Abstract
Protein translation and folding are tightly controlled processes in all cells, by proteostasis, an important component of which is the unfolded protein response (UPR). During periods of endoplasmic reticulum stress because of protein misfolding, the UPR activates a coordinated response in which the PERK branch activation restricts translation, while a variety of genes involved with protein folding, degradation, chaperone expression and stress responses are induced through signaling of the other branches. Chronic overactivation of the UPR, particularly the PERK branch, is observed in the brains of patients in a number of protein misfolding neurodegenerative diseases, including Alzheimer's, and Parkinson's diseases and the tauopathies. Recently, numerous genetic and pharmacological studies in mice have demonstrated the effectiveness of inhibiting the UPR for eliciting therapeutic benefit and boosting memory. In particular, fine‐tuning the level of PERK inhibition to provide neuroprotection without adverse side effects has emerged as a safe, effective approach. This includes the recent discovery of licensed drugs that can now be repurposed in clinical trials for new human treatments for dementia. This review provides an overview of the links between UPR overactivation and neurodegeneration in protein misfolding disorders. It discusses recent therapeutic approaches targeting this pathway, with a focus on treatments that fine‐tune PERK signaling.
Highlights
S (Morris et al 2014)
These unfolded protein response (UPR) markers appear in the same neurons and glia that present with abnormal tau phosphorylation, again suggesting phosphorylated tau aggregates and activation of the UPR during neurodegeneration are closely linked
Constitutive protein kinase RNA like ER kinase (PERK) signaling has been shown to promote cell death by apoptosis (Lin et al 2009), and PERK signaling in the absence of the other UPR components has been suggested to represent the terminal, pro-apoptotic phase of the UPR, that responds to prolonged endoplasmic reticulum (ER) stress (Lin et al 2007)
Summary
ER stress and to the CHOP controlled switch to pro-death signaling are not understood, but are extremely important in the context of neurodegeneration. Nrf is maintained in an inactive state by Keap (Itoh et al 1999), but ER stress induces a PERK dependent dissociation of the Nrf2/Keap complex, allowing nuclear translocation (Cullinan et al 2003). This pro-survival response is independent of eIF2a-P (Cullinan et al 2003), and places PERK at the center of two distinct patterns of gene expression mediated by the direct phosphorylation of eIF2a and Nrf. This event removes a 26nucleotide intron, causing a frame shift in the reading frame eIF2α GDP eIF2γ eIF2β eIF2B tRNAi-Met eIF2α GTP eIF2γ eIF2β
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