Molecular chaperones and the assembly of the prion Ure2p in vitro

The protein Ure2 from Saccharomyces cerevisiae possesses prion properties at the origin of the [URE3] trait. In vivo, a high molecular weight form of inactive Ure2p is associated to [URE3]. The faithful and continued propagation of [URE3]is dependent on the expression levels of molecular chaperones from the Hsp100, -70, and -40 families; however, so far, their role is not fully documented. Here we investigate the effects of molecular chaperones from the Hsp40, Hsp70, Hsp90, and Hsp100 families and the chaperonin CCT/Tric on the assembly of full-length Ure2p. We show that Hsp104p greatly stimulates Ure2p aggregation, whereas Ssa1p, Ydj1p, Sis1p, and Hsp82p inhibit aggregation to different extents. The nature of the high molecular weight Ure2p species that forms in the presence of the different molecular chaperones and their nucleotide dependence is described. We show that Hsp104p favors the aggregation of Ure2p into non-fibrillar high molecular weight particles, whereas Ssa1p, Ydj1p, Sis1p, and Hsp82p sequester Ure2p in spherical oligomers. Using fluorescently labeled full-length Ure2p and Ure2p-(94-354) and fluorescence polarization, we show that Ssa1p binding to Ure2p is ATP-dependent, whereas that of Hsp104p is not. We also show that Ssa1p preferentially interacts with the N-terminal domain of Ure2p that is critical for prion propagation, whereas Ydj1p preferentially interacts with the C-terminal domain of the protein, and we discuss the significance of this observation. Finally, the affinities of Ssa1p, Ydj1p, and Hsp104p for Ure2p are determined. Our in vitro observations bring new insight into the mechanism by which molecular chaperones influence the propagation of [URE3].     

Recombinant expression and purification of Ssa1p (Hsp70) from Saccharomyces cerevisiae using Pichia pastoris

Heat shock proteins with a molecular mass of 70000 (Hsp70s) are a ubiquitous class of ATP-dependent molecular chaperones involved in the folding of cellular proteins. Sequencing the entire genome of Saccharomyces cerevisiae revealed 14 different genes for Hsp70 proteins in different cellular compartments. Among these 14 Hsp70s, the subclass of Ssa (Ssa1p-Ssa4p) is abundant and essential in the cytosol. Since high yield expression of cytoplasmic Ssa1p is inefficient in Saccharomyces cerevisiae and recombinant expression in E. coli yields low protein levels, we chose Pichia pastoris as the recombinant expression system. In Pichia pastoris, expression levels of Ssa1p are high and Ssa1p is soluble and correctly folded. Also, we present a new protocol for purification of Ssa1p. Previously described purifications include ATP-agarose chromatography leading to Ssa1p partially complexed with ATP. Our optimized purification protocol follows the CiPP strategy (capture, intermediate purification, polishing) avoiding ATP-agarose chromatography, which allows detailed studies on the ATP-dependent Hsp70 functions. We obtained Ssa1p in high purity and 400 times higher quantity compared to previous studies.     

Hydrogen/deuterium exchange mass spectrometric analysis of conformational changes accompanying the assembly of the yeast prion Ure2p into protein fibrils

