Epigenetic reprogramming as a key contributor to melanocyte malignant transformation

Melanoma progression requires deregulation of gene expression by currently uncharacterized epigenetic mechanisms. A mouse model based on changes in cell microenvironment was developed by our group to study melanocyte malignant transformation. Melanoma cell lines (4C11- and 4C11+) were obtained as result of 5 sequential anchorage blockades of non-tumorigenic melan-a melanocytes. Melan-a cells submitted to 4 de-adhesion cycles were also established (4C), are non-tumorigenic and represent an intermediary phase of tumor progression. The aim of this work was to identify factors contributing to epigenetic modifications in early and later phases of malignant transformation induced by anchorage impediment. Epigenetic alterations occur early in tumorigenesis; 4C cell line shows changes in global and gene-specific DNA methylation and histone marks. Many histone modifications differ between melan-a, 4C, 4C11- (non-metastatic melanoma cell line) and 4C11+ (metastatic melanoma cell line) which could be associated with changes in gene and microRNA expression. These epigenetic alterations seem to play a key role in malignant transformation since melanocytes treated with 5-Aza-2'-deoxycytidine before each anchorage blockade do not transform. Some epigenetic changes seem to be also responsible for the maintenance of malignant phenotype, since melanoma cell lines (4C11- and 4C11+) treated in vitro with 5-Aza-2'-deoxycytidine or Trichostatin A showed reduction of tumor growth in vivo. Changes in gene expression reflecting cell adaptation to new environment were also observed. We propose a model in which sustained microenvironmental stress in melanocytes results in epigenetic reprogramming. Thus, after adaptation, cells may acquire epigenetic marks that could contribute to the establishment of a malignant phenotype.     

One- and two-step transformations of rat thyroid epithelial cells by retroviral oncogenes.

A system of epithelial cells is described in which it is possible to study the number and the nature of genes capable of conferring the malignant phenotype. Two fully differentiated, hormone-responsive cell lines from rat thyroid glands are presented which are susceptible to one-step or two-step transformation upon infection with several murine acute retroviruses. After infection, both cell lines became independent from their thyrotropic hormone requirement for growth. However, complete transformation was achieved with one of the cell lines (FRTL-5 Cl 2), whereas the other cell line (PC Cl 3) failed to grow in agar and to give rise to tumors in vivo. The latter cell line was susceptible to complete transformation upon cooperation of the v-ras-Ha and the human c-myc oncogenes.     

Epigenetic reprogramming as a key contributor to melanocyte malignant transformation

Melanoma progression requires deregulation of gene expression by currently uncharacterized epigenetic mechanisms. A mouse model based on changes in cell microenvironment was developed by our group to study melanocyte malignant transformation. Melanoma cell lines (4C11− and 4C11+) were obtained as result of 5 sequential anchorage blockades of non-tumorigenic melan-a melanocytes. Melan-a cells submitted to 4 de-adhesion cycles were also established (4C), are non-tumorigenic and represent an intermediary phase of tumor progression. The aim of this work was to identify factors contributing to epigenetic modifications in early and later phases of malignant transformation induced by anchorage impediment. Epigenetic alterations occur early in tumorigenesis; 4C cell line shows changes in global and gene-specific DNA methylation and histone marks. Many histone modifications differ between melan-a, 4C, 4C11− (non-metastatic melanoma cell line) and 4C11+ (metastatic melanoma cell line) which could be associated with changes in gene and microRNA expression. These epigenetic alterations seem to play a key role in malignant transformation since melanocytes treated with 5-Aza-2′-deoxycytidine before each anchorage blockade do not transform. Some epigenetic changes seem to be also responsible for the maintenance of malignant phenotype, since melanoma cell lines (4C11− and 4C11+) treated in vitro with 5-Aza-2′-deoxycytidine or Trichostatin A showed reduction of tumor growth in vivo. Changes in gene expression reflecting cell adaptation to new environment were also observed. We propose a model in which sustained microenvironmental stress in melanocytes results in epigenetic reprogramming. Thus, after adaptation, cells may acquire epigenetic marks that could contribute to the establishment of a malignant phenotype.Key words: anchorage blockade, sustained stress, pluripotency, epigenetic reprogramming, malignant melanoma     

