Human prion protein sequence elements impede cross-species chronic wasting disease transmission
Timothy D. Kurt, … , Qingzhong Kong, Christina J. Sigurdson
Timothy D. Kurt, … , Qingzhong Kong, Christina J. Sigurdson
Published February 23, 2015
Citation Information: J Clin Invest. 2015;125(4):1485-1496. https://doi.org/10.1172/JCI79408.
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Research Article Infectious disease Neuroscience

Human prion protein sequence elements impede cross-species chronic wasting disease transmission

Abstract

Chronic wasting disease (CWD) is a fatal prion disease of North American deer and elk and poses an unclear risk for transmission to humans. Human exposure to CWD occurs through hunting activities and consumption of venison from prion-infected animals. Although the amino acid residues of the prion protein (PrP) that prevent or permit human CWD infection are unknown, NMR-based structural studies suggest that the β2-α2 loop (residues 165–175) may impact species barriers. Here we sought to define PrP sequence determinants that affect CWD transmission to humans. We engineered transgenic mice that express human PrP with four amino acid substitutions that result in expression of PrP with a β2-α2 loop (residues 165–175) that exactly matches that of elk PrP. Compared with transgenic mice expressing unaltered human PrP, mice expressing the human-elk chimeric PrP were highly susceptible to elk and deer CWD prions but were concurrently less susceptible to human Creutzfeldt-Jakob disease prions. A systematic in vitro survey of amino acid differences between humans and cervids identified two additional residues that impacted CWD conversion of human PrP. This work identifies amino acids that constitute a substantial structural barrier for CWD transmission to humans and helps illuminate the molecular requirements for cross-species prion transmission.

Authors

Timothy D. Kurt, Lin Jiang, Natalia Fernández-Borges, Cyrus Bett, Jun Liu, Tom Yang, Terry R. Spraker, Joaquín Castilla, David Eisenberg, Qingzhong Kong, Christina J. Sigurdson

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Figure 4

Two elk residue substitutions in the β2-α2 loop of human PrPC enable 100% conversion by CWD prions in a cell lysate–based PMCA.

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Two elk residue substitutions in the β2-α2 loop of human PrPC enable 100...
(A) CWD-seeded conversion of human PrPC with a single M166V, E168Q, S170N, or N174T substitution showed conversion of HuPrP-168Q and HuPrP-170N. Human PrPC was not converted by CWD prions. Samples without PK show that PrPC levels were equivalent. Cer, cervid. (B) Quantification of CWD-seeded human PrPC variants relative to cervid PrPC. (C) CWD-seeded conversion of HuPrP-168Q,170N and cervid PrPC showed similar levels of conversion. (D) Quantification of CWD-seeded human PrPC variants relative to cervid PrPC. The conversion of HuPrP-168Q,170N and HuPrP-166V,168Q,170N was not significantly different than that of cervid PrPC. (E) CWD-seeded conversion of human PrPC with a single M138L, S143N, H155Y, I184V, or V203I substitution. (F) Quantification of CWD-seeded human PrPC variants relative to cervid PrPC. In A and E, the “No PrPC” lane shows untransfected RK13 cell lysate that was seeded and subjected to PMCA as a control. There was no detection of the seed as shown here. **P < 0.01, 2-tailed, unpaired Student’s t test, relative to conversion of HuPrP (n = 3–6 experimental replicates each).