Prion-like propagation of cytosolic protein aggregates: Insights from cell culture models

Amyloid formation is a hallmark of several systemic and neurodegenerative diseases. Extracellular amyloid deposits or intracellular inclusions arise from the conformational transition of normally soluble proteins into highly ordered fibrillar aggregates. Amyloid fibrils are formed by nucleated polymerization, a process also shared by prions, proteinaceous infectious agents identified in mammals and fungi. Unlike so called non-infectious amyloids, the aggregation phenotype of prion proteins can be efficiently transmitted between cells and organisms. Recent discoveries in vivo now implicate that even disease-associated intracellular protein aggregates consisting of α-synuclein or Tau have the capacity to seed aggregation of homotypic native proteins and might propagate their amyloid states in a prion-like manner. Studies in tissue culture demonstrate that aggregation of diverse intracellular amyloidogenic proteins can be induced by exogenous fibrillar seeds. Still, a prerequisite for prion-like propagation is the fragmentation of proteinaceous aggregates into smaller seeds that can be transmitted to daughter cells. So far efficient propagation of the aggregation phenotype in the absence of exogenous seeds was only observed for a yeast prion domain expressed in tissue culture. Intrinsic properties of amyloidogenic protein aggregates and a suitable host environment likely determine if a protein polymer can propagate in a prion-like manner in the mammalian cytosol.Key words: prion, Sup35, huntingtin, polyglutamine, Tau, co-aggregation, amyloid, α-synuclein     

Exogenous amyloidogenic proteins function as seeds in amyloid β-protein aggregation

Amyloid β-protein (Aβ) aggregation is considered to be a critical step in the neurodegeneration of Alzheimer's disease (AD). In addition to Aβ, many proteins aggregate into the amyloid state, in which they form elongated fibers with spines comprising stranded β-sheets. However, the cross-seeding effects of other protein aggregates on Aβ aggregation pathways are not completely clear. To investigate the cross-seeding effects of exogenous and human non-CNS amyloidogenic proteins on Aβ aggregation pathways, we examined whether and how sonicated fibrils of casein, fibroin, sericin, actin, and islet amyloid polypeptide affected Aβ40 and Aβ42 aggregation pathways using the thioflavin T assay and electron microscopy. Interestingly, the fibrillar seeds of all amyloidogenic proteins functioned as seeds. The cross-seeding effect of actin was stronger but that of fibroin was weaker than that of other proteins. Furthermore, our nuclear magnetic resonance spectroscopic studies identified the binding sites of Aβ with the amyloidogenic proteins. Our results indicate that the amyloidogenic proteins, including those contained in foods and cosmetics, contribute to Aβ aggregation by binding to Aβ, suggesting their possible roles in the propagation of Aβ amyloidosis.     

Amyloids, prions and the inherent infectious nature of misfolded protein aggregates

Misfolded aggregates present in amyloid fibrils are associated with various diseases known as "protein misfolding" disorders. Among them, prion diseases are unique in that the pathology can be transmitted by an infectious process involving an unprecedented agent known as a "prion". Prions are infectious proteins that can transmit biological information by propagating protein misfolding and aggregation. The molecular mechanism of prion conversion has a striking resemblance to the process of amyloid formation, suggesting that misfolded aggregates have an inherent ability to be transmissible. Intriguing recent data suggest that other protein misfolding disorders might also be transmitted by a prion-like infectious process.     

Substoichiometric Hsp104 regulates the genesis and persistence of self-replicable amyloid seeds of Sup35 prion domain

