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.     

Elevated expression of an exogenous c-myc gene is insufficient for transformation and tumorigenic conversion of established fibroblasts

Two established rat fibroblast lines, differing only by their number of generations in culture, show dramatically different responses to the elevated c-myc expression delivered by an efficient murine c-myc retrovirus vector. Thus, a late passage (60 generation) FR3T3 line acquires a transformed and tumorigenic phenotype upon introduction of this activated c-myc gene as indicated by its altered morphology, high efficiency of focus formation, soft agar clonability, saturation density in monolayer culture, and short latency of tumorigenicity in syngeneic hosts. Remarkably, none of these characteristics, except for an increased refractility in monolayers and an epidermal growth factor (EGF)-dependent agar clonability, were observed in a variety of early passage (10 generation) FR3T3 c-myc clones. BALB/c A31 fibroblasts transfected with this c-myc retroviral vector behaved essentially the same as the FR3T3 early line except for their inability to grow in suspension in response to EGF. However, transformation and tumorigenic conversion of each of these three fibroblast lines was achieved by an activated ras oncogene. Hence, elevated c-myc expression is insufficient for transformation of established fibroblasts but depends upon other acquired cooperating functions which are not necessary for ras induced transformation. We also demonstrate that endogenous c-myc expression remains unaffected even in clones expressing a 100-fold excess of exogenous c-myc RNAs demonstrating that c-myc autoregulation is not operative in these cells.     

Introduction of the activated N-ras oncogene into human fibroblasts by retroviral vector induces morphological transformation and tumorigenicity

The introduction of activated N-ras cDNA into normal diploid human skin fibroblast cell cultures using the retroviral vector pZIPneo results in a spectrum of morphologies ranging from near normal to, in rare instances, dense piled-up colonies of morphologically transformed cells. However, none of the clones isolated were transformed as assessed by growth on agar or tumorigenicity in nude mice. Introduction of both c-myc and N-ras oncogene cDNAs into normal skin fibroblasts failed to produce transformation as assessed by growth on agar and tumorigenicity in nude mice, although c-myc infection alone conferred immortality and the resultant doubly infected cell line was immortal. Using the same construct, activated N-ras cDNA was shown to transform immortalized human fibroblasts to tumorigenicity. However, immortalization per se was shown not to guarantee 'co-operation' with an activated N-ras gene to give malignant transformation. Although numerical and structural chromosome aberrations (clonal and non-clonal) were observed in some of the cell strains isolated after retroviral infection, these were not directly associated with viral infection, the presence of the oncogenes or with the morphologically transformed phenotype.     

Hormone receptors and cathepsin D levels in human breast epithelial cells transformed by chemical carcinogens and c-Ha-ras transfection

Summary The objective of this work was to determine whether transformation of the human breast epithelial cell line MCF-10F by the chemical carcinogens 7, 12-dimethylbenz(a)anthracene (DMBA) or benzo(a)pyrene (BP), or c-Ha-ras oncogene transfection, influence the expression of epidermal growth factor receptor (EGFR), estrogen (ER) or progesterone (PR) receptors, and the content of cathepsin-D (Cath.D). MCF-10F control cells did not express any of the phenotypes of neoplastic transformation, whereas carcinogen-treated cells and clones derived from the latter formed colonies in agar-methocel, and exhibited increased chemotaxis and chemoinvasion. Clone BP-1E was also tumorigenic in SCID mice. The BP1 cell line transfected with mutated c-Ha-ras oncogene, named BP1-Tras, became more aggressive after transfection and decreased the latency time to tumorigenesis. Radioligand binding and immunocytochemical reactions were utilized for determining the receptors and Cath.D content of control and carcinogen-treated cells and their derived clones. MCF-10F cells contained 37 fmol/mg of protein of EGFR, ER and PR were undetectable, and Cath.D content was 70 fmol/mg protein. EGFR content was significantly higher in D3-1 and BP1-E cell lines vs the control MCF-10F and the other DMBA and BP clones, correlating positively with the emergence of the transformation phenotype. Whereas EGFR levels were not significantly different in BP1-Tras cells when compared with BP1-E, the former were more tumorigenic in SCID mice, an observation suggesting an alternative pathway in these cells in the formation of tumors. PR, ER, and Cath.D content was not modified by either carcinogen treatment or ras transfection in most of the clones and subclones, except clone BP2 that has a significant increase in ER content, and was not associated with any of the neoplastic phenotypes. These data allowed us to conclude that the level of EGFR is associated with the expression of carcinogen-induced transformation phenotypes whereas ER, PR, and Cath.D did not seem to be modified during the process of chemically induced or c-Ha-ras enhanced transformation of MCF-10F cells.     

Induction of the neoplastic phenotype of EBV-established B lymphocytes by the human Ha-ras oncogene

We report on the use of human B lymphocytes immortalized by the Epstein-Barr virus (EBV) as targets for transformation by the c-Ha-ras oncogene of bladder carcinoma cells T24. Several stably transformed cell lines were obtained and their in vivo and in vitro growth properties as well as levels of expression of the ras gene were studied. The transformed phenotype in these cells was correlated to ras oncoprotein expression level; only the cell lines which overproduce p21 ras, by at least six-fold, were tumorigenic in nude mice. In this regard, our ras transformed cells behave as lymphoblastoid cells transformed by the c-myc oncogene, suggesting that c-myc and c-Ha-ras might act on the same regulatory level.     