Accelerated heme synthesis and degradation in transformed fibroblasts

Various parameters of the heme biosynthetic pathway were studied in two cell lines, one nontransformed and the other malignantly transformed (MLV/MS), both replicating at the same rate. Using the above system enabled us to distinguish between phenomena characteristic of the malignant transformation per se and those due to accelerated growth rate. Heme synthesis and degradation as well as the activities of ALAS, ALAD, PBGD, and FC were found to be increased in the transformed cells. However, the concentration of intracellular heme was markedly reduced from 30.4 +/- 4.4 pmole/mg protein in nontransformed cells to 10.5 +/- 2.6 pmole/mg protein in transformed cells. These observations show that malignant transformation leads to changes in heme metabolism unrelated to growth rate in this cell line.     

Agglomerates of aberrant DNA methylation are associated with toxicant-induced malignant transformation

Epigenetic dysfunction is a known contributor in carcinogenesis, and is emerging as a mechanism involved in toxicant-induced malignant transformation for environmental carcinogens such as arsenicals or cadmium. In addition to aberrant DNA methylation of single genes, another manifestation of epigenetic dysfunction in cancer is agglomerative DNA methylation, which can participate in long-range epigenetic silencing that targets many neighboring genes and has been shown to occur in several types of clinical cancers. Using in vitro model systems of toxicant-induced malignant transformation, we found hundreds of aberrant DNA methylation events that emerge during malignant transformation, some of which occur in an agglomerative fashion. In an arsenite-transformed prostate epithelial cell line, the protocadherin (PCDH), HOXC and HOXD gene family clusters are targeted for agglomerative DNA methylation. The agglomerative DNA methylation changes induced by arsenicals appear to be common and clinically relevant events, since they occur in other human cancer cell lines and models of malignant transformation, as well as clinical cancer specimens. Aberrant DNA methylation in general occurred more often within histone H3 lysine-27 trimethylation stem cell domains. We found a striking association between enrichment of histone H3 lysine-9 trimethylation stem cell domains and toxicant-induced agglomerative DNA methylation, suggesting these epigenetic modifications may become aberrantly linked during malignant transformation. In summary, we found an association between toxicant-induced malignant transformation and agglomerative DNA methylation, which lends further support to the hypothesis that epigenetic dysfunction plays an important role in toxicant-induced malignant transformation.     

Agglomerates of aberrant DNA methylation are associated with toxicant-induced malignant transformation

Epigenetic dysfunction is a known contributor in carcinogenesis, and is emerging as a mechanism involved in toxicant-induced malignant transformation for environmental carcinogens such as arsenicals or cadmium. In addition to aberrant DNA methylation of single genes, another manifestation of epigenetic dysfunction in cancer is agglomerative DNA methylation, which can participate in long-range epigenetic silencing that targets many neighboring genes and has been shown to occur in several types of clinical cancers. Using in vitro model systems of toxicant-induced malignant transformation, we found hundreds of aberrant DNA methylation events that emerge during malignant transformation, some of which occur in an agglomerative fashion. In an arsenite-transformed prostate epithelial cell line, the protocadherin (PCDH), HOXC and HOXD gene family clusters are targeted for agglomerative DNA methylation. The agglomerative DNA methylation changes induced by arsenicals appear to be common and clinically relevant events, since they occur in other human cancer cell lines and models of malignant transformation, as well as clinical cancer specimens. Aberrant DNA methylation in general occurred more often within histone H3 lysine-27 trimethylation stem cell domains. We found a striking association between enrichment of histone H3 lysine-9 trimethylation stem cell domains and toxicant-induced agglomerative DNA methylation, suggesting these epigenetic modifications may become aberrantly linked during malignant transformation. In summary, we found an association between toxicant-induced malignant transformation and agglomerative DNA methylation, which lends further support to the hypothesis that epigenetic dysfunction plays an important role in toxicant-induced malignant transformation.     