Prion-like self-perpetuating conformational conversion of proteins is involved in both transmissible neurodegenerative diseases in mammals and non-Mendelian inheritance in yeast. The transmissibility of amyloid-like aggregates is dependent on the stoichiometry of chaperones such as heat shock proteins (Hsps), including disaggregases. To provide the mechanistic underpinnings of the formation and persistence of prefibrillar amyloid seeds, we investigated the role of substoichiometric Hsp104 on the in vitro amyloid aggregation of the prion domain (NM-domain) of Saccharomyces cerevisiae Sup35. At low substoichiometric concentrations, we show Hsp104 exhibits a dual role: it considerably accelerates the formation of prefibrillar species by shortening the lag phase but also prolongs their persistence by introducing unusual kinetic halts and delaying their conversion into mature amyloid fibers. Additionally, Hsp104-modulated amyloid species displayed a better seeding capability compared to NM-only amyloids. Using biochemical and biophysical tools coupled with site-specific dynamic readouts, we characterized the distinct structural and dynamical signatures of these amyloids. We reveal that Hsp104-remodeled amyloidogenic species are compositionally diverse in prefibrillar aggregates and are packed in a more ordered fashion compared to NM-only amyloids. Finally, we show these Hsp104-remodeled, conformationally distinct NM aggregates display an enhanced autocatalytic self-templating ability that might be crucial for phenotypic outcomes. Taken together, our results demonstrate that substoichiometric Hsp104 promotes compositional diversity and conformational modulations during amyloid formation, yielding effective prefibrillar seeds that are capable of driving prion-like Sup35 propagation. Our findings underscore the key functional and pathological roles of substoichiometric chaperones in prion-like propagation.     

Amyloidogenic domains, prions and structural inheritance: rudiments of early life or recent acquisition?

Amyloids are self-assembled fibre-like beta-rich protein aggregates. Amyloidogenic prion proteins propagate amyloid state in vivo and transmit it via infection or in cell divisions. While amyloid aggregation may occur in the absence of any other proteins, in vivo propagation of the amyloid state requires chaperone helpers. Yeast prion proteins contain prion domains which include distinct aggregation and propagation elements, responsible for these functions. Known aggregation and propagation elements are short in length and composed of relatively simple sequences, indicating possible ancient origin. Prion-like self-assembled structures could be involved in the initial steps of biological compartmentalization in early life.     

The aggregation of mutant p53 produces prion-like properties in cancer

The tumor suppressor protein p53 loses its function in more than 50% of human malignant tumors. Recent studies have suggested that mutant p53 can form aggregates that are related to loss-of-function effects, negative dominance and gain-of-function effects and cancers with a worsened prognosis. In recent years, several degenerative diseases have been shown to have prion-like properties similar to mammalian prion proteins (PrPs). However, whereas prion diseases are rare, the incidence of these neurodegenerative pathologies is high. Malignant tumors involving mutated forms of the tumor suppressor p53 protein seem to have similar substrata. The aggregation of the entire p53 protein and three functional domains of p53 into amyloid oligomers and fibrils has been demonstrated. Amyloid aggregates of mutant p53 have been detected in breast cancer and malignant skin tumors. Most p53 mutations related to cancer development are found in the DNA-binding domain (p53C), which has been experimentally shown to form amyloid oligomers and fibrils. Several computation programs have corroborated the predicted propensity of p53C to form aggregates, and some of these programs suggest that p53C is more likely to form aggregates than the globular domain of PrP. Overall, studies imply that mutant p53 exerts a dominant-negative regulatory effect on wild-type (WT) p53 and exerts gain-of-function effects when co-aggregating with other proteins such as p63, p73 and acetyltransferase p300. We review here the prion-like behavior of oncogenic p53 mutants that provides an explanation for their dominant-negative and gain-of-function properties and for the high metastatic potential of cancers bearing p53 mutations. The inhibition of the aggregation of p53 into oligomeric and fibrillar amyloids appears to be a promising target for therapeutic intervention in malignant tumor diseases.     

Self-replicating protein conformations and information transfer: The adaptive β-sheet model

The deposition of proteins with a highly ordered β-sheet conformation is characteristic of several amyloid diseases. However, recent data indicate that amyloid formation is not always pathological, but may also be physiological. Based on the new insights in understanding the structural arrangements and the self-propagating properties of the β-conformational proteins in combination with the progress in elucidating the mechanisms of prion genetics and chaperone-controlled protein folding, a model of an adaptive β-sheet information system was developed. The idea is advanced that exogenous information can be specifically stored in the protease-resistant β-sheet rich protein aggregates in a prion-like mode creating a cytoplasmic molecular memory. The conformationally-bound information can then be transmitted to next cell generations by way of the self-propagating potential of the amyloidogenic structure. Controlled by a network of input-sensitive molecular chaperones, the β-conformation based information system could constitute a form of soft inheritance characterized by adaptability and plasticity. It is suggested that the β-system represents an evolutionary conserved primordial inheritance mechanism based on protein conformation.     

