Project description:Lysosomal-autophagic degradation of Endoplasmic Reticulum via autophagy (ER-phagy) is emerging as critical regulator of ER homeostasis and function. However, the molecular mechanisms governing ER-phagy are still unknown. Working in chondrocytes, we found that ER-phagy and lysosome biogenesis are co-activated by FGF signaling during hypertrophic differentiation, a mandatory step for bone formation. FGF induced ER-phagy trough IRS1-dependent inhibition of the insulin signaling and activation of MiT/TFE transcription factors, master regulators of lysosome biogenesis. MiT/TFE promoted ER-phagy through the induction of the ER-phagy receptor FAM134B. Notably, the activation of ER-phagy promotes chondrocytes differentiation and secretion of factors required for cartilage replacement by bone. Consistently, medaka fish knock-down for FAM134B have impaired ossification of cranial bones. Thus, ER-phagy is a transcriptionally regulated process that participates to cell differentiation during development.

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.

Project description:The mannose-6-phosphate (M6P) pathway is critical for lysosome biogenesis, facilitating the trafficking of hydrolases to lysosomes to ensure cellular degradative capacity [1], [2]. Fibroblast Growth Factor (FGF) signaling, a key regulator of skeletogenesis [3], has been linked to the autophagy-lysosomal pathway in chondrocytes [4], [5], [6], but its role in lysosome biogenesis remains poorly characterized. Here, using mass spectrometry, lysosome immune-purification, and functional assays, we reveal that chondrocytes lacking FGF receptors 3 and 4 exhibit dysregulations of the M6P pathway, resulting in hypersecretion of lysosomal enzymes and impaired lysosomal function. We found that FGF receptors control the expression of M6P receptors genes in response to FGF stimulation and during cell cycle via TFEB/TFE3 activation. Notably, restoring MPRs function—either through gene expression or activation of TFEB—rescues lysosomal defects in FGFR3;4-deficient chondrocytes. These findings uncover a novel mechanism by which FGF signaling regulates lysosomal function, offering insights into the control of chondrocyte catabolism and the understanding of FGF-related human diseases.

Project description:The mannose-6-phosphate (M6P) pathway is critical for lysosome biogenesis, facilitating the trafficking of hydrolases to lysosomes to ensure cellular degradative capacity [1], [2]. Fibroblast Growth Factor (FGF) signaling, a key regulator of skeletogenesis [3], has been linked to the autophagy-lysosomal pathway in chondrocytes [4], [5], [6], but its role in lysosome biogenesis remains poorly characterized. Here, using mass spectrometry, lysosome immune-purification, and functional assays, we reveal that chondrocytes lacking FGF receptors 3 and 4 exhibit dysregulations of the M6P pathway, resulting in hypersecretion of lysosomal enzymes and impaired lysosomal function. We found that FGF receptors control the expression of M6P receptors genes in response to FGF stimulation and during cell cycle via TFEB/TFE3 activation. Notably, restoring MPRs function—either through gene expression or activation of TFEB—rescues lysosomal defects in FGFR3;4-deficient chondrocytes. These findings uncover a novel mechanism by which FGF signaling regulates lysosomal function, offering insights into the control of chondrocyte catabolism and the understanding of FGF-related human diseases.

Project description:The mannose-6-phosphate (M6P) pathway is critical for lysosome biogenesis, facilitating the trafficking of hydrolases to lysosomes to ensure cellular degradative capacity [1], [2]. Fibroblast Growth Factor (FGF) signaling, a key regulator of skeletogenesis [3], has been linked to the autophagy-lysosomal pathway in chondrocytes [4], [5], [6], but its role in lysosome biogenesis remains poorly characterized. Here, using mass spectrometry, lysosome immune-purification, and functional assays, we reveal that chondrocytes lacking FGF receptors 3 and 4 exhibit dysregulations of the M6P pathway, resulting in hypersecretion of lysosomal enzymes and impaired lysosomal function. We found that FGF receptors control the expression of M6P receptors genes in response to FGF stimulation and during cell cycle via TFEB/TFE3 activation. Notably, restoring MPRs function—either through gene expression or activation of TFEB—rescues lysosomal defects in FGFR3;4-deficient chondrocytes. These findings uncover a novel mechanism by which FGF signaling regulates lysosomal function, offering insights into the control of chondrocyte catabolism and the understanding of FGF-related human diseases.

