Somatic cell hybridization of mouse myeloma cells

Somatic cell hybrids between different mouse myeloma cell lines have been readily isolated using modifications of existing techniques. The hybrid nature of these cells was established by HAT or HAT-ouabain selective procedures, their chromosome number, and, in one case, H-2 surface antigen expression. Three hybrid cell lines are described here in detail: an IgG_2b, ? X IgG_2a, ?; an IgG₁, ? X IgG_2b, ?; and an IgG₁, ? X IgM, λ. In all cases, both parental types of H and L chains are expressed in the hybrid cells and no new chains are observed. However, molecules possessing disulfide-bonded mixtures of parental H and/or L chains are seen. Analysis of subclones of these hybrids indicates considerable stability in the expression of the immunoglobulins for up to 13 months. However, segregant clones no longer synthesizing one or more of the parental H or L chains arise frequently.     

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.     

Supermelanotic hybrids derived from mouse melanomas and normal mouse cells

Hybrids formed between HPRT- Cloudman mouse melanoma and normal cells were isolated. The parental origin of the hybrids was verified by isoenzyme and karyotype analyses. These hybrid cells differed in two major characteristics from hybrids of melanoma and established fibroblastic cells. (1) They grew as tumors when injected into mice, and (2) they expressed differentiated melanocytic functions. At least one of the differentiated functions was overexpressed. The specific activity of tyrosinase was 3-20 times higher in the hybrid cells than in the parental mouse melanoma. The overexpression of tyrosinase in these hybrid cells has been stable for more than a year, has been transmitted to subclones of the original hybrid cell lines, and has been expressed in tumors that grew after injections of hybrid cells into animals.     

Maintenance of hemoglobin inducibility in somatic cell hybrids of tetraploid (2S) mouse erythroleukemia cells with mouse or human fibroblasts.

It has previously been reported that Friend mouse erythroleukemia (MEL) cells synthesize hemoglobin when exposed to 2% dimethylsulfoxide, and that hybrids between MEL cells and fibroblasts (or other nonerythroid cells) do not synthesize hemoglobin. We have been successful in obtaining hybrids (3/15) between MEL cells and mouse L-cell fibroblasts that maintain hemoglobin inducibility by preserving nonadherent cells after fusion. The proportion of hemoglobin inducible hybrids can be increased (8/11) by using a stable 2S (pseudotetraploid) MEL parent in addition to preserving nonadherent cells after fusion. All hybrids which were nonadherent were hemoglobin inducible, and all hybrids which were adherent were not. Five nonadherent hybrid clones were analyzed from fusions between a stable 2S MEL parent and a human fibroblast (WI-38, VA-2). All these clones were inducible for hemoglobin. It is concluded that gene dosage is effective in increasing the proportion of hemoglobin inducible hybrids, but hybrid morphology is the phenotype characteristic that correlates most closely with expression of hemoglobin inducibility.     

Co-expression of spectrin and fodrin in friend erythroleukemic cells treated with DMSO

Friend erythroleukemic cells can be used as a model of erythroid cell differentiation with the synthesis of the erythrocyte-specific products hemoglobin and spectrin stimulated by agents such as DMSO. In the present study we investigated the expression of both erythroid spectrin and non-erythroid fodrin in uninduced and DMSO-treated Friend cells. We report that both spectrin and fodrin co-exist at low levels in uninduced Friend cells and both are induced by treatment with DMSO. After longer times both spectrin and fodrin appear to undergo rearrangements into submembranous ‘patches’ and ‘caps’. Although both molecules co-localize in most of these cells, they can be independently immunoprecipitated, suggesting that significant amounts of hybrid molecules are not formed.     

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.     

Adaptation of the interspersed repetitive sequence polymerase chain reaction to the isolation of mouse DNA probes from somatic cell hybrids on a hamster background

A strategy for the rapid isolation of DNA probes from radiation-fusion Chinese hamster cell hybrids containing overlapping portions of the murine X chromosome based on the interspersed repetitive sequence polymerase chain reaction (IRS-PCR) previously used with human somatic cell hybrids has been developed. This specific amplification of mouse DNA on a hamster background depends on the use of primers directed to the B2 short interspersed repeat element family and the R repeat, from the long interspersed repeat element family, L1. Two sets of amplification conditions, which gave specific amplification of mouse DNA from either a mouse X-monochromosomal hybrid or irradiation-fusion hybrids having reduced X content, were defined. The mouse X-only chromosome hybrid yielded approximately 20 discrete reproducible bands, while the irradiation-fusion hybrids yielded between 1 and 10 discrete products. Comparison of different irradiation-fusion hybrids has allowed the definition of both specific and shared products corresponding to different regions within the overlapping X-chromosome fragments present within these hybrids. Use of such hybrids and the IRS-PCR technique has allowed the isolation of probes corresponding to the central region of the mouse X chromosome that contains the X-inactivation center. The method should be widely applicable to the isolation of mouse DNA sequences from mouse hybrid cell lines on either human or Chinese hamster backgrounds.     

