Pathogenic mutations in the hydrophobic core of the human prion protein can promote structural instability and misfolding

Transmissible spongiform encephalopathies, or prion diseases, are caused by misfolding and aggregation of the prion protein PrP. These diseases can be hereditary in humans and four of the many disease-associated missense mutants of PrP are in the hydrophobic core: V180I, F198S, V203I and V210I. The T183A mutation is related to the hydrophobic core mutants as it is close to the hydrophobic core and known to cause instability. We used extensive molecular dynamics simulations of these five PrP mutants to compare their dynamics and conformations to those of the wild type PrP. The simulations highlight the changes that occur upon introduction of mutations and help to rationalize experimental findings. Changes can occur around the mutation site, but they can also be propagated over long distances. In particular, the F198S and T183A mutations lead to increased flexibility in parts of the structure that are normally stable, and the short β-sheet moves away from the rest of the protein. Mutations V180I, V210I and, to a lesser extent, V203I cause changes similar to those observed upon lowering the pH, which has been linked to misfolding. Early misfolding is observed in one V180I simulation. Overall, mutations in the hydrophobic core have a significant effect on the dynamics and stability of PrP, including the propensity to misfold, which helps to explain their role in the development of familial prion diseases.     

Thermodynamic characterization for the denatured state of bovine prion protein and the BSE Associated variant E211K

ABSTRACT

Propagation of transmissible spongiform encephalopathies involves the conversion of cellular prion protein, PrP^C, into a misfolded oligomeric form, PrP^Sc. The most common hereditary prion disease is a genetic form of Creutzfeldt-Jakob disease in humans, in which a mutation in the prion gene results in a glutamic acid to lysine substitution at position 200 (E200K) in PrP. In cattle, the analogous amino acid substitution is found at residue 211 (E211K) and has been associated with a case of bovine spongiform encephalopathy. Here, we have compared the secondary structure of E211K to that of wild type using circular dichroism and completed a thermodynamic analysis of the folding of recombinant wild type and E211K variants of the bovine prion protein. The secondary structure of the E211K variant was essentially indistinguishable from that of wild type. The thermodynamic stability of E211K substitution showed a slight destabilization relative to the wild type consistent with results reported for recombinant human prion protein and its mutant E200K. In addition, the E211K variant exhibits a similarly compact denatured state to that of wild type based upon similar m-value and change in heat capacity of unfolding for the proteins. Together these results indicate that residual structure in the denatured state of bPrP is present in both the wild type protein and BSE associated variant E211K. Given this observation, as well as folding similarities reported for other disease associated variants of PrP it is worth consideration that functional aspects of PrP conformation may play a role in the misfolding process.     

The dominant-negative effect of the Q218K variant of the prion protein does not require protein X

Previous studies identified several single-point mutants of the prion protein that displayed dominant-negative effects on prion replication. The dominant-negative effect was assumed to be mediated by protein X, an as-yet-unknown cellular cofactor that is believed to be essential for prion replication. To gain insight into the mechanism that underlies the dominant-negative phenomena, we evaluated the effect of the Q218K variant of full-length recombinant prion protein (Q218K rPrP), one of the dominant-negative mutants, on cell-free polymerization of wild-type rPrP into amyloid fibrils. We found that both Q218K and wild-type (WT) rPrPs were incorporated into fibrils when incubated as a mixture; however, the yield of polymerization was substantially decreased in the presence of Q218K rPrP. Furthermore, in contrast to fibrils produced from WT rPrP, the fibrils generated in the mixture of WT and Q218K rPrPs did not acquire the proteinase K-resistant core of 16 kDa that was shown previously to encompass residues 97-230 and was similar to that of PrP(Sc). Our studies demonstrate that the Q218K variant exhibits the dominant-negative effect in cell-free conversion in the absence of protein X, and that this effect is, presumably, mediated by physical interaction between Q218K and WT rPrP during the polymerization process.     

Fragment molecular orbital calculations reveal that the E200K mutation markedly alters local structural stability in the human prion protein

The E200K mutation of the human prion protein (PrP) is known to cause familial Creutzfeldt–Jakob disease. In order to elucidate the effects of the mutation on the local structural stability of PrP, we performed ab initio fragment molecular orbital calculations for the wild-type human PrP and the E200K variant modeled under neutral and mild acidic conditions. The calculations revealed that this substitution markedly altered the intramolecular interactions in the PrP, suggesting that the local structural instabilities induced by the E200K mutation might cause initial denaturation of the PrP and its subsequent conversion to a pathogenic form. This work presents a new approach for quantitatively elucidating structural instabilities in proteins that cause misfolding diseases.     

