通过动力学复制模型研究朊病毒株的构象稳定性。

Investigating the conformational stability of prion strains through a kinetic replication model.

作者信息

Zampieri Mattia, Legname Giuseppe, Altafini Claudio

机构信息

Functional Analysis Sector, International School for Advanced Studies, Trieste, Italy.

出版信息

PLoS Comput Biol. 2009 Jul;5(7):e1000420. doi: 10.1371/journal.pcbi.1000420. Epub 2009 Jul 3.

DOI:10.1371/journal.pcbi.1000420

PMID:19578427

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2697384/

Abstract

Prion proteins are known to misfold into a range of different aggregated forms, showing different phenotypic and pathological states. Understanding strain specificities is an important problem in the field of prion disease. Little is known about which PrP(Sc) structural properties and molecular mechanisms determine prion replication, disease progression and strain phenotype. The aim of this work is to investigate, through a mathematical model, how the structural stability of different aggregated forms can influence the kinetics of prion replication. The model-based results suggest that prion strains with different conformational stability undergoing in vivo replication are characterizable in primis by means of different rates of breakage. A further role seems to be played by the aggregation rate (i.e. the rate at which a prion fibril grows). The kinetic variability introduced in the model by these two parameters allows us to reproduce the different characteristic features of the various strains (e.g., fibrils' mean length) and is coherent with all experimental observations concerning strain-specific behavior.

摘要

已知朊病毒蛋白会错误折叠成一系列不同的聚集形式，呈现出不同的表型和病理状态。了解毒株特异性是朊病毒疾病领域的一个重要问题。关于哪些PrP(Sc)结构特性和分子机制决定朊病毒复制、疾病进展和毒株表型，人们知之甚少。这项工作的目的是通过一个数学模型来研究不同聚集形式的结构稳定性如何影响朊病毒复制的动力学。基于模型的结果表明，具有不同构象稳定性的朊病毒毒株在体内复制时，首先可以通过不同的断裂速率来表征。聚集速率（即朊病毒纤维生长的速率）似乎也起到了进一步的作用。这两个参数在模型中引入的动力学变异性使我们能够重现各种毒株的不同特征（例如，纤维的平均长度），并且与所有关于毒株特异性行为的实验观察结果一致。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0dd0/2697384/8bf1fdf5b837/pcbi.1000420.g001.jpg

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通过动力学复制模型研究朊病毒株的构象稳定性。

Investigating the conformational stability of prion strains through a kinetic replication model.

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