The Ure2 protein from baker's yeast (Saccharomyces cerevisiae) has prion properties. In vitro, at neutral pH, soluble Ure2p forms long, twisted fibrils. Two models have been proposed to account for Ure2p polymerization. The first postulates that a segment of 70 amino acid residues in the flexible N-terminal domain from different Ure2p molecules forms a parallel superpleated beta-structure running along the fibrils. The second hypothesizes that assembly of full-length Ure2p is driven by limited conformational rearrangements and non-native inter- and intramolecular interactions. The knowledge of the three-dimensional structure of the fibrillar form of Ure2p is critical for understanding the molecular events leading to the polymerization of soluble Ure2p into fibrils and hence for the design of inhibitors that might have therapeutic potential as yeast prions possessing domains rich in N and Q residues, similar to huntingtin. Solvent-accessibility studies using hydrogen/deuterium exchange monitored by mass spectrometry (HXMS) can provide insights into the structure of the fibrillar form of Ure2p and characterize at the molecular level the conformational rearrangements that occur upon assembly, in particular through the identification of protected regions and their localization in the overall structure of the protein. We have analyzed the changes in Ure2p structure associated with its assembly into fibrils using HXMS. The deuterium incorporation profile along the sequence allows the identification of the regions that exhibit the most important conformational change. Our data reveal that Ure2p undergoes minor structural changes upon assembly. While polypeptides [82-92] and [13-37] exhibit significant increased and decreased exposure to the solvent, respectively, no marked change was observed for the rest of the protein upon assembly. Our results afford new insights into the conformational rearrangements that lead to the assembly of Ure2p into fibrils and the propagation of the [URE3] element in yeast.     

Molecular chaperones and the assembly of the prion Sup35p, an in vitro study

The protein Sup35 from Saccharomyces cerevisiae possesses prion properties. In vivo, a high molecular weight form of Sup35p is associated to the [PSI+] factor. The continued propagation of [PSI+] is highly dependent on the expression levels of molecular chaperones from the Hsp100, 70 and 40 families; however, so far, their role in this process is unclear. We have developed a reproducible in vitro system to study the effects of molecular chaperones on the assembly of full-length Sup35p. We show that Hsp104p greatly stimulates the assembly of Sup35p into fibrils, whereas Ydj1p has inhibitory effect. Hsp82p, Ssa1p and Sis1p, individually, do not affect assembly. In contrast, Ssa1p together with either of its Hsp40 cochaperones blocks Sup35p polymerization. Furthermore, Ssa1p and Ydj1p or Sis1p can counteract the stimulatory activity of Hsp104p, by forming complexes with Sup35p oligomers, in an ATP-dependent manner. Our observations reveal the functional differences between Hsp104p and the Hsp70-40 systems in the assembly of Sup35p into fibrils and bring new insight into the mechanism by which molecular chaperones influence the propagation of [PSI+].     

Structure and Assembly Properties of the N-Terminal Domain of the Prion Ure2p in Isolation and in Its Natural Context

Background

The aggregation of the baker''s yeast prion Ure2p is at the origin of the [URE3] trait. The Q- and N-rich N-terminal part of the protein is believed to drive Ure2p assembly into fibrils of amyloid nature and the fibrillar forms of full-length Ure2p and its N-terminal part generated in vitro have been shown to induce [URE3] occurrence when introduced into yeast cells. This has led to the view that the fibrillar form of the N-terminal part of the protein is sufficient for the recruitment of constitutive Ure2p and that it imprints its amyloid structure to full-length Ure2p.

Results

Here we generate a set of Ure2p N-terminal fragments, document their assembly and structural properties and compare them to that of full-length Ure2p. We identify the minimal region critical for the assembly of Ure2p N-terminal part into amyloids and show that such fibrils are unable to seed the assembly of full length Ure2p unlike fibrils made of intact Ure2p.

Conclusion

Our results clearly indicate that fibrillar Ure2p shares no structural similarities with the amyloid fibrils made of Ure2p N-terminal part. Our results further suggest that the induction of [URE3] by fibrils made of full-length Ure2p is likely the consequence of fibrils growth by depletion of cytosolic Ure2p while it is the consequence of de novo formation of prion particles following, for example, titration within the cells of a specific set of molecular chaperones when fibrils made of Ure2p N-terminal domain are introduced within the cytoplasm.     

