BRD9 Degraders Unleash GBAF Chromatin Remodeling Activity in Synovial Sarcoma
Jinxiu Li, Mary L. Nelson, Li Li, Xiaobo Xia, Christine Stephan, Katarzyna Modzelewska, Gary Yu, Iain Mulford, Honnappa Srinivas, Xinyi Ge, Sarah McCollum, Ewin R. Jones, Yixuan Guo, Xin Chen, Gregory Hollingworth, Thomas Zoller, Ensar Halilovic, Cedric R. Clapier, Aneasha F. Whittaker-Tademy, Faheem, Tinya Abrams, Edmund Harrington, Sofia Gkountela, Giorgio G. Galli, Hans Voshol, Jason Thomas, Nathalie Carte, Xiaoyang Zhang, Katharine L. Diehl, David H. Lum, Martin Hirst, Jeffrey T. Yap, William Forrester, Bradley R. Cairns, Kevin B. JonesAbstract
Synovial sarcoma (SyS) incorporates the SS18::SSX fusion oncoprotein into GLTSCR1-containing BRG1/BRM and associated factors (GBAF) complexes, which confers a dependency on the GBAF subunit BRD9. However, SyS clinical trials with multiple BRD9 degraders failed to achieve clinically impactful remissions. Here, we identified a mechanistic framework to explain these results. BRD9 depletion served to blunt proliferation in SyS harboring minimal genomic alterations, rare in trial participants. In cultured cells, xenografts, and recombinant purified complexes, BRD9 loss did not impact GBAF assembly. Although BRD9 degradation in SyS reduced GBAF enrichment at target loci, BRD9-less complexes maintained or increased chromatin accessibility and associated gene transcription. Biochemical assays with purified recombinant GBAF demonstrated increased nucleosome sliding in the absence of BRD9. Together, these findings show that BRD9 restrains GBAF activity, with BRD9 degradation increasing enzymatic remodeling and target gene expression by fusion oncoprotein-distributed GBAFs in SyS. This subtle epigenetic disturbance creates a low hurdle for SyS to surpass, limiting the therapeutic efficacy of BRD9 degraders.