Aberrant redox regulation in human metastatic melanoma cells compared to normal melanocytes.

Melanocytes and melanoma cells contain melanin, a complex polymer that modulates redox changes in these cells. Relative intracellular hydrogen peroxide levels measured by dichlorodihydrofluorescein are similar in the two cell types, but the levels of superoxide anion measured by dihydroethidium were markedly increased in melanoma cells. Chelator-induced oxidative stress is efficiently suppressed by melanocytes without substantial recruitment of the transcription factors NF-kappaB and AP-1 as measured by electrophoretic mobility shift assay and quantitated by densitometry or by a change in frequency of apoptosis as determined by annexin V binding. In contrast, NF-kappaB in melanoma cells is strongly recruited by changes in redox status and exhibits a correlative relationship to intracellular hydrogen peroxide (but not superoxide anion). However, the response of the NF-kappaB pathway to intracellular hydrogen peroxide is anomalous, including downregulation of p65 and IkappaBalpha RNA expression (Northern blot). Additionally, recruitment of AP-1 binding in melanoma cells was directly correlated with intracellular levels of superoxide anion (but not hydrogen peroxide). Neither the degree of NF-kappaB nor AP-1 binding in melanoma cells was related to the frequency of apoptosis. The responsiveness of NF-kappaB and AP-1 recruitment to intracellular levels of hydrogen peroxide and superoxide anion without concomitant control of apoptosis provides a general mechanism by which these cells can escape noxious injury (e.g., chemotherapy). The marked enhancement of apoptosis in melanoma cells by chelators indicates, however, that this alteration can be circumvented and offers a unique therapeutic window to explore.

Correlation of chemopreventive efficacy data from the human epidermal cell assay with in vivo data.

Continuous exposure to low doses of potentially mutagenic and carcinogenic chemicals over the human lifetime makes the identification of agents, which could reduce the ensuing risk of cancer, beneficial. The Human Epidermal Cell (HEC) Assay includes multiple exposures to low, non-toxic doses of propane sultone, which increases cellular growth and inhibits differentiation, and co-exposure to potential chemopreventive agents to determine their ability to inhibit the increased growth or increase differentiation. Original data are presented on the efficacy of twenty potential cancer chemopreventive agents were screened for efficacy in the HEC Assay. Efficacy was determined by the ability of agents, at nontoxic concentrations, to reverse either of the propane sultone-induced biomarkers, enhanced growth and reduced involucrin expression. Based on the number of positive concentrations and the lack of toxicity, 1,2-dithiol-3-thione, oltipraz, and a synthetic retinoid, Ro 16-9100, were the most active. Eleven of seventeen positive agents were active for both endpoints. S-Allylcysteine was only active for the growth inhibition endpoint, and DFMO, Iycopene, perillyl alcohol, ursodiol, and black tea polyphenols were only active for the involucrin endpoint. The three agents that have been shown to be negative in animal models, diphenhydramine, d-mannitol, and nordihydroguaiaretic acid, were correctly identified as negative by the assay. When the data from previous studies (Elmore et al, Anticancer Res, 19: 909-918, 1999) are included, a positive response in one or more endpoints of the HEC Assay correlates 100% (26/26) with a positive response in one or more of the animal cancer prevention models (8). The available data suggest that the HEC Assay response is highly predictive of efficacy in animals in vivo with an overall accuracy of 90%. Future studies will include data with additional negative agents. The correlation of the HEC Assay data with data from in vivo studies in animal models, which utilize multiple carcinogens and multiple target organs, would suggest that this in vitro assay has the ability to identify agents with the potential to prevent carcinogen-induced cancer. While our ultimate goal is to identify agents with potential efficacy for preventing human cancer, sufficient human data are not yet available to make this correlation.

Activation of nuclear factor-kappa B in human metastatic melanomacells and the effect of oxidative stress.

The biological basis for the general pharmacological resistance of human melanoma is unknown. A unique biochemical feature of the melanocyte is the synthesis of melanin, which leads to the generation of hydrogen peroxide and the consumption of reduced glutathione. This activity produces a state of chronic oxidative stress in these cells. We demonstrated previously that the expression of the c-jun family was dysregulated in metastatic melanoma cells compared with normal human melanocytes (D. T. Yamanishi et al., J. Invest. Dermatol., 97: 349-353, 1991). In the current investigation, we measured the levels of two major redox response transcription factors, nuclear factor-kappaB (NF-kappaB) and activator protein-1, in metastatic melanoma cells and normal melanocytes and their response to oxidative stress. The basal DNA-binding activity of NF-kappaB as measured by the electrophoretic mobility shift assay in metastatic melanoma cells was increased 4-fold compared with that of normal melanocytes. This level of binding was paralleled by a 1.5- to 4-fold increase in the expression of p50 (NF-kappaB1), p65 (Rel-A), and IkappaB-alpha as measured by Northern blot analysis. In contrast, the expression of p75 (c-rel) was markedly decreased (60%) in melanoma cells compared with normal melanocytes. Following oxidative stress produced by enzyme-generated H2O2, free H2O2, or incubation with buthionine sulfoximine, NF-kappaB binding activity increased 1.5- to 2.5-fold in melanoma cells (buthionine sulfoximine > H2O2), but only slightly in normal melanocytes. In contrast, activator protein-1 binding activity was unaffected or increased in normal melanocytes in response to oxidative stress, but was either unaffected or decreased in melanoma cells. These results suggest that the redox regulation of melanoma cells at the molecular level is fundamentally different from normal melanocytes and may offer a unique avenue for preventive or therapeutic intervention as well as new insights into the pathogenesis of melanocyte transformation.

