Summary
Chondroitin sulfate proteoglycan 4 (CSPG4), a transmembrane proteoglycan originally identified as a highly immunogenic tumor antigen on the surface of melanoma cells, is associated with melanoma tumor formation and poor prognosis in certain melanomas and several other tumor types. The complex mechanisms by which CSPG4 affects melanoma progression have started to be defined, in particular the association with other cell surface proteins and receptor tyrosine kinases (RTKs) and its central role in modulating the function of these proteins. CSPG4 is essential to the growth of melanoma tumors through its modulation of integrin function and enhanced growth factor receptor-regulated pathways including sustained activation of ERK 1,2. This activation of integrin, RTK, and ERK 1,2 function by CSPG4 modulates numerous aspects of tumor progression. CSPG4 expression has further been correlated to resistance of melanoma to conventional chemotherapeutics. This review outlines recent advances in our understanding of CSPG4-associated cell signaling, describing the central role it plays in melanoma tumor cell growth, motility, and survival, and explores how modifying CSPG4 function and protein–protein interactions may provide us with novel combinatorial therapies for the treatment of advanced melanoma.
Activation of the Sonic Hedgehog (Shh) pathway and increased expression of Gli1 play an important role in proliferation and transformation of granule cell progenitors (GCPs) in the developing cerebellum. Medulloblastomas arising from cerebellar GCPs are frequently driven by Shh pathway-activating mutations, however molecular mechanisms of Shh pathway dysregulation and transformation of neural progenitors remain poorly defined. We report that the transcription factor and oncogene Snail1 (Sna1) is directly induced by Shh pathway activity in GCPs, murine medulloblastomas, and human medulloblastoma cells. Enforced expression of Sna1 was sufficient to induce GCPs and medulloblastoma cell proliferation in the absence of Shh/Gli1 exposure. Additionally, enforced expression of Sna1 increased transformation of medulloblastoma cells in vitro and in vivo. Analysis of potential Sna1 targets in neural cells revealed a novel Sna1 target, N-Myc, a transcription factor known to play a role in Shh-mediated GCP proliferation and medulloblastoma formation. We found that Sna1 directly induced transcription of N-Myc in human medulloblastoma cells, and that depletion of N-Myc ablated the Sna1-induced proliferation and transformation. Taken together, these results provide further insight into the mechanism of Shh-induced transformation of neural progenitor cells and suggest that induction of Sna1 may serve to amplify the oncogenic potential of Shh pathway activation through N-Myc induction.
Chondroitin sulfate proteoglycan 4 (CSPG4) is a cell surface proteoglycan that enhances malignant potential in melanoma and several other tumor types. CSPG4 functions as a transmembrane scaffold in melanoma cells to activate oncogenic signaling pathways such as focal adhesion kinase (FAK) and extracellular signal regulated kinases 1,2, that control motility, invasion and anchorage independent growth. Here, we demonstrate that CSPG4 promotes directional motility and anchorage independent growth of melanoma cells by organizing and positioning a signaling complex containing activated FAK to lipid rafts within the plasma membrane of migrating cells. This FAK-containing signal transduction platform, which consists of syntenin-1, active Src and caveolin-1 requires the cytoplasmic domain of CSPG4 for assembly. Enhanced directional motility promoted by this complex also requires a CSPG4 transmembrane cysteine residue C2230. Substituting C2230 with alanine (CSPG4C2230A) still permits assembly of the signaling complex, however Src remains in an inactive state. CSPG4C2230A also fails to promote anchorage independent growth and activation of extracellular signal regulated kinases 1,2. Therapies that target the transmembrane domain of CSPG4 could be a novel strategy for limiting progression by disrupting its function as a compartmentalized motogenic and growth-promoting oncogenic signaling node.
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