The role of the prion protein in the internalization of α-synuclein amyloids

Synucleinopathies are a group of neurodegenerative diseases characterized by the accumulation of α-synuclein amyloids in several regions of the brain. α-Synuclein fibrils are able to spread via cell-to-cell transfer, and once inside the cells, they can template the misfolding and aggregation of the endogenous α-synuclein. Multiple mechanisms have been shown to participate in the process of propagation: endocytosis, tunneling nanotubes and macropinocytosis. Recently, we published a research showing that the cellular form of the prion protein (PrP^C) acts as a receptor for α-synuclein amyloid fibrils, facilitating their internalization through and endocytic pathway. This interaction occurs by a direct interaction between the fibrils and the N-terminal domain of PrP^C. In cell lines expressing the pathological form of PrP (PrP^Sc), the binding between PrP^C and α-synuclein fibrils prevents the formation and accumulation of PrP^Sc, since PrP^C is no longer available as a substrate for the pathological conversion templated by PrP^Sc. On the contrary, PrP^Sc deposits are cleared over passages, probably due to the increased processing of PrP^C into the neuroprotective fragments N1 and C1. Starting from these data, in this work we present new insights into the role of PrP^C in the internalization of protein amyloids and the possible therapeutic applications of these findings.     

Role of polysaccharide and lipid in lipopolysaccharide induced prion protein conversion

Conversion of native cellular prion protein (PrP^c) from an α-helical structure to a toxic and infectious β-sheet structure (PrP^Sc) is a critical step in the development of prion disease. There are some indications that the formation of PrP^Sc is preceded by a β-sheet rich PrP (PrP^β) form which is non-infectious, but is an intermediate in the formation of infectious PrP^Sc. Furthermore the presence of lipid cofactors is thought to be critical in the formation of both intermediate-PrP^β and lethal, infectious PrP^Sc. We previously discovered that the endotoxin, lipopolysaccharide (LPS), interacts with recombinant PrP^c and induces rapid conformational change to a β-sheet rich structure. This LPS induced PrP^β structure exhibits PrP^Sc-like features including proteinase K (PK) resistance and the capacity to form large oligomers and rod-like fibrils. LPS is a large, complex molecule with lipid, polysaccharide, 2-keto-3-deoxyoctonate (Kdo) and glucosamine components. To learn more about which LPS chemical constituents are critical for binding PrP^c and inducing β-sheet conversion we systematically investigated which chemical components of LPS either bind or induce PrP conversion to PrP^β. We analyzed this PrP conversion using resolution enhanced native acidic gel electrophoresis (RENAGE), tryptophan fluorescence, circular dichroism, electron microscopy and PK resistance. Our results indicate that a minimal version of LPS (called detoxified and partially de-acylated LPS or dLPS) containing a portion of the polysaccharide and a portion of the lipid component is sufficient for PrP conversion. Lipid components, alone, and saccharide components, alone, are insufficient for conversion.     

Conformational detection of prion protein with biarsenical labeling and FlAsH fluorescence

Prion diseases are associated with the misfolding of the host-encoded cellular prion protein (PrP^C) into a disease associated form (PrP^Sc). Recombinant PrP can be refolded into either an α-helical rich conformation (α-PrP) resembling PrP^C or a β-sheet rich, protease resistant form similar to PrP^Sc. Here, we generated tetracysteine tagged recombinant PrP, folded this into α- or β-PrP and determined the levels of FlAsH fluorescence. Insertion of the tetracysteine tag at three different sites within the 91-111 epitope readily distinguished β-PrP from α-PrP upon FlAsH labeling. Labelling of tetracysteine tagged PrP in the α-helical form showed minimal fluorescence, whereas labeling of tagged PrP in the β-sheet form showed high fluorescence indicating that this region is exposed upon conversion. This highlights a region of PrP that can be implicated in the development of diagnostics and is a novel, protease free mechanism for distinguishing PrP^Sc from PrP^C. This technique may also be applied to any protein that undergoes conformational change and/or misfolding such as those involved in other neurodegenerative disorders including Alzheimer’s, Huntington’s and Parkinson’s diseases.     

