Project description:Mycobacterium tuberculosis impairs host lysosomal trafficking pathways. Xenophagy and LC3-associated phagocytosis (LAP) are lysosomal trafficking pathways that normally clear intracellular microbes. The xenophagy and LAP pathways depend upon ATG5 and ATG7, which result in the lipidation of LC3-I to LC3-II. How Mtb undermines these innate immune defenses of the host in not well understood. We used a transposon sequencing (Tn-seq) screen to identify bacterial factors that are required for the bacilli to resist ATG5 and ATG7-dependent processes. We found that that mutants defective in production of PDIM are attenuated in murine macrophages, and they are able to survive in macrophages lacking ATG5 or ATG7.

Project description:PINK1-Parkin mediated mitophagy, a selective form of autophagy, represents an important mechanism in mitochondrial quality control (MQC) via clearance of damaged mitochondria. Although it is well known that the conjugation of mammalian ATG8s to phosphatidylethanolamine (PE) is a key step in autophagy, its role in mitophagy remains controversial. In this study, we attempted to clarify the role of the mATG8-conjugation system in mitophagy by generating knockouts of the mATG8-conjugation machinery. Unexpectedly, we show that mitochondria could still be cleared in the absence of mATG8 lipidation, in a process that was found to be independent of lysosomal degradation. Instead, mitochondria were found to be cleared via a secretory autophagy pathway, resulting in the extracellular release of mitochondria, in a process we defined as autophagic secretion of mitochondria (ASM). Functionally, increased ASM promoted the activation of the innate immune cGAS-STING pathway in recipient cells. Overall, data from this study reveal ASM as a novel mechanism in MQC, especially when the cellular mATG8-conjugation machinery is dysfunctional.

Project description:Autophagy is a conserved lysosomal-dependent cellular degradation process shown to play a key role in immune defense against Mycobacterium tuberculosis inside host macrophages. Induction of autophagy enhances mycobacterial phagosome acquisition of lysosomal hydrolases, resulting in the destruction of intracellular M. tuberculosis reference strain H37Rv and strains belonging to the East African Indian genotype. However, our previous study showed that strains belonging to the hypervirulent M. tuberculosis Beijing genotype have a special ability to resist autophagic killing but the mechanism involved remains unclear. In this study, we carried out whole transcriptome analyses of host macrophages infected with the autophagy resistant Beijing strain compared to that of H37Rv. Our results identified several genes that are differentially regulated in the Beijing strain-infected host cells including those function in the lysosome positioning pathway. Host macrophages depleted of Kxd1 and Pleckhm2, two proteins in this pathway, can now enhance the lysosomal hydrolase acquisition into the Beijing phagosomes and restrict the bacterial survival upon autophagy induction. High-content image analysis showed an increase in lysosome numbers at the cell periphery in host cells infected with the autophagy resistant Beijing strain in a Pleckhm2-dependent manner. Taken together, these data indicated that the M. tuberculosis Beijing strain escapes autophagic elimination by upregulating the lysosome positioning pathway resulting in an increase in lysosome relocation toward the cell periphery and therefore sparing the mycobacteria from autophagic restriction. Our work thus identified new strategy employed by M. tuberculosis to evade autophagy which may provide potential new targets for drug discovery against tuberculosis

Project description:Stress granule formation is a part of cellular homeostatic responses, with prototypical inducers being viral infections, heat shock and oxidative damage. Here we show that lysosomal damage is a previously unappreciated robust inducer of stress granule formation interlinked with mTOR inactivation during lysosomal damage. We find the two processes to be coordinated by a non-autophagy function of mammalian Atg8 proteins (mAtg8s). Stress granules were induced in response to biochemical damage and diverse lysosome damaging biological agents including SARS-CoV-2 ORF3a, Mycobacterium tuberculosis and protopathic tau. Proteomic analyses of purified lysosomes subjected to biochemical damage revealed recruitment to lysosomes of a network of stress granule proteins, including G3BP1 and NUFIP2. G3BP1 and NUFIP2 contributed to inactivation of mTOR during lysosomal damage via the Ragulator-RagA/B system. Lysosomal damage recruited a subset of mAtg8s commonly related to autophagy but also known to associate with other stressed or remodeling membranes. The GABARAP subset of mAtg8s interacted with G3BP1 and NUFIP2 and were required for NUFIP2 and G3BP1 recruitment to the damaged lysosomes. GABARAPs acted as a switch between the utilization of G3BP1 and NUFIP2 in stress granule formation vs. their role in mTOR inactivation. We furthermore found that mAtg8s lipidation, referred herein as Atg8ylation to distinguish it from its conventional implication in autophagy, but not the canonical autophagy factors ATG13, FIP200, and ATG9A, favored mTOR inactivation during lysosomal damage vs. the stress granule formation. Thus, cells utilize Atg8ylation as a response to membrane stress for specific outcomes beyond the process of autophagy, which include the coordinated stress granule formation and mTOR inactivation during lysosomal damage