Reversal of X-inactivation in female mouse somatic cells hybridized with murine teratocarcinoma stem cells in vitro

A series of near-diploid embryonal carcinoma-like hybrid cells were obtained from polyethylene glycol mediated cell fusion between murine embryonal carcinoma cells (PSA-6TG1 or OTF9-63) having one X chromosome and thymocytes or bone marrow cells from female mice carrying Cattanach's or Searle's translocation. Prior to fusion with EC cells the somatic cells are presumed to contain only one active X chromosome. Following hybrid formation, the chronology of X chromosome replication and the expression of X-linked gene Pgk-1 indicated that all X chromosomes contributed by both parents were active in these hybrids. Experiments were performed to rule out the possibility that the hybrids were formed by fusion of EC cells with rare somatic cells in which both X chromosomes were active. Taken together the data indicate that within four days of fusion there is reactivation of the entire inactive X chromosome.     

Specific esterase activity induced in mouse Friend erythroleukemia cells by dimethylsulfoxide.

Three cell lines of mouse erythroleukemia transformed by Friend virus (FLC), namely 745, F4-1, and 3BM-78, were grown for six days in the absence or in the presence of 1.5% (v/v) dimethylsulfoxide (DMSO) and compared cytochemically for naphtol-AS D-chloroacetate esterase (E), alkalinephosphatase (AP), myeloperoxidase (MP) and periodic acid Schiff (PAS) reaction activity. In the absence of inducer only 1–2% of slightly E positive cells could be found. E positivity greatly increased in 3BM-78 and F4-1 but poorly in 745 cells, after treatment with DMSO. Unlike E reaction, AP and MP reactions were positive in about 5% 3BM-78 and F4-1 cells without DMSO, but there were no positive cells after DMSO treatment. All three lines were always PAS negative. Hemoglobin synthesis (benzidine staining) was intensively induced by DMSO in all three lines. Morphologically after DMSO treatment, FLC matured displaying characteristics of basophilic megaloblastoid cells. The emergence of specific esterase activity, a marker of granulocytes, in FLC differentiating along the erythroid pathway, suggests that in these leukemia cells the genetic determinants for leukopoietic differentiation are retained and capable of being expressed phenotypically.     

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.     

Globin synthesis in friend-erythroleukemia mouse cells in protein- and lipid-free medium : Effects of dimethyl-sulfoxide, iron and erythropoietin

A cell clone of erythroleukemic mouse cells transformed by the spleen focus forming virus (SFFV) was adapted to growth in serum-free medium. The cells show induced erythroid differentiation if dimethylsulfoxide (DMSO) and iron are added to the serum-free medium. No serum constituents or macromolecules are required for induced differentiation. Serum enhances the capacity of the cells to differentiate. Erythropoietin is ineffective in promoting erythroid differentiation or an increased rate of cell division. Transferrin is not necessary for transport of iron into these cells.     

Acetylcholinesterase, carbonic anhydrase and catalase activity in Friend erythroleukemic cells, non-erythroid mouse cell lines and their somatic hybrids

Friend erythroleukemic cells (clone 745), when compared with transformed mouse fibroblasts, hepatoma, myeloma and teratocarcinoma cells, display high levels of acetylcholinesterase and carbonic anhydrase activity. Dimethylsulfoxide, which enhances hemoglobin production in Friend cells, also increases the activity of both enzymes. Inhibitor studies demonstrate that all the cholinesterase activity present in Friend cells is accounted for by the “true” acetylcholinesterase form of the enzyme. Cultured hepatoma cells have low levels of both acetylcholinesterase and pseudocholinesterase. Hybrids between the Friend cells and either transformed mouse fibroblasts or hepatoma cells not only fail to produce any detectable level of hemoglobin or globin mRNA, but also have no carbonic anhydrase activity and only low levels of acetylcholinesterase activity. Dimethylsulfoxide induces an increase in acetylcholinesterase activity in these hybrids. Catalase, which does not increase during erythropoiesis until the reticulocyte stage, is at roughly the same level in Friend cells and the non-erythroid cells we have examined; dimethylsulfoxide has no effect on the level of catalase activity in any of these cells. The data suggest that the Friend cells represent an intermediate stage of erythroid differentiation. It would appear that dimethylsulfoxide treatment stimulates the cells to differentiate further, along a pathway whose events closely follow normal in vivo erythroid differentiation. The data also support the idea that a set of genes usually expressed together in a particular cell type can be coordinatively affected in hybrids between cells maintaining two different epigenetic states.     

