Project description:ER-phagy, a selective degradation of endoplasmic reticulum (ER) fragment, plays a critical role in maintaining the ER homeostasis. Dysregulation of ER-phagy is involved in the unfolded protein response (UPR), which serves as a vital clue to evoke inflammatory disease. However, the molecular mechanism underpinning the connection between ER-phagy and disease remains poorly defined. Here, we identified ubiquitin-associated domain-containing protein 2 (UBAC2) as an ER-phagy receptor, but a negative regulator of inflammatory responses. UBAC2 harbors a canonical LC3-interacting region (LIR) in the cytoplasmic domain that bind to autophagosomal GABARAP. Upon ER-stress or autophagy activation condition, microtubule affinity-regulating kinase 2 (MARK2) catalyzes the phosphorylation of UBAC2 at serine (S) 223 to promote its dimerization. Dimerized UBAC2 exhibits a stronger ability to interact with GABARAP for selective degradation of ER. Moreover, UBAC2 restrains inflammatory responses and acute ulcerative colitis (UC) in mice through affecting the ER-phagy. Our findings reveal ER-phagy directed by MARK2-UBAC2 axis can provide therapy target for inflammatory disease.

Project description:ER-phagy, a selective degradation of endoplasmic reticulum (ER) fragment, plays a critical role in maintaining the ER homeostasis. Dysregulation of ER-phagy is involved in the unfolded protein response (UPR), which serves as a vital clue to evoke inflammatory disease. However, the molecular mechanism underpinning the connection between ER-phagy and disease remains poorly defined. Here, we identified ubiquitin-associated domain-containing protein 2 (UBAC2) as an ER-phagy receptor, but a negative regulator of inflammatory responses. UBAC2 harbors a canonical LC3-interacting region (LIR) in the cytoplasmic domain that bind to autophagosomal GABARAP. Upon ER-stress or autophagy activation condition, microtubule affinity-regulating kinase 2 (MARK2) catalyzes the phosphorylation of UBAC2 at serine (S) 223 to promote its dimerization. Dimerized UBAC2 exhibits a stronger ability to interact with GABARAP for selective degradation of ER. Moreover, UBAC2 restrains inflammatory responses and acute ulcerative colitis (UC) in mice through affecting the ER-phagy. Our findings reveal ER-phagy directed by MARK2-UBAC2 axis can provide therapy target for inflammatory disease.

Project description:Autophagy is a conserved degradative process that promotes cellular homeostasis under stress conditions. Under nutrient starvation autophagy is largely non-selective, promoting indiscriminate breakdown of cytosolic components. Conversely, selective autophagy is responsible for the specific turnover of damaged organelles. We hypothesized that selective autophagy may be regulated by distinct upstream signaling from starvation induced autophagy to promote organelle turn-over. To address this question, we conducted kinome-wide CRISPR screens using the DsRed-IRES-GFP-p62 reporter line to identify distinct signaling pathways responsible for the regulation of basal autophagy, starvation-induced autophagy, and two types of selective autophagy, ER-phagy and pexophagy. The Brunello kinome library was designed to enhance on-target activity while minimizing off-target effects, ensuring the effectiveness and efficiency of our screens. These parallel screens identified established and novel autophagy shared regulators under these conditions, as well as kinases specifically required for ER-phagy or pexophagy. More specifically, CDK11A and NME3 were further characterized to be selective ER-phagy regulators. Meanwhile, PAN3 and CDC42BPG were identified as activator or inhibitor of pexophagy, respectively. Collectively, these datasets provide the first comparative description of the kinase signaling specificity, separating regulation of selective autophagy and bulk autophagy.

