Three hamster species with different scrapie incubation times and neuropathological features encode distinct prion proteins

Prion Strains and Transmission Barrier Phenomena

Several experimental evidences show that prions are non-conventional pathogens, which physical support consists only in proteins. This finding raised questions regarding the observed prion strain-to-strain variations and the species barrier that happened to be crossed with dramatic consequences on human health and veterinary policies during the last 3 decades. This review presents a focus on a few advances in the field of prion structure and prion strains characterization: from the historical approaches that allowed the concept of prion strains to emerge, to the last results demonstrating that a prion strain may in fact be a combination of a few quasi species with subtle biophysical specificities. Then, we will focus on the current knowledge on the factors that impact species barrier strength and species barrier crossing. Finally, we present probable scenarios on how the interaction of strain properties with host characteristics may account for differential selection of new conformer variants and eventually species barrier crossing.

Secondary-structure prediction revisited: Theoretical β-sheet propensity and coil propensity represent structures of amyloids and aid in elucidating phenomena involved in interspecies transmission of prions

Prions are unique infectious agents, consisting solely of abnormally-folded prion protein (PrP^Sc). However, they possess virus-like features, including strain diversity, the ability to adapt to new hosts and to be altered evolutionarily. Because prions lack genetic material (DNA and RNA), these biological phenomena have been attributed to the structural properties of PrP^Sc. Therefore, many structural models of the structure of PrP^Sc have been proposed based on the limited structural information available, regardless of the incompatibility with high-resolution structural analysis. Recently hypothesized models consist solely of β-sheets and intervening loops/kinks; i.e. parallel in-register β-sheet and β-solenoid models. Owing to the relative simplicity of these structural models of PrP^Sc, we hypothesized that numerical conversion of the primary structures with a relevant algorithm would enable quantitative comparison between PrPs of distinct primary structures. We therefore used the theoretical values of β-sheet (Pβ) and random-coil (Pc) propensity calculated by secondary structure prediction with a neural network, to analyze interspecies transmission of prions. By reviewing experiments in the literature, we ascertained the biological relevance of Pβ and Pc and found that these classical parameters surprisingly carry substantial information of amyloid structures. We also demonstrated how these parameters could aid in interpreting and explaining phenomena in interspecies transmissions. Our approach can lead to the development of a versatile tool for investigating not only prions but also other amyloids.

Is the prevalent human prion protein 129M/V mutation a living fossil from a Paleolithic panzootic superprion pandemic?

Prion diseases are consistently associated with prion protein (PrP(C)) misfolding rendering a cascade of auto-catalytic self-perpetuation of misfolded PrP in an afflicted individual. The molecular process is intriguingly similar to all known amyloid diseases both local and systemic. The prion disease is also infectious by the transfer of misfolded PrP from one individual to the next. Transmissibility is surprisingly efficient in prion diseases and given the rapid disease progression following initial symptoms the prionoses stand out from other amyloidoses, which all may be transmissible under certain circumstances. The nature of the infectious prion as well as the genotype of the host is important for transmissibility. For hitherto unexplained reasons the majority of Europeans carry a missense mutation on one or both alleles of the PrP gene (PRNP), and hence express a variant of PrP with a substitution for valine (V) instead of methionine (M) in position 129. In fact the 129M/V variant is very common in all populations except for the Japanese. Sporadic Creutzfeldt-Jakob disease is a disease rarely striking people below the age of 60, where homozygosity especially 129MM is a very strong risk factor. Paradoxically, the 129M/V polymorphism suggestive of heterozygote advantage is one of the most clear cut disease associated traits of the human population, yet prion disease is extraordinarily rare. The genetic basis for how this trait spread with such prevalence within human populations is still target to investigations and deserves attention. This short essay represents a somewhat provocative hypothetical notion of a possible ancient significance of this polymorphism.

