The ultrastructure of infectious L-type bovine spongiform encephalopathy prions constrains molecular models.

Bovine spongiform encephalopathy (BSE) is a prion disease of cattle that is caused by the misfolding of the cellular prion protein (PrPC) into an infectious conformation (PrPSc). PrPC is a predominantly α-helical membrane protein that misfolds into a ß-sheet rich, infectious state, which has a high propensity to self-assemble into amyloid fibrils. Three strains of BSE prions can cause prion disease in cattle, including classical BSE (C-type) and two atypical strains, named L-type and H-type BSE. To date, there is no detailed information available about the structure of any of the infectious BSE prion strains. In this study, we purified L-type BSE prions from transgenic mouse brains and investigated their biochemical and ultrastructural characteristics using electron microscopy, image processing, and immunogold labeling techniques. By using phosphotungstate anions (PTA) to precipitate PrPSc combined with sucrose gradient centrifugation, a high yield of proteinase K-resistant BSE amyloid fibrils was obtained. A morphological examination using electron microscopy, two-dimensional class averages, and three-dimensional reconstructions revealed two structural classes of L-type BSE amyloid fibrils; fibrils that consisted of two protofilaments with a central gap and an average width of 22.5 nm and one-protofilament fibrils that were 10.6 nm wide. The one-protofilament fibrils were found to be more abundant compared to the thicker two-protofilament fibrils. Both fibrillar assemblies were successfully decorated with monoclonal antibodies against N- and C-terminal epitopes of PrP using immunogold-labeling techniques, confirming the presence of polypeptides that span residues 100-110 to 227-237. The fact that the one-protofilament fibrils contain both N- and C-terminal PrP epitopes constrains molecular models for the structure of the infectious conformer in favour of a compact four-rung ß-solenoid fold.

Recombinant PrPSc shares structural features with brain-derived PrPSc: Insights from limited proteolysis.

Very solid evidence suggests that the core of full length PrPSc is a 4-rung ß-solenoid, and that individual PrPSc subunits stack to form amyloid fibers. We recently used limited proteolysis to map the ß-strands and connecting loops that make up the PrPSc solenoid. Using high resolution SDS-PAGE followed by epitope analysis, and mass spectrometry, we identified positions ~116/118, 133-134, 141, 152-153, 162, 169 and 179 (murine numbering) as Proteinase K (PK) cleavage sites in PrPSc. Such sites likely define loops and/or borders of ß-strands, helping us to predict the threading of the ß-solenoid. We have now extended this approach to recombinant PrPSc (recPrPSc). The term recPrPSc refers to bona fide recombinant prions prepared by PMCA, exhibiting infectivity with attack rates of ~100%. Limited proteolysis of mouse and bank vole recPrPSc species yielded N-terminally truncated PK-resistant fragments similar to those seen in brain-derived PrPSc, albeit with varying relative yields. Along with these fragments, doubly N- and C-terminally truncated fragments, in particular ~89/97-152, were detected in some recPrPSc preparations; similar fragments are characteristic of atypical strains of brain-derived PrPSc. Our results suggest a shared architecture of recPrPSc and brain PrPSc prions. The observed differences, in particular the distinct yields of specific PK-resistant fragments, are likely due to differences in threading which result in the specific biochemical characteristics of recPrPSc. Furthermore, recombinant PrPSc offers exciting opportunities for structural studies unachievable with brain-derived PrPSc.

The Structural Architecture of an Infectious Mammalian Prion Using Electron Cryomicroscopy.

The structure of the infectious prion protein (PrPSc), which is responsible for Creutzfeldt-Jakob disease in humans and bovine spongiform encephalopathy, has escaped all attempts at elucidation due to its insolubility and propensity to aggregate. PrPSc replicates by converting the non-infectious, cellular prion protein (PrPC) into the misfolded, infectious conformer through an unknown mechanism. PrPSc and its N-terminally truncated variant, PrP 27-30, aggregate into amorphous aggregates, 2D crystals, and amyloid fibrils. The structure of these infectious conformers is essential to understanding prion replication and the development of structure-based therapeutic interventions. Here we used the repetitive organization inherent to GPI-anchorless PrP 27-30 amyloid fibrils to analyze their structure via electron cryomicroscopy. Fourier-transform analyses of averaged fibril segments indicate a repeating unit of 19.1 Å. 3D reconstructions of these fibrils revealed two distinct protofilaments, and, together with a molecular volume of 18,990 Å3, predicted the height of each PrP 27-30 molecule as ~17.7 Å. Together, the data indicate a four-rung ß-solenoid structure as a key feature for the architecture of infectious mammalian prions. Furthermore, they allow to formulate a molecular mechanism for the replication of prions. Knowledge of the prion structure will provide important insights into the self-propagation mechanisms of protein misfolding.

Proteinase K and the structure of PrPSc: The good, the bad and the ugly.

Infectious proteins (prions) are, ironically, defined by their resistance to proteolytic digestion. A defining characteristic of the transmissible isoform of the prion protein (PrP(Sc)) is its partial resistance to proteinase K (PK) digestion. Diagnosis of prion disease typically relies upon immunodetection of PK-digested PrP(Sc) by Western blot, ELISA or immunohistochemical detection. PK digestion has also been used to detect differences in prion strains. Thus, PK has been a crucial tool to detect and, thereby, control the spread of prions. PK has also been used as a tool to probe the structure of PrP(Sc). Mass spectrometry and antibodies have been used to identify PK cleavage sites in PrP(Sc). These results have been used to identify the more accessible, flexible stretches connecting the ß-strand components in PrP(Sc). These data, combined with physical constraints imposed by spectroscopic results, were used to propose a qualitative model for the structure of PrP(Sc). Assuming that PrP(Sc) is a four rung ß-solenoid, we have threaded the PrP sequence to satisfy the PK proteolysis data and other experimental constraints.