Project description:Organelle fragmentation is crucial for the onset of autophagic programs that control lysosomal clearance of portions of organelles to be removed from cells. It is driven by membrane-bound organello-phagy receptors that display cytoplasmic intrinsically disordered modules (IDRs) containing short LC3-interacting regions (LIRs). Studies on ER-phagy receptors of the FAM134 family revealed the importance of transcriptional induction, and receptors phosphorylation, ubiquitylation and clustering for execution of the ER-phagy programs. In this model, ER fragmentation is promoted by the membrane-remodeling function of FAM134 reticulon homology domains (RHDs)18,19. However, RHDs are not conserved in ER-phagy receptors, nor in receptors for autophagy of other organelles that also require fragmentation such as the mitochondria. Thus, membrane remodeling by RHDs is unlikely to be a conserved mechanism to regulate organelle turnover. Here, we show that the membrane-tethering modules of ER-phagy receptors (RHDs for FAM134B, single/multi spanning transmembrane domains for TEX264 and SEC62) determine the sub-compartmental distribution of the receptors but are dispensable for ER fragmentation, regardless of their propensity to remodel the ER membrane. Our experiments reveal that the information encoding for ER fragmentation is contained in the cytoplasmic IDR modules of the ER-phagy receptors, which also control delivery of the ER fragments within degradative acidic compartments upon engagements of lipidated LC3/GABARAP proteins via their LIRs. Notably, the transplantation of ER-phagy receptors IDRs at the mitochondrial membrane induces DRP1-driven mitochondrial fragmentation and mitophagy, and the transplantation of mitophagy receptors IDRs at the ER membrane induces ER fragmentation and ER-phagy. Our work reveals the functional conservation of membrane-exposed IDRs in promoting organelle fragmentation and offers a method to control integrity and activity of intracellular organelles by surface activation of IDR modules with net negative charges.

Project description:ER degradation by selective autophagy (ER-phagy) is crucial for ER homeostasis. However, it remains unclear how ER scission is regulated for subsequent autophagosomal sequestration and lysosomal degradation. Here, we show that oligomer formation of FAM134B (also referred to as reticulophagy regulator 1 or RETREG1) through its Reticulon domain was required for membrane fragmentation in vitro and ER-phagy in vivo. Under ER stress conditions, activated CAMK2B phosphorylated the Reticulon domain of FAM134B, which enhanced FAM134B oligomerization and activity in membrane fragmentation to accommodate high demand of ER-phagy. Unexpectedly, FAM134BG216R, a variant derived from a type II HSAN patient, exhibited gain-of-function defects, such as hyperactive self-association and membrane scission, which resulted in excessive ER-phagy and sensory neuron death. Therefore, this study revealed a mechanism of ER membrane fragmentation in ER-phagy, along with a signaling pathway in regulating ER turnover, and suggested a potential implication of excessive selective autophagy in human diseases.

Project description:Pancreatic acinar cells are surprisingly resistant to pre-malignant transformation by the mutant Kras oncogene. Here, reporter mice show that an early, transcriptionally-mediated effect of Kras activation is downregulation of ER-phagy. Subsequently, stochastic failure of ER-phagy correlates with pre-malignant transdifferentiation into acinar-ductal metaplasia (ADM). Genetic perturbation of ER-phagy, combined with proteomics and transcriptomics, reveals endogenous injury, micro-inflammation and ADM across the acinar epithelium. Phenotypically, this occurs alongside intra-acinar formation of distinctive insoluble aggregates of ER proteins, including the injury marker REG3B. Mechanistically, REG3B is shown to bind to the ER-phagy receptor CCPG1 to facilitate degradation. Strikingly, spatial transcriptomics shows that oncogenic Kras also drives this cell state in a highly stochastic fashion, again characterised by protein aggregation, partial ductal identity, evidence of injury and propensity for ADM. Importantly, expression of insoluble mutant REG3B shows that protein aggregate formation directly engenders this state. Pancreatic cancer can thus arise from stochastic proteostatic defects that are both made probable by, and co-operate with, oncogenic Kras.

Project description:Pancreatic acinar cells are surprisingly resistant to pre-malignant transformation by the mutant Kras oncogene. Here, reporter mice show that an early, transcriptionally-mediated effect of Kras activation is downregulation of ER-phagy. Subsequently, stochastic failure of ER-phagy correlates with pre-malignant transdifferentiation into acinar-ductal metaplasia (ADM). Genetic perturbation of ER-phagy, combined with proteomics and transcriptomics, reveals endogenous injury, micro-inflammation and ADM across the acinar epithelium. Phenotypically, this occurs alongside intra-acinar formation of distinctive insoluble aggregates of ER proteins, including the injury marker REG3B. Mechanistically, REG3B is shown to bind to the ER-phagy receptor CCPG1 to facilitate degradation. Strikingly, spatial transcriptomics shows that oncogenic Kras also drives this cell state in a highly stochastic fashion, again characterised by protein aggregation, partial ductal identity, evidence of injury and propensity for ADM. Importantly, expression of insoluble mutant REG3B shows that protein aggregate formation directly engenders this state. Pancreatic cancer can thus arise from stochastic proteostatic defects that are both made probable by, and co-operate with, oncogenic Kras.

