Ability of the cells of intra- and interspecific hybrids of murine hepatoma XXIIa to synthesize the serum proteins albumin and transferrin

Independent hybrid clones resulted from the whole cell and microcell-mediated transfer of hamster or mouse fibroblast chromosomes into mouse hepatoma XXIIa cells. The fusion was promoted with PEG, ethidium bromide alone, or in combination with HAT and ouabain, was used for selecting the hybrids. Using indirect immunoautoradiography, three clones (one intra- and one interspecies microcellular; one interspecies, whole cell fusion) have been found to express their hepatic function to synthesize transferrin. The liver specific protein--albumin--was extinguished in all the hybrid combinations. Possible mechanisms of gene expression are discussed. The hybrids selected could be used for mapping chromosomes, coding proteins, as well as for studying regulation in the tandem of albumin and alpha-fetoprotein genes in the mouse genome. The microcell mediated chromosome transfer into differentiated cells has been used to construct original genetical combinations of regulatory and structural elements of the mouse genome.     

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.     

Extinction of Albumin Gene Expression in a Panel of Human Chromosome 2 Microcell Hybrids

Expression of the serum albumin gene is extinguished in rat hepatoma microcell hybrids that retain mouse chromosome 1. These data define atrans-dominant extinguisher locus,Tse-2,on mouse chromosome 1. To localize the human TSE2 locus, we prepared and characterized rat/human microcell hybrids that contained either human chromosome 1 or chromosome 2, the genetic homologues of mouse chromosome 1. Rat hepatoma microcell hybrids retaining a derivative human chromosome 1 [der 1 t(1;17)(p34.3;q11.2)] expressed their serum albumin genes at levels similar to those of parental hepatoma cells. In contrast, microcell transfer of human chromosome 2 into rat hepatoma recipients produced karyotypically heterogeneous collections of hybrid clones, some of which displayed dramatic albumin extinction phenotypes. For example, albumin mRNA levels in several extinguished microcell hybrids were reduced at least 500-fold, similar to albumin mRNA levels in hepatoma × fibroblast whole-cell hybrids. Expression of several other liver genes, including α1-antitrypsin, aldolase B, alcohol dehydrogenase, and phosphoenolpyruvate carboxykinase, was also affected in some of the microcell hybrids, but expression of these genes was not concordant with expression of albumin. Hybrid segregants were prepared from the albumin-extinguished hybrids, and reexpression of albumin mRNA and protein was observed in sublines that had lost or fragmented human chromosome 2. Finally, expression of mRNAs encoding the liver-enrichedtransactivators HNF-1, HNF-4, HNF-3α, and HNF-3β was not affected in any of the chromosome 2-containing hybrids. These data define and map a genetic locus on human chromosome 2 that extinguishes albumin gene expression intrans,and they suggest that TSE2-mediated extinction is independent of HNF-1, -4, -3α, and -3β expression.     

Activation of a silent gene is accompanied by its demethylation

The phenomenon of gene activation by cell fusion makes it possible to study a gene when it passes from a silent to an active state. The relationship between methylation and activation of the mouse albumin gene has been investigated in two types of hybrid clones: mouse lymphoblastoma--rat hepatoma hybrids where activation is very frequent, and mouse L-cell--rat hepatoma hybrids where activation is a rare event. Analysis of the methylation pattern of seven MspI/HpaII sites that occur along the first 8000 bases of the mouse albumin gene has been performed. The entire 5' region is unmethylated only in albumin-producing cells (adult liver and hepatoma); in non-hepatic cells this region is heavily methylated. In hybrids between rat hepatoma cells and mouse cells of mesenchymal origin, the only regular change is the demethylation of the most 5' site (M1), which is systematically observed in clones where expression of the mouse albumin gene has been activated. Demethylation of this site, like activation of the mouse albumin gene, is gene dosage-dependent; it is systematic in the lymphoblastoma--hepatoma hybrids and rare in L-cell--hepatoma hybrids. We conclude that demethylation of this site is tightly coupled with activation of the gene and may well be a necessary prerequisite for activation.     

Regulation of chimeric phosphoenolpyruvate carboxykinase genes by the trans-dominant locus TSE1.

