Suppression of class I human histocompatibility leukocyte antigen by c-myc is locus specific.

The c-myc oncogene downregulates class I HLA expression in human melanoma. The major class I HLA antigens are encoded by three loci, A, B, and C, and we investigated whether these loci are suppressed equally by c-myc. In three melanoma cell lines with high c-myc expression, we analyzed mRNA, protein, and cell surface expression of the class I HLA antigens. Whereas the HLA-B locus expression was found to be strongly reduced, the HLA-A locus was expressed normally. Analysis of c-myc-transfected clones of two melanoma cell lines confirmed that c-myc preferentially suppresses the class I HLA-B locus. Immunohistochemical analysis of fresh melanoma lesions also showed that in the tumors the HLA-A loci are expressed normally, while on the majority of tumor cells no HLA-B antigen expression was found. This downregulation may have consequences for the recognition of malignant cells by tumor-infiltrating lymphocytes. Our results predict that HLA-B-restricted cytotoxic T cells will be unable to kill high c-myc-expressing melanoma cells.

Adenovirus serotype determines association and localization of the large E1B tumor antigen with cellular tumor antigen p53 in transformed cells.

The distribution and stability of the cellular tumor antigen p53 were studied in baby rat kidney cells transformed by region E1 sequences of nononcogenic adenovirus (Ad) type 5 (Ad5) or oncogenic type 12 (Ad12). In transformed cells expressing the large E1B T antigen of Ad5, p53 was associated with this T antigen. The complexed proteins were concentrated in a cytoplasmic body, which has been shown to consist of a cluster of 8-nm filaments (A. Zantema et al., Virology 142:44-58, 1985). In transformed cells expressing the E1B region of Ad12, however, no association between the viral large T antigen and p53 was detectable. In the latter case, both proteins were found almost exclusively in the nucleus. The stability of p53 in both Ad5- and Ad12-transformed cells was increased relative to that in primary cells or cells immortalized by the E1A region only. Thus, the increased stability of p53 in Ad-transformed cells is not caused by association with a viral T antigen, but it correlates with expression of E1B and with morphological transformation.

N-ras mutations in human cutaneous melanoma from sun-exposed body sites.

In 7 of 37 patients with cutaneous melanoma, mutations in the N-ras gene were found. The primary tumors of these seven patients were exclusively localized on body sites continuously exposed to sunlight. Moreover, the ras mutations were all at or near dipyrimidine sites known to be targets of UV damage. Two primary tumors were biclonal with respect to ras mutation. An active role for UV irradiation in induction of the mutations is suggested.

cis-diamminedichloroplatinum(II)-resistant sublines derived from two human ovarian tumor cell lines.

In two human ovarian tumor cell lines, resistance to cis-diamminedichloroplatinum(II) (CDDP) was induced by continuous exposure of the parental lines to an increasing CDDP concentration in the culture medium. In contrast, a six times repeated pulse exposure of 6.7 microM or 16.7 microM CDDP for 1 h did not result in a cell line that showed a higher survival in CDDP-containing medium. The ID50 value for CDDP was seven to eight times higher for the resistant lines and those lines were able to grow at 3.3 microM CDDP. The induced resistance was stable during at least 25 doubling times. The CDDP-resistant sublines showed cross-resistance to the CDDP-analogues cis-diammine-1,1-cyclobutane-dicarboxylateplatinum(II) and cis-dichlorobis(isopropylamine)-trans-dihydroxyplatinum(IV) indicating that resistance to the different platinum compounds is generated by a common mechanism. The resistant sublines were also cross-resistant to mitomycin C and melphalan. The degree of cross-resistance for the tested drugs varied widely between the two cell lines. Resistance to CDDP was clearly correlated to decreased amounts of platinum in the resistant cells as compared to the sensitive cells. The amplification and expression of genes encoding proteins that had been shown to be involved in multidrug resistance, e.g., the Mr 170,000 P-glycoprotein was also studied. No amplification or overexpression of these genes could be shown in the resistant cell lines.

Activated N-ras contributes to the chemoresistance of human melanoma in severe combined immunodeficiency (SCID) mice by blocking apoptosis.