Residue-specific mobility changes in soluble oligomers of the prion protein define regions involved in aggregation

Prion (PrP) diseases are neurodegenerative diseases characterized by the formation of β-sheet rich, insoluble and protease resistant protein deposits (called PrP^Sc) that occur throughout the brain. Formation of synthetic or in vitro PrP^Sc can occur through on-pathway toxic oligomers. Similarly, toxic and infectious oligomers identified in cell and animal models of prion disease indicate that soluble oligomers are likely intermediates in the formation of insoluble PrP^Sc. Despite the critical role of prion oligomers in disease progression, little is known about their structure. In order, to obtain structural insight into prion oligomers, we generated oligomers by shaking-induced conversion of recombinant, monomeric prion protein PrP^c (spanning residues 90–231). We then obtained two-dimensional solution NMR spectra of the PrP^c monomer, a 40% converted oligomer, and a 94% converted oligomer. Heteronuclear single-quantum correlation (¹H–¹⁵N) studies revealed that, in comparison to monomeric PrP^c, the oligomer has intense amide peak signals in the N-terminal (residues 90–114) and C-terminal regions (residues 226–231). Furthermore, a core region with decreased mobility is revealed from residues ~127 to 225. Within this core oligomer region with decreased mobility, there is a pocket of increased amide peak signal corresponding to the middle of α-helix 2 and the loop between α-helices 2 and 3 in the PrP^c monomer structure. Using high-resolution solution-state NMR, this work reveals detailed and divergent residue-specific changes in soluble oligomeric models of PrP.     

Interaction of Peptide Aptamers with Prion Protein Central Domain Promotes α-Cleavage of PrP<Superscript>C</Superscript>

Prion diseases are infectious and fatal neurodegenerative diseases affecting humans and animals. Transmission is possible within and between species with zoonotic potential. Currently, no prophylaxis or treatment exists. Prions are composed of the misfolded isoform PrP^Sc of the cellular prion protein PrP^C. Expression of PrP^C is a prerequisite for prion infection, and conformational conversion of PrP^C is induced upon its direct interaction with PrP^Sc. Inhibition of this interaction can abrogate prion propagation, and we have previously established peptide aptamers (PAs) binding to PrP^C as new anti-prion compounds. Here, we mapped the interaction site of PA8 in PrP and modeled the complex in silico to design targeted mutations in PA8 which presumably enhance binding properties. Using these PA8 variants, we could improve PA-mediated inhibition of PrP^Sc replication and de novo infection of neuronal cells. Furthermore, we demonstrate that binding of PA8 and its variants increases PrP^C α-cleavage and interferes with its internalization. This gives rise to high levels of the membrane-anchored PrP-C1 fragment, a transdominant negative inhibitor of prion replication. PA8 and its variants interact with PrP^C at its central and most highly conserved domain, a region which is crucial for prion conversion and facilitates toxic signaling of Aβ oligomers characteristic for Alzheimer’s disease. Our strategy allows for the first time to induce α-cleavage, which occurs within this central domain, independent of targeting the responsible protease. Therefore, interaction of PAs with PrP^C and enhancement of α-cleavage represent mechanisms that can be beneficial for the treatment of prion and other neurodegenerative diseases.     

Molecular model of an alpha-helical prion protein dimer and its monomeric subunits as derived from chemical cross-linking and molecular modeling calculations

Prions are the agents of a series of lethal neurodegenerative diseases. They are composed largely, if not entirely, of the host-encoded prion protein (PrP), which can exist in the cellular isoform PrP^C and the pathological isoform PrP^Sc. The conformational change of the α-helical PrP^C into β-sheet-rich PrP^Sc is the fundamental event of prion disease. The transition of recombinant PrP from a PrP^C-like into a PrP^Sc-like conformation can be induced in vitro by submicellar concentrations of SDS. An α-helical dimer was identified that might represent either the native state of PrP^C or the first step from the monomeric PrP^C to highly aggregated PrP^Sc. In the present study, the molecular structure of these dimers was analyzed by introducing covalent cross-links using 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide. Inter- and intramolecular bonds between directly neighboured amino groups and carboxy groups were generated. The bonds formed in PrP dimers of recombinant PrP (90-231) were identified by tryptic digestion and subsequent mass spectrometric analysis. Intra- and intermolecular cross-links between N-terminal glycine and three acidic amino acid side chains in the globular part of PrP were identified, showing the N-terminal amino acids (90-124) are not as flexible as known from NMR analysis. When the cross-linked sites were used as structural constraint, molecular modeling calculations yielded a structural model for PrP dimer and its monomeric subunit, including the folding of amino acids 90-124 in addition to the known structure. Molecular dynamics of the structure after release of the constraint indicated an intrinsic stability of the domain of amino acids 90-124.     