Conformational transition occurring upon amyloid aggregation of the HET-s prion protein of Podospora anserina analyzed by hydrogen/deuterium exchange and mass spectrometry

The [Het-s] infectious element of the filamentous fungus Podospora anserina corresponds to the prion form of the HET-s protein. HET-s (289 amino acids in length) aggregates into amyloid fibers in vitro. Such fibers obtained in vitro are infectious, indicating that the [Het-s] prion can propagate as a self-perpetuating amyloid aggregate of the HET-s protein. Previous analyses have suggested that only a limited region of the HET-s protein is involved in amyloid formation and prion propagation. To document the conformational transition occurring upon amyloid aggregation of HET-s, we have developed a method involving hydrogen/deuterium exchange monitored by MALDI-MS. In a first step, a peptide mass fingerprint of the protein was obtained, leading to 87% coverage of the HET-s primary structure. Amyloid aggregates of HET-s were obtained, and H/D exchange was monitored on the soluble and on the amyloid form of HET-s. This study revealed that in the soluble form of HET-s, the C-terminal region (spanning from residues 240-289) displays a high solvent accessibility. In sharp contrast, solvent accessibility is drastically reduced in that region in the amyloid form. H/D exchange rates and levels in the N-terminal part of the protein (residues 1-220) are comparable in the soluble and the aggregated state. These results indicate that amyloid aggregation of HET-s involves a conformational transition of the C-terminal part of the protein from a mainly disordered to an aggregated state in which this region is highly protected from hydrogen exchange.     

Infectious Fold and Amyloid Propagation in Podospora anserina

Amyloid protein aggregation is involved in serious neurodegenerative disorders such as Alzheimer''s disease and transmissible encephalopathies. The concept of an infectious protein (prion) being the scrapie agent was successfully validated for several yeast and fungi proteins. Ure2, Sup35 and Rnq1 in Saccharomyces cerevisiae and HET-s in Podospora anserina have been genetically and biochemically identified as prion proteins. Studies on these proteins have revealed critical information on the mechanisms of prions appearance and propagation. The prion phenotype correlates with the aggregation state of these particular proteins. In vitro, the recombinant prion proteins form amyloid fibers characterized by rich β sheet content. In a previous work on the HET-s prion protein Podospora, we demonstrated the infectivity of HET-s recombinant amyloid aggregates. More recently, the structural analysis of the HET-s prion domain associated with in vivo mutagenesis allowed us to propose a model for the infectious fold of the HET-s prion domain. Further investigations to complete this model are discussed in this review, as are relevant questions about the [Het-s] system of Podospora anserina.Key Words: prion, HET-s, Podospora, amyloid, infectious, β sheet, mutagenesis, fold, propagation     

Glycosylphosphatidylinositol Anchoring Directs the Assembly of Sup35NM Protein into Non-fibrillar,Membrane-bound Aggregates