Towards an understanding of the malignant transformation of diploid human fibroblasts

This paper reviews the major reports of the spontaneous or carcinogen-induced transformation of human fibroblasts to the malignant state, to infinite lifespan, or to anchorage independence. In some cases, the transformed cells and the parent cell with which the work began were made available to us to be tested to determine whether the cells shared common isozymes, HLA antigens, restriction-fragment length polymorphisms, marker chromosomes, etc., as one would expect. When we examined the normal fibroblastic cell line KD for these markers, and the transformed HuT cell lines developed from it by Kakunaga (Proc. Natl. Acad. Sci. (U.S.A.), 75, 1334, 1978) for these markers, we found marked differences, indicating that KD cells and HuT cells are derived from different individuals. When we applied these techniques to the 3 human fibroblast cell lines transformed by Namba to acquire infinite lifespan in culture (Gann, 27, 221, 1981), it became clear that KSMT-6 was derived from the parent cell, KMS-6, but that both cell lines CT-1 and SUSM-1 were derived from the same parental cell line, AD387. Similar studies with other sets of cell lines are also reported. In the light of these studies, it appears that there is no example of the malignant transformation of human fibroblasts by carcinogen treatment. However, neoplastic transformation and transformation to infinite lifespan by carcinogen treatment have been achieved by a number of workers. We speculate as to how malignant transformation might be obtained by carcinogen treatment.     

Protein and mRNA characterization in high and low metastasis adenoid cystic carcinoma cell lines

Metastasis and invasion, the important characteristics of malignant tumors, are closely associated with a series of changes in the expression of genes and proteins. In this study, we compare mRNA and protein expression in high and low metastasis adenoid cystic carcinoma cell lines by mRNA suppression subtractive hybridization and two-dimensional electrophoresis combined with peptide mass fingerprint analysis. 34 differentially expressed genes were obtained using suppression subtractive hybridization experiments including 6 highly expressed gene sequences in the high metastasis cell line, and 28 in the low metastasis cell line. RNA dot blot hybridization further confirmed the results after excluding false positives. For protein analysis, ten significantly different protein spots were detected using two-dimensional gel electrophoresis technique combined with matrix-assisted laser desorption/ionization time-of-flight mass spectrometer (MALDI- TOF-MS). The results then compare with the SWISS PROT database. These results suggest that high tumor metastasis of adenoid cystic carcinoma is associated with multiple genes whose function include angiogenesis, protein synthesis, signal transduction, modulation of cell cycle, molecular chaperones, and immune co-stimulating molecule. Moreover, the results of the phenotypic function-related expression mapping analysis at the mRNA and protein level revealed obvious complementarities, providing important clues for further study of the molecular mechanism of metastasis, metastasis control and possible targets for cancer gene therapy.     

Protein and mRNA characterization in high and low metastasis adenoid cystic carcinoma cell lines

Metastasis and invasion, the important characteristics of malignant tumors, are closely associated with a series of changes in the expression of genes and proteins. In this study, we compare mRNA and protein expression in high and low metastasis adenoid cystic carcinoma cell lines by mRNA suppression subtractive hybridization and two-dimensional electrophoresis combined with peptide mass fingerprint analysis. 34 differentially expressed genes were obtained using suppression subtractive hybridization experiments including 6 highly expressed gene sequences in the high metastasis cell line, and 28 in the low metastasis cell line. RNA dot blot hybridization further confirmed the results after excluding false positives. For protein analysis, ten significantly different protein spots were detected using two-dimensional gel electrophoresis technique combined with matrix-assisted laser desorption/ionization time-of-flight mass spectrometer (MALDI- TOF-MS). The results then compare with the SWISS PROT database. These results suggest that high tumor metastasis of adenoid cystic carcinoma is associated with multiple genes whose function include angiogenesis, protein synthesis, signal transduction, modulation of cell cycle, molecular chaperones, and immune co-stimulating molecule. Moreover, the results of the phenotypic function-related expression mapping analysis at the mRNA and protein level revealed obvious complementarities, providing important clues for further study of the molecular mechanism of metastasis, metastasis control and possible targets for cancer gene therapy.     

