Activation of production of mouse liver enzymes in rat hepatoma-mouse lymphoid cell hybrids

The production of four liver-specific enzymes (tyrosine aminotransferase or TAT, alanine aminotransferase, aldolase B, and alcohol dehydrogenase) has been analyzed in rat hepatoma-mouse lymphoid cell hybrids containing a 1s or 2s complement of rat chromosomes. The hybrid clones which retain a nearly 2s complement of rat chromosomes show high activity of all four enzymes; those which contain a 1s rat complement show partial or complete extinction of these enzymes. The tyrosine aminotransferase produced by most of the hybrid clones is identifiable as being of both rat and mouse origin, based upon criteria of temperature sensitivity and electrophoretic mobility; antiserum to the rat liver enzyme was used to distinguish the pseudo-TAT produced by the lymphoid parent from liver-TAT produced by hepatoma and hybrid cells. By the criteron of electrophoretic mobility, the liver form (B) of aldolase, produced by only some of the hybrid clones, appears to be composed of both rat and mouse subunits. We conclude that when extinction of tissue-specific proteins does not occur or is only partial in hybrid cells (due to gene dosage effects), the genomes of both parents may be active in directing synthesis of these proteins.     

A mouse hepatoma cell line which secretes several serum proteins including albumin and alpha-foetoprotein.

A permanent cell line (BW) was established from a transplantable mouse hepatoma, BW7756, which produces alpha-foetoprotein (AFP). Three clones were isolated from the uncloned culture: BW1, BW2 and BWTG3. The cells of the latter clone, which was isolated after selection in the presence of thioguanine, are deficient in the enzyme hypoxanthine-guanine-phosphoribosyl transferase. Both BW1 and BWTG3 cells have mean chromosome number of 64 (60 telocentric and 4 metacentric chromosomes). All three clones secrete at least five serum proteins into the culture medium: albumin, AFP, and alpha 2 globulin, transferrin and C3, the third component of complement. The approximate rate of albumin secretion by BW1 and BWTG3 cells is 10 mug/24 h/10(6) cells. Both albumin and AFP can easily be detected in cell extracts. The simultaneous production of AFP and a hepatocyte specific marker (albumin) by cloned hepatoma cells show that the production of AFP by the tumour is due to the tumoural hepatocytes themselves.     

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.     

Immunofluorescence analysis of the time-course of extinction, reexpression, and activation of albumin production in rat hepatoma- mouse fibroblast heterokaryons and hybrids

We have used a combination of a sensitive immunocytochemical stain for intracellular albumin, and Hoechst 33258 dye for identification of parental nuclei to investigate the time-course of extinction, reexpression, and activation of albumin production in fusion products of 1s (hyperdiploid) or 2s (hypertetradiploid) rat hepatoma cells with mouse fibroblasts (L cells or embryonic cells). In all combinations, the initial event is extinction of albumin production. Extinction occurs immediately after fusion when the mouse fibroblast is a normal embryonic (senescent?) cell. In the case of an L cell, rat albumin is synthesized and secreted during the first 12 h after fusion; no production of mouse albumin occurs. Thereafter, albumin production ceases. 8-12 d after fusion, young hybrid colonies are found to resume the synthesis of rat albumin (reexpression), and several days later the production of mouse albumin begins (activation). The patterns of reexpression and activation indicate (a) that chromosome loss is not necessary for either event to occur and (b) that the cells active in the synthesis of mouse albumin are a subpopulation of those cells already engaged in the production of rat albumin. We conclude that (a) extinction is mediated by diffusible factor(s) from the L-cell parent that act in the hepatoma nucleus to prevent the formation of new albumin messenger RNA; (b) reexpression and activation are gene dosage- dependent but extinction is not; and (c) previously active genes are more rapidly expressed than previously silent ones.     

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.     