Activation of the N-ras gene by point mutations occurs in about 15 % of all human melanomas. Using recently established melanoma severe combined immunodeficiency-human mouse xenotransplantation models, here we further investigate the biological significance of these mutations. We demonstrate that activated N-ras significantly contributes to the chemoresistance of human melanoma both in vitro and in vivo by blocking apoptosis. Overexpression of wild-type N-ras had no such effects. With antisense oligonucleotides and farnesyltransferase inhibitors, tools capable of blocking Ras function on the therapeutic horizon, our observation that activated N-ras is not a bystander but a factor worth targeting to improve therapeutic outcome in melanoma gains additional importance.

Correlation between cell killing by cis-diamminedichloroplatinum(II) in six mammalian cell lines and binding of a cis-diamminedichloroplatinum(II)-DNA antiserum.

The relationship between cell killing and the binding of the anticancer drug cis-diamminedichloroplatinum(II) (cis-DDP) to DNA was studied in six mammalian cell lines. Two of the human cell lines (COV413B) were of the same origin, comprising one sensitive to cis-DDP and the other with induced resistance to the drug. The four other lines, two rodent (RIF-1, Chinese hamster ovary) and two human (A2780, A1847), were unrelated. The cell lines differed in their sensitivity to cis-DDP, as tested in a clonogenic assay. cis-DDP-DNA binding was determined by quantitative immunocytochemistry using an antiserum against cis-DDP-modified DNA. The resistance factors relative to RIF-1, calculated from full survival curves for cis-DDP, were 3.8 +/- 0.4 for Chinese hamster ovary cells and 8.8 +/- 0.7 for both A2780 and A1847 lines. Using quantitative immunocytochemistry, the levels of the adduct-specific nuclear staining density compared with RIF-1 cells were 4.8 +/- 0.2 for Chinese hamster ovary cells, 9.1 +/- 0.2 for A2780, and 10.0 +/- 0.1 for A1847 cells, i.e., in good agreement with the resistance factors. In studies with the COV413B cells and their cis-DDP-resistant counterpart COV413B-PtR, immunologically detected adduct levels again correlated closely with resistance factors (correlation coefficient = 0.97). The kinetics of cis-DDP-DNA adduct formation and loss was investigated in RIF-1, A2780, and A1847 cells by the immunocytochemistry technique. Adduct levels after a 1-h incubation with approximately equitoxic doses of cis-DDP increased by 18 to 32% (average, 27%) between 0 and 6.5 h after treatment and then declined. Adduct half-lives in this latter phase did not correlate with the sensitivities of the cells for cis-DDP. These results indicate that the initial level of cis-DDP-DNA binding measured by quantitative immunocytochemistry may be a reasonable predictor of sensitivity to this chemotherapeutic drug.

ras oncogene activation in human ovarian carcinoma.

Samples of 37 fresh human ovarian tumor biopsies were screened to detect proto-oncogene amplification and ras mutations. Three samples showed c-K-ras2 amplification; none of the other oncogenes tested revealed any gene amplification. 5-, 25-, and 120-fold amplifications were assessed by dilution experiments and soft laser densitometry. Corresponding elevated levels of c-K-ras2 mRNA and p21 ras protein were found in the three tumors. Analysis by the polymerase chain reaction method to detect point mutations of codon 12 or codon 61 of Harvey-, Kirsten-, or N-ras showed only the wildtype sequence in all specimens. No correlation was found between ras activation and degree of tumor progression or histological subtype. DNA from one of the tumors with c-K-ras2 amplification proved to have high transforming activity in the NIH 3T3 tumorigenicity assay, but the transforming gene was not c-K-ras2.

Activation of the mas oncogene involves coupling to human alphoid sequences.

