Expression of malignancy traits in the interspecific somatic hybrids of tumor and normal cells

Tumorigenicity and anchorage independence in two types of the interspecies hybrids of the tumor and normal mammalian cells were studied. One hybrid type was derived from fusion of spontaneously transformed Chinese hamster and normal mouse cells; the second type was obtained by fusion of SV40-transformed Djungarian hamster and the same mouse cells. The tumorigenicity in the athymic nude mice was suppressed in the first type of hybrids. The hybrid clones derived from fusion of SV40-transformed and normal cells could form tumor in nude mice. Testing of hybrid clones for their ability to form colonies in soft agar showed that all hybrids grew well in the medium, similar to tumor parental cells. These data suggest that malignancy and anchorage independence are under separate genetic control. The influence of the origin of the tumor parental cells (spontaneous or SV40-virus transformation) on the expression of the malignancy in hybrids of the tumor and normal cells is discussed.     

Noncoordinate expression of SV40-induced transformation and tumorigenicity in mouse cell hybrids.

Somatic mouse cells hybrids formed by fusion of nontumorigenic 3T3 closely related SV40-transformed SVT2 cells were analyzed in a study designed to probe the genetic basis of the multiple phenotypic changes induced by SV40 transformation. These hybrids showed noncoordinate expression of the transformation phenotype. Although they cloned at high efficiency in medium with low serum and expressed the SV40 T-antigen of the SVT2 parent, hybrid cells grew poorly without anchorage and exhibited a cell and colony morphology intermediate between that of the parents. Tumorigenicity was assayed quantitatively by subcutaneous coinjection into athymic nude mice of serial dilutions of 10(2) to 10(5) hybrid cells with 10(7) lethally irradiated 3T3 cells. The results showed that 100--1000 times more hybrid cells had to be injected for tumor formation than were required with SVT2. These and other observations show that most 3T3/SVT2 hybrid cells are not tumorigenic but that each population contains a rare subset of tumorigenic cells.     

Quantitation of the viral DNA present in somatic cell hybrids between mouse and SV40-transformed human cells

Recent studies of somatic cell hybrids between mouse cells and SV40-transformed human cells have demonstrated a correlation between the expression of SV40 T-antigen and the presence of human chromosome 7. We have used two types of nucleic acid hybridization procedures to detect and quantitate the presence of viral DNA sequences in the DNA of the hybrid cell clones. Results of reassociation kinetics as well as hybridization with a single-strand probe indicate that SV40 DNA is present only in those hybrid clones which both contain human chromosome 7 and express the SV40 T-antigen. SV40 DNA was not detectable either in the clones which had lost human chromosome 7, or in the rare clones which retain human chromosome 7 but which do not express T-antigen. We have thus extended the correlation between human chromosome 7 and the SV40 T-antigen to the presence of integrated SV40 DNA in somatic cell hybrid clones.     

Pigmentation and tumorigenicity of reconstituted, cybrid and hybrid mouse cells

Cybrid, reconstituted and hybrid cells were formed by fusing cytoplasts with whole cells, cytoplasts with nucleoplasts, or whole cells with whole cells, respectively. The cells or cellular fragments were derived from murine melanomas expressing melanocytic functions and from tumorigenic or non-tumorigenic fibroblasts. The cybrids and reconstituted cells resembled the nuclear donor parent in the expression of melanocytic activity and tumorigenicity. The hybrid cells resembled the fibroblastic parent when comparable numbers of chromosomes were present from each parent. A ratio of 1.5:1 in favor of the melanoma genome resulted in hybrids of either phenotype. The expression and extinction of melanocytic functions and the expression and suppression of tumorigenicity were transmitted only through the nucleus. The stable expression of A-type viral particles, on the other hand, may have been inherited also by cytoplasmic transfer.     

Evidence for suppression of cellular growth in vitro and selection against the indigenous mouse X chromosome in A9 cell hybrids after microcell-mediated transfer of an X from other mammalian species

Introduction of a human or Syrian hamster X chromosome (derived from BHK-191-5C cell hybrids) into tumorigenic mouse A9 cells via microcell fusion induced changes in cellular morphology and a retardation of cellular growth. The suppression of growth of the hybrids could be abolished, however, by daily changes of medium containing 20% serum. G-banding analysis showed the absence of a single, cytogenetically identifiable, indigenous X chromosome (marker Z) in two of four hybrid clones after an X chromosome was transferred from either hamster or human cells. All hybrids were tumorigenic when tested in nude mice. Together, these data suggest that the loss of the mouse X chromosome took place probably because of growth inhibitory effects imposed on hybrid cells due to the increase in X chromosome dosage. In addition, our results show a lack of association between the phenotype of cellular growth suppression in vitro and the phenotype of suppression of tumorigenicity in vivo.     

