Highly Promiscuous Nature of Prion Polymerization

Natallia Makarava,Cheng-I Lee,Valeriy G Ostapchenko,Ilia V Baskakov

doi:10.1074/jbc.m704926200

Natallia Makarava, Cheng-I Lee + Show 2 more

Open Access

https://doi.org/10.1074/jbc.m704926200

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Abstract

The primary structure of the prion protein (PrP) is believed to be the key factor in regulating the species barrier of prion transmission. Because the strength of the species barrier was found to be affected by the prion strain, the extent to which the barrier can indeed be attributed to differences in the PrP primary structures of either donor and acceptor species remains unclear. In this study, we exploited the intrinsic property of PrP to polymerize spontaneously into disease-related amyloid conformations in the absence of a strain-specified template and analyzed polymerization of mouse and hamster full-length recombinant PrPs. Unexpectedly, we found no evidence of species specificity in cross-seeding polymerization assays. Even when both recombinant PrP variants were present in mixtures, preformed mouse or hamster fibrils displayed no selectivity in elongation reactions and consumed equally well both homologous and heterologous substrates. Analysis of individual fibrils revealed that fibrils can elongate in a bidirectional or unidirectional manner. Our work revealed that, in the absence of a cellular environment, post-translational modifications, or strain-specified conformational constraints, PrP fibrils are intrinsically promiscuous and capable of utilizing heterologous PrP variants as a substrate in a highly efficient manner. This study suggests that amyloid structures are capable of accommodating local perturbations arising because of a mismatch in amino acid sequences and highlights the promiscuous nature of the self-propagating activity of amyloid fibrils.

Highlights

Depend primarily on the differences in the amino acid sequence of the two PrP3 isoforms, PrPSc of the donor species and PrPC of the host [2, 3]
Lack of Species Specificity in Mo and Ha Fibril Formation— The species barrier for prion transmission between Syrian hamster and mouse has been well established in previous studies
The species specificity was primarily attributed to differences in the primary structure of Ha and Mo prion protein (PrP) variants (Mo and Ha PrPs are different at eight residues within the amyloidogenic region 90 –231)

Summary

The abbreviations used are

PrP, prion protein; PrPC, normal cellular isoform of the prion protein; PrPSc, abnormal, disease-associated isoform of the prion protein; rPrP, recombinant PrP; Mo, mouse; Ha, hamster; AFFM, atomic force fluorescence microscopy; PK, proteinase K; ThT, thioflavine T; CJD, Creutzfeld-Jakob disease; MES, 4-morpholineethanesulfonic acid; GdnHCl, guanidine hydrochloride; Ab, antibody; AFM, atomic force microscopy; TSE, transmissible spongiform encephalopathy. Species Specificity of Prion Conversion length rPrP mimics the species specificity of prion replication in the absence of a cellular environment, PrP glycosylation, or strain-specified conformational constraints. We found no evidence of species specificity in cross-seeding polymerization assays that utilized mouse (Mo) and Syrian hamster (Ha) rPrPs. Even when Mo and Ha PrPs were present together in mixtures, rPrPs showed no selectivity in supporting elongation of fibrils made up of homologous or heterologous seeds. Our data strongly indicate that amyloid structures are intrinsically promiscuous, that the differences in PrP primary structure are not sufficient to block fibril growth in cross-seeded reactions, and that other factors such as strain-specified conformational constraints, species-specific glycosylation status, or hostencoded factors should be involved in regulating the species barrier

EXPERIMENTAL PROCEDURES

RESULTS

DISCUSSION