Extinction of globin gene expression in human fibroblast x mouse erythroleukemia cell hybrids.

We have chosen human fibroblast x mouse erythroleukemia hybrid cells as a model system to examine regulation of unique genes. The globin genes were studied as a marker of erythroid differentiation. Three separate hybrid cell lines were incubated in 2% dimethylsulfoxide, an agent which induces erythroid differentiation of the parental erythroleukemia cells. Neither human nor mouse globin mRNA sequences could be detected by a sensitive molecular hybridization assay which utilized globin complementary D N A. However, td n a from one of the cell lines was shown to contain both the mouse and humand globin genes. Thus, loss of the genes by chromosomal segregation did not account for their failure to be expressed. Cocultivation of the mouse erythroleukemia cells with excess human fibroblasts did not prevent erythroid differentiation of the erythroleukemia cells in the presence of dimethylsulfoxide. Similarly globin gene expression was preserved in tetraploid cells generated by fusion of two erythroleukemia lines. Thus, extinction of globin geneated by fusion of two erythroleukemia lines. Thus, extinction of blobin gene expression in the human fibroblast x erythroleukemia hybrids occurred at the level of mRNA production and appeared to be due to the presence of the fibroblast genome within the hybrial cell.     

Assignment of the genes for mouse type I procollagen to chromosome 16 using mouse fibroblast-Chinese hamster somatic cell hybrids

Somatic cell hybrids between mouse and Chinese hamster fibroblasts have been used to identify the chromosome responsible for the synthesis of both mouse type I procollagen subunit chains (MCOLA1 and MCOLA2). Thirty-one separate hybrid clones and subclones from ten separate hybridization events were isolated in hypoxanthine-aminopterin-thymidine (HAT) selection medium and were used for detailed gene-mapping studies. ELISA and "Western blotting" immunochemical analysis were used to detect the production of mouse type I procollagen in each hybrid clone. Mouse and Chinese hamster chromosomes were identified in each hybrid clone by trypsin-Giemsa banding of metaphase chromosome spreads and by isozyme analysis. We have found that mouse type I procollagen production segregates concordantly with mouse superoxide dismutase-1, previously mapped to mouse chromosome 16, and with the presence of mouse chromosome 16 karyotypically. Western blotting immunochemical analysis of the separated mouse procollagen chains produced by each hybrid line demonstrated that apparently the genes for both subunit chains are located on the same chromosome. These studies, therefore, assign the structural genes for mouse type I procollagen pro alpha 1 (MCOLA1) and pro alpha 2 (MCOLA2) chains to mouse chromosome 16.     

X chromosome-induced reversion of chromosome segregation in mouse/Chinese hamster somatic cell hybrids : Cellular recognition of native and foreign X chromosomes

The direction of chromosome loss in two sets of mouse-Chinese hamster hybrids was compared with the direction of segregation of the same hybrids, to which an additional X chromosome derived from either of the mouse sarcoma lines MethAa, MethAs, or CMS4, was introduced at the time of the fusion. The addition of the X chromosome was carried out by substituting in place of the Chinese hamster parent a mouse X containing microcell hybrid of the latter. It was found that the addition of an X chromosome reverses the direction of chromosome segregation, but it can do so only if the mouse parent in the hybridization is different from the line from which the X originated. The possible reasons for recognition by the cells of a native and a foreign X are discussed. The existence of a multigene family on the X chromosome, involved in this recognition, is proposed.     

Induction of erythroid differentiation in Friend leukemia cells by bromodeoxyuridine

Treatment of Friend leukemia cells with BrdU, the thymidine analog which interferes with DMSO induced differentiation in these cells as well as the expression of differentiated character in many other cell systems, is capable of inducing erythroid differentiation. Globin mRNA, as assayed by hybridization to globin cDNA, increases 2.5- to 30-fold after appropriate treatment with BrdU. This effect was observed with several different subclones of three independent Friend tumor cell lines. After BrdU treatment, globin mRNA content may reach up to 10-20% of the levels in DMSO induced cultures. The induction of erythroid differentiation is also apparent when accumulated heme content or the appearance of benzidine positive cells is monitored. One Friend cell line (745) we examined was not induced by BrdU although it incorporated an amount of BrdU into its DNA comparable to that incorporated by the other cell lines. In addition, BrdU did interfere with DMSO induction in this cell line. These results suggest that two different mechanisms may be operative in regulating erythroid differentiation in Friend leukemia cells. While BrdU interferes with the mechanism activated by DMSO treatment, this analog could independently activate an alternative mechanism.     

