h Phenotypic plasticity involves a process in which cells transiently acquire phenotypic traits of another lineage. Two commonly studied types of phenotypic plasticity are epithelial-mesenchymal transition (EMT) and mesenchymal-epithelial transition (MET). In carcinomas, EMT drives invasion and metastatic dissemination, while MET is proposed to play a role in metastatic colonization. Phenotypic plasticity in sarcomas is not well studied; however, there is evidence that a subset of sarcomas undergo an MET-like phenomenon. While the exact mechanisms by which these transitions occur remain largely unknown, it is likely that some of the same master regulators that drive EMT and MET in carcinomas also act in sarcomas. In this study, we combined mathematical models with bench experiments to identify a core regulatory circuit that controls MET in sarcomas. This circuit comprises the microRNA 200 (miR-200) family, ZEB1, and GRHL2. Interestingly, combined expression of miR-200s and GRHL2 further upregulates epithelial genes to induce MET. This effect is phenocopied by downregulation of either ZEB1 or the ZEB1 cofactor, BRG1. In addition, an MET gene expression signature is prognostic for improved overall survival in sarcoma patients. Together, our results suggest that a miR-200, ZEB1, GRHL2 gene regulatory network may drive sarcoma cells to a more epithelial-like state and that this likely has prognostic relevance. P henotypic plasticity is defined as the reversible conversion of cellular phenotypes from one state to another. The two most commonly studied types of plasticity are epithelial-mesenchymal transition (EMT) and the reverse, mesenchymal-epithelial transition (MET). These phenotypic transitions play important roles in normal development (reviewed in references 1 to 4) and wound healing (reviewed in reference 5); however, similar pathways and gene expression programs can also be coopted by the cell during fibrosis (reviewed in references 6 to 8) and carcinoma progression (reviewed in references 9 to 12). In the context of carcinoma progression, a subset of cells within the tumor are thought to undergo an EMT, which enables those cells to break free from the tumor mass via loss of cell-cell adhesions (13,14) and upregulate invasive programs that facilitate dissemination (13). In addition to these phenotypic changes, EMT also contributes to alterations in cancer cell metabolism (10), drug resistance (15, 16), tumor initiation ability (17, 18), and perhaps even host immune evasion (19). EMT is often accompanied by downregulation of proliferation (20, 21), and, in some cases, MET is important for reinitiation of proliferation during metastatic colonization (22). It is important to note that as the field of phenotypic plasticity has matured, particularly in the context of carcinoma progression, EMT and MET have become recognized as more of a spectrum of phenotypes, rather than discrete states of fully differentiated epithelial and mesenchymal phenotypes. These metastable, or hybrid, E/M transition states have been obs...