Expression of human hepatic genes in somatic cell hybrids

Four diploid human cell types (lymphocytes, fibroblasts, amniotic fluid cells, and hepatocytes) were fused to mouse hepatoma cells, HH. HH synthesized and secreted several liver-specific gene products including albumin, transferrin, and alpha-fetoprotein. The resulting interspecific hybrids were compared to determine whether or not the pattern of human hepatic gene expression was similar when these various cells were fused with the mouse hepatoma line. The expression of six human hepatic genes was examined, including albumin, alpha-fetoprotein, ceruloplasmin, transferrin, alpha-1-antitrypsin, and haptoglobin. Albumin was most frequently expressed while alpha-fetoprotein was not detected in any of the hybrids studied. The patterns of expression of human serum proteins differed between the hybrid series. Hybrids derived from human fibroblasts produced primarily albumin, while those derived from lymphoblastoid cells and amniocytes had a higher frequency of clones secreting alpha-1-antitrypsin. The findings reported here suggest that the frequency of hybrid clones expressing human hepatic gene products and the array of proteins produced are influenced by the histogenetic state of the human parental cell type.     

Phenotypic exclusion in mouse melanoma-rat hepatoma hybrid cells: pigment and albumin production are not reexpressed simultaneously.

Hybridization of cells of defined and different histotypes has been carried out to investigate whether the expression (or reexpression) of parental functions is mutually exclusive, as is expected if the generally assumed rule of discreteness of differentiation applies to hybrid cells. A cross of pigmented mouse melanoma cells and albumin-producing rat hepatoma cells gave rise to hybrids containing essentially one set of chromosomes from each parent and producing neither melanin nor albumin. Cells of one hybrid clone are shown to retain the potential to reexpress both parental differentiations. Successive subclonings of this hybrid have shown that cells which reexpress one function may retain the potential to reexpress the other, and that freshly isolated, morphologically homogeneous subclones may produce pigment or albumin, but not both; there successive and exclusive shifts of phenotype are documented, and in these cases, chromosome loss is very slight. The use of immunoadsorbed antisera has revealed that most (if not all) of the albumin produced by the hybrid cells is of the mouse type. We conclude that both parental determinations are retained by the hybrid cells, and that the parental differentiations are reexpressed only in a mutually exclusive fashion.     

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.     

A Mouse Hepatoma Cell Line which Secretes Several Serum Proteins Including Albumin and α-foetoprotein

A permanent cell line (BW) was established from a transplantable mouse hepatoma, BW7756, which produces α-foetoprotein (AFP).Three clones were isolated from the uncloned culture: BW1, BW2 and B WTG3. The cells of the latter clone, which was isolated after selection in the presence of thioguanine, are deficient in the enzyme hypoxanthine-guanine-phosphoribosyl transferase. Both B W1 and BWTG3 cells have mean chromosome number of 64 (60 telocentric and 4 metacentric chromosomes). All three clones secrete at least'five serum proteins into the culture medium: albumin, AFP, an a2 globulin, transferrin and C3, the third component of complement. The approximate rate of albumin secretion by BW1 and BWTG3 cells is 10 μg/24 h/10⁶ cells. Both albumin and AFP can easily be detected in cell extracts. The simultaneous production of AFP and a hepatocyte specific marker (albumin) by cloned hepatoma cells show that the production of AFP by the tumour is due to the tumoural hepatocytes themselves.     

A genetic analysis of extinction: trans-dominant loci regulate expression of liver-specific traits in hepatoma hybrid cells

Extinction is an operational term that refers to the lack of expression of tissue-specific traits that is generally observed in hybrid cells formed by fusing dissimilar cell types. To define the genetic basis of this phenomenon, a series of rat hepatoma x mouse fibroblast hybrids has been isolated and characterized. We report here that the extinction of hepatic marker traits in these clones was strictly correlated with the retention of five particular fibroblast chromosomes (autosomes 8, 9, 10, 11, and 13). In order to dissect this correlation into its component parts, hepatoma microcell hybrids containing single, specific fibroblast chromosomes were constructed. Hepatoma clones retaining only fibroblast chromosome 11 were specifically extinguished for liver-specific tyrosine aminotransferase (TAT) expression, while expression of four other hepatic traits and of numerous constitutive markers was unaffected. Furthermore, removal of fibroblast chromosome 11 from the populations by back-selection resulted in reexpression of TAT activity to full parental levels. These data define and localize a genetic locus, tissue-specific extinguisher-1 (Tse-1), which regulates hepatic TAT expression in trans. We also provide evidence that human Tse-1 resides on the homologous chromosome (human chromosome 17), and that hybrids retaining active Tse-1 loci lack TAT-specific mRNA.     

