Inhibition of endoplasmic reticulum-associated degradation rescues native folding in loss of function protein misfolding diseases

Lysosomal storage disorders are often caused by mutations that destabilize native folding and impair trafficking of secretory proteins. We demonstrate that endoplasmic reticulum (ER)-associated degradation (ERAD) prevents native folding of mutated lysosomal enzymes in patient-derived fibroblasts from two clinically distinct lysosomal storage disorders, namely Gaucher and Tay-Sachs disease. Prolonging ER retention via ERAD inhibition enhanced folding, trafficking, and activity of these unstable enzyme variants. Furthermore, combining ERAD inhibition with enhancement of the cellular folding capacity via proteostasis modulation resulted in synergistic rescue of mutated enzymes. ERAD inhibition was achieved by cell treatment with small molecules that interfere with recognition (kifunensine) or retrotranslocation (eeyarestatin I) of misfolded substrates. These different mechanisms of ERAD inhibition were shown to enhance ER retention of mutated proteins but were associated with dramatically different levels of ER stress, unfolded protein response activation, and unfolded protein response-induced apoptosis.     

Using a ubiquitin ligase as an unfolded protein sensor

A significant fraction of all proteins are misfolded and must be degraded. The ubiquitin-proteasome pathway provides an essential protein quality control function necessary for normal cellular homeostasis. Substrate specificity is mediated by proteins called ubiquitin ligases. In the endoplasmic reticulum (ER) a specialized pathway, the endoplasmic reticulum associated degradation (ERAD) pathway provides means to eliminate misfolded proteins from the ER. One marker used by the ER to identify misfolded glycoproteins is the presence of a high-mannose (Man5-8GlcNAc2) glycan. Recently, FBXO2 was shown to bind high mannose glycans and participate in ERAD. Using glycan arrays, immobilized glycoprotein pulldowns, and glycan competition assays we demonstrate that FBXO2 preferentially binds unfolded glycoproteins. Using recombinant, bacterially expressed GST-FBXO2 as an unfolded protein sensor we demonstrate it can be used to monitor increases in misfolded glycoproteins after physiological or pharmaceutical stressors.     

Derlin-2 and Derlin-3 are regulated by the mammalian unfolded protein response and are required for ER-associated degradation

Proteins that are unfolded or misfolded in the endoplasmic reticulum (ER) must be refolded or degraded to maintain the homeostasis of the ER. Components of both productive folding and ER-associated degradation (ERAD) mechanisms are known to be up-regulated by the unfolded protein response (UPR). We describe two novel components of mammalian ERAD, Derlin-2 and -3, which show weak homology to Der1p, a transmembrane protein involved in yeast ERAD. Both Derlin-2 and -3 are up-regulated by the UPR, and at least Derlin-2 is a target of the IRE1 branch of the response, which is known to up-regulate ER degradation enhancing alpha-mannosidase-like protein (EDEM) and EDEM2, receptor-like molecules for misfolded glycoprotein. Overexpression of Derlin-2 or -3 accelerated degradation of misfolded glycoprotein, whereas their knockdown blocked degradation. Derlin-2 and -3 are associated with EDEM and p97, a cytosolic ATPase responsible for extraction of ERAD substrates. These findings indicate that Derlin-2 and -3 provide the missing link between EDEM and p97 in the process of degrading misfolded glycoproteins.     

Degradation of misfolded proteins prevents ER-derived oxidative stress and cell death

A variety of debilitating diseases including diabetes, Alzheimer's, Huntington's, Parkinson's, and prion-based diseases are linked to stress within the endoplasmic reticulum (ER). Using S. cerevisiae, we sought to determine the relationship between protein misfolding, ER stress, and cell death. In the absence of ERV29, a stress-induced gene required for ER associated degradation (ERAD), misfolded proteins accumulate in the ER leading to persistent ER stress and subsequent cell death. Cells alleviate ER stress through the unfolded protein response (UPR); however, if stress is sustained the UPR contributes to cell death by causing the accumulation of reactive oxygen species (ROS). ROS are generated from two sources: the UPR-regulated oxidative folding machinery in the ER and mitochondria. Our results demonstrate a direct mechanism(s) by which misfolded proteins lead to cellular damage and death.     