Project description:The PI3K-PKB/c-akt-FOXO signalling network provides a major intracellular hub for regulation of cell proliferation, survival and stress resistance1. Here we report a novel function for FOXO transcription factors in regulating autophagy through modulation of intracellular glutamine levels. To identify novel transcriptional targets of this module we performed an unbiased microarray analysis after conditional activation of the key components PI3K, PKB, FOXO3 and FOXO4. Utilising this global pathway approach we identified glutamine synthetase (GS) as being transcriptionally regulated by PI3K-PKB-FOXO signalling. FOXO-mediated increase in GS expression specifically induced glutamine production independently of cell type, and this was evolutionary conserved. FOXO activation resulted in mTOR inhibition by preventing the translocation of mTOR to lysosomal membranes, which was dependent on GS activity. Increased GS activity resulted in increased autophagosome turnover as measured by LC3 lipidation, p62 degradation, and confocal imaging of LC3, p62, WIPI-1, ULK2 and Atg12. Inhibition of FOXO3-mediated autophagy resulted in increased apoptosis, suggesting that the induction of autophagy by FOXO3-mediated upregulation of GS is important for cellular survival. These findings reveal a novel signalling network that can directly modulate autophagy through regulation of glutamine metabolism. conditional activation of pkb and pi3k were followed in a timeseries. Each timepoint consists of 4 independent replicates, labeled with either cy3 or cy5 and put on array against time0.

Project description:The PI3K-PKB/c-akt-FOXO signalling network provides a major intracellular hub for regulation of cell proliferation, survival and stress resistance1. Here we report a novel function for FOXO transcription factors in regulating autophagy through modulation of intracellular glutamine levels. To identify novel transcriptional targets of this module we performed an unbiased microarray analysis after conditional activation of the key components PI3K, PKB, FOXO3 and FOXO4. Utilising this global pathway approach we identified glutamine synthetase (GS) as being transcriptionally regulated by PI3K-PKB-FOXO signalling. FOXO-mediated increase in GS expression specifically induced glutamine production independently of cell type, and this was evolutionary conserved. FOXO activation resulted in mTOR inhibition by preventing the translocation of mTOR to lysosomal membranes, which was dependent on GS activity. Increased GS activity resulted in increased autophagosome turnover as measured by LC3 lipidation, p62 degradation, and confocal imaging of LC3, p62, WIPI-1, ULK2 and Atg12. Inhibition of FOXO3-mediated autophagy resulted in increased apoptosis, suggesting that the induction of autophagy by FOXO3-mediated upregulation of GS is important for cellular survival. These findings reveal a novel signalling network that can directly modulate autophagy through regulation of glutamine metabolism. conditional activation of foxo3 and foxo4 were followed in a timeseries. Each timepoint consists of 4 independent replicates, labeled with either cy3 or cy5 and put on array against time0 as reference.

Project description:Autophagy is an essential catabolic process responsible for recycling of intracellular material and preserving cellular fidelity. Key to the autophagy pathway is the ubiquitin-like conjugation system mediating lipidation of Atg8 proteins and their anchoring to autophagosomal membranes. While regulation of autophagy has been characterized at the level of transcription, protein interactions and post-translational modifications, its translational regulation remains elusive. Here we describe a novel regulatory axis of autophagy at the translational level, guided by the conserved eukaryotic translation factor eIF5A. Identified from a high-throughput screen, we find that eIF5A is required for lipidation of LC3B and its paralogs and promotes autophagosome formation. This feature is evolutionarily conserved and results from the translation of the E2-like ATG3 protein. Mechanistically, we identify an amino acid motif in ATG3 causing eIF5A-dependency for its efficient translation. Our study identifies a key regulatory mechanism of autophagosome formation and demonstrates the impact of translation in the regulation autophagy.

Project description:Loss of function mutations in MECP2are associated to Rett syndrome (RTT), a severe neurodevelopmental disease. Mainly working as a transcriptional regulator, MECP2 absence leads to gene expression perturbations resulting in deficits of synaptic function and neuronal activity. In addition, RTT patients and mouse models suffer from a complex metabolic syndrome, suggesting that related cellular pathways might contribute to neuropathogenesis. Along this line, autophagy is critical in sustaining developing neuron homeostasis by breaking down dysfunctional proteins, lipids, and organelles. Here, we investigated the autophagic pathway in RTT and found reduced content of autophagic vacuoles in Mecp2 knock-out neurons. This correlates with defective lipidation of LC3B-II probably caused by a deficiency of the autophagic membrane lipid phosphatidylethanolamine. The administration of the autophagy inducer trehalose recovers LC3B lipidation, autophagosomes content in knock-out neurons, and ameliorates their morphology, neuronal activity and synaptic ultrastructure. Moreover, we provide evidence for attenuation of motor and exploratory impairment in Mecp2 knock-out mice upon trehalose administration. Overall, our findings open new perspectives for neurodevelopmental disorders therapies based on the concept of autophagy modulation.

Project description:Activation of Stimulator of interferon genes (STING) is well known to upregulate inflammation through canonical TBK1 signaling. STING is recently found to activate noncanonical functions through its transmembrane proton channel. Whether STING stimulates any transcription programs through its channel is unknown. In this study, we identified the transcription factor EB (TFEB) as a downstream effector of the STING channel. TFEB is a transcriptional regulator of lysosomal biogenesis and autophagy. Using RNA sequencing approaches, we confirmed that STING activated transcriptional upregulation of lysosomal biogenesis and autophagy independently of TBK1.

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.