Lipopolysaccharide induced conversion of recombinant prion protein

The conformational conversion of the cellular prion protein (PrP^C) to the β-rich infectious isoform PrP^Sc is considered a critical and central feature in prion pathology. Although PrP^Sc is the critical component of the infectious agent, as proposed in the “protein-only” prion hypothesis, cellular components have been identified as important cofactors in triggering and enhancing the conversion of PrP^C to proteinase K resistant PrP^Sc. A number of in vitro systems using various chemical and/or physical agents such as guanidine hydrochloride, urea, SDS, high temperature, and low pH, have been developed that cause PrP^C conversion, their amplification, and amyloid fibril formation often under non-physiological conditions. In our ongoing efforts to look for endogenous and exogenous chemical mediators that might initiate, influence, or result in the natural conversion of PrP^C to PrP^Sc, we discovered that lipopolysaccharide (LPS), a component of gram-negative bacterial membranes interacts with recombinant prion proteins and induces conversion to an isoform richer in β sheet at near physiological conditions as long as the LPS concentration remains above the critical micelle concentration (CMC). More significant was the LPS mediated conversion that was observed even at sub-molar ratios of LPS to recombinant ShPrP (90–232).     

Identification of an Intracellular Site of Prion Conversion

Prion diseases are fatal, neurodegenerative disorders in humans and animals and are characterized by the accumulation of an abnormally folded isoform of the cellular prion protein (PrP^C), denoted PrP^Sc, which represents the major component of infectious scrapie prions. Characterization of the mechanism of conversion of PrP^C into PrP^Sc and identification of the intracellular site where it occurs are among the most important questions in prion biology. Despite numerous efforts, both of these questions remain unsolved. We have quantitatively analyzed the distribution of PrP^C and PrP^Sc and measured PrP^Sc levels in different infected neuronal cell lines in which protein trafficking has been selectively impaired. Our data exclude roles for both early and late endosomes and identify the endosomal recycling compartment as the likely site of prion conversion. These findings represent a fundamental step towards understanding the cellular mechanism of prion conversion and will allow the development of new therapeutic approaches for prion diseases.     

Pathologic Prion Protein Infects Cells by Lipid-Raft Dependent Macropinocytosis

Transmissible spongiform encephalopathies, including variant-Creutzfeldt-Jakob disease (vCJD) in humans and bovine spongiform encephalopathies in cattle, are fatal neurodegenerative disorders characterized by protein misfolding of the host cellular prion protein (PrP^C) to the infectious scrapie form (PrP^Sc). However, the mechanism that exogenous PrP^Sc infects cells and where pathologic conversion of PrP^C to the PrP^Sc form occurs remains uncertain. Here we report that similar to the mechanism of HIV-1 TAT-mediated peptide transduction, processed mature, full length PrP contains a conserved N-terminal cationic domain that stimulates cellular uptake by lipid raft-dependent, macropinocytosis. Inhibition of macropinocytosis by three independent means prevented cellular uptake of recombinant PrP; however, it did not affect recombinant PrP cell surface association. In addition, fusion of the cationic N-terminal PrP domain to a Cre recombinase reporter protein was sufficient to promote both cellular uptake and escape from the macropinosomes into the cytoplasm. Inhibition of macropinocytosis was sufficient to prevent conversion of PrP^C to the pathologic PrP^Sc form in N2a cells exposed to strain RML PrP^Sc infected brain homogenates, suggesting that a critical determinant of PrP^C conversion occurs following macropinocytotic internalization and not through mere membrane association. Taken together, these observations provide a cellular mechanism that exogenous pathological PrP^Sc infects cells by lipid raft dependent, macropinocytosis.     

