Porcine prion protein amyloid

ABSTRACT

Mammalian prions are composed of misfolded aggregated prion protein (PrP) with amyloid-like features. Prions are zoonotic disease agents that infect a wide variety of mammalian species including humans. Mammals and by-products thereof which are frequently encountered in daily life are most important for human health. It is established that bovine prions (BSE) can infect humans while there is no such evidence for any other prion susceptible species in the human food chain (sheep, goat, elk, deer) and largely prion resistant species (pig) or susceptible and resistant pets (cat and dogs, respectively). PrPs from these species have been characterized using biochemistry, biophysics and neurobiology. Recently we studied PrPs from several mammals in vitro and found evidence for generic amyloidogenicity as well as cross-seeding fibril formation activity of all PrPs on the human PrP sequence regardless if the original species was resistant or susceptible to prion disease. Porcine PrP amyloidogenicity was among the studied. Experimentally inoculated pigs as well as transgenic mouse lines overexpressing porcine PrP have, in the past, been used to investigate the possibility of prion transmission in pigs. The pig is a species with extraordinarily wide use within human daily life with over a billion pigs harvested for human consumption each year. Here we discuss the possibility that the largely prion disease resistant pig can be a clinically silent carrier of replicating prions.     

Transgenic Mouse Bioassay: Evidence That Rabbits Are Susceptible to a Variety of Prion Isolates

Interspecies transmission of prions is a well-established phenomenon, both experimentally and under field conditions. Upon passage through new hosts, prion strains have proven their capacity to change their properties and this is a source of strain diversity which needs to be considered when assessing the potential risks associated with consumption of prion contaminated protein sources. Rabbits were considered for decades to be a prion resistant species until proven otherwise recently. To determine the extent of rabbit susceptibility to prions and to assess the effects of passage of different prion strains through this species a transgenic mouse model overexpressing rabbit PrP^C was developed (TgRab). Intracerebral challenges with prion strains originating from a variety of species including field isolates (ovine SSBP/1 scrapie, Nor98- scrapie; cattle BSE, BSE-L and cervid CWD), experimental murine strains (ME7 and RML) and experimentally obtained ruminant (sheepBSE) and rabbit (de novo NZW) strains were performed. On first passage TgRab were susceptible to the majority of prions (Cattle BSE, SheepBSE, BSE-L, de novo NZW, ME7 and RML) tested with the exception of SSBP/1 scrapie, CWD and Nor98 scrapie. Furthermore, TgRab were capable of propagating strain-specific features such as differences in incubation periods, histological brain lesions, abnormal prion (PrP^d) deposition profiles and proteinase-K (PK) resistant western blotting band patterns. Our results confirm previous studies proving that rabbits are not resistant to prion infection and show for the first time that rabbits are susceptible to PrP^d originating in a number of other species. This should be taken into account when choosing protein sources to feed rabbits.     

Naturally prion resistant mammals

Each known abnormal prion protein (PrP^Sc) is considered to have a specific range and therefore the ability to infect some species and not others. Consequently, some species have been assumed to be prion disease resistant as no successful natural or experimental challenge infections have been reported. This assumption suggested that, independent of the virulence of the PrP^Sc strain, normal prion protein (PrP^C) from these ‘resistant’ species could not be induced to misfold. Numerous in vitro and in vivo studies trying to corroborate the unique properties of PrP^Sc have been undertaken. The results presented in the article “Rabbits are not resistant to prion infection” demonstrated that normal rabbit PrP^C, which was considered to be resistant to prion disease, can be misfolded to PrP^Sc and subsequently used to infect and transmit a standard prion disease to leporids. Using the concept of species resistance to prion disease, we will discuss the mistake of attributing species specific prion disease resistance based purely on the absence of natural cases and incomplete in vivo challenges. The BSE epidemic was partially due to an underestimation of species barriers. To repeat this error would be unacceptable, especially if present knowledge and techniques can show a theoretical risk. Now that the myth of prion disease resistance has been refuted it is time to re-evaluate, using the new powerful tools available in modern prion laboratories, whether any other species could be at risk.     

