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:Lysosomal degradation of the endoplasmic reticulum (ER) via autophagy (ER-phagy) is emerging as a critical regulator of cell homeostasis and function1. The recent identification of ER-phagy receptors has shed light on the molecular mechanism underlining this process; however, the signaling pathways regulating ER-phagy in response to cellular needs are still largely unknown. We found that the nutrient responsive transcription factors TFEB and TFE3 - master regulators of lysosomal biogenesis and autophagy2- control ER-phagy by inducing the expression of the ER-phagy receptor FAM134B. The TFEB/TFE3-FAM134B axis promotes ER-phagy activation upon prolonged starvation. In addition, we discovered that this pathway is activated in chondrocytes by FGF signaling, a critical regulator of cell differentiation 3. FGF signaling induces a JNK-dependent proteasomal degradation of the insulin receptor substrate 1, which inhibits the insulin-PI3K-PKB/Akt-mTORC1 pathway and promotes TFEB/TFE3 nuclear translocation and FAM134B induction. Consistent with a role of the TFEB/TFE3-FAM134B axis in chondrocytes, FAM134B knock-down impairs cartilage growth and mineralization in medaka fish. This study identifies a new signaling pathway that allows ER-phagy to respond to both metabolic and developmental cues.

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: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 cathepsins regulate an exquisite range of biological functions, and their deregulation is associated with inflammatory, metabolic and degenerative disease in humans. Here, we identified a key cell-intrinsic role for cathepsin B as a negative feedback regulator of lysosomal biogenesis and autophagy. Mice and macrophages lacking cathepsin B activity had increased resistance to the cytosolic bacterial pathogen Francisella novicida. Genetic deletion or pharmacological inhibition of cathepsin B downregulated mTOR activity and prevented cleavage of the lysosomal calcium channel TRPML1. These events drove transcription of lysosomal and autophagy genes via the transcription factor TFEB, which increased lysosomal biogenesis and activation of autophagy-initiation kinase ULK1 for clearance of the bacteria. Our results identified a fundamental biological function of cathepsin B in providing a checkpoint for homeostatic maintenance of lysosome population and basic recycling functions in the cell. We used microarrays to explore the gene expression profiles differentially expressed in bone marrow-derived macrophages (BMDM) isolated from cathepsin B-/- and wild-type mice.

Project description:Mycobacterium tuberculosis (Mtb) infects multiple lung myeloid cell subsets and persists despite innate and adaptive immune responses. However, the mechanisms allowing Mtb to evade elimination by these subsets are not fully understood. Here, we determined that four weeks post infection, after development of adaptive immune responses, CD11clo monocyte-derived lung cells termed MNC1 (mononuclear cell subset 1), harbor more live Mtb compared to alveolar macrophages (AM), neutrophils, and less permissive CD11chi MNC2. Bulk RNA-seq analysis for these subsets identified that lysosome biogenesis pathway is underexpressed in MNC1. Functional assays confirmed that Mtb-permissive MNC1 are deficient in lysosome content, lysosomal acidification, and lysosomal activity compared to AM, and have less nuclear TFEB, a master regulator of lysosome biogenesis. Mtb infection does not alter lysosome deficiency in MNC1. Instead, Mtb recruits MNC1 and MNC2 to the lungs for its spread from AM to these subsets, which depend on Mtb ESX-1 secretion system. Furthermore, nilotinib-mediated TFEB activation enhances lysosome function of primary macrophages in vitro, and MNC1 and MNC2 in vivo, improving control of Mtb infection. Our results suggest that Mtb exploits lysosome-poor monocyte-derived lung cells for persistence; targeting lysosome biogenesis may be an effective approach to host-directed therapy for tuberculosis, enabling permissive lung cells to restrict and kill Mtb through autophagy and other mechanisms.

Project description:TFEB has been recently reported to be a key molecule for lysosomal regulation. Renal cell carcinoma (RCC) with t(6;11) (p21;q12) is known to be the only tumor in which TFEB is upregulated. Transcriptome analysis using a whole-genome expression array and pathway analysis using upregulated genes in tumor tissue revealed that the lysosome-associated pathways were significantly deregulated. Total RNA was extracted from non-tumor and tumor in patient of renal cell carcinoma with t(6;11) (p21;q12) and subjected to gene expression microarray analysis.

Project description:Cells respond to mitochondrial energetic stress with rapid activation of the AMP-activated protein kinase (AMPK), which acutely inhibits anabolism and stimulates catabolism. AMPK also induces sustained transcriptional reprogramming of metabolism. The TFEB transcription factor is a major effector of AMPK signals, inducing lysosome genes following energetic stress. Yet the molecular mechanism underlying how AMPK activates TFEB remains unresolved. We demonstrate here that AMPK directly phosphorylates five conserved serine residues in FNIP1, which suppresses the function of the FLCN/FNIP1 RagC GAP complex, in turn controlling TFEB lysosomal localization. We demonstrate that FNIP1 phosphorylation is required for AMPK to induce nuclear translocation of TFEB, which is fully separable from AMPK control of canonical mTORC1 signaling. Using a non-phosphorylatable allele of FNIP1, we show that in parallel to lysosomal biogenesis, AMPK induces mitochondrial biogenesis via TFEB-dependent induction of PGC1a mRNA. This signaling from mitochondrial stress is also independent of amino-acid control of the Rags and TFEB, which still proceed normally in cells bearing the AMPK-non phosphorylatable allele of FNIP1. Taken together, mitochondrial energetic stress triggers AMPK/FNIP1-dependent TFEB nuclear translocation, inducing transcriptional waves of lysosomal and mitochondrial biogenesis.

Project description:Lysosomes are at the epicenter of cellular processes critical for inflammasome activation in macrophages, including autophagy and lipid metabolism. Inflammasome activation and IL1-beta secretion are implicated in atherogenesis, ischemic cardiac injury and resultant heart failure; however, little is known about the role of macrophage lysosome function in regulating these processes. We hypothesized that macrophages exhibit lysosome dysfunction in heart failure due to ischemic injury, and that augmentation of macrophage lysosomal biogenesis via macrophage-specific overexpression of transcription factor EB (mf-TFEB) would attenuate ischemic remodeling by modulating macrophage inflammatory responses. In both mice subject to ischemia-reperfusion injury, and human heart tissue from patients with ischemic cardiomyopathy, we find evidence of lysosome insufficiency and autophagic impairment, respectively. Mf-TFEB overexpression significantly attenuated post-IR adverse left ventricular remodeling at 4 weeks without affecting scar size. Mf-TFEB overexpression reduced the relative amounts of pro-inflammatory macrophage populations in the myocardium. RNA sequencing of flow-sorted cardiac macrophages post-IR confirmed that TFEB stimulated a lysosomal transcriptional program in macrophages, and upregulated key targets involved in lysosomal lipid metabolism, which we show are critical for inflammasome suppression. Both TFEB-dependent inflammasome suppression and effects on post-IR remodeling were independent of autophagy. Our findings suggest that TFEB reprograms macrophage lysosomal lipid metabolism to attenuate inflammasome activity and protect against post-ischemic cardiac remodeling and simultaneously shift our understanding of how autophagy and lipid metabolism impact acute inflammation.