Accumulation of mutant alpha1-antitrypsin Z in the endoplasmic reticulum activates caspases-4 and -12, NFkappaB, and BAP31 but not the unfolded protein response

In alpha(1)-antitrypsin (alpha1AT) deficiency, a polymerogenic mutant form of the secretory glycoprotein alpha1AT, alpha1ATZ, is retained in the endoplasmic reticulum (ER) of liver cells. It is not yet known how this results in liver injury in a subgroup of deficient individuals and how the remainder of deficient individuals escapes liver disease. One possible explanation is that the "susceptible" subgroup is unable to mount the appropriate protective cellular responses. Here we examined the effect of mutant alpha1ATZ on several potential protective signaling pathways by using cell lines with inducible expression of mutant alpha1AT as well as liver from transgenic mice with liver-specific inducible expression of mutant alpha1AT. The results show that ER retention of polymerogenic mutant alpha1ATZ does not result in an unfolded protein response (UPR). The UPR can be induced in the presence of alpha1ATZ by tunicamycin excluding the possibility that the pathway has been disabled. In striking contrast, ER retention of nonpolymerogenic alpha1AT mutants does induce the UPR. These results indicate that the machinery responsible for activation of the UPR can distinguish the physical characteristics of proteins that accumulate in the ER in such a way that it can respond to misfolded but not relatively ordered polymeric structures. Accumulation of mutant alpha1ATZ does activate specific signaling pathways, including caspase-12 in mouse, caspase-4 in human, NFkappaB, and BAP31, a profile that was distinct from that activated by nonpolymerogenic alpha1AT mutants.     

Mitochondrial autophagy and injury in the liver in alpha 1-antitrypsin deficiency

Homozygous, PIZZ alpha(1)-antitrypsin (alpha(1)-AT) deficiency is associated with chronic liver disease and hepatocellular carcinoma resulting from the toxic effects of mutant alpha(1)-anti-trypsin Z (alpha(1)-ATZ) protein retained in the endoplasmic reticulum (ER) of hepatocytes. However, the exact mechanism(s) by which retention of this aggregated mutant protein leads to cellular injury are still unknown. Previous studies have shown that retention of mutant alpha(1)-ATZ in the ER induces an intense autophagic response in hepatocytes. In this study, we present evidence that the autophagic response induced by ER retention of alpha(1)-ATZ also involves the mitochondria, with specific patterns of both mitochondrial autophagy and mitochondrial injury seen in cell culture models of alpha(1)-AT deficiency, in PiZ transgenic mouse liver, and in liver from alpha(1)-AT-deficient patients. Evidence for a unique pattern of caspase activation was also detected. Administration of cyclosporin A, an inhibitor of mitochondrial permeability transition, to PiZ mice was associated with a reduction in mitochondrial autophagy and injury and reduced mortality during experimental stress. These results provide evidence for the novel concept that mitochondrial damage and caspase activation play a role in the mechanism of liver cell injury in alpha(1)-AT deficiency and suggest the possibility of mechanism-based therapeutic interventions.     

Fasting in alpha1-antitrypsin deficient liver: constitutive [correction of consultative] activation of autophagy

Alpha1-antitrypsin (alpha1-AT) deficiency causes severe liver injury in a subgroup of patients. Liver injury is thought to be caused by retention of a polymerized mutant alpha1-ATZ molecule in the endoplasmic reticulum (ER) of hepatocytes and is associated with an intense autophagic response. However, there is limited information about what physiologic stressors might influence liver injury. In this study, we examined the effect of fasting in the PiZ mouse model of alpha1-AT deficiency, because fasting is a well-characterized physiological stressor and a known stimulus for autophagy. Results show that there is a marked increase in fat accumulation and in alpha1-AT-containing globules in the liver of the PiZ mouse induced by fasting. Although fasting induced a marked autophagic response in wild-type mice, the autophagic response was already activated in PiZ mice and did not further increase with fasting. PiZ mice also had a significantly decreased tolerance for prolonged fasting compared with wild-type mice (PiZ mice 0% survival of 72-h fast; wild-type 100% survivial). These results demonstrate an altered response to stress in the alpha1-AT-deficient liver, including inability to further increase an activated autophagic response, a developmental state-specific increase in alpha1-AT-containing globules, and increased mortality.     

