Project description:Group 3 innate lymphoid cells (ILC3s) play a crucial role in intestinal inflammatory disorders such as necrotizing enterocolitis (NEC) in neonates; however, the mechanisms by which ILC3s contribute to NEC remain unclear. In this study, single-cell transcriptomics, in vivo experiments on T cell-deficient mice, and targeted cell interventions demonstrated that NKp46−CCR6− (double-negative, DN) ILC3 autophagy significantly impacts NEC development by regulating intracellular metabolism. Mice lacking ATG5 or treated with autophagy inhibitors exhibited reduced ILC3 abundance and impaired ILC3 function, alleviating NEC. Mechanistically, ATG5 deficiency enhanced fatty acid metabolism while reducing glycolysis. Conversely, inhibiting fatty acid oxidation or supplementing with lactate restored the quantity and functionality of ATG5-deficient DN ILC3s, exacerbating NEC. Lipid metabolism analyses combined with a mouse model of NEC indicated that phosphatidylcholine supplementation alleviated intestinal inflammation by inhibiting DN ILC3 autophagy. Clinically, patients with NEC showed elevated ILC3 levels and significant enrichment of autophagy genes. These findings highlight the importance of DN ILC3 autophagy in metabolic adaptation, suggesting potential strategies for managing NEC.

Project description:Group 3 innate lymphoid cells (ILC3s) play a crucial role in intestinal inflammatory disorders such as necrotizing enterocolitis (NEC) in neonates; however, the mechanisms by which ILC3s contribute to NEC remain unclear. In this study, single-cell transcriptomics, in vivo experiments on T cell-deficient mice, and targeted cell interventions demonstrated that NKp46−CCR6− (double-negative, DN) ILC3 autophagy significantly impacts NEC development by regulating intracellular metabolism. Mice lacking ATG5 or treated with autophagy inhibitors exhibited reduced ILC3 abundance and impaired ILC3 function, alleviating NEC. Mechanistically, ATG5 deficiency enhanced fatty acid metabolism while reducing glycolysis. Conversely, inhibiting fatty acid oxidation or supplementing with lactate restored the quantity and functionality of ATG5-deficient DN ILC3s, exacerbating NEC. Lipid metabolism analyses combined with a mouse model of NEC indicated that phosphatidylcholine supplementation alleviated intestinal inflammation by inhibiting DN ILC3 autophagy. Clinically, patients with NEC showed elevated ILC3 levels and significant enrichment of autophagy genes. These findings highlight the importance of DN ILC3 autophagy in metabolic adaptation, suggesting potential strategies for managing NEC.

Project description:Group 3 innate lymphoid cells (ILC3s) play a crucial role in intestinal inflammatory disorders such as necrotizing enterocolitis (NEC) in neonates; however, the mechanisms by which ILC3s contribute to NEC remain unclear. In this study, single-cell transcriptomics, in vivo experiments on T cell-deficient mice, and targeted cell interventions demonstrated that NKp46−CCR6− (double-negative, DN) ILC3 autophagy significantly impacts NEC development by regulating intracellular metabolism. Mice lacking ATG5 or treated with autophagy inhibitors exhibited reduced ILC3 abundance and impaired ILC3 function, alleviating NEC. Mechanistically, ATG5 deficiency enhanced fatty acid metabolism while reducing glycolysis. Conversely, inhibiting fatty acid oxidation or supplementing with lactate restored the quantity and functionality of ATG5-deficient DN ILC3s, exacerbating NEC. Lipid metabolism analyses combined with a mouse model of NEC indicated that phosphatidylcholine supplementation alleviated intestinal inflammation by inhibiting DN ILC3 autophagy. Clinically, patients with NEC showed elevated ILC3 levels and significant enrichment of autophagy genes. These findings highlight the importance of DN ILC3 autophagy in metabolic adaptation, suggesting potential strategies for managing NEC.

Project description:Susceptibility to Crohn's disease, a complex inflammatory disease involving the small intestine, is controlled by over 30 loci. One Crohn's disease risk allele is in ATG16L1, a gene homologous to the essential yeast autophagy gene ATG16 (ref. 2). It is not known how ATG16L1 or autophagy contributes to intestinal biology or Crohn's disease pathogenesis. To address these questions, we generated and characterized mice that are hypomorphic for ATG16L1 protein expression, and validated conclusions on the basis of studies in these mice by analysing intestinal tissues that we collected from Crohn's disease patients carrying the Crohn's disease risk allele of ATG16L1. Here we show that ATG16L1 is a bona fide autophagy protein. Within the ileal epithelium, both ATG16L1 and a second essential autophagy protein ATG5 are selectively important for the biology of the Paneth cell, a specialized epithelial cell that functions in part by secretion of granule contents containing antimicrobial peptides and other proteins that alter the intestinal environment. ATG16L1- and ATG5-deficient Paneth cells exhibited notable abnormalities in the granule exocytosis pathway. In addition, transcriptional analysis revealed an unexpected gain of function specific to ATG16L1-deficient Paneth cells including increased expression of genes involved in peroxisome proliferator-activated receptor (PPAR) signalling and lipid metabolism, of acute phase reactants and of two adipocytokines, leptin and adiponectin, known to directly influence intestinal injury responses. Importantly, Crohn's disease patients homozygous for the ATG16L1 Crohn's disease risk allele displayed Paneth cell granule abnormalities similar to those observed in autophagy-protein-deficient mice and expressed increased levels of leptin protein. Thus, ATG16L1, and probably the process of autophagy, have a role within the intestinal epithelium of mice and Crohn's disease patients by selective effects on the cell biology and specialized regulatory properties of Paneth cells. Experiment Overall Design: 4 Samples: 2 replicates of Atg16-hypomorph Paneth cells and 2 replicates of Wildtype Paneth cells.

