Modeling a prion protein dimer: Predictions for fibril formation

Jim Warwicker

doi:10.1006/bbrc.2000.3829

Modeling a prion protein dimer: Predictions for fibril formation

Research output: Contribution to journal › Article › peer-review

Abstract

Models of structural transition in prion protein (PrP) focus on the domain visualised by solution NMR. Accumulating evidence suggests that the adjacent and highly conserved nonpolar segment, as well as PrP-membrane interactions, should also be considered. Calculations predict that membrane-induced structural destabilisation is mediated by stabilisation of the unfolded form. Comparative analysis of PrP structures leads to a model for PrP dimerisation that incorporates the nonpolar segment. A prediction that PrP will interact with the PrP-like protein (Dpl) to form a heterodimer, but that Dpl will not form a homodimer, can be tested. Modelling is discussed in the context of ataxias associated with the expression of Dpl or truncated PrP in transgenic animals lacking wild-type PrP. A PrP(c) dimer model forms the basis for considering the geometry of PrP(Sc) fibril formation. (C) 2000 Academic Press.

Original language	English
Pages (from-to)	646-652
Number of pages	6
Journal	Biochemical and Biophysical Research Communications
Volume	278
Issue number	3
DOIs	https://doi.org/10.1006/bbrc.2000.3829
Publication status	Published - 30 Nov 2000

Keywords

Fibril formation
Molecular modelling
pH dependence
Prion protein
Transmissible spongiform encephalopathy

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10.1006/bbrc.2000.3829

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abstract = "Models of structural transition in prion protein (PrP) focus on the domain visualised by solution NMR. Accumulating evidence suggests that the adjacent and highly conserved nonpolar segment, as well as PrP-membrane interactions, should also be considered. Calculations predict that membrane-induced structural destabilisation is mediated by stabilisation of the unfolded form. Comparative analysis of PrP structures leads to a model for PrP dimerisation that incorporates the nonpolar segment. A prediction that PrP will interact with the PrP-like protein (Dpl) to form a heterodimer, but that Dpl will not form a homodimer, can be tested. Modelling is discussed in the context of ataxias associated with the expression of Dpl or truncated PrP in transgenic animals lacking wild-type PrP. A PrP(c) dimer model forms the basis for considering the geometry of PrP(Sc) fibril formation. (C) 2000 Academic Press.",

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AB - Models of structural transition in prion protein (PrP) focus on the domain visualised by solution NMR. Accumulating evidence suggests that the adjacent and highly conserved nonpolar segment, as well as PrP-membrane interactions, should also be considered. Calculations predict that membrane-induced structural destabilisation is mediated by stabilisation of the unfolded form. Comparative analysis of PrP structures leads to a model for PrP dimerisation that incorporates the nonpolar segment. A prediction that PrP will interact with the PrP-like protein (Dpl) to form a heterodimer, but that Dpl will not form a homodimer, can be tested. Modelling is discussed in the context of ataxias associated with the expression of Dpl or truncated PrP in transgenic animals lacking wild-type PrP. A PrP(c) dimer model forms the basis for considering the geometry of PrP(Sc) fibril formation. (C) 2000 Academic Press.

KW - Fibril formation

KW - Molecular modelling

KW - pH dependence

KW - Prion protein

KW - Transmissible spongiform encephalopathy

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DO - 10.1006/bbrc.2000.3829

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JF - Biochemical and Biophysical Research Communications

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Modeling a prion protein dimer: Predictions for fibril formation

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