Nonlytic simian virus 40-specific 100K phosphoprotein is associated with anchorage-independent growth in simian virus 40-transformed and revertant mouse cell lines.

Normal fibroblasts display two distinct growth controls which can be assayed as requirements for serum or for anchorage. Interaction of mouse 3T3 fibroblasts with simian virus 40 (SV40) thus generates four classes of transformed cells. We have examined viral gene expression in these four classes of cell lines. Immunoprecipitation of [35S]methionine-labeled cell extracts with an antiserum obtained from tumor-bearing hamsters detected the SV40 large T and small t proteins (94,000 molecular weight [94K], 17K) and the nonviral host 54K protein in all cell lines tested. A tumor antigen with an apparent molecular weight of 100,000 was also found in some, but not all, lines. Similar "super T" molecules have been found by others in many rodent transformed lines. We carried out an analysis of the relation of phenotype to relative amounts of these proteins in cell lines of the four classes, using the Spearman rank correlation test. The amount of the 100K T antigen relative to the 94K T antigen or to total viral protein was well correlated with the ability to form colonies in semisolid medium. No significant correlation was found between quantities of labeled 94K T antigen, 54K host antigen, or 17K t antigen and either serum or anchorage independence. Mouse cells transformed with the small t SV40 deletion mutant 884 synthesized a 100K T antigen, suggesting that small t is not required for the production of this protein. The 100K T antigen migrated more slowly than lytic T. Since mixtures of extracts from cells expressing and lacking the 100K T antigen yielded the expected amount of this protein, it is unlikely that the 100K T derives from the 94K protein by a posttranslational modification.     

Events preceding stable integration of SV40 genomes in a human cell line

We have examined the organization of integrated SV40 sequences in an uncloned population of a transformed human fibroblast cell line. Somatic cell hybrids between mouse B82 cells and human GM847 cells were examined for SV40 T-antigen expression and individual human chromosome presence. This analysis revealed that a functional SV40 genome is located on human chromosome 7. Restriction endonuclease digestion followed by blot hybridization of the parental human cell line revealed that it contains multiple normal and defective SV40 copies integrated into the host genome in tandem. A similar analysis of several T-ag+ hybrid cell lines indicated that the integrated viral sequences in different hybrid cell lines (thus in different cells of the original population) are very closely related but not always identical. Analysis of subclones of GM847 also revealed such differences. Based upon these results, we postulate that following the initial integration event, viral as well as the flanking host DNA sequences become unstable and are subject to deletions and rearrangements. This short-lived structural instability is followed by highly stable integration of SV40 which is maintained in these cells or their hybrid derivatives for at least hundreds of cell generations.     

Cellular and cell-free synthesis of simian virus 40 T-antigens in permissive and transformed cells.

mRNA extracted from a variety of simian virus 40 (SV40)-infected monkey cell lines directs the cell-free synthesis of viral T-antigen polypeptides with molecular weights estimated as 90,000 and 17,000. However, the size, abundance, and distribution of these T-antigens synthesized in vivo vary greatly over a range of permissive and transformed cell lines. To establish whether differences in the size of T-antigen polypeptides can be correlated with the transformed or lytic state, recently developed lines of SV40-transformed monkey cells that are permissive to lytic superinfection were analyzed for T-antigen. In these cells, regardless of the state of viral infection, the size and pattern of T-antigen are the same. However, species differences in the largest size of T-antigen are the same. However, species differences in the largest size of T-antigen do exist. In addition to the 90,000 T-antigen, mouse SV3T3 cells contain a 94,000 T-antigen polypeptide as well. Unlike the size variations in monkey cells, which are due to modification of T-antigen polypeptides, the 94,000 SV3T3 T-antigen results from an altered mRNA, since the cell-free products of SV3T3 mRNA also contains the 94,000 T-antigen polypeptide.     

Genetic control of tumorigenicity in interspecific mammalian cell hybrids.