We have shown previously that mouse NIH3T3 cells transfected with DNA from a human ovarian carcinoma were rendered tumourigenic by an activated mas oncogene in four independent transfection experiments. In all cases the 5'-noncoding region was rearranged in comparison to the original ovarian tumour DNA. We now report that in all four transfectants the newly acquired sequences consist of human centromeric alpha satellite repeat DNA. In at least three transfectants the alphoid DNA originates from the centromere of chromosome three. Analysis of the sequences of the recombination site in one transfectant revealed that a homologous sequence of five base pairs (CAGCA) is present in both parental strands, and might thus have contributed to the recombinational event. To establish a conclusive role for alphoid DNA in the activation of mas, we performed a co-transfection experiment in NIH3T3 cells with cloned alphoid DNA and the mas coding sequence. We show that the transfectants expressing a transformed phenotype contain amplified mas linked to alphoid DNA. NIH3T3 cells transfected with plasmids that contained alphoid sequences cloned directly upstream of the mas coding sequence, and injected into nude mice, gave rise to tumours with amplified mas sequences (7/7). In six of these tumours the alphoid sequences were amplified as well. Our data suggest a novel mechanism of oncogene activation: recombination with normal alphoid repeat DNA resulting in amplification of the oncogene.

Ribosomal proteins L7/L12 of Escherichia coli. Localization and possible molecular mechanism in translation.

Experiments were performed in order to determine the minimal requirement for the proteins L7/L12 in polyphenylalanine synthesis and elongation factor EF-G-dependent GTP hydrolysis. Via reconstitution, ribosomal particles were prepared containing variable amounts of L7/L12. The L7/L12 content of these particles was carefully determined by the use of 3H-labelled L7/L12 and by radioimmunoassay. The activity of the particles was determined as a function of the L7/L12 content. Our results show that only one dimer of L7/L12 is required for full activity in EF-G-dependent GTP hydrolysis. On the other hand, two L7/L12 dimers are required for polyphenylalanine synthesis. In addition, we have determined the relation between the number of L7/L12 stalks, as observed by electron microscopy, and the L7/L12 content of the 50 S particles. Our interpretation of these results is that each ribosomal particle possesses two L7/L12 binding sites, each site being involved in binding one dimer. Binding of L7/L12 dimer in one site gives rise to formation of the L7/L12 stalk, whereas binding in the other site has no effect on the number of visible stalks.

Repression of the minimal HLA-B promoter by c-myc and p53 occurs through independent mechanisms.

Major Histocompatibility Complex (MHC, HLA in humans) class I antigens play an important role in cellular immunology by presenting antigens to T cells. Downregulation of MHC class I expression is thought to be a mechanism by which tumor cells escape from T cell-mediated lysis. In primary human melanomas and melanoma cell lines, HLA-B expression is frequently downmodulated, correlating with elevated expression of the c-myc oncogene. Transfection experiments have shown that c-myc induces HLA-B downregulation through a -68 to +13 base pairs (bp) core promoter fragment, containing CCAAT and TATA-like (TCTA) boxes. Since (i) c-myc has been reported to activate the human p53 promoter and (ii) p53 is capable of repressing a large array of basal promoters, we investigated whether c-myc-induced HLA-B abrogation is mediated by p53. In this article, it is shown that the HLA-B core promoter is indeed repressed by wild-type p53, making p53 a candidate for mediating c-myc-induced HLA-B downregulation. However, transfection of c-myc into p53-null cell lines still resulted in suppression of the basal HLA-B promoter, demonstrating that c-myc and p53 repress the minimal HLA-B promoter through independent mechanisms.

Immunization with interleukin-2 transfected melanoma cells. A phase I-II study in patients with metastatic melanoma.

The safety, tolerance and clinical effects of immunization with irradiated, allogeneic melanoma cells that express high levels of HLA-A1 and -A2 and secrete IL-2 after transfection with the Interleukin-2 gene, will be assessed in HLA-A1 or HLA-A2 positive melanoma patients with metastatic disease. As a pilot, the first 5-10 patients, if no immediate regression of tumor lesions are observed, will in addition to immunization with these allogeneic tumor cells receive recombinant IL-2 in relatively low doses during three consecutive weeks on an outpatient basis. If no clinical remissions are induced in these first 5-10 patients, subsequent 5-10 patients will receive the same dose of melanoma cells without additional rIL-2. Thereafter the dose of injected melanoma cells will be increased in every following 5-10 patients, but all subsequent patients will receive only IL-2 producing, allogeneic tumor cells, without the addition of rIL-2.

Vaccination of melanoma patients with an allogeneic, genetically modified interleukin 2-producing melanoma cell line.