In vitro chemopreventive efficacy screening using human keratinocytes and the in vivo data correlation.

Agents with potential cancer preventive activity were screened for efficacy in the Human Epidermal Cell (HEC) Assay. The HEC Assay measures inhibition of propane sultone-induced changes in the growth and/or differentiation in early passage keratinocyte cultures. The assay biomarkers were calcium tolerance, growth inhibition, and involucrin induction. The HEC Assay also provides information on the cytotoxicity of the agents following acute and chronic exposure. Agents were evaluated at non-toxic doses in the HEC Assay. The HEC Assay has been used to screen twenty-eight agents for chemopreventive efficacy. A positive response in one or more endpoints of the HEC Assay correlates 100% (16/16) with a positive response in one or more of the animal cancer prevention models (J. Cell. Biochem., 26S:29-53, 1996). The overall sensitivity for predicting efficacy in animals is 84%. The available data suggest that a positive assay response appears to be highly predictive of efficacy in vivo.

Variable expression of IL-1 beta has minimal effect on the radiation sensitivity of three human glioma cell lines.

Interleukin 1 (IL-1) has been reported to act as a radioprotector in vivo. Data from our laboratory and from other investigators suggest that glioma cell lines can produce bioactive cytokines including IL-1 and also express IL-1 receptors. In view of the putative radioprotective effect of this cytokine, we have examined the in vitro radiosensitivity of three human glioma cell lines with widely varying levels of endogenous IL-1 beta. The data reveal that when irradiated (2 Gy/min) as confluent cultures (conditions optimal for differential IL-1 beta expression), and plated for colony formation after postirradiation holding, cell survival was not correlated with level of IL-1 beta mRNA expression in the two IL-1-expressing cell lines. However, this was not correlated with a further reduction in radiosensitivity. These data indicate that IL-1 beta does not act as an endogenous radioprotector in these cells under these experimental conditions.

Protein kinase C beta expression in melanoma cells and melanocytes: differential expression correlates with biological responses to 12-O-tetradecanoylphorbol 13-acetate.

Normal human melanocytes require 12-O-tetradecanoylphorbol 13-acetate (TPA) for prolonged growth in vitro. In contrast, the growth of human malignant melanoma cells is often inhibited by TPA. In this study, we have confirmed and extended these observations. Since protein kinase C (PKC) is an important mediator of the effects of TPA, we have investigated the nature of this differential growth response by examining PKC expression and activity in primary cultures of human neonatal melanocytes and metastatic melanoma cell strains. PKC, when measured by immunoreactivity or a functional assay, was found to be more abundant in melanoma cells than in melanocytes. When specific isotypes were examined by Northern analysis, PKC-alpha and -epsilon were expressed in both melanocytes and melanoma. PKC-beta was expressed in melanocytes, but was undetectable by Northern analysis in 10 out of 11 melanoma cell strains. Southern analysis revealed that no gross deletions or rearrangements of the PKC-beta gene had occurred. These data suggest that down-regulation of the PKC-beta gene occurs frequently during the process of transformation of melanocytes. Furthermore, differential expression of PKC isotypes may explain the different effects of TPA on melanocyte and melanoma cell growth.

Comparison of calmodulin gene expression in human neonatal melanocytes and metastatic melanoma cell lines.