Cellular factors implicated in prion replication

Prions are the unconventional infectious agents responsible for prion diseases, which are composed mainly by the misfolded prion protein (PrP(Sc)) that replicates by converting the host associated cellular prion protein (PrP(C)). Several lines of evidence suggest that other cellular components participate in prion conversion, however, the identity or even the chemical nature of such factors are entirely unknown. In this article we study the conversion factor activity by complementation of a PMCA procedure employing purified PrP(C) and PrP(Sc). Our results show that the conversion factor is present in all major organs of diverse mammalian species, and is predominantly located in the lipid raft fraction of the cytoplasmic membrane. On the other hand, it is not present in the lower organisms tested (yeast, bacteria and flies). Surprisingly, treatments that eliminate the major classes of chemical molecules do not affect conversion activity, suggesting that various different compounds may act as conversion factor in vitro. This conclusion is further supported by experiments showing that addition of various classes of molecules have a small, but detectable effect on enhancing prion replication in vitro. More research is needed to elucidate the identity of these factors, their detailed mechanism of action and whether or not they are essential component of the infectious particle.

Characteristics of 263K scrapie agent in multiple hamster species

Transmissible spongiform encephalopathy (TSE) diseases are known to cross species barriers, but the pathologic and biochemical changes that occur during transmission are not well understood. To better understand these changes, we infected 6 hamster species with 263K hamster scrapie strain and, after each of 3 successive passages in the new species, analyzed abnormal proteinase K (PK)-resistant prion protein (PrPres) glycoform ratios, PrPres PK sensitivity, incubation periods, and lesion profiles. Unique 263K molecular and biochemical profiles evolved in each of the infected hamster species. Characteristics of 263K in the new hamster species seemed to correlate best with host factors rather than agent strain. Furthermore, 2 polymorphic regions of the prion protein amino acid sequence correlated with profile differences in these TSE-infected hamster species.

Biological characteristics of Chinese hamster ovary cells transfected with bovine Prnp

A normal prion protein (PrP^c) is converted to a protease-resistant isoform by an apparent self-propagating activity in transmissible spongiform encephalopathy, a neurodegenerative disease. The cDNA encoding open reading frame (ORF) of the bovine prion protein gene (Prnp) was cloned from Korean cattle by PCR, and was transfected into Chinese hamster ovary (CHO-K1) cells using lipofectamine. The gene expression of the cloned cDNA was confirmed by RT-PCR and Western blotting with the monoclonal antibody, 6H4. Cellular changes in the transfected CHO-K1 cells were investigated using parameters such as MTT, lactate dehydrogenase (LDH), and superoxide dismutase (SOD) activities, as well as nitric oxide (NO) production, and an apoptosis assay. In the MTT and LDH assays, the bovine PrnP-transfectant showed a lower proliferation rate than the wild-type (p < 0.05). Production of NO, after LPS or ConA stimulation, was not detected in either transfectants or CHO-K1 cells. In SOD assay under ConA stimulation, the SOD activity of transfectants was 10 times higher than that of CHO-K1 cells at 6 h after treatment (p < 0.05). The genomic DNA of both the transfectants and control cells began to be fragmented at 6 h after treatment with cyclohexamide. Caspase-3 activity was reduced by transfection with the bovine Prnp (p < 0.05). Conclusively, the viability of transfectants expressing exogenous bovine Prnp was decreased while the capacities for cellular protection against antioxidative stress and apoptosis were increased.

