Folding intermediates of the prion protein stabilized by hydrostatic pressure and low temperature

Prion diseases are associated with conformational conversion of the cellular prion protein, PrPC, into a misfolded form, PrPSc. We have investigated the equilibrium unfolding of the structured domain of recombinant murine prion protein, comprising residues 121-231 (mPrP-(121-231)). The equilibrium unfolding of mPrP-(121-231) by urea monitored by intrinsic fluorescence and circular dichroism (CD) spectroscopies indicated a two-state transition, without detectable folding intermediates. The fluorescent probe 4,4'-dianilino-1,1'-binaphthyl-5,5-disulfonic acid (bis-ANS) binds to native mPrP-(121-231), indicating exposure of hydrophobic domains on the protein surface. Increasing concentrations of urea (up to 4 M) caused the release of bound bis-ANS, whereas changes in intrinsic fluorescence and CD of mPrP took place only above 4 M urea. This indicates the existence of a partially unfolded conformation of mPrP, characterized by loss of bis-ANS binding and preservation of the overall structure of the protein, stabilized at low concentrations of urea. Hydrostatic pressure and low temperatures were also used to stabilize partially folded intermediates that are not detectable in the presence of chemical denaturants. Compression of mPrP to 3.5 kbar at 25 degrees C and pH 7 caused a slight decrease in intrinsic fluorescence emission and an 8-fold increase in bis-ANS fluorescence. Lowering the temperature to -9 degrees C under pressure reversed the decrease in intrinsic fluorescence and caused a marked (approximately 40-fold) increase in bis-ANS fluorescence. The increase in bis-ANS fluorescence at low temperatures was similar to that observed for mPrP at 1 atm at pH 4. These results suggest that pressure-assisted cold denaturation of mPrP stabilizes a partially folded intermediate that is qualitatively similar to the state obtained at acidic pH. Compression of mPrP in the presence of a subdenaturing concentration of urea stabilized another partially folded intermediate, and cold denaturation under these conditions led to complete unfolding of the protein. Possible implications of the existence of such partially folded intermediates in the folding of the prion protein and in the conversion to the PrPSc conformer are discussed.     

Electron paramagnetic resonance evidence for binding of Cu(2+) to the C-terminal domain of the murine prion protein.

Transmissible spongiform encephalopathies in mammals are believed to be caused by scrapie form of prion protein (PrP(Sc)), an abnormal, oligomeric isoform of the monomeric cellular prion protein (PrP(C)). One of the proposed functions of PrP(C) in vivo is a Cu(II) binding activity. Previous studies revealed that Cu(2+) binds to the unstructured N-terminal PrP(C) segment (residues 23-120) through conserved histidine residues. Here we analyzed the Cu(II) binding properties of full-length murine PrP(C) (mPrP), of its isolated C-terminal domain mPrP(121-231) and of the N-terminal fragment mPrP(58-91) in the range of pH 3-8 with electron paramagnetic resonance spectroscopy. We find that the C-terminal domain, both in its isolated form and in the context of the full-length protein, is capable of interacting with Cu(2+). Three Cu(II) coordination types are observed for the C-terminal domain. The N-terminal segment mPrP(58-91) binds Cu(2+) only at pH values above 5.0, whereas both mPrP(121-231) and mPrP(23-231) already show identical Cu(II) coordination in the pH range 3-5. As the Cu(2+)-binding N-terminal segment 58-91 is not required for prion propagation, our results open the possibility that Cu(2+) ions bound to the C-terminal domain are involved in the replication of prions, and provide the basis for further analytical studies on the specificity of Cu(II) binding by PrP.     

Prion Protein mPrP[F175A](121-231): Structure and Stability in Solution

The three-dimensional structures of prion proteins (PrPs) in the cellular form (PrP^C) include a stacking interaction between the aromatic rings of the residues Y169 and F175, where F175 is conserved in all but two so far analyzed mammalian PrP sequences and where Y169 is strictly conserved. To investigate the structural role of F175, we characterized the variant mouse prion protein mPrP[F175A](121-231). The NMR solution structure represents a typical PrP^C-fold, and it contains a 3₁₀-helical β2-α2 loop conformation, which is well defined because all amide group signals in this loop are observed at 20 °C. With this “rigid‐loop PrP^C” behavior, mPrP[F175A](121-231) differs from the previously studied mPrP[Y169A](121-231), which contains a type I β-turn β2-α2 loop structure. When compared to other rigid‐loop variants of mPrP(121-231), mPrP[F175A](121-231) is unique in that the thermal unfolding temperature is lowered by 8 °C. These observations enable further refined dissection of the effects of different single-residue exchanges on the PrP^C conformation and their implications for the PrP^C physiological function.     