Overexpression of ha-ras oncogene transforms rodent fibroblasts with low-frequency but not human-diploid fibroblasts

Activated Ha-ras oncogenes were introduced into early passage normal human adult dermal fibroblasts, 149BR and established mouse Swiss 3T3 fibroblasts by retroviral-mediated gene transfer or by DNA transfection, respectively. The presence and expression of Ha-ras oncogenes was followed by Southern and Northern blotting and immunoprecipitation. Overexpression of the human mutant c-Ha-ras1 T24 oncogene in mouse cells induced morphological transformation, focus formation and growth in soft agar with low frequency. Tumourigenicity studies showed that the malignant transformation of these cells by p21Ha-ras T24 oncoprotein was concentration-dependent and it required additional events suggesting that in vitro establishment is not a sufficient prerequisite for tumourigenic conversion by activated Ha-ras oncogenes. In contrast, constitutive expression of the viral Ha-ras oncogene in human diploid fibroblasts failed to immortalise or transform them. All ras-expressing human cells remained flat, anchorage-dependent and non-tumourigenic suggesting that these cells are resistant to transformation by activated oncogenes. The role of Ha-ras oncogenes in the transformation of mammalian cells in discussed.     

In vitro reversion of transformed phenotype in mouse C3H/10T1/2 cells

Spontaneous tumor regression is still one of the most puzzling events in human cancer. A cell culture model of malignant transformation designed to permit the study of this phenomenon in vitro was applied to examine reversion and re-expression of the transformed phenotype in two X-ray transformed mouse 10T1/2 cell clones. By alternating cell passages at low and high seeding density, the expression of cell contact inhibition and tumorigenic capacity were both reverted and restored. Growth of non-transformed wild-type cells was not affected by seeding density. This reversion of the transformed phenotype was associated with a modification in genomic 5-methylcytosine content. Initially, the transformed clones were hypomethylated, as occurs in most human tumors. After only four passages at low seeding density, the phenotype was reverted to that of non-transformed 10T1/2 cells and genomic 5-methylcytosine content was significantly increased to levels measured in non-transformed C3H/10T1/2 mouse cells. Thus, hypomethylation induced by ionizing radiation was not a permanent feature of malignantly transformed 10T1/2 cells. Although genomic 5-methylcytosine content returned to normal levels during low density passaging, the methylation pattern of the c-myc gene specifically was not associated with cell passages either at low or high seeding density. In an attempt to identify genes involved in this process, expression of the tumor suppressor gene p53 was measured. Western blot analysis failed to detect any correlation between expression of p53 protein and reversion of the transformed phenotype. The results of this study indicate that the transformed phenotype is not permanently associated with the malignant transformation of C3H/1OT1/2 cells, and can be modulated by growth conditions in vitro. We propose that modulation of genomic 5-methylcytosine levels may be involved in this process.     

Increased sensitivity of nontumorigenic fibroblasts expressing ras or myc oncogenes to malignant transformation induced by 5-aza-2'-deoxycytidine.

The hypomethylating chemotherapeutic drug 5-aza-2'-deoxycytidine (5AzadC) has been shown to induce cell differentiation in some systems, while promoting neoplastic transformation in others. Using both in vitro and in vivo models, we have explored the relationship between oncogene expression and the susceptibility of cells to malignant transformation by 5AzadC. The study involved several nontumorigenic subclones of NIH3T3 fibroblasts, including cells transfected with deregulated c-myc, as well as phenotypic revertants expressing v-Ki-ras or long terminal repeat-activated c-Ha-ras. Transient 5AzadC treatment of the oncogene-bearing cell lines was associated with a rapid and efficient neoplastic transformation. In some cases, over 50% of the cell population exhibited loss of contact inhibition of growth within 1 week of treatment. The transformants were capable of forming s.c. tumors and experimental lung metastases in recipient nude mice. In contrast, 5AzadC failed to induce malignant properties in control 3T3 cultures transfected with the bacterial neor gene; rather, treatment of these cells was associated with differentiation into adipocytes and myotubes. The differential response to 5AzadC was also observed in vivo, in mice first inoculated s.c. with the premalignant cells and then treated with 5AzadC 24 h later. In agreement with the in vitro model, tumor development in mice correlated with the presence of cells with activated ras or myc oncogenes. Cytidine analogs that do not inhibit DNA methylation (i.e., 6-azacytidine and 1-beta-D-arabinofuranosyl cytosine) had no effect on cell phenotype. The results indicate that exposure of cells to 5AzadC can lead to tumor progression both in vitro and in vivo and suggest that preexisting alterations in oncogene expression may facilitate the evolution of cancerous growth induced by hypomethylating agents.     