Naturally prion resistant mammals: A utopia?

Each known abnormal prion protein (PrP^Sc) is considered to have a specific range and therefore the ability to infect some species and not others. Consequently, some species have been assumed to be prion disease resistant as no successful natural or experimental challenge infections have been reported. This assumption suggested that, independent of the virulence of the PrP^Sc strain, normal prion protein (PrP^C) from these ‘resistant’ species could not be induced to misfold. Numerous in vitro and in vivo studies trying to corroborate the unique properties of PrP^Sc have been undertaken. The results presented in the article “Rabbits are not resistant to prion infection” demonstrated that normal rabbit PrP^C, which was considered to be resistant to prion disease, can be misfolded to PrP^Sc and subsequently used to infect and transmit a standard prion disease to leporids. Using the concept of species resistance to prion disease, we will discuss the mistake of attributing species specific prion disease resistance based purely on the absence of natural cases and incomplete in vivo challenges. The BSE epidemic was partially due to an underestimation of species barriers. To repeat this error would be unacceptable, especially if present knowledge and techniques can show a theoretical risk. Now that the myth of prion disease resistance has been refuted it is time to re-evaluate, using the new powerful tools available in modern prion laboratories, whether any other species could be at risk.     

A new model for sensitive detection of zoonotic prions by PrP transgenic Drosophila

Prions are transmissible protein pathogens most reliably detected by a bioassay in a suitable host, typically mice. However, the mouse bioassay is slow and cumbersome, and relatively insensitive to low titers of prion infectivity. Prions can be detected biochemically in vitro by the protein misfolding cyclic amplification (PMCA) technique, which amplifies disease-associated prion protein but does not detect bona fide prion infectivity. Here, we demonstrate that Drosophila transgenic for bovine prion protein (PrP) expression can serve as a model system for the detection of bovine prions significantly more efficiently than either the mouse prion bioassay or PMCA. Strikingly, bovine PrP transgenic Drosophila could detect bovine prion infectivity in the region of a 10⁻¹² dilution of classical bovine spongiform encephalopathy (BSE) inoculum, which is 10⁶-fold more sensitive than that achieved by the bovine PrP mouse bioassay. A similar level of sensitivity was observed in the detection of H-type and L-type atypical BSE and sheep-passaged BSE by bovine PrP transgenic Drosophila. Bioassays of bovine prions in Drosophila were performed within 7 weeks, whereas the mouse prion bioassay required at least a year to assess the same inoculum. In addition, bovine PrP transgenic Drosophila could detect classical BSE at a level 10⁵-fold lower than that achieved by PMCA. These data show that PrP transgenic Drosophila represent a new tractable prion bioassay for the efficient and sensitive detection of mammalian prions, including those of known zoonotic potential.     

The Priority position paper: Protecting Europe's food chain from prions

Bovine spongiform encephalopathy (BSE) created a global European crisis in the 1980s and 90s, with very serious health and economic implications. Classical BSE now appears to be under control, to a great extent as a result of a global research effort that identified the sources of prions in meat and bone meal (MBM) and developed new animal-testing tools that guided policy. Priority (www.prionpriority.eu) was a European Union (EU) Framework Program 7 (FP7)-funded project through which 21 European research institutions and small and medium enterprises (SMEs) joined efforts between 2009 and 2014, to conduct coordinated basic and applied research on prions and prion diseases. At the end of the project, the Priority consortium drafted a position paper (www.prionpriority.eu/Priority position paper) with its main conclusions. In the present opinion paper, we summarize these conclusions.