Erythrocyte membrane antigen expression during friend cell differentiation: Analysis of two non-inducible variants

Erythrocyte membrane antigens have been detected on induced Friend erythroleukemic cells with a rabbit antiserum raised against mouse erythrocyte membranes. The antibody specificities of this antiserum have been quantitatively analyzed using a cellular radioimmunoassay. After absorption with thymocytes, the rabbit anti-erythrocyte membrane serum bound to dimethylsulfoxide (DMSO)-induced Friend erythroleukemic cells and to mouse erythrocytes but not to uninduced Friend cells or thymocytes. Reciprocal inhibition studies demonstrated that, following complete thymocyte absorption, the antiserum detected similar antigenic specificities, termed erythrocyte membrane antigens (EMA), on both mature erythrocytes and induced Friend cells. The expression of these erythrocyte membrane antigens was also induced on Friend cells by other agents, such as ouabain and dimethylacetamide (DMA). In contrast, exogenous hematin, which did not induce hemoglobin synthesis in the Friend cell clones used in this study, also did not induce erythrocyte membrane antigen expression. Two independently derived variant clones which do not produce hemoglobin in reponse to DMSO were analyzed for their ability to produce erythrocyte membrane antigens in response to various inducers of Friend cell differentiation. Clone TG-13 is not inducible by DMSO or hematin but is weakly induced by DMA for both hemoglobin production and erythrocyte membrane antigen expression. Another variant clone, M18, was also analyzed. This clone does not synthesize detectable hemoglobin when grown in either DMSO or hematin alone, but undergoes extensive hemoglobin synthesis when grown in medium containing both DMSO and hematin. M18 does, however, express erythrocyte membrane antigens when grown in DMSO alone: the presence of hematin and DMSO together in the growth medium does not enhance expression of these antigens. Thus M18 appears to be defective for hemoglobin inducibility, and this defect can be overcome by exogenous hematin; however, the expression of erythrocyte membrane antigens is not affected by this block in hemoglobin synthesis. The results with the variant clones are discussed in terms of a program for Friend cell differentiation in which the induction of hemoglobin synthesis and erythrocyte membrane antigen expression are under both co-ordinate and separate controls.     

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.     

A new genetic locus, Bevi, on human chromosome 6 which controls the replication of baboon type C virus in human cells.

Somatic cell hybrids derived from seven independent fusions between mouse X human and hamster X human parental cells were examined for their ability to support the replication of the baboon endogenous type C virus. These hybrids preferentially segregated human chromosomes while retaining rodent chromosomes, as demonstrated by karyotypic and isozyme analysis. A total of 41 primary colonies and 33 secondary subclones were analyzed for viral replication, as well as for the presence of enzyme structural gene markers for 19 of 23 human chromosomes. A syntenic association was seen between the ability of the baboon type C virus to infect and replicate in hybrid cultures and the expression of human malic enzyme-1 (assigned to human chromosome 6). Analysis of 86 highly segregated subclones derived from cells preinfected with baboon type C virus showed that the continued production of baboon type C virus segregated concordantly with the expression of three enzyme genes assigned to human chromosome 6 (malic enzyme-1, phosphoglucomutase-3 and superoxide dismutase-2). Subclones of infected hybrids which lost chromosome 6 and failed to release virus also failed to synthesize the virus-coded major structural protein p30. No syntenic association between baboon virus expression and any of 18 other human chromosomes was observed. These studies define a new gene (designated Bevi) on human chromosome 6 which dominantly controls the replication of baboon type C virus. The data suggest that Bevi may be a preferred integration site for the baboon type C DNA provirus in the human genome.     

X-chromosome activity in heterokaryons and hybrids between mouse fibroblasts and teratocarcinoma stem cells

To determine whether 2X-active cells contain factors capable of reactivating the inactive mammalian X chromosome, fibroblast lines, having a cytologically or genetically marked inactive X, were fused with 2X-active mouse embryos or ovarian teratocarcinoma stem cells. Fusions with 2–16 cell embryos were uninformative because no mitosis occurred in heterokaryons. Fusions with 2X-active teratocarcinoma cells, and screening for re-expression of alleles on the inactive X showed that reactivation did not occur with detectable frequency in heterokaryon. Hybridization of HPRT^?M. musculus × M. caroli cells with XO HPRT^? teratocarcinoma cells yielded hybrids with a frequency of >10^?6; these hybrids all expressed the Hpt allele on the inactive M. caroli X, but not the M. caroliGpd or Pgk. Late replication-banding studies of hybrids and 6-thioguanine-resistant revertants showed that the reactivated Hp⁺ allele was still located on the late replicating X. Similar results were obtained with hybridization of this line to 1X-active (male-derived) fibroblast lines, indicating that hybridization per se, rather than a specific factor contributed by the teratocarcinoma cell partner, was reponsible for the frequent localized derepression of the Hpt⁺ allele on the inactive X.