Global ETD Search

21	ATG9A and ATG13 Cooperate to Drive Basal Autophagy Poole, Daniel Morgan 06 April 2022 (has links) Autophagy, as the name suggests, is a cellular process of self-eating in which cytoplasmic debris is engulfed by a double membrane vesicle dubbed the autophagosome and is ultimately degraded and recycled by proteases in the lysosome. The process is initiated by a group of core ATG proteins, including a multi-pass transmembrane protein called ATG9A. Although ATG9A has been shown to be essential for both stress induced and basal autophagy, its mechanism and interaction network remain largely illusive. Our current study employs BioID proteomics to identify a network of interactors, including regulators of membrane fusion and vesicle trafficking, such as TRAPP, EARP, GARP, exocyst, AP-1 and AP-4 complexes, as well as members of the ULK1 autophagy kinase complex. Further investigations confirm that two components of the ULK1 complex, ATG13 and ATG101, directly interact with ATG9A. Using CRISPR, we show that deletion of ATG13 or ATG101 disrupts ATG9A trafficking and causes an accumulation of ATG9A at p62/SQSTM1-positive ubiquitin clusters. Lentivirus reconstitution and split-mVenus approaches using an ULK1 binding deficient mutant of ATG13 reveal that ATG9A interacts with ATG13 and ATG101 in an ULK1-independent manner. Together, these data reveal ATG9A interactions in vesicle trafficking and autophagy pathways, including a role for an ULK1- independent ATG13 complex in regulating ATG9A. ATG9A ATG13 ATG101 ULK1 p62 ubiquitin macroautophagy BioID subcomplex Physical Sciences and Mathematics
22	p62-mediated Selective Autophagy Endows Virus-Transformed Cells With Insusceptibility to DNA Damage Under Oxidative Stress Wang, Ling, Howell, Mary E. A., Wallace, Aryianna Sparks, Hawkins, Caroline, Nicksic, Camri A., Kohne, Carissa, Hall, Kenton H., Moorman, Jonathan P., Yao, Zhi Q., Ning, Shunbin 24 April 2019 (has links) (PDF) DNA damage response (DDR) and selective autophagy both can be activated by reactive oxygen/nitrogen species (ROS/RNS), and both are of paramount importance in cancer development. The selective autophagy receptor and ubiquitin (Ub) sensor p62 plays a key role in their crosstalk. ROS production has been well documented in latent infection of oncogenic viruses including Epstein-Barr Virus (EBV). However, p62-mediated selective autophagy and its interplay with DDR have not been investigated in these settings. In this study, we provide evidence that considerable levels of p62-mediated selective autophagy are spontaneously induced, and correlate with ROS-Keap1-NRF2 pathway activity, in virus-transformed cells. Inhibition of autophagy results in p62 accumulation in the nucleus, and promotes ROS-induced DNA damage and cell death, as well as downregulates the DNA repair proteins CHK1 and RAD51. In contrast, MG132-mediated proteasome inhibition, which induces rigorous autophagy, promotes p62 degradation but accumulation of the DNA repair proteins CHK1 and RAD51. However, pretreatment with an autophagy inhibitor offsets the effects of MG132 on CHK1 and RAD51 levels. These findings imply that p62 accumulation in the nucleus in response to autophagy inhibition promotes proteasome-mediated CHK1 and RAD51 protein instability. This claim is further supported by the findings that transient expression of a p62 mutant, which is constitutively localized in the nucleus, in B cell lines with low endogenous p62 levels recaptures the effects of autophagy inhibition on CHK1 and RAD51 protein stability. These results indicate that proteasomal degradation of RAD51 and CHK1 is dependent on p62 accumulation in the nucleus. However, small hairpin RNA (shRNA)-mediated p62 depletion in EBV-transformed lymphoblastic cell lines (LCLs) had no apparent effects on the protein levels of CHK1 and RAD51, likely due to the constitutive localization of p62 in the cytoplasm and incomplete knockdown is insufficient to manifest its nuclear effects on these proteins. Rather, shRNA-mediated p62 depletion in EBV-transformed LCLs results in significant increases of endogenous RNF168-γH2AX damage foci and chromatin ubiquitination, indicative of activation of RNF168-mediated DNA repair mechanisms. Our results have unveiled a pivotal role for p62-mediated selective autophagy that governs DDR in the setting of oncogenic virus latent infection, and provide a novel insight into virus-mediated oncogenesis. p62-mediated virus-transformed cells oidative stress Internal Medicine Internal Medicine