Extinction of phosphoenolpyruvate carboxykinase (PCK) gene expression in hepatoma x fibroblast hybrids is mediated by a trans-acting genetic locus designated tissue-specific extinguisher 1 (TSE1). To identify PCK gene sequences required for extinction, hepatoma transfectants expressing PCK-thymidine kinase (TK) chimeric genes were fused with TK- fibroblasts and PCK-TK expression in the resulting hybrids was monitored. Expression of a PCK-TK chimera containing PCK sequences between base pairs -548 and +73 was extinguished in four of five hepatoma transfectants tested, although hybrids derived from one transfectant clone failed to extinguish PCK-TK expression. In contrast, crosses between hepatoma transfectants expressing the herpesvirus TK gene from its own promoter and TK- fibroblasts produced TK+ hybrids; extinction of the transfected TK gene was not observed. Thus, rat PCK gene sequences between base pairs -548 and +73 are sufficient for tissue-specific extinction in hybrid cells. Extinction of PCK-TK gene expression in transfectant microcell hybrids mapped specifically to human chromosome 17, the site of human TSE1.     

Segregation of the NK-sensitive phenotype in human x mouse somatic cell hybrids reveals separate genetic control of recognition and postrecognition determinants

In an attempt to investigate the nature of tumor cell-derived membrane surface determinants involved in natural killer cell (NK) recognition or postrecognition events, we have constructed human X mouse interspecies somatic cell hybrids. Highly NK-sensitive (NKs) human tumor cells were fused with NK resistant (NKr) mouse fibroblasts (LMTK-) in polyethylene glycol and selected in hypoxanthine/aminopterin/thymidine medium and ouabain. Hybrids generated from NKs erythroleukemia cells (K-562) or NKs retinoblastoma cells (Y-79) with LMTK- displayed an intermediate NK-sensitive phenotype. One Y-79 X LMTK- hybrid (YL-22) retained a high level of susceptibility to NK binding and cytolysis, as determined by 51Cr release and in cold-target inhibition assays. On the other hand, human NKr RAJI cells generated NK-resistant hybrids when fused with LMTK- fibroblasts. Four hybrids (KL-12, YL-2, YL-22, and YL-43) displaying consistent NK sensitivity were subsequently cloned by limiting dilution. Various hybrid clones derived from the KL-12 hybrid (K-562 X LMTK-) demonstrated a range of NK-sensitive phenotypes. However, the uncloned KL-12 and most cloned lines derived from this hybrid competed against 51Cr-labeled K-562 targets as well as unlabeled K-562 parental cells, regardless of their NK-sensitive phenotype. These findings raise the possibility that chromosomal segregation may be affecting a postbinding step in this hybrid system. The NK-sensitive hybrids exhibited a limited number of human chromosomes as assessed by quinacrine banding. Furthermore, human transferrin receptor (TfR) expression, as monitored by flow cytometry using the B3/25 monoclonal antibody, demonstrated no clear correlation with NK sensitivity or competitive ability in either KL or YL hybrid clones, thus arguing against the involvement of the TfR in human NK recognition. These results suggest that the NK-sensitive phenotype in human tumor cells may be regulated by genes encoded by a limited number of human chromosomes.     

Extinction, Retention and Induction of Serum Protein Secretion in Hepatoma-fibroblast Hybrids

The production of four serum proteins has been analysed in several hepatoma-fibroblast hybrids. Extinction of albumin and alpha-foetoprotein production occurs systematically in intra and interspecific (rat X mouse) hybrids derived from mouse hepatoma cells (BW). Similar hybrids derived from two related clones of rat hepatoma cells either do not produce albumin (Fa32-derived hybrids), as the BW-derived hybrids, or retain the capacity to produce it, but at a reduced rate (Fu5-derived hybrids); some differences in the control of albumin production thus seem to exist between clonal hepatoma cell lines. The mouse hepatoma cell hybrids retain the capacity to secrete transferrin at a reduced rate, and C3 (the third component of complement) at a high rate. Further analysis of C3 production in interspecific hybrids showed that both parental genomes actively contribute to C3 production: induction of C3 secretion is thus observed in these hybrids.     