Thirty-three metastatic melanoma patients were vaccinated according to a phase I-II study with an allogeneic melanoma cell line that was genetically modified by transfection with a plasmid containing the gene encoding human interleukin 2 (IL-2). The cell line expresses the major melanoma-associated antigens and the HLA class I alleles HLA-A1, -A2, -B8, and Cw7. All patients shared one or more HLA class I alleles with this cell line vaccine. Patients were immunized by three vaccinations, each consisting of 60 x 106 irradiated (100 Gy) melanoma cells (secreting 120 ng of IL-2/10(6) cells/24 hr) administered subcutaneously at weekly intervals for 3 consecutive weeks. Side effects of treatment consisted of swelling of locoregional lymph nodes and induration at the site of injection, i.e., a delayed-type hypersensitivity (DTH) reaction. In three patients, vaccination induced inflammatory responses in distant metastases containing necrosis or apoptosis along with T cell infiltration. Apoptosis occurred only in Bcl-2-negative areas, not in Bcl-2-expressing parts of the metastases. Two other patients experienced complete or partial regression of subcutaneous metastases. Seven patients had protracted stabilization (4 to >46 months) of soft tissue metastases, including one patient who developed vitiligo after vaccination. Immune responses to the vaccine could be detected in 67% of the 27 patients measured. Vaccination was shown to induce a variable change in the number of anti-vaccine cytotoxic T lymphocytes (CTLs) in peripheral blood, which did not correlate with response to treatment. However, in two of five patients the frequency of anti-autologous tumor CTLs measured was significantly higher than before vaccination. This study demonstrates the feasibility, safety, and therapeutic potential of vaccination of humans with allogeneic, gene-modified tumor cells, and that frequencies of vaccine-specific CTLs among patient lymphocytes can be determined by using a modified limited dilution analysis (LDA).

ras oncogene activation does not induce sensitivity to natural killer cell-mediated lysis in human melanoma.

An important phenomenon in tumor immunology that has come under recent attention is the impact of oncogene activation in tumor cells on the sensitivity to lysis by immune effector cells. Several studies suggested that transfer of an activated ras oncogene into cultured rodent fibroblasts induces susceptibility to natural killer cell (NK)-mediated lysis. Experiments using human tumor cells, however, have produced conflicting data on the effect of ras activation in this respect. In studying the activation of the oncogene c-myc, which is often overexpressed in human melanoma, we have found that in cell lines expressing high levels of Myc protein, the sensitivity to lysis by NK cells was dramatically increased due to reduced expression of Human Leukocyte Antigen B locus products. Since the N-ras oncogene was found to be activated in 15% of human melanomas, we examined the possibility that in melanoma, in analogy to the murine systems, the mutated ras oncogene may influence NK susceptibility of human melanoma cells. Two N-ras genes harboring frequently found mutations were cloned into an expression vector. Transfection of the IGR39D melanoma cell line with wildtype and mutant N-ras constructs yielded several ras-expressing clones that were tested for NK sensitivity. Neither high expression of the wildtype N-ras protein, nor expression of two mutant proteins (N61-arg, N61-lys) was shown to result in enhanced NK-mediated lysis. We conclude that activation of ras oncogenes does not lead to the induction of an NK-sensitive phenotype in human melanoma cells.

Influence of increased c-Myc expression on the growth characteristics of human melanoma.

Overexpression of the proto-oncogene c-myc has been associated with neoplastic transformation in a variety of tumors. For human melanoma high c-myc expression has been found in the vertical growth phase and higher positivity reported in metastases than primary tumors. The principle aim of this study was to determine, whether c-Myc expression influences the metastatic behavior of human melanoma in the absence of lymphocyte-mediated immune phenomena. The growth characteristics and tumor biology of two c-myc transfectants of the human melanoma cell line IGR39D, expressing c-Myc 1.7 and three times over baseline and the respective vector control were analyzed both in vitro and in a severe combined immunodeficient mouse model in vivo. Both c-myc transfectants showed increased growth rates, anchorage independent growth and directed cell movement in culture. Subcutaneously implanted IGR39D melanomas highly overexpressing c-Myc spontaneously formed macroscopic metastases (lymph nodes and lung) in severe combined immunodeficient mice in all cases (n = 7 per group), whereas less prominent c-Myc overexpression caused the development of only lung micrometastases. During the time period leading to terminal disease in animals injected with c-myc transfected human melanoma cells, melanoma development was not seen in vector controls. These findings suggest that constitutive high c-Myc expression in human melanoma results in a more aggressive growth behavior both in vitro and in vivo and favors metastasis in severe combined immunodeficient mice by factors unrelated to immune phenomena such as class I human leukocyte antigen downregulation known to be associated with c-Myc expression.

