Abstract
The yeast translation termination factor Sup35p, by aggregating as the [PSI+] prion, enables ribosomes to read-through stop codons, thus expanding the diversity of the Saccharomyces cerevisiae proteome. Yeast prions are functional amyloids that replicate by templating their conformation on native protein molecules, then assembling as large aggregates and fibers. Prions propagate epigenetically from mother to daughter cells by fragmentation of such assemblies. In the N-terminal prion-forming domain, Sup35p has glutamine/asparagine-rich oligopeptide repeats (OPRs), which enable propagation through chaperone-elicited shearing. We have engineered chimeras by replacing the polar OPRs in Sup35p by up to five repeats of a hydrophobic amyloidogenic sequence from the synthetic bacterial prionoid RepA-WH1. The resulting hybrid, [REP-PSI+], (i) was functional in a stop codon read-through assay in S. cerevisiae; (ii) generates weak phenotypic variants upon both its expression or transformation into [psi-] cells; (iii) these variants correlated with high molecular weight aggregates resistant to SDS during electrophoresis; and (iv) according to fluorescence microscopy, the fusion of the prion domains from the engineered chimeras to the reporter protein mCherry generated perivacuolar aggregate foci in yeast cells. All these are signatures of bona fide yeast prions. As assessed through biophysical approaches, the chimeras assembled as oligomers rather than as the fibers characteristic of [PSI+]. These results suggest that it is the balance between polar and hydrophobic residues in OPRs what determines prion conformational dynamics. In addition, our findings illustrate the feasibility of enabling new propagation traits in yeast prions by engineering OPRs with heterologous amyloidogenic sequence repeats.
Highlights
Modularity is a basic principle of organization in proteins and their assemblies
With a β-arcade based model in mind, we used a plasmid reporter system (Parham et al, 2001) in which all the oligopeptide repeats (OPRs) in Sup35p were replaced by up to five tandem repeats of the hydrophobic amyloidogenic stretch found in the bacterial prionoid RepA-WH1 (Giraldo, 2007; WH1-R1-5; Figure 1)
RepA-WH1 + Sup35p Chimeras are Functional in Yeast The engineered chimeras were expressed in yeast from the SUP35 promoter in a centromeric plasmid, and tested in an epigenetic red–white colony color assay (Figure 2): upon Sup35p aggregation as [PSI+], the reporter ade1-14 allele, including a premature amber stop codon, is read-through by the ribosomes allowing for the synthesis of adenine, giving white color colonies on rich, unselective medium
Summary
In the case of the aggregation-prone amyloidogenic proteins, modularity comes from the existence of sequence stretches that become the β-strand building blocks in cross-β sheets (reviewed in Eisenberg and Jucker, 2012). Such stretches can either have hydrophobic or polar average residue compositions, but usually not both at the same time, posing constrains to homotypic interactions, which require chemically compatible side chains to cross-aggregate.
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