X-linked control of hemoglobin production in somatic hybrids of mouse erythroleukemic cells and mouse lymphoma or bone marrow cells

Somatic cell hybrids were generated by fusion of mouse erythroleukemic cells (clone 745) to mouse lymphoma cells or mouse bone marrow cells. The erythroleukemic cells have been shown previously to have a low basal level of erythroid differentiation which is markedly amplified when the cells are grown in medium containing dimethylsulfoxide (DMSO). Hybrid cells were examined for hemoglobin production by benzidine staining. Many hybrid clones were found in which hemoglobin production in response to DMSO was either abolished or greatly reduced. From these hybrids, subclones were isolated in which hemoglobin production was restored. Karyological and enzyme analysis showed that the restoration of hemoglobin production was associated with the loss of an X chromosome contributed by the nonerythroleukemic parent. Other subclones which retained an X chromosome continued to be inhibited for hemoglobin production. Analysis of other hybrid lines capable of a limited degree of erythroid differentiation indicated a quantitative inverse correlation between the proportion of cells bearing an X chromosome and the proportion of cells able to form hemoglobin. Finally, four hybrid lines having many cells without an X chromosome were grown in medium containing DMSO. This procedure led to the selection of hybrid sublines having a nondifferentiating phenotype and concomitantly having a greatly increased proportion of cells bearing an X chromosome. Thus three lines of evidence suggest that a locus (loci) on the X chromosome is capable of inhibiting the DMSO-inducible hemoglobin production of the erythroleukemic cells.     

Suppression of the transformed phenotype of hepatoma cells after hybridization with normal diploid fibroblasts

Hybrids were generated between mouse hepatoma cells which exhibit a transformed phenotype, and rat normal diploid fibroblasts. Most isolated hybrid clones contain a single set of chromosomes from each parent. Such clones grow to low saturation densities and are unable to grow or to form colonies in soft agar. The transformed phenotype of the parental hepatoma cells is thus suppressed in these hybrids. Suppression is very stable; however, subclones which have regained a transformed phenotype could be selected; these subclones show a significant reduction of their chromosome number. Amongst the hybrid clones isolated after fusion, a few are characterized by an excess of mouse chromosomes and a reduced number of rat chromosomes. Such clones exhibit a transformed phenotype. Our results show that, provided the hybrids contain an almost complete single set of chromosomes of each parent, spontaneous transformation behaves as a recessive trait in hybrids formed with normal diploid cells.     

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.     

Co-expression of differentiation markers in hybrids between friend cells and lymphoid cells and the influence of the cell shape

We have studied the regulation of differentiation within the hemopoietic system by fusing mouse Friend cells (which can be induced to undergo red blood cell differentiation) to various mouse lymphomas and myelomas which express characteristic T and B lymphocyte surface antigens. Our results show that both erythroid and lymphoid differentiation markers can be co-expressed within the same cell. To determine whether this result applies to other differentiation states, we fused suspension Friend cells to three adherent fibroblast cell lines, and isolated both adherent and suspension hybrids. In fact, suspension hybrid clones were inducible for hemoglobin, whereas adherent clones were not. No obvious differences in overall chromosome balance were evident between the adherent and suspension hybrids. A similar correlation between suspension morphology and inducibility of hemoglobin was found in hybrids between suspension Friend cells and an adherent lymphoma line. These results show that different developmental programs can be coexpressed within the same hybrid cell; but the strongly adherent type of morphology is inconsistent with expression of the red blood cell phenotype, both in hybrid cells derived entirely from hemopoietic parental cells and in cells from widely different lineages.     

Analysis of myogenesis by somatic cell hybridization: III. Myogenic competence of hybrids derived from rat L6 myoblasts and mouse primary fibroblasts and myoblasts

Hybrid cells derived from rat L6 myoblasts and mouse primary fibroblasts (M x F hybrids), as well as those derived from rat L6 myoblasts and mouse primary myoblasts (M x M hybrids), were examined for their ability to engage in myogenesis as judged by muscle fiber formation plus the expression of skeletal muscle myosin and creatine kinase (CK). Of 172 primary hybrid colonies scored, 59% were myogenic in the M x F fusion and 97% exhibited muscle fiber formation in the M x M fusion. Individual hybrid clones from each cross were isolated, expanded and analyzed for myogenic capabilities as well. All three M x M and all ten M x F isolated clones exhibited preferential elimination of mouse chromosomes. Nonetheless, all were capable of fusing spontaneously and of elaborating skeletal muscle myosin and CK. The three M x M hybrids expressed only MM-CK whereas nine out of ten M x F hybrids produced all three CK isoenzymes (MM, MB, BB). These results suggest that M X M hybrids express CK patterns reminiscent of the rat L6 parental cells while M X F hybrids apparently mimic mouse muscle fiber CK patterns. Various models are discussed which address these phenomena.     