Cooperative binding of dominant-negative prion protein to kringle domains

Conversion of the cellular prion protein (PrP(C)) to the pathogenic isoform (PrP(Sc)) is a major biochemical alteration in the progression of prion disease. This conversion process is thought to require interaction between PrP(C) and an as yet unidentified auxiliary factor, provisionally designated protein X. In searching for protein X, we screened a phage display cDNA expression library constructed from prion-infected neuroblastoma (ScN2a) cells and identified a kringle protein domain using full-length recombinant mouse PrP (recMoPrP(23-231), hereafter recMoPrP) expressing a dominant-negative mutation at codon 218 (recMoPrP(Q218K)). In vitro binding analysis using ELISA verified specific interaction of recMoPrP to kringle domains (K(1+2+3)) with higher binding by recMoPrP(Q218K) than by full-length recMoPrP without the mutation. This interaction was confirmed by competitive binding analysis, in which the addition of either a specific anti-kringle antibody or L-lysine abolished the interaction. Biochemical studies of the interactions between K(1+2+3) and various concentrations of both recMoPrP molecules demonstrated binding in a dose-dependent manner. A Hill plot analysis of the data indicates positive cooperative binding of both recMoPrP(Q218K) and recMoPrP to K(1+2+3) with stronger binding by recMoPrP(Q218K). Using full-length and an N-terminally truncated MoPrP(89-231), we demonstrate that N-terminal sequences enable PrP to bind strongly to K(1+2+3). Further characterization with truncated MoPrP(89-231) refolded in different conformations revealed that both alpha-helical and beta-sheet conformations bind to K(1+2+3). Our data demonstrate specific, high-affinity binding of a dominant-negative PrP as well as binding of other PrPs to K(1+2+3). The relevance of such interactions during prion pathogenesis remains to be established.     

Transmissibility of Gerstmann–Sträussler–Scheinker syndrome in rodent models: New insights into the molecular underpinnings of prion infectivity

Prion diseases, or transmissible spongiform encephalopathies, have revealed the bewildering phenomenon of transmissibility in neurodegenerative diseases. Hence, the experimental transmissibility of prion-like neurodegenerative diseases via template directed misfolding has become the focus of intense research. Gerstmann-Sträussler-Scheinker disease (GSS) is an inherited prion disease associated with mutations in the prion protein gene. However, with the exception of a few GSS cases with P102L mutation characterized by co-accumulation of protease-resistant PrP core (PrP^res) of ～21?kDa, attempts to transmit to rodents GSS associated to atypical misfolded prion protein with ～8 kDa PrP^res have been unsuccessful. As a result, these GSS subtypes have often been considered as non-transmissible proteinopathies rather than true prion diseases. In a recent study we inoculated bank voles with GSS cases associated with P102L, A117V and F198S mutations and found that they transmitted efficiently and produced distinct pathological phenotypes, irrespective of the presence of 21?kDa PrP^res in the inoculum. This study demonstrates that GSS is a genuine prion disease characterized by both transmissibility and strain variation. We discuss the implications of these findings for the understanding of the heterogeneous clinic-pathological phenotypes of GSS and of the molecular underpinnings of prion infectivity.     

Disease-associated F198S mutation increases the propensity of the recombinant prion protein for conformational conversion to scrapie-like form

The critical step in the pathogenesis of transmissible spongiform encephalopathies (prion diseases) is the conversion of a cellular prion protein (PrP(c)) into a protease-resistant, beta-sheet rich form (PrP(Sc)). Although the disease transmission normally requires direct interaction between exogenous PrP(Sc) and endogenous PrP(C), the pathogenic process in hereditary prion diseases appears to develop spontaneously (i.e. not requiring infection with exogenous PrP(Sc)). To gain insight into the molecular basis of hereditary spongiform encephalopathies, we have characterized the biophysical properties of the recombinant human prion protein variant containing the mutation (Phe(198) --> Ser) associated with familial Gerstmann-Straussler-Scheinker disease. Compared with the wild-type protein, the F198S variant shows a dramatically increased propensity to self-associate into beta-sheet-rich oligomers. In a guanidine HCl-containing buffer, the transition of the F198S variant from a normal alpha-helical conformation into an oligomeric beta-sheet structure is about 50 times faster than that of the wild-type protein. Importantly, in contrast to the wild-type PrP, the mutant protein undergoes a spontaneous conversion to oligomeric beta-sheet structure even in the absence of guanidine HCl or any other denaturants. In addition to beta-sheet structure, the oligomeric form of the protein is characterized by partial resistance to proteinase K digestion, affinity for amyloid-specific dye, thioflavine T, and fibrillar morphology. The increased propensity of the F198S variant to undergo a conversion to a PrP(Sc)-like form correlates with a markedly decreased thermodynamic stability of the native alpha-helical conformer of the mutant protein. This correlation supports the notion that partially unfolded intermediates may be involved in conformational conversion of the prion protein.     

