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Cellular heterogeneity is a well-known feature of human neuroblastoma tumors and cell lines. Of the 3 phenotypes (N-, I-, and S-type) isolated and characterized, the I-type cancer stem cell of neuroblastoma is the most malignant. Here, we report that, although wild-type N-Ras protein is expressed at the same level in all 3 neuroblastoma cell phenotypes, activated N-Ras-GTP level is significantly higher in I-type cancer stem cells. When activated N-Ras levels were decreased by transfection of a dominant-negative N-Ras construct, the malignant potential of I-type cancer stem cells decreased significantly. Conversely, when weakly malignant N-type cells were transfected with a constitutively active N-Ras construct, activated N-Ras levels, and malignant potential, were significantly increased. Thus, high levels of N-Ras-GTP are required for the increased malignancy of I-type neuroblastoma cancer stem cells. Moreover, increased activation of N-Ras results from significant down-regulation of neurofibromin (NF1), an important RasGAP. This specific down-regulation is mediated by an ubiquitin-proteasome-dependent pathway. Thus, decreased expression of NF1 in I-type neuroblastoma cancer stem cells causes a high level of activated N-Ras that is, at least in part, responsible for their higher tumorigenic potential.

Increased Wild-Type N-Ras Activation by Neurofibromin Down-Regulation Increases Human Neuroblastoma Stem Cell Malignancy