Factor VIII exhibits chaperone-dependent and glucose-regulated reversible amyloid formation in the endoplasmic reticulum

Abstract

AbstractFactor VIII (FVIII) is the coagulation factor deficient in hemophilia A, which is treated by protein replacement. Unfortunately, this regimen is costly due to the expense of producing recombinant FVIII as a consequence of its low level secretion. FVIII expression activates the endoplasmic reticulum (ER) stress response, causes oxidative stress and induces apoptosis. Importantly, little is known about the factors that cause protein misfolding and aggregation in metazoans. Here we identified intrinsic and extrinsic factors that cause FVIII to form aggregates in the ER. We show that FVIII forms amyloid-like fibrils within the ER upon increased FVIII synthesis or inhibition of glucose metabolism. Significantly, FVIII amyloids can be dissolved upon restoration of glucose metabolism to produce functional secreted FVIII. Two ER chaperones and their co-chaperones, BiP and CANX/CRT, promote FVIII solubility in the ER, where the former is also required for disaggregation. A short aggregation motif in the FVIII A1 domain (termed Aggron) is necessary and sufficient to seed β-sheet polymerization and BiP binding to this Aggron prevents amyloidogenesis. Our findings provide novel insight into mechanisms that limit FVIII secretion and ER protein folding in general and have implication for ongoing hemophilia A gene therapy clinical trials.Key Points-FVIII forms amyloid aggregates in the ER that are dissolved in a chaperone- and glucose-dependent manner to produce secreted active FVIII.-A short amino acid sequence in the A1 domain causes β sheet polymerization and ER chaperone BiP binding to this site prevents aggregation.