Prion protein with an E200K mutation displays properties similar to those of the cellular isoform PrP(C)

Creutzfeldt-Jakob disease (CJD) in Libyan Jews, linked to the E200K mutation in PRNP (E200KCJD), is the most prevalent of the inherited prion diseases. As other prion diseases, E200KCJD is characterized by the brain accumulation of PrP(Sc), a pathologic conformational isoform of a normal glycoprotein denominated PrP(C). To investigate whether the E200K mutation is enough to de novo confer PrP(Sc) properties to mutant PrP, as suggested by experiments in Chinese hamster ovary cells, we examined the biochemical behavior of E200KPrP in brains and fibroblasts from sporadic as well as homozygous and heterozygous E200KCJD patients, asymptomatic transgenic mice carrying the E200K mutation, as well as in normal and scrapie-infected mouse neuroblastoma cells expressing E200KPrP. E200KPrP was examined for protease sensitivity, solubility in detergents, releasibility by phosphoinositol phospholypase-C and localization in cholesterol enriched membrane microdomains (rafts). In all tissues except in brains of CJD patients and ScN2a cells, E200KPrP displayed properties similar to those of PrP(C). Our results indicate that the E200K mutation does not automatically convey the properties of PrP(Sc) to new PrP molecules. A conversion process occurs mainly in the prion disease affected brain, suggesting the presence of a tissue-specific or age-dependent factor, in accord with the late onset nature of inherited CJD.     

Y145Stop is sufficient to induce de novo generation prions using protein misfolding cyclic amplification

A point mutation in Prnp that converts tyrosine (Y) at position 145 into a stop codon leading to a truncated prion molecule as found in an inherited transmissible spongiform encephalopathy (TSE), Gertsmann-Sträussler-Scheincker syndrome, suggests that the N-terminus of the molecule (spanning amino acids 23–144) likely plays a critical role in prion misfolding as well as in protein-protein interactions. We hypothesized that Y145Stop molecule represents an unstable part of the prion protein that is prone to spontaneous misfolding. Utilizing protein misfolding cyclic amplification (PMCA) we show that the recombinant polypeptide corresponding to the Y145Stop of sheep and deer PRNP can be in vitro converted to PK-resistant PrP^Sc in presence or absence of preexisting prions. In contrast, recombinant protein full-length PrP^C did not show a propensity for spontaneous conformational conversion to protease resistant isoforms. Further, we show that seeded or spontaneously misfolded Y145Stop molecules can efficiently convert purified mammalian PrP^C into protease resistant isoforms. These results establish that the N-terminus of PrP^C molecule corresponding to residues 23–144 plays a role in seeding and misfolding of mammalian prions.     

Multiple biochemical similarities between infectious and non-infectious aggregates of a prion protein carrying an octapeptide insertion

A nine-octapeptide insertion in the prion protein (PrP) gene is associated with an inherited form of human prion disease. Transgenic (Tg) mice that express the mouse homolog of this mutation (designated PG14) spontaneously accumulate in their brains an insoluble and weakly protease-resistant form of the mutant protein. This form (designated PG14(Spon)) is highly neurotoxic, but is not infectious in animal bioassays. In contrast, when Tg(PG14) mice are inoculated with the Rocky Mountain Laboratory (RML) strain of prions, they accumulate a different form of PG14 PrP (designated PG14(RML)) that is highly protease resistant and infectious in animal transmission experiments. We have been interested in characterizing the molecular properties of PG14(Spon) and PG14(RML), with a view to identifying features that determine two, apparently distinct properties of PrP aggregates: their infectivity and their pathogenicity. In this paper, we have subjected PG14(Spon) and PG14(RML) to a panel of assays commonly used to distinguish infectious PrP (PrP(Sc)) from cellular PrP (PrP(C)), including immobilized metal affinity chromatography, precipitation with sodium phosphotungstate, and immunoprecipitation with PrP(C)- and PrP(Sc)-specific antibodies. Surprisingly, we found that aggregates of PG14(Spon) and PG14(RML) behave identically to each other, and to authentic PrP(Sc), in each of these biochemical assays. PG14(Spon) however, in contrast to PG14(RML) and PrP(Sc), was unable to seed the misfolding of PrP(C) in an in vitro protein misfolding cyclic amplification reaction. Collectively, these results suggest that infectious and non-infectious aggregates of PrP share common structural features accounting for their toxicity, and that self-propagation of PrP involves more subtle molecular differences.     

