Project description:Perivascular epithelioid cell neoplasms (PEComas) are ultra-rare mesenchymal tumors lacking a molecular classification to guide therapy. Here we perform comprehensive multi-omic profiling of an unselected PEComa cohort. We identify frequent MITF rearrangements involving actin gene partners (ACTA2, ACTG1 and ACTB). Anatomical stratification reveals cyclin-dependent kinase module mutations in gynecologic tumors, whereas soft tissue, gastrointestinal, and pelvic tumors lacked mTOR pathway alterations but are enriched for TFE3/MITF rearrangements. Transcriptomic analysis defines four subtypes with distinct lineage programs—melanocytic, mesenchymal, or adipogenic—as well as unique mutational patterns and clinical behaviors. Notably, an aggressive stem-like subtype enriched for TP53/RB1 mutations exhibits high proliferation, activation of embryonic and Hedgehog signaling, immune infiltration, and resistance to mTOR inhibitors, but potential responsiveness to immunotherapy. Single-nucleus RNA sequencing reveals intra-tumoral heterogeneity within this subtype, including divergent inflammatory states. Together, these findings establish a molecular classification framework and identify actionable vulnerabilities in PEComa.

Project description:Perivascular epithelioid cell neoplasms (PEComas) are ultra-rare mesenchymal tumors lacking a molecular classification to guide therapy. Here we perform comprehensive multi-omic profiling of an unselected PEComa cohort. We identify frequent MITF rearrangements involving actin gene partners (ACTA2, ACTG1 and ACTB). Anatomical stratification reveals cyclin-dependent kinase module mutations in gynecologic tumors, whereas soft tissue, gastrointestinal, and pelvic tumors lacked mTOR pathway alterations but are enriched for TFE3/MITF rearrangements. Transcriptomic analysis defines four subtypes with distinct lineage programs—melanocytic, mesenchymal, or adipogenic—as well as unique mutational patterns and clinical behaviors. Notably, an aggressive stem-like subtype enriched for TP53/RB1 mutations exhibits high proliferation, activation of embryonic and Hedgehog signaling, immune infiltration, and resistance to mTOR inhibitors, but potential responsiveness to immunotherapy. Single-nucleus RNA sequencing reveals intra-tumoral heterogeneity within this subtype, including divergent inflammatory states. Together, these findings establish a molecular classification framework and identify actionable vulnerabilities in PEComa.

Project description:This study investigates the safety/toxicity and potential anti-tumor activity of sequential administration of nivolumab and escalating doses of the mTOR inhibitor ABI-009 in advanced Ewing’s sarcoma, PEComa, epithelioid sarcoma, desmoid tumor, chordoma, non-small cell lung cancer, small cell lung cancer, urethelial carcinoma, melanoma, renal cell carcinoma, squamous cell carcinoma of head and neck, hepatocellular carcinoma, classical Hodgkin’s lymphoma, MSI-H/dMMR metastatic colorectal cancer, and tumors with genetic mutations sensitive to mTOR inhibitors

Project description: Not available

Project description:The MiT/TFE family gene fusion proteins, such as SFPQ-TFE3, drive both epithelial (eg, translocation renal cell carcinoma, tRCC) and mesenchymal (eg, perivascular epithelioid cell tumor, PEComa) neoplasms with aggressive behavior. However, no prior mouse models for SFPQ-TFE3-related tumors exist and the mechanisms of lineage plasticity induced by this fusion remain unclear. Here, we demonstrate that constitutive murine renal expression of human SFPQ-TFE3 using Ksp Cadherin-Cre as a driver disrupts kidney development leading to early neonatal renal failure and death. In contrast, post-natal induction of SFPQ-TFE3 in renal tubular epithelial cells using Pax8 ERT-Cre induces infiltrative epithelioid tumors, which morphologically and transcriptionally resemble human PEComas. As seen in MiT/TFE fusion-driven human tumors, SFPQ-TFE3 expression is accompanied by the strong induction of mTORC1 signaling, which is partially amino acid-sensitive and dependent on increased SFPQ-TFE3-mediated RRAGC/D transcription. Remarkably, SFPQ-TFE3 expression is sufficient to induce lineage plasticity in renal tubular epithelial cells, with rapid down-regulation of the critical PAX2/PAX8 nephric lineage factors and tubular epithelial markers, and concomitant up-regulation of PEComa differentiation markers in transgenic mice, human cell line models and human tRCC. Pharmacologic or genetic inhibition of mTOR signaling downregulates expression of the SFPQ-TFE3 fusion protein and rescues nephric lineage marker expression and transcriptional activity in vitro. These data provide evidence of a potential epithelial cell-of-origin for TFE3-driven PEComas and highlight a reciprocal role for SFPQ-TFE3 and mTOR in driving lineage plasticity in the kidney, expanding our understanding of the pathogenesis of MiT/TFE-driven tumors.

Project description:MiT Fusions, TSC1–TSC2 Divergence, and Stem-like Programs Reveal Distinct Origins and Vulnerabilities in PEComa [Methylation]

Project description:We characterized the transcriptomic effects of chronic mTOR activation in aortic SMCs using a conditional genetic model to delete Tsc1 under control of a smooth muscle-specific Myh11 promoter

Project description:MiT Fusions, TSC1–TSC2 Divergence, and Stem-like Programs Reveal Distinct Origins and Vulnerabilities in PEComa [scRNA-seq]

Project description:MiT Fusions, TSC1–TSC2 Divergence, and Stem-like Programs Reveal Distinct Origins and Vulnerabilities in PEComa [RNA-seq]

Project description:We characterized the transcriptomic effects at the single cell level of chronic mTOR activation in aortic SMCs using a conditional genetic model to delete Tsc1 under control of a smooth muscle-specific Myh11 promoter