Cell density dependent plating efficiency affects outcome and interpretation of colony forming assays.

BACKGROUND AND PURPOSE: The usefulness of colony forming assays (CFA) has been established for almost 40 years (Puck and Marcus, J.Exp.Med. 103: 653-666, 1956). Although time-consuming and not successful for all cell lines, it is generally considered to be the gold standard of assays for testing the sensitivity of cell lines to ionizing radiation or other cytotoxic agents in vitro. We recently found for several cell lines that the plating efficiencies of both control and irradiated cells is dependent upon the density of cells seeded for colony formation; that is, increasing cell inoculum levels resulted in a non-linear relationship with colony formation, even at relatively low colony numbers. MATERIAL AND METHODS: All data from a human melanoma cell line, transfected with c-myc or N-ras, as well as from normal human diploid fibroblasts, were taken to see how this phenomenon influenced outcome and interpretation of clonogenic assays. Survival was recalculated using all data, or only data with a linear relationship between inoculum level and colony formation. RESULTS: It is found that when data with a non-linear relationship between inoculum level and colony formation are included, survival can be underestimated due to inhibition of colony formation in treated cultures. CONCLUSION: For validity, colony forming assays must be standardized to assure a constant relationship between the cell density and colony forming efficiency. This usually requires a much lower density of colonies than has been typically published for many cell survival studies.

C-myc represses transiently transfected HLA class I promoter sequences not locus-specifically.

Overexpression of the c-myc oncogene is frequently accompanied by downregulation of Major Histocompatibility Complex (MHC, HLA in humans) class I antigens. In human melanoma c-myc overexpression downmodulates HLA-B expression, whereas HLA-A is hardly affected. Repression of HLA-B is mediated through the core promoter, containing a CAAT-box and a non-conventional TATA-box. We show evidence that in transient transfection assays the HLA-A2 and HLA-B7 promoters are repressed by c-myc to the same extent. Therefore, other sequences of the HLA-A and HLA-B genes, possibly intron/exon sequences, should contribute to the locus B-specificity of the downregulation. Furthermore, c-myc does not seem to alter binding of protein complexes to the CAAT- or TATA-box of HLA-B7 or HLA-A2 in gel retardation assays. Comparison of promoters repressed by c-myc reveals a weak consensus sequence of the initiator (Inr) element: TCA(+1)YYYNY. The presence of a TCA sequence in the initiator region of the MHC class I promoter makes downregulation by c-myc through the Inr likely. We speculate that the Inr contributes to MHC class I promoter activity by stimulating recruitment of TFIID to the weak, non-conventional TATA-box, thereby making it susceptible to repression by c-myc through the Inr.

The influence of the oncogenes NRAS and MYC on the radiation sensitivity of cells of a human melanoma cell line.

Activation of certain oncogenes may alter the sensitivity of cells to ionizing radiation. We studied the effect of oncogene activation on the radiation sensitivity of cells of a human melanoma cell line. The cell line IGR39D was transfected with the MYC oncogene, the proto-oncogene NRAS, NRAS activated by a point mutation (61-arginine) or a combination of mutated NRAS and MYC. Single-dose experiments showed a decreased survival after transfection with MYC, wild-type NRAS or mutated NRAS. Co-transfection with MYC and mutated NRAS decreased survival up to 4 Gy, whereas at higher doses no shift in radiosensitivity was seen. Flow cytometry data indicated that differences in radiosensitivity could be explained at least in part by a difference in the distribution of cells in the phases of the cell cycle. After transfection of cells with either NRAS or MYC, the number of cells in G1 phase decreased with a concomitant increase of cells in the G2/M phase. When the cell line transfected with activated NRAS was manipulated so that the distribution of the cells in the phases of the cell cycle resembled th at of the parental line at the time of irradiation, the survival of the cells was improved. Similar experiments with the cell line containing MYC did not result in an alteration of the distribution of the cells in the cycle, or the survival after single-dose fractions, suggesting the presence of a distinct mechanism for influencing radiation sensitivity. Both NRAS and MYC transfection decrease the radiation sensitivity of human melanoma cells, but the underlying mechanisms seem different. In conclusion, transfection with NRAS or MYC alone increases radiation sensitivity while transfection of cells containing NRAS with MYC restores resistance at higher doses.