Glypican-1 Mediates Both Prion Protein Lipid Raft Association and Disease Isoform Formation

In prion diseases, the cellular form of the prion protein, PrP^C, undergoes a conformational conversion to the infectious isoform, PrP^Sc. PrP^C associates with lipid rafts through its glycosyl-phosphatidylinositol (GPI) anchor and a region in its N-terminal domain which also binds to heparan sulfate proteoglycans (HSPGs). We show that heparin displaces PrP^C from rafts and promotes its endocytosis, suggesting that heparin competes with an endogenous raft-resident HSPG for binding to PrP^C. We then utilised a transmembrane-anchored form of PrP (PrP-TM), which is targeted to rafts solely by its N-terminal domain, to show that both heparin and phosphatidylinositol-specific phospholipase C can inhibit its association with detergent-resistant rafts, implying that a GPI-anchored HSPG targets PrP^C to rafts. Depletion of the major neuronal GPI-anchored HSPG, glypican-1, significantly reduced the raft association of PrP-TM and displaced PrP^C from rafts, promoting its endocytosis. Glypican-1 and PrP^C colocalised on the cell surface and both PrP^C and PrP^Sc co-immunoprecipitated with glypican-1. Critically, treatment of scrapie-infected N2a cells with glypican-1 siRNA significantly reduced PrP^Sc formation. In contrast, depletion of glypican-1 did not alter the inhibitory effect of PrP^C on the β-secretase cleavage of the Alzheimer''s amyloid precursor protein. These data indicate that glypican-1 is a novel cellular cofactor for prion conversion and we propose that it acts as a scaffold facilitating the interaction of PrP^C and PrP^Sc in lipid rafts.     

Pressure-assisted dissociation and degradation of “proteinase K-resistant” fibrils prepared by seeding with scrapie-infected hamster prion protein

The crucial step for the fatal neurodegenerative prion diseases involves the conversion of a normal cellular protein, PrP^C, into a fibrous pathogenic form, PrP^Sc, which has an unusual stability against heat and resistance against proteinase K digestion. A successful challenge to reverse the reaction from PrP^Sc into PrP^C is considered valuable, as it would give a key to dissolving the complex molecular events into thermodynamic and kinetic analyses and may also provide a means to prevent the formation of PrP^Sc from PrP^C eventually in vivo. Here we show that, by applying pressures at kbar range, the “proteinase K-resistant” fibrils (rHaPrP^res) prepared from hamster prion protein (rHaPrP [23–231]) by seeding with brain homogenate of scrapie-infected hamster, becomes easily digestible. The result is consistent with the notion that rHaPrP^res fibrils are dissociated into rHaPrP monomers under pressure and that the formation of PrP^Sc from PrP^C is thermodynamically controlled. Moreover, the efficient degradation of prion fibrils under pressure provides a novel means of eliminating infectious PrP^Sc from various systems of pathogenic concern.     

The Extent of Protease Resistance of Misfolded Prion Protein Is Highly Dependent on the Salt Concentration

Transmissible spongiform encephalopathies are neurodegenerative diseases caused by prions in mammals. An aberrantly folded protein (PrP^Sc) is the main component of these proteinaceous infectious particles. Prions exhibit strong resistance to protease digestion, which is typically exploited for biochemical discrimination from its native cellular form (PrP^C). This classical feature has been partially challenged by the isolation of sizeable amounts of protease-sensitive PrP^Sc isoforms that self-propagate in vivo. Here, we report that the degree of PrP^Sc protease resistance is highly dependent on the concentration of salt in the solution. Similar changes were observed in PrP^Sc obtained from different strains and species. Strikingly, the effect of salt is reversible and is associated with changes on the size of PrP^Sc particles, but surprisingly, the more protease-sensitive species consists of a larger size. These findings shed light on the mechanistic aspects of prion proteolysis and should be considered when assessing samples of biomedical relevance.     