Kinetic intermediate in the folding of human prion protein

Transmissible spongiform encephalopathies are associated with the conversion of cellular prion protein, PrP(C), into a misfolded oligomeric form, PrP(Sc). Here we have examined the kinetics of folding and unfolding reactions for the recombinant human prion protein C-terminal fragment 90-231 at pH 4.8 and 7.0. The stopped-flow data provide clear evidence for the population of an intermediate on the refolding pathway of the prion protein as indicated by a pronounced curvature in chevron plots and the presence of significant burst phase amplitude in the refolding kinetics. In addition to its role in the normal prion protein folding, this intermediate likely represents a crucial monomeric precursor of the pathogenic PrP(Sc) isoform.     

The effect of disease-associated mutations on the folding pathway of human prion protein

Propagation of transmissible spongiform encephalopathies is believed to involve the conversion of cellular prion protein, PrP(C), into a misfolded oligomeric form, PrP(Sc). An important step toward understanding the mechanism of this conversion is to elucidate the folding pathway(s) of the prion protein. We reported recently (Apetri, A. C., and Surewicz, W. K. (2002) J. Biol. Chem. 277, 44589-44592) that the folding of wild-type prion protein can best be described by a three-state sequential model involving a partially folded intermediate. Here we have performed kinetic stopped-flow studies for a number of recombinant prion protein variants carrying mutations associated with familial forms of prion disease. Analysis of kinetic data clearly demonstrates the presence of partially structured intermediates on the refolding pathway of each PrP variant studied. In each case, the partially folded state is at least one order of magnitude more populated than the fully unfolded state. The present study also reveals that, for the majority of PrP variants tested, mutations linked to familial prion diseases result in a pronounced increase in the thermodynamic stability, and thus the population, of the folding intermediate. These data strongly suggest that partially structured intermediates of PrP may play a crucial role in prion protein conversion, serving as direct precursors of the pathogenic PrP(Sc) isoform.     

NMR structure of the bank vole prion protein at 20 degrees C contains a structured loop of residues 165-171

The recent introduction of bank vole (Clethrionomys glareolus) as an additional laboratory animal for research on prion diseases revealed an important difference when compared to the mouse and the Syrian hamster, since bank voles show a high susceptibility to infection by brain homogenates from a wide range of diseased species such as sheep, goats, and humans. In this context, we determined the NMR structure of the C-terminal globular domain of the recombinant bank vole prion protein (bvPrP) [bvPrP(121-231)] at 20 °C. bvPrP(121-231) has the same overall architecture as other mammalian PrPs, with three α-helices and an antiparallel β-sheet, but it differs from PrP of the mouse and most other mammalian species in that the loop connecting the second β-strand and helix α2 is precisely defined at 20 °C. This is similar to the previously described structures of elk PrP and the designed mouse PrP (mPrP) variant mPrP[S170N,N174T](121-231), whereas Syrian hamster PrP displays a structure that is in-between these limiting cases. Studies with the newly designed variant mPrP[S170N](121-231), which contains the same loop sequence as bvPrP, now also showed that the single-amino-acid substitution S170N in mPrP is sufficient for obtaining a well-defined loop, thus providing the rationale for this local structural feature in bvPrP.     