Construction of microcell hybrid clones containing specific mouse chromosomes: application to autosomes 8 and 17.

Fibroblast cultures prepared from mice homozygous for a Robertsonian translocation (centric fusion) between autosomes 8 and 17 [Rb(8.17)] were used as donors in microcell-mediated chromosome transfer experiments. By using hamster recipient cells deficient in adenine phosphoribosyltransferase (APRT-) and selecting for expression of murine APRT (a chromosome 8 marker), microcell hybrids were isolated which retained only the mouse Rb(8.17) translocation in addition to the hamster chromosome complement. The translocation was stable in cells maintained under APRT+ selective pressure, and mouse marker traits encoded by genes on both chromosomes 8 and 17 segregated concordantly. A second family of hybrid clones was constructed by fusing microcells derived from wild-type mouse fibroblasts with APRT- hamster cells. Four of six clones analyzed retained only mouse chromosome 8. These studies demonstrated that microcell hybrids containing specific Robertsonian translocations as the only donor-derived genetic material can be obtained. Furthermore, a number of Robertsonian translocations between chromosomes which carry selectable markers (chromosomes 3, 8, and 11) and other autosomes have been described. By using fibroblast cultures prepared from mice containing these translocations as donors in microcell fusions, 18 of the 20 mouse chromosomes could be selectively fixed in different hybrid clones. Thus, a collection of 20 hybrid clones, each containing a single, specific mouse chromosome, can be constructed by using the strategy described in this report. The potential utility of such a monochromosomal hybrid panel is discussed.     

Differential expression of mouse beta/goat beta c, mouse beta/goat beta F, and mouse beta/goat epsilon II hybrid globin genes in murine erythroleukemia cells.

We assembled three hybrid beta-globin genes by fusing the mouse beta-major promoter and initial transcribed region to one of three goat beta-like globin gene bodies: beta c (preadult), beta F (fetal), or epsilon II (embryonic). Thymidine kinase (tk)-deficient murine erythroleukemia (MEL) cells were cotransformed with one of these constructs and a separate plasmid bearing the tk gene. Half of the 24 cell lines containing either the mouse beta/goat beta c or mouse beta/goat beta F genes expressed the transferred genes at significant levels; in many cases the hybrid genes were, like the endogenous beta-globin genes, inducible with dimethyl sulfoxide. We obtained 13 cell lines containing the mouse beta/goat epsilon II hybrid gene, 6 of which were cotransfected with a mouse beta/human beta fusion gene known to function in MEL cells. In contrast to the results with the other fusion genes, the mouse beta/goat epsilon II hybrid was very poorly expressed: in two separate experiments, 0 of 13 and 2 of 13 lines showed significant mouse beta/goat epsilon II RNA levels after induction. In all these lines the endogenous mouse beta and cotransfected mouse beta/human beta genes were expressed. As an initial test of possible reasons for the inactivity of the mouse beta/goat epsilon II hybrid, we recloned this fusion gene into a tk-bearing plasmid, adjacent to the tk gene. Of 12 cell lines transformed with this plasmid, 11 produced mouse beta/goat epsilon II RNA; in 6 cases the expression was both strong and dimethyl sulfoxide inducible.     

Absence of extensive recombination between inter- and intraspecies mitochondrial DNA in mammalian cells

Recombination of mammalian mitochondrial DNA (mtDNA) was examined using mouse X rat somatic cell hybrid clones and rat cybrid clones. The mouse X rat hybrids were isolated by fusion of chloramphenicol-sensitive (CAPs) mouse and CAP-resistant (CAPr) rat cells. The rat cybrids were isolated by fusion of rat cells with type B mtDNA and enucleated cells with type A mtDNA. Genetic and physical analyses showed that the mtDNAs of the hybrids and cybrids were simple mixtures of the two parental mtDNAs except in the following two cases: One was subclone H2-9 of mouse X rat hybrids, which was CAPr even though mtDNA from the CAPs mouse parent was predominantly retained. The other was rat cybrid subclones, Y12-24 and -61, which showed specific loss of one Hinf I fragment of type B mtDNA, B10. These observations suggest that, in contrast to the case with plant mtDNA, recombination of mammalian mtDNA occurs rarely, if at all.     