Stability, folding, dimerization, and assembly properties of the yeast prion Ure2p

The [URE3] factor of Saccharomyces cerevisiae propagates by a prion-like mechanism and corresponds to the loss of the function of the cellular protein Ure2. The molecular basis of the propagation of this phenotype is unknown. We recently expressed Ure2p in Escherichia coli and demonstrated that the N-terminal region of the protein is flexible and unstructured, while its C-terminal region is compactly folded. Ure2p oligomerizes in solution to form mainly dimers that assemble into fibrils [Thual et al. (1999) J. Biol. Chem. 274, 13666-13674]. To determine the role played by each domain of Ure2p in the overall properties of the protein, specifically, its stability, conformation, and capacity to assemble into fibrils, we have further analyzed the properties of Ure2p N- and C-terminal regions. We show here that Ure2p dimerizes through its C-terminal region. We also show that the N-terminal region is essential for directing the assembly of the protein into a particular pathway that yields amyloid fibrils. A full-length Ure2p variant that possesses an additional tryptophan residue in its N-terminal moiety was generated to follow conformational changes affecting this domain. Comparison of the overall conformation, folding, and unfolding properties, and the behavior upon proteolytic treatments of full-length Ure2p, Ure2pW37 variant, and Ure2p C-terminal fragment reveals that Ure2p N-terminal domain confers no additional stability to the protein. This study reveals the existence of a stable unfolding intermediate of Ure2p under conditions where the protein assembles into amyloid fibrils. Our results contradict the intramolecular interaction between the N- and C-terminal moieties of Ure2p and the single unfolding transitions reported in a number of previous studies.     

Structure of the prion Ure2p in protein fibrils assembled in vitro

The Ure2 protein from the yeast Saccharomyces cerevisiae has prion properties. In vitro and at neutral pH, soluble Ure2p spontaneously forms long, straight, insoluble protein fibrils. Two models have been proposed to account for the assembly of Ure2p into protein fibrils. The "amyloid backbone" model postulates that a segment ranging from 40 to 70 amino acids in the flexible N-terminal domain from different Ure2p molecules forms a parallel superpleated beta-structure running along the fibrils. The second model hypothesizes that assembly of full-length Ure2p is driven by limited conformational rearrangements and non-native inter- and/or intramolecular interactions between Ure2p monomers. Here, we performed a cysteine scan on residues located in the N- and C-terminal parts of Ure2p to determine whether these domains interact. Amino acid sequences centered around residue 6 in the N-terminal domain of Ure2p and residue 137 in the C-terminal moiety interacted at least transiently via intramolecular interactions. We documented the assembly properties of a Ure2p variant in which a disulfide bond was established between the N- and C-terminal domains and showed that it possesses assembly properties indistinguishable from those of wild-type Ure2p. We probed the structure of Ure2pC6C137 within the fibrils and demonstrate that the polypeptide is in a conformation similar to that of its soluble assembly-competent state. Our results constitute the first structural characterization of the N-terminal domain of Ure2p in both its soluble assembly-competent and fibrillar forms. Our data indicate that the flexibility of the N-terminal domain and conformational changes within this domain are essential for fibril formation and provide new insight into the conformational rearrangements that lead to the assembly of Ure2p into fibrils and the propagation of the [URE3] phenotype in yeast.     

Structure and assembly properties of the yeast prion Ure2p

The non-Mendelian phenotype [URE3] is due to a transmissible conformational change of the protein Ure2. The infectious protein form of Ure2p has lost its function and gained the capacity to transform the active form of the protein into an inactive form. The molecular basis of this conversion process is unknown. There are however indications that the conformational changes at the origin of the propagation of the inactive form of Ure2p in yeast cells are similar to those at the origin of the transition of PrPC into the scrapie-associated PrPSc form of the protein. To better understand the nature of the conformational changes at the origin of prion propagation, we have purified, characterized biochemically, examined the assembly properties and solved the crystal structure of Ure2p. Our data are presented below and a number of conclusions dealing with the molecular basis of the conversion of soluble Ure2p into its amyloid-forming state are derived.     