The cellular prion protein (PrPC): Its physiological function and role in disease

Prion diseases are caused by conversion of a normal cell-surface glycoprotein (PrP^C) into a conformationally altered isoform (PrP^Sc) that is infectious in the absence of nucleic acid. Although a great deal has been learned about PrP^Sc and its role in prion propagation, much less is known about the physiological function of PrP^C. In this review, we will summarize some of the major proposed functions for PrP^C, including protection against apoptotic and oxidative stress, cellular uptake or binding of copper ions, transmembrane signaling, formation and maintenance of synapses, and adhesion to the extracellular matrix. We will also outline how loss or subversion of the cytoprotective or neuronal survival activities of PrP^C might contribute to the pathogenesis of prion diseases, and how similar mechanisms are probably operative in other neurodegenerative disorders.     

Conformational diversity in prion protein variants influences intermolecular β‐sheet formation

A conformational transition of normal cellular prion protein (PrP^C) to its pathogenic form (PrP^Sc) is believed to be a central event in the transmission of the devastating neurological diseases known as spongiform encephalopathies. The common methionine/valine polymorphism at residue 129 in the PrP influences disease susceptibility and phenotype. We report here seven crystal structures of human PrP variants: three of wild‐type (WT) PrP containing V129, and four of the familial variants D178N and F198S, containing either M129 or V129. Comparison of these structures with each other and with previously published WT PrP structures containing M129 revealed that only WT PrPs were found to crystallize as domain‐swapped dimers or closed monomers; the four mutant PrPs crystallized as non‐swapped dimers. Three of the four mutant PrPs aligned to form intermolecular β‐sheets. Several regions of structural variability were identified, and analysis of their conformations provides an explanation for the structural features, which can influence the formation and conformation of intermolecular β‐sheets involving the M/V129 polymorphic residue.     

Real-time visualization of prion transport in single live cells using quantum dots

Prion diseases are fatal neurodegenerative disorders resulting from structural conversion of the cellular isoform of PrP^C to the infectious scrapie isoform PrP^Sc. It is believed that such structural alteration may occur within the internalization pathway. However, there is no direct evidence to support this hypothesis. Employing quantum dots (QDs) as a probe, we have recorded a real-time movie demonstrating the process of prion internalization in a living cell for the first time. The entire internalization process can be divided into four discrete but connected stages. In addition, using methyl-beta-cyclodextrin to disrupt cell membrane cholesterol, we show that lipid rafts play an important role in locating cellular PrP^C to the cell membrane and in initiating PrP^C endocytosis.     

Mammalian prions

Upon prion infection, abnormal prion protein (PrP^Sc) self-perpetuate by conformational conversion of α-helix-rich PrP^C into β sheet enriched form, leading to formation and deposition of PrP^Sc aggregates in affected brains. However the process remains poorly understood at the molecular level and the regions of PrP critical for conversion are still debated. Minimal amino acid substitutions can impair prion replication at many places in PrP. Conversely, we recently showed that bona fide prions could be generated after introduction of eight and up to 16 additional amino acids in the H2-H3 inter-helix loop of PrP. Prion replication also accommodated the insertions of an octapeptide at different places in the last turns of H2. This reverse genetic approach reveals an unexpected tolerance of prions to substantial sequence changes in the protease-resistant part which is associated with infectivity. It also demonstrates that conversion does not require the presence of a specific sequence in the middle of the H2-H3 area. We discuss the implications of our findings according to different structural models proposed for PrP^Sc and questioned the postulated existence of an N- or C-terminal prion domain in the protease-resistant region.     