The nature of genetic control of cellular malignancy was investigated by examining the tumorigenicity of a series of interspecific mouse-human cell hybrids in the athymic nude mouse. Two highly malignant but genetically distinct mouse cell lines, A9 and PG19, were hybridized with three normal human diploid fibroblast strains, and 19 independently arising hybrid clones were isolated. Each of these clones was capable of forming progressive lethal tumors in the nude mouse, and thus resembled the malignant parental mouse cells rather than the nonmalignant parental human cells. We failed to obtain any evidence for complete suppression of tumorigenicity in these cell hybrids. The absence of suppression was observed regardless of the extent and composition of the human chromosome complements retained in the hybrid clones; the results of detailed cytological and isoenzyme analyses would make it highly improbable that the observed lack of suppression was due to cellular selection in vivo for a more tumorigenic subpopulation in the injected hybrid cells. These data demonstrate that at least for the parental cell combinations used in this study, no human chromosome, when present singly in the mouse-human cell hybrids, can suppress the tumorigenic phenotype of the mouse cells. Our results are consistent with the view that the suppression of cellular malignancy previously demonstrated in intraspecific (mouse × mouse) somatic cell hybrids does not occur in interspecific (mouse-human) cell hybrids, or alternatively, genetic determinants located on two or more human chromosomes are required simultaneously to suppress the malignancy of the mouse cells in cell hybrids derived from malignant mouse cell and nonmalignant human cells.     

Suppressor genes for malignant and anchorage-independent phenotypes located on human chromosome 9 have no dosage effects

We have previously shown that microcell-mediated transfer of a der(9)t(X;9) human chromosome (HSA), derived from human fibroblast strain GM0705, into the Syrian hamster cell line BHK-191-5C produced only near-tetraploid hybrids, although the recipient cell line contained a 1:1 ratio of near-diploid and near-tetraploid cells. However, the tumorigenicity and the anchorage independence could be suppressed in the near-tetraploid hybrids with one copy of the der(9)t(X;9) chromosome. The introduction of an HSA X chromosome did not suppress either of these phenotypes. We concluded that in addition to two suppressor genes, one for tumorigenicity and another for anchorage independence, HSA 9 might carry a third gene capable of inhibiting cellular growth in vitro, which had dosage effects. In the present study, keeping one copy of the der(9)t(X;9) chromosome, we have increased the hamster background chromosome number beyond hexaploid level by fusing two microcell-generated hybrid cell lines, where both malignant and anchorage-independent phenotypes were suppressed, with the parental malignant BHK-191-5C cell line. Tests with nude mice showed that hybrids containing one copy of the der(9)t(X;9) chromosome against the increased background of chromosomes of malignant parental origin were still suppressed for both phenotypes. These results suggest that the suppressor genes for malignancy and for anchorage independence have no dosage effects, in contrast to the suppressor gene(s) for cellular growth.     

Functional analysis of a simian virus 40 super T-antigen.

The SV3T3 C120 line of simian virus 40-transformed mouse cells synthesizes no large T-antigen of molecular weight 94,000 but instead a super T-antigen of molecular weight 145,000. In the accompanying paper (Lovett et al., J. Virol. 44:963-973, 1982), we showed that the integrated viral DNA segment SV3T3-20-K contains a perfect, in-phase, tandem duplication of 1.212 kilobases within the large T-antigen coding sequences. Our data suggested that this integrated template encodes mRNAs of 3.9 and 3.6 kilobases, the smaller of which directs the synthesis of the super T-antigen of molecular weight 145,000. We transfected the DNA segment SV3T3-20-K into nonpermissive rat cells and into TK- mouse L cells and analyzed the T-antigens and viral mRNAs in the transfectants; these data prove directly the coding assignments suggested previously. The super T-antigen retained the ability to induce morphological transformation, and may even transform better than the wild-type protein. It also retained the ability to bind to the cell-coded p53 protein. Transfection into permissive CV-1 cells showed that the super T-antigen encoded by SV3T3-20-K was incapable of initiating DNA replication at the viral origin. The duplication in SV3T3-20-K thus defines a mutation which separates the transformation and DNA replication functions of large T-antigen. We discuss why such mutations may be selected in transformed cells.     

DNA-mediated gene transfer in Friend leukemia cells by cotransfection of simian virus 40 DNA with herpes simplex virus thymidine kinase DNA.

