Published today in Science Advances, corresponding author Mondira Kundu, PhD, St. Jude Department of Cell & Molecular Biology, investigated how the protein ASPL helps regulate stress granule assembly and disassembly in cells, a process critical for protecting RNA during cellular stress.
Stress granules are droplet-like protein hubs that temporarily shield fragile RNA from cellular stresses such as toxins. VCP is a protein essential for breaking up stress granules and has been linked to neurodegenerative diseases. However, VCP has a protein partner, ASPL, whose role has been unclear until now. Scientists at St. Jude Children’s Research Hospital discovered that ASPL regulates stress granule disassembly by facilitating VCP phosphorylation. They also found ASPL facilitates stress granule assembly independent of VCP by stabilizing interactions among core stress granule proteins. The findings, published today in Science Advances, provide key insight into the link between stress granules and neurodegenerative disease.
Stress granules are carefully regulated, forming only during stresses, such as heat or infection, and disassembling once the stress is resolved. Mutations in proteins such as VCP can derail this cycle, leading to the abnormal accumulation of proteins, which causes a condition called multisystem proteinopathy.
“VCP mutations are found in patients with multisystem proteinopathy, which includes amyotrophic lateral sclerosis, frontotemporal dementia and Paget’s disease of bone,” said corresponding author Mondira Kundu, MD, PhD, St. Jude Department of Cell & Molecular Biology. “While VCP has multiple functions, its ability to disassemble RNA-protein assemblies, such as stress granules, is impaired by disease-causing mutations.”
ASPL, VCP and ULK work together to break up stress granules
After discovering that VCP and ASPL interact with ULK, another protein involved in regulating stress granule disassembly, Kundu and her team decided to dig into the relationship. “ULK regulates stress granule dynamics, so we wondered whether ASPL was also involved through its interaction with either ULK or VCP,” Kundu said.
The team found that ASPL was required for ULK to carry out its function, which is VCP’s phosphorylation (addition of a phosphate group). Phosphorylation triggers VCP to remove the keystone stress granule protein G3BP from stress granules, causing them to break up. Without VCP phosphorylation, the stress granules persist.
These findings are consistent with what occurs during multisystem proteinopathy. “Certain disease-causing VCP mutants don’t interact as well with ASPL and ULK, and also have stress granule disassembly defects,” Kundu explained. “Restoring VCP phosphorylation restores disassembly, suggesting that these mutants decrease VCP binding to ASPL and subsequent phosphorylation by ULK.”
ASPL goes solo to help assemble stress granules
The researchers, including first author Gautam Pareek, PhD, St. Jude Department Cell & Molecular Biology, discovered that ASPL not only stabilizes core stress granule proteins but also enables VCP phosphorylation, providing key insight into how stress granule dynamics links to neurodegenerative disease.
In a surprising turn, the researchers also observed that ASPL overexpression sharply increased stress granule formation. Removing ASPL resulted in smaller and slower-forming stress granules. This suggested that ASPL plays a role in stress granule assembly. But this function of ASPL did not involve VCP, so the researchers set out to tease apart how ASPL could promote the formation of stress granules on its own, independent of VCP.
“We created cell lines that express a version of ASPL that cannot bind VCP and found that these cells had no problems with granule assembly but did a poor job with disassembly,” Kundu said. “This showed us that ASPL promoted stress granule assembly, and ASPL’s interaction with VCP is important for efficient disassembly.”
The researchers discovered this mechanism was tied to G3BP. “Removing ASPL decreased interactions between stress granule components, lowering the probability of stress granules being formed,” Kundu explained. “Fluorescence recovery experiments suggested that ASPL alters G3BP’s interactions with other proteins, making the network less stable without ASPL.”
These findings add nuance to scientists’ understanding of stress granule regulation, expanding on the checks and balances that govern the process and highlighting potential pathways to disease. “A key question is whether disrupting the ASPL-VCP interaction, specifically through ASPL, can mimic multisystem proteinopathy,” Kundu said. “That’s the biggest missing link currently, and one we are exploring.”
Authors and funding
The study’s co-corresponding and co-first author is Bo Wang, Xiamen University. The other co-first authors are Gautam Pareek and Dongfang Li, St. Jude. Other authors are Joseph Basalla, Tharun Selvam Mahendran, Anurag Singh and Priya Banerjee, The State University of New York at Buffalo; and Amanda Nourse, Ravi Kalathur, Mitra Rana, Jinjun Wu, Brian Freibaum, Honghu Quan, Brian Maxwell, Yong-Dong Wang, James Messing, Yonghui Ni, Stanley Pounds, Rachayata Dharmat, Jingjun Lu, Xiujie Li-Harms, Alexandre Carisey, Shondra Pruett-Miller, J. Paul Taylor and Hong Joo Kim, St. Jude.
The study was supported by the National Institutes of Health (R01 GM132231, R01 MH115058, R35 GM138186 and R35 NS097974), the St. Jude Children’s Research Collaborative on the Biology and Biophysics of RNP Granules and the American Lebanese Syrian Associated Charities (ALSAC), the fundraising and awareness organization of St. Jude.
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