Formation of soluble oligomers and amyloid fibrils with physical properties of the scrapie isoform of the prion protein from the C-terminal domain of recombinant murine prion protein mPrP-(121-231)

Prion diseases are fatal neurodegenerative disorders associated with conformational conversion of the cellular prion protein, PrP(C), into a misfolded, protease-resistant form, PrP(Sc). Here we show, for the first time, the oligomerization and fibrillization of the C-terminal domain of murine PrP, mPrP-(121-231), which lacks the entire unstructured N-terminal domain of the protein. In particular, the construct we used lacks amino acid residues 106-120 from the so-called amyloidogenic core of PrP (residues 106-126). Amyloid formation was accompanied by acquisition of resistance to proteinase K digestion. Aggregation of mPrP-(121-231) was investigated using a combination of biophysical and biochemical techniques at pH 4.0, 5.5, and 7.0 and at 37 and 65 degrees C. Under partially denaturing conditions (65 degrees C), aggregates of different morphologies ranging from soluble oligomers to mature amyloid fibrils of mPrP-(121-231) were formed. Transmission electron microscopy analysis showed that roughly spherical aggregates were readily formed when the protein was incubated at pH 5.5 and 65 degrees C for 1 h, whereas prolonged incubation led to the formation of mature amyloid fibrils. Samples incubated at 65 degrees C at pH 4.0 or 7.0 presented an initial mixture of oligomers and protofibrils or fibrils. Electrophoretic analysis of samples incubated at 65 degrees C revealed formation of sodium dodecyl sulfate-resistant oligomers (dimers, trimers, and tetramers) and higher molecular weight aggregates of mPrP-(121-231). These results demonstrate that formation of an amyloid form with physical properties of PrP(Sc) can be achieved in the absence of the flexible N-terminal domain and, in particular, of residues 106-120 of PrP and does not require other cellular factors or a PrP(Sc) template.     

Folding and intrinsic stability of deletion variants of PrP(121-231), the folded C-terminal domain of the prion protein

Transmissible spongiform encephalopathies in mammals are believed to be caused by PrPSc, the insoluble, oligomeric isoform of the cellular prion protein PrPC. PrPC and the subunits of PrPSc have identical covalent but different tertiary structure. To address the question of whether parts of the structure of PrPC are sufficiently stable to be retained in PrPSc, we have constructed two deletion variants of the C-terminal PrPC domain, PrP(121-231), which is the only part of recombinant PrP with defined tertiary structure. One of the variants, H2-H3, comprises the last two alpha-helices of PrP(121-231) that have been proposed to be preserved in models of PrP(Sc). In the other variant, PrP(121-231)-deltaH1, the first alpha-helix of PrP(121-231) was deleted and replaced by introduction of the beta-turn dipeptide Asn-Gly between the strands of the single beta-sheet of PrP(121-231). Although both deletion constructs still show alpha-helical CD-spectra, they are more disordered and thermodynamically strongly destabilized compared to PrP(121-231), with free energies of folding close to zero. These data demonstrate that the tertiary structure context is critical for the conformation of the segment comprising alpha-helix 2 and 3 in the solution structure of recombinant PrP.     

Locally disordered conformer of the hamster prion protein: a crucial intermediate to PrPSc?

A crucial step for transformation of the normal cellular isoform of the prion protein (PrP(C)) to the infectious prion protein (PrP(Sc)) is thought to entail a previously uncharacterized intermediate conformer, PrP*, which interacts with a template PrP(Sc) molecule in the conversion process. By carrying out (15)N-(1)H two-dimensional NMR measurements under variable pressure on Syrian hamster prion protein rPrP(90-231), we found a metastable conformer of PrP(C) coexisting at a population of approximately 1% at pH 5.2 and 30 degrees C, in which helices B and C are preferentially disordered. While the identity is still unproven, this observed metastable conformer is most logically PrP* or a closely related precursor. The structural characteristics of this metastable conformer are consistent with available immunological and pathological information about the prion protein.     

Prion Protein NMR Structure from Tammar Wallaby (Macropus eugenii) Shows that the β2-α2 Loop Is Modulated by Long-Range Sequence Effects

