Dorothea Becker

Whole-genome expression profiling of the melanoma progression pathway reveals marked molecular differences between nevi/melanoma in situ and advanced-stage melanomas

Over the past two decades, several known genes have been shown to govern important functions in the development of primary and metastatic melanomas. However, from this limited number of genes, it is not possible to establish detailed molecular profiles for the early and advanced stages of melanoma development. To gain insights into the genetic profile of every stage of the melanoma progression pathway, and to determine to what extent these profiles are similar or distinct, we performed whole-genome expression profiling of tissue specimens representing normal skin, benign and atypical nevi, and early and advanced-stage melanomas. The results of this study provide first-time evidence that significant molecular changes occur distinctly at the border of/transition from melanoma in situ to primary melanoma, and that genes involved in mitotic cell cycle regulation and cell proliferation constitute the two leading categories of genes associated with these changes.

Generation and analysis of melanoma SAGE libraries: SAGE advice on the melanoma transcriptome

In this study, we generated three SAGE libraries from melanoma tissues. Using bioinformatics tools usually applied to microarray data, we identified several genes, including novel transcripts, which are preferentially expressed in melanoma. SAGE results converged with previous microarray analysis on the importance of intracellular calcium and G-protein signaling, and the Wnt/Frizzled family. We also examined the expression of CD74, which was specifically, albeit not abundantly, expressed in the melanoma libraries using a melanoma progression tissue microarray, and demonstrate that this protein is expressed by melanoma cells but not by benign melanocytes. Many genes involved in intracellular calcium and G-protein signaling were highly expressed in melanoma, results we had observed earlier from microarray studies (Bittner et al., 2000). One of the genes most highly expressed in our melanoma SAGE libraries was a calcium-regulated gene, calpain 3 (p94). Immunohistochemical analysis demonstrated that calpain 3 moves from the nuclei of non-neoplastic cells to the cytoplasm of malignant cells, suggesting activation of this intracellular proteinase. Our SAGE results and the clinical validation data demonstrate how SAGE profiles can highlight specific links between signaling pathways as well as associations with tumor progression. This may provide insights into new genes that may be useful for the diagnosis and therapy of melanoma.

Importance of glycolysis and oxidative phosphorylation in advanced melanoma

Serum lactate dehydrogenase (LDH) is a prognostic factor for patients with stage IV melanoma. To gain insights into the biology underlying this prognostic factor, we analyzed total serum LDH, serum LDH isoenzymes, and serum lactate in up to 49 patients with metastatic melanoma. Our data demonstrate that high serum LDH is associated with a significant increase in LDH isoenzymes 3 and 4, and a decrease in LDH isoenzymes 1 and 2. Since LDH isoenzymes play a role in both glycolysis and oxidative phosphorylation (OXPHOS), we subsequently determined using tissue microarray (TMA) analysis that the levels of proteins associated with mitochondrial function, lactate metabolism, and regulators of glycolysis were all elevated in advanced melanomas compared with nevic melanocytes. To investigate whether in advanced melanoma, the glycolysis and OXPHOS pathways might be linked, we determined expression of the monocarboxylate transporters (MCT) 1 and 4. Analysis of a nevus-to-melanoma progression TMA revealed that MCT4, and to a lesser extend MCT1, were elevated with progression to advanced melanoma. Further analysis of human melanoma specimens using the Seahorse XF24 extracellular flux analyzer indicated that metastatic melanoma tumors derived a large fraction of energy from OXPHOS. Taken together, these findings suggest that in stage IV melanomas with normal serum LDH, glycolysis and OXPHOS may provide metabolic symbiosis within the same tumor, whereas in stage IV melanomas with high serum LDH glycolysis is the principle source of energy.

SAGE and antibody array analysis of melanoma-infiltrated lymph nodes: identification of Ubc9 as an important molecule in advanced-stage melanomas.

Although patients diagnosed with melanoma of ⩽1.00 mm thickness have a relatively good cure rate, the prognosis for patients with locally advanced and metastatic melanoma is grave. The discovery of new and effective therapies for this disease depends in large part on molecular studies that will resolve why advanced-stage melanoma is refractory to conventional chemotherapy and radiation therapy. To identify genes that have important functions in advanced-stage melanomas, in particular, in melanoma-infiltrated lymph nodes, which are not well characterized at the molecular level, we generated a LongSAGE library from a melanoma-positive lymph node, and subjected melanoma-infiltrated lymph nodes to protein expression profiling. The data document that the molecular signature of melanoma, which has spread to regional lymph nodes, is very similar to the molecular signature of primary melanomas. Equally important, we provide evidence that the ubiquitin-conjugating enzyme, Ubc9, is expressed at high levels in melanoma-positive lymph nodes, and that it plays a crucial role in preventing advanced-stage melanomas from undergoing chemotherapy-induced apoptosis.

The role of N-Cadherin, MCAM, and β3 integrin in melanoma progression, proliferation, migration and invasion

Melanoma, the most aggressive form of skin cancer, which accounts for 75% of all skin cancer-related deaths, continues to rise at an alarming rate worldwide. Despite a favorable cure rate when surgically removed at an early stage, the response rate of patients with metastatic disease to single agent chemotherapy is less than 15%, and biologic therapies are only marginally effective. Given this bleak picture, there is a great need to identify and characterize genes that play an important role in the advanced-stages of melanoma and thus, may represent valuable targets for clinical therapy. The cell adhesion molecules N-cadherin, MCAM, and 3 integrin have been suggested to represent melanoma progression markers; yet, little is known as to whether they may constitute therapeutic targets for the disease. To provide information regarding this aspect, we determined by way of whole-genome and tissue microarray analysis, their level of expression concordant with melanoma progression, and via RNA interference and antisense technology, their role in melanoma cell proliferation, migration, and invasion. The results of these studies demonstrate that N-cadherin and β3 integrin expression correlates with progression to advanced-stage melanoma, whereas expression of MCAM does not. On the other hand, MCAM and β3 integrin are the two adhesion molecules that play a pivotal role in melanoma cell migration and invasion, and for this reason, may represent valuable targets for melanoma therapy.

