Inheritance of immunogenicity and metastatic potential in murine cell hybrids from the T-lymphoma ESb08 and normal spleen lymphocytes

T-lymphoma cells were fused with normal lymphoid cells to examine the segregation of tumorigenicity and metastatic capacity in the hybrids. In independent fusions the immunogenic ESb08 T-lymphoma line fused successfully with normal syngeneic spleen cells (from DBA/2 and CD1 mice) enriched either with T-cells or B-cells. Ten times fewer hybrids were obtained with B-cells compared to the number obtained with T-cells, and marker assays showed that both types of fusions preferentially generated T-T hybridomas. Some of the hybrids resembled their tumor parent in their ability to form primary and secondary tumors only in irradiated DBA/2 mice, whereas other hybrids lost the high ESb08 immunogenicity, were equally tumorigenic, and in some cases metastatic, in nonirradiated mice. DNA distributions of the original hybrid lines ranged from a hexaploid DNA content (expected for complete hybrids derived from a tetraploid line and normal diploid cells) to a tetraploid DNA content, confirming the reported chromosome instability of T-T hybrids. No correlation was noted between the initial DNA content and tumorigenicity, but in the case of complete hybrids, reduction in the ploidy levels always was observed in the cells of primary and metastatic lesions. One chromosomally stable and highly malignant hybrid (C2), which was analyzed for segregation of chromosomes and for drug-resistance markers, showed preferential loss of chromosomes from the normal T-cell fusion partner. The decreased immunogenicity of this hybrid could not be related to any detectable loss of chromosomes from the ESb08 tumor parent.     

The ability of normal mouse cells to reduce the malignant potential of transformed mouse bladder epithelial cells depends on their somatic origin

Somatic cell hybrids have been made between a transformed mouse bladder carcinoma cell line and normal mouse bladder epithelium and mesenchyme. In the epithelial tumour/mesenchyme hybrids the malignant phenotype was expressed dominantly whereas in the carcinoma/normal epithelium hybrids the malignant potential was greatly reduced. In both cases the dominant in vitro and in vivo phenotype was that of the normal parental cells. All hybrid tumours were first palpable after 4-7 days, demonstrating that the tumours had not arisen as a result of in vivo selection of a sub-population of tumorigenic cells. Chromosome analysis showed that the carcinoma/normal epithelium hybrids were all in the hypertetraploid range but the large variation in the karyotypic profile of each hybrid made it impossible to implicate any specific chromosomes in the control of expression of the malignant phenotype. During normal development in bladder epithelium, terminal differentiation is associated with tetraploid formation by cell fusion. The reduction in malignancy of the carcinoma/normal epithelium hybrids may perhaps be due to the expression of genes associated with normal terminal differentiation after cell fusion and tetraploid formation. This is also supported by the more differentiated phenotype of the hybrid tumours. Of the 10 mesenchyme/epithelium hybrids analysed cytogenetically , four were in the hypertetraploid range from which little meaningful data could be obtained about specific chromosome losses. Chromosome analysis of the cells from the near-tetraploid hybrids showed only minor differences from what might have been expected from the input of the two parents; these differences appeared to be due to random chromosome loss. The maximum number of chromosomes lost from any of the hybrids was five, although one, two or three was more usual. The only consistent chromosome loss was of a single copy of chromosome 4, which in two of the hybrids represented the only chromosome change. The possibility that this loss might facilitate re-expression of the malignant phenotype is discussed.     

Suppression of the translocated myc gene and expression of intracisternal A-particle genes in tumorigenic and non-tumorigenic hybrids between murine myeloma and normal fibroblasts

We have studied the tumorigenic potential of a series of independent intraspecies hybrid clones derived from fusion of murine myeloma (BALB/c) and normal fibroblasts (C3H). All of these hybrids grew as adherent cells and thus resembled the fibroblast phenotype. As judged by chromosome enumeration, these hybrids appear to retain the full complement of their parental cells. Three out of 4 hybrids tested were able to form colonies in soft agar and to grow as tumors in either nude or (BALB/c x C3H) F1 mice, albeit at a reduced rate. The 4th hybrid did not grow in agar, was non-tumorigenic and may have had a 2:1 fibroblast to myeloma genomic equivalence ratio. In contrast to the parental myeloma cells, all the hybrids exhibited restricted growth rates in serum-free medium. As in our previous sets of hybrids formed between myeloma and L-cells, expression of the Ig genes was inhibited in the new hybrids and the derived tumors. The constitutive expression of the translocated myc gene in the myeloma parental cells was decreased in the hybrids and in all their derived tumors. In contrast, all of the hybrid cell lines and the tumors express high levels of the intracisternal A particle mRNAs. Our results show that the tumorigenic phenotype of myeloma cells is either fully or partially suppressed in myeloma x fibroblast hybrids and that this may be due to the fact that expression of the translocated c-myc is suppressed. We suggest that, in addition to the translocated myc gene, myeloma cells contain other activated oncogene(s), and that the latter are responsible for the residual tumorigenic potential of the myeloma x fibroblast hybrids.     