Structural characterization of the fibrillar form of the yeast Saccharomyces cerevisiae prion Ure2p

The protein Ure2 from the yeast Saccharomyces cerevisiae has prion properties. It assembles in vitro into long, straight, insoluble fibrils that are similar to amyloids in that they bind Congo Red and show green-yellow birefringence and have an increased resistance to proteolysis. We recently showed that Ure2p fibrils assembled under physiologically relevant conditions are devoid of a cross-beta-core. A model for fibril formation, where assembly is driven by non-native inter- and/or intramolecular interaction between Ure2p monomers following subtle conformational changes was proposed [Bousset et al. (2002) EMBO J. 21, 2903-2911]. An alternative model for the assembly of Ure2p into fibrils where assembly is driven by the stacking of 40-70 N-terminal amino acid residues of Ure2p into a central beta-core running along the fibrils from which the C-terminal domains protrude was proposed [Baxa et al. (2003) J. Biol. Chem. 278, 43717-43727]. We show here that Ure2p fibril congophilia and the associated yellow-green birefringence in polarized light are not indicative that the fibrils are of amyloid nature. We map the structures of the fibrillar and soluble forms of Ure2p using limited proteolysis and identify the reaction products by microsequencing and mass spectrometry. Finally, we demonstrate that the C-terminal domain of Ure2p is tightly involved in the fibrillar scaffold using a sedimentation assay and a variant Ure2p where a highly specific cleavage site between the N- and C-terminal domains of the protein was engineered. Our results are inconsistent with the cross-beta-core model and support the model for Ure2p assembly driven by subtle conformational changes and underline the influence of the natural context of the N-terminal domain on the assembly of Ure2p.     

Parallel beta-sheets and polar zippers in amyloid fibrils formed by residues 10-39 of the yeast prion protein Ure2p

We report the results of solid-state nuclear magnetic resonance (NMR) and atomic force microscopy measurements on amyloid fibrils formed by residues 10-39 of the yeast prion protein Ure2p (Ure2p(10)(-)(39)). Measurements of intermolecular (13)C-(13)C nuclear magnetic dipole-dipole couplings indicate that Ure2p(10)(-)(39) fibrils contain in-register parallel beta-sheets. Measurements of intermolecular (15)N-(13)C dipole-dipole couplings, using a new solid-state NMR technique called DSQ-REDOR, are consistent with hydrogen bonds between side chain amide groups of Gln18 residues. Such side chain hydrogen bonding interactions have been called "polar zippers" by M. F. Perutz and have been proposed to stabilize amyloid fibrils formed by peptides with glutamine- and asparagine-rich sequences, such as Ure2p(10)(-)(39). We propose that polar zipper interactions account for the in-register parallel beta-sheet structure in Ure2p(10)(-)(39) fibrils and that similar peptides will also exhibit parallel beta-sheet structures in amyloid fibrils. We present molecular models for Ure2p(10)(-)(39) fibrils that are consistent with available experimental data. Finally, we show that solid-state (13)C NMR chemical shifts for (13)C-labeled Ure2p(10)(-)(39) fibrils are insensitive to hydration level, indicating that the fibril structure is not affected by the presence or absence of bulk water.     

Fes1p acts as a nucleotide exchange factor for the ribosome-associated molecular chaperone Ssb1p

The HspBP1 homolog Fes1p was recently identified as a nucleotide exchange factor (NEF) of Ssa1p, a canonical Hsp70 molecular chaperone in the cytosol of Saccharomyces cerevisiae. Besides the Ssa-type Hsp70s, the yeast cytosol contains three additional classes of Hsp70, termed Ssb, Sse and Ssz. Here, we show that Fes1p also functions as NEF for the ribosome-bound Ssb Hsp70s. Sequence analysis indicated that residues important for interaction with Fes1p are highly conserved in Ssa1p and Ssb1p, but not in Sse1p and Ssz1p. Indeed, Fes1p interacts with Ssa1p and Ssb1p with similar affinity, but does not form a complex with Sse1p. Functional analysis showed that Fes1p accelerates the release of the nucleotide analog MABA-ADP from Ssb1p by a factor of 35. In contrast to the interaction between mammalian HspBP1 and Hsp70, however, addition of ATP only moderately decreases the affinity of Fes1p for Ssb1p. Point mutations in Fes1p abolishing complex formation with Ssa1p also prevent the interaction with Ssb1p. The ATPase activity of Ssb1p is stimulated by the ribosome-associated complex of Zuotin and Ssz1p (RAC). Interestingly, Fes1p inhibits the stimulation of Ssb1p ATPase by RAC, suggesting a complex regulatory role of Fes1p in modulating the function of Ssb Hsp70s in co-translational protein folding.     

