SARS-CoV-2 virions are surrounded by a lipid bilayer that contains membrane proteins such as spike, responsible for target-cell binding and virus fusion. We found that during SARS-CoV-2 infection, spike becomes lipid modified, through the sequential action of the S-acyltransferases ZDHHC20 and 9. Particularly striking is the rapid acylation of spike on 10 cytosolic cysteines within the ER and Golgi. Using a combination of computational, lipidomics, and biochemical approaches, we show that this massive lipidation controls spike biogenesis and degradation, and drives the formation of localized ordered cholesterol and sphingolipid-rich lipid nanodomains in the early Golgi, where viral budding occurs. Finally, S-acylation of spike allows the formation of viruses with enhanced fusion capacity. Our study points toward S-acylating enzymes and lipid biosynthesis enzymes as novel therapeutic anti-viral targets.
Background:The subunit-specific roles of the CCT subunits in the chaperonin, TRiC, have not been elucidated. Results: When expressed in E. coli, CCT4 and CCT5 form TRiC-like homo-oligomeric rings. Conclusion: TRiC does not require all eight CCT subunits to form functional rings. Significance: The unexpected formation of homo-oligomeric CCT rings provides clues into the assembly of TRiC as a complex.
The human chaperonin TRiC consists of eight non-identical subunits, and its protein-folding activity is critical for cellular health. Misfolded proteins are associated with many human diseases, such as amyloid diseases, cancer, and neuropathies, making TRiC a potential therapeutic target. A detailed structural understanding of its ATP-dependent folding mechanism and substrate recognition is therefore of great importance. Of particular health-related interest is the mutation Histidine 147 to Arginine (H147R) in human TRiC subunit 5 (CCT5), which has been associated with hereditary sensory neuropathy. In this paper, we describe the crystal structures of CCT5 and the CCT5-H147R mutant, which provide important structural information for this vital protein-folding machine in humans. This first X-ray crystallographic study of a single human CCT subunit in the context of a hexadecameric complex can be expanded in the future to the other 7 subunits that form the TRiC complex.
Background: Huntington disease patients show an accumulation of oligomers and fibrillar species of mutant huntingtin (mHTT). Results: Cryoelectron tomography and subvolume averaging visualizes heterogeneous mHTT oligomeric species inside the chaperonin-like CCT5 cavity.
Conclusion:The structural basis of mHTT aggregation inhibition by CCT5 is through capping of fibrils and encapsulation of oligomers. Significance: These structural mechanisms inspire the development of new strategies for inhibiting mHTT aggregation.
Background: Point mutations in two genes encoding chaperonin subunits have been implicated in neuropathies. Results: CCT4 and CCT5 proteins carrying these mutations were expressed in bacteria and investigated for their biochemical defects. Conclusion: H147R CCT5 is faulty in chaperoning function, whereas C450Y CCT4 may be defective in protein stability. Significance: These biochemical defects may be the source of these neuropathies in patients.
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