Somatic cell hybrids of mouse myeloma cells and B lymphocytes from a patient with agammaglobulinemia: failure to secrete human immunoglobulin.

Somatic cell hybrid clones were isolated from the fusion of RPC5.4 mouse myeloma cells and B lymphocytes from a patient with common varied agammaglobuinemia. The patient has B lymphocytes that synthesize immunoglobulin but fail to secrete immunoglobulin. The hybrid character of the six clones was established by examination of metaphase chromosome spreads. Most of the hybrid clones expressed mouse and human surface immunoglobulin. All of the clones synthesized immunoglobulin of mouse and human parental origin. Mouse parental immunoglobulin was secreted, whereas the human parental immunoglobulin was not secreted. Human light chain molecules were secreted as part of hybrid H2L2 molecules formed with mouse heavy chains. Human heavy chains had a reduced m.w. in comparison to the mouse heavy chains. Kinetic experiments indicated that human Ig was synthesized in amounts that were comparable to the mouse Ig. Pulse-chase experiments showed that that the intracellular human Ig was removed from the cytoplasm, probably by degradation. These experiments demonstrate that the hybrid cells are an in vitro model of naturally occurring failure of immunoglobulin secretion from agammaglobulinemia. The failure of fusion with mouse myeloma cells to complement the secretion defect suggests that these B cells produce an altered immunoglobulin molecule that is not programmed for secretion.     

Expression of the neuron-specific protein, 14-3-2, and steroid sulfatase in neuroblastoma cell hybrids

Three series of neuroblastoma X fibroblast hybrid clones were isolated from crosses between mouse or human fibroblasts and mouse or human neuroblastoma cell lines by virus-mediated cell fusion. The expression of 14-3-2 protein (an acidic protein specific to neurons) and steroid sulfatase activity was studied in parental and hybrid cell lines. Steroid sulfatase was extinguished in hybrids when only one parent expressed the enzyme, but was expressed in one hybrid combination in which both parents expressed the enzyme. The neuron-specific 14-3-2 protein, on the other hand, continued to be expressed in all three series of neuroblastoma x fibroblast hybrids. In most cases where these pheno-types were expressed, they also exhibited temporal modulation; that is, specific activity is low during logarithmic growth and increases markedly during stationary phase. The glial-specific protein S-100 is absent from all parents and hybrids. The results are discussed in terms of mechanisms of regulation of differentiated phenotypes in mammalian cells.     

Expression of differentiated functions in hepatoma cell hybrids. II. Aldolase

A study of aldolases in rat hepatoma clones and subclones has revealed that they synthesize all three forms of aldolase monomers: A (the ubiquitous glycolytic isozyme), B (the form characteristic of the liver) and C, and that in vitro–in vivo passage results in a reversible modulation in aldolase A activity. Three kinds of somatic hybrids, between rat hepatoma cells and either mouse fibroblasts or rat epithelial cells, have been studied. In each case, aldolase B, found only in the hepatoma parent, was absent in the hybrid cells. The absence of aldolase B in the somatic hybrids seems not to be due to trivial factors (species differences, inactivation of all hepatoma aldolase genes, increase in ploidy or loss of chromosomes); it is concluded that extinction of this differentiated function of the hepatoma parent reflects a genetic regulatory phenomenon.     

Antigenic immunostaining patterns in somatic hybrids of human HeLa cells and mouse fibroblasts 3T3.4E propagated in conventional medium and delipidized serum

Somatic cell hybrids were obtained with electric pulse by fusion of human epithelial HeLa cells derived from a carcinoma of the uterine cervix and mouse fibroblasts 3T3.4E, deficient in thymidine kinase. Hybrids were selected and propagated in HAT media; some experiments were carried out in medium with delipidized serum. The hybrid cells were characterized by indirect immunofluorescence with a biotin-streptavidin system using a panel of nine monoclonal antibodies specific for membrane and cytoplasmic antigens of parental cells: intermediate filaments (keratins and vimentin), HLA class 1 (beta 2-microglobulin), cell activation (EGF and transferrin receptors) and cellular adhesion (fibronectin and laminin). All of these antigens were expressed in HeLa cells cultured in conventional medium or with delipidized serum. Conversely mouse fibroblasts contained only vimentin, fibronectin and laminin. All the parental antigens were present in first passage hybrid cells cultured in conventional medium. Vimentin, fibronectin and laminin were maintained in fourth passage hybrids whereas keratins, beta 2-microglobulin, EGF and transferrin receptors were no longer detected. When propagated in medium with delipidized serum, hybrid cells re-expressed these antigens after 5 days of culture. These findings suggest that the reexpression of HeLa cell antigens in hybrid cells was related to deficiency in vitamin A.     