In prion-infected hosts, PrPSc usually accumulates as non-fibrillar, membrane-bound aggregates. Glycosylphosphatidylinositol (GPI) anchor-directed membrane association appears to be an important factor controlling the biophysical properties of PrPSc aggregates. To determine whether GPI anchoring can similarly modulate the assembly of other amyloid-forming proteins, neuronal cell lines were generated that expressed a GPI-anchored form of a model amyloidogenic protein, the NM domain of the yeast prion protein Sup35 (Sup35^GPI). We recently reported that GPI anchoring facilitated the induction of Sup35^GPI prions in this system. Here, we report the ultrastructural characterization of self-propagating Sup35^GPI aggregates of either spontaneous or induced origin. Like membrane-bound PrPSc, Sup35^GPI aggregates resisted release from cells treated with phosphatidylinositol-specific phospholipase C. Sup35^GPI aggregates of spontaneous origin were detergent-insoluble, protease-resistant, and self-propagating, in a manner similar to that reported for recombinant Sup35NM amyloid fibrils and induced Sup35^GPI aggregates. However, GPI-anchored Sup35 aggregates were not stained with amyloid-binding dyes, such as Thioflavin T. This was consistent with ultrastructural analyses, which showed that the aggregates corresponded to dense cell surface accumulations of membrane vesicle-like structures and were not fibrillar. Together, these results showed that GPI anchoring directs the assembly of Sup35NM into non-fibrillar, membrane-bound aggregates that resemble PrPSc, raising the possibility that GPI anchor-dependent modulation of protein aggregation might occur with other amyloidogenic proteins. This may contribute to differences in pathogenesis and pathology between prion diseases, which uniquely involve aggregation of a GPI-anchored protein, versus other protein misfolding diseases.     

Soluble oligomers are sufficient for transmission of a yeast prion but do not confer phenotype

Amyloidogenic proteins aggregate through a self-templating mechanism that likely involves oligomeric or prefibrillar intermediates. For disease-associated amyloidogenic proteins, such intermediates have been suggested to be the primary cause of cellular toxicity. However, isolation and characterization of these oligomeric intermediates has proven difficult, sparking controversy over their biological relevance in disease pathology. Here, we describe an oligomeric species of a yeast prion protein in cells that is sufficient for prion transmission and infectivity. These oligomers differ from the classic prion aggregates in that they are soluble and less resistant to SDS. We found that large, SDS-resistant aggregates were required for the prion phenotype but that soluble, more SDS-sensitive oligomers contained all the information necessary to transmit the prion conformation. Thus, we identified distinct functional requirements of two types of prion species for this endogenous epigenetic element. Furthermore, the nontoxic, self-replicating amyloid conformers of yeast prion proteins have again provided valuable insight into the mechanisms of amyloid formation and propagation in cells.     

Amyloidogenesis of Tau protein

The role of microtubule‐associated protein Tau in neurodegeneration has been extensively investigated since the discovery of Tau amyloid aggregates in the brains of patients with Alzheimer's disease (AD). The process of formation of amyloid fibrils is known as amyloidogenesis and attracts much attention as a potential target in the prevention and treatment of neurodegenerative conditions linked to protein aggregation. Cerebral deposition of amyloid aggregates of Tau is observed not only in AD but also in numerous other tauopathies and prion diseases. Amyloidogenesis of intrinsically unstructured monomers of Tau can be triggered by mutations in the Tau gene, post‐translational modifications, or interactions with polyanionic molecules and aggregation‐prone proteins/peptides. The self‐assembly of amyloid fibrils of Tau shares a number of characteristic features with amyloidogenesis of other proteins involved in neurodegenerative diseases. For example, in vitro experiments have demonstrated that the nucleation phase, which is the rate‐limiting stage of Tau amyloidogenesis, is shortened in the presence of fragmented preformed Tau fibrils acting as aggregation templates (“seeds”). Accordingly, Tau aggregates released by tauopathy‐affected neurons can spread the neurodegenerative process in the brain through a prion‐like mechanism, originally described for the pathogenic form of prion protein. Moreover, Tau has been shown to form amyloid strains—structurally diverse self‐propagating aggregates of potentially various pathological effects, resembling in this respect prion strains. Here, we review the current literature on Tau aggregation and discuss mechanisms of propagation of Tau amyloid in the light of the prion‐like paradigm.     

Prion-like Properties of Tau Protein: The Importance of Extracellular Tau as a Therapeutic Target

Work over the past 4 years indicates that multiple proteins associated with neurodegenerative diseases, especially Tau and α-synuclein, can propagate aggregates between cells in a prion-like manner. This means that once an aggregate is formed it can escape the cell of origin, contact a connected cell, enter the cell, and induce further aggregation via templated conformational change. The prion model predicts a key role for extracellular protein aggregates in mediating progression of disease. This suggests new therapeutic approaches based on blocking neuronal uptake of protein aggregates and promoting their clearance. This will likely include therapeutic antibodies or small molecules, both of which can be developed and optimized in vitro prior to preclinical studies.     

