Creutzfeldt-Jakob disease and mad cows: lessons learnt from yeast cells.

Transmissible spongiform encephalopathies are fatal neurodegenerative diseases that affect mammals including humans. The proteinaceous nature of the infectious agent, the prion, and its propagation, challenge established dogmas in biology. It is now widely accepted that prion diseases are caused by unconventional agents principally composed of a misfolded host-encoded protein, PrP. Surprisingly, major break-throughs in prion research came from studies on functionally unrelated proteins in yeast and filamentous fungi. Aggregates composed of these proteins act as epigenetic elements of inheritance that can propagate their alternative states by a conformational switch into an ordered ß-sheet rich polymer just like mammalian prions. Since their discovery prions of lower eukaryotes have provided invaluable insights into all aspects of prion biogenesis. Importantly, yeast prions provide proof-of-principle that distinct protein conformers can be infectious and can serve as genetic elements that have the capacity to encipher strain specific information. As a powerful and tractable model system, yeast prions will continue to increase our understanding of prion-host cell interaction and potential mechanisms of protein-based epigenetic inheritance.

Species barriers in prion diseases--brief review.

Transmissible spongiform encephalopathies (TSEs or prion diseases) are neurological disorders associated with the aggregation of a pathologic isoform of a host-encoded protein, termed prion protein (PrP). The pathologic isoform of PrP, termed PrP(Sc), is a major constituent of the infectious agent. TSE diseases are characterized by neurodegenerative failure and inevitable morbidity. Bovine spongiform encephalopathy (BSE) has been transmitted from cattle to humans to cause a new variant of Creutzfeldt-Jakob syndrome. The potential for chronic wasting disease to similarly cross the species barrier from cervids to humans is considered unlikely but possible. Thus, understanding how TSE agents overcome resistance to transmission between species is crucial if we are to prevent future epidemics. The species barrier usually can be abrogated to varying degrees in laboratory animals. Studies done with transgenic animals, tissue culture, and cell-free assays established PrP as being necessary for TSE pathogenesis and illustrated that certain amino acid residues are more influential than others for conferring resistance to TSE agent transmission. The essence of what constitutes a TSE agent's species compatibility is thought to be orchestrated by a complex interplay of contributions from its primary amino acid sequence, its glycoform patterns, and its three-dimensional structure.

Deletion of beta-strand and alpha-helix secondary structure in normal prion protein inhibits formation of its protease-resistant isoform.

A fundamental event in the pathogenesis of transmissible spongiform encephalopathies (TSE) is the conversion of a normal, proteinase K-sensitive, host-encoded protein, PrP-sen, into its protease-resistant isoform, PrP-res. During the formation of PrP-res, PrP-sen undergoes conformational changes that involve an increase of beta-sheet secondary structure. While previous studies in which PrP-sen deletion mutants were expressed in transgenic mice or scrapie-infected cell cultures have identified regions in PrP-sen that are important in the formation of PrP-res, the exact role of PrP-sen secondary structures in the conformational transition of PrP-sen to PrP-res has not yet been defined. We constructed PrP-sen mutants with deletions of the first beta-strand, the second beta-strand, or the first alpha-helix and tested whether these mutants could be converted to PrP-res in both scrapie-infected neuroblastoma cells (Sc(+)-MNB cells) and a cell-free conversion assay. Removal of the second beta-strand or the first alpha-helix significantly altered both processing and the cellular localization of PrP-sen, while deletion of the first beta-strand had no effect on these events. However, all of the mutants significantly inhibited the formation of PrP-res in Sc(+)-MNB cells and had a greatly reduced ability to form protease-resistant PrP in a cell-free assay system. Thus, our results demonstrate that deletion of the beta-strands and the first alpha-helix of PrP-sen can fundamentally affect PrP-res formation and/or PrP-sen processing.

The use of monoclonal antibody epitopes for tagging PrP in conversion experiments.

The key event in the pathogenesis of spongiform encephalopathies is a conformational transition of a normal cellular protein, PrPsen, to its pathological isoform, PrPres. The mechanism of PrPres formation is unknown but is likely to involve a direct interaction between PrPsen and PrPres. The molecular basis of PrPres formation has been studied extensively using transgenic mice and scrapie-infected tissue cultures that express heterologous PrP molecules. However, these experiments are dependant on the discrimination of endogenous host PrP and exogenous PrP molecules. Here we give a short review on the PrP-specific epitopes that have been used for tagging exogenous PrP molecules and present a novel PrP-specific epitope that is well suitable for in vivo and in vitro conversion experiments.

A novel epitope for the specific detection of exogenous prion proteins in transgenic mice and transfected murine cell lines.

Prion diseases are closely linked to the conversion of host-encoded cellular prion protein (PrPC) into its pathological isoform (PrPSc). PrP conversion experiments in scrapie infected tissue culture cells, transgenic mice, and cell-free systems usually require unique epitopes and corresponding monoclonal antibodies (MAbs) for the immunological discrimination of exogenously introduced and endogenous PrP compounds (e.g., MAb 3F4, which is directed to an epitope on hamster and human but not on murine PrP). In the current work, we characterize a novel MAb designated L42 that reacts to PrP of a variety of species, including cattle, sheep, goat, dog, human, cat, mink, rabbit, and guinea pig, but does not bind to mouse, hamster, and rat PrP. Therefore, MAb L42 may allow future in vitro conversion and transgenic studies on PrPs of the former species. The MAb L42 epitope on PrPC includes a tyrosine residue at position 144, whereas mouse, rat, and hamster PrPs incorporate tryptophane at this site. To verify this observation, we generated PrP expression vectors coding for authentic or mutated murine PrPCs (i.e., codon 144 encoding tyrosine instead of tryptophan). After transfection into neuroblastoma cells, MAb L42 did not react with immunoblotted wild-type murine PrPC, whereas L42 epitope-tagged murine PrPC was strongly recognized. Immunoblot and fluorescence-activated cell sorting data revealed that tagged PrPC was correctly posttranslationally processed and translocated to the cell surface.