The qualitative and quantitative expression of three calmodulin genes (CAM I, CAM II and CAM III) was characterized in human neonatal melanocytes and metastatic melanoma cell lines in the absence and presence of serum, other growth modulators, and/or 12-O-tetradecanoyl-phorbol-13-acetate (TPA). Results indicated that the qualitative expression in melanocytes was the same as that of melanomas, that is, CAM I gene expressed two transcripts, 4.4 kb and 2.1 kb, whereas CAM II and CAM III expressed one transcript each, 1.95 kb and 2.37 kb, respectively. Differential quantitative expression was seen particularly with CAM I. The average levels of both CAM I transcripts in melanomas were less than one-half those of melanocytes. Serum and other growth modulators (including Ca++, isobutyl methyl xanthine, bovine pituitary extract, and insulin) enhanced CAM I and CAM II gene expression in melanocytes; in contrast, the net effect of serum in melanomas was to decrease expression of CAM I and CAM III. This effect was most prominent in melanoma C81-46C. TPA markedly inhibited expression of all three CaM genes in melanocytes; however, in melanomas the net effect of TPA was to increase their expression. CAM I in melanoma C81-46C was the most sensitive to TPA stimulation.

Differences in basic fibroblast growth factor RNA and protein levels in human primary melanocytes and metastatic melanoma cells.

Cultivation of human melanocytes requires several growth factors for cell proliferation. For example, basic fibroblast growth factor (bFGF) is an essential growth agent for melanocyte proliferation in vitro and has been proposed to be an autocrine growth factor in human melanoma cells. Studies using either anti-bFGF antibodies or antisense oligonucleotides partially inhibited the proliferation of human melanoma cells. However, one group was unable to detect bFGF RNA transcripts in human melanoma cells using a human complementary DNA probe. These contradictory results prompted us to investigate the bFGF gene expression in human primary melanocytes and metastatic melanoma cells using Southern, Northern, and Western blot analyses. No gross rearrangements in the bFGF gene were detected in the genomic DNA. Although high levels of bFGF RNA transcripts were detected in melanocytes, no bFGF protein was detected using Western blot analysis. In contrast, melanoma cells expressed much lower levels of bFGF RNA transcripts, and cells from three of four cell strains synthesized the multiple isoforms of bFGF protein. In one of the melanoma cell strains, no bFGF protein was detected using Western blot analysis. Although three of four melanoma cell strains expressed bFGF protein, this molecule does not appear to function as an autocrine growth factor, and expression of the bFGF protein was not a consistent alteration in all melanoma cell strains.

Expression of c-jun, jun-B, and c-fos proto-oncogenes in human primary melanocytes and metastatic melanomas.

Analysis of the regulation of c-jun, jun-B, and c-fos RNA transcript expression was performed in human primary melanocytes and metastatic melanoma cell strains. The medium requirements for human melanocyte in vitro growth are phorbol esters, agents that elevate intracellular cAMP levels, hormones, and growth factors. Cellular jun, jun-B, and c-fos gene expression are known to be affected by growth promoting agents. In primary melanocytes, the expression of c-jun, jun-B, and c-fos RNA transcripts was dependent on the growth-promoting agents present in the medium. Uniformly high c-jun, jun-B, and c-fos RNA transcript levels were observed in melanocytes cultivated in complete medium. Higher levels of c-jun RNA transcripts and low levels of c-fos RNA transcripts were observed in melanocytes cultivated in plain medium. In contrast, a range of c-jun, jun-B, and c-fos RNA transcript levels was detected in metastatic melanoma cell strains cultivated in medium with or without serum. In general, an increase in jun-B and c-fos RNA transcript expression and a decrease in c-jun RNA transcript expression was observed in metastatic melanomas compared to neonatal melanocytes. These data suggest a potential role for c-jun, jun-B, and c-fos genes in the transformation of melanocytes to malignant melanoma.

The differential expression of protein kinase C genes in normal human neonatal melanocytes and metastatic melanomas.

Expression of protein kinase C (PKC) genes (alpha, beta, gamma and epsilon) was measured in cultured normal human neonatal melanocytes and metastatic melanoma cell strains. Three of the PKC isotypes (alpha, beta and epsilon) were constitutively expressed in neonatal melanocytes. Protein kinase C beta RNA transcripts were induced in neonatal melanocytes cultivated in medium with serum and 12-O-tetradecanoylphorbol-13-acetate (TPA). In contrast, PKC alpha and epsilon RNA transcripts were detected in melanocytes cultivated in medium without serum and TPA, but were repressed in melanocytes cultivated in medium with serum and TPA. Only PKC alpha and epsilon RNA transcripts were detected in the melanoma cell strains and the PKC RNA transcript expression levels varied among the five metastatic melanomas. In four metastatic melanoma cell strains, PKC alpha and epsilon RNA transcript expression levels were repressed by serum, but in one melanoma cell strain, PKC alpha and epsilon RNA transcript expression levels were induced by serum. Protein kinase C gamma RNA transcripts were not detected in either the melanocytes or melanoma cell strains. These data suggest an alteration of PKC isotype gene expression in the progression of primary melanocytes to metastatic melanoma. The absence of the PKC beta RNA transcripts and altered expression of PKC alpha and epsilon isotypes in particular may be a feature in the transformation of human primary melanocytes.