Xianshi Liu scite author profile

Fused in sarcoma (FUS), a nuclear RNA binding protein, can not only undergo liquid−liquid phase separation (LLPS) to form dynamic biomolecular condensates but also aggregate into solid amyloid fibrils which are associated with the pathology of amyotrophic lateral sclerosis and frontotemporal lobar degeneration diseases. Phosphorylation in the FUS lowcomplexity domain (FUS-LC) inhibits FUS LLPS and aggregation. However, it remains largely elusive what are the underlying atomistic mechanisms of this inhibitory effect and whether phosphorylation can disrupt preformed FUS fibrils, reversing the FUS gel/solid phase toward the liquid phase. Herein, we systematically investigate the impacts of phosphorylation on the conformational ensemble of the FUS 37−97 monomer and dimer and the structure of the FUS 37−97 fibril by performing extensive all-atom molecular dynamics simulations. Our simulations reveal three key findings: (1) phosphorylation shifts the conformations of FUS 37−97 from the β-rich, fibril-competent state toward a helix-rich, fibril-incompetent state; (2) phosphorylation significantly weakens protein−protein interactions and enhances protein−water interactions, which disfavor FUS-LC LLPS as well as aggregation and facilitate the dissolution of the preformed FUS-LC fibril; and (3) the FUS 37−97 peptide displays a high β-strand probability in the region spanning residues 52−67, and phosphorylation at S54 and S61 residues located in this region is crucial for the disruption of LLPS and aggregation of FUS-LC. This study may pave the way for ameliorating phase-separation-related pathologies via site-specific phosphorylation.

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ALS-associated A315E and A315pT variants exhibit distinct mechanisms in inducing irreversible aggregation of TDP-43_312–317 peptides

Liu

Lao

et al. 2022

Phys. Chem. Chem. Phys.

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Atomistic Insights into A315E Mutation-Enhanced Pathogenicity of TDP-43 Core Fibrils

Chen

Liu

et al. 2022

ACS Chem. Neurosci.

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The aggregation of TAR DNA-binding protein of 43 kDa (TDP-43) into fibrillary deposits is implicated in amyotrophic lateral sclerosis (ALS), and some hereditary mutations localized in the low complexity domain (LCD) facilitate the formation of pathogenic TDP-43 fibrils. A recent cryo-EM study reported the atomic-level structures of the A315E TDP-43 LCD (residues 288–319, TDP-43288–319) core fibril in which the protofilaments have R-shaped structures and hypothesized that A315E U-shaped protofilaments can readily convert to R-shaped protofilaments compared to the wild-type (WT) ones. There are no atomic structures of WT protofilaments available yet. Herein, we performed extensive all-atom explicit-solvent molecular dynamics simulations on A315E and WT protofilaments starting from both the cryo-EM-determined R-shaped and our constructed U-shaped structures. Our simulations show that WT protofilaments also adopt the R-shaped structures but are less stable than their A315E counterparts. Except for R293-E315 salt bridges, N312-F316 hydrophobic interactions and F316–F316 π–π stacking interactions are also crucial for the stabilization of the neck region of the R-shaped A315E protofilaments. The loss of R293-E315 salt bridges and the weakened interactions of N312-F316 and F316–F316 result in the reduced stability of the R-shaped WT protofilaments. Simulations starting from U-shaped folds reveal that A315E protofilaments can spontaneously convert to the cryo-EM-derived R-shaped protofilaments, whereas WT protofilaments convert to R-shape-like structures with remodeled neck regions. The R-shape-like WT protofilaments could act as intermediate states slowing down the U-to-R transition. This study reveals that A315E mutation can not only enhance the structural stability of the R-shaped TDP-43288–319 protofilaments but also promote the U-to-R transition, which provides atomistic insights into the A315E mutation-enhanced TDP-43 pathogenicity in ALS.

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ALS-Linked A315T and A315E Mutations Enhance β-Barrel Formation of the TDP-43_307–319 Hexamer: A REST2 Simulation Study

Liu

Qiao

et al. 2023

ACS Chem. Neurosci.

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Pathogenic mutations of transactivation response element DNA-binding protein 43 (TDP-43) are closely linked with amyotrophic lateral sclerosis (ALS). It was recently reported that two ALS-linked familial mutants A315T and A315E of TDP-43307–319 peptides can self-assemble into oligomers including tetramers, hexamers, and octamers, among which hexamers were suggested to form the β-barrel structure. However, due to the transient nature of oligomers, their conformational properties and the atomic mechanisms underlying the β-barrel formation remain largely elusive. Herein, we investigated the hexameric conformational distributions of the wild-type (WT) TDP-43307–319 fragment and its A315T and A315E mutants by performing all-atom explicit-solvent replica exchange with solute tempering 2 simulations. Our simulations reveal that each peptide can self-assemble into diverse conformations including ordered β-barrels, bilayer β-sheets and/or monolayer β-sheets, and disordered complexes. A315T and A315E mutants display higher propensity to form β-barrel structures than the WT, which provides atomic explanation for their enhanced neurotoxicity reported previously. Detailed interaction analysis shows that A315T and A315E mutations increase inter-molecular interactions. Also, the β-barrel structures formed by the three different peptides are stabilized by distinct inter-peptide side-chain hydrogen bonding, hydrophobic, and aromatic stacking interactions. This study demonstrates the enhanced β-barrel formation of the TDP-43307–319 hexamer by the pathogenic A315T and A315E mutations and reveals the underlying molecular determinants, which may be helpful for in-depth understanding of the ALS-mutation-induced neurotoxicity of TDP-43 protein.

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Dissecting how ALS-associated D290V mutation enhances pathogenic aggregation of hnRNPA2286–291 peptides: Dynamics and conformational ensembles

Yuan

Chen

Liu

et al. 2023

International Journal of Biological Macromolecules

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Xianshi Liu

Insights into the Atomistic Mechanisms of Phosphorylation in Disrupting Liquid–Liquid Phase Separation and Aggregation of the FUS Low-Complexity Domain

ALS-associated A315E and A315pT variants exhibit distinct mechanisms in inducing irreversible aggregation of TDP-43_312–317 peptides

Atomistic Insights into A315E Mutation-Enhanced Pathogenicity of TDP-43 Core Fibrils

ALS-Linked A315T and A315E Mutations Enhance β-Barrel Formation of the TDP-43_307–319 Hexamer: A REST2 Simulation Study

Dissecting how ALS-associated D290V mutation enhances pathogenic aggregation of hnRNPA2286–291 peptides: Dynamics and conformational ensembles

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Xianshi Liu

Insights into the Atomistic Mechanisms of Phosphorylation in Disrupting Liquid–Liquid Phase Separation and Aggregation of the FUS Low-Complexity Domain

ALS-associated A315E and A315pT variants exhibit distinct mechanisms in inducing irreversible aggregation of TDP-43312–317 peptides

Atomistic Insights into A315E Mutation-Enhanced Pathogenicity of TDP-43 Core Fibrils

ALS-Linked A315T and A315E Mutations Enhance β-Barrel Formation of the TDP-43307–319 Hexamer: A REST2 Simulation Study

Dissecting how ALS-associated D290V mutation enhances pathogenic aggregation of hnRNPA2286–291 peptides: Dynamics and conformational ensembles

Contact Info

Product

Resources

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ALS-associated A315E and A315pT variants exhibit distinct mechanisms in inducing irreversible aggregation of TDP-43_312–317 peptides

ALS-Linked A315T and A315E Mutations Enhance β-Barrel Formation of the TDP-43_307–319 Hexamer: A REST2 Simulation Study