Role of ubiquitin in proteasomal degradation of mutant alpha(1)-antitrypsin Z in the endoplasmic reticulum

A delay in intracellular degradation of the mutant alpha(1)-antitrypsin (alpha(1)AT)Z molecule is associated with greater retention within the endoplasmic reticulum (ER) and susceptibility to liver disease in a subgroup of patients with alpha(1)AT deficiency. Recent studies have shown that alpha(1)ATZ is ordinarily degraded in the ER by a mechanism that involves the proteasome, as demonstrated in intact cells using human fibroblast cell lines engineered for expression of alpha(1)ATZ and in a cell-free microsomal translocation assay system programmed with purified alpha(1)ATZ mRNA. To determine whether the ubiquitin system is required for proteasomal degradation of alpha(1)ATZ and whether specific components of the ubiquitin system can be implicated, we have now used two approaches. First, we overexpressed a dominant-negative ubiquitin mutant (UbK48R-G76A) by transient transfection in the human fibroblast cell lines expressing alpha(1)ATZ. The results showed that there was marked, specific, and selective inhibition of alpha(1)ATZ degradation mediated by UbK48R-G76A, indicating that the ubiquitin system is at least in part involved in ER degradation of alpha(1)ATZ. Second, we subjected reticulocyte lysate to DE52 chromatography and tested the resulting well-characterized fractions in the cell-free system. The results showed that there were both ubiquitin-dependent and -independent proteasomal mechanisms for degradation of alpha(1)ATZ and that the ubiquitin-conjugating enzyme E2-F1 may play a role in the ubiquitin-dependent proteasomal mechanism.     

The role of autophagy in alpha-1-antitrypsin deficiency: a specific cellular response in genetic diseases associated with aggregation-prone proteins

In the classical form of alpha-1-antitrypsin (AT) deficiency a point mutation renders aggregation-prone properties on a hepatic secretory protein. The mutant ATZ protein in retained in the endoplasmic reticulum (ER) of liver cells rather than secreted into the blood and body fluids where it ordinarily functions as an inhibitor of neutrophil proteases. A loss-of-function mechanism allows the neutrophil proteases to slowly destroy the connective tissue matrix of the lung, resulting in premature development of pulmonary emphysema as early as the third decade of life. A gain-of-toxic function mechanism is responsible for liver inflammation and carcinogenesis. Indeed this deficiency is the most common genetic cause of liver disease in children in the US. It also causes chronic liver inflammation and carcinoma that manifests itself later in life. However, the majority of affected homozygotes apparently escape liver disease. This last observation has led to the concept that genetic and/or environmental modifiers affect the disposal of mutant ATZ within the ER or affect the protective cellular responses activated by accumulation of ATZ in the ER and, in turn, these modifiers determine which homozygotes develop liver inflammation and carcinoma. In this article I review a series of studies published over the last six years showing that autophagy is specifically activated by ER accumulation of ATZ and that it plays a critical role in the disposal of this mutant protein. Indeed, the most recent studies suggest that there is specialization of the autophagic pathway in that it is specifically activated by, and designed for disposal of, the aggregated forms of ATZ while the proteasome is specialized for disposal of soluble forms of ATZ. Together, these studies provide further evidence for the importance of autophagy in the cellular adaptive response to aggregated proteins in general.     