With respect to the issue of re-introducing ruminant protein into the feed-chain, our opinion is that sustaining an absolute ban on feeding ruminant protein to ruminants is essential. In particular, the spread and impact of non-classical forms of scrapie and BSE in ruminants is not fully understood and the risks cannot be estimated. Atypical prion agents will probably continue to represent the dominant form of prion diseases in the near future in Europe. Atypical L-type BSE has clear zoonotic potential, as demonstrated in experimental models. Similarly, there are now data indicating that the atypical scrapie agent can cross various species barriers. More epidemiological data from large cohorts are necessary to reach any conclusion on the impact of its transmissibility on public health. Re-evaluations of safety precautions may become necessary depending on the outcome of these studies.

Intensified searching for molecular determinants of the species barrier is recommended, since this barrier is key for important policy areas and risk assessment. Understanding the structural basis for strains and the basis for adaptation of a strain to a new host will require continued fundamental research, also needed to understand mechanisms of prion transmission, replication and how they cause nervous system dysfunction and death. Early detection of prion infection, ideally at a preclinical stage, also remains crucial for development of effective treatment strategies.     

Resistance of Bovine Spongiform Encephalopathy (BSE) Prions to Inactivation

Distinct prion strains often exhibit different incubation periods and patterns of neuropathological lesions. Strain characteristics are generally retained upon intraspecies transmission, but may change on transmission to another species. We investigated the inactivation of two related prions strains: BSE prions from cattle and mouse-passaged BSE prions, termed 301V. Inactivation was manipulated by exposure to sodium dodecyl sulfate (SDS), variations in pH, and different temperatures. Infectivity was measured using transgenic mouse lines that are highly susceptible to either BSE or 301V prions. Bioassays demonstrated that BSE prions are up to 1,000-fold more resistant to inactivation than 301V prions while Western immunoblotting showed that short acidic SDS treatments reduced protease-resistant PrP^Sc from BSE prions and 301V prions at similar rates. Our findings argue that despite being derived from BSE prions, mouse 301V prions are not necessarily a reliable model for cattle BSE prions. Extending these comparisons to human sporadic Creutzfeldt-Jakob disease and hamster Sc237 prions, we found that BSE prions were 10- and 10⁶-fold more resistant to inactivation, respectively. Our studies contend that any prion inactivation procedures must be validated by bioassay against the prion strain for which they are intended to be used.     

Transgenic Rabbits Expressing Ovine PrP Are Susceptible to Scrapie

Transmissible spongiform encephalopathies (TSEs) are a group of neurodegenerative diseases affecting a wide range of mammalian species. They are caused by prions, a proteinaceous pathogen essentially composed of PrP^Sc, an abnormal isoform of the host encoded cellular prion protein PrPC. Constrained steric interactions between PrP^Sc and PrP^C are thought to provide prions with species specificity, and to control cross-species transmission into other host populations, including humans. Transgenetic expression of foreign PrP genes has been successfully and widely used to overcome the recognized resistance of mouse to foreign TSE sources. Rabbit is one of the species that exhibit a pronounced resistance to TSEs. Most attempts to infect experimentally rabbit have failed, except after inoculation with cell-free generated rabbit prions. To gain insights on the molecular determinants of the relative resistance of rabbits to prions, we generated transgenic rabbits expressing the susceptible V¹³⁶R¹⁵⁴Q¹⁷¹ allele of the ovine PRNP gene on a rabbit wild type PRNP New Zealand background and assessed their experimental susceptibility to scrapie prions. All transgenic animals developed a typical TSE 6–8 months after intracerebral inoculation, whereas wild type rabbits remained healthy more than 700 days after inoculation. Despite the endogenous presence of rabbit PrP^C, only ovine PrP^Sc was detectable in the brains of diseased animals. Collectively these data indicate that the low susceptibility of rabbits to prion infection is not enciphered within their non-PrP genetic background.     