23	The Multifunctional Protein p62 and Its Mechanistic Roles in Cancers Ning, Shunbin, Wang, Ling 01 January 2019 (has links) The multifunctional signaling hub p62 is well recognized as a ubiquitin sensor and a selective autophagy receptor. As a ubiquitin sensor, p62 promotes NFκB activation by facilitating TRAF6 ubiquitination and aggregation. As a selective autophagy receptor, p62 sorts ubiquitinated substrates including p62 itself for lysosome-mediated degradation. p62 plays crucial roles in myriad cellular processes including DNA damage response, aging/senescence, infection and immunity, chronic inflammation, and cancerogenesis, dependent on or independent of autophagy. Targeting p62-mediated autophagy may represent a promising strategy for clinical interventions of different cancers. In this review, we summarize the transcriptional and post-translational regulation of p62, and its mechanistic roles in cancers, with the emphasis on its roles in regulation of DNA damage response and its connection to the cGAS-STING-mediated antitumor immune response, which is promising for cancer vaccine design. p62 autophagy ubiquitination ROS antitumor immune response cancer vaccine design Internal Medicine Internal Medicine
24	The Discovery of Novel 14-3-3 Binding Proteins ATG9A and PTOV1 and Their Role in Regulating Cancer Mechanisms McEwan, Colten Mitchell 03 August 2022 (has links) 14-3-3 proteins are among a family of phospho-binding proteins that are known to regulate many essential cellular mechanisms. By binding to sites of phosphorylation, 14-3-3s are integrated into multiple signaling pathways that govern critical processes, such as apoptosis, cell cycle progression, autophagy, glucose metabolism, and cell motility. These processes are crucial for tumorigenesis and 14-3-3 proteins are known to play a central role in facilitating cancer progression. In this study, my colleagues and I discover two novel 14-3-3 interacting proteins, ATG9A and PTOV1, that are both vital to essential cellular functions and describe various mechanisms that these two proteins regulate. ATG9A is a multi-pass transmembrane lipid scramblase that is found primarily as a homotrimer in the ER or small ATG9A vesicles. It is essential in the cellular recycling process called autophagy and is believed to act at the earliest stages of autophagy by providing the seed for the growth of the double membrane vesicle called an autophagosome. Previous work in our lab demonstrated that upon hypoxic stress, AMPK, the master nutrient-sensing kinase, phosphorylates S761 on the C-terminus of ATG9A. This triggers the binding of 14-3-3ζ to contribute to ATG9A function in hypoxia induced autophagy. Despite this revelation, the exact function of ATG9A is still poorly understood, especially in unstimulated conditions where autophagy functions at a basal level and AMPK is inactive. In this study, we sought to understand ATG9A function more broadly by identifying novel interactors of ATG9A and the role ATG9A plays in basal autophagy. To do this, we employed BioID mass spectrometry and various biochemical approaches to identify LRBA as a bona fide ATG9A interactor and autophagy regulator. Furthermore, using deuterium labeling and quantitative whole proteome mass spectrometry, and various other biochemical techniques, we show that ATG9A regulates the basal degradation of p62 and is recruited to sites of basal autophagy by active poly-ubiquitination to initiate basal autophagy. PTOV1 is an oncogenic protein that is poorly understood. Our current understanding of PTOV1 is limited to a few studies, which demonstrate that PTOV1 is highly expressed in primary prostate tumor samples and is correlated with metastasis, drug resistance, and poor clinical outcomes. In this study, we identify a mechanism by which SGK2, a poorly understood kinase, phosphorylates PTOV1 at S36 to trigger 14-3-3 binding at that site to increase PTOV1 stability in the cytosol and increase c-Jun expression. Upon SGK2 inhibition, 14-3-3 releases PTOV1 and PTOV1 is shuttled into the nucleus where HUWE1, an E3 ubiquitin ligase, ubiquitinates PTOV1 and initiates PTOV1 degradation by the proteasome. This is the first detailed mechanism of regulation identified for the poorly understood oncogene, PTOV1, and sheds light on potential therapeutic targets for cancer treatments. 14-3-3 ATG9A LRBA PTOV1 autophagy ubiquitin p62 SQSTM1 BioID autophagy adaptor Physical Sciences and Mathematics
25	The Role of Autophagy in Burkholderia cenocepacia Infection Abdulrahman, Basant Ahmed 18 December 2012 (has links) No description available. Biochemistry Biology Biomedical Research Immunology Microbiology Molecular Biology Autophagy Burkholderia cenocepacia p62
26	Rôles et mécanismes d’action de la protéine Epac dans l’hypertrophie cardiaque / Functions and signaling of Epac protein in cardiac hypertrophy Laurent, Anne-Coline 17 July 2013 (has links) Les catécholamines induisent la synthèse d’AMPc par une stimulation des récepteurs β-adrénergiques et contrôlent ainsi la fonction cardiaque en activant une pléiade de voies de signalisation intracellulaires. Les protéines Epac sont des facteurs d’échange pour les petites protéines G et sont directement activés par l’AMPc. Devant l’importance de la voie β-adrénergique dans la physiopathologie cardiaque et dans le but de mieux comprendre la régulation des processus cellulaires dépendants de l’AMPc dans le cœur, il apparaît essentiel de caractériser le rôle des facteurs d’échange Epac dans le myocarde. Dans une première partie, cette étude démontre que les effets de Epac sur l’hypertrophie des cardiomyocytes ventriculaires de rats nouveaux nés requièrent les GTPases H-Ras et Rap2B. Epac