The Role of Autophagy in Alpha-1-Antitrypsin Deficiency: A Specific Cellular Response in Genetic Diseases Associated with Aggregation-Prone Proteins

In the classical form of alpha-1-antitrypsin (AT) deficiency a point mutation renders aggregation-prone properties on a hepatic secretory protein. The mutant ATZ protein in retained in the endoplasmic reticulum (ER) of liver cells rather than secreted into the blood and body fluids where it ordinarily functions as an inhibitor of neutrophil proteases. A loss-of-function mechanism allows the neutrophil proteases to slowly destroy the connective tissue matrix of the lung, resulting in premature development of pulmonary emphysema as early as the third decade of life. A gain-of-toxic function mechanism is responsible for liver inflammation and carcinogenesis. Indeed this deficiency is the most common genetic cause of liver disease in children in the US. It also causes chronic liver inflammation and carcinoma that manifests itself later in life. However, the majority of affected homozygotes apparently escape liver disease. This last observation has led to the concept that genetic and/or environmental modifiers affect the disposal of mutant ATZ within the ER or affect the protective cellular responses activated by accumulation of ATZ in the ER and, in turn, these modifiers determine which homozygotes develop liver inflammation and carcinoma. In this article I review a series of studies published over the last 6 years showing that autophagy is specifically activated by ER accumulation of ATZ and that autophagy plays a critical role in the disposal of this mutant protein. Further, I review data suggesting that the autophagy is specifically designed for the cellular response to aggregated ATZ and aggregated proteins in general.     

Regulator of G Signaling 16 is a marker for the distinct endoplasmic reticulum stress state associated with aggregated mutant alpha1-antitrypsin Z in the classical form of alpha1-antitrypsin deficiency

In the classical form of alpha(1)-antitrypsin deficiency, a mutant protein accumulates in a polymerized form in the endoplasmic reticulum (ER) of liver cells causing liver damage and carcinogenesis by a gain-of-toxic function mechanism. Recent studies have indicated that the accumulation of mutant alpha(1)-antitrypsin Z in the ER specifically activates the autophagic response but not the unfolded protein response and that autophagy plays a critical role in disposal of insoluble alpha(1)-antitrypsin Z. In this study, we used genomic analysis of the liver in a novel transgenic mouse model with inducible expression to screen for changes in gene expression that would potentially define how the liver responds to accumulation of this mutant protein. There was no unfolded protein response. Of several distinct gene expression profiles, marked up-regulation of regulator of G signaling (RGS16) was particularly notable. RGS16 did not increase when model systems were exposed to classical inducers of ER stress, including tunicamycin and calcium ionophore, or when a nonpolymerogenic alpha(1)-antitrypsin mutant accumulated in the ER. RGS16 was up-regulated in livers from patients with alpha(1)-antitrypsin deficiency, and the degree of up-regulation correlated with the hepatic levels of insoluble alpha(1)-antitrypsin Z protein. Taken together, these results indicate that expression of RGS16 is an excellent marker for the distinct form of "ER stress" that occurs in alpha(1)-antitrypsin deficiency, presumably determined by the aggregation-prone properties of the mutant protein that characterizes the deficiency.     

Ubiquitin ligase SYVN1/HRD1 facilitates degradation of the SERPINA1 Z variant/α-1-antitrypsin Z variant via SQSTM1/p62-dependent selective autophagy

