Structure and assembly properties of the yeast prion Ure2p

Fluorescent dye ProteoStat to detect and discriminate intracellular amyloid-like aggregates in Escherichia coli

The formation of amyloid aggregates is linked to the onset of an increasing number of human disorders. Thus, there is an increasing need for methodologies able to provide insights into protein deposition and its modulation. Many approaches exist to study amyloids in vitro, but the techniques available for the study of amyloid aggregation in cells are still limited and non-specific. In this study we developed a methodology for the detection of amyloid-like aggregates inside cells that discriminates these ordered assemblies from other intracellular aggregates. We chose bacteria as model system, since the inclusion bodies formed by amyloid proteins in the cytosol of bacteria resemble toxic amyloids both structurally and functionally. Using confocal microscopy, fluorescence spectroscopy, and flow cytometry, we show that the recently developed red fluorescent dye ProteoStat can detect the presence of intracellular amyloid-like deposits in living bacterial cells with high specificity, even when the target proteins are expressed at low levels. This methodology allows quantitation of the intracellular amyloid content, shows the potential to replace in vitro screenings in the search for therapeutic anti-amyloidogenic compounds, and might be useful for identifying conditions that prevent the aggregation of therapeutic recombinant proteins.

Prions in yeast

The concept of a prion as an infectious self-propagating protein isoform was initially proposed to explain certain mammalian diseases. It is now clear that yeast also has heritable elements transmitted via protein. Indeed, the "protein only" model of prion transmission was first proven using a yeast prion. Typically, known prions are ordered cross-β aggregates (amyloids). Recently, there has been an explosion in the number of recognized prions in yeast. Yeast continues to lead the way in understanding cellular control of prion propagation, prion structure, mechanisms of de novo prion formation, specificity of prion transmission, and the biological roles of prions. This review summarizes what has been learned from yeast prions.

Propagation of the [PIN+] prion by fragments of Rnq1 fused to GFP

Prions are viewed as enigmatic infectious entities whose genetic properties are enciphered solely in an array of self-propagating protein aggregate conformations. Rnq1, a yeast protein with yet unknown function, forms a prion named [PIN+] for its ability to facilitate the de novo induction of another prion, [PSI+]. Here we investigate a set of RNQ1 truncations that were designed to cover major Rnq1 sequence elements similar to those important for the propagation of other yeast prions: a region rich in asparagines and glutamines and several types of oligopeptide repeats. Proteins encoded by these RNQ1 truncations were tested for their ability to (a) join (decorate) pre-existing [PIN+] aggregates made of wild-type Rnq1 and (b) maintain the heritable aggregated state in the absence of wild-type RNQ1. While the possible involvement of particular sequence elements in the propagation of [PIN+] is discussed, the major result is that the efficiency of transmission of [PIN+] from wild-type Rnq1 to a fragment decreased with the fragment's length.

An efficient protein transformation protocol for introducing prions into yeast

Although a range of robust techniques exists for transforming organisms with nucleic acids, approaches for introducing proteins into cells are far less developed. Here we describe a facile and highly efficient protein transformation protocol suitable for introducing prion particles, produced in vitro from pure protein or purified from an in vivo source, into yeast. Prion particles composed of amyloid forms of fragments of Sup35p, the protein determinant of the yeast prion state [PSI(+)], lead to dose-dependent de novo induction of [PSI(+)] with efficiencies approaching 100% at high protein concentrations. We also describe a procedure for generating distinct, self-propagating amyloid conformations of a prionogenic Sup35p fragment termed Sup-NM. Remarkably, infection of yeast with different Sup-NM amyloid conformations leads to distinct [PSI(+)] prion strains, establishing that the heritable differences in prion strain differences result directly from self-propagating differences in the conformations of the infectious protein. This protein transformation protocol can be readily adapted to the analysis of other yeast prion states, as well as to test the infectious (prion) nature of protein extracts from less well-characterized epigenetic traits. More generally, the protein transformation procedure makes it possible to bridge in vitro and in vivo studies, thus greatly facilitating efforts to explain the structural and mechanistic basis of prion inheritance.