Pathogenicity, strain properties and interspecies transmission capacity of pure recombinant prion protein assemblies

Abstract

AbstractThe pathogenicity of fibrillar assemblies derived from bacterially expressed recombinant prion protein (rPrP) has been key to the demonstration that prions are infectious proteins responsible for human and animal transmissible spongiform encephalopathies. Yet, their use in identifying which structural PrP features are important for prion biology, including strain properties and capacity to transmit between species, has been hampered by their limited transmissibility de novo. We report the generation of prions with distinct biological characteristics from rPrP assemblies differing only in their primary structure (hamster, mouse and human amino acid sequence). These rPrP assemblies were transmissible to transgenic mice expressing hamster PrP, causing a clinical disease at full attack rate, brain deposition of pathological prion protein PrPScand spongiform degeneration. Their adaptation process on serial sub-passaging seemed to depend, as for genuine prions, on the presence of a species/transmission barrier, due notably to PrP sequence mismatch. Remarkably, one of the strains obtained is an unprecedented shortened prion, lacking the 90-140 amino-acid region which is believed to be key to infectivity and structural stability of disease-associated PrP assemblies. Finally, we provide evidence that rPrP prionogenicity lies in the structural organization and/or heterogeneity of the rPrP assemblies. These preparations of rPrP offer unprecedented opportunities for meaningful studies correlating the dynamicity and structures of PrPScassemblies to prion pathobiology.Author summaryPrions are infectious proteins, causing rapidly progressive neurodegenerative diseases in animals and humans. They are formed from the assisted-refolding and aggregation of the host-encoded prion protein (PrP). During the propagation of the disease, pathological PrP forces normal PrP to adopt its own conformation by a self-templating process. In infected host, different pathological structures of PrP or strains are found, causing diseases with specific biological phenotypes. Prions can also transmit between species. This capacity is limited by a species barrier, which critically depends on the infecting strain and PrP primary structure. How strain biological information is encoded in PrP structural fold remains unknown. We describe here the generation of differentbona fideprion strains with markedly distinct adaptation capacities by transmission of refolded assemblies derived from bacterially-derived recombinant PrP (rPrP) of different species. We provide evidence that pathogenicity lies in the structural organization and/or heterogeneity of rPrP assemblies. Pathological PrP from one of the generated strains exhibited unique molecular features, including absence of domains that are thought to be key to prion infectivity, according to most recent ultrastructural studies. Our findings provide new insights for generating prion infectious material and resolving mechanisms of infectivity acquisition during PrP conversion process.