Expression of nervous system antigen-3 by lines of mouse fibroblasts and kidney cells and continued expression in hybrid cells

In a survey of the expression on cultured mouse cells of the cell surface antigen known as nervous system antigen-3 (NS-3), it was found that RAG, a renal adenocarcinoma line, expressed that antigen. It was also observed that 3T3, a fibroblast line of unknown tissue origin, expressed NS-3. Cells of these two lines were hybridized with cells of two mouse L cell lines that did not express NS-3. Four hybrid clones were tested for both the 3T3 × L cell cross and the RAG × L cell cross, and all the hybrids were found to be NS-3 positive. All the hybrids had at least 40% as much activity as the NS-3 positive parent. Of the four parental mouse cell lines used, only 3T3 expressed Thy-1.2 antigen on the cell surface. In contrast to the continued expression of NS-3 on hybrid cells, Thy-1.2 antigen was not detectable on two clones of 3T3 × L cell hybrids that were tested.     

Activation and Suppression of Melanogenesis in Mouse Melanoma Cells by Hybridization with Chick Embryonic Cells

Sendai virus-induced fusion of 6-thioguanine-resistant mouse melanoma cells (TG14) with various types of chick embryonic tissue cells resulted in the formation of hybrid cells. Isolated hybrid clones possessed almost complete sets of the cell chromosomes of the parent mouse and several dot-like chromosomes of the chick. Each type of hybrid clone showed characteristic tyrosinase activity that resulted in melanin production. An enhanced production of melanin was observed in the hybrids between not highly pigmented TG14 cells and retinal pigment cells. Electrophoretic analyses showed that banding patterns of tyrosinase were not of chick type but of mouse melanoma type. Numerous stage 111 and IV melanosomes of the mouse melanoma type were observed in pigmented hybrid clones. On the other hand, hybrid cells between mouse melanoma cells and chick embryonic liver cells exhibited lower tyrosinase activity.     

Hybrids formed by fusion of X- or gamma-irradiated and non-irradiated mouse cells

Hybrid cells were obtained by fusion of irradiated and non-irradiated mouse cells of two different lines; they differed from the parent lines and from the hybrid cells of non-irradiated parents in their morphological, growth and karyological properties. The frequency of their occurrence was lower than in hybrids from non-irradiated cells, and unlike the irradiated cells of the parent line, these hybrid cells were capable of permanent proliferation in vitro. Chromosomes of the irradiated parent line were preferentially eliminated from the karyotype of the hybrids.     

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.     

Characteristics of the ultrastructural organization of the nuclei of somatic cell hybrids

A study was made of the ultrastructure of cell nuclei of two types of hybrid clones obtained from the fusion of Chinese hamster with human skin fibroblasts, and from that of mouse hepatoma cells with mink fibroblasts. In cell nuclei of the eight hybrid clones deep invaginations of the inner membrane, not characteristic of the parent cells, were revealed. Analysis of serial sections, and application of electron microscopic radioautography and histochemistry have suggested that these structures are associated with the nuclear envelope which is necessary for regulating the superfluous chromosome localization in the hybrid nucleus.     

Microsomal epoxide hydrolase activity in human x mouse hybrid cells

Microsomal epoxide hydrolase (E.C.3.3.2.3) activity has been measured in human x mouse hybrid cells prepared from human cells expressing 6-7 x the activity of the mouse cells. Rabbit antihuman and antimouse antisera raised against purified enzymes were used to discriminate between human and mouse enzymes. All twenty five clones examined did not express human enzyme and this correlated with the loss of human chromosome 6 from each cell line. Four hybrids expressed 2-3 x the activity expressed by the mouse cell parent and these all retained more human chromosomes, specifically chromosome 19, than those with low activity. It is concluded that the human gene for epoxide hydrolase may be on chromosome 6 and that other gene products can affect the level of activity expressed by a cell.