Expression of differentiated functions in hepatoma cell hybrids: IX extinction and reexpression of liver-specific enzymes in rat hepatoma-Chinese hamster fibroblast hybrids.

Most of the hybrid clones derived from a cross of Chinese hamster fibroblasts (DON) with rat hepatoma cells (Faza 967) showed preferential loss of rat chromosomes. Two of the hybrid clones retained the rat chromosomes, and both showed extinction of 4 liver-specific enzymes: aldolase B, liver alcohol dehydrogenase, and the inducible enzymes tyrosine aminotransferase and alanine aminotransferase. Subcloning of 1 of these hybrids, which contained 2 sets of hepatoma chromosomes and 1 set of hamster chromosomes, permitted the isolation of some clones which reexpressed 1 or more of the liver-specific enzymes. Liver alcohol dehydrogenase was the most frequently reexpressed enzyme and aldolase B the least. Tyrosine aminotransferase inducibility was reexpressed independently of basal activity, and the enzyme produced by the reexpressing hybrid cells was precipitated by a specific antiserum. No correlation was detected between the presence or absence of the marker chromosomes (large metacentrics) of the hamster parent and the extinction and reexpression of the hepatic enzymes. The results reported confirm and extend to interspecific hybrids the observation of the stable and independent reexpression of tissue-specific enzymes.     

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.     

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.     

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.     

Localization of the casein gene family to a single mouse chromosome

A series of mouse-hamster somatic cell hybrids containing a variable number of mouse chromosomes and a constant set of hamster chromosomes have been used to determine the chromosomal location of a family of hormone-inducible genes, the murine caseins. Recombinant mouse cDNA clones encoding the alpha-, beta-, and gamma-caseins were constructed and used in DNA restriction mapping experiments. All three casein cDNAs hybridized to the same set of somatic cell hybrid DNAs isolated from cells containing mouse chromosome 5, while negative hybridization was observed to ten other hybrid DNAs isolated from cells lacking chromosome 5. A fourth cDNA clone, designated pCM delta 40, which hybridized to an abundant 790 nucleotide poly(A)RNA isolated from 6-d lactating mouse mammary tissue, was also mapped to chromosome 5. The chromosomal assignment of the casein gene family was confirmed using a mouse albumin clone. The albumin gene had been previously localized to mouse chromosome 5 by both breeding studies and analogous molecular hybridization experiments. An additional control experiment demonstrated that another hormone-inducible gene, specifying a 620 nucleotide abundant mammary gland mRNA, hybridized to DNA isolated from a different somatic cell hybrid line. These studies represent the first localization of a peptide and steroid hormone-responsive gene family to a single mouse chromosome.     

Chromosomal assignment and trans regulation of the tyrosine aminotransferase structural gene in hepatoma hybrid cells.

The structural gene encoding liver-specific tyrosine aminotransferase (TAT; EC 2.6.1.5) was assigned to mouse chromosome 8 by screening a series of hybrid cell lines for retention of murine Tat-1 gene sequences by genomic Southern blotting. This assignment demonstrated that the Tat-1 structural gene was not syntenic with Tse-1, a chromosome 11-linked locus that negatively regulates TAT expression in trans (A. M. Killary and R. E. K. Fournier, Cell 38:523-534, 1984). We also showed that the fibroblast Tat-1 gene was systematically activated in hepatoma X fibroblast hybrids retaining fibroblast chromosomes 8 in the absence of chromosome 11 but was extinguished in cells retaining both fibroblast chromosomes. Thus, the TAT structural genes of both parental cell types were coordinately regulated in the intertypic hybrids, and the TAT phenotype of the cells was determined by the presence or absence of fibroblast Tse-1.