Convergent generation of atypical prions in knock-in mouse models of genetic prion disease

Most cases of human prion disease arise due to spontaneous misfolding of wild-type or mutant prion protein. Though recapitulating spontaneous prion conversion in animal models has proven challenging, transgenic mice expressing the misfolding-prone bank vole prion protein (BVPrP) recreate certain key aspects of sporadic and genetic prion disease. However, it remains unclear whether spontaneous prion generation can occur in the absence of protein over-expression and how disease-causing mutations affect prion strain properties. To address these issues, we generated knock-in mice expressing physiological levels of either wild-type or mutant BVPrP with isoleucine at codon 109. While mice expressing wild-type BVPrP remained free from neurological disease, a subset of knock-in mice expressing BVPrP with mutations that cause either fatal familial insomnia (D178N) or familial Creutzfeldt-Jakob disease (E200K) developed progressive neurological illness. Brains from spontaneously ill knock-in mice contained prion disease-specific neuropathological changes as well as atypical protease-resistant prion protein. Moreover, brain extracts from spontaneously ill D178N- or E200K-mutant BVPrP knock-in mice transmitted disease to mice expressing wild-type BVPrP. Surprisingly, the properties of the D178N- and E200K-mutant prions appeared identical both pre- and post-transmission, suggesting that both mutations guide the formation of a highly similar atypical prion strain. These findings imply that knock-in mice expressing mutant BVPrP spontaneously develop a bona fide prion disease and that mutations causing prion diseases may share a uniform initial mechanism of action. Therefore, these mice represent useful tools for studying the early stages of genetic prion diseases. ### Competing Interest Statement The authors have declared no competing interest.