Suppression of transformed phenotypes in intraspecific somatic cell hybrid clones between the c-myc activating mouse plasmacytoma line and normal cells

The role of normal-cell-derived chromosome 15 in suppressing transformed phenotypes was studied in intraspecific hybrid clones between the c-myc oncogene activating BALB/c mouse plasmacytoma (S194) cells and normal spleen cells or fibroblasts from CBA/H-T6 mice. All the hybrid clones between S194 and normal spleen cells grew very rapidly in suspension and formed colonies in soft agar. In contrast, the hybrid clones between S194 and normal fibroblasts grew slowly in an attached form. They were divided into 2 groups on the basis of their morphology and growth properties: most clones showed flat type morphology, and no colony formation was seen in soft agar, while some clones grew in a piled-up fashion and formed colonies in soft agar. The hybrid clones between S194 and normal spleen cells lost some normal-cell-derived chromosomes but retained most tumor-derived marker chromosomes including the t(12;15) chromosome which carried the activated c-myc oncogene. On the other hand, hybrid clones between S194 cells and normal fibroblasts retained almost all chromosomes from both parental cells. With respect to retention of normal-cell-derived chromosome 15, both the flat and piled-up type clones retained 2 copies each of the t(14;15) and T6 marker chromosomes, the normal counterparts of the t(12;15) chromosomes. Our results suggest that the transformed phenotypes of the hybrid clones between S194 cells and normal fibroblasts are negatively modulated by normal-cell-derived chromosomes but not by normal-cell-derived chromosome 15 alone.     

Tumorigenicity of human HT1080 fibrosarcoma X normal fibroblast hybrids: chromosome dosage dependency

The tumorigenic capacity of hybrids formed by fusion of the highly tumorigenic HT1080 human fibrosarcoma cell line with nontumorigenic normal fibroblasts was examined. The HT1080 also contains an activated N-ras oncogene. Near-tetraploid hybrids which contained an approximately complete chromosomal complement from both parental cells were nontumorigenic when 1 X 10(7) cells were injected s.c. into athymic (nude) mice, whereas the parental HT1080 cells produced tumors in 100% of the animals with no latency period following injection of 2 X 10(6) cells. Tumorigenic variants were obtained from these hybrids which had lost only a few chromosomes compared to cells from the nontumorigenic mass cultures. In addition, several near-hexaploid hybrids were obtained which contained approximately a double chromosomal complement from the HT1080 parental line and a single chromosomal complement from the normal fibroblasts. All of these near-hexaploid hybrids produce tumors in 100% of nude mice with no latency period. Our results indicate that tumorigenicity of these particular human malignant cells of mesenchymal origin can be suppressed when fused with normal diploid fibroblasts. In addition, the results suggest that tumorigenicity in this system is chromosomal dosage dependent, since a diploid chromosomal complement from normal fibroblasts is capable of suppressing the tumorigenicity of a near-diploid but not a near-tetraploid chromosomal complement from the tumorigenic HT1080 parent. Finally, the loss of chromosome 1 (the chromosome to which the N-ras oncogene has been assigned) as well as chromosome 4 was correlated with the reappearance of tumorigenicity in the rare variant populations from otherwise nontumorigenic near-tetraploid hybrid cultures. Our results also suggest the possibility that tumorigenicity in these hybrids may be a gene dosage effect involving the number of activated N-ras genes in the hybrids compared to the gene(s) controlling the suppression of the activated N-ras genes.     

Properties and malignant transformation of established rat liver parenchymal cells in culture.