Prion Protein Prolines 102 and 105 and the Surrounding Lysine Cluster Impede Amyloid Formation

Human prion diseases can have acquired, sporadic, or genetic origins, each of which results in the conversion of prion protein (PrP) to transmissible, pathological forms. The genetic prion disease Gerstmann-Straussler-Scheinker syndrome can arise from point mutations of prolines 102 or 105. However, the structural effects of these two prolines, and mutations thereof, on PrP misfolding are not well understood. Here, we provide evidence that individual mutations of Pro-102 or Pro-105 to noncyclic aliphatic residues such as the Gerstmann-Straussler-Scheinker-linked leucines can promote the in vitro formation of PrP amyloid with extended protease-resistant cores reminiscent of infectious prions. This effect was enhanced by additional charge-neutralizing mutations of four nearby lysine residues comprising the so-called central lysine cluster. Substitution of these proline and lysine residues accelerated PrP conversion such that spontaneous amyloid formation was no longer slower than scrapie-seeded amyloid formation. Thus, Pro-102 and Pro-105, as well as the lysines in the central lysine cluster, impede amyloid formation by PrP, implicating these residues as key structural modulators in the conversion of PrP to disease-associated types of amyloid.     

Molecular morphology and toxicity of cytoplasmic prion protein aggregates in neuronal and non-neuronal cells

Recent studies have revealed that accumulation of prion protein (PrP) in the cytoplasm results in the production of aggregates that are insoluble in non-ionic detergents and partially resistant to proteinase K. Transgenic mice expressing PrP in the cytoplasm develop severe ataxia with cerebellar degeneration and gliosis, suggesting that cytoplasmic PrP may play a role in the pathogenesis of prion diseases. The mechanism of cytoplasmic PrP neurotoxicity is not known. In this report, we determined the molecular morphology of cytoplasmic PrP aggregates by immunofluorescence and electron microscopy, in neuronal and non-neuronal cells. Transient expression of cytoplasmic PrP produced juxtanuclear aggregates reminiscent of aggresomes in human embryonic kidney 293 cells, human neuroblastoma BE2-M17 cells and mouse neuroblastoma N2a cells. Time course studies revealed that discrete aggregates form first throughout the cytoplasm, and then coalesce to form an aggresome. Aggresomes containing cytoplasmic PrP were 1-5-microm inclusion bodies and were filled with electron-dense particles. Cytoplasmic PrP aggregates induced mitochondrial clustering, reorganization of intermediate filaments, prevented the secretion of wild-type PrP molecules and diverted these molecules to the cytoplasm. Cytoplasmic PrP decreased the viability of neuronal and non-neuronal cells. We conclude that any event leading to accumulation of PrP in the cytoplasm is likely to result in cell death.     

Misfolding of the prion protein at the plasma membrane induces endocytosis, intracellular retention and degradation

Suramin induces misfolding of the cellular prion protein (PrP(C)) and interferes with the propagation of infectious scrapie prions. A mechanistic analysis of this effect revealed that suramin-induced misfolding occurs at the plasma membrane and is dependent on the proximal region of the C-terminal domain (aa 90-158) of PrP(C). The conformational transition induces rapid internalization, mediated by the unstructured N-terminal domain, and subsequent intracellular degradation of PrP(C). As a consequence, PrP Delta N adopts a misfolded conformation at the plasma membrane; however, internalization is significantly delayed. We also found that misfolding and intracellular retention of PrP(C) can be induced by copper and that, moreover, copper interferes with the propagation of the pathogenic prion protein (PrP(Sc)) in scrapie-infected N2a cells. Our study revealed a quality control pathway for aberrant PrP conformers present at the plasma membrane and identified distinct PrP domains involved.     