ERAD substrate recognition in budding yeast

During protein synthesis, the orderly progression of folding, modification, and assembly is paramount to function and vis-à-vis cellular viability. Accordingly, sophisticated quality control mechanisms have evolved to monitor protein maturation throughout the cell. Proteins failing at any step are segregated and degraded as a preventative measure against potential toxicity. Although protein quality control is generally poorly understood, recent research advances in endoplasmic reticulum-associated degradation (ERAD) pathways have provided the most detailed view so far. The discovery of distinct substrate processing sites established a biochemical basis for genetic profiles of model misfolded proteins. Detailed mechanisms for substrate recognition were recently uncovered. For some proteins, sequential glycan trimming steps set a time window for folding. Proteins still unfolded at the final stage expose a specific degradation signal recognized by the ERAD machinery. Through this mechanism, the system does not in fact know that a molecule is “misfolded”. Instead, it goes by the premise that proteins past due have veered off their normal folding pathways and therefore aberrant.     

Endoplasmic reticulum-associated degradation mediated by MoHrd1 and MoDer1 is pivotal for appressorium development and pathogenicity of Magnaporthe oryzae

Most secretory proteins are folded and modified in the endoplasmic reticulum (ER); however, protein folding is error-prone, resulting in toxic protein aggregation and cause ER stress. Irreversibly misfolded proteins are subjected to ER-associated degradation (ERAD), modified by ubiquitination, and degraded by the 26S proteasome. The yeast ERAD ubiquitin ligase Hrd1p and multispanning membrane protein Der1p are involved in ubiquitination and transportation of the folding-defective proteins. Here, we performed functional characterization of MoHrd1 and MoDer1 and revealed that both of them are localized to the ER and are pivotal for ERAD substrate degradation and the ER stress response. MoHrd1 and MoDer1 are involved in hyphal growth, asexual reproduction, infection-related morphogenesis, protein secretion and pathogenicity of M. oryzae. Importantly, MoHrd1 and MoDer1 mediated conidial autophagic cell death and subsequent septin ring assembly at the appressorium pore, leading to abnormal appressorium development and loss of pathogenicity. In addition, deletion of MoHrd1 and MoDer1 activated the basal unfolded protein response (UPR) and autophagy, suggesting that crosstalk between ERAD and two other closely related mechanisms in ER quality control system (UPR and autophagy) governs the ER stress response. Our study indicates the importance of ERAD function in fungal development and pathogenesis of M. oryzae.     

ER stress differentially regulates the stabilities of ERAD ubiquitin ligases and their substrates

Endoplasmic reticulum (ER) stress-induced accumulation of misfolded proteins in the ER stimulates the ER-associated degradation (ERAD) process. ERAD in turn eliminates those misfolded proteins. Upregulation of ubiquitination enzymes is an essential mechanism by which ER stress enhances ERAD. However, ectopic overexpression of ubiquitination enzymes often fails to increase, and sometimes, inhibits ERAD. To further understand how ER stress regulates ERAD, we studied the effects of ER stress on ubiquitin ligase (E3) gp78-mediated ERAD and on the stabilities of gp78 and another ERAD E3 Hrd1. The results showed that ER stress-inducing agent tunicamycin significantly enhanced ERAD in cells that either express endogenous or overexpress gp78. Importantly, ER stress could increase ERAD even when new protein synthesis was inhibited by cycloheximide. Surprisingly, tunicamycin treatment stabilized gp78, an established ERAD E3 and an ERAD substrate as well, for up to 8h. By contrast, ER stress had little effects on the stability of another E3 Hrd1 except that it reduced the total ubiquitination level of Hrd1. Our data suggest that ER stress differentially regulates the stabilities of ERAD E3s and their substrates, which may represent a novel mechanism by which ER stress increases ERAD.     

The endoplasmic reticulum-associated degradation is necessary for plant salt tolerance

Eukaryotic organisms have quality-control mechanisms that allow misfolded or unassembled proteins to be retained in the endoplasmic reticulum (ER) and subsequently degraded by ER-associated degradation (ERAD). The ERAD pathway is well studied in yeast and mammals; however, the biological functions of plant ERAD have not been reported. Through molecular and cellular biological approaches, we found that ERAD is necessary for plants to overcome salt stress. Upon salt treatment ubiquitinated proteins increased in plant cells, especially unfolded proteins that quickly accumulated in the ER and subsequently induced ER stress responses. Defect in HRD3A of the HRD1/HRD3 complex of the ERAD pathway resulted in alteration of the unfolded protein response (UPR), increased plant sensitivity to salt, and retention of ERAD substrates in plant cells. Furthermore, we demonstrated that Ca(2+) release from the ER is involved in the elevation of UPR and reactive oxygen species (ROS) participates the ERAD-related plant salt response pathway.     