SERPINA1/AAT/α-1-antitrypsin (serpin family A member 1) deficiency (SERPINA1/ AAT-D) is an autosomal recessive disorder characterized by the retention of misfolded SERPINA1/AAT in the endoplasmic reticulum (ER) of hepatocytes and a significant reduction of serum SERPINA1/AAT level. The Z variant of SERPINA1/AAT, containing a Glu342Lys (E342K) mutation (SERPINA1^E342K/ATZ), the most common form of SERPINA1/AAT-D, is prone to misfolding and polymerization, which retains it in the ER of hepatocytes and leads to liver injury. Both proteasome and macroautophagy/autophagy pathways are responsible for disposal of SERPINA1^E342K/ATZ after it accumulates in the ER. However, the mechanisms by which SERPINA1^E342K/ATZ is selectively degraded by autophagy remain unknown. Here, we showed that ER membrane-spanning ubiquitin ligase (E3) SYVN1/HRD1 enhances the degradation of SERPINA1^E342K/ATZ through the autophagy-lysosome pathway. We found that SYVN1 promoted SERPINA1^E342K/ATZ, especially Triton X 100-insoluble SERPINA1^E342K/ATZ clearance. However, the effect of SYVN1 in SERPINA1^E342K/ATZ clearance was impaired after autophagy inhibition, as well as in autophagy-related 5 (atg5) knockout cells. On the contrary, autophagy induction enhanced SYVN1-mediated SERPINA1^E342K/ATZ degradation. Further study showed that SYVN1 mediated SERPINA1^E342K/ATZ ubiquitination, which is required for autophagic degradation of SERPINA1^E342K/ATZ by promoting the interaction between SERPINA1^E342K/ATZ and SQSTM1/p62 for formation of the autophagy complex. Interestingly, SYVN1-mediated lysine 48 (K48)-linked polyubiquitin chains that conjugated onto SERPINA1^E342K/ATZ might predominantly bind to the ubiquitin-associated (UBA) domain of SQSTM1 and couple the ubiquitinated SERPINA1^E342K/ATZ to the lysosome for degradation. In addition, autophagy inhibition attenuated the suppressive effect of SYVN1 on SERPINA1^E342K/ATZ cytotoxicity, and the autophagy inducer rapamycin enhanced the suppressive effect of SYVN1 on SERPINA1^E342K/ATZ-induced cell apoptosis. Therefore, this study proved that SYVN1 enhances SERPINA1^E342K/ATZ degradation through SQSTM1-dependent autophagy and attenuates SERPINA1^E342K/ATZ cytotoxicity.     

Activation of endoplasmic reticulum-specific stress responses associated with the conformational disease Z alpha 1-antitrypsin deficiency

Conformational diseases are a class of disorders associated with aberrant protein accumulation in tissues and cellular compartments. Z alpha1-antitrypsin (A1AT) deficiency is a genetic disease associated with accumulation of misfolded A1AT in the endoplasmic reticulum (ER) of hepatocytes. We sought to identify intracellular events involved in the molecular pathogenesis of Z A1AT-induced liver disease using an in vitro model system of Z A1AT ER accumulation. We investigated ER stress signals induced by Z A1AT and demonstrated that both the ER overload response and the unfolded protein response were activated by mutant Z A1AT, but not wild-type M A1AT. Interestingly, activation of the unfolded protein response pathway required an additional insult, whereas NF-kappa B activation, a hallmark of the ER overload response, was constitutive. These findings have important implications for the design of future therapeutics for Z A1AT liver disease and may also impact on drug design for other conformational diseases.     

Autophagy: an ER protein quality control process

Protein quality control processes active in the endoplasmic reticulum (ER), including ER-associated protein degradation (ERAD) and the unfolded protein response (UPR), prevent the cytotoxic effects that can result from the accumulation of misfolded proteins. Characterization of a yeast mutant deficient in ERAD, a proteasome-dependent degradation pathway, revealed the employment of two overflow pathways from the ER to the vacuole when ERAD was compromised. One removes the soluble misfolded protein via the biosynthetic pathway and the second clears aggregated proteins via autophagy. Previously, autophagy had been implicated in the clearance of cytoplasmic aggresomes, but was not known to play a direct role in ER protein quality control. These findings provide insight into the molecular mechanisms that result in the gain-of-function liver disease associated with both alpha1-deficiency and hypofibrinogenemia (abnormally low levels of plasma fibrinogen, which is required for blood clotting), and emphasize the need for a more complete understanding of the molecular mechanisms of autophagy and its relationship to protein quality control.     