NMR structures are presented for the recombinant construct of residues 121-230 from the tammar wallaby (Macropus eugenii) prion protein (PrP) twPrP(121-230) and for the variant mouse PrPs mPrP[Y225A,Y226A](121-231) and mPrP[V166A](121-231) at 20 °C and pH 4.5. All three proteins exhibit the same global architecture as seen in other recombinant PrP^Cs (cellular isoforms of PrP) and shown to prevail in natural bovine PrP^C. Special interest was focused on a loop that connects the β2-strand with helix α2 in the PrP^C fold, since there are indications from in vivo experiments that this local structural feature affects the susceptibility of transgenic mice to transmissible spongiform encephalopathies. This β2-α2 loop and helix α3 form a solvent-accessible contiguous epitope, which has been proposed to be the recognition area for a hypothetical chaperone, the “protein X”. This hypothetical chaperone would affect the conversion of PrP^C into the disease-related scrapie form (PrP^Sc) by moderating intermolecular interactions related to the transmission barrier of transmissible spongiform encephalopathies between different species. In contrast to mPrP(121-231) and most other mammalian PrP^Cs, the β2-α2 loop is well defined at 20 °C in tammar wallaby PrP and in the two aforementioned variants of mPrP, showing that long-range interactions with helix α3 can have an overriding influence on the structural definition of the β2-α2 loop. Further NMR studies with two variant mPrPs, mPrP[Y225A](121-231) and mPrP[Y226A](121-231), showed that these interactions are dominantly mediated by close contacts between residues 166 and 225. The results of the present study then lead to the intriguing indication that well-defined long-range intramolecular interactions could act as regulators of the functional specificity of PrP^C.     

The role of the 132-160 region in prion protein conformational transitions

The native conformation of host-encoded cellular prion protein (PrP(C)) is metastable. As a result of a post-translational event, PrP(C) can convert to the scrapie form (PrP(Sc)), which emerges as the essential constituent of infectious prions. Despite thorough research, the mechanism underlying this conformational transition remains unknown. However, several studies have highlighted the importance of the N-terminal region spanning residues 90-154 in PrP folding. In order to understand why PrP folds into two different conformational states exhibiting distinct secondary and tertiary structure, and to gain insight into the involvement of this particular region in PrP transconformation, we studied the pressure-induced unfolding/ refolding of recombinant Syrian hamster PrP expanding from residues 90-231, and compared it with heat unfolding. By using two intrinsic fluorescent variants of this protein (Y150W and F141W), conformational changes confined to the 132-160 segment were monitored. Multiple conformational states of the Trp variants, characterized by their spectroscopic properties (fluorescence and UV absorbance in the fourth derivative mode), were achieved by tuning the experimental conditions of pressure and temperature. Further insight into unexplored conformational states of the prion protein, likely to mimic the in vivo structural change, was obtained from pressure-assisted cold unfolding. Furthermore, salt-induced conformational changes suggested a structural stabilizing role of Tyr150 and Phe141 residues, slowing down the conversion to a beta-sheet form.     

Prion protein 90-231 contains a streptavidin-binding motif

The biological function of prion protein (PrP) and the physiological relevance of its truncated subtypes and glycoforms is still enigmatic. In this paper, we adduce evidence that recombinant murine PrP fragment 90-231 (mPrP90-231) contains a biotin-mimicking sequence motif that causes binding of the bacterial protein streptavidin to mPrP90-231. As indicated by epitope mapping and proven by analysis of a deletion mutant (mPrP101-231), streptavidin binding is primarily mediated by the amino-terminus of mPrP90-231 with the core-binding sequence represented by residues 94-100. Competition with biotin significantly reduces the interaction pointing to an involvement of streptavidin's biotin-binding site (BBS). Since the BBS of streptavidin shares similarities with the active sites of proteins involved in biotin metabolism we speculate that biotin mimicry by truncated PrP-species may have an impact in vivo.     

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.     

Aggregation and fibrillization of the recombinant human prion protein huPrP90-231

According to the "protein-only" hypothesis, the critical step in the pathogenesis of prion diseases is the conformational transition between the normal (PrP(C)) and pathological (PrP(Sc)) isoforms of prion protein. To gain insight into the mechanism of this transition, we have characterized the biophysical properties of the recombinant protein corresponding to residues 90-231 of the human prion protein (huPrP90-231). Incubation of the protein under acidic conditions (pH 3.6-5) in the presence of 1 M guanidine-HCl resulted in a time-dependent transition from an alpha-helical conformation to a beta-sheet structure and oligomerization of huPrP90-231 into large molecular weight aggregates. No stable monomeric beta-sheet-rich folding intermediate of the protein could be detected in the present experiments. Kinetic analysis of the data indicates that the formation of beta-sheet structure and protein oligomerization likely occur concomitantly. The beta-sheet-rich oligomers were characterized by a markedly increased resistance to proteinase K digestion and a fibrillar morphology (i.e., they had the essential physicochemical properties of PrP(Sc)). Contrary to previous suggestions, the conversion of the recombinant prion protein into a PrP(Sc)-like form could be accomplished under nonreducing conditions, without the need to disrupt the disulfide bond. Experiments in urea indicate that, in addition to acidic pH, another critical factor controlling the transition of huPrP90-231 to an oligomeric beta-sheet structure is the presence of salt.     