Misfolded proteins traffic from the endoplasmic reticulum (ER) due to ER export signals

Most misfolded secretory proteins remain in the endoplasmic reticulum (ER) and are degraded by ER-associated degradation (ERAD). However, some misfolded proteins exit the ER and traffic to the Golgi before degradation. Using model misfolded substrates, with or without defined ER exit signals, we found misfolded proteins can depart the ER by continuing to exhibit the functional export signals present in the corresponding correctly folded proteins. Anterograde transport of misfolded proteins utilizes the same machinery responsible for exporting correctly folded proteins. Passive ER retention, in which misfolded proteins fail to exit the ER due to the absence of exit signals or the inability to functionally present them, likely contributes to the retention of nonnative proteins in the ER. Intriguingly, compromising ERAD resulted in increased anterograde trafficking of a misfolded protein with an ER exit signal, suggesting that ERAD and ER exit machinery can compete for binding of misfolded proteins. Disabling ERAD did not result in transport of an ERAD substrate lacking an export signal. This is an important distinction for those seeking possible therapeutic approaches involving inactivating ERAD in anticipation of exporting a partially active protein.     

内质网应激偶联炎症反应与慢性病发病机制

内质网是合成细胞内分泌蛋白和膜蛋白并进行蛋白折叠的主要细胞器。新近研究证明,当内质网蛋白质合成与折叠的负担增加、非折叠或错误折叠蛋白质堆积,可激活内质网的几组特定信号转导通路,将这些应激信号传递到细胞浆和细胞核,引起未/错误折叠蛋白反应。这对维持细胞动态平衡和生物体的发育具有重要意义。更为重要的是,未/错误折叠蛋白反应能够与细胞内炎症反应信号转导通路偶联,是非感染性致病原引发炎症反应的主要原因。因此,内质网应激-未/错误折叠蛋白反应-炎症反应在特定的细胞发生偶联是许多炎症疾病的发病机制。本文综述该领域的研究进展,并介绍了内质网应激信号和炎症反应偶联参与一些慢性病发病的分子细胞机制。这些研究不仅加深人们对这些慢性病发病机制的了解,也有助于对调节内质网应激-炎症反应的药物的研发。     

Mnl2, a novel component of the ER associated protein degradation pathway

In eukaryotes, membrane and soluble proteins of the secretory pathway enter the endoplasmic reticulum (ER) after synthesis in an unfolded state. Directly after entry, most proteins are modified with glycans at suitable glycosylation sites and start to fold. A protein that cannot fold properly will be degraded in a process called ER associated degradation (ERAD). Failures in ERAD, either by loss of function or by premature degradation of proteins, are a cause of severe diseases. Therefore, the search for novel ERAD components to gain better insight in this process is of high importance. Carbohydrate trimming is a relevant process in ER quality control. In this work a novel putative yeast mannosidase encoded by the open reading frame YLR057W was identified and named Mnl2. Deletion of MNL2 diminished the degradation efficiency of misfolded CPY^* in the absence of the cognate mannosidase Mnl1, indicating a specific role in ERAD.     

ER stress and diseases

Proteins synthesized in the endoplasmic reticulum (ER) are properly folded with the assistance of ER chaperones. Malfolded proteins are disposed of by ER-associated protein degradation (ERAD). When the amount of unfolded protein exceeds the folding capacity of the ER, human cells activate a defense mechanism called the ER stress response, which induces expression of ER chaperones and ERAD components and transiently attenuates protein synthesis to decrease the burden on the ER. It has been revealed that three independent response pathways separately regulate induction of the expression of chaperones, ERAD components, and translational attenuation. A malfunction of the ER stress response caused by aging, genetic mutations, or environmental factors can result in various diseases such as diabetes, inflammation, and neurodegenerative disorders including Alzheimer's disease, Parkinson's disease, and bipolar disorder, which are collectively known as 'conformational diseases'. In this review, I will summarize recent progress in this field. Molecules that regulate the ER stress response would be potential candidates for drug targets in various conformational diseases.     

Cotranslocational degradation protects the stressed endoplasmic reticulum from protein overload

The ER's capacity to process proteins is limited, and stress caused by accumulation of unfolded and misfolded proteins (ER stress) contributes to human disease. ER stress elicits the unfolded protein response (UPR), whose components attenuate protein synthesis, increase folding capacity, and enhance misfolded protein degradation. Here, we report that P58(IPK)/DNAJC3, a UPR-responsive gene previously implicated in translational control, encodes a cytosolic cochaperone that associates with the ER protein translocation channel Sec61. P58(IPK) recruits HSP70 chaperones to the cytosolic face of Sec61 and can be crosslinked to proteins entering the ER that are delayed at the translocon. Proteasome-mediated cytosolic degradation of translocating proteins delayed at Sec61 is cochaperone dependent. In P58(IPK-/-) mice, cells with a high secretory burden are markedly compromised in their ability to cope with ER stress. Thus, P58(IPK) is a key mediator of cotranslocational ER protein degradation, and this process likely contributes to ER homeostasis in stressed cells.