Ischaemia-induced expression of bFGF in normal skeletal muscle: a potential paracrine mechanism for mediating angiogenesis in ischaemic skeletal muscle.

To test the hypothesis that induction of endogenous bFGF can lead to angiogenesis in ischaemic skeletal muscle, we studied the expression of bFGF after transposition of a well-vascularized muscle flap onto an ischaemic hindlimb in the rabbit. The results indicated a marked induction of bFGF mRNA throughout the myoblasts of the well-perfused muscle flap but not the myoblasts of the ischaemic muscle. bFGF protein was detected in the muscle flap, particularly in the myoblasts located closest to a newly formed, adjacent interface, and in the interface itself. In contrast, bFGF expression was not induced after transposition of a well-perfused muscle flap onto healthy muscle tissue. These data provide evidence that the juxtaposition of ischaemic skeletal muscle with healthy mesenchymal tissue triggers an increased expression of bFGF in the myoblasts of the well-perfused muscle. This paracrine induction of bFGF, in turn, leads to increased angiogenesis and regeneration of the ischaemic skeletal muscle.

Expression analysis and molecular targeting of cyclin-dependent kinases in advanced melanoma.

A major focus of melanoma research continues to be the search for genes/proteins that may be suitable targets for molecular therapy of primary and metastatic melanoma. In line with this effort, the objective of the study presented herein was to determine whether interfering with cell cycle progression and in particular, the expression and function of select cyclin-dependent kinases, would impair the biological features of advanced melanoma. We provide data, which document that unlike nevi and melanoma in situ, primary and metastatic melanomas express high levels of CDK2, CDK1, and CDK5. Furthermore, we present the results of in vitro and preclinical in vivo studies, which demonstrate that treatment with a small-molecule cyclin-dependent kinase inhibitor that selectively blocks the function of CDK2, CDK5, CDK1, and CDK9, leads not only to inhibition of melanoma cell proliferation and apoptosis of melanoma cells, but also impairs the growth of human melanoma xenografts.

Mitochondrial Respiration - An Important Therapeutic Target in Melanoma

The importance of mitochondria as oxygen sensors as well as producers of ATP and reactive oxygen species (ROS) has recently become a focal point of cancer research. However, in the case of melanoma, little information is available to what extent cellular bioenergetics processes contribute to the progression of the disease and related to it, whether oxidative phosphorylation (OXPHOS) has a prominent role in advanced melanoma. In this study we demonstrate that compared to melanocytes, metastatic melanoma cells have elevated levels of OXPHOS. Furthermore, treating metastatic melanoma cells with the drug, Elesclomol, which induces cancer cell apoptosis through oxidative stress, we document by way of stable isotope labeling with amino acids in cell culture (SILAC) that proteins participating in OXPHOS are downregulated. We also provide evidence that melanoma cells with high levels of glycolysis are more resistant to Elesclomol. We further show that Elesclomol upregulates hypoxia inducible factor 1-α (HIF-1α), and that prolonged exposure of melanoma cells to this drug leads to selection of melanoma cells with high levels of glycolysis. Taken together, our findings suggest that molecular targeting of OXPHOS may have efficacy for advanced melanoma.

Markers and Tissue Resources for Melanoma: Meeting Report

The Markers and Tissue Resources for Melanoma meeting convened by the Cancer Diagnosis Program, Division of Cancer Treatment and Diagnosis, Specialized Programs of Research Excellence at the Organ Systems Branch of the National Cancer Institute (NCI), and the Melanoma Research Foundation was held in Gaithersburg, MD on October 2005. The meeting reviewed the current status of biomarkers for early- and advanced-stage melanoma and addressed some of the challenges scientists and clinicians face as they unravel the biology of melanoma and try to apply these findings to patient care. Specifically, the participants focused on molecular changes associated with melanoma progression, potential diagnostic and prognostic markers emerging from molecular profiling studies, and new treatment targets for current and future clinical trials. They also highlighted the ongoing challenges about translational research in melanoma, including availability of tissue resources, and summarized the status of nevus and melanoma tissue microarrays, recently developed as a collaborative project between the melanoma research community and the NCI. The meeting report is intended to provide a perspective on emerging scientific approaches in translational research that can enhance the progress in discovery and validation of markers for melanoma. (Cancer Res 2006; 66(22): 10652-7).

SAGE Identification and Fluorescence Imaging Analysis of Genes and Transcripts in Melanomas and Precursor Lesions

Melanomas of sporadic and familial origin develop in a stepwise fashion in approximately 40-80% of all cases; yet, the genetic events governing the progression from nevocytic precursor lesions to early and advanced-stage melanomas remain largely unknown. In the present study, we provide an analysis of genes that were identified in four recently generated primary and metastatic melanoma Serial Analysis of Gene Expression (SAGE) libraries. In addition to SAGE tags corresponding to transcripts with unknown function, or to unidentified transcripts, known genes were identified that hitherto have not been shown to be expressed or have a function in early and advanced-stage melanomas and/or melanoma precursor lesions. Conducting fluorescence imaging analysis with cyanine dye-conjugated antibodies and oligonucleotides, we established the expression pattern of ATM, HEI10, PKD1, KAI11, IL-10R, and hypothetical protein FLJ11151 in nevus and melanoma specimens.