Common Structural Traits across Pathogenic Mutants of the Human Prion Protein and Their Implications for Familial Prion Diseases
Common Structural Traits across Pathogenic Mutants of the Human Prion Protein and Their Implications for Familial Prion Diseases
Human (Hu) familial prion diseases are associated with about 40 point mutations of the gene coding for the prion protein (PrP). Most of the variants associated with these mutations are located in the globular domain of the protein. We performed 50 ns of molecular dynamics for each of these mutants t...
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Personal Name(s): | Rossetti, Giulia |
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Cong, Xiaojing / Caliandro, Rocco / Legname, Giuseppe (Corresponding Author) / Carloni, Paolo | |
Contributing Institute: |
Computational Biomedicine; IAS-5 GRS; GRS |
Published in: | Journal of molecular biology, 411 (2011) 3, S. 700 - 712 |
Imprint: |
Amsterdam [u.a.]
Elsevier
2011
|
DOI: |
10.1016/j.jmb.2011.06.008 |
Document Type: |
Journal Article |
Research Program: |
ohne Topic |
Publikationsportal JuSER |
Human (Hu) familial prion diseases are associated with about 40 point mutations of the gene coding for the prion protein (PrP). Most of the variants associated with these mutations are located in the globular domain of the protein. We performed 50 ns of molecular dynamics for each of these mutants to investigate their structure in aqueous solution. Overall, 1.6 μs of molecular dynamics data is presented. The calculations are based on the AMBER(parm99) force field, which has been shown to reproduce very accurately the structural features of the HuPrP wild type and a few variants for which experimental structural information is available. The variants present structural determinants different from those of wild-type HuPrP and the protective mutation HuPrP(E219K-129M). These include the loss of salt bridges in α2–α3 regions and the loss of π-stacking interactions in the β2–α2 loop. In addition, in the majority of the mutants, the α3 helix is more flexible and Y169 is more solvent exposed. The presence of similar traits in this large spectrum of mutations hints to a role of these fingerprints in their known disease-causing properties. Overall, the regions most affected by disease-linked mutations in terms of structure and/or flexibility are those involved in the pathogenic conversion to the scrapie form of the protein and in the interaction with cellular partners. These regions thus emerge as optimal targets for antibody- and ligand-binding studies. |