GPI anchoring facilitates propagation and spread of misfolded Sup35 aggregates in mammalian cells

Prion diseases differ from other amyloid‐associated protein misfolding diseases (e.g. Alzheimer's) because they are naturally transmitted between individuals and involve spread of protein aggregation between tissues. Factors underlying these features of prion diseases are poorly understood. Of all protein misfolding disorders, only prion diseases involve the misfolding of a glycosylphosphatidylinositol (GPI)‐anchored protein. To test whether GPI anchoring can modulate the propagation and spread of protein aggregates, a GPI‐anchored version of the amyloidogenic yeast protein Sup35NM (Sup35^GPI) was expressed in neuronal cells. Treatment of cells with Sup35NM fibrils induced the GPI anchor‐dependent formation of self‐propagating, detergent‐insoluble, protease‐resistant, prion‐like aggregates of Sup35^GPI. Live‐cell imaging showed intercellular spread of Sup35^GPI aggregation to involve contact between aggregate‐positive and aggregate‐negative cells and transfer of Sup35^GPI from aggregate‐positive cells. These data demonstrate GPI anchoring facilitates the propagation and spread of protein aggregation and thus may enhance the transmissibility and pathogenesis of prion diseases relative to other protein misfolding diseases.     

Branched chain mechanism of polymerization and ultrastructure of prion protein amyloid fibrils

The discovery of prion disease and the establishment of the protein only hypothesis of prion propagation raised substantial interest in the class of maladies referred to as conformational diseases. Although significant progress has been made in elucidating the mechanisms of polymerization for several amyloidogenic proteins and peptides linked to conformational disorders and solving their fibrillar 3D structures, studies of prion protein amyloid fibrils and their polymerization mechanism have proven to be very difficult. The present minireview introduces the mechanism of branched-chain reaction for describing the peculiar kinetics of prion polymerization and summarizes our current knowledge about the substructure of prion protein amyloid fibrils.     

Protein misfolding in Dictyostelium: Using a freak of nature to gain insight into a universal problem

Prion-like proteins can undergo conformational rearrangements from an intrinsically disordered to a highly ordered amyloid state. This ability to change conformation is encoded in distinctive domains, termed prion domains (PrDs). Previous work suggests that PrDs change conformation to affect protein function and create phenotypic diversity. More recent work shows that PrDs can also undergo many weak interactions when disordered, allowing them to organize the intracellular space into dynamic compartments. However, mutations within PrDs and altered aggregation properties have also been linked to age-related diseases in humans. Thus, the physiological role of prion-like proteins, the mechanisms regulating their conformational promiscuity and the links to disease are still unclear. Here, we summarize recent work with prion-like proteins in Dictyostelium discoideum. This work was motivated by the finding that D. discoideum has the highest content of prion-like proteins of all organisms investigated to date. Surprisingly, we find that endogenous and exogenous prion-like proteins remain soluble in D. discoideum and do not misfold and aggregate. We provide evidence that this is due to specific adaptations in the protein quality control machinery, which may allow D. discoideum to tolerate its highly aggregation-prone proteome. We predict that D. discoideum will be an important model to study the function of prion-like proteins and their mechanistic links to disease.KEYWORDS: amyloid, Hsp104, prion, molecular chaperone, phase separation, protein aggregate, protein misfolding, ubiquitin/proteasome system     