A new perspective on Hsp104-mediated propagation and curing of the yeast prion [PSI+]

Most prions in yeast form amyloid fibrils that must be severed by the protein disaggregase Hsp104 to be propagated and transmitted efficiently to newly formed buds. Only one yeast prion, [PSI⁺], is cured by Hsp104 overexpression. We investigated the interaction between Hsp104 and Sup35, the priongenic protein in yeast that forms the [PSI⁺] prion.¹ We found that a 20-amino acid segment within the highly-charged, unstructured middle domain of Sup35 contributes to the physical interaction between the middle domain and Hsp104. When this segment was deleted from Sup35, the efficiency of [PSI⁺] severing was substantially reduced, resulting in larger Sup35 particles and weakening of the [PSI⁺] phenotype. Furthermore, [PSI⁺] in these cells was completely resistant to Hsp104 curing. The affinity of Hsp104 was considerably weaker than that of model Hsp104-binding proteins and peptides, implying that Sup35 prions are not ideal substrates for Hsp104-mediated remodeling. In light of this finding, we present a modified model of Hsp104-mediated [PSI⁺] propagation and curing that requires only partial remodeling of Sup35 assembled into amyloid fibrils.     

The yeast prions [PSI+] and [URE3] are molecular degenerative diseases

The yeast prions [URE3] and [PSI] are not found in wild strains, suggesting they are not an advantage. Prion-forming ability is not conserved, even within Saccharomyces, suggesting it is a disease. Prion domains have non-prion functions, explaining some conservation of sequence. However, in spite of the sequence being constrained in evolution by these non-prion functions, the prion domains vary more rapidly than the remainder of the molecule, and these changes produce a transmission barrier, suggesting that these changes were selected to block prion infection. Yeast prions [PSI] and [URE3] induce a cellular stress response (Hsp104 and Hsp70 induction), suggesting the cells are not happy about being infected. Recently, we showed that the array of [PSI] and [URE3] prions includes a majority of lethal or very toxic variants, a result not expected if either prion were an adaptive cellular response to stress.Key words: [URE3], [PSI⁺], prion, Sup35p, Ure2pfMammalian prions are uniformly fatal, but a lethal yeast prion would not be detected by the usual procedure, which requires growth of a colony under some selective condition. As a result, the prion variants commonly studied are quite mild in their effects. This circumstance has led to the suggestion that yeast prions actually benefit their host. Sup35p, the translation termination subunit whose amyloid becomes the [PSI⁺] prion, is essential for growth and Ure2p, the nitrogen regulation protein whose amyloid constitutes the [URE3] prion, is important for growth, with ure2 mutants showing noticeably slowed growth.When yeast prions were discovered,¹ we assumed they were diseases, by analogy with the mammalian diseases and the many non-prion amyloid diseases. Inactivating the essential Sup35p or the desireable Ure2p did not seem like a useful strategy. While control of either protein''s activity might be advantageous, and Ure2p activity control is the key to regulation of nitrogen catabolism, prion formation is a stochastic process, so it makes control of activity of these proteins random instead of appropriate to the circumstances. The [Het-s] prion changed that picture.² Here was a prion necessary for a normal function, heterokaryon incompatibility, and we suggested that it was the first beneficial prion.³     

Genetic Predictions of Prion Disease Susceptibility in Carnivore Species Based on Variability of the Prion Gene Coding Region