The Unfolded State of the Murine Prion Protein and Properties of Single-point Mutants Related to Human Prion Diseases

The prion protein can exist both in a normal cellular isoform and in a pathogenic conformational isoform. The latter is responsible for the development of different neurodegenerative diseases, for example Creutzfeldt-Jakob disease or fatal familial insomnia. To convert the native benign state of the protein into a highly ordered fibrillar aggregate, large-scale rearrangements of the tertiary structure are necessary during the conversion process and intermediates that are at least partially unfolded are present during fibril formation. In addition to the sporadic conversion into the pathogenic isoform, more than 20 familial diseases are known that are caused by single point mutations increasing the probability of aggregation and neurodegeneration. Here, we demonstrate that the chemically denatured states of the mouse and human prion proteins have very similar structural and dynamic characteristics. Initial studies on the single point mutants E196K, F198S, V203I and R208H of the oxidized mouse construct, which are related to human prion diseases, reveal significant differences in the rate of aggregation. Aggregation for mutants V203I and R208H is slower than it is for the wild type, and the constructs E196K and F198S show accelerated aggregation. These differences in aggregation behaviour are not correlated with the thermal stability of the mutants, indicating different mechanisms promoting the conformational conversion process.     

Molecular mechanisms of functional rescue mediated by P53 tumor suppressor mutations

We have utilized both molecular dynamics simulations and solution biophysical measurements to investigate the rescue mechanism of mutation N235K, which plays a key role in the recently identified global suppressor motif of K235/Y239/R240 in the human p53 DNA-binding domain (DBD). Previous genetic analysis indicates that N235K alone rescues five out of six destabilized cancer mutants. However, the solution biophysical measurement shows that N235K generates only a slight increase to the stability of DBD, implying a rescue mechanism that is not a simple additive contribution to thermodynamic stability. Our molecular simulations show that the N235K substitution generates two non-native salt bridges with residues D186 and E198. We find that the nonnative salt bridges, D186-K235 and E198-K235, and a native salt bridge, E171-R249, are mutually exclusive, thus resulting in only a marginal increase in stability as compared to the wild type protein. When a destabilized V157F is paired with N235K, the native salt bridge E171-R249 is retained. In this context, the non-native salt bridges, D186-K235 and E198-K235, produce a net increase in stability as compared to V157F alone. A similar rescue mechanism may explain how N235K stabilize other highly unstable β-sandwich cancer mutants.     

Structural and Dynamic Properties of the Human Prion Protein

Prion diseases involve the conformational conversion of the cellular prion protein (PrP^C) to its misfolded pathogenic form (PrP^Sc). To better understand the structural mechanism of this conversion, we performed extensive all-atom, explicit-solvent molecular-dynamics simulations for three structures of the wild-type human PrP (huPrP) at different pH values and temperatures. Residue 129 is polymorphic, being either Met or Val. Two of the three structures have Met in position 129 and the other has Val. Lowering the pH or raising the temperature induced large conformational changes of the C-terminal globular domain and increased exposure of its hydrophobic core. In some simulations, HA and its preceding S1-HA loop underwent large displacements. The C-terminus of HB was unstable and sometimes partially unfolded. Two hydrophobic residues, Phe-198 and Met-134, frequently became exposed to solvent. These conformational changes became more dramatic at lower pH or higher temperature. Furthermore, Tyr-169 and the S2-HB loop, or the X-loop, were different in the starting structures but converged to common conformations in the simulations for the Met-129, but not the Val-129, protein. α-Strands and β-strands formed in the initially unstructured N-terminus. α-Strand propensity in the N-terminus was different between the Met-129 and Val129 proteins, but β-strand propensity was similar. This study reveals detailed structural and dynamic properties of huPrP, providing insight into the mechanism of the conversion of PrP^C to PrP^Sc.     

Stability and Cu(II) binding of prion protein variants related to inherited human prion diseases

All inherited forms of human prion diseases are linked with mutations in the prion protein (PrP) gene. Here we have investigated the stability and Cu(II) binding properties of three recombinant variants of murine full-length PrP(23-231)-containing destabilizing point mutations that are associated with human Gerstmann-Str?ussler-Scheinker disease (F198S), Creutzfeld-Jakob disease (E200K), and fatal familial insomnia (D178N) by electron paramagnetic resonance and circular dichroism spectroscopy. Furthermore, we analyzed the variants H140S, H177S, and H187S of the isolated C-terminal domain of murine PrP, mPrP(121-231), to test a role of the histidine residues in Cu(II) binding. The F198S and E200K variants of PrP(23-231) differed in Cu(II) binding from the wild-type mPrP(23-231). However, circular dichroism spectroscopy indicated that the variants and the wild type did not undergo conformational changes in the presence of Cu(II). The D178N variant showed a high tendency to aggregate at pH 7.4 both with and without Cu(II). At lower pH values, it showed the same Cu(II) binding behavior as the wild type. The analysis allowed for a better location of the Cu(II) binding sites in the C-terminal part of the protein. Our present data indicate that hereditary forms of prion diseases cannot be rationalized on the basis of altered Cu(II) binding or mutation-induced protein destabilization alone.     