Life cycle of cytosolic prions

Prions are self-templating protein aggregates that were originally identified as the causative agent of prion diseases in mammals, but have since been discovered in other kingdoms. Mammalian prions represent a unique class of infectious agents that are composed of misfolded prion protein. Prion proteins usually exist as soluble proteins but can refold and assemble into highly ordered, self-propagating prion polymers. The prion concept is also applicable to a growing number of non-Mendelian elements of inheritance in lower eukaryotes. While prions identified in mammals are clearly pathogens, prions in lower eukaryotes can be either detrimental or beneficial to the host. Prion phenotypes in fungi are transmitted vertically from mother to daughter cells during cell division and horizontally during mating or abortive mating, but extracellular phases have not been reported. Recent findings now demonstrate that in a mammalian cell environment, protein aggregates derived from yeast prion domains exhibit a prion life cycle similar to mammalian prions propagated ex vivo. This life cycle includes a soluble state of the protein, an induction phase by exogenous prion fibrils, stable replication of prion entities, vertical transmission to progeny and natural horizontal transmission to neighboring cells. Our data reveal that mammalian cells contain all co-factors required for cytosolic prion propagation and dissemination. This has important implications for understanding prion-like properties of disease-related protein aggregates. In light of the growing number of identified functional amyloids, cell-to-cell propagation of cytosolic protein conformers might not only be relevant for the spreading of disease-associated proteins, but might also be of more general relevance under non-disease conditions.     

Prions on the run: How extracellular vesicles serve as delivery vehicles for self-templating protein aggregates

Extracellular vesicles (EVs) are actively secreted, membrane-bound communication vehicles that exchange biomolecules between cells. EVs also serve as dissemination vehicles for pathogens, including prions, proteinaceous infectious agents that cause transmissible spongiform encephalopathies (TSEs) in mammals. Increasing evidence accumulates that diverse protein aggregates associated with common neurodegenerative diseases are packaged into EVs as well. Vesicle-mediated intercellular transmission of protein aggregates can induce aggregation of homotypic proteins in acceptor cells and might thereby contribute to disease progression. Our knowledge of how protein aggregates are sorted into EVs and how these vesicles adhere to and fuse with target cells is limited. Here we review how TSE prions exploit EVs for intercellular transmission and compare this to the transmission behavior of self-templating cytosolic protein aggregates derived from the yeast prion domain Sup 35 NM. Artificial NM prions are non-toxic to mammalian cell cultures and do not cause loss-of-function phenotypes. Importantly, NM particles are also secreted in association with exosomes that horizontally transmit the prion phenotype to naive bystander cells, a process that can be monitored with high accuracy by automated high throughput confocal microscopy. The high abundance of mammalian proteins with amino acid stretches compositionally similar to yeast prion domains makes the NM cell model an attractive model to study self-templating and dissemination properties of proteins with prion-like domains in the mammalian context.     

N-terminal domain of yeast Hsp104 chaperone is dispensable for thermotolerance and prion propagation but necessary for curing prions by Hsp104 overexpression

Hsp104 is a hexameric protein chaperone that resolubilizes stress-damaged proteins from aggregates. Hsp104 promotes [PSI(+)] prion propagation by breaking prion aggregates, which propagate as amyloid fibers, into more numerous prion "seeds." Inactivating Hsp104 cures cells of [PSI(+)] and other amyloid-like yeast prions. Overexpressing Hsp104 also eliminates [PSI(+)], presumably by completely resolubilizing prion aggregates. Inexplicably, however, excess Hsp104 does not cure the other prions. Here we identify missense mutations in Hsp104's amino-terminal domain (NTD), which is conserved among Hsp100 proteins but whose function is unknown, that improve [PSI(+)] propagation. Hsp104Delta147, engineered to lack the NTD, supported [PSI(+)] and functioned normally in thermotolerance and protein disaggregation. Hsp104Delta147 failed to cure [PSI(+)] when overexpressed, however, implying that excess Hsp104 does not eliminate [PSI(+)] by direct dissolution of prion aggregates. Curing of [PSI(+)] by overexpressing catalytically inactive Hsp104 (Hsp104KT), which interferes with endogenous Hsp104, did not require the NTD. We further found that Hsp104 mutants defective in threading peptides through the hexamer pore had reduced ability to support [PSI(+)] in proportion to protein resolubilization defects, suggesting that [PSI(+)] propagation depends on this threading and that Hsp104 "breaks" prion aggregates by extracting protein monomers from the amyloid fibers.