Development of the new yeast-based assays for prion properties

Sun, Meng

29 August 2011

Prion is an infectious isoform of a normal cellular protein which is capable of converting the non-prion form of the same protein into the alternative prion form. Mammalian prion protein PrP is responsible for prion formation in mammals, causing a series of fatal and incurable prion diseases. (1) We constructed, for the first time, a two-component system to phenotypically monitor the conformational status of PrP in the yeast cells. In this system, the prion domain of Sup35 (Sup35N) was fused to PrP90-230, and the initial formation of the PrPSc-like conformation stimulated prion formation of Sup35N, which in turn converted soluble Sup35 into the prion isoform, leading to a detectable phenotype. Prion-like properties of PrP were studied in this novel yeast model system. Additionally, we employed this system to study amyloidogenic protein Aβ42 aggregation in the yeast model. It has been suggested that the ability to form transmissible amyloids (prions) is widespread among yeast proteins and is likely intrinsic to proteins from other organisms. However, the distribution of yeast prions in natural conditions is not yet clear, which prevents us from understanding the relationship between prions and their adaptive roles in various environmental conditions. (2) We modified and developed sequence and phenotype-independent approaches for prion detection and monitoring. We employed these approaches for prion-profiling among yeast strains of various origins. (3) Lastly, we found a prion-like state [MCS+] causing nonsense suppression in the absence of the Sup35 prion domain. Our results suggested that [MCS+] is determined by both a prion factor and a nuclear factor. The prion-related properties of [MCS+] were studied by genetic and biochemical approaches.

Amyloid beta

[PSI+]

Prion detection

Prion induction

Mammalian prion protein

Prions

Proteins

Prion diseases

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

Ehsani, Sepehr

11 December 2012

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.

Prion protein

ZIP transporters

Zinc

Metal biology

0715

0379

0369

0317

Prions and platelets: a possible role for cellular prion protein

Robertson, Catherine

28 April 2005

Cellular prion protein (PrPc) is a GPI–anchored protein, of unknown function, found in a number of cells throughout the body. It is now widely believed that a mis-folded, protease resistant form of this protein is responsible for a group of fatal neurodegenerative diseases called transmissible spongiform encephalopathies (TSE), including Creutzfeldt-Jakob disease (CJD) and kuru in humans, scrapie in sheep, chronic wasting disease (CWD) in deer and elk and bovine spongiform encephalopathy (BSE) in cattle. Although the exact function of PrPc is unknown it has been implicated in copper binding, signal transduction and cell adhesion. The pathogenesis of prion diseases is poorly understood, however it is known that PrPc must be present in order for the disease to progress. Platelets have been shown to be the largest reservoir of PrPc in peripheral blood cells and previous studies in animal models have suggested platelets may also be involved in TSE infectivity. In this study, we determine the exact location of PrPc within human platelets, examine the mobilization and release of PrPc from activated platelets on both microvesicles and exosomes and suggest a possible role for platelets in prion infectivity. In addition we examine the role of PrPc within normal platelet functions including aggregation, signal transduction and adhesion. / May 2005

platelets

cellular prion protein

blood cells

microvesicles

exosomes

Surveillance Of Prion Protein (prp) Gene Polymorphisms In Turkish Native Sheep Breeds

Uzun, Begum

01 June 2012

v It was found that most of the classical scrapie genotypes belong to R3 risk group, whereas atypical scrapie genotypes belonging to zero (0) and one (1) risk groups were frequently seen in sheep analyzed. In other words, Turkish sheep is found to have intermediate risk of classical scrapie and low atypical scrapie risk, in general. The data from the current study may help to establish a breeding program for classical scrapie control in Turkey and will be beneficial for both the animal and public health in the country. In addition, the outcomes of the study will fill the gap which is present in the geographic distribution data of PrP gene polymorphisms in Eurasia.Scrapie is an infectious fatal disease of sheep and goats which affects the central nervous system. In the present study, samples of 14 native Turkish sheep breeds (n=655) were analyzed with respect to their polymorphisms of PrP gene (at codons: 136, 141, 154 and 171) and their classical and atypical scrapie risk levels were identified. Turkish sheep are found to have the highest PrP genetic variability with 13 classical scrapie alleles and 14 atypical scrapie alleles compared to all previous studies. Classical scrapie-susceptible and wild-type ARQ allele was found as the most frequent allele in Turkish sheep examined. The most classical scrapie-susceptible allele, VRQ was detected at low frequencies in 5 of the breeds (&Ccedil / ine &Ccedil / apari, Dagli&ccedil / , Kivircik, Karayaka and G&ouml / k&ccedil / eada). One novel allele (TL141HQ) was observed in Sakiz breed for the first time in this study.