In vitro carcinogenesis studies on mouse fibroblast cells

Fibroblast cell lines were established from pulmonary explants derived from inbred CBA T6T6 mouse embryos. Cell lines controlled for the absence of spontaneous transformation were treated with 20=methylcholenthrene (0, 1 microgram/ml). The altered biological characteristics were studied during the process of the malignant transformation by the comparison of the untreated and 20-methylcholanthrene pretreated cell populations: the loss of contact inhibition and the connection between the malignant transformation and the arylhydrocarbon hydroxylase enzyme activity were investigated. No changes in the cell proliferation rate could be found following malignant transformation, but an increased resistance against altered circumstances was observed. In the course of passages, a gradual decreases in aryl hydrocarbon hydroxylase activity of the untreated line was seen, which disappeared or significantly decreased following 20-methylcholanthrene treatment, compared to the controls.     

Proteins of BrdU-Dependent Hamster Cell Lines as Characterized by Two-Dimensional Gel Electrophoresis

Cell lines which exhibit the BrdU-dependent phenotype (B4 and HAB) were studied with respect to BrdU-induced alterations in genetic expression by two-dimensional gel electrophoresis. A comparison of the proteins from the HAB cells, in which the DNA is 100% substituted by BrdU, to those of the unsubstituted parent line (3460) showed 55 protein alterations; the synthesis of 15 increased while that of the other 40 decreased. When 3460 cells were grown in BrdU such that their DNA was > 50% substituted, 27 protein changes could be detected; of these, the synthesis of 10 increased while that of 17 decreased. A comparison of all these changes in the various cell lines showed six which were common to the BrdU-substituted cell lines. The proteins from another Syrian hamster cell line, BHK.-21 (C-13) and those of HAB cells grown in thymidine or BrdC were also examined on two-dimensional gels.
Although BrdU has a dramatic effect on many cellular functions, relatively few changes in the pattern of protein synthesis could be detected in these cell lines, perhaps reflecting the specialized action of this analogue on particular cellular functions.     

Characterization of a murine monoclonal antibody that detects a C-terminal fragment of the raf oncogene product

A murine mAb, STEGI 1, was generated against a 30-kDa raf protein purified from an Escherichia coli expression vector. Immunoblot analysis confirmed that this antibody recognized the original immunizing protein as well as a 44- to 48-kDa protein from several raf-transformed cell lines. Immunoprecipitation experiments isolated a 48-kDa protein from a cell line transfected with a c-raf construct as well as from normal NIH 3T3 fibroblasts. Parallel experiments with polyvalent antiserum prepared against E. coli-derived v-raf (C terminus)-precipitated proteins with apparent Mr of 48 and 74 kDa, as had been described previously. Immunofluorescence flow cytometry of raf-transformed cell lines revealed intense intracytoplasmic staining. This staining was specifically inhibited by preincubation of STEGI 1 with purified raf 30-kDa protein. It should now be possible to more easily assess the role of the raf oncogene product in malignant transformation.     

