Abstract
Prion or PrPSc is a proteinaceous infectious agent that consists of a misfolded and aggregated form of a sialoglycoprotein called prion protein or PrPC. PrPC has two sialylated N-linked carbohydrates. In PrPSc, the glycans are directed outward, with the terminal sialic acid residues creating a negative charge on the surface of prion particles. The current study proposes a new hypothesis that electrostatic repulsion between sialic residues creates structural constraints that control prion replication and PrPSc glycoform ratio. In support of this hypothesis, here we show that diglycosylated PrPC molecules that have more sialic groups per molecule than monoglycosylated PrPC were preferentially excluded from conversion. However, when partially desialylated PrPC was used as a substrate, recruitment of three glycoforms into PrPSc was found to be proportional to their respective populations in the substrate. In addition, hypersialylated molecules were also excluded from conversion in the strains with the strongest structural constraints, a strategy that helped reduce electrostatic repulsion. Moreover, as predicted by the hypothesis, partial desialylation of PrPC significantly increased the replication rate. This study illustrates that sialylation of N-linked glycans creates a prion replication barrier that controls replication rate and glycoform ratios and has broad implications.
Highlights
Prion or PrPSc is a proteinaceous infectious agent that consists of a misfolded and aggregated form of a sialoglycoprotein called prion protein or PrPC
These findings led to a new hypothesis that electrostatic repulsion between sialic acid residues creates a replication barrier that slows down prion replication
The current study tests the above hypothesis on the role of sialylation in controlling the prion replication barrier and glycoform ratios
Summary
The current study proposes a new hypothesis that electrostatic repulsion between sialic residues creates structural constraints that control prion replication and PrPSc glycoform ratio. In support of this hypothesis, here we show that diglycosylated PrPC molecules that have more sialic groups per molecule than monoglycosylated PrPC were preferentially excluded from conversion. Because sialic acid residues create a dense negative charge on the PrPSc surface, glycan sialylation might play a major role in modulating interactions between PrPSc and PrPC and defining prion replication rate. We propose that diglycosylated glycoforms are selectively excluded to reduce electrostatic repulsion between sialic acid residues within PrPSc. The current study tests the above hypothesis on the role of sialylation in controlling the prion replication barrier and glycoform ratios
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