Thymidine kinase-negative Friend leukemia cells were cotransfected with simian virus 40 (SV40) DNA and thymidine kinase gene DNA of herpes simplex virus type 1. The transfected thymidine kinase-positive cells were selected in HAT medium, and SV40 T-antigen expression was observed over many months in cells cultured under selective conditions, and after adaptation to normal growth medium under nonselective conditions. It was shown by Southern blot hybridization that SV40 DNA was integrated in multiple copies in the chromosomal DNA of several clones. All SV40 DNA-containing Friend leukemia cell clones analyzed were able to undergo induced erythroid differentiation. Induced cultures still expressed SV40 T-antigen to the same extent that untreated control cultures did.     

Simian virus 40 T- and U-antigens: immunological characterization and localization in different nuclear subfractions of simian virus 40-transformed cells.

Simian virus 40 (SV40)-transformed cells and cells infected by the nondefective adenovirus 2(Ad2)-SV40 hybrid viruses Ad2+ND1 and Ad2+ND2 were analyzed for SV40 T- and U-antigens, respectively, using individual hamster SV40 tumor sera or serum for which U-antibodies were removd by absorption. These studies showed that (i) T- and U-antigens can be defined by separate classes of antigenic determinants and (ii) the U-antigenic determinants in SV40-transformed cells and in hybrid virus-infected cells are similar. The apparent discrepancy in the subcellular location of U-antigen in SV40-transformed cells (nuclear location) and in hybrid virus-infected cells (perinuclear location) as determined by immunofluorescence staining of methanol/acetone-fixed cells could be resolved by treating hybrid virus-infected cells with a hypotonic KCl solution before fixation. Upon this treatment hybrid virus-infected cells also showed nuclear U-antigen staining. The possibility of an association of T- and U-antigens with different nuclear subfractions in SV40-transformed cells was investigated. Detergent-cleaned nuclei of SV40-transformed cells were fractionated into nuclear matrices and a DNase-treated, high-salt nuclear extract. Analysis of the nuclear matrices by immunofluorescence microscopy with T+U+ and T+U- hamster SV40 tumor serum revealed that U-antigen remained associated with the nuclear matrices, whereas T-antigen could not be detected in this nuclear subfraction. T-antigen, however, could be immunoprecipitated from nuclear extracts of the SV40-transformed cells.     

Cell cycle-dependent expression of early viral genes in one group of simian virus 40-transformed rat cells.

SV40-transformed FR 3T3 rat cells were previously shown to exhibit different patterns of accumulation of the virus-coded T-antigen. One group of transformants accumulates T-antigen throughout the cell cycle, whereas in another group, only the cells in the G2 phase of the cell cycle are stained by immunofluorescence with anti-T antigen antibodies. We investigated the mechanism involved by determining the amounts of early SV40 RNA during the cell cycle. Cells in the various phases of the cell cycle were sorted from an asynchronously growing population using a flow cytofluorimeter. Determination of the amounts of viral RNA in the different nuclear and cytoplasmic RNA fractions showed that in transformants with a G2-restricted accumulation of T-antigen, viral RNA was present in G2, to some extent in S, but could not be detected in cells in G1. In contrast, equivalent amounts of viral RNA were detected in all the phases of the cell cycle in the other group of transformants. Cell sorting, performed after pulse-labeling the cells for 2 h with [35S]methionine, confirmed that translation of the viral mRNAs occurred only in G2 in the first group of transformants, and throughout the cell cycle in the second group.     

Cell properties after repeated transplantation of spontaneously and of SV40 virus transformed mouse cell lines. I. Growth in culture.

"Spontaneously" or SV40 virus transformed AL/N mouse cell lines were passed repeatedly through syngeneic mice. Cell lines were re-established in culture from minced pieces of tumors in the presence of concentrated fetal calf serum or from tumor cells dispersed by trypsin. The aim of this study was to compare the two cell lines in regard to the selection processes which operate during such procedures by characterization of the resulting cell lines. Measurements of growth in tissue culture on substratum showed no significant difference between any of the transformed cell lines. The SV40 transformed cells and its derivative cells had a low anchorage requirement for growth. The greatest anchorage requirement for growth was in the normal untransformed cells and in the derivative cells from the "spontaneously" transformed cells which were established from minced tumors. The spontaneously transformed cells and all derivative cells had high tumorigenicity (TD50 is less than 10-2). The SV40 transformed cells had no observable tumorigenicity (TD50 is greater than 10-8), except when injected into irradiated mice (TD50 = 1-5 X 10-5 in the immunocompetent mice, 5 X 10-4 in the irradiated mice). The SV40 transformed derivative cells maintained their SV40 specific T antigen and their susceptibility to lysis by specific antiserum.