Structural organization of mammalian prions as probed by limited proteolysis.

Elucidation of the structure of PrP(Sc) continues to be one major challenge in prion research. The mechanism of propagation of these infectious agents will not be understood until their structure is solved. Given that high resolution techniques such as NMR or X-ray crystallography cannot be used, a number of lower resolution analytical approaches have been attempted. Thus, limited proteolysis has been successfully used to pinpoint flexible regions within prion multimers (PrP(Sc)). However, the presence of covalently attached sugar antennae and glycosylphosphatidylinositol (GPI) moieties makes mass spectrometry-based analysis impractical. In order to surmount these difficulties we analyzed PrP(Sc) from transgenic mice expressing prion protein (PrP) lacking the GPI membrane anchor. Such animals produce prions that are devoid of the GPI anchor and sugar antennae, and, thereby, permit the detection and location of flexible, proteinase K (PK) susceptible regions by Western blot and mass spectrometry-based analysis. GPI-less PrP(Sc) samples were digested with PK. PK-resistant peptides were identified, and found to correspond to molecules cleaved at positions 81, 85, 89, 116, 118, 133, 134, 141, 152, 153, 162, 169 and 179. The first 10 peptides (to position 153), match very well with PK cleavage sites we previously identified in wild type PrP(Sc). These results reinforce the hypothesis that the structure of PrP(Sc) consists of a series of highly PK-resistant ß-sheet strands connected by short flexible PK-sensitive loops and turns. A sizeable C-terminal stretch of PrP(Sc) is highly resistant to PK and therefore perhaps also contains ß-sheet secondary structure.

PK-sensitive PrP is infectious and shares basic structural features with PK-resistant PrP.

One of the main characteristics of the transmissible isoform of the prion protein (PrP(Sc)) is its partial resistance to proteinase K (PK) digestion. Diagnosis of prion disease typically relies upon immunodetection of PK-digested PrP(Sc) following Western blot or ELISA. More recently, researchers determined that there is a sizeable fraction of PrP(Sc) that is sensitive to PK hydrolysis (sPrP(Sc)). Our group has previously reported a method to isolate this fraction by centrifugation and showed that it has protein misfolding cyclic amplification (PMCA) converting activity. We compared the infectivity of the sPrP(Sc) versus the PK-resistant (rPrP(Sc)) fractions of PrP(Sc) and analyzed the biochemical characteristics of these fractions under conditions of limited proteolysis. Our results show that sPrP(Sc) and rPrP(Sc) fractions have comparable degrees of infectivity and that although they contain different sized multimers, these multimers share similar structural properties. Furthermore, the PK-sensitive fractions of two hamster strains, 263K and Drowsy (Dy), showed strain-dependent differences in the ratios of the sPrP(Sc) to the rPrP(Sc) forms of PrP(Sc). Although the sPrP(Sc) and rPrP(Sc) fractions have different resistance to PK-digestion, and have previously been shown to sediment differently, and have a different distribution of multimers, they share a common structure and phenotype.

Probing structural differences between PrP(C) and PrP(Sc) by surface nitration and acetylation: evidence of conformational change in the C-terminus.

We used two chemical modifiers, tetranitromethane (TNM) and acetic anhydride (Ac(2)O), which specifically target accessible tyrosine and lysine residues, respectively, to modify recombinant Syrian hamster PrP(90-231) [rSHaPrP(90-231)] and SHaPrP 27-30, the proteinase K-resistant core of PrP(Sc) isolated from brain of scrapie-infected Syrian hamsters. Our aim was to find locations of conformational change. Modified proteins were subjected to in-gel proteolytic digestion with trypsin or chymotrypsin and subsequent analysis by mass spectrometry (MALDI-TOF). Several differences in chemical reactivity were observed. With TNM, the most conspicuous reactivity difference seen involves peptide E(221)-R(229) (containing Y(225) and Y(226)), which in rSHaPrP(90-231) was much more extensively modified than in SHaPrP 27-30; peptide H(111)-R(136), containing Y(128), was also more modified in rSHaPrP(90-231). Conversely, peptides Y(149)-R(151), Y(157)-R(164), and R(151)-Y(162) suffered more extensive modification in SHaPrP 27-30. Acetic anhydride modified very extensively peptide G(90)-K(106), containing K(101), K(104), K(106), and the amino terminus, in both rSHaPrP(90-231) and SHaPrP 27-30. These results suggest that (1) SHaPrP 27-30 exhibits important conformational differences in the C-terminal region with respect to rSHaPrP(90-231), resulting in the loss of solvent accessibility of Y(225) and Y(226), very solvent-exposed in the latter conformation; because other results suggest preservation of the two C-terminal helices, this might mean that these are tightly packed in SHaPrP 27-30. (2) On the other hand, tyrosines contained in the stretch spanning approximately Y(149)-R(164) are more accessible in SHaPrP 27-30, suggesting rearrangements in α-helix H1 and the short ß-sheet of rSHaPrP(90-231). (3) The amino-terminal region of SHaPrP 27-30 is very accessible. These data should help in the validation and construction of structural models of PrP(Sc).