Project description:The degradation of endoplasmic reticulum (ER) via selective autophagy is driven by the ER-phagy receptors that facilitate the incorporation of ER-fragments into nascent autophagosomes. How these receptors are regulated, in response to ER-phagy-inducing stimuluses, is largely unknown. Here we propose that starvation, as well as mTOR inhibition, triggers ER-phagy primarily through the activation of the ER-phagy receptor FAM134C. In physiological, nutrient reach, conditions FAM134C is phosphorylated by the Casein kinase 2 (CK2) protein at specific residues negatively affecting FAM134C interaction with the LC3 proteins, thereby preventing ER-phagy. Pharmacological or starvation-induced mTORC1 inhibition limits phosphorylation of FAM134C by CK2, hence promoting FAM134C activation and ER-phagy. Moreover, inhibition of CK2 or the expression of a phospho-mutant FAM134C protein is sufficient to stimulate ER-phagy. Conversely, starvation induced ER-phagy is inhibited in cells and mice that lack FAM134C or expressing a phospho-mimetic FAM134C protein. Overall, these data describe a new mechanism regulating ER-phagy and provides an example of cargo selectivity mechanism during starvation induced autophagy.

Project description:Macroautophagy/autophagy is a key catabolic-recycling pathway that can selectively target damaged organelles or invading pathogens for degradation. The selective autophagic degradation of the endoplasmic reticulum (hereafter referred to as ER-phagy) is a homeostatic mechanism, controlling ER size, the removal of misfolded protein aggregates, and organelle damage. ER-phagy can also be stimulated by pathogen infection. However, the link between ER-phagy and bacterial infection remains poorly understood, as are the mechanisms evolved by pathogens to escape the effects of ER-phagy. Here, we show that Salmonella enterica serovar Typhimurium inhibits ER-phagy by targeting the ER-phagy receptor FAM134B, leading to a pronounced increase in Salmonella burden after invasion. Salmonella prevents FAM134B oligomerization, which is required for efficient ER-phagy. FAM134B knock-out raises intracellular Salmonella number, while FAM134B activation reduces Salmonella burden. Additionally, we found that Salmonella targets FAM134B through the bacterial effector SopF to enhance intracellular survival through ER-phagy inhibition. Furthermore, FAM134B knock-out mice infected with Salmonella presented severe intestinal damage and increased bacterial burden. These results provide mechanistic insight into the interplay between ER-phagy and bacterial infection, highlighting a key role for FAM134B in innate immunity.

Project description:Lysosomal degradation of the endoplasmic reticulum (ER) via autophagy (ER-phagy) is emerging as a critical regulator of ER homeostasis and function1. The selective incorporation of ER fragments into nascent autophagosomes is facilitated by ER resident proteins, ER-phagy receptors, that bind the autophagosomal LC3 protein via the cytosolic LC3 interacting domain (LIR) (REF). However, the molecular mechanisms that regulate ER-phagy in response to cellular needs are still largely unknown. We found that the MiT/TFE transcription factors - master regulators of lysosomal biogenesis and autophagy2- control ER-phagy by inducing the expression of the ER-phagy receptor FAM134B. This pathway is robustly activated in chondrocytes by FGF signaling, a critical regulator of chondrocyte differentiation3. FGF triggers TFEB/TFE3-mediated ER-phagy through JNK-dependent proteasomal degradation of the insulin receptor substrate 1 (IRS-1) protein and inhibition of the insulin signaling. FAM134B knock-down impairs cartilage growth and mineralization in medaka fish, suggesting a physiological role for this process during skeletal growth. Notably, we showed that the TFEB/TFE3-FAM134B axis promotes ER-phagy activation upon prolonged starvation. Thus, this study identifies MiT/TFE-factors as key transcriptional activators of ER-phagy in response to both metabolic and developmental cues.