Complementation between pathological prion protein subassemblies to cross existing species barriers

Angélique Igel-Egalon, Florent Laferrière, Philippe Tixador, Mohammed Moudjou, Laetitia Herzog, Fabienne Reine, Juan Maria Torres, Hubert Laude, Human Rezaei, Vincent Béringue
. 2019-12-03; :
DOI: 10.1101/861278


AbstractBackgroundprion replication results from the autocatalytic templated assisted conversion of the host-encoded prion protein PrPCinto misfolded, polydisperse PrPSc conformers. Structurally distinct PrPScconformers can give rise to multiple prion strains. Within and between prion strains, the biological activity (replicative efficacy and specific infectivity) of PrPScassemblies is size-dependent and thus reflects an intrinsic structural heterogeneity. The contribution of such PrPScheterogeneity across species prion adaptation, – which is believed to be based on fit-adjustment between PrPSctemplate(s) and host PrPC-, has not been explored.Methodsto define the structural-to-fitness PrPSclandscape, we measured the relative capacity of size-fractionated PrPScassemblies from different prion strains to cross mounting species barriers in transgenic mice expressing foreign PrPc.Resultsin the absence of a transmission barrier, the relative efficacy of the isolated PrPScassemblies to induce the disease is superimposable to the efficacy observed in the homotypic context. However, in the presence of a transmission barrier, size fractionation overtly delays and even abrogates prion pathogenesis in both neural and extraneural, prion-permissive tissues, for reason independent of the infectivity load of the isolated assemblies. This suggests that a synergy between structurally distinct PrPScassemblies in the inoculum is requested for crossing the species barrier. We further strengthen this hypothesis by showing that altering, by serial dilution, PrPScassemblies content of unfractionated inocula reduce their specific infectivity in an aberrant manner, solely in the presence of a transmission barrier.Conclusionsour data support a mechanism whereby overcoming prion species barrier requires complementation between structurally distinct PrPScassemblies. This work provides key insight into the “quasi-species” concept applied to prions, which would not necessarily rely on prion sub-strains as constituent but on structural PrPScheterogeneity within prion population.

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