The functional role of Ire1 in regulating autophagy and proteasomal degradation under prolonged proteotoxic stress.

Inhibition of endoribonuclease/kinase Ire1 has shown beneficial effects in many proteotoxicity-induced pathology models. The mechanism by which this occurs has not been elucidated completely. Using a proteotoxic yeast model of Huntington's disease, we show that the deletion of Ire1 led to lower protein aggregation at longer time points. The rate of protein degradation was higher in ΔIre1 cells. We monitored the two major protein degradation mechanisms in the cell. The increase in expression of Rpn4, coding for the transcription factor controlling proteasome biogenesis, was higher in ΔIre1 cells. The chymotrypsin-like proteasomal activity was also significantly enhanced in these cells at later time points of aggregation. The gene and protein expression levels of the autophagy gene Atg8 were higher in ΔIre1 than in wild-type cells. Significant increase in autophagy flux was also seen in ΔIre1 cells at later time points of aggregation. The results suggest that the deletion of Ire1 activates UPR-independent arms of the proteostasis network, especially under conditions of aggravated stress. Thus, the inhibition of Ire1 may regulate UPR-independent cellular stress-response pathways under prolonged stress.

The role of the glycerol transporter channel Fps1p in cellular proteostasis during enhanced proteotoxic stress.

In response to osmotic shock, the components of high-osmolarity glycerol (HOG) pathway regulate the level of intracellular glycerol in yeast and ensure cell survival. Glycerol is a compatible solute and a stabiliser of proteins. Its role in maintaining proteostasis is less explored. We show that mild stress in the form of dietary restriction leads to increased glycerol level which increases cell viability. However, dietary restriction coupled with protein aggregation decreases intracellular glycerol level and attenuates cell viability. The transcript level of FPS1, the glycerol transporter channel, remains unchanged. However, its activity is altered under enhanced proteotoxic stress. Our results provide evidence for a probable role of the Fps1p channel in the cellular proteostasis network. KEY POINTS: • Dietary restriction led to increased accumulation of glycerol in Fps1-deleted yeast cells. • This led to lower protein aggregation in these cells. • Increased production of glycerol under dietary restriction was not linked to increased level of Fps1.

Saccharomyces cerevisiae Fpr1 functions as a chaperone to inhibit protein aggregation.

Peptidyl prolyl isomerases (PPIases) accelerate the rate limiting step of protein folding by catalyzing cis/trans isomerization of peptidyl prolyl bonds. The larger PPIases have been shown to be multi-domain proteins, with functions other than isomerization of the proline-containing peptide bond. Recently, a few smaller PPIases have also been described for their ability to stabilize folding intermediates. The yeast Fpr1 (FK506-sensitive proline rotamase) is a homologue of the mammalian prolyl isomerase FKBP12 (FK506-binding protein of 12 kDa). Its ability to stabilize stressed cellular proteins has not been reported yet. We had earlier reported upregulation of Fpr1 in yeast cells exposed to proteotoxic stress conditions. In this work, we show that yeast Fpr1 exhibits characteristics typical of a general chaperone of the proteostasis network. Aggregation of mutant huntingtin fragment was higher in Fpr1-deleted as compared to parental yeast cells. Overexpression of Fpr1 led to reduced protein aggregation by decreasing the amount of oligomers and diverting the aggregation pathway towards the formation of detergent-soluble species. This correlated well with higher survival of these cells. Purified and enzymatically active yeast Fpr1 was able to inhibit aggregation of mutant huntingtin fragment and luciferase in vitro in a concentration-dependent manner; suggesting a direct action for aggregation inhibitory action of Fpr1. Overexpression of yeast Fpr1 was able to protect E. coli cells against thermal shock. This work establishes the role of Fpr1 in the protein folding network and will be used for the identification of novel pharmacological leads in disease conditions.

Discrete roles of trehalose and Hsp104 in inhibition of protein aggregation in yeast cells.

Heat shock response (HSR) is an important element of cellular homeostasis. In yeast, HSR comprises of the heat shock proteins (Hsps) and the osmolytes trehalose and glycerol. The respective roles of trehalose and Hsp104 in regulating protein aggregation remain ambiguous. We report that trehalose and Hsp104 are important during the early stages of protein aggregation, i.e. when the process is still reversible. This corroborates the earlier reported role of trehalose being an inhibitor of protein folding. Under in vitro conditions, trehalose is able to restore the GdHCl-induced loss of ATPase activity of recombinant Hsp104 to almost its original level. As the saturation phase of aggregation approaches, neither of the two components is able to exert any effect. Inactivation of Hsp104 at the stage when oligomers have already been formed increases the rate of formation of aggregates by inhibiting disaggregation of oligomers. In the absence of an active disaggregase, the oligomers are converted to mature irreversible aggregates, accelerating their formation. Our results suggest that the disaccharide may have a marginally stronger influence than Hsp104 in inhibiting protein aggregation in yeast cells.

Protein aggregation activates erratic stress response in dietary restricted yeast cells.

Chronic stress and prolonged activation of defence pathways have deleterious consequences for the cell. Dietary restriction is believed to be beneficial as it induces the cellular stress response machinery. We report here that although the phenomenon is beneficial in a wild-type cell, dietary restriction leads to an inconsistent response in a cell that is already under proteotoxicity-induced stress. Using a yeast model of Huntington's disease, we show that contrary to expectation, aggregation of mutant huntingtin is exacerbated and activation of the unfolded protein response pathway is dampened under dietary restriction. Global proteomic analysis shows that when exposed to a single stress, either protein aggregation or dietary restriction, the expression of foldases like peptidyl-prolyl isomerase, is strongly upregulated. However, under combinatorial stress, this lead is lost, which results in enhanced protein aggregation and reduced cell survival. Successful designing of aggregation-targeted therapeutics will need to take additional stressors into account.