Plasticity of Cadherin–Catenin Expression in the Melanocyte Lineage

Cadherins are calcium‐dependent cell adhesion receptors with strong morphoregulatory functions. To mediate functional adhesion, cadherins must interact with actin cytoskeleton. Catenins are cytoplasmic proteins that mediate the interactions between cadherins and the cytoskeleton. In addition to their role in cell–cell adhesion, catenins also participate in signaling pathways that regulate cell growth and differentiation. Cadherins and catenins appear to be involved in melanocyte development and transformation. Here, we investigated the function of cadherin–catenin complexes in the normal development and transformation of melanocytes by studying the patterns of expression of the cell–cell adhesion molecules, E‐, N‐ and P‐cadherin, and the expression of their cytoplasmic partners, α‐, β‐ and Γ‐catenin, during murine development. Similar analyses were performed in vitro using murine melanoblast, melanocyte, and melanoma cell lines in the presence and absence of keratinocytes, the cells with which melanocytes interact in vivo. Overall, the results suggest that the expression of cadherins and catenins is very plastic and depends on their environment as well as the transformation status of the cells. This plasticity is important in fundamental cellular mechanisms associated with normal and pathological ontogenesis, as well as with tumorigenesis.     

Expression analysis of epithelial cadherin and related proteins in IBH‐6 and IBH‐4 human breast cancer cell lines

Epithelial cadherin (E‐cadherin) is a 120 kDa cell–cell adhesion molecule involved in the establishment of epithelial adherens junctions. It is connected to the actin cytoskeleton by adaptor proteins such as β‐catenin. Loss of E‐cadherin expression/function has been related to tumor progression and metastasis. Several molecules associated with down‐regulation of E‐cadherin have been described, within them neural cadherin, Twist and dysadherin. Human breast cancer cell lines IBH‐6 and IBH‐4 were developed from ductal primary tumors and show characteristic features of malignant epithelial cells. In this study expression of E‐cadherin and related proteins in IBH‐6 and IBH‐4 cell lines was evaluated. In IBH‐6 and IBH‐4 cell extracts, only an 89 kDa E‐cadherin form (Ecad89) was detected, which is truncated at the C‐terminus and is present at low levels. Moreover, no accumulation of the 86 kDa E‐cadherin ectodomain and of the 38 kDa CTF1 fragment was observed. IBH‐6 and IBH‐4 cells showed an intracellular scattered E‐cadherin localization. β‐catenin accompanied E‐cadherin localization, and actin stress fibers were identified in both cell types. E‐cadherin mRNA levels were remarkably low in IBH‐6 and IBH‐4 cells. The E‐cadherin mRNA and genomic sequence encoding exons 14–16 could not be amplified in either cell line. Neither the mRNA nor the protein of neural cadherin and dysadherin were detected. Up‐regulation of Twist mRNA was found in both cell lines. In conclusion, IBH‐6 and IBH‐4 breast cancer cells show down‐regulation of E‐cadherin expression with aberrant protein localization, and up‐regulation of Twist; these features can be related to their invasive/metastatic characteristics. J. Cell. Physiol. 222: 596–605, 2010. © 2009 Wiley‐Liss, Inc.     

A secreted form of P-cadherin is expressed in malignant melanoma

Cadherins are Ca-dependent homophilic cell-cell adhesion molecules which are responsible for correct location of cells and tissue integrity. They are critical for development and maintenance of epithelial architecture. Aberrantly expressed cadherins are known to be involved in malignant transformation of different types of tissues. In this study, we show the expression of a short truncated 50 kDa form of the N-terminal part of P-cadherin in seven melanoma cell lines compared to melanocytes and keratinocytes. In vitro protein analysis on cell culture supernatant as well as immunohistochemistry of primary and metastatic melanoma tissue revealed the expression of this short form of P-cadherin. Furthermore, analysis showed that this short 50 kDa form of P-cadherin is secreted by melanoma cells in contrast to the membrane bound form in melanocytes. Analysis on mRNA level detected only exon 1 to 10 of P-cadherin resulting in the 50 kDa form missing the transmembrane and cytoplasmatic region. Genomic sequence analysis did not show any mutations in melanoma cells neither in the exons nor in the exon-intron boundaries. Furthermore, there was no loss of exons 11-16 on the genomic level. Functionally, the secreted form of P-cadherin could play a role as regulator of the homophilic interaction between P-cadherin molecules by antagonizing their biological role acting as a dominant negative form to interrupt cell-cell attachment.     