Epithelioid cells from the livers of normal and genetically impaired (Gunn) rats were established in long-term cultures in vitro. These cells grew as flat, epithelioid cobble-stone-type monolayers and showed a diploid karyotype. They secreted rat serum albumin and proteins into their growth media and contained aryl hydrocarbon hydroxylase. Such cells were transformed by treatment with methylazoxymethanol acetate; they then exhibited an irregular, piling growth pattern, acquired the ability to grow in soft agar, and thereafter grew as tumors in hamsters given cortisone and in nude mice. These malignant spindle-cell tumors were reestablished in culture and still secreted serum albumin. The transformed cells became highly multinucleate when exposed to cytochalasin B and thus behaved like tumor cells. This behavior was not shown by the original cells. Cells transformed by benzo[a]pyrene failed to grow in soft agar culture or as tumor in animals. Cells were not affected by diethylnitrosamine.     

Suppression of tumorigenicity in hybrids of tumorigenic Chinese hamster cells and diploid mouse fibroblasts: dependence on the presence of at least three different mouse chromosomes and independence of hamster genome dosage

Somatic cell hybrids were generated between Chinese hamster cell lines (Cl-4 and TK 17-O) with a near-diploid number of partially abnormal chromosomes and embryonic mouse fibroblasts (BALB/c). Hybrids harboring a near-diploid, near-triploid, and near-tetraploid set of hamster chromosomes plus 22 to 30 mouse chromosomes were analyzed for the expression of the transformed or tumorigenic phenotype, respectively, indicated by their capacity to form colonies in soft agar and by tumor formation after s.c. injection into nude mice. The hybrids showed (partial) suppression of tumorigenicity and of anchorage independence. The minimum number of hybrid cells required to initiate tumor growth in nude mice was 100- to 50,000-fold higher, and the latency period was 3- to 6-fold longer in comparison with the highly tumorigenic parental hamster cells. Suppression of tumorigenicity was also found in intraspecific Chinese hamster hybrids involving tumorigenic cells (E 36-O and TK 17-O) and embryonic hamster fibroblasts. To identify those mouse chromosomes associated with suppression of tumorigenicity, we investigated the expression of mouse isozyme genes and the presence of mouse chromosomes in interspecific suppressed hybrids and their tumorigenic hybrids described previously. No single mouse chromosome, even if present in two copies, and no combination of two different mouse chromosomes was sufficient to suppress tumorigenicity in these hybrids. This conclusion is based on either the presence of these chromosomes in hybrids isolated from tumors or their absence in suppressed hybrids.     

Growth and transformation suppressor genes for BHK Syrian hamster cells on human chromosomes 1 and 11.

To map putative tumor suppressor genes for the near-diploid baby hamster kidney fibrosarcoma cell line BHK, we transferred five different normal human chromosomes (1, 3, 7, 11, and 12) into these tumor cells by microcell-mediated chromosome transfer. Transfer of human chromosome 1 into BHK cells resulted in suppression of cell growth both on plastic and in soft agar, indicating that chromosome 1 has a generalized effect on cell growth and thereby suppresses anchorage-independent growth. Selection against cells with an intact chromosome 1 was observed. In contrast, the introduction of chromosome 11 into BHK cells resulted in suppression of anchorage independence but not growth on plastic. Most chromosome-11 growth-suppressed BHK hybrids retained intact copies of human chromosome 11. Tumorigenic derivatives of chromosome 11 hybrids had lost this chromosome. Transfer of human chromosome 3, 7, or 12 into BHK cells did not correlate with growth suppression of BHK cells on plastic or in soft agar. Thus, we conclude that genes that suppress BHK-cell growth in general or in agar reside on human chromosomes 1 and 11, respectively.     

Establishment and chromosome studies of in vitro lines of chemically induced rat erythroblastic leukemia cells

Eight cultured lines with a normal diploid karyotype, no. 2 trisomy, and markers involving chromosome No. 2 were established from three 7,12-dimethylbenz[a]anthracene (DMBA)- and two N-butyl-N-nitrosourea (BNU)-induced erythroblastic leukemias in noninbred Long-Evans rats. Serial in vivo and in vitro passage of these cells frequently evoked karyotype changes in stemline cells. In both lines from DMBA- and BNU-induced leukemias, ordinary and translocation no. 2 trisomy cells appeared and gradually replaced the normal diploid stemline cells. Obvious secondary karyotypic changes were also recognized in the "cloned" leukemia cells. Nucleolar chromosomes such as chromosomes no. 3 and no. 12 were frequently involved in aneuploidy and translocation. One cell line from a BNU-induced leukemia did not change its normal diploid karyotype during 12 months of in vitro passage. The above preferential growth of cells with no. 2 trisomy and the related changes during in vivo and in vitro passage as well as in-colony formation in soft agar suggest that these chromosome changes are somehow associated with the growth behavior of the leukemia cells. No positive correlation was demonstrated between karyotype and dimethyl sulfoxide-induced erythroid differentiation of the leukemia cells.     