QH Genetics 426-470

Interactions between Amyloid Precursor Protein and Prion Protein Impact Cell Adhesion and Apoptosis in the Developing Zebrafish

Kaiser, Darcy

Unknown Date

No description available.

Zebrafish

Amyloid Precursor Protein

Prion Protein

Cell Adhesion

Apoptosis

Knock down

Interactions

Über die Interaktionen des zellulären Prion-Proteins (PrPc) mit relevanten Proteinen der Alzheimer Erkrankung / The interaktion of the cellular prion protein (PrPc) with relevant proteins of Alzheimer's disease

Maibach-Wulf, Katharina

15 July 2014

No description available.

610

Medizin (PPN619874732)

Prions and platelets: a possible role for cellular prion protein

Robertson, Catherine

28 April 2005

Cellular prion protein (PrPc) is a GPI–anchored protein, of unknown function, found in a number of cells throughout the body. It is now widely believed that a mis-folded, protease resistant form of this protein is responsible for a group of fatal neurodegenerative diseases called transmissible spongiform encephalopathies (TSE), including Creutzfeldt-Jakob disease (CJD) and kuru in humans, scrapie in sheep, chronic wasting disease (CWD) in deer and elk and bovine spongiform encephalopathy (BSE) in cattle. Although the exact function of PrPc is unknown it has been implicated in copper binding, signal transduction and cell adhesion. The pathogenesis of prion diseases is poorly understood, however it is known that PrPc must be present in order for the disease to progress. Platelets have been shown to be the largest reservoir of PrPc in peripheral blood cells and previous studies in animal models have suggested platelets may also be involved in TSE infectivity. In this study, we determine the exact location of PrPc within human platelets, examine the mobilization and release of PrPc from activated platelets on both microvesicles and exosomes and suggest a possible role for platelets in prion infectivity. In addition we examine the role of PrPc within normal platelet functions including aggregation, signal transduction and adhesion.

platelets

cellular prion protein

blood cells

microvesicles

exosomes

Misfolding of Particular PrP and Susceptibility to Prion Infection

Khan, Muhammad Qasim

27 July 2010

Pathogenesis of prion diseases in animals is associated with the misfolding of the cellular prion protein PrPC to the infectious form, PrPSc. We hypothesized that an animal’s susceptibility to prions is correlated with the propensity of an animal’s PrPC to adopt a β-sheet, PrPSc-like, conformation. We have developed a method which uses circular dichroism (CD) to directly calculate the relative population of PrP molecules that adopt a β-sheet conformation or the ‘β-state’, as a function of denaturant concentration and pH. We find that the PrP from animals that are more susceptible to prion diseases, like hamsters and mice, adopt the β-state more readily than the PrP from rabbits. The X-ray crystal structure of rabbit PrP reveals a helix-capping motif that may lower the propensity to form the β-state. PrP in the β-state contains both monomeric and octameric β-structured species, and possesses cytotoxic properties.

Prion protein

prion disease

prion susceptibility

protein misfolding

circular dichroism

analytical ultracentrifugation

0487

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

Ehsani, Sepehr

11 December 2012

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.

Prion protein

ZIP transporters

Zinc

Metal biology

0715

0379

0369

0317

Misfolding of Particular PrP and Susceptibility to Prion Infection

Khan, Muhammad Qasim

27 July 2010

Pathogenesis of prion diseases in animals is associated with the misfolding of the cellular prion protein PrPC to the infectious form, PrPSc. We hypothesized that an animal’s susceptibility to prions is correlated with the propensity of an animal’s PrPC to adopt a β-sheet, PrPSc-like, conformation. We have developed a method which uses circular dichroism (CD) to directly calculate the relative population of PrP molecules that adopt a β-sheet conformation or the ‘β-state’, as a function of denaturant concentration and pH. We find that the PrP from animals that are more susceptible to prion diseases, like hamsters and mice, adopt the β-state more readily than the PrP from rabbits. The X-ray crystal structure of rabbit PrP reveals a helix-capping motif that may lower the propensity to form the β-state. PrP in the β-state contains both monomeric and octameric β-structured species, and possesses cytotoxic properties.

Prion protein

prion disease

prion susceptibility

protein misfolding

circular dichroism

analytical ultracentrifugation

0487