Loss of maspin expression contributes to a more invasive potential in malignant melanoma

Deregulation of protease expression and activity is known to play an important role in tumour progression of malignant melanoma. The serpin maspin, a tumour suppressor in breast and prostate cancer was described as an inhibitor of cell migration and inducer of cell adhesion between the basement membrane and extracellular matrix resulting in inhibition of tumour metastasis. In contrast, overexpression of maspin is correlated with poor prognosis in other cancers. However, little is known about expression, regulation and function of maspin in malignant melanoma. In this study, we found loss of maspin expression in malignant melanoma cells compared with normal human epidermal melanocytes, which was analysed by quantitative real-time PCR, Western blot analysis, immunohistochemistry and microarray. For functional studies, melanoma cell clones stably transfected with a maspin expression vector were tested for changes in proliferation, migration and invasion. Although we could not see differences in proliferation and migration, we detected strongly reduced invasive capacity in the melanoma cell clones in which maspin is re-expressed compared with control. Reduced invasive potential was also detected in three different melanoma cell lines transiently transfected with a maspin expression vector. Furthermore, exogenously added maspin alone was sufficient to reduce invasion in MelIm significantly, indicating that maspin directly inhibits invasion on the cell surface. In summary, we believe that maspin is a tumour suppressor in malignant melanoma.     

E‐cadherin determines Caveolin‐1 tumor suppression or metastasis enhancing function in melanoma cells

The role of caveolin‐1 (CAV1) in cancer is highly controversial. CAV1 suppresses genes that favor tumor development, yet also promotes focal adhesion turnover and migration of metastatic cells. How these contrasting observations relate to CAV1 function in vivo is unclear. Our previous studies implicate E‐cadherin in CAV1‐dependent tumor suppression. Here, we use murine melanoma B16F10 cells, with low levels of endogenous CAV1 and E‐cadherin, to unravel how CAV1 affects tumor growth and metastasis and to assess how co‐expression of E‐cadherin modulates CAV1 function in vivo in C57BL/6 mice. We find that overexpression of CAV1 in B16F10 (cav‐1) cells reduces subcutaneous tumor formation, but enhances metastasis relative to control cells. Furthermore, E‐cadherin expression in B16F10 (E‐cad) cells reduces subcutaneous tumor formation and lung metastasis when intravenously injected. Importantly, co‐expression of CAV1 and E‐cadherin in B16F10 (cav‐1/E‐cad) cells abolishes tumor formation, lung metastasis, increased Rac‐1 activity, and cell migration observed with B16F10 (cav‐1) cells. Finally, consistent with the notion that CAV1 participates in switching human melanomas to a more malignant phenotype, elevated levels of CAV1 expression correlated with enhanced migration and Rac‐1 activation in these cells.     

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.     

Crosstalk in skin: melanocytes,keratinocytes, stem cells,and melanoma

In the vertebrate embryo, melanocytes arise from the neural crest, migrate to and colonize the basal layer within the skin and skin appendages. Post-migratory melanocytes are securely attached to the basement membrane, and their morphology, growth, adhesion, and migration are under control of neighboring keratinocytes. Melanoma is a malignant tumor originated from melanocytes or their progenitor cells. During melanocyte transformation and melanoma progression, melanocytes lose their interactions with keratinocytes, resulting in uncontrolled proliferation and invasion of the malignant cells. Melanoma cells at the advanced stages often lack melanocytic features and resemble multipotent progenitors, which are a potential melanocyte reservoir in human skin. In this mini-review, we will summarize findings on cell-cell interactions that are responsible for normal melanocyte homeostasis, stem cell self-renewal, and differentiation. Our ultimate goal is to define molecules and pathways, which are essential for normal cell-cell interactions but deregulated in melanoma formation and progression.     

Deletion of specific protein kinase C subspecies in human melanoma cells

It has been shown that tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA), stimulates the proliferation of normal human melanocytes, whereas it inhibits the growth of human melanoma cell lines. The expression of protein kinase C (PKC) subspecies, the major intracellular receptors for TPA, was examined in normal melanocytes and the four melanoma cell lines HM3KO, MeWo, HMV-1, and G361. PKC was partially purified and then separated into subspecies by column chromatography on Mono Q and hydroxyapatite successively, and finally subjected to immunoblot analysis using antibodies specific for the PKC subspecies. Of the PKC subspecies examined, δ-, ϵ-, and ζ-PKC were detected in both normal melanocytes and the four melanoma cell lines. In contrast, both α-PKC and β-PKC were expressed in normal melanocytes, whereas either α-PKC or β-PKC was detected in melanoma cells. Specifically, HM3KO, MeWo, and HMV-1 cells were shown to contain α-PKC but not β-PKC, while G361 cells expressed β-PKC but not α-PKC. The growth of these melanoma cells was suppressed by TPA treatment, and the growth of the G361 cells lacking α-PKC was inhibited more efficiently than the other melanoma cell lines which lacked β-PKC. It was further shown that β-PKC was not detected in freshly isolated human primary or metastatic melanoma tissues. These results suggest that the expression of α-PKC or β-PKC may be altered during the malignant transformation of normal melanocytes and that loss of α-PKC or β-PKC may be related to the inhibitory effect of TPA on the growth of melanoma cells. © 1996 Wiley-Liss, Inc.     