The elusive intermediate on the folding pathway of the prion protein

A key molecular event in prion diseases is the conversion of the cellular conformation of the prion protein (PrP(C)) to an altered disease-associated form, generally denoted as scrapie isoform (PrP(Sc)). The molecular details of this conformational transition are not fully understood, but it has been suggested that an intermediate on the folding pathway of PrP(C) may be recruited to form PrP(Sc). In order to investigate the folding pathway of PrP we designed and expressed two mutants, each possessing a single strategically located tryptophan residue. The secondary structure and folding properties of the mutants were examined. Using conventional analyses of folding transition data determined by fluorescence and CD, and novel phase-diagram analyses, we present compelling evidence for the presence of an intermediate species on the folding pathway of PrP. The potential role of this intermediate in prion conversion is discussed.     

Recombinant human prion protein fragment 90-231, a useful model to study prion neurotoxicity

Transmissible spongiform encephalopathies (TSE), or prion diseases, are a group of fatal neurodegenerative disorders of animals and humans. Human diseases include Creutzfeldt-Jakob (CJD) and Gerstmann-Straussler-Scheinker (GSSD) diseases, fatal familial insomnia, and Kuru. Human and animal TSEs share a common histopathology with a pathognomonic triad: spongiform vacuolation of the grey matter, neuronal death, glial proliferation, and, more inconstantly, amyloid deposition. According to the "protein only" hypothesis, TSEs are caused by a unique post-translational conversion of normal, host-encoded, protease-sensitive prion protein (PrP(sen) or PrP(C)) to an abnormal disease-associated isoform (PrP(res) or PrP(Sc)). To investigate the molecular mechanism of neurotoxicity induced by PrP(Sc) we developed a protocol to obtain millimolar amounts of soluble recombinant polypeptide encompassing the amino acid sequence 90-231 of human PrP (hPrP90-231). This protein corresponds to the protease-resistant prion protein fragment that originates after amino-terminal truncation. Importantly, hPrP90-231 has a flexible backbone that, similar to PrP(C), can undergo to structural rearrangement. This peptide, structurally resembling PrP(C), can be converted in a PrP(Sc)-like conformation, and thus represents a valuable model to study prion neurotoxicity. In this article we summarized our experimental evidence on the molecular and structural mechanisms responsible of hPrP90-231 neurotoxicity on neuroectodermal cell line SHSY5Y and the effects of some PrP pathogen mutations identified in familial TSE.     

Oxidative folding of murine prion mPrP(23-231).

A systematic study of the oxidative folding of murine prion protein mPrP(23-231) is reported here. Folding of mPrP(23-231) involves formation of a single disulfide bond, Cys179-Cys214. Despite this simplicity, reduced mPrP(23-231) exhibits numerous unusual folding properties. In the absence of denaturant, folding of mPrP(23-231) is extremely sluggish, regardless of pH. The optimal pH for mPrP(23-231) folding was found to be 4-5. At pH 8.0, a condition that typically favors disulfide formation, folding of mPrP(23-231) hardly occurs, and it not facilitated by inclusion of redox agent. In the presence of denaturant (4 M urea or 2 M guanidine hydrochloride) and basic pH (8.0), reduced mPrP(23-231) refolds to the native structure quantitatively. The efficiency of folding can be further promoted by the presence of oxidized glutathione. At pH 4.0 and in the presence of 4 M urea, reduced mPrP(23-231) converts to three distinctive conformational isomers, unable to form the native structure. These unusual properties lead us to the following conclusions. The reduced mPrP(23-231) adopts a highly rigid structure with the two cysteines buried or situated apart. The presence of denaturant or low pH disrupts this rigid structure and lowers the energy barrier, which permits oxidation and refolding of the reduced mPrP(23-231). Under selected conditions, reduced mPrP(23-231) is capable of taking on multiple forms of stable conformational isomer that are segregated by energy barriers.     