Mammalian species vary widely in their apparent susceptibility to prion diseases. For example, several felid species developed prion disease (feline spongiform encephalopathy or FSE) during the bovine spongiform encephalopathy (BSE) epidemic in the United Kingdom, whereas no canine BSE cases were detected. Whether either of these or other groups of carnivore species can contract other prion diseases (e.g. chronic wasting disease or CWD) remains an open question. Variation in the host-encoded prion protein (PrP^C) largely explains observed disease susceptibility patterns within ruminant species, and may explain interspecies differences in susceptibility as well. We sequenced and compared the open reading frame of the PRNP gene encoding PrP^C protein from 609 animal samples comprising 29 species from 22 genera of the Order Carnivora; amongst these samples were 15 FSE cases. Our analysis revealed that FSE cases did not encode an identifiable disease-associated PrP polymorphism. However, all canid PrPs contained aspartic acid or glutamic acid at codon 163 which we propose provides a genetic basis for observed susceptibility differences between canids and felids. Among other carnivores studied, wolverine (Gulo gulo) and pine marten (Martes martes) were the only non-canid species to also express PrP-Asp163, which may impact on their prion diseases susceptibility. Populations of black bear (Ursus americanus) and mountain lion (Puma concolor) from Colorado showed little genetic variation in the PrP protein and no variants likely to be highly resistant to prions in general, suggesting that strain differences between BSE and CWD prions also may contribute to the limited apparent host range of the latter.     

Strategies for identifying new prions in yeast

The unexpected discovery of two prions, [URE3] and [PSI⁺], in Saccharomyces cerevisiae led to questions about how many other proteins could undergo similar prion-based structural conversions. However, [URE3] and [PSI⁺] were discovered by serendipity in genetic screens. Cataloging the full range of prions in yeast or in other organisms will therefore require more systematic search methods. Taking advantage of some of the unique features of prions, various researchers have developed bioinformatic and experimental methods for identifying novel prion proteins. These methods have generated long lists of prion candidates. The systematic testing of some of these prion candidates has led to notable successes; however, even in yeast, where rapid growth rate and ease of genetic manipulation aid in testing for prion activity, such candidate testing is laborious. Development of better methods to winnow the field of prion candidates will greatly aid in the discovery of new prions, both in yeast and in other organisms, and help us to better understand the role of prions in biology.Key words: yeast, prion, bioinformatics, Sup35, [PSI⁺], Ure2, [URE3]     

Phosphatidylethanolamine as a prion cofactor: Potential implications for disease pathogenesis

Mammalian prions with significant levels of specific infectivity can be formed in vitro from mixtures of prion protein (PrP) and cofactor molecules, but not from PrP alone. We recently isolated and identified the essential membrane phospholipid phosphatidylethanolamine (PE) as an endogenous cofactor for prion propagation in vitro.¹ In this article, we discuss the potential role of PE and other essential cofactor molecules as a molecular link between the processes of prion formation and prion-induced neurodegeneration.     

Enzymatic degradation of a prion-like protein,Sup35NM-His6

Recent studies indicate that enzymatic treatment of the infectious PrP^Sc prion under defined conditions could be an effective method to inactivate infectious prions. However, field studies on prion inactivation are hampered by restricted access to the dangerous and expensive infectious prion material. Hence, a surrogate marker for infectious prions would facilitate more practical prion inactivation research. Protein Sup35p, a non-pathogenic prion-like protein produced in yeast, has physical and chemical properties very similar to the BSE prion. Sup35NM-His6, a derivative of Sup35p, was produced from Escherichia coli by gene cloning, protein expression and purification. Monomeric Sup35NM-His6 is soluble. When aggregated, it forms prion-like amyloid, insoluble and resistant to proteases. Similar to BSE prion, a pre-heating step renders this protein digestible by proteinase K, subtilisin and keratinase but not collagenase and elastase. These results indicated that Sup35NM-His6, being simple and inexpensive to produce and non-pathogenic, can be a potential ideal candidate of prion surrogate protein in the study of prion inactivation and prevention of prion diseases.     