Melanoma tumors frequently acquire LRP2/megalin expression,which modulates melanoma cell proliferation and survival rates

We show that the multiligand receptor megalin, known to mediate uptake and trafficking of nutrients and signaling molecules, is frequently expressed in malignant melanoma samples. Expression of megalin‐encoding mRNA was investigated in 65 samples of nevi, melanomas, and melanoma metastases and was observed in more than 60% of the malignant samples, while only in 20% of the benign counterparts. Megalin expression in nevus and melanoma samples was additionally investigated by immunohistochemistry, which confirmed our mRNA‐based observations. We furthermore show that a panel of tumor‐derived melanoma cell lines express LRP2/megalin endogenously. In these cells, megalin is internalized from the cell surface and localizes extensively to intracellular vesicles, confirming receptor activity and pointing toward association with the endocytic apparatus. Groundbreaking, our results indicate that sustained megalin expression in melanoma cells is crucial for cell maintenance, as siRNA‐mediated reduction in melanoma cell expression of LRP2/megalin significantly decreases melanoma cell proliferation and survival rates.     

A monoclonal antibody recognizes an O-acylated sialic acid in a human melanoma-associated ganglioside

Monoclonal antibody D1.1 originally prepared against the B49 cell line derived from a rat brain tumor was shown to react with a ganglioside present in fetal rat brain. We have found that this antigen is also present in human malignant melanoma tumors as well as many melanoma cell lines. The ganglioside from human melanoma cell lines migrates between GM1 and GM2 on one-dimensional thin layer chromatography. Analysis by two-dimensional thin layer chromatography with intermediate ammonia treatment suggests that the ganglioside contains one or more base-labile O-acyl esters. Mild base hydrolysis under conditions known to remove O-acyl esters results in complete loss of antigenic reactivity. Thus, the alkali-labile moiety is a critical component of the epitope recognized by the antibody. Analysis of the sialic acids of total gangliosides from [6-3H]glucosamine-labeled melanoma cells showed that approximately 10% of these molecules are O-acylated. Similar analysis of the purified ganglioside showed that greater than 30% of the sialic acids comigrated with authentic 9-O-acetyl-N-acetylneuraminic acid. The antibody did not cross-react with normal human skin melanocytes nor with any of a large number of normal human adult and fetal tissues. The antibody also did not react with numerous other malignant cell lines studied. These findings suggest that the antigenic epitope defined by antibody D1.1 contains an O-acylated sialic acid and may arise from aberrant O-acetylation occurring in human malignant melanoma cells.     

Competing to coordinate cell fate decisions: the MST2-Raf-1 signaling device

Malignant melanoma is still poorly understood at the genomic level. Recently, a new technique for the high-resolution analysis of copy number changes named digital karyotyping was introduced. This approach is derived from SAGE (serial analysis of gene expression) and allows the detection of genomic amplifications and deletions, which are indicative of oncogenes and tumor suppressor genes. Four human melanoma cell lines were subjected to analysis by digital karyotyping. 828,780 genomic tags were generated and analysed quantitatively. Thereby, we identified a somatic, homozygous deletion of 570 kbp removing exons 3-29 of the dystrophin (DMD, Duchenne muscular dystrophy) gene. Analysis of DMD in 51 melanoma cell lines further revealed a homozygous and a hemizygous deletion in DMD. Furthermore, DMD mRNA expression was down-regulated with respect to primary melanocytes and accompanied by loss of DMD protein expression in 38 of 55 (69%) and a significant reduction in 10 of 55 (18%) melanoma cell lines. Sequence analysis of DMD cDNAs in 37 melanoma cell lines revealed 6 new sequence variants with a significantly lower frequency than previously described DMD polymorphisms, which may affect dystrophin function. Knock-down of DMD enhanced migration and invasion, whereas re-expression of DMD attenuated migration and induced a senescent phenotype in melanoma cell lines. Taken together, our results suggest that inactivation of DMD is involved in the pathogenesis of malignant melanoma. Loss of DMD may critically change the migratory and proliferative capacity of melanocytes.     

MicroRNA‐622 is a novel mediator of tumorigenicity in melanoma by targeting Kirsten rat sarcoma

The network of molecular players is similar when comparing neural crest‐derived, actively migrating melanoblasts to melanoma cells. However, melanoblasts are sensitive to differentiation‐initiating signals at their target site (epidermis), while melanoma cells maintain migratory and undifferentiated features. We aimed at identifying downregulated genes in melanoma that are particularly upregulated in melanoblasts. Loss of such genes could contribute to stabilization of a dedifferentiated, malignant phenotype in melanoma. We determined that microRNA‐622 (miR‐622) expression was strongly downregulated in melanoma cells and tissues compared to melanocytes and melanoblast‐related cells. miR‐622 expression correlated with survival of patients with melanoma. miR‐622 re‐expression inhibited clonogenicity, proliferation, and migration in melanoma. Inhibition of miR‐622 in melanocytes induced enhanced migration. Kirsten rat sarcoma (KRAS) was identified as a major functional target of miR‐622 in melanoma. We conclude that miR‐622 is a novel tumor suppressor in melanoma and identify the miR‐622‐KRAS axis as potential therapeutic target.