Water molecules as structural determinants among prions of low sequence identity

The nature of the factors leading to the conversion of the cellular prion protein (PrP(C)) into its amyloidogenic isoform (PrP(Sc)) is still matter of debate in the field of structural biology. The NMR structures of non-mammalian PrP(C) (non-mPrP) from frog, chicken and turtle [Calzolai, L., Lysek, D.A., Perez, D.R., Guntert, P. and Wuthrich, K. (2005) Prion protein NMR structures of chickens, turtles, and frogs. Proc. Natl. Acad. Sci. USA 102, 651-655] have provided some new and valuable information on the scaffolding elements that preserve the PrP(C) folding, despite their low sequence identity with the mammalian prions (mPrP). The present molecular dynamics study of non-mPrP(C) focuses on the hydration properties of these proteins in comparison with the mammalian ones. The data reveal new insights in the PrP hydration and focus on the implications for PrP(C) folding stability and its propensity for interactions. In addition, for the first time, a role in disfavoring the PrP(C) aggregation is suggested for a conserved beta-bulge which is stabilized by the local hydration.     

Toxicity of novel C-terminal prion protein fragments and peptides harbouring disease-related C-terminal mutations.

Mice expressing a C-terminal fragment of the prion protein instead of wild-type prion protein die from massive neuronal degeneration within weeks of birth. The C-terminal region of PrPc (PrP121-231) expressed in these mice has an intrinsic neurotoxicity to cultured neurones. Unlike PrPSc, which is not neurotoxic to neurones lacking PrPc expression, PrP121-231 was more neurotoxic to PrPc-deficient cells. Human mutations E200K and F198S were found to enhance toxicity of PrP121-231 to PrP-knockout neurones and E200K enhanced toxicity to wild-type neurones. The normal metabolic cleavage point of PrPc is approximately amino-acid residue 113. A fragment of PrPc corresponding to the whole C-terminus of PrPc (PrP113-231), which is eight amino acids longer than PrP121-231, lacked any toxicity. This suggests the first eight amino residues of PrP113-121 suppress toxicity of the toxic domain in PrP121-231. Addition to cultures of a peptide (PrP112-125) corresponding to this region, in parallel with PrP121-231, suppressed the toxicity of PrP121-231. These results suggest that the prion protein contains two domains that are toxic on their own but which neutralize each other's toxicity in the intact protein. Point mutations in the inherited forms of disease might have their effects by diminishing this inhibition.     

DNA converts cellular prion protein into the beta-sheet conformation and inhibits prion peptide aggregation

The main hypothesis for prion diseases proposes that the cellular protein (PrP(C)) can be altered into a misfolded, beta-sheet-rich isoform (PrP(Sc)), which in most cases undergoes aggregation. In an organism infected with PrP(Sc), PrP(C) is converted into the beta-sheet form, generating more PrP(Sc). We find that sequence-specific DNA binding to recombinant murine prion protein (mPrP-(23-231)) converts it from an alpha-helical conformation (cellular isoform) into a soluble, beta-sheet isoform similar to that found in the fibrillar state. The recombinant murine prion protein and prion domains bind with high affinity to DNA sequences. Several double-stranded DNA sequences in molar excess above 2:1 (pH 4.0) or 0.5:1 (pH 5.0) completely inhibit aggregation of prion peptides, as measured by light scattering, fluorescence, and circular dichroism spectroscopy. However, at a high concentration, fibers (or peptide aggregates) can rescue the peptide bound to the DNA, converting it to the aggregating form. Our results indicate that a macromolecular complex of prion-DNA may act as an intermediate for the formation of the growing fiber. We propose that host nucleic acid may modulate the delicate balance between the cellular and the misfolded conformations by reducing the protein mobility and by making the protein-protein interactions more likely. In our model, the infectious material would act as a seed to rescue the protein bound to nucleic acid. Accordingly, DNA would act on the one hand as a guardian of the Sc conformation, preventing its propagation, but on the other hand may catalyze Sc conversion and aggregation if a threshold level is exceeded.