Transformation by inorganic arsenic compounds of normal Syrian hamster embryo cells into a neoplastic state in which they become anchorage-independent and cause tumors in newborn hamsters

Arsenic is a known human carcinogen, but little evidence exists for its carcinogenicity in animals. In order to investigate the ability of inorganic arsenics to transform normal cells into a neoplastic state, mass cultures of normal, diploid Syrian hamster embryo (SHE) cells exposed to various concentrations of sodium arsenite or sodium arsenate for 48 hr were continually passaged and tested for neoplastic transformation, as determined by anchorage-independent growth in semisolid agar and tumorigenicity in newborn hamsters. Twenty-one of 22 (96%) untreated, control cultures senesced by 20 passages. While 1 culture escaped senescence, it did not acquire the ability to either grow in semisolid agar or form tumors in animals. Ten of 14 (71%) cultures exposed to sodium arsenite or sodium arsenate escaped senescence. Nine of the 10 (90%) arsenic-treated immortal cultures acquired the anchorage-independent phenotype. Five of 5 anchorage-independent cultures examined were tumorigenic. Two of 3 morphologically transformed colonies induced by sodium arsenate also acquired the ability to grow in semisolid agar when isolated. Amplification of the c-myc or c-Ha-ras oncogene was detected in 3 of 5 and 4 of 5 tumorigenic cell lines, respectively. Both c-myc and c-Ha-ras were amplified even in a preneoplastic, anchorage-dependent cell line, but neither was amplified in 6 of 9 anchorage-independent cell lines. Overexpression of c-myc and c-Ha-ras mRNA was observed in most of the neoplastically transformed cell lines but not in the preneoplastic cell line. Experiments using the methylation-sensitive restriction endonuclease isoschizomers HpaII and MspI revealed hypomethylation of c-myc and c-Ha-ras in the 5'-CCGG sequence of arsenic-exposed cell lines but not in the parental SHE cells or a spontaneously transformed cell line. Thus, inorganic arsenics induce neoplastic transformation of normal, diploid mammalian cells. Overexpression of oncogenes by DNA hypomethylation may participate in the arsenic-induced neoplastic transformation of mammalian cells.     

A 3' truncation of myc caused by chromosomal translocation in a human T-cell leukemia is tumorigenic when tested in established rat fibroblasts.

We have previously identified in human T-leukemia cells a myc gene with an unusual 3' rearrangement, and we have shown that expression of the gene is deregulated by stabilization of mRNA. Here we report that the rearranged gene transforms established rat fibroblasts to a tumorigenic phenotype. In hybrid genes, the transforming capability segregates with the 3' rearrangement. Transformation is apparently due to a more than fivefold enhancement in myc expression, attributable to stabilization of mRNA. The rearranged allele of myc also contains a point mutation in a region upstream of the gene, identified previously as a potential negative regulator of myc expression. The mutation may increase expression of myc, but not sufficiently to cause cellular transformation. Our findings enlarge the variety of genetic lesions that may activate myc to an oncogene and sustain the view that augmented expression of an otherwise normal allele of myc can be pathogenic.     

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.     

Antipain-induced suppression of oncogene expression in H-ras-transformed NIH3T3 cells

Antipain (AP; 50 micrograms/ml) inhibits transformation of NIH3T3 cells after transfection with an activated H-ras oncogene. To determine whether AP effects on transformation are associated with alterations in oncogene expression, NIH3T3 cells were cotransfected with an activated H-ras oncogene and the selectable marker gene aph, and gene expression was quantified. Fifty percent of geneticin-resistant colonies which were exposed to AP failed to express the transformed phenotype as determined by their inability to grow in soft agar. Northern blot analysis of the transformed and nontransformed colonies revealed that suppression of H-ras transformation by AP was associated with a decrease in expression of the exogenously transfected H-ras gene by approximately 4-fold. Expression of the endogenous oncogene c-myc was decreased by approximately 2.5-fold, to levels seen in untransfected cells. AP-treated colonies that retained the transformed phenotype had levels of oncogene expression that were similar to untreated ras-transformed colonies. Southern blot analysis revealed no effects of AP on incorporation or copy number of the H-ras gene.     

Thermal response of oncogene-transfected rat cells

Rat embryo cells or Rat-1 fibroblasts were transfected with either an activated c-myc or a c-Ha-ras from the T24/EJ bladder carcinoma, or they were cotransfected with both. A gene conferring neomycin or hygromycin resistance was also cotransfected so that independent cell lines could be selected by growth in medium containing the antibiotic. Certain isolates from cells transfected with only one type of oncogene were further transformed by exposure to 600 cGy of 250-kVp X-rays. Successful transfection and transformation were characterized by altered morphology, increased plating efficiency, shorter doubling time, longer life span, foci formation, anchorage-independent growth, and Southern and Northern hybridization analysis. The thermal response of these cells at different stages of oncogenic transformation was examined by exposing exponentially growing cells to 45 degrees C for 0 to 45 min and measuring cellular survivals using colony formation assay. We found that cells transfected with myc oncogene, singly or in combination with ras, were more sensitive to thermal stress. Aside from that, the cells' thermal sensitivity was not affected by the degree or the nature of transformation.