Project description:Degradation of the endoplasmic reticulum (ER) by selective autophagy (ER-phagy) is vital for cellular homeostasis. Here, we introduce FAM134A/RETREG2 and FAM134C/RETREG3 as new ER-phagy receptors. FAM134A and FAM134C exist in a relatively inactive state under basal conditions and require an activation signal to induce significant ER fragmentation. Molecular modeling and simulations implicate a single compact fold of FAM134A’s reticulon homology domain (RHD). In contrast, the RHDs of FAM134B and FAM134C are able to adopt at least three discrete conformations. These differences result in slower vesicle formation for FAM134A compared to FAM134C and mostly FAM134B. Global proteomic analyses of knockout MEFs indicate both distinct and overlapping roles for the Fam134s, with Fam134a being most distant from Fam134b and Fam134c. Fam134c appears to enhance and facilitate Fam134b’s role in maintaining pro-collagen-I levels and is therefore insufficient to compensate for its loss. By contrast, Fam134a has a particular mode of action in maintaining pro-collagen-I levels and is able to fully compensate loss of Fam134b or Fam134c upon over-expression in its wild-type or LIR mutant form.

Project description:Birt-Hogg-Dubè (BHD) syndrome is an inherited condition caused by loss-of-function mutations in the gene encoding the tumor-suppressor protein folliculin (FLCN) and frequently associated with kidney cysts and cancer. FLCN acts as a negative regulator of TFEB and TFE3 transcription factors, master controllers of lysosomal biogenesis and autophagy, by enabling their phosphorylation by the mechanistic Target Of Rapamycin Complex 1 (mTORC1). We previously showed that deletion of TFEB rescued the renal cystic phenotype of kidney-specific Flcn KO mice. Using Flcn/TFEB/TFE3 double and triple KO mice we now show that both TFEB and TFE3 contribute, in a differential and cooperative manner, to kidney cystogenesis. Importantly, silencing of either TFEB or TFE3 rescued tumorigenesis in patient-derived xenografts (PDXs) generated from a kidney tumor of a BHD patient. Furthermore, transcriptome analyses performed in transgenic mice, PDXs and patient tumor samples revealed TFEB/TFE3 downstream targets that may contribute to their tumorigenic activity. Our findings demonstrate in disease-relevant models that TFEB and TFE3 are key drivers of kidney tumorigenesis and suggest novel therapeutic strategies based on the inhibition of these transcription factors.

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: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:Selective autophagy of the endoplasmic reticulum (ER), known as ER-phagy, is an important regulator of ER remodeling and is critical to maintaining cellular homeostasis during environmental changes. We recently showed that members of the FAM134 family play a role during stress-induced ER-phagy. However, the mechanisms on how they are activated remain largely unknown. In this study, we analyzed mTOR-mediated phosphorylation of FAM134 as a trigger of FAM134-driven ER-phagy. An unbiased screen of kinase inhibitors revealed that CK2 is essential for ER-phagy driven by FAM134B and FAM134C after inhibition of mTOR. Using superresolution microscopy, we showed that CK2 activity is essential for the formation of high-density groups of FAM134B and FAM134C. Continually, the FAM134B and FAM134C proteins that carry point mutations of selected serine residues within their reticulon homology domain are unable to form high-density clusters. Furthermore, we provide evidence that ubiquitination regulates ER-phagy receptors and that dense clustering of FAM134B and FAM134C requires events upstream of ubiquitination. Treatment with the CK2 inhibitor SGC-CK2-1 or mutation of phosphosites prevents Torin1-induced ER-phagy flux as well as ubiquitination of FAM134 proteins, and consistently treatment with E1 inhibitor suppresses Torin1-induced ER-phagy flux. Therefore, we propose that CK2 dependent phosphorylation of ER-phagy receptors precedes ubiquitin-dependent activation of ER-phagy flux.