pH-Induced Misfolding Mechanism of Prion Protein: Insights from Microsecond-Accelerated Molecular Dynamics Simulations

Zhou, Shuangyan; Shi, Danfeng; Liu, Xuewei; Yao, Xiaojun; Da, Lin-Tai; Liu, Huanxiang

doi:10.1021/acschemneuro.8b00582

Cited by 12 publications

(12 citation statements)

References 70 publications

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“…Additionally, the result of secondary structure analysis proves the instability of H2 C-terminus, which fits well with the experimental results . This result is also in line with our previous work that H2 C-terminus was easily partially unfolded and was the key site for PrP misfolding …”

Section: Resultssupporting

confidence: 91%

“…Compared to experimental methods, computational molecular dynamics (MD) simulations can provide more detailed transient structural dynamics at the atomic level and the potential transition pathways as well. For the PrP system, our group has recently investigated the pH-induced misfolding mechanism of PrP by accelerated MD simulations and found that both the H2 C-terminus and the S2–H2 loop were critical sites for PrP misfolding . Protonated H187 in the H2 C-terminus is the key inducing factor in the pH-induced PrP misfolding process.…”

Section: Introductionmentioning

confidence: 99%

“…Well-tempered metadynamics simulations of 500 ns were performed for each system. The contact number ( N C ) between residue 187 and R156, Y157, P158, and F198 (Figure b) and the average ψ angle (ψ avg ) of H2 C-terminus (Figure c) were chosen as two CVs for metadynamics simulations, since these parameters were formerly reported to be crucial for the stability and structural transition of H2 C-terminus. , Specifically, N C can directly reflect the change of interactions among related residues, , and ψ avg can be employed to monitor the secondary structure change process . This investigation allowed us to construct the FESs of the PrP misfolding process based on the structural transition of H2 C-terminus, which may provide quantitative insights into the possible implications of the H2 C-terminus related function for PrP misfolding.…”

Section: Introductionmentioning

confidence: 99%

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Unraveling the Molecular Mechanism of Prion H2 C-Terminus Misfolding by Metadynamics Simulations

Liu

Wang

et al. 2020

ACS Chem. Neurosci.

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Conformational transition from the normal cellular form of prion protein (PrP C ) to the pathogenic "scrapie" form (PrP Sc ) is considered to be a key event in the occurrence of prion disease. Additionally, the H2 C-terminus is widely considered to be a vital site for PrP conformational transition, which can be used as an important region to explore the potential mechanism of PrP misfolding. Therefore, to study the misfolding mechanism of PrP, 500 ns well-tempered metadynamics simulations were performed by focusing on the H2 C-terminus of PrP. For comparison, three systems were designed in total, including PrP in neutral and acidic conditions, as well as H187R mutant. The resulting free energy surfaces (FESs) obtained from metadynamics simulations reveal that acidic conditions and H187R mutation can facilitate PrP misfolding by decreasing free energy barriers for conformational transition and forming energy stable conformational states. Further analyses aimed at H2 C-terminus show that due to the increase of positive charge on residue 187 in both acidic and H187R systems, the electrostatic repulsion of residue 187 and R136/R156 increases greatly, which disrupts the electrostatic interaction network around H2 C-terminus and exposes the hydrophobic core to the solvent. Taken together, acidic conditions and H187R mutation can accelerate PrP misfolding mainly by forming more energetically stable metastable conformations with lower free energy barriers, and electrostatic network disruption involving residue 187 drives the initial misfolding of H2 C-terminus. This study provides quantitative insight into the related function of the H2 Cterminus in the PrP misfolding process, which may guide H2 C-terminus mediated drug design in the future.

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Section: Resultssupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Unraveling the Molecular Mechanism of Prion H2 C-Terminus Misfolding by Metadynamics Simulations

Liu

Wang

et al. 2020

ACS Chem. Neurosci.

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“…Dynamic network analysis, as an effective method to extract information from the obtained molecular dynamics trajectories, has been successfully applied in protein misfolding (Zhou et al, 2019) and protein–protein interaction analysis (Sethi et al, 2009; Bai et al, 2014). Here, in order to observe the dynamic changes of the residues interaction network, 2,000 snapshots were extracted from the last 50-ns trajectory for each system.…”

Section: Methodsmentioning

confidence: 99%

Uncovering the Resistance Mechanism of Mycobacterium tuberculosis to Rifampicin Due to RNA Polymerase H451D/Y/R Mutations From Computational Perspective

Zhang

Liu

et al. 2019

Front. Chem.

