SUMMARY Stress granules are mRNA-protein granules that form when translation initiation is limited and are related to pathological granules in various neurodegenerative diseases. Super-resolution microscopy reveals stable substructures referred to as cores within stress granules that can be purified. Proteomic analysis of stress granule cores reveals a dense network of protein-protein interactions, links between stress granules and human diseases, and identifies ATP-dependent helicases and protein remodelers as conserved stress granule components. ATP is required for stress granule assembly and dynamics. Moreover, multiple ATP-driven machines affect stress granules differently; with the CCT complex inhibiting stress granule assembly, while the MCM and RVB complexes promote stress granule persistence. Our observations suggest that stress granules contain a stable core structure surrounded by a dynamic shell with assembly, disassembly and transitions between the core and shell modulated by numerous protein and RNA remodeling complexes.
SUMMARY Stress granules are mRNA-protein assemblies formed from nontranslating mRNAs. Stress granules are important in the stress response and may contribute to some degenerative diseases. Here we describe the stress granule transcriptome of yeast and mammalian cells through RNA-Seq analysis of purified stress granule cores and smFISH validation. While essentially every mRNA, and some ncRNAs, can be targeted to stress granules, the targeting efficiency varies from <1% to >95%. mRNA accumulation in stress granules correlates with longer coding and UTR regions and poor translatability. Quantifying the RNA-Seq analysis by smFISH reveals only 10% of bulk mRNA molecules accumulate in mammalian stress granules, and only 185 genes have more than 50% of their mRNA molecules in stress granules. These results suggest stress granules may not represent a specific biological program of mRNP assembly, but instead form by condensation of nontranslating mRNPs in proportion to their length and lack of association with ribosomes.
Stress granules are non-membrane bound RNA-protein (RNP) assemblies that form when translation initiation is limited and contain a biphasic structure with stable core structures surrounded by a less concentrated shell. The order of assembly and disassembly of these two structures remains unknown. Time course analysis of granule assembly suggests that core formation is an early event in granule assembly. Stress granule disassembly is also a stepwise process with shell dissipation followed by core clearance. Perturbations that alter liquid-liquid phase separations (LLPS) driven by intrinsically disordered protein regions (IDR) of RNA binding proteins in vitro have the opposite effect on stress granule assembly in vivo. Taken together, these observations argue that stress granules assemble through a multistep process initiated by stable assembly of untranslated mRNPs into core structures, which could provide sufficient high local concentrations to allow for a localized LLPS driven by IDRs on RNA binding proteins.DOI: http://dx.doi.org/10.7554/eLife.18413.001
SummaryA dominant histopathological feature in neuromuscular diseases including amyotrophic lateral sclerosis and inclusion body myopathy is cytoplasmic aggregation of the RNA-binding protein TDP-43. Although rare protein-misfolding mutations in TDP-43 often cause protein aggregation, most patients do not have a TDP-43 mutation suggesting aggregates of wild-type TDP-43 arise by an unknown mechanism. Here we show TDP-43 is an essential protein for normal skeletal muscle formation that unexpectedly forms cytoplasmic, amyloid-like oligomeric assemblies, termed myo-granules, during skeletal muscle regeneration in mice and humans. Myo-granules bind mRNAs encoding sarcomeric proteins and are cleared as myofibers mature. Although myo-granules occur during normal skeletal muscle regeneration, myo-granules can seed TDP-43 amyloid fibrils in vitro, and are increased in a mouse model of inclusion body myopathy. Therefore, heightened assembly or decreased clearance of functionally normal myo-granules could be the source of cytoplasmic TDP-43 aggregates common to neuromuscular disease.
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