Role of prion protein glycosylation in replication of human prions by protein misfolding cyclic amplification.

Prion diseases are transmissible neurological disorders associated with the presence of abnormal, disease-related prion protein (PrPD). The detection of PrPD in the brain is the only definitive diagnostic evidence of prion disease and its identification in body fluids and peripheral tissues are valuable for pre-mortem diagnosis. Protein misfolding cyclic amplification (PMCA) is a technique able to detect minute amount of PrPD and is based on the conversion of normal or cellular PrP (PrPC) to newly formed PrPD, sustained by a self-templating mechanism. Several animal prions have been efficiently amplified by PMCA, but limited results have been obtained with human prions with the exception of variant-Creutzfeldt-Jakob-disease (vCJD). Since the total or partial absence of glycans on PrPC has been shown to affect PMCA efficiency in animal prion studies, we attempted to enhance the amplification of four major sporadic-CJD (sCJD) subtypes (MM1, MM2, VV1, and VV2) and vCJD by single round PMCA using partially or totally unglycosylated PrPC as substrates. The amplification efficiency of all tested sCJD subtypes underwent a strong increase, inversely correlated to the degree of PrPC glycosylation and directly related to the matching of the PrP polymorphic 129 M/V genotype between seed and substrate. This effect was particularly significant in sCJDMM2 and sCJDVV2 allowing the detection of PK-resistant PrPD (resPrPD) in sCJDMM2 and sCJDVV2 brains at dilutions of 6 × 107 and 3 × 106. vCJD, at variance with the tested sCJD subtypes, showed the best amplification with partially deglycosylated PrPC substrate reaching a resPrPD detectability at up to 3 × 1016 brain dilution. The differential effect of substrate PrPC glycosylations suggests subtype-dependent PrPC-PrPD interactions, strongly affected by the PrPC glycans. The enhanced PMCA prion amplification efficiency achieved with unglycosylated PrPC substrates may allow for the developing of a sensitive, non-invasive, diagnostic test for the different CJD subtypes based on body fluids or easily-accessible-peripheral tissues.