Time-resolved proteomics reveals five modules of stress granule disassembly and identifies SYNCRIP as a late-phase clearance factor

Stress granules

β-propeller protein-associated neurodegeneration (BPAN) is a rare X-linked neurodegenerative disorder caused by mutations in the WDR45 gene, yet its molecular mechanisms remain poorly understood. Here, we identify a role for WDR45 in stress granule (SG) disassembly, mediated through its phase separation with Caprin-1. We demonstrate that WDR45 forms gel-like condensates via its WD5 domain, which competitively displaces G3BP1 from Caprin-1 to promote SG disassembly. BPAN-associated WDR45 mutations impair condensate formation and Caprin-1 interaction, leading to delayed SG disassembly, which correlates with earlier disease onset. WDR45 depletion also exacerbates amyotrophic lateral sclerosis-associated pathological SGs, highlighting its broader relevance to neurodegenerative diseases. Using iPSC-derived midbrain neurons from a BPAN patient, we demonstrate delayed SG recovery, directly linking WDR45 dysfunction to neurodegeneration. These findings establish WDR45 as a critical regulator of SG dynamics, uncover a potential molecular basis of BPAN pathogenesis, and identify therapeutic targets for neurodegenerative diseases associated with SG dysregulation.

Stress granules (SGs) are dynamic RNA-protein assemblies that form in response to cellular stress and must be efficiently disassembled to restore normal cell function. Valosin-containing protein (VCP), an enzyme implicated in neurodegenerative diseases, is essential for SG disassembly, but whether and how this process is coordinated with SG assembly remains unclear. Here, we identify the VCP cofactor, Alveolar soft part sarcoma locus (ASPL) as a key regulator linking SG assembly and disassembly. ASPL promotes SG assembly by facilitating biomolecular condensation of Ras guanosine triphosphatase–activating protein-binding protein (G3BP) and stabilizing its interactions with other SG proteins. ASPL also facilitates phosphorylation and activation of VCP by UNC-51-like kinases 1 and 2 (ULK1/2), enabling G3BP extraction and efficient SG disassembly. Pathogenic VCP mutations that disrupt ASPL binding impair SG disassembly, a defect rescued by phosphomimetic mutations or ASPL depletion. Our findings suggest that disruptions in the ASPL-VCP interaction uncouple SG assembly and disassembly, representing a potential mechanism underlying VCP-associated neurodegenerative diseases.

Stress granules and P-bodies are conserved assemblies of nontranslating mRNAs in eukaryotic cells that can be related to RNA–protein aggregates found in some neurodegenerative diseases. Herein, we examine how the Hsp70/Hsp40 protein chaperones affected the assembly and disassembly of stress granules and P-bodies in yeast. We observed that Hsp70 and the Ydj1 and Sis1 Hsp40 proteins accumulated in stress granules and defects in these proteins led to decreases in the disassembly and/or clearance of stress granules. We observed that individual Hsp40 proteins have different effects on stress granules with defects in Ydj1 leading to accumulation of stress granules in the vacuole and limited recovery of translation following stress, which suggests that Ydj1 promotes disassembly of stress granules to promote translation. In contrast, defects in Sis1 did not affect recovery of translation, accumulated cytoplasmic stress granules, and showed reductions in the targeting of stress granules to the vacuole. This demonstrates a new principle whereby alternative disassembly machineries lead to different fates of components within stress granules, thereby providing additional avenues for regulation of their assembly, composition, and function. Moreover, a role for Hsp70 and Hsp40 proteins in stress granule disassembly couples the assembly of these stress responsive structures to the proteostatic state of the cell.

Spatio-Temporal Proteomic Analysis of Stress Granule Disassembly Using APEX Reveals Regulation by SUMOylation and Links to ALS Pathogenesis

Spatiotemporal Proteomic Analysis of Stress Granule Disassembly Using APEX Reveals Regulation by SUMOylation and Links to ALS Pathogenesis

Stress granules are membraneless protein- and mRNA-rich organelles that form in response to perturbations in environmental conditions. Stress granule formation is reversible, and persistent stress granules have been implicated in a variety of neurodegenerative disorders, including amyotrophic lateral sclerosis. However, characterization of the factors involved in dissolving stress granules is incomplete. Many stress granule proteins contain prion-like domains (PrLDs), some of which have been linked to stress granule formation. Here, we demonstrate that the PrLD-containing yeast protein kinase Sky1 is a stress granule component. Sky1 is recruited to stress granules in part via its PrLD, and Sky1’s kinase activity regulates timely stress granule disassembly during stress recovery. This effect is mediated by phosphorylation of the stress granule component Npl3. Sky1 can compensate for defects in chaperone-mediated stress granule disassembly and vice-versa, demonstrating that cells have multiple overlapping mechanisms for re-solubilizing stress granule components.