Ubiquitin ligase gp78 increases solubility and facilitates degradation of the Z variant of alpha-1-antitrypsin

Deficiency of circulating alpha-1-antitrypsin (AAT) is the most widely recognized abnormality of a proteinase inhibitor that causes lung disease. AAT-deficiency is caused by mutations of the AAT gene that lead to AAT protein retention in the endoplasmic reticulum (ER). Moreover, the mutant AAT accumulated in the ER predisposes the homozygote to severe liver injuries, such as neonatal hepatitis, juvenile cirrhosis, and hepatocellular carcinoma. Despite the fact that mutant AAT protein is subject to ER-associated degradation (ERAD), yeast genetic studies have determined that the ubiquitination machinery, Hrd1/Der3p-cue1p-Ubc7/6p, which plays a prominent role in ERAD, is not involved in degradation of mutant AAT. Here we report that gp78, a ubiquitin ligase (E3) pairing with mammalian Ubc7 for ERAD, ubiquitinates and facilitates degradation of ATZ, the classic deficiency variant of AAT having a Z mutation (Glu 342 Lys). Unexpectedly, gp78 over-expression also significantly increases ATZ solubility. p97/VCP, an AAA ATPase essential for retrotranslocation of misfolded proteins from the ER during ERAD, is involved in gp78-mediated degradation of ATZ. Surprisingly, unlike other ERAD substrates that cause ER stress leading to apoptosis when accumulated in the ER, ATZ, in fact, increases cell proliferation when over-expressed in cells. This effect can be partially inhibited by gp78 over-expression. These data indicate that gp78 assumes multiple unique quality control roles over ATZ, including the facilitation of degradation and inhibition of aggregation of ATZ.     

Regulation of ER stress-induced macroautophagy by protein kinase C

The endoplasmic reticulum (ER) is the primary site for folding and quality control for proteins destined to the cell surface and intracellular organelles. A variety of cellular insults alter ER homeostasis to disrupt protein folding, cause the accumulation of misfolded protein and activate an autophagic response. However, the molecular signaling pathways required for ER stress-induced autophagy are largely unknown. Recently, we discovered that a novel-type protein kinase C family member (PKCθ) is required for ER stress-induced autophagy. We shown that ER stress, in a Ca²⁺-dependent manner, induces PKCθ phosphorylation within the activation loop and localization with LC3-II in punctate cytoplasmic structures. Pharmacological inhibition, siRNA-mediated knockdown, or transdominant-negative mutant expression of PKCθ block the ER stress-induced autophagic response. PKCθ activation is not required for autophagy induced by amino acid starvation, and PKCθ activation in response to ER stress does not require either the mTOR kinase or the unfolded protein response signaling pathways. Herein, we review and discuss the significance of these findings with respect to regulation of autophagy in response to ER stress.

Addendum to: Sakaki K, Wu J, Kaufman RJ. Protein kinase C-θ is required for autophagy in response to stress in the endoplasmic reticulum. J Biol Chem 2008; 283:15370-80.     

Autophagy delivers misfolded secretory proteins accumulated in endoplasmic reticulum to vacuoles in the filamentous fungus Aspergillus oryzae

Autophagy is a conserved intracellular degradation process of eukaryotic cells. In filamentous fungi, although autophagy has been reported to have multiple physiological roles, it is not clear whether autophagy is involved in the degradation of misfolded proteins. Here, we investigated the role of autophagy in the degradation of misfolded secretory proteins accumulated in endoplasmic reticulum (ER) in the filamentous fungus Aspergillus oryzae. In late-phase cultures, a disulfide bond-deleted mutant of the secretory protein α-amylase AmyB fused with mDsRed that had accumulated in the ER was subsequently delivered to vacuoles, whereas wild-type AmyB-mDsRed was predominantly located at cell walls and septa. To examine the involvement of autophagy in the delivery of mutant AmyB to vacuoles, mutant AmyB-EGFP was expressed in an A. oryzae autophagy-deficient strain (ΔAoatg8). Microscopic examination revealed that the protein delivery to vacuoles did not occur in the absence of autophagic activity, with mutant AmyB-mDsRed forming large spherical structures surrounded by ER membrane. Hence, we conclude that autophagy is responsible for the delivery of misfolded secretory proteins accumulated in the ER to vacuoles for degradation during late-growth phase in A. oryzae. This is the first study to provide evidence that autophagy plays a role in the degradation of misfolded secretory proteins in filamentous fungi.     