Packing of the prion Ure2p in protein fibrils probed by fluorescence X-ray near-edge structure spectroscopy at sulfur K-edge

The soluble protein Ure2p from the yeast Saccharomyces cerevisiae assembles in vitro into straight and insoluble protein fibrils, through subtle changes of conformation. Whereas the structure of soluble Ure2p has been revealed by X-ray crystallography, further characterization of the structure of insoluble Ure2p fibrils is needed. We performed X-ray absorption near-edge spectroscopy (XANES) at the sulfur K-edge to probe the state of Cys221 in the fibrillar form of Ure2pC221 and provide structural information on the structure of Ure2p within fibrils. Although the Ure2p dimer dissociation into its constituent monomers has proven to be a prerequisite for assembly into fibrils, we showed the ability of every Ure2pC221 monomer to establish disulfide bonds upon incubation of the fibrils under oxidizing conditions. Our result indicates either that the constituent unit of the fibrillar form of the protein is a dimeric Ure2p or that the fibrils are made of protofilaments assembled in such a way that the residue C221 from a Ure2p molecule in one protofilament is located in the vicinity of a C221 residue from another molecule belonging to a neighbor protofilament.     

Antagonistic interactions between yeast [PSI(+)] and [URE3] prions and curing of [URE3] by Hsp70 protein chaperone Ssa1p but not by Ssa2p

The yeast [PSI(+)], [URE3], and [PIN(+)] genetic elements are prion forms of Sup35p, Ure2p, and Rnq1p, respectively. Overexpression of Sup35p, Ure2p, or Rnq1p leads to increased de novo appearance of [PSI(+)], [URE3], and [PIN(+)], respectively. This inducible appearance of [PSI(+)] was shown to be dependent on the presence of [PIN(+)] or [URE3] or overexpression of other yeast proteins that have stretches of polar residues similar to the prion-determining domains of the known prion proteins. In a similar manner, [PSI(+)] and [URE3] facilitate the appearance of [PIN(+)]. In contrast to these positive interactions, here we find that in the presence of [PIN(+)], [PSI(+)] and [URE3] repressed each other's propagation and de novo appearance. Elevated expression of Hsp104 and Hsp70 (Ssa2p) had little effect on these interactions, ruling out competition between the two prions for limiting amounts of these protein chaperones. In contrast, we find that constitutive overexpression of SSA1 but not SSA2 cured cells of [URE3], uncovering a specific interaction between Ssa1p and [URE3] and a functional distinction between these nearly identical Hsp70 isoforms. We also find that Hsp104 abundance, which critically affects [PSI(+)] propagation, is elevated when [URE3] is present. Our results are consistent with the notion that proteins that have a propensity to form prions may interact with heterologous prions but, as we now show, in a negative manner. Our data also suggest that differences in how [PSI(+)] and [URE3] interact with Hsp104 and Hsp70 may contribute to their antagonistic interactions.     

Crystal structures of the yeast prion Ure2p functional region in complex with glutathione and related compounds.

