Somatic cell hybrids between totipotent mouse teratocarcinoma and rat hepatoma cells.

We have produced somatic cell hybrids between totipotent mouse teratocarcinoma cells and rat hepatoma cells. These hybrids were tested for the expression of liver specific functions expressed in the hepatoma cell parent and for their ability to differentiate when injected into nude mice. The results of this study indicate that hybrid cell clones do not resemble either of the parental cells, since they do not produce albumin and tyrosine aminotransferase that are expressed in the rat hepatoma parent, and are incapable of forming either teratocarcinomas or hepatomas when injected in experimental animals.     

Delayed malignancy and altered growth properties of somatic cell hybrids between rat hepatoma and mouse L-cells.

Somatic cell hybrids of mouse L-cells with rat HTC cells were studied for their growth properties in vitro and tumorigenicity in vivo. Three hybrid clones were selected for detailed study. All were delayed in tumor formation in nude mice compared with the parent lines despite their varied growth properties in vitro. One clone was sensitive to density dependent inhibition of growth (DDIG) and had a relatively low saturation density. A second clone was not sensitive to DDIG and had a higher saturation density. The third clone had atypical morphology, was insensitive to DDIG, and had a relatively high saturation density. All of the clones studied produced colonies suspended in agarose gel which were much smaller than those of the parents incubated for the same period of time. Only the pattern of growth in agarose gel corresponded to the delayed tumor formation in vivo of the hybrids. Sensitivity to DDIG and saturation density were not consistent with tumor growth. The hybrid clone that was sensitive to DDIG was the only one of the three that had a nearly complete set of chromosomes derived from each of the parents. The chromosome numbers of all three clones were unchanged after growth in agarose or as tumors in the nude mice.     

Somatic cell hybrids between Friend erythroleukemia cells and mouse hepatoma cells.

Somatic cell hybrids between hepatoma and Friend erythroleukemia parental cells were studied for the expression of liver-specific and erythroid properties. Several independent clones were isolated using HAT selection and were shown to be true hybrids by isozyme and chromosome analysis. All displayed a complete extinction of hemoglobin and globin mRNA production, but a retention of albumin and transferrin secretion. The data suggest that erythroid differntiation is being actively inhibited by the hepatoma genome. Possible mechanisms that might explain these results are discussed in the light of current hypotheses regarding the mechanism of cell differentiation.     

Developmental characteristics of somatic cell hybrids between totipotent mouse teratocarcinoma and rat intestinal villus cells

Hybrids between mouse PCC4-azal teratocarcinoma cells and rat epithelial intestinal villus cells (PCI hybrids) are phenotypically teratocarcinoma cells. They express several teratocarcinoma-specific traits but do not express functions specific for differentiated cells. Tumour formation is partially or completely suppressed. Some of the hybrids show more extensive differentiation both in vitro and in vivo than the PCC4-azal parental line. The hybrids are capable of endoderm formation in monolayer cultures and of the formation of embryoid bodies in suspension cultures. Two of the tumour-forming hybrids generate derivatives of all three germ layers, whereas differentiation in the PCC4-azal tumours is restricted to the formation of primitive neuronal tissues.     

Cell-cycle regulation of insulin-stimulated tyrosine aminotransferase activity in rat hepatoma cells

Amongst the proteins that are subjected to variation during the cell division cycle few are under hormonal regulation. The variation in amount of tyrosine aminotransferase (TAT) in the hepatic tissue is under the control of glucagon, glucocorticoids and insulin. It has been reported that the inducibility of TAT activity by dexamethasone in rat hepatoma (HTC) is limited to the late G1 and the S portions of the cell cycle. Evidence is presented in this report that in the rat hepatoma Fao, insulin (which has the capability to promote both cell growth and hormonal effects via its own receptors) modulates the TAT activity during the cell cycle. The maximal insulin-stimulated induction of TAT activity was observed at the end of the G1 phase and then decreased as cells progressed through their mitotic cycle. The number of insulin binding sites per cell was decreased by only 30% during the same period of time. Furthermore, the extent of receptor autophosphorylation decreased in the same proportion, suggesting that insulin receptors remained functional through the whole cell cycle. In fact, another insulin-stimulated cellular function, neutral amino-acid transport, was not modified as cells progressed into the S phase. Hydroxyurea, which is known to prevent cell progression into the S phase, stabilized the insulin-induced TAT activity at its maximal level for several hours. Reciprocally, removal of hydroxyurea resulted in a concomitant decrease in TAT activity and reinitiation of DNA synthesis.     

Inverse correlation between cyclic GMP and tyrosine aminotransferase degradation in rat hepatoma tissue culture cells

[1,2-³H]Cholesterol was epoxidized to radioactive cholesterol α- and β-epoxides (5,6α-epoxy-5α- and 5,6β-epoxy-5β-cholestan-3β-ols) in the ratio 1:4 by hepatic microsomal lipid hydroperoxides (MsOOH, 1 mM as active oxygen) in the presence of ferrous ion. MsOOH could be replaced by methyl linoleate hydroperoxides (MOOH) under the same conditions although the latter was less effective than the former. None of cumene hydroperoxide, t-butyl hydroperoxide, and hydrogen peroxide was an effective oxidant even at 10 mM. Neither ADP nor EDTA had an effect on the epoxidation of cholesterol by MsOOH as well as by MOOH. Ferrous ion could not be replaced by ferric ion in the hydroperoxide-mediated epoxidation. Cyanide anion potentially inhibited the reaction.     