Transplantation behavior and cytogenetic characteristics of a spontaneous reticulum cell sarcoma in the golden hamster

During a period of 2 1/2 years, 33 spontaneous reticulum-cell sarcomas arose in our colony of golden hamsters. One of the tumors, made transplantable in the solid and the ascitic form, is described with regard to behavior in homologous hosts and to cytogenetic characteristics. During four years of transplantation, the tumor changed its pattern of growth and, after an initial phase of localized growth, displayed a leukemialike mode of spread resulting in the death of the hosts on the 6th or 7th day irrespective of site of transplantation. Animals of the same passage reacted differently to tumor implantation: some hamsters developed large tumors without tumor cell spread, others showed very small tumors with heavy tumor cell dissemination. These different modes of growth are assumed to be dependent on host factors. Chromosome analyses were carried out on tumor cells of different transplantation generations. The chromosomes in cells of the 38th generation did not differ from normal hamster cells, except for a higher variation in the number of chromosomes. Within the next 15 passages the karyotype changed considerably, but from then on remained stable with a stemline of 44 chromosomes and six markers. The late replication pattern of sex chromosomes and of most of the autosomes seems to be the same for both normal hamster cells and tumor cells. The DNA content of the tumor cells was found to correspond to the modal chromosome number. No causal relationship between changes in growth characteristics and in karyotype could be established.     

Malignant cellular transformation and karyologic modifications: the contribution of intraspecific somatic hybridization in Chinese hamsters

Malignant cellular transformation and karyologic modifications: The contribution of intraspecific somatic hybridization in chinese hamsters Different characteristics of transformation were studied on subclones isolated from a hybrid cell line obtained by fusion of two Chinese hamster sublines, similar in origin but differing in some properties, particularly in transplantability. The mixed hybrid population (H^yC) has been described previously (Berebbi and Barski, 1971). Different sublines (Cl A, Cl 2, Cl3, Cl Ebl) were obtained by cloning in soft agar. Transplantability, plating efficiency in soft agar, agglutinability by Concanavalin A were studied in parallel with karyotypic evolution to establish a possible correlation. DC-3F, one of the parent strain, spontaneously transformed in vitro, produced tumors when inoculated in the cheek pouch of cortisone-treated Syrian hamsters, grew easily in soft agar and was highly agglutinable by Concanavalin A. On the contrary, the second parent strain, DC-3F/ADX/Aza had lost its tumor-producing ability; it did not grow in soft agar and was poorly agglutinated by Concanavalin A. The HyC population had actually intermediate characteristics, for the cloning efficiency as well as for Concanavalin A agglutinability. A comparison between the clones isolated from the HyC line revealed differences in tumorigenicity. These differences seem to be correlated with the modification of some surface properties: in fact these clones differed in their cloning efficiency and in their agglutinability. The clones were separated in Cl 2 and Cl A, which were poorly agglutinated, and Cl 3 and Cl Ebl with a higher agglutinability efficiency. The karyotypic evolutions of the HyC line in vitro and of the corresponding tumors were studied in parallel. We performed a statistical chromosomal analysis of each line, trying to establish a correlation between the tumorigenicity and the appearance of a distinctive abnormal sub-telocentric chromosome (M2) which was a marker of the HyC line (the arithmetical mean of this marker was 0.85). In fact the arithmetical mean of the M2 marker varied along the subcultures of the H^yC line and also in the clones studied. A relationship seemed to exist between the presence of this marker and the percentage of tumors. However a comparative statistical analysis of the different clones and of the derived tumors indicated that the M2 marker would not be the unique chromosome responsible for malignancy, since the balance of the other chromosomal pairs plays a role in the expression of cell transformation. The M2 marker would be especially involved in the modifications of the cell surface. So the polygenic phenomenon of cell transformation is probably less the result of a dominance or a deletion than of a genetic unbalance.     