Prion protein conversion in vitro

The infectious agents of prion diseases are composed primarily of an infectious protein designated PrPSc. In cells infected with prions, a host glycoprotein termed PrPC undergoes induced conformational change to PrPSc, but the molecular mechanism underlying this structural transition occurs remains unknown. The prion-seeded conversion of PrPC to protease-resistant PrPSc-like molecules (PrPres) has been studied both in crude and purified in vitro systems in order to investigate the mechanism of protein conformational change in prion disease. Conversion of purified PrPC into PrPres is specific with respect to species-dependent and polymorphic differences in PrP sequence as well as biophysical variations between prion strains, recapitulating the specificity of prion propagation in vitro. The protein misfolding cyclic amplification (PMCA) technique, which utilizes crude brain homogenates, produces much higher yields of PrPres than conversion of purified PrP molecules, suggesting that additional cellular factors may stimulate PrPres formation. In a modified version of the PMCA technique, PrPres from diluted prion-infected brain homogenate can be amplified > ten-fold when mixed with normal brain homogenate without sonication or the anionic detergent sodium dodecyl sulfate (SDS). Under these conditions, PrPres amplification in vitro depends upon both time and temperature, has a neutral pH optimum, and does not require divalent cations. In vitro PrPres amplification is inhibited by both reversible and irreversible thiol blockers, indicating that the conformational change from PrPC to PrPres requires a thiol-containing factor. Stoichiometric transformation of PrPC to PrPres in vitro also requires specific RNA molecules, suggesting that host-encoded catalytic RNA molecules may play a role in the pathogenesis of prion disease. Heparan sulfate stimulates conversion of purified PrPC into PrPres in vitro, and heparan sulfate proteoglycan molecules are required for efficient PrPres formation in prion-infected cells. Future studies using in vitro PrPres conversion and amplification assays promise to provide new mechanistic insights about the PrP conversion process, and to generate clinically useful tools.

The prion protein gene is dispensable for the development of spongiform myeloencephalopathy induced by the neurovirulent Cas-Br-E murine leukemia virus

The Cas-Br-E murine leukemia virus (MuLV) induces paralysis in susceptible mice that is accompanied by a severe spongiform myeloencephalopathy. These neurodegenerative lesions are very similar to those observed in prion diseases. To determine whether the prion protein gene (Prn-p) product was a downstream effector of this neurovirulent MuLV, we inoculated Prn-p(-/-) knockout homozygote and control heterozygote or wild-type mice with this retrovirus. All groups developed typical paralysis and spongiform encephalopathy, and no differences in clinical or histological phenotypes were observed between these groups. These results indicate that the Cas-Br-E MuLV does not require the prion protein to induce lesions. Thus, MuLV and prion proteins may induce a very similar disease through distinct pathways, or the viral Env protein, which harbors the primary determinant of pathogenicity, may act in a common pathway but downstream of the prion protein.

The major species specific epitope in prion proteins of ruminants

The species specific nature of an antigenic determinant previously discovered in the scrapie form of prion protein (PrPD) from cattle, sheep and mice, was further investigated in normal prion protein (PrPC) from these and other species. This was carried out with eight different anti-peptide sera raised in rabbits against various synthetic peptides representing segments of the amino acid (aa) sequence 101-122 of ovine, bovine, murine and hamster PrP. Antipeptide serum against a peptide representing aa 107-122 of ovine PrP showed almost specific reaction and crossreacted in immunoblot with caprine and human PrP only. Antisera to the corresponding bovine sequence stained bovine and porcine PrP and to a minor extent PrP of goat, man, cat, and mink, while antiserum to the murine aa sequence reacted with rodent and monkey PrP only. In contrast, antiserum to the corresponding hamster sequence displayed a broader reactivity pattern, just like the four other anti-peptide sera to various ovine and bovine sequences. Antisera were also tested for reactivity with the pathogenic isoforms of PrP of sheep, cow, hamster and mouse and showed generally similar reactivity patterns as by using PrPC. In conclusion, the region close to the actual or putative proteinase K cleavage sites of PrP seems to exhibit high structural variability among mammalian species.

129/Ola mice carrying a null mutation in PrP that abolishes mRNA production are developmentally normal

The neural membrane glycoprotein PrP is implicated in the pathogenesis of the transmissible spongiform encephalopathies; however, the normal function of PrP and its precise role in disease are not understood. Recently, gene targeting has been used to produce mice with neo/PrP fusion transcripts, but no detectable PrP protein in the brain (1). Here we report the use of a different targeting strategy, to produce inbred mice with a complete absence of both PrP protein and mRNA sequences. At 7 mo of age, these mice show no overt phenotypic abnormalities despite the normal high levels of expression of PrP during mouse development. The mice are being used in experiments designed to address the role of PrP in the pathogenesis of scrapie and the replication of infectivity.