Yeast J-protein Sis1 prevents prion toxicity by moderating depletion of prion protein

[PSI⁺] is a prion of Saccharomyces cerevisiae Sup35, an essential ribosome release factor. In [PSI⁺] cells, most Sup35 is sequestered into insoluble amyloid aggregates. Despite this depletion, [PSI⁺] prions typically affect viability only modestly, so [PSI⁺] must balance sequestering Sup35 into prions with keeping enough Sup35 functional for normal growth. Sis1 is an essential J-protein regulator of Hsp70 required for the propagation of amyloid-based yeast prions. C-terminally truncated Sis1 (Sis1JGF) supports cell growth in place of wild-type Sis1. Sis1JGF also supports [PSI⁺] propagation, yet [PSI⁺] is highly toxic to cells expressing only Sis1JGF. We searched extensively for factors that mitigate the toxicity and identified only Sis1, suggesting Sis1 is uniquely needed to protect from [PSI⁺] toxicity. We find the C-terminal substrate-binding domain of Sis1 has a critical and transferable activity needed for the protection. In [PSI⁺] cells that express Sis1JGF in place of Sis1, Sup35 was less soluble and formed visibly larger prion aggregates. Exogenous expression of a truncated Sup35 that cannot incorporate into prions relieved [PSI⁺] toxicity. Together our data suggest that Sis1 has separable roles in propagating Sup35 prions and in moderating Sup35 aggregation that are crucial to the balance needed for the propagation of what otherwise would be lethal [PSI⁺] prions.     

The aminoglycoside G418 hinders de novo prion infection in cultured cells

The study of prions and the discovery of candidate therapeutics for prion disease have been facilitated by the ability of prions to replicate in cultured cells. Paradigms in which prion proteins from different species are expressed in cells with low or no expression of endogenous prion protein (PrP) have expanded the range of prion strains that can be propagated. In these systems, cells stably expressing a PrP of interest are typically generated via coexpression of a selectable marker and treatment with an antibiotic. Here, we report the unexpected discovery that the aminoglycoside G418 (Geneticin) interferes with the ability of stably transfected cultured cells to become infected with prions. In G418-resistant lines of N2a or CAD5 cells, the presence of G418 reduced levels of protease-resistant PrP following challenge with the RML or 22L strains of mouse prions. G418 also interfered with the infection of cells expressing hamster PrP with the 263K strain of hamster prions. Interestingly, G418 had minimal to no effect on protease-resistant PrP levels in cells with established prion infection, arguing that G418 selectively interferes with de novo prion infection. As G418 treatment had no discernible effect on cellular PrP levels or its localization, this suggests that G418 may specifically target prion assemblies or processes involved in the earliest stages of prion infection.     