Metastatic phenotype of mouse-human melanoma cell hybrids is associated with the presence of chromosome 17 from highly metastatic human melanoma cells

We have previously shown that in interspecific mouse-human melanoma cell hybrids obtained by fusion of nonmetastatic mouse with metastatic human melanoma cells, the metastatic phenotype predominates. The purpose of this study was to identify human chromosome(s) which could be responsible for conferring metastatic potential upon nonmetastatic mouse melanoma cells and therefore harbor the genes important for the metastatic properties of human melanoma cells. Seven mouse-human melanoma hybrids were examined; five were derived from the fusion of nonmetastatic (C19) and metastatic (C3) mouse K-1735 melanoma clones with highly metastatic clone (C15) of human melanoma A375 and the two others had as a human partner a nonmetastatic clone (Cls) of the A375 melanoma. The hybrids were examined during segregation of human chromosomes in vitro and in vivo for metastatic properties in nude mice and for the retaining human chromosomes. In the hybrid H7, which demonstrated the highest metastatic potential, the presence of human chromosomes was studied by GTG-banding and by fluorescence in situ hybridization (FISH) analysis. In the other hybrids, only FISH detection of human chromosomes was applied. All hybrids derived from nonmetastatic mouse and metastatic human melanoma cells demonstrated metastatic properties from early passages, when they contained the majority of the human chromosomes. Their metastatic phenotype remained stable during further segregation of most of the human chromosomes except for 17. Chromosome 17 was retained most consistently in all examined hybrids. However, the metastatic phenotype of the hybrids was associated only with the presence of chromosome 17 from the metastatic human donor cells. This chromosome was also found in almost 100% of cells recovered from lung metastases derived from the hybrid cells. In one lung metastasis developed from the H7 hybrid, chromosome 17 was detected as the sole human chromosome and these cells preserved the acquired high metastatic properties. Based on these results we conclude that human chromosome 17 from metastatic melanoma cells (A375 C15), when functional in the mouse genetic background, can be sufficient to render the recipient nonmetastatic mouse cells to a fully malignant phenotype. Additional data suggest that this ability might be related to the expression of the mutated human p53 gene.     

Suppression of tumorigenicity of A549 lung adenocarcinoma cells by human chromosomes 3 and 11 introduced via microcell-mediated chromosome transfer

To map tumor suppressor genes for lung adenocarcinomas, we introduced normal human chromosomes 3, 7, and 11 into the A549 tumor cell line by microcell-mediated chromosome transfer to test which chromosomes had the ability to suppress tumorigenicity. These human chromosomes, which contain the neomycin gene as a selectable marker, were transferred into A549 lung adenocarcinoma cells at frequencies of 0.3–1.8 × 10^?6. Two microcell hybrid clones with an introduced chromosome 3, two with an introduced chromosome 7, and six with an introduced chromosome 11 were isolated and examined for their growth properties and tumorigenicity in nude mice. Whereas parental A549 cells formed tumors with an average latency of 68 d, both microcell hybrids with an introduced chromosome 3 failed to form tumors for over 360 d. Similar tumorigenicity results were obtained when the clones were implanted into denuded tracheas, a more orthotopic transplantation site. The two clones with an introduced chromosome 7 were still tumorigenic; they formed tumors within 100–123 d after injection and grew progressively, although the tumors grew slightly slower than the parental cells did. Among the six clones with an introduced chromosome 11, one clone was still highly tumorigenic but did not contain an extra copy of an intact introduced chromosome 11. Three clones with a single intact copy of introduced chromosome 11 formed tumors with latency periods significantly longer than those of the parental cells. Two clones had two copies of the introduced chromosome 11, and both failed to form tumors within 1 yr of injection. These results indicate that chromosomes 3 and 11 can suppress the tumorigenicity of A549 lung adenocarcinoma cells.     

Characterization of an established cell line from human renal carcinoma.

A cell line, designated as OUR-10, has been established from a renal carcinoma in a Japanese woman. This cell line forms monolayers of polygonal epithelial cells with scattered round or dendritic cells and exhibits multilayering. With electron microscopy, differentiated surface structures that resemble the microvilli characteristic of renal carcinomas can be seen even at the 60th transfer. The cells have a hypodiploid karyotype with modal numbers of 39 and 40. No marker chromosomes were seen, but definite nonrandom loss of three chromosomes in Group D and one in Group E were recognized. The doubling time was estimated as approximately 32 hr in exponentially growing cultures, and the cells formed colonies in soft agar with an average efficiency of 25%. Heterotransplantation into the cheek pouch of immunosuppressed hamsters produced tumors that were histologically similar to the original cancerous tissue. The electrophoretic mobility of gamma-glutamyl transpeptidase extracted from the cells coincided with that of a novel isozyme found in human renal carcinoma tissue, and the genetic phenotype of the glucose-6-phosphate dehydrogenase was proved to be the B phenotype. The antigenic structure of HLA was determined as HLA-A2, 11; B5, 40, which was the same as that of peripheral blood lymphocytes of the woman with renal carcinoma.     