Growth rate determines activity of porphobilinogen deaminase both in nonmalignant and malignant cell lines

PBGD activity and growth rate were determined in cultures of rat embryo fibroblasts, nontransformed and MLV/MS transformed fibroblastic cell lines; NIH-3T3 cells, and in a mouse lymphosarcoma cell line [L-929]. The two parameters examined correlate positively (P less than 0.001). The results of this investigation would seem to indicate clearly that porphobilinogen deaminase activity is related to growth. However, these experiments do not rule out the possibility that malignant transformation per se also causes changes in porphobilinogen deaminase activity.     

Immortalized cells and one oncogene in malignant transformation: old insights on new explanation

Background

Nearly thirty years ago, it was first shown that malignant transformation with single oncogene necessarily requires the immortal state of the cell. From that time this thesis for the cells of human origin was not disproved. The basic point which we want to focus on by this short communication is the correct interpretation of the results obtained on the widely used human embryonic kidney 293 (HEK293) cells.

Results

Intensive literature analysis revealed an increasing number of recent studies discovering new oncogenes with non-overlapping functions. Since the 1970s, dozens of oncogenes have been identified in human cancer. Cultured cell lines are often used as model systems in these experiments. In some investigations the results obtained on such cells are interpreted by the authors as a malignant transformation of normal animal or even normal human cells (as for example with HEK293 cells). However, when a cell line gains the ability to undergo continuous cell division, the cells are not normal any more, they are immortalized cells. Nevertheless, the authors consider these cells as normal human ones, what is basically incorrect. Moreover, it was early demonstrated that the widely used human embryonic kidney 293 (HEK293) cells have a relationship to neurons.

Conclusions

Thus, the experiments with established cell lines reinforce the notion that immortality is an essential requirement for malignant transformation that cooperates with other oncogenic changes to program the neoplastic state and substances under such investigation should be interpreted as factors which do not malignantly transform normal cells alone, but possess the ability to enhance the tumorigenic potential of already immortalized cells.     

Proteins of BrdU-dependent hamster cell lines as characterized by two-dimensional gel electrophoresis.

Cell lines which exhibit the BrdU-dependent phenotype (B4 and HAB) were studied with respect to BrdU-induced alterations in genetic expression by two-dimensional gel electrophoresis. A comparison of the proteins from the HAB cells, in which the DNA is 100% substituted by BrdU, to those of the unsubstituted parent line (3460) showed 55 protein alterations; the synthesis of 15 increased while that of the other 40 decreased. When 3460 cells were grown in BrdU such that their DNA was greater than 50% substituted, 27 protein changes could be detected; of these, the synthesis of 10 increased while that of 17 decreased. A comparison of all these changes in the various cell lines showed six which were common to the BrdU-substituted cell lines. The proteins from another Syrian hamster cell line, BHK-21 (C-13) and those of HAB cells grown in thymidine or BrdC were also examined on two-dimensional gels. Although BrdU has a dramatic effect on many cellular functions, relatively few changes in the pattern of protein synthesis could be detected in these cell lines, perhaps reflecting the specialized action of this analogue on particular cellular functions.     

Immortalization and malignant transformation of Eukaryotic cells

The process of cellular transformation has been amply studied in vitro using immortalized cell lines. Immortalized cells never have the normal diploid karyotype, nevertheless, they cannot grow over one another in cell culture (contact inhibition), do not form colonies in soft agar (anchorage-dependent growth) and do not form tumors when injected into immunodeficient rodents. All these characteristics can be obtained with additional chromosome changes. Multiple genetic rearrangements, including whole chromosome and gene copy number gains and losses, chromosome translocations, gene mutations are necessary for establishing the malignant cell phenotype. Most of the experiments detecting transforming ability of genes overexpressed and/or mutated in tumors (oncogenes) were performed using mouse embryonic fibroblasts (MEFs), NIH3T3 mouse fibroblast cell line, human embryonic kidney 293 cell line (HEK293), and human mammary epithelial cell lines (mainly HMECs and MCF10A). These cell lines have abnormal karyotypes and are prone to progress to malignantly transformed cells. This review is aimed at understanding the mechanisms of cell immortalization by different “immortalizing agents”, oncogene-induced cell transformation of immortalized cells and moderate response of the advanced tumors to anticancer therapy in the light of tumor “oncogene and chromosome addiction”, intra-/intertumor heterogeneity, and chromosome instability.     

