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Nuclear domains (NDs)—such as nucleoli or nuclear speckles—are membraneless, organelle-like compartments that concentrate and retain nuclear proteins. Despite their ubiquitous presence in the cell, the organization, regulation, and functions of many NDs remain poorly understood. The B-body is a prominent nuclear domain observed in developing flight muscles of Drosophila. In this study, we expand the understanding of B-body composition and function. We identify several additional RNA-binding proteins (RBPs) as B-body components and show that some proteins can dynamically disappear from this ND. We further demonstrate that the B-body contains an RNA component, which was identified as the long non-coding RNA hsrω. Genetic analyses reveal that hsrω acts as a structural scaffold for the B-body, and its depletion leads to B-body disassembly. In contrast, loss of the resident protein Bruno (Bru), a splicing factor, does not compromise B-body integrity. Finally, we show that imbalance in the hsrω/Bru ratio promotes Bru aggregation, suggesting that the B-body plays a role in maintaining nuclear protein homeostasis. 

Abstract Sequencing of human patient tumors has identified recurrent missense mutations in genes encoding core histones. We report that mutations that convert histone H3 amino acid 50 from a glutamate to a lysine (H3E50K) support an oncogenic phenotype. Expression of H3E50K is sufficient to transform human cells as evidenced by an increase in cell migration and invasion, and an increase in proliferation and clonogenicity. H3E50K also increases the invasive phenotype in the context of co-occurring BRAF mutations, which are present in patient tumors characterized by H3E50K. H3E50 lies on the globular domain surface in a region that contacts H4 within the nucleosome. We find that H3E50K selectively increases chromatin accessibility and perturbs proximal H3 post-translational modifications including H3K27me3; together these changes to chromatin dynamics dysregulate gene expression to support the epithelial-to-mesenchymal transition. Functional studies using Saccharomyces cerevisiae reveal that, while yeast cells that express H3E50K as the sole copy of histone H3 show sensitivity to cellular stressors, including caffeine, H3E50K cells display some genetic interactions that are distinct from the characterized H3K36M oncohistone yeast model. Taken together, these data suggest that additional H3 mutations have the potential to support oncogenic activity and function through distinct mechanisms that dysregulate gene expression.