Development of a new largely scalable in vitro prion propagation method for the production of infectious recombinant prions for high resolution structural studies.

The resolution of the three-dimensional structure of infectious prions at the atomic level is pivotal to understand the pathobiology of Transmissible Spongiform Encephalopathies (TSE), but has been long hindered due to certain particularities of these proteinaceous pathogens. Difficulties related to their purification from brain homogenates of disease-affected animals were resolved almost a decade ago by the development of in vitro recombinant prion propagation systems giving rise to highly infectious recombinant prions. However, lack of knowledge about the molecular mechanisms of the misfolding event and the complexity of systems such as the Protein Misfolding Cyclic Amplification (PMCA), have limited generating the large amounts of homogeneous recombinant prion preparations required for high-resolution techniques such as solid state Nuclear Magnetic Resonance (ssNMR) imaging. Herein, we present a novel recombinant prion propagation system based on PMCA that substitutes sonication with shaking thereby allowing the production of unprecedented amounts of multi-labeled, infectious recombinant prions. The use of specific cofactors, such as dextran sulfate, limit the structural heterogeneity of the in vitro propagated prions and makes possible, for the first time, the generation of infectious and likely homogeneous samples in sufficient quantities for studies with high-resolution structural techniques as demonstrated by the preliminary ssNMR spectrum presented here. Overall, we consider that this new method named Protein Misfolding Shaking Amplification (PMSA), opens new avenues to finally elucidate the three-dimensional structure of infectious prions. Author summary Prion disorders are a group of devastating neurodegenerative diseases caused by an aberrantly folded isoform of the endogenous prion protein. The molecular mechanisms by which this proteinaceous pathogen is able to propagate in the central nervous system and cause neuronal death are poorly understood, partially due to the difficulties elucidating the three-dimensional structure of the aggregation-prone aberrant isoform or prion. Obtaining sufficient amounts of highly pure and homogeneous prions for high-resolution structural studies has been limited until now due to technical reasons. Here, we present a novel method for the production of large amounts of highly infectious recombinant prions suitable for solid state Nuclear Magnetic Resonance imaging, which could help to unveil the molecular pathogenesis of these particular pathogens.