Human ovarian tumors of epithelial origin express PDGF in vitro and in vivo.

In human malignant mesothelioma cell lines an elevation of the expression of the genes for the PDGF A-chain, PDGF B-chain, and PDGF beta-receptor was found compared to normal mesothelial cells. As ovarian epithelial tumors originate from the ovarian surface epithelium, which is of mesothelial origin, we investigated PDGF chain and PDGF receptor mRNA expression in six human ovarian cell lines of epithelial origin and a granulosa tumor cell line. All six investigated ovarian epithelial tumor cell lines expressed the PDGF A- and B-chain genes, while the granulosa tumor cell line expressed the PDGF A-chain gene only. Expression of PDGF receptors was not found in the epithelial or granulosa tumor cell lines. Cytogenetic and molecular biological studies did not provide evidence for rearrangement or genomic amplification of the PDGF B-chain. Expression of PDGF was also demonstrated in ovarian tumors in vivo. Frozen sections of six serous ovarian carcinomas stained positive with an antibody against PDGF and negative with antibodies against the PDGF alpha- and beta-receptors. These results suggest that PDGF expression might be a useful marker for ovarian carcinomas.

The influence of the oncogene N-ras on cell cycle delay in a human melanoma cell line with reduced radioresistance.

In a previous study we found that transfection of a human melanoma cell line with the oncogene N-ras led to increased radiosensitivity as measured by clonogenic assays. Since a shift in radiosensitivity is often correlated with altered G2/M delay, we investigated whether this was also the case in this oncogene containing melanoma cell line (IGRras). A human melanoma cell line, stably transfected with mutated N-ras, and its parental cell line transfected with the neomycin phosphotransferase gene only (IGRneo), were irradiated with 5 Gy and cell cycle distribution was measured at hourly time intervals by DNA staining with propidium iodide. Next, the effect of ionising radiation on the duration of the S-phase was determined by pulse labelling cells with BrdUrd before irradiation. Both cell lines showed a radiation induced G2/M delay, which was most prolonged for the ras transfected cell line. After 5 Gy, the S-phase duration was unaltered, although the shape of the relative movement (RM) curves was slightly different. No G1 delay was observed in either cell line. Ras transfection in a melanoma cell line leads to prolonged G2/M delay after radiotherapy. This prolongation is associated with increased radiosensitivity and not with radioresistance. These data throw doubt on the use of oncogene expression or G2/M delay as predictors of radiosensitivity.

UV-induced N-ras mutations are T-cell targets in human melanoma.

Human cutaneous melanoma is heterogeneous with respect to the genetic aberrations involved and the genes altered are potential targets for the immune system. The incidence of cutaneous melanoma is known to be linked to UV peak exposure, and the N-ras oncogene is clearly one of the genes involved in the UV carcinogenesis in melanoma. It is mutated in a significant proportion of melanomas and therefore may serve as a target for T cells. Here, we report that an human leukocyte antigen-A2 binding peptide CLLDILDTAGL, encompassing the frequently found 61-Leu mutation in N-ras, induces cytotoxic T lymphocytes from healthy donor blood that lyse 61-Leu N-ras transfected melanoma cells. Furthermore, we have found an association between the presence of N-ras mutations and clinical response to immunotherapy with interleukin-2 plus interferon in a group of stage IV melanoma patients. Although the overall survival of these patients was not affected by the N-ras status of their melanomas, these studies suggest that mutated N-ras may provide a target for cytotoxic T lymphocytes in melanoma patients.