Mapping the Prion Protein Using Recombinant Antibodies

The fundamental event in prion disease is thought to be the posttranslational conversion of the cellular prion protein (PrP^C) into a pathogenic isoform (PrP^Sc). The occurrence of PrP^C on the cell surface and PrP^Sc in amyloid plaques in situ or in aggregates following purification complicates the study of the molecular events that underlie the disease process. Monoclonal antibodies are highly sensitive probes of protein conformation which can be used under these conditions. Here, we report the rescue of a diverse panel of 19 PrP-specific recombinant monoclonal antibodies from phage display libraries prepared from PrP deficient (Prnp^0/0) mice immunized with infectious prions either in the form of rods or PrP 27-30 dispersed into liposomes. The antibodies recognize a number of distinct linear and discontinuous epitopes that are presented to a varying degree on different PrP preparations. The epitope reactivity of the recombinant PrP(90-231) molecule was almost indistinguishable from that of PrP^C on the cell surface, validating the importance of detailed structural studies on the recombinant molecule. Only one epitope region at the C terminus of PrP was well presented on both PrP^C and PrP^Sc, while epitopes associated with most of the antibodies in the panel were present on PrP^C but absent from PrP^Sc.     

Transition of the prion protein from a structured cellular form (PrPC) to the infectious scrapie agent (PrPSc)

Prion diseases in mammals are caused by a conformational transition of the cellular prion protein from its native conformation (PrP^C) to a pathological isoform called “prion protein scrapie” (PrP^Sc). A molecular level of understanding of this conformational transition will be helpful in unveiling the disease etiology. Experimental structural biological techniques (NMR and X‐ray crystallography) have been used to unravel the atomic level structural information for the prion and its binding partners. More than one hundred three‐dimensional structures of the mammalian prions have been deposited in the protein databank. Structural studies on the prion protein and its structural transitions will deepen our understanding of the molecular basis of prion pathogenesis and will provide valuable guidance for future structure‐based drug discovery endeavors.     

The Role of Electrostatic Interaction in Triggering the Unraveling of Stable Helix 1 in Normal Prion Protein. A Molecular Dynamics Simulation Investigation

Abstract

The conversion of normal prion protein (PrP^C) into scrapie isoform (PrP^Sc) is a key event in the pathogenesis of prion diseases. However, the conversion mechanism has given rise to much controversy. For instance, there is much debate on the behavior of helix 1 (H1) in the conversion. A series of experiments demonstrated that H1 in isolated state was very stable under a variety of conditions. But, other experiments indicated that helices 2 and 3 rather than H1 were retained in PrP^Sc. In this paper, molecular dynamics (MD) simulation is employed to investigate the dynamic behavior of H1. It is revealed that although the helix 1 of Human PrP^C (HuPrP^C) is very stable in the isolated state, it becomes unstable when incorporated into native HuPrP^C, which likely results from the long-range electrostatic interaction between Asp147 and Arg208 located in the helices 1 and 3, respectively. This explanation is supported by experimental evaluation and MD simulation on D147N mutant of HuPrP^C that the mutant becomes a little more stable than the wild type HuPrP^C. This finding not only help to reconcile the existing debate on the role of helix 1 in the PrP^C→PrP^Sc transition, but also reveals a possible mechanism for triggering the PrP^C→PrP^Sc conversion.     

The Val-210-Ile pathogenic Creutzfeldt–Jakob disease mutation increases both the helical and aggregation propensities of a sequence corresponding to helix-3 of PrPC

A peptide corresponding to the third helical region within the PrP^C protein, from residues 198 to 218 (helix-3), was synthesised with and without the familial 210-Val to Ile Creutzfeldt–Jakob disease mutation. The NMR structure of PrP^C predicts no global variation in stability for this mutation, indicating that local sequence rather than global structural factors are involved in the pathological effects of this mutation. ¹H NMR analysis of peptides with and without this mutation indicated that it had no significant effect on local helical structure. Temperature denaturation studies monitored by CD showed that the mutation increased the helical content within this region (helical propensity), but did not stabilise the helix toward denaturation (helical stability). Aggregation data indicated that, in addition to increasing helical propensity, this mutation increased the aggregation propensity of this sequence. CD and NMR data indicate that helical interactions, stabilised by the Val-210-Ile mutation, may precede the formation of β-sheet aggregates in this peptide sequence. Therefore, this pathological mutation probably does not facilitate PrP^C to PrP^Sc conversion by directly destabilising the helical structure of PrP^C, but may preferentially stabilise PrP^Sc by facilitating β-sheet formation within this sequence region of PrP. In addition, helical interactions between helix-3 in two or more PrP^C molecules may promote conversion to PrP^Sc.