The TRAnsport Protein Particle (TRAPP) complex controls multiple membrane trafficking steps and is strategically positioned to mediate cell adaptation to diverse environmental conditions, including acute stress. We have identified the TRAPP complex as a component of a branch of the integrated stress response that impinges on the early secretory pathway. The TRAPP complex associates with and drives the recruitment of the COPII coat to stress granules (SGs) leading to vesiculation of the Golgi complex and arrest of ER export. The relocation of the TRAPP complex and COPII to SGs only occurs in cycling cells and is CDK1/2-dependent, being driven by the interaction of TRAPP with hnRNPK, a CDK substrate that associates with SGs when phosphorylated. In addition, CDK1/2 inhibition impairs TRAPP complex/COPII relocation to SGs while stabilizing them at ER exit sites. Importantly, the TRAPP complex controls the maturation of SGs. SGs that assemble in TRAPP-depleted cells are smaller and are no longer able to recruit RACK1 and Raptor, two TRAPP-interactive signaling proteins, sensitizing cells to stress-induced apoptosis.

Pharmacological inhibition of DEAD-Box RNA Helicase 3 attenuates stress granule assembly

SummaryStress granules are biomolecular condensates that form in response to environmental stress and disassemble once normal conditions are restored. However, when disassembly fails, stress granules can persist and solidify. While stress granule solidification has been well documented, the cellular mechanisms underlying the transition from reversible to persistent stress granules remain unclear. Persistent stress granules can seed the formation of pathological aggregates, such as TDP-43 in amyotrophic lateral sclerosis1, 2. Although amyloid and tau aggregates are hallmarks of Alzheimer’s disease, a subset of patients also develop TDP-43 deposits, suggesting a possible role for stress granule solidification in Alzheimer’s disease progression3–5. Despite theoretical models explaining why persistence and ensuing solidification occurs, strong in vivo evidence is lacking6. Here we show that competition for limited chaperone resources drive stress granule persistence. In the presence of TDP-43 aggregates or yeast amyloid proteins called prions, stress granule disassembly is slowed or halted disassembly. Using yeast prions as a model, we show that the addition of chaperones, specifically the AAA+ ATPase molecular chaperone, Hsp104, resulted in resumption of stress granule disassembly. Our results demonstrate that the competition for shared resources, such as molecular chaperones, can limit stress granule disassembly. We suspect that the presence of pathological aggregates results in resource competition within the aging brain, contributing to the persistence of stress granules and their subsequent solidification and aggregation.

Stress granules

Stress granules are dynamic biomolecular condensates of proteins and non‐translating RNAs that form when translation is inhibited during stress. Stress conditions associated with disease including ER dysfunction, toxic metalloids, and inflammatory factors induce stress granule formation. Stress granules disassemble when translation resumes during the recovery from stress. Aberrant, cytotoxic stress granules are implicated in degenerative diseases of the nervous, muscular and skeletal systems. Yet, the mechanisms underlying stress granule dynamicity are not well understood. A growing body of research suggests that the ubiquitin‐proteasome system regulates the formation and disassembly of stress granules. Valosin‐containing protein (VCP) is a homohexameric AAA+ ATPase that functions as a ubiquitin‐binding protein segregase in protein quality control and general protein degradation pathways in the ubiquitin‐proteasome system. Prior research demonstrated that VCP is an important mediator of stress granule disassembly. Our recent work suggests an additional role for VCP in stress granule assembly. By imaging single mRNA molecules in living and fixed human cells, we determined that VCP and other members of the ribosome‐associated quality control pathway (i.e. listerin, nuclear export mediator factor, and the proteasome) are critical for the release of specific mRNAs from translation complexes and localization to stress granules. Overexpression of VCP alleles associated with amyotrophic lateral sclerosis and frontotemporal dementia caused increased mRNA localization to stress granules. Thus, understanding the molecular mechanisms by which VCP regulates stress granules will be important for discovering its role in disease. This research will contribute to our knowledge of how defects in stress granules and the ubiquitin‐proteasome system drive human degenerative diseases and suggest potential diagnostic and therapeutic strategies.

Dynein motor contributes to stress granule dynamics in primary neurons

Molecular mechanisms of stress granule assembly and disassembly

To survive under adverse conditions, plants form stress granules (SGs) to temporally store mRNA and halt translation as a primary response. Dysregulation in SG disassembly can have detrimental effects on plant survival after stress release, yet the underlying mechanism remains poorly understood. Using Arabidopsis as a model system, we demonstrate that the β subunit of adaptor protein (AP) -3 complex (AP-3β) interacts with the SG core RNA-binding proteins Tudor staphylococcal nuclease 1/2 (TSN1/2) both in vitro and in vivo. We also show that AP-3β is rapidly recruited to SGs upon heat induction and plays a key role in disassembling SGs during stress recovery. Genetic evidences support that AP-3β serves as an adaptor to recruit the 19S regulatory particle (RP) of the proteasome to SGs. Notably, the 19S RP promotes SG disassembly through RP-associated deubiquitylation, independent of its proteolytic activity. This deubiquitylation process of SG components is crucial for translation reinitiation and growth recovery after heat release. Our findings uncover a previously unexplored role of the 19S RP in regulating SG disassembly and highlights the importance of endomembrane proteins in supporting RNA granule dynamics in plants.