The Significance of the Evolutionary Relationship of Prion Proteins and ZIP Transporters in Health and Disease

The cellular prion protein (PrPC) is unique amongst mammalian proteins in that it not only has the capacity to aggregate (in the form of scrapie PrP; PrPSc) and cause neuronal degeneration, but can also act as an independent vector for the transmission of disease from one individual to another of th...

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Bibliographic Details
Main Author: Ehsani, Sepehr
Other Authors: Schmitt-Ulms, Gerold
Language:en_ca
Published: 2012
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Online Access:http://hdl.handle.net/1807/33986
Description
Summary:The cellular prion protein (PrPC) is unique amongst mammalian proteins in that it not only has the capacity to aggregate (in the form of scrapie PrP; PrPSc) and cause neuronal degeneration, but can also act as an independent vector for the transmission of disease from one individual to another of the same or, in some instances, other species. Since the discovery of PrPC nearly thirty years ago, two salient questions have remained largely unanswered, namely, (i) what is the normal function of the cellular protein in the central nervous system, and (ii) what is/are the factor(s) involved in the misfolding of PrPC into PrPSc? To shed light on aspects of these questions, we undertook a discovery-based interactome investigation of PrPC in mouse neuroblastoma cells (Chapter 2), and among the candidate interactors, identified two members of the ZIP family of zinc transporters (ZIP6 and ZIP10) as possessing a PrP-like domain. Detailed analyses revealed that the LIV-1 subfamily of ZIP transporters (to which ZIPs 6 and 10 belong) are in fact the evolutionary ancestors of prions (Chapter 3). We were further able to demonstrate that PrPC likely emerged from a ZIP ancestor molecule nearly half-a-billion years ago via a retrotransposition event (Chapter 4). Moreover, biochemical investigations on ZIP10, as a model LIV-1 ZIP transporter, demonstrated that the ectodomain shedding of ZIP10 observed in prion-infected mice resembles a cellular response to transition metal starvation and suggested that prion disease in mice might phenocopy a transition metal starvation status (Chapter 5). These studies have opened a new angle to study prion biology in health and disease. Biochemical investigations on other LIV-1 ZIPs and attempts at the structural elucidation of the PrP-like domain of LIV-1 ZIP proteins are ongoing and have not been included in this thesis.