observed in human-mouse hybrid cells. Analysis on starch gel electrophoresis revealed that not only the human homodimer, but also human-mouse heterodimer molecules, in cases of PGI and IDH, were precipitated. Thus this method is sensitive and allows quantitative determination of human-specific enzymes. The presence of a human-specific enzyme identified by this method correlated with the presence of a particular human chromosome permitting assignments of the human cytoplasmic forms of NADP-linked IDH, human PGI, and human HGPRT genes to chromosomes 2, 19, and X, respectively. These assignments are consistent with published data (Ruddle, 1973).

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.

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.

Adenine phosphoribosyltransferase and hypoxanthine-guanine phosphoribosyltransferase immunoprecipitation reactions in human-mouse and human-hamster cell hybrids

Male New Zealand White rabbits were immunized with human adenine phosphoribosyltransferase (APRT) and hypoxanthine-guanine phosphoribosyltransferase (HGPRT), which were purified about 2000-fold and 800-fold, respectively, from erythrocytes by DEAE-cellulose chromatography, ammonium sulfate precipitation and preparative polyacrylamide gel electrophoresis. Specific immunoprecipitations of APRT and HGPRT were achieved with the antisera that were obtained and by using polyethylene glycol as a substitute for goat anti-(rabbit) gamma globulin. The activities of the human forms of these enzymes, whether from red blood cells or from cultured cells, were almost completely eliminated under the conditions of immunoprecipitation used. Little or no reduction of APRT and HGPRT activities from mouse and Chinese hamster cells was observed. This discriminatory capacity of the antisera was successfully used for the identification of human APRT and HGPRT in human-mouse and human-hamster cell hybrids using the immunoprecipitation reaction.

The control of serum protein synthesis in hepatoma-fibroblast hybrids

Hybrids between mouse hepatoma cells (which secrete several serum proteins) and mouse or rat fibroblasts (which do not secrete these proteins) produce transferrin and the third component of complement (C3) like the parental hepatoma cells, while they do not secrete either albumin or alpha-fetoprotein (AFP). This lack of albumin and AFP secretion is probably due to a lack of synthesis, rather than to a simple defect in secretion. The cessation of albumin and AFP production is not dependent upon the parental fibroblast nor upon the selection conditions; it is best explained by a shut-off synthesis and could thus reflect the existence of a regulatory mechanism. This would imply a difference between the control of albumin and AFP synthesis and that of transferrin and C3 synthesis. On the other hand, in agreement with Peterson and Weiss (1972), hybrids between rat hepatoma cells and mouse fibroblasts continue to product rat albumin. This suggests that the mouse hepatoma cells differ from the rat hepatoma cells in the way they control albumin production.

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.

[Gibberellic acid stimulated gene activity in the endosperm of Phaseolus]

Gibberellic acid, injected into maturing ovules of Phaseolus vulgaris, induces 3.2-fold enhancement of the number of additional nucleoli within the endopolyploid endosperm nuclei. The additional nucleoli originate at different sites of polytene chromosome-like chromosome bundles. They contain RNA and are sensitive to actinomycin D. Similar nucleolar bodies are extruded by the main nucleolus. It is assumed that gibberellic acid stimulates the chromosomal and nucleolar RNA synthesis, i.e., the gene activity, in the endosperm nuclei.RNA synthesis was tested by (3)H-thymidine it could be seen that gibberellin-treated and gibberellin-treated endosperms were labeled, but those of actinomycin-treated endosperms were not. Using (3)H-thymidine it could be seen that gibberellin-treated endosperm nuclei continue to replicate their DNA for a longer period than untreated nuclei. Hence it follows that the treated nuclei become more highly endopolyploid and are capable of functioning longer than the untreated ones.