Project description:Susceptibility to Crohn's disease, a complex inflammatory disease involving the small intestine, is controlled by over 30 loci. One Crohn's disease risk allele is in ATG16L1, a gene homologous to the essential yeast autophagy gene ATG16 (ref. 2). It is not known how ATG16L1 or autophagy contributes to intestinal biology or Crohn's disease pathogenesis. To address these questions, we generated and characterized mice that are hypomorphic for ATG16L1 protein expression, and validated conclusions on the basis of studies in these mice by analysing intestinal tissues that we collected from Crohn's disease patients carrying the Crohn's disease risk allele of ATG16L1. Here we show that ATG16L1 is a bona fide autophagy protein. Within the ileal epithelium, both ATG16L1 and a second essential autophagy protein ATG5 are selectively important for the biology of the Paneth cell, a specialized epithelial cell that functions in part by secretion of granule contents containing antimicrobial peptides and other proteins that alter the intestinal environment. ATG16L1- and ATG5-deficient Paneth cells exhibited notable abnormalities in the granule exocytosis pathway. In addition, transcriptional analysis revealed an unexpected gain of function specific to ATG16L1-deficient Paneth cells including increased expression of genes involved in peroxisome proliferator-activated receptor (PPAR) signalling and lipid metabolism, of acute phase reactants and of two adipocytokines, leptin and adiponectin, known to directly influence intestinal injury responses. Importantly, Crohn's disease patients homozygous for the ATG16L1 Crohn's disease risk allele displayed Paneth cell granule abnormalities similar to those observed in autophagy-protein-deficient mice and expressed increased levels of leptin protein. Thus, ATG16L1, and probably the process of autophagy, have a role within the intestinal epithelium of mice and Crohn's disease patients by selective effects on the cell biology and specialized regulatory properties of Paneth cells.

Project description:Metabolic profiling in wild type and autophagy-deficient human embryonic stem cell (hESC)-derived neurons after 3 weeks of neuronal differentiation. Autophagy is a homeostatic process critical for cellular survival, and its malfunction is implicated in myriad human diseases including neurodegeneration. Loss of autophagy contributes to cytotoxicity and tissue degeneration, but the mechanistic understanding of this phenomenon remains elusive. Here we have generated autophagy-deficient human embryonic stem cells (hESCs), from which we have established human neuronal platform to investigate how loss of autophagy affects neuronal survival. ATG5 deficient neurons exhibit basal cytotoxicity accompanied by metabolic defects. Depletion of nicotinamide adenine dinucleotide (NAD) due to hyperactivation of NAD-consuming enzymes is found to trigger cell death via mitochondrial depolarisation in ATG5 deficient neurons. Boosting intracellular NAD levels improve cell viability by restoring mitochondrial bioenergetics and proteostasis in ATG5 deficient neurons. Our findings elucidate a mechanistic link between autophagy deficiency and neuronal cell death that can be targeted for therapeutic interventions in neurodegenerative and lysosomal storage diseases associated with autophagic defect.

Project description:Autophagy maintains intestinal stem cell integrity

Project description:Ambroxol Induced Myeloma Cell Death by Inhibiting Autophagy

Project description:Metabolic profiling in wild type and autophagy-deficient human embryonic stem cell (hESC)-derived neurons after 3 weeks of neuronal differentiation. Autophagy is a homeostatic process critical for cellular survival, and its malfunction is implicated in myriad human diseases including neurodegeneration. Loss of autophagy contributes to cytotoxicity and tissue degeneration, but the mechanistic understanding of this phenomenon remains elusive. Here we have generated autophagy-deficient human embryonic stem cells (hESCs), from which we have established human neuronal platform to investigate how loss of autophagy affects neuronal survival. ATG5 deficient neurons exhibit basal cytotoxicity accompanied by metabolic defects. Depletion of nicotinamide adenine dinucleotide (NAD) due to hyperactivation of NAD-consuming enzymes is found to trigger cell death via mitochondrial depolarisation in ATG5 deficient neurons. Boosting intracellular NAD levels improve cell viability by restoring mitochondrial bioenergetics and proteostasis in ATG5 deficient neurons. Our findings elucidate a mechanistic link between autophagy deficiency and neuronal cell death that can be targeted for therapeutic interventions in neurodegenerative and lysosomal storage diseases associated with autophagic defect.

Project description:The intestinal epithelium is continuously renewed by a pool of intestinal stem cells expressing Lgr5. We show that deletion of the key autophagy gene Atg7 affects the survival of Lgr5+ intestinal stem cells. Mechanistically, this involves defective DNA repair, oxidative stress, and altered interactions with the microbiota. This study highlights the importance of autophagy in maintaining the integrity of intestinal stem cells.