The [URE3] phenotype in yeast Saccharomyces cerevisiae is due to an altered prion form of Ure2p, a protein involved in nitrogen catabolism. To understand possible conformational changes at the origin of prion propagation, we previously solved the crystal structure of the Ure2p functional region [Bousset et al. (2001) Structure 9, 39-46]. We showed the protein to have a fold similar to that of the beta class of glutathione S-transferases (GSTs). Here we report crystal structures of the Ure2p functional region (extending from residues 95-354) in complex with glutathione (GSH), the substrate of all GSTs, and two widely used GST inhibitors, namely, S-hexylglutathione and S-p-nitrobenzylglutathione. In a manner similar to what is observed in many GSTs, ligand binding is not accompanied by a significant change in the conformation of the protein. We identify one GSH and one hydrophobic electrophile binding site per monomer as observed in all other GSTs. The sulfur group of GSH, that conjugates electrophiles, is located near the amide group of Asn124, allowing a hydrogen bond to be formed. Biochemical data indicate that GSH binds to Ure2p with high affinity. Its binding affects Ure2p oligomerization but has no effect on the assembly of the protein into amyloid fibrils. Despite results indicating that Ure2p lacks GST activity, we propose that Ure2p is a member of the GST superfamily that may describe a novel GST class. Our data bring new insights into the function of the Ure2p active region.     

The carrier Msn5p/Kap142p promotes nuclear export of the hsp70 Ssa4p and relocates in response to stress

Cytoplasmic hsp70s like yeast Ssa4p shuttle between nucleus and cytoplasm under normal growth conditions but accumulate in nuclei upon stress. This nuclear accumulation is only transient, and Ssa4p relocates to the cytoplasm when cells recover. We show here that Ssa4p nuclear export is independent of Xpol/Crm1 and identify the importin-beta family member Msn5p/Kap142p as the exporter for Ssa4p. In growing cells and in vitro, Msn5p and Ssa4p generate genuine export complexes that require Ran/Gsp1p-GTP. Furthermore, nucleoporin Nup82p, which plays a role in Msn5p-mediated transport, is necessary for efficient export of Ssa4p. In living cells, stress not only regulates Ssa4p localization, but also controls the distribution of Msn5p. Msn5p is concentrated in nuclei of unstressed cells, but appears in the cytoplasm upon exposure to ethanol, heat, starvation or severe oxidative stress. In addition, growth on non-fermentable carbon sources relocates a portion of Msn5p to the cytoplasm and leads to a partial nuclear accumulation of Ssa4p. Taken together, growth and stress conditions that localize the transporter Msn5p to the cytoplasm also induce the nuclear accumulation of its cargo Ssa4p.     

The native-like conformation of Ure2p in fibrils assembled under physiologically relevant conditions switches to an amyloid-like conformation upon heat-treatment of the fibrils

The [URE3] phenotype in the yeast Saccharomyces cerevisiae is inherited by a prion mechanism involving self-propagating Ure2p aggregates. It is believed that assembly of intact Ure2p into fibrillar polymers that bind Congo Red and show yellow-green birefringence upon staining and are resistant to proteolysis is the consequence of a major change in the conformation of the protein. We recently dissected the assembly process of Ure2p and showed the protein to retain its native alpha-helical structure upon assembly into protein fibrils that are similar to amyloids in that they are straight, bind Congo red and show green-yellow birefringence and have an increased resistance to proteolysis (). Here we further show using specific ligand binding, FTIR spectroscopy and X-ray fiber diffraction that Ure2p fibrils assembled under physiologically relevant conditions are devoid of a cross-beta core. The X-ray fiber diffraction pattern of these fibrils reveals their well-defined axial supramolecular order. By analyzing the effect of heat-treatment on Ure2p fibrils we bring evidences for a large conformational change that occurs within the fibrils with the loss of the ligand binding capacity, decrease of the alpha helicity, the formation of a cross-beta core and the disappearance of the axial supramolecular order. The extent of the conformational change suggests that it is not limited to the N-terminal part of Ure2p polypeptide chain. We show that the heat-treated fibrils that possess a cross-beta core are unable to propagate their structural characteristic while native-like fibrils are. Finally, the potential evolution of native-like fibrils into amyloid fibrils is discussed.     