Multiple human chromosomes carrying tumor-suppressor functions for the mouse melanoma cell line B16-F10, identified by microcell-mediated chromosome transfer

Many tumor-suppressor genes are involved in the development and progression of cellular malignancy. To understand the functional role of tumor-suppressor genes in melanoma and to identify the human chromosome that carries these genes, we transferred individually each normal human chromosome, except for the Y chromosome, into the mouse melanoma cell line B16-F10, by microcell fusion. We examined the tumorigenicity of hybrid cells in nude mice and their in vitro growth properties. The introduction of human chromosomes 1 and 2 elicited a remarkable change in cell morphologic features, and cellular senescence was induced at seven to 10 population doublings. The growth rates of tumors derived from microcell hybrid clones containing introduced human chromosome 5, 7, 9, 10, 11, 13, 14, 15, 16, 19, 20, 21, 22, or X were significantly slower than that of the parental B16-F10 cells, whereas the introduction of other human chromosomes had no effect on the tumorigenicity of these cells. The majority of microcell hybrid clones that exhibited suppressed tumorigenicity also showed a moderate reduction in doubling time compared with B16-F10 cells. Microcell hybrid clones with an introduced human chromosome 5 showed complete suppression of in vitro-transformed phenotypes, including cell growth, saturation density, and colony-forming efficiency in soft agar. Thus, these results indicated the presence of many cell senescence-related genes and putative tumor-suppressor genes for the mouse melanoma cell line B16-F10 and showed in vitro that many tumor-suppressor genes control the phenotypes of transformed cells in the multistep process of neoplastic development.     

Suppression of tumorigenicity in somatic cell hybrids. II. Human chromosomes implicated as suppressors of tumorigenicity in hybrids with Chinese hamster ovary cells

Nontumorigenic diploid human cells were fused with tumorigenic Chinese hamster ovary cells (CHO), and the hybrids were tested for tumorigenicity to determine if specific human chromosomes are associated with suppression of tumorigenicity in cell hybrids. Chromosome complements of cells of 62 nontumorigenic and 45 tumorigenic hybrids (divided into those of low, medium, and high tumorigenicity) as well as 44 tumors derived from the tumorigenic hybrids were determined by both analysis of banded chromosomes and assays of gene markers. Although no single human chromosome was consistently associated with the suppressed phenotype, chromosome 2 was never found in tumor cells, and chromosomes 9, 10, 11, and 17 were found at very low incidences in tumor cells, which suggested that they carry tumorigenicity suppressor information. Since not all suppressed hybrids contained these chromosomes, it is likely that they suppressed tumorigenicity only in combination with each other or other chromosomes. Nine chromosomes in 12 pairwise combinations of nonhomologous chromosomes were not found in tumor cells and were found at an incidence of 5% or less in hybrids of both medium and high tumorigenicity. Other experiments implicated 11 of these combinations involving only 8 chromosomes (chromosomes 4, 7, 8, 9, 10, 11, 13, and 17) as those primarily involved in suppression. Whether chromosome 2 requires another chromosome to effect suppression could not be determined. Further evaluations of the implicated suppressors, including selection of tumorigenic segregants from a panel of suppressed hybrids, again implicated the same chromosomes and their combinations in suppression. Oncogenes have been mapped to many of these chromosomes, and they are frequently involved in tumor-type-specific numerical or structural abnormalities in human neoplasias. The combined evidence suggests that specific human chromosomes of a normal cell carry genes that can regulate several cell phenotypes necessary for the expression of tumorigenicity.     

