MicroRNA-185 suppresses tumor growth and progression by targeting the Six1 oncogene in human cancers.

Homeobox genes encode transcription factors that are essential for normal development and are often dysregulated in cancers. The molecular mechanisms that cause their misregulation in cancers are largely unknown. In this study, we investigate the mechanism by which the Six1 homeobox protein, which has a crucial role during development, is frequently deregulated in several poor outcome, aggressive, metastatic adult human cancers, including breast cancer, ovarian cancer, hepatocellular carcinoma and pediatric malignancies such as rhabdomyosarcoma and Wilms' tumor. Our results reveal that miRNA-185 translationally represses Six1 by binding to its 3'-untranslated region. Analyses of ovarian cancers, pediatric renal tumors and multiple breast cancer cell lines showed decreased miR-185 expression, paralleling an increase in Six1 levels. Further investigation revealed that miR-185 impedes anchorage-independent growth and cell migration, in addition to suppressing tumor growth in vivo, implicating it to be a potent tumor suppressor. Our results indicate that miR-185 mediates its tumor suppressor function by regulating cell-cycle proteins and Six1 transcriptional targets c-myc and cyclin A1. Furthermore, we show that miR-185 sensitizes Six1-overexpressing resistant cancer cells to apoptosis in general and tumor necrosis factor-related apoptosis-inducing ligand (TRAIL)-mediated apoptosis in particular. Together, our findings suggest that the altered expression of the novel tumor suppressor miR-185 may be one of the central events that leads to dysregulation of oncogenic protein Six1 in human cancers.

Pheochromocytomas: from genetic diversity to new paradigms.

Pheochromocytomas and paragangliomas are catecholamine-secreting tumors of neural crest origin caused by germline mutations in at least six distinct genes. This genetic heterogeneity has provided a rich source for both the discovery and functional characterization of new tumor-related genes. However, the genetic repertoire of these tumors is still not fully known, and current evidence points to the existence of additional pheochromocytoma susceptibility genes. Here, the unique contributions of three hereditary models of pheochromocytoma that can advance our knowledge of the disease pathogenesis are presented. The first model, loss of succinate dehydrogenase (SDH) function, illustrates how SDHB, C, or D mutations, components of the energy metabolism pathway, serve as a unique system to explore the pervasive metabolic shift of cancer cells towards glycolysis as a source of energy (also known as the Warburg effect) in contrast to the characteristic oxidative phosphorylation of normal cells. In the second model, mechanisms of tumorigenesis distinct from classical pheochromocytoma susceptibility genes are discussed in the context of a novel putative suppressor of neural crest-derived tumors, the KIF1B beta gene. Finally, NF1 loss is highlighted as a valuable study model to investigate the cell lineage selectivity of the Egln3-mediated developmental apoptotic defect of chromaffin precursor cells. Results from these studies may offer clues to understand the tissue specificity of hereditary pheochromocytoma syndromes. These distinct hereditary disease models illustrate how genetic-driven progress has the potential to narrow current gaps in our knowledge of pheochromocytoma and paraganglioma pathogenesis.