Immortalization and malignant transformation of eukaryotic cells

The process of cellular transformation has been amply studied in vitro using immortalized cell lines. Immortalized cells never have the normal diploid karyotype, nevertheless, they cannot grow over one another in cell culture (contact inhibition), do not form colonies in soft agar (anchorage-dependent growth) and do not form tumors when injected into immunodeficient rodents. All these characteristics can be obtained with additional chromosome changes. Multiple genetic rearrangements, including whole chromosome and gene copy number gains and losses, chromosome translocations, gene mutations are necessary for establishing the malignant cell phenotype. Most of the experiments detecting transforming ability of genes overexpressed and/or mutated in tumors (oncogenes) were performed using mouse embryonic fibroblasts (MEFs), NIH3T3 mouse fibroblast cell line, human embryonic kidney 293 cell line (HEK293), and human mammary epithelial cell lines (mainly HMECs and MC-F10A). These cell lines have abnormal karyotypes and are prone to progress to malignantly transformed cells. This review is aimed at understanding the mechanisms of cell immortalization by different "immortalizing agents", oncogene-induced cell transformation of immortalized cells and moderate response of the advanced tumors to anticancer therapy in the light of tumor "oncogene and chromosome addiction", intra-/intertumor heterogeneity, and chromosome instability.     

The cytotoxicity of bleomycin A2 on adult rat liver epithelial cell lines at different stages of spontaneous cell transformation

Cytotoxic effects of Bleomycin A2 on adult rat liver epithelial cell lines were evaluated by three methods: the incorporation rate of (3H) thymidine for DNA biosynthesis, the incorporation rate of L-(3H) leucine for protein biosynthesis and Giemsa dye staining of surviving cells. Chromosome investigations at successive passages of cell lines have shown that spontaneous chromosome abnormalities in distribution and structure after 15-20 passages, i.e. 50 to 60 cell generations, were the earliest morphological sign of spontaneous transformation. In this study a highly spontaneously transformed cell line was very sensitive to the drug. Another cell line at the beginning of spontaneous transformation appeared to be insensitive although on further passage it became more sensitive. The use of microtitration plates made it easier for us to undertake a comparative study of the different parameters. Following Bleomycin A2 exposure, Giemsa staining gave the best evaluation of cell killing whereas thymidine incorporation allowed the estimation of cell recovery. The antineoplastic effect of Bleomycin A2 can probably be used to evaluate the malignant potential of different rat liver epithelial cell lines.     

EZH2蛋白在食管上皮永生化细胞系和恶性转化细胞系中的表达

目的研究EZH2蛋白在食管上皮永生化细胞系(SHEE)和恶性转化细胞系(SHEEC)中的表达。方法采用免疫细胞化学染色、免疫印迹分析和流式细胞术检测两种细胞系EZH2蛋白的表达。结果两种细胞EZH2蛋白染色均呈阳性,阳性反应定位于细胞核,部分细胞胞浆也有阳性着色。免疫印迹分析表明SHEEC细胞和SHEE细胞的总蛋白、核蛋白在分子质量约90ku的位置均出现特异性印迹条带。SHEE细胞中EZH2蛋白的表达强于SHEEC细胞(P<0.05)。流式细胞术显示EZH2蛋白在两种细胞中均有表达,两者的平均荧光强度无明显差别;阳性细胞率均较高,其中SHEE细胞阳性率高于SHEEC细胞。结论EZH2蛋白在SHEE细胞和SHEEC细胞中高表达可能参与了它们的恶性改变;而EZH2蛋白在两种细胞系中的差异表达可能与细胞的分化程度及来源于胚胎食管上皮细胞相关。