Loss of the intrinsic heat resistance of human cells and changes in Mr 70,000 heat shock protein expression in human x hamster hybrids

Since mammalian cells vary widely in their intrinsic thermoresistance, we have investigated the genetic basis underlying this phenomenon in human and rodent cell lines. Typically, human cells are considerably more resistant to killing by heat than rodent cell lines. To determine whether the heat-resistant phenotype is dominant or recessive and to locate the chromosome(s) bearing determinants for heat resistance, we have prepared hybrids of heat-resistant human HT1080 cells and heat-sensitive Chinese hamster ovary (CHO) cells to test their response to heat. For both mass hybrid cultures and individual clones, the heat response of the hybrids was similar to that of the CHO parent. Analysis by in situ hybridization revealed the presence of five to 20 human chromosomes per cell in the mass hybrids and four to eight intact chromosomes plus some fragments in individual clones isolated from the hybrid cell population. A similar result was obtained using a different human cell line, AG1522. These data suggest that heat resistance is a recessive trait. Consistent with this conclusion are the results from a study of a fusion of HT1080 to a CHO mutant, BL-10, which was found to be hypersensitive to heat-induced killing. These hybrids had a normal CHO heat response and not the more heat-resistant phenotype of HT1080 cells. Two hybrid clones, H2 and H4, from the HT1080/BL-10 fusion were studied in more detail. Both clones possess similar amounts of Mr 70,000 heat shock protein (HSP70), despite the fact that H4 contains three human chromosomes (Nos. 6, 14, and 21) which carry HSP70 genes while H2 contains only one (chromosome 6). Both hybrid cell lines have the same response to heat. Although we found a wide range of sensitivities to heat, all cell lines contained a similar amount of constitutive HSP70, suggesting that HSP70 levels per se are not the critical determinant of intrinsic heat resistance.     

Specific chromosome changes associated with viral transformation of rat glial cells

Karyotypes of three malignant cell lines derived from Wistar and WKA/Mk fetal rat glioblasts, transformed by murine sarcoma virus (MSV-M-os) as well as those of four cell lines derived from C6 glioma cells of Wistar origin, retransformed by MSV-M-os, were analyzed in early culture passages. The C6 line had a modal number of 42 chromosomes with a normal male karyotype, and only a minor population of cells with 43 chromosomes. The modal chromosome number in every transformed glial cell line shifted from 42 to 43. The G-banding pattern revealed consistent chromosome abnormalities. Structural chromosome changes occurred in one chromosome No. 2 (2q-) and in one No. 4 (4q+). The cells with a 43 chromosome karyotype showed trisomy of chromosome No. 12 and its heteromorphism, a finding also confirmed by silver staining. Identical chromosome changes were found in transformed C6 cell lines. A further interesting feature was that all malignant cells had different distribution patterns of silver-stained nucleolar organizer regions (Ag-NORs) among particular chromosomes (Nos. 3, 11 and 12) from normal cells, showing an increased frequency of chromosome No. 12 with Ag-NORs. These results suggested that the gain and/or loss of specific segments involved in chromosomes Nos. 2, 4 and 12 contain(s) genes favorable to malignant transformation in rat glial cells.     

Multiple chromosomes carrying tumor suppressor activity for a uterine endometrial carcinoma cell line identified by microcell-mediated chromosome transfer

Putative tumor suppressor genes can be mapped to specific chromosomes by the introduction of individual chromosomes derived from normal cells via microcell fusion. We have examined whether a highly malignant human uterine endometrial carcinoma cell line, HHUA, can be suppressed by only one normal chromosome or by multiple chromosomes. A library of mouse A9 clones containing different human chromosomes tagged with the pSV2-neo plasmid DNA were constructed. Transfer by microcell fusion of either chromosome 1, 6, 9, 11, or 19 into the HHUA tumor cell line was performed, and the abilities of the microcell hybrids to form tumors in nude mice were examined. The introduction of a chromosome 19 had no effect on the tumorigenicity of the cells, whereas microcell-hybrid clones with an introduced chromosome 1, 6 or 9 were completely suppressed for tumorigenicity. A decrease in tumor-take incidence in some but not all clones was observed following the introduction of a chromosome 11. The nontumorigenic microcell hybrids with an introduced chromosome 1 differed from the nontumorigenic microcell hybrids with an introduced chromosome 6, 9, or 11. A large percentage of hybrids with chromosome 1 senesced and/or showed alterations in cellular morphology and transformed growth properties in vitro. No growth or morphology alterations were observed following transfer of the other chromosomes. These results may indicate that more than one chromosome carries a tumor suppressor gene(s) for this human uterine endometrial carcinoma cell line and support the hypothesis that multiple tumor suppressor genes control the tumorigenic phenotype in the multistep process of neoplastic development.