Expression of the Prion Protein Family Member Shadoo Causes Drug Hypersensitivity That Is Diminished by the Coexpression of the Wild Type Prion Protein

The prion protein (PrP) seems to exert both neuroprotective and neurotoxic activities. The toxic activities are associated with the C-terminal globular parts in the absence of the flexible N terminus, specifically the hydrophobic domain (HD) or the central region (CR). The wild type prion protein (PrP-WT), having an intact flexible part, exhibits neuroprotective qualities by virtue of diminishing many of the cytotoxic effects of these mutant prion proteins (PrPΔHD and PrPΔCR) when coexpressed. The prion protein family member Doppel, which possesses a three-dimensional fold similar to the C-terminal part of PrP, is also harmful to neuronal and other cells in various models, a phenotype that can also be eliminated by the coexpression of PrP-WT. In contrast, another prion protein family member, Shadoo (Sho), a natively disordered protein possessing structural features similar to the flexible N-terminal tail of PrP, exhibits PrP-WT-like protective properties. Here, we report that, contrary to expectations, Sho expression in SH-SY5Y or HEK293 cells induces the same toxic phenotype of drug hypersensitivity as PrPΔCR. This effect is exhibited in a dose-dependent manner and is also counteracted by the coexpression of PrP-WT. The opposing effects of Shadoo in different model systems revealed here may be explored to help discern the relationship of the various toxic activities of mutant PrPs with each other and the neurotoxic effects seen in neurodegenerative diseases, such as transmissible spongiform encephalopathy and Alzheimer disease.     

Prion protein—Semisynthetic prion protein (PrP) variants with posttranslational modifications

Deciphering the pathophysiologic events in prion diseases is challenging, and the role of posttranslational modifications (PTMs) such as glypidation and glycosylation remains elusive due to the lack of homogeneous protein preparations. So far, experimental studies have been limited in directly analyzing the earliest events of the conformational change of cellular prion protein (PrP^C) into scrapie prion protein (PrP^Sc) that further propagates PrP^C misfolding and aggregation at the cellular membrane, the initial site of prion infection, and PrP misfolding, by a lack of suitably modified PrP variants. PTMs of PrP, especially attachment of the glycosylphosphatidylinositol (GPI) anchor, have been shown to be crucially involved in the PrP^Sc formation. To this end, semisynthesis offers a unique possibility to understand PrP behavior invitro and invivo as it provides access to defined site‐selectively modified PrP variants. This approach relies on the production and chemoselective linkage of peptide segments, amenable to chemical modifications, with recombinantly produced protein segments. In this article, advances in understanding PrP conversion using semisynthesis as a tool to obtain homogeneous posttranslationally modified PrP will be discussed.     

The Volumetric Diversity of Misfolded Prion Protein Oligomers Revealed by Pressure Dissociation

Protein oligomerization has been associated with a wide range of diseases. High pressure approaches offer a powerful tool for deciphering the underlying molecular mechanisms by revealing volume changes associated with the misfolding and assembly reactions. We applied high pressure to induce conformational changes in three distinct β-sheet-rich oligomers of the prion protein PrP, a protein characterized by a variety of infectious quaternary structures that can propagate stably and faithfully and cause diseases with specific phenotypic traits. We show that pressure induces dissociation of the oligomers and leads to a lower volume monomeric PrP state that refolds into the native conformation after pressure release. By measuring the different pressure and temperature sensitivity of the tested PrP oligomers, we demonstrate significantly different void volumes in their quaternary structure. In addition, by focusing on the kinetic and energetic behavior of the pressure-induced dissociation of one specific PrP oligomer, we reveal a large negative activation volume and an increase in both apparent activation enthalpy and entropy. This suggests a transition state ensemble that is less structured and significantly more hydrated than the oligomeric state. Finally, we found that site-specific fluorescent labeling allows monitoring of the transient population of a kinetic intermediate in the dissociation reaction. Our results indicate that defects in atomic packing may deserve consideration as a new factor that influences differences between PrP assemblies and that could be relevant also for explaining the origin of prion strains.