Epstein-Barr virus in somatic cell hybrids between mouse cells and human nasopharyngeal carcinoma cells.

Somatic cell hybrids between mouse cells and cells derived directly from NPC biopsies were produced in order to study the association of the Epstein-Barr virus (EBV) genome and the expression of Epstein-Barr nuclear antigen (EBNA) with the human chromosome(s). All attempts to correlate the presence of EBV-DNA and the expression of EBNA with the presence of a particular human chromosome(s) showed that the segregation of EBV-DNA or of EBNA and human chromosomes was dysconcordant. The data, therefore, suggest that in the hybrids studied the presence of EBA-DNA is not determined by the presence of a specific human chromosome.     

Phenotype and hybrids between lymphoid cells and rat hepatoma cells

Subtetraploid rat hepatoma cells were fused with diploid or tetraploid lymphoid cells of various origins. All hybrid cells, analysed 28 h to 26 days after fusion, expressed basal and steroid-induced activities of the liver-specific enzyme tyrosine aminotransferase within the range given by the parental hepatoma cell line. Only the rat enzyme was produced in the hybrids. This was true, irrespective of the gene dosage of the lymphoid partner cell and of the presence of human X chromosomes. In contrast, the lymphoid phenotype, as monitored by production of kappa light chains specified by the diploid and tetraploid lymphoid partner cells, was totally suppressed within 72 h after fusion. No difference in phenotypic expression was observed, whether the hybrid cells were grown as monolayer or as suspension cultures.     

Segregation of rat chromosomes in somatic cell hybrids between rat cells and HT 1080 human fibrosarcoma cells

Summary We produced somatic cell hybrids between HT 1080-6TG human fibrosarcoma cells and either rat white blood cells (WBC) or cells directly derived from rat spleen. Karyologic and isozyme analyses of hybrid cells indicated that they preferentially lose rat chromosomes. Hypoxanthine-aminopterine thymidine-selected hybrid clones expressing rat hypoxanthine phosphoribosyltransferase (HPRT), glucose-6-phosphate dehydrogenase (G6PD), and phosphoglycerate kinase (PGK) and containing the rat X chromosome were counterselected in a medium containing 30 g/ml of 6-thioguanine. Concordant loss of the rat X chromosome and of the expression of rat HPRT and G6PD was observed in the hybrid clones.     

Lack of expression of differentiation in mouse teratoma-fibroblast somatic cell hybrids

Somatic cell hybrids between multipotent mouse teratoma cells and mouse fibroblasts were established and isolated. The hybrid cells possess one chromosome set of each parental type and express major histocompatibility antigens of both strains of mice from which the parental cells were derived. Upon inoculation into F1 mice, hybrid cells produced tumors which were typical fibrosarcomas as were the tumors produced by the fibroblastic parental cell line. None of the well differentiated tissue types characteristic of the teratoma parent cell tumors were expressed in the hybrid tumors. The hybrid tumors possessed the majority of the chromosomes of the two parental cells; however, the modal numbers were slightly reduced in comparison with those of the cell populations inoculated. The possible role of ‘genic balance’ in phenotypic expression of cell hybrids is discussed.     

Re-expression of hepatic functions in mouse hepatoma X rat hepatoma hybrids

Neonatal hepatic functions are selectively extinguished in hybrids between mouse hepatoma cells, that express only fetal hepatic functions, and rat hepatoma cells expressing neonatal as well as fetal functions. A search for hybrid cells reexpressing these neonatal functions was undertaken to determine; (1) whether the selective extinction of neonatal functions is reversible and at what frequency, and (2) whether the re-expression of neonatal functions would be accompanied by modifications in the expression of fetal functions. The criterion used to obtain hybrids showing re-expression was glucose-free medium (G) where growth requires the presence of the extinguished gluconeogenic enzymes. Even though the parental cells are of the same histotype it proved difficult to obtain re-expression. Survivors in G- were obtained only from hybrids containing a greater than 1s complement of rat chromosomes; they reexpress not only gluconeogenic enzymes but also basal tyrosine aminotransferase activity, and the fetal hepatic function alpha-fetoprotein continues to be expressed in most of the clones. All survivors in G- display a significant loss of chromosomes and this loss concerns essentially mouse chromosomes.     

Re-expression of hepatic functions in mouse hepatoma X rat hepatoma hybrids

Abstract. Neonatal hepatic functions are selectively extinguished in hybrids between mouse hepatoma cells, that express only fetal hepatic functions, and rat hepatoma cells expressing neonatal as well as fetal functions. A search for hybrid cells reexpressing these neonatal functions was undertaken to determine; (1) whether the selective extinction of neonatal functions is reversible and at what frequency, and (2) whether the reexpression of neonatal functions would be accompanied by modifications in the expression of fetal functions. The criterion used to obtain hybrids showing reexpression was glucose-free medium (G-) where growth requires the presence of the extinguished gluconeogenic enzymes. Even though the parental cells are of the same histotype it proved difficult to obtain re-expression. Survivors in G- were obtained only from hybrids containing a greater than Is complement of rat chromosomes; they reexpress not only gluconeogenic enzymes but also basal tyrosine aminotransferase activity, and the fetal hepatic function a-fetoprotein continues to be expressed in most of the clones. All survivors in G- display a significant loss of chromosomes and this loss concerns essentially mouse chromosomes.