Conditions required for activation of the mouse albumin or α-fetoprotein gene in hybrids between mouse lymphoblastoma and rat hepatoma cells

Activation of two previously silent mouse hepatic genes has been investigated in hybrid cells between pseudodiploid mouse lymphoblastoma cells and hyperdiploid or hypertetraploid rat hepatoma cells. In this material, activation of the mouse albumin gene is a frequent event, whereas activation of mouse alpha-fetoprotein (AFP) occurs only in those cells that produce large amounts of albumin. Quantitative tests of hybrid populations for the activated proteins and their mRNAs revealed the expected sizes and structures: moreover, as in hepatoma cells, the amount of both rat and mouse albumin produced was directly proportional to the intracellular concentration of the corresponding mRNA. The cellular environment required for activation of the liver-specific genes was investigated by cell-by-cell analysis of each hybrid clone. Immunostaining for the presence of rat and mouse albumin and mouse AFP revealed unexpected heterogeneity in the phenotypes of the hybrid populations, which were found to contain cells that: (a) failed to express either of the proteins; (b) produced all three; (c) produced both rat and mouse albumin; or (d) produced rat albumin only. Karyotypic analysis indicated that the hybrid-cell phenotype depended on parental chromosome ratios rather than absolute numbers of chromosomes. It was found for albumin and mouse AFP that the fraction of immunostained cells was equal to the fraction of metaphases that contained a minimal rat-to-mouse chromosome ratio of 2.5 and 9, respectively. It is concluded that in those hybrids, expression of liver-specific genes is regulated by extinguishers, but in a dose-dependent fashion, suggesting the intervention of antagonistic activators from the rat hepatoma chromosomes.     

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.     

Phenotypic and molecular expression of albumin in rat hepatoma X L cell hybrids

A rat hepatoma cell line (H₄A_ZC₂) was characterized with respect to seven liver-specific phenotypes. Ten clones from the fusion of H₄A_ZC₂ and mouse L cell were analyzed for the expression of these phenotypes. The only hepatic function retained by the hybrid clones was rat albumin synthesis which continued at reduced levels relative to the hepatoma parent. Rat albumin cDNA analysis of RNA from parental and hybrid cells indicated that the reduction in albumin production observed in the hybrids was reflected in coordinate reduction of cytoplasmic rat albumin mRNA.     

Plasma-protein production by rat hepatoma cells in culture, their variants and revertants

A series of subclones of the H4II line of the Reuber H35 rat hepatoma produce substantial amounts of three plasma proteins, transferrin, alpha 1-antitrypsin and fibrinogen. Immunocytochemical staining demonstrated that each of these proteins is synthesized by essentially every cell of these cell populations. Cells of dedifferentiated variant clones either cease to produce the proteins, or exhibit a substantial reduction that is accompanied by variability in the synthetic activity of individual cells of the population. As previously observed with regard to angiotensinogen production, the variant clones clearly divide into two categories: those that show only a reduction in synthesis are able to give rise to revertants, whereas the negative clones fail to do so. Revertant cells exhibit a dramatic restoration of the synthesis of plasma proteins, which in some cases, exceeds by severalfold the rates seen in the differentiated clones of origin. In addition, the revertant cells synthesize alpha-fetoprotein, a function that is not expressed by H4II cells or its daughter subclones. Immunocytochemical staining revealed that, with regard to several plasma proteins including albumin, fibrinogen and alpha-fetoprotein, the cell populations of revertant clones are very heterogeneous, for only a fraction of the cells synthesizes each protein. Hybrid cells resulting from several types of crosses, exhibited extinction of the plasma proteins, the exception being transferrin, whose production was maintained, but at a reduced level and in only a fraction of the cells. Taken together, our results show that the expression of albumin and transferrin can be dissociated from one to another, and from that of fibrinogen, alpha 1-antitrypsin and angiotensinogen.     

Albumin extinction followed by de novo methylation of its gene in somatic hybrids of a rat hepatoma

We have previously identified an Msp I site at the 5′ end of the rat albumin gene whose undermethylation is necessary but not sufficient for stable albumin expression in rat hepatoma cells [1]. We have also shown that the extinction of albumin expression in somatic hybrids is not the result of methylation at this site, since for two different crosses, rapid extinction was found to occur in the absence of any de novo methylation of the previously active gene[2]. In the present study, we examine albumin expression and albumin gene methylation for independent hybrid clones isolated from crosses between albumin expressing rat hepatoma cells and cells of two different non-expressing lines. The cells from hybrid clones of both crosses are characterized by stable extinction of albumin expression. Moreover, we find that de novo methylation of the “extinguished” albumin gene can occur in somatic hybrids, but only some weeks after the gene has ceased to be expressed.     

