SUMMARYIn the developing retina, multipotent neural progenitors undergo unidirectional differentiation in a precise spatiotemporal order. Here we profile the epigenetic and transcriptional changes that occur during retinogenesis in mice and humans. Although some progenitor genes and cell cycle genes were epigenetically silenced during retinogenesis, the most dramatic change was derepression of cell type–specific differentiation programs. We identified developmental stage–specific super-enhancers and showed that most epigenetic changes are conserved in humans and mice. To determine how the epigenome changes during tumorigenesis and reprogramming, we performed integrated epigenetic analysis of murine and human retinoblastomas and induced pluripotent stem cells (iPSCs) derived from murine rod photoreceptors. The retinoblastoma epigenome mapped to the developmental stage when retinal progenitors switch from neurogenic to a terminal patterns of cell division. The epigenome of retinoblastomas was more similar to that of normal retina than was that of retina-derived iPSCs, and we identified retina-specific epigenetic memory.
Ewing sarcoma (EWS) is a tumor of the bone and soft-tissue that primarily affects adolescents and young adults. With current therapies, 70% of patients with localized disease survive, but patients with metastatic or recurrent disease have a poor outcome. We found that EWS cell lines are defective in DNA break repair and are sensitive to PARP inhibitors (PARPis). PARPi-induced cytotoxicity in EWS cells was 10- to 1,000-fold higher after administration of the DNA-damaging agents irinotecan or temozolomide. We developed an orthotopic EWS mouse model and performed pharmacokinetic and pharmacodynamic studies using 3 different PARPis that are in clinical development for pediatric cancer. Irinotecan administered on a low-dose, protracted schedule previously optimized for pediatric patients was an effective DNA-damaging agent when combined with PARPis; it was also better tolerated than combinations with temozolomide. Combining PARPis with irinotecan and temozolomide gave complete and durable responses in more than 80% of the mice.
Personalized cancer therapy targeting somatic mutations in patient tumors is increasingly being incorporated into practice. Other therapeutic vulnerabilities resulting from changes in gene expression due to tumor specific epigenetic perturbations are progressively being recognized. These genomic and epigenomic changes are ultimately manifest in the tumor proteome and phosphoproteome. We integrated transcriptomic, epigenomic, and proteomic/phosphoproteomic data to elucidate the cellular origins and therapeutic vulnerabilities of rhabdomyosarcoma (RMS). We discovered that alveolar RMS occurs further along the developmental program than embryonal RMS. We also identified deregulation of the RAS/MEK/ERK/CDK4/6, G/M, and unfolded protein response pathways through our integrated analysis. Comprehensive preclinical testing revealed that targeting the WEE1 kinase in the G/M pathway is the most effective approach in vivo for high-risk RMS.
Summary
Cell-based therapies to treat retinal degeneration are now being tested in clinical trials. However, it is not known if the source of stem cells is important for the production of differentiated cells suitable for transplantation. To test this, we generated iPSCs murine rod photoreceptors (r-iPSCs) and scored their ability to make retina using a standardized quantitative protocol called STEM-RET. We discovered that r-iPSCs were more efficient at producing differentiated retina than embryonic stem cells (ESCs) or fibroblast-derived iPSCs (f-iPSCs). Retinae derived from f-iPSCs had a reduction in amacrine cells and other inner nuclear layer cells. Integrated epigenetic analysis showed that DNA methylation contributes to the defects in f-iPSC retinogenesis and that rod specific CTCF insulator protein binding sites may promote retinogenes in r-iPSCs. Taken together, our data suggest that the source of stem cells are important for producing retinal neurons in 3D organ cultures.
Highlights d There are dynamic changes in chromatin compartments and looping during retinogenesis d Euchromatin and heterochromatin localization can be predicted by machine learning d Vsx2 has a cell-type-and stage-specific core regulatory circuit super-enhancer d Vsx2 core regulatory circuit super-enhancer deletion eliminates bipolar neurons
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