Glucosidase and mannosidase inhibitors mediate increased secretion of mutant alpha1 antitrypsin Z

It is now well known that the addition and trimming of oligosaccharide side chains during post-translational modification play an important role in determining the fate of secretory, membrane, and lysosomal glycoproteins. Recent studies have suggested that trimming of oligosaccharide side chains also plays a role in the degradation of misfolded glycoproteins as a part of the quality control mechanism of the endoplasmic reticulum (ER). In this study, we examined the effect of several inhibitors of carbohydrate processing on the fate of the misfolded secretory protein alpha1 antitrypsin Z. Retention of this misfolded glycoprotein in the ER of liver cells in the classical form of alpha1 antitrypsin (alpha1-AT) deficiency is associated with severe liver injury and hepatocellular carcinoma and lack of its secretion is associated with destructive lung disease/emphysema. The results show marked alterations in the fate of alpha1 antitrypsin Z (alpha1-ATZ). Indeed, one glucosidase inhibitor, castanospermine (CST), and two mannosidase inhibitors, kifunensine (KIF) and deoxymannojirimycin (DMJ), mediate marked increases in secretion of alpha1-ATZ by distinct mechanisms. The effects of these inhibitors on secretion have interesting implications for our understanding of the quality control apparatus of the ER. These inhibitors may also constitute models for development of additional drugs for chemoprophylaxis of liver injury and emphysema in patients with alpha1-AT deficiency.     

Sorting, recognition and activation of the misfolded protein degradation pathways through macroautophagy and the proteasome

Based on a functional categorization, proteins may be grouped into three types and sorted to either the proteasome or the macroautophagy pathway for degradation. The two pathways are mechanistically connected but their capacity seems different. Macroautophagy can degrade all forms of misfolded proteins whereas proteasomal degradation is likely limited to soluble ones. Unlike the bulk protein degradation that occurs during starvation, autophagic degradation of misfolded proteins can have a degree of specificity, determined by ubiquitin modification and the interactions of p62/SQSTM1 and HDAC6. Macroautophagy is initiated in response to endoplasmic reticulum (ER) stress caused by misfolded proteins, via the ER-activated autophagy (ERAA) pathway, which activates a partial unfolded protein response involving PERK and/or IRE1, and a calcium-mediated signaling cascade. ERAA serves the function of mitigating ER stress and suppressing cell death, which may be explored for controlling protein conformational diseases. Conversely, inhibition of ERAA may be explored for sensitizing resistant tumor cells to cytotoxic agents.     

Autophagic Elimination of Misfolded Procollagen Aggregates in the Endoplasmic Reticulum as a Means of Cell Protection

Type I collagen is a major component of the extracellular matrix, and mutations in the collagen gene cause several matrix-associated diseases. These mutant procollagens are misfolded and often aggregated in the endoplasmic reticulum (ER). Although the misfolded procollagens are potentially toxic to the cell, little is known about how they are eliminated from the ER. Here, we show that procollagen that can initially trimerize but then aggregates in the ER are eliminated by an autophagy-lysosome pathway, but not by the ER-associated degradation (ERAD) pathway. Inhibition of autophagy by specific inhibitors or RNAi-mediated knockdown of an autophagy-related gene significantly stimulated accumulation of aggregated procollagen trimers in the ER, and activation of autophagy with rapamycin resulted in reduced amount of aggregates. In contrast, a mutant procollagen which has a compromised ability to form trimers was degraded by ERAD. Moreover, we found that autophagy plays an essential role in protecting cells against the toxicity of the ERAD-inefficient procollagen aggregates. The autophagic elimination of aggregated procollagen occurs independently of the ERAD system. These results indicate that autophagy is a final cell protection strategy deployed against ER-accumulated cytotoxic aggregates that are not able to be removed by ERAD.     

