BackgroundETS transcription factors regulate important signaling pathways involved in cell differentiation and development in many tissues and have emerged as important players in prostate cancer. However, the biological impact of ETS factors in prostate tumorigenesis is still debated.Methodology/Principal FindingsWe performed an analysis of the ETS gene family using microarray data and real-time PCR in normal and tumor tissues along with functional studies in normal and cancer cell lines to understand the impact in prostate tumorigenesis and identify key targets of these transcription factors. We found frequent dysregulation of ETS genes with oncogenic (i.e., ERG and ESE1) and tumor suppressor (i.e., ESE3) properties in prostate tumors compared to normal prostate. Tumor subgroups (i.e., ERGhigh, ESE1high, ESE3low and NoETS tumors) were identified on the basis of their ETS expression status and showed distinct transcriptional and biological features. ERGhigh and ESE3low tumors had the most robust gene signatures with both distinct and overlapping features. Integrating genomic data with functional studies in multiple cell lines, we demonstrated that ERG and ESE3 controlled in opposite direction transcription of the Polycomb Group protein EZH2, a key gene in development, differentiation, stem cell biology and tumorigenesis. We further demonstrated that the prostate-specific tumor suppressor gene Nkx3.1 was controlled by ERG and ESE3 both directly and through induction of EZH2.Conclusions/SignificanceThese findings provide new insights into the role of the ETS transcriptional network in prostate tumorigenesis and uncover previously unrecognized links between aberrant expression of ETS factors, deregulation of epigenetic effectors and silencing of tumor suppressor genes. The link between aberrant ETS activity and epigenetic gene silencing may be relevant for the clinical management of prostate cancer and design of new therapeutic strategies.
The aureolic acid antibiotic mithramycin (MTM) binds selectively to GC-rich DNA sequences and blocks preferentially binding of proteins, like Sp1 transcription factors, to GC-rich elements in gene promoters. Genetic approaches can be applied to alter the MTM biosynthetic pathway in the producing microorganism and obtain new products with improved pharmacological properties. Here, we report on a new analog, MTM SDK, obtained by targeted gene inactivation of the ketoreductase MtmW catalyzing the last step in MTM biosynthesis. SDK exhibited greater activity as transcriptional inhibitor compared to MTM. SDK was a potent inhibitor of Sp1-dependent reporter activity and interfered minimally with reporters of other transcription factors, indicating that it retained a high degree of selectivity toward GC-rich DNA-binding transcription factors. RT–PCR and microarray analysis showed that SDK repressed transcription of multiple genes implicated in critical aspects of cancer development and progression, including cell cycle, apoptosis, migration, invasion and angiogenesis, consistent with the pleiotropic role of Sp1 family transcription factors. SDK inhibited proliferation and was a potent inducer of apoptosis in ovarian cancer cells while it had minimal effects on viability of normal cells. The new MTM derivative SDK could be an effective agent for treatment of cancer and other diseases with abnormal expression or activity of GC-rich DNA-binding transcription factors.
Background: The stromal vascular fraction (SVF) is a heterogeneous cell population derived from the adipose tissue. There is still a lack of information concerning the characterization of the cell subpopulations constituting the SVF as well as its mesenchymal and haematopoietic potential. Furthermore there are great variations in its phenotypical characterization.
Deregulated expression of ETS transcription factors has emerged as an important event in prostate cancer pathogenesis. Here we show that the expression of epithelial-specific ETS (ESE)-3 factor is frequently reduced at the RNA and protein level in prostate cancer clinical samples compared to normal prostate. In PC3 and DU145 cells, ESE-3 was silenced by methylation of an evolutionarily conserved CpG site in its promoter and treatment with 5-aza-2 0 -deoxycytidine restored its expression. In a prostate epithelial cell transformation model, methylation of this site was inversely correlated with ESE-3 expression and occurred only in Ras-transformed and tumorigenic cells and not in normal and immortalized cells suggesting that ESE-3 silencing was functionally linked to oncogenic transformation. Consistent with a tumor suppressor function, re-expression of ESE-3 in prostate cancer cells inhibited clonogenic survival and induced apoptotic cell death. ESE-3 increased the level of procaspase-3, a key element in the apoptotic cascade. This effect was mediated at the transcriptional level by direct binding of ESE-3 to the caspase-3 promoter. Collectively, our findings implicate ESE-3 as a candidate tumor suppressor in prostate cancer. Decreased expression of ESE-3 may result in loss of important regulatory mechanisms in prostate epithelial cells and contribute to the pathogenesis of prostate cancer.
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