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Tuberculosis is still one of the top 10 causes of deaths worldwide, especially with the emergence of multidrug-resistant tuberculosis. Rifampicin, as the most effective first-line antituberculosis drug, also develops resistance due to the mutation on Mycobacterium tuberculosis (Mtb) RNA polymerase. Among these mutations, three mutations at position 451 (H451D, H451Y, H451R) are associated with high-level resistance to rifampicin. However, the resistance mechanism of Mtb to rifampicin is still unclear. In this work, to explore the resistance mechanism of Mtb to rifampicin due to H451D/Y/R mutations, we combined the molecular dynamics simulation, molecular mechanics generalized-Born surface area calculation, dynamic network analysis, and residue interactions network analysis to compare the interaction change of rifampicin with wild-type RNA polymerase and three mutants. The results of molecular mechanics generalized-Born surface area calculations indicate that the binding free energy of rifampicin with three mutants decreases. In addition, the dynamic network analysis and residue interaction network analysis show that when H451 was mutated, the interactions of residue 451 with its adjacent residues such as Q438, F439, M440, D441, and S447 disappeared or weakened, increasing the flexibility of binding pocket. At the same time, the disappearance of hydrogen bonds between R613 and rifampicin caused by the flipping of R613 is another important reason for the reduction of binding ability of rifampicin in H451D/Y mutants. In H451R mutant, the mutation causes the binding pocket change too much so that the position of rifampicin has a large movement in the binding pocket. In this study, the resistance mechanism of rifampicin at the atomic level is proposed. The proposed drug-resistance mechanism will provide the valuable guidance for the design of antituberculosis drugs.

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“…Accelerated molecular dynamics (aMD) simulations, which add a boost potential to the system’s potential and sample enhanced conformational space 21 , 22 , have been increasingly exploited to investigate long-time dynamics and infrequent conformational changes of biomacromolecules 23 – 27 . Simulations have also confirmed the effect of the ligand in MarR family 28 .…”

Section: Introductionmentioning

confidence: 99%

Zinc-mediated conformational preselection mechanism in the allosteric control of DNA binding to the zinc transcriptional regulator (ZitR)

Zhang

et al. 2020

Sci Rep

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The zinc transcriptional regulator (ZitR) functions as a metalloregulator that fine tunes transcriptional regulation through zinc-dependent DNA binding. However, the molecular mechanism of zinc-driven allosteric control of the DNA binding to ZitR remains elusive. Here, we performed enhanced sampling accelerated molecular dynamics simulations to figure out the mechanism, revealing the role of protein dynamics in the zinc-induced allosteric control of DNA binding to ZitR. The results suggest that zinc-free ZitR samples distinct conformational states, only a handful of which are compatible with DNA binding. Remarkably, zinc binding reduces the conformational plasticity of the DNA-binding domain of ZitR, promoting the population shift in the ZitR conformational ensemble towards the DNA binding-competent conformation. Further co-binding of DNA to the zinc–ZitR complex stabilizes this competent conformation. These findings suggest that ZitR–DNA interactions are allosterically regulated in a zinc-mediated conformational preselection manner, highlighting the importance of conformational dynamics in the regulation of transcription factor family.

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pH-Induced Misfolding Mechanism of Prion Protein: Insights from Microsecond-Accelerated Molecular Dynamics Simulations

Cited by 12 publications

References 70 publications

Unraveling the Molecular Mechanism of Prion H2 C-Terminus Misfolding by Metadynamics Simulations

Unraveling the Molecular Mechanism of Prion H2 C-Terminus Misfolding by Metadynamics Simulations

Uncovering the Resistance Mechanism of Mycobacterium tuberculosis to Rifampicin Due to RNA Polymerase H451D/Y/R Mutations From Computational Perspective

Zinc-mediated conformational preselection mechanism in the allosteric control of DNA binding to the zinc transcriptional regulator (ZitR)

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