Autophagic disposal of the aggregation-prone protein that causes liver inflammation and carcinogenesis in alpha-1-antitrypsin deficiency

Alpha-1-antitrypsin (AT) deficiency is a relatively common autosomal co-dominant disorder, which causes chronic lung and liver disease. A point mutation renders aggregation-prone properties on a hepatic secretory protein in such a way that the mutant protein is retained in the endoplasmic reticulum of hepatocytes rather than secreted into the blood and body fluids where it ordinarily functions as an inhibitor of neutrophil proteases. A loss-of-function mechanism allows neutrophil proteases to degrade the connective tissue matrix of the lung causing chronic emphysema. Accumulation of aggregated mutant AT in the endoplasmic reticulum of hepatocytes causes liver inflammation and carcinogenesis by a gain-of-toxic function mechanism. However, genetic epidemiology studies indicate that many, if not the majority of, affected homozygotes are protected from liver disease by unlinked genetic and/or environmental modifiers. Studies performed over the last several years have demonstrated the importance of autophagy in disposal of mutant, aggregated AT and raise the possibility that predisposition to, or protection from, liver injury and carcinogenesis is determined by the balance of de novo biogenesis of the mutant AT molecule and its autophagic disposal.     

The autophagic response to nutrient deprivation in the hl-1 cardiac myocyte is modulated by Bcl-2 and sarco/endoplasmic reticulum calcium stores

Macroautophagy is a vital process in the cardiac myocyte: it plays a protective role in the response to ischemic injury, and chronic perturbation is causative in heart disease. Recent findings evidence a link between the apoptotic and autophagic pathways through the interaction of the antiapoptotic proteins Bcl-2 and Bcl-XL with Beclin 1. However, the nature of the interaction, either in promoting or blocking autophagy, remains unclear. Here, using a highly sensitive, macroautophagy-specific flux assay allowing for the distinction between enhanced autophagosome production and suppressed autophagosome degradation, we investigated the control of Beclin 1 and Bcl-2 on nutrient deprivation-activated macroautophagy. We found that in HL-1 cardiac myocytes the relationship between Beclin 1 and Bcl-2 is subtle: Beclin 1 mutant lacking the Bcl-2-binding domain significantly reduced autophagic activity, indicating that Beclin 1-mediated autophagy required an interaction with Bcl-2. Overexpression of Bcl-2 had no effect on the autophagic response to nutrient deprivation; however, targeting Bcl-2 to the sarco/endoplasmic reticulum (S/ER) significantly suppressed autophagy. The suppressive effect of S/ER-targeted Bcl-2 was in part due to the depletion of S/ER calcium stores. Intracellular scavenging of calcium by BAPTA-AM significantly blocked autophagy, and thapsigargin, an inhibitor of sarco/endoplasmic reticulum calcium ATPase, reduced autophagic activity by approximately 50%. In cells expressing Bcl-2-ER, thapsigargin maximally reduced autophagic flux. Thus, our results demonstrate that Bcl-2 negatively regulated the autophagic response at the level of S/ER calcium content rather than via direct interaction with Beclin 1. Moreover, we identify calcium homeostasis as an essential component of the autophagic response to nutrient deprivation.     

Endoplasmic reticulum stress triggers autophagy

Eukaryotic cells have evolved strategies to respond to stress conditions. For example, autophagy in yeast is primarily a response to the stress of nutrient limitation. Autophagy is a catabolic process for the degradation and recycling of cytosolic, long lived, or aggregated proteins and excess or defective organelles. In this study, we demonstrate a new pathway for the induction of autophagy. In the endoplasmic reticulum (ER), accumulation of misfolded proteins causes stress and activates the unfolded protein response to induce the expression of chaperones and proteins involved in the recovery process. ER stress stimulated the assembly of the pre-autophagosomal structure. In addition, autophagosome formation and transport to the vacuole were stimulated in an Atg protein-dependent manner. Finally, Atg1 kinase activity reflects both the nutritional status and autophagic state of the cell; starvation-induced autophagy results in increased Atg1 kinase activity. We found that Atg1 had high kinase activity during ER stress-induced autophagy. Together, these results indicate that ER stress can induce an autophagic response.