Purification and properties of the cellular prion protein from Syrian hamster brain

The cellular prion protein (PrPC) is encoded by a chromosomal gene, and its scrapie isoform (PrPSc) features in all aspects of the prion diseases. Prior to the studies reported here, purification of PrPC has only been accomplished using immunoaffinity chromatography yielding small amounts of protein. Brain homogenates contain two PrPC forms designated PrPC-I and -II. These proteins were purified from a microsomal fraction by detergent extraction and separated by immobilized Cu2+ ion affinity chromatography. PrPC-II appears to be generated from PrPC-I by limited proteolysis of the N-terminus. Fractions enriched for PrPC-I were purified further by cation-exchange chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Greater than 90% of the final product migrated as a broad band of M(r) 33-35 kDa as judged by silver staining after SDS-PAGE. Digestion of PrPC-I with peptide-N-glycosidase (PNGase) compressed the band and shifted its mobility giving an M(r) of 27 kDa. The protocol described should be amenable to large-scale preparation of PrPC, enabling physical comparisons of PrPC and PrPSc.

Comparative sequence analysis and expression of bovine PrP gene in mouse L-929 cells

A cDNA clone encoding bovine scrapie-associated fibril protein, PrP, from a bovine brain cDNA library and six amplified genomic DNA clones of bovine PrP were characterized. These clones possessed specific characteristics observed in other animal PrP genes. However, the bovine PrP was divided into two types by the number of repeats. One possessed four octapeptide repetitive sequences, like other animal PrP genes, and consisted of 256 amino acids; the other had five such repetitive sequences and 264 amino acids. The amino acid sequence of the former bovine PrP agreed with that of sheep PrP up to the 165th amino acid from the N-terminus. Bovine PrP cDNA introduced into mouse L-929 cells were stably expressed. The expression level of recombinant bovine PrP in the cells judged by immunofluorescence was higher than that of authentic mouse PrP. The recombinant PrP comigrated with authentic bovine PrP in SDS-polyacrylamide gel electrophoresis, suggesting that the recombinant product was fully glycosylated in L-929 cells. Distinct bundles of the intermediate filaments were frequently seen at the perinuclear region of the cells.

Analysis of the prion protein gene in thalamic dementia

Thalamic degenerations or dementias are poorly understood conditions. The familial forms are (1) selective thalamic degenerations and (2) thalamic degenerations associated with multiple system atrophy. Selective thalamic degenerations share clinical and pathologic features with fatal familial insomnia, an autosomal dominant disease linked to a mutation at codon 178 of the prion protein (PrP) gene that causes the substitution of asparagine for aspartic acid (178Asn mutation). We amplified the carboxyl terminal coding region of the PrP gene from subjects with selective thalamic dementia or thalamic dementia associated with multiple system atrophy. Three of the four kindreds with selective thalamic dementia and none of the three kindreds with thalamic dementia associated with multiple system atrophy had the PrP 178Asn mutation. Thus, analysis of the PrP gene may be useful in diagnosing the subtypes of thalamic dementia. Moreover, since selective thalamic dementia with the PrP 178Asn mutation and fatal familial insomnia share clinical and histopathologic features, we propose that they are the same disease.

Molecular cloning of a candidate chicken prion protein

Fractions enriched for acetylcholine receptor-inducing activity from chicken brain were found to contain a protein that was approximately 30% homologous with mammalian prion proteins [Harris, D. A., Falls, D. L., Johnson, F. A. & Fischbach, G. D. (1991) Proc. Natl. Acad. Sci. USA 88, 7664-7668]. To extend these observations, we recovered genomic clones encoding a putative chicken prion protein (PrP). Like mammalian PrP molecules, the candidate chicken PrP is encoded by a single-copy gene and the entire open reading frame is found within a single exon. All of the structural features of mammalian PrP were found in the chicken protein. When the N-terminal repeats of PrP were not considered, the chicken and mammalian proteins were approximately 55% homologous, allowing for conservative substitutions. Screening of a chicken genomic DNA library failed to identify a more closely related chicken PrP homologue. These findings argue that the protein which purifies with acetylcholine receptor-inducing activity is chicken PrP.