Assembly of the yeast prion Ure2p into protein fibrils. Thermodynamic and kinetic characterization

The [URE3] phenotype in Saccharomyces cerevisiae propagates by a prion mechanism, involving the aggregation of the normally soluble and highly helical protein Ure2. Previous data have shown that the protein spontaneously forms in vitro long, straight, insoluble fibrils at neutral pH that are similar to amyloids in that they bind Congo red and show green-yellow birefringence and have an increased resistance to proteolysis. These fibrils are not amyloids as they are devoid of a cross-beta core. Here we further document the mechanism of assembly of Ure2p into fibrils. The critical concentration for Ure2p assembly is measured, and the minimal size of the nuclei that are the precursors of Ure2p fibrils is determined. Our data indicate that the assembly process is irreversible. As a consequence, the critical concentration is very low. By analyzing the elongation rates of preformed fibrils and combining the results with single-fiber imaging experiments of a variant Ure2p labeled by fluorescent dyes, we reveal the polarity of the fibrils and differences in the elongation rates at their ends. These results bring novel insight in the process of Ure2p assembly into fibrils and the mechanism of propagation of yeast prions.     

Molecular chaperone Hsp104 can promote yeast prion generation

[URE3] is an amyloid-based prion of Ure2p, a regulator of nitrogen catabolism in Saccharomyces cerevisiae. The Ure2p of the human pathogen Candida albicans can also be a prion in S. cerevisiae. We find that overproduction of the disaggregating chaperone, Hsp104, increases the frequency of de novo [URE3] prion formation by the Ure2p of S. cerevisiae and that of C. albicans. This stimulation is strongly dependent on the presence of the [PIN(+)] prion, known from previous work to enhance [URE3] prion generation. Our data suggest that transient Hsp104 overproduction enhances prion generation through persistent effects on Rnq1 amyloid, as well as during overproduction by disassembly of amorphous Ure2 aggregates (generated during Ure2p overproduction), driving the aggregation toward the amyloid pathway. Overproduction of other major cytosolic chaperones of the Hsp70 and Hsp40 families (Ssa1p, Sse1p, and Ydj1p) inhibit prion formation, whereas another yeast Hsp40, Sis1p, modulates the effects of Hsp104p on both prion induction and prion curing in a prion-specific manner. The same factor may both enhance de novo prion generation and destabilize existing prion variants, suggesting that prion variants may be selected by changes in the chaperone network.     

Proteomics analysis of the tombusvirus replicase: Hsp70 molecular chaperone is associated with the replicase and enhances viral RNA replication

Plus-strand RNA virus replication occurs via the assembly of viral replicase complexes involving multiple viral and host proteins. To identify host proteins present in the cucumber necrosis tombusvirus (CNV) replicase, we affinity purified functional viral replicase complexes from yeast. Mass spectrometry analysis of proteins resolved by two-dimensional gel electrophoresis revealed the presence of CNV p33 and p92 replicase proteins as well as four major host proteins in the CNV replicase. The host proteins included the Ssa1/2p molecular chaperones (yeast homologues of Hsp70 proteins), Tdh2/3p (glyceraldehyde-3-phosphate dehydrogenase, an RNA-binding protein), Pdc1p (pyruvate decarboxylase), and an unknown approximately 35-kDa acidic protein. Copurification experiments demonstrated that Ssa1p bound to p33 replication protein in vivo, and surface plasmon resonance measurements with purified recombinant proteins confirmed this interaction in vitro. The double mutant strain (ssa1 ssa2) showed 75% reduction in viral RNA accumulation, whereas overexpression of either Ssa1p or Ssa2p stimulated viral RNA replication by approximately threefold. The activity of the purified CNV replicase correlated with viral RNA replication in the above-mentioned ssa1 ssa2 mutant and in the Ssa overexpression strains, suggesting that Ssa1/2p likely plays an important role in the assembly of the CNV replicase.