The sensitive [SWI+] prion: New perspectives on yeast prion diversity

Yeast prions are heritable protein-based genetic elements which rely on molecular chaperone proteins for stable transmission to cell progeny. Within the past few years, five new prions have been validated and 18 additional putative prions identified in Saccharomyces cerevisiae. The exploration of the physical and biological properties of these “nouveau prions” has begun to reveal the extent of prion diversity in yeast. We recently reported that one such prion, [SWI⁺], differs from the best studied, archetypal prion [PSI⁺] in several significant ways.¹ Notably, [SWI⁺] is highly sensitive to alterations in Hsp70 system chaperone activity and is lost upon growth at elevated temperatures. In that report we briefly noted a correlation amongst prions regarding amino acid composition, seed number and sensitivity to the activity of the Hsp70 chaperone system. Here we extend that analysis and put forth the idea that [SWI⁺] may be representative of a class of asparagine-rich yeast prions which also includes [URE3], [MOT3⁺] and [ISP⁺], distinct from the glutamine-rich prions such as [PSI⁺] and [RNQ⁺]. While much work remains, it is apparent that our understanding of the extent of the diversity of prion characteristics is in its infancy.Key words: Sis1, Hsp40, chromatin remodeling, Swi1, Ssa, heat-shock, protein misfolding, cell stress, Hsp 104, PINYeast prions are heritable elements, most of which are amyloid aggregates of single proteins. The three best studied yeast prions [PSI⁺], [RNQ⁺] (also called [PIN⁺]), and [URE3] are formed from amyloid aggregates of the cytosolic yeast proteins Sup35, Rnq1 and Ure2, respectively.² Yeast prions can spontaneously arise in an otherwise clonal cell population, a process referred to as prion formation or nucleation, but once formed their continued propagation is intimately related to molecular chaperone activity. Chaperone function is needed to fragment prion amyloids to create heritable seeds which can then be passed on to cell progeny, thus maintaining the prion in the cell line.³ Yeast prions vary in the steady-state number of heritable seeds per cell; having more seeds increases the chances of passing the prion to progeny and hence prions with higher seed numbers are more mitotically stable.^4–6The currently accepted model of prion fragmentation posits that components of the Hsp70 chaperone system work in congress with the disaggregase Hsp104.^1,7–9 Hsp70-type chaperones function by repeatedly binding and releasing client polypeptides in an ATP-dependent manner, a cycle that is tightly regulated by co-chaperone proteins (Fig. 1). J-proteins (Hsp40s) stimulate Hsp70 ATP hydrolysis and peptide binding via a conserved J-domain whereas nucleotide exchange factors (NEFs) stimulate ADP/ATP exchange, restoring the ATP-bound (peptide unbound) state. In prion fragmentation, the J-protein Sis1, the Hsp70 Ssa, and nucleotide exchange factors (NEFs) of the Sse family are co-chaperones required as partners for the Hsp70 Ssa. While chaperone proteins may have additional functions in prion biology, e.g., prion formation, these additional functions are still poorly understood.⁹Open in a separate windowFigure 1The Cyclic Hsp70 Chaperone System. Ssa (purple), the yeast cytosolic Hsp70, binds and releases client polypeptides (blue) in a regulated and ATP-dependent manner. J-proteins (aquamarine) including Sis1, Ydj1 and others, stimulate Ssa ATP hydrolysis by virtue of a conserved J-domain and thereby catalyze the “forward” direction of the cycle as indicated above. ADP•Ssa more stably associates with client polypeptides than the ATP-bound form and hence J-proteins favor the ADP•Ssa•Peptide complex. In some cases, J-proteins can also bind and deliver client polypeptides to Hsp70s via C-terminal domains (also shown above). Nucleotide exchange factors (NEFs), including the Sse proteins (dark blue) which share some structural homology with Ssa, catalyze the “reverse” direction of the cycle by facilitating ADP release and subsequent ATP binding, and thus favor an ATP•Ssa state with a dissociated peptide.In the past few years, the number of known yeast prions has rapidly grown such that, to date, a total of eight yeast prions have been identified and an additional 18 proteins have been annotated as putative prions.¹⁰ The biological and physical properties of these newly discovered prions are only beginning to be explored. We recently reported the results of an investigation into the biological properties of the prion [SWI⁺], which is formed from the chromatin-remodeling factor Swi1.¹ Swi1 is part of the SWI/SNF chromatin-remodeling complex that regulates the expression of approximately 6% of all yeast genes.¹¹ The presence of [SWI⁺] causes partial loss of SWI/SNF chromatin-remodeling function, resulting in the impaired ability to uptake certain sugars, among other phenotypes.¹¹ [SWI⁺] is a prion of particular interest because of its potential to alter global gene expression. Below we describe its intriguing interactions with molecular chaperone proteins and environmental stress, and the implications of these properties on yeast prion biology.     

Assessing the Susceptibility of Transgenic Mice Overexpressing Deer Prion Protein to Bovine Spongiform Encephalopathy

Several transgenic mouse models have been developed which facilitate the transmission of chronic wasting disease (CWD) of cervids and allow prion strain discrimination. The present study was designed to assess the susceptibility of the prototypic mouse line, Tg(CerPrP)1536^+/−, to bovine spongiform encephalopathy (BSE) prions, which have the ability to overcome species barriers. Tg(CerPrP)1536^+/− mice challenged with red deer-adapted BSE resulted in 90% to 100% attack rates, and BSE from cattle failed to transmit, indicating agent adaptation in the deer.