Regional mapping of prion proteins in brain

Scrapie is characterized by the accumulation of a protease-resistant isoform of the prion protein PrPSc. Limited proteolysis and chaotropes were used to map the distribution of PrPSc in cryostat sections of scrapie-infected brain blotted onto nitrocellulose membranes, designated histoblots. Proteolysis was omitted in order to map the cellular isoform of the prion protein (PrPC) in uninfected brains. Compared with immunohistochemistry, histoblots increased the sensitivity for PrPSc detection and showed different patterns of PrPSc accumulation. In Syrian hamsters with Sc237 scrapie, the most intense PrPSc signals occurred in sites with relatively little PrPC, suggesting that aberrant localization of prion protein may be an important feature in the pathogenesis of prion diseases. Immunostaining of PrPSc in white-matter tracts suggested that prions spread along neuroanatomical pathways. PrPSc immunostaining in histoblots was quantitated by densitometry, permitting assessment of the extent of PrPSc accumulation within specific structures. Histoblots were also useful in localizing PrPCJD and beta/A4-amyloid peptide in the brains of patients with Creutzfeldt-Jakob disease and Alzheimer disease, respectively.

The transmissible amyloidoses: genetical control of spontaneous generation of infectious amyloid proteins by nucleation of configurational change in host precursors: kuru-CJD-GSS-scrapie-BSE

Kuru, Creutzfeld-Jakob disease, Gerstmann-Sträussler syndrome, scrapie, and bovine spongiform encephalopathy are caused by so-called unconventional viruses which are really replicating proteins which induce by auto nucleation and autopatterning a configurational change in the precursor protein to produce an infectious amyloid form. Crystallography and NMR may eventually determine how amyloid precursor protein is converted to this infectious form by configurational changes in all tertiary and quaternary structure of the normal precursor. Most sporadic cases of CJD arise by de novo spontaneous conversion of the normal precursor to the infectious form, a rare event occurring at the frequency of one per million persons per year (the annual incidence of CJD throughout the world). In the familial forms of CJD and GSS, where the occurrence is an autosomal dominant trait, each family has one of five different mutations causing a single amino acid change or one of five insertions of 5, 6, 7, 8 or 9 octapeptide repeats. Each mutation causes a million-fold increased probability of the spontaneous configurational change to an infectious polypeptide, and appears as an autosomal dominant trait. Thus, the behavior of the transmissible brain amyloidosis parallels completely that of the transthyretin amyloidoses causing familial amyloidotic polyneuropathy, in which there are 19 different point mutations, each one of which increases enormously the likelihood of configurational change of transthyretin prealbumin to amyloid.

A prion-like protein from chicken brain copurifies with an acetylcholine receptor-inducing activity

The mammalian prion protein (PrPC) is a cellular protein of unknown function, an altered isoform of which (PrPSc) is a component of the infectious particle (prion) thought to be responsible for spongiform encephalopathies in humans and animals. We report here the isolation of a cDNA that encodes a chicken protein that is homologous to PrPC. This chicken prion-like protein (ch-PrLP) is identical to the mouse PrP at 33% of its amino acid positions, including an uninterrupted stretch of 24 identical residues, and it displays the same structural domains. In addition, ch-PrLP, like its mammalian counterpart, is attached to the cell surface by a glycosyl-phosphatidylinositol anchor. We find that ch-PrLP is the major protein in preparations of an acetylcholine receptor-inducing activity that has been purified greater than 10(6)-fold from brain on the basis of its ability to stimulate synthesis of nicotinic receptors by cultured myotubes. The ch-PrLP gene is expressed in the spinal cord and brain as early as embryonic day 6; and in the spinal cord, the protein appears to be concentrated in motor neurons. Our results therefore raise the possibility that prion proteins serve normally to regulate the chemoreceptor number at the neuromuscular junction and perhaps in the central nervous system as well.