Secretion of alpha 1-antitrypsin by an established human hepatoma cell line and by human/mouse hybrids

The human hepatoma cell line SK-HEP-1 has been shown by radioimmunoelectrophoresis to synthesize and secrete a protein which coprecipitates with human alpha 1-antitrypsin. This protein was indistinguishable from serum alpha 1-antitrypsin in terms of electrophoretic mobility, apparent subunit molecular weight (47,000), and binding to concanavalin-A. The protein identified as alpha 1-antitrypsin (alpha 1 AT) was secreted by seven clones derived from SK-HEP-1 and by twelve out of eighteen hybrid clones derived from the fusion of SK-HEP-1 with mouse RAG cells. There was no correlation between the expression of alpha 1 AT and that of human enzymes assigned to sixteen different autosomes. There was an imperfect correlation between the expression of alpha 1 AT and of the two chromosome 9 marker enzymes AK1 and AK3 (two discordant clones).     

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.     

Molecular mechanism of extinction of liver-specific functions in mouse hepatoma x rat fibroblast hybrids: extinction of the albumin gene

Hybrids formed by the fusion of mouse hepatoma (BWTG3) and rat fibroblast (JF1) cells exhibit the extinction of mouse albumin and alpha-fetoprotein synthesis. Karyotype analyses suggest that all parental chromosomes are present in the hybrids. The extinction, therefore, of mouse hepatocyte genes is attributed to the inhibitory action of the rat genome. In these studies, we show that these hybrids possess and express the mouse beta-glucuronidase gene (which is encoded on the same chromosome as the mouse albumin and alpha-fetoprotein gene), and we present data of Southern blot analysis which demonstrate that such hybrids have indeed retained both mouse and rat albumin DNA sequences. In addition, using mouse albumin cDNA, we have shown by cDNA-RNA reassociation kinetics that albumin mRNA is virtually absent in these hybrids. We conclude from these studies that the extinction of albumin synthesis involves a mechanism which results in the loss of cytoplasmic albumin mRNA.     

Tse-2: a trans-dominant extinguisher of albumin gene expression in hepatoma hybrid cells.

Serum albumin gene expression is generally extinguished in hepatoma x fibroblast hybrids. To define the genetic basis of this phenomenon, we screened a panel of hepatoma hybrids retaining different fibroblast chromosomes for albumin production by immunofluorescence. We report that albumin extinction in these clones was strictly correlated with the retention of mouse chromosome 1. Furthermore, albumin was systematically reexpressed in chromosome 1 segregants. These data define a tissue-specific extinguisher locus (Tse-2) that affects albumin gene expression in trans. Two other liver genes, those encoding liver alcohol dehydrogenase and liv-10, were coordinately extinguished with albumin in monochromosomal hybrids that specifically retained mouse chromosome 1.     

Activation of human alpha 1-antitrypsin gene in rat hepatoma x human fetal liver cell hybrids depends on presence of human chromosome 14

In order to study the involvement of human chromosomes in the expression of liver-specific functions, we have produced somatic cell hybrids between a rat hepatoma (7777) cell line and human diploid skin fibroblasts (series XIX) or human fetal liver cells (series XXII). Production of human serum proteins was detected by immunoelectrophoretic analyses of concentrated serum-free hybrid culture supernatants. Human alpha 1-antitrypsin (AAT) was secreted by a subset of hybrids but not by the parental cells. The activated human AAT phenotype segregated concordantly with human chromosome 14 in 18 primarily HAT-selected and five azaguanine back-selected series XXII hybrids. All other chromosomes were excluded as playing a role in AAT expression. Therefore, the AAT gene (PI) is assigned to chromosome 14. This quasi-constitutive expression of a liver-specific function was not observed for the other serum proteins studied, nor was it seen in the skin fibroblast-derived hybrids (series XIX) although AAT was produced by some of them.     

Coexistence of expressed and non-expressed alpha-fetoprotein genes in somatic cell hybrids

Hybrids have been generated between mouse hepatoma cells, which actively synthesize alpha-fetoprotein (AFP), and adult hepatocytes, where AFP production is shut off. These hybrids maintain an active synthesis of mouse AFP. Using a specific radioimmunoassay, we found that rat AFP production is not activated. Southern blot analysis showed that mouse and rat AFP DNA sequences can be distinguished and that hybrid clones possessing something close to the complete chromosome sets of both parents have retained both parental AFP DNA sequences. Thus expressed and non-expressed AFP genes coexist in these hybrid cells as if their expression were dependent on a cis-acting event.