Molecular location of a species-specific epitope on the hamster scrapie agent protein

Scrapie is a transmissible neurodegenerative disease of sheep and goats. An abnormal host protein, Sp33-37, is the major protein component of the scrapie agent and the only known disease- or agent-specific macromolecule. Two monoclonal antibodies (MAbs), 4H8 (immunoglobulin G2b [IgG2b]) and 6B11 (IgG1), produced by immunizing mice with the intact hamster 263K scrapie agent protein, Sp33-37Ha, were found to have species specificity similar to that reported previously for MAb 3F4 (IgG2a), which was produced by using PrP-27-30 as the immunogen (R. J. Kascsak, R. Rubenstein, P. A. Merz, M. Tonna-DeMasi, R. Fersko, R. I. Carp, H. M. Wisniewski, and H. Diringer, J. Virol. 61:3688-3693, 1987). These antibodies all bound to Sp33-37 derived from hamster but not from mouse cells. Competitive binding assays demonstrated that all three MAbs bound to the same or overlapping sites on Sp33-37Ha. The molecular location of the epitope for these antibodies was determined to within 10 residues by using an antigen competition enzyme-linked immunosorbent assay in which synthetic peptides spanning Sp33-37Ha residues 79 to 93 or 84 to 93 specifically inhibited binding of these antibodies to plates coated with purified Sp33-37Ha. A synthetic peptide with the mouse-specific sequence (83 to 92) that differed from the hamster sequence by substitution at two positions (MetHa-87----LeuMo-86 and MetHa-90----ValMo-89) did not inhibit antibody binding to Sp33-37Ha. MAb 3F4 binding to hamster Sp33-37 was eliminated by chemical modification of Sp33-37Ha with diethylpyrocarbonate or succinic anhydride and by cleavage with CNBr or trypsin. The effect of diethylpyrocarbonate on MAb 3F4 binding was not reversed by hydroxylamine treatment. MAb 3F4 binding was not affected by prolonged exposure of Sp33-37Ha to 70% formic acid or by boiling in sodium dodecyl sulfate. We conclude that the epitope for these MAbs is a linear determinant that includes Met-87, Lys-88, and Met-90 and that Met-90 is probably the major species-specific determinant.

Scrapie prion rod formation in vitro requires both detergent extraction and limited proteolysis

Scrapie prion infectivity can be enriched from hamster brain homogenates by using limited proteolysis and detergent extraction. Purified fractions contain both scrapie infectivity and the protein PrP 27-30, which is aggregated in the form of prion rods. During purification, PrP 27-30 is produced from a larger membrane protein, PrPSc, by limited proteolysis with proteinase K. Brain homogenates from scrapie-infected hamsters do not contain prion rods prior to exposure to detergents and proteases. To determine whether both detergent extraction and limited proteolysis are required for the formation of prion rods, microsomal membranes were prepared from infected brains in the presence of protease inhibitors. The isolated membranes were then detergent extracted as well as protease digested to evaluate the effects of these treatments on the formation of prion rods. Neither detergent (2% Sarkosyl) extraction nor limited proteinase K digestion of scrapie microsomes produced recognizable prion amyloid rods. Only after combining detergent extraction with limited proteolysis were numerous prion rods observed. Rod formation was influenced by the protease concentration, the specificity of the protease, and the duration of digestion. Rod formation also depended upon the detergent; some combinations of protease and detergent did not produce prion amyloid rods. Similar results were obtained with purified PrPSc fractions prepared by repeated detergent extractions in the presence of protease inhibitors. These fractions contained amorphous structures but not rods; however, prion rods were produced upon conversion of PrPSc to PrP 27-30 by limited proteolysis. We conclude that the formation of prion amyloid rods in vitro requires both detergent extraction and limited proteolysis. In vivo, amyloid filaments found in the brains of animals with scrapie resemble prion rods in their width and their labeling with prion protein (PrP) antisera; however, filaments are typically longer than rods. Whether limited proteolysis and some process equivalent to detergent extraction are required for amyloid filament formation in vivo remains to be established.