active la voie PLC/IP3/Ca2+ qui est nécessaire pour l’activation de H-Ras. Au niveau transcriptionnel, Epac induit l’export nucléaire de HDAC4 permettant l’activation d’un programme génique d’hypertrophie. Dans une deuxième partie, cette étude révèle l’implication de Epac1 dans l’hypertrophie des cardiomyocytes in vivo, chez la souris. La délétion de Epac1 protège du remodelage cardiaque induit par l’activation prolongée des récepteurs β-adrénergiques et améliore la fonction cardiaque. La surexpression de Epac1 spécifiquement dans le myocarde entraîne une hypertrophie des cardiomyocytes. Par ailleurs, la voie β-AR/Epac1 induit l’accumulation de protéines ubiquitinylées et provoque l’activation du processus d’autophagie in vitro et in vivo. L’autophagie protège des effets délétères de la voie β-adrénergique/Epac en participant à l’élimination des agrégats protéiques et en contrant les effets hypertrophiques de Epac1. Ces résultats ouvrent de nouvelles perspectives pour le traitement de l’hypertrophie et de l’insuffisance cardiaque. / Catecholamines regulate cardiac function by stimulating β-adrenergic receptors (β-AR), leading to cAMP production and activation of a multiplicity of signaling pathways. Epac proteins are exchange factors for small G proteins which are directly activated by cAMP. Given the importance of the β-adrenergic pathway in cardiac physiopathology, it becomes essential to characterize functions of Epac protein in myocardium. In a first part, this study shows that H-Ras and Rap2B GTPases are involved in Epac-induced neonatal rat cardiac myocytes hypertrophy. Epac induces activation of the PLC/IP3/Ca2+ pathway which is necessary for H-Ras activation. At the transcriptional level, Epac causes HDAC4 nuclear export leading to activation of a hypertrophic gene program. In a second part, this study reveals implication of Epac1 in cardiac hypertrophy in vivo. Deletion of Epac1 in mice protects from cardiac remodeling induced by chronic isoproterenol infusion and enhances cardiac function. Cardiac specific overexpression of Epac1 in mice induces cardiac myocytes hypertrophy. Interestingly, β-AR/Epac1 pathway triggers ubiquitinated proteins accumulation and activation of autophagy both in vitro and in vivo. By eliminating aggregates and by counteracting hypertrophic effects of Epac, autophagy protects from deleterious effects of the β-AR/Epac pathway. These results open news insights into the treatment of cardiac hypertrophy and heart failure. Hypertrophie et insuffisance cardiaque Autophagie Récepteur β-adrénergique AMP cyclique Epac Petites protéines G HDAC Protéines ubiquitinylées Bécline 1 P62 LC3 Cardiac hypertrophy and failure Autophagy Β-adrenergic receptor Cyclic AMP Epac Small GTPases HDAC Ubiquitinated proteins Beclin 1 P62 LC3
27	Prognostische Relevanz der Autophagie in histologischen Subtypen des papillären Nierenzellkarzinoms / Prognostic relevance of autophagy in histological subtypes of papillary renal cell carcinoma Schlegel, Christina 22 August 2018 (has links) No description available. 610 papilläres Nierenzellkarzinom Autophagie Beclin-1 LC3 p62 Immunhistochemie papillary renal cell carcinoma autophagy Beclin-1 LC3 p62 immunohistochemistry Medizin (PPN619874732)
28	THE ROLE OF p62 IN OSTEOCLASTOGENESIS AND PAGET’S DISEASE OF BONE Hadi, Tamer 20 November 2012 (has links) Paget’s disease (PDB) is the second most common metabolic bone disease after osteoporosis, affecting up to 3% of adults over age 55. It is characterized by focal lesions of bone resorbed by hyperactive osteoclasts coupled with rapid formation of highly disorganized, low quality bone formed by osteoblasts. Such lesions cause skeletal deformity, fractures, and other symptoms that significantly decrease quality of life. In 2001, mutations in the SQSTM1/p62 gene were found in a subset of Paget’s patients. The work summarized in this dissertation sought to answer two broad questions: what is the function of p62 in normal bone homeostasis and how do PDB-associated mutations alter it? These studies took advantage of two mouse models: p62 knock-out (KO) mice, and p62P394L “knock-in” (KI) mice carrying the most common PDB-associated mutation. KO, KI, and wildtype (WT) controls were aged to one year for skeletal-histological characterization. No differences were observed in a variety of bone parameters between WT and KO bones, while bones from age-matched KI mice exhibited a 33% decrease in bone volume and a 25% increase in osteoclast formation. In vivo, TNF-α caused a potent induction of osteoclastogenesis in calvariae of WT and KI, but not KO, mice. In vitro, RANKL induced osteoclast formation in a dose-dependent manner in WT and KI, but not KO, cultures. Gene expression profiling of RANKL-treated osteoclast progenitors from WT, KO, and KI mice was then performed to identify the changes in signaling pathways responsible for these effects. Surprisingly, gene expression patterns from all three groups were consistent with robust activation of NFκB signaling in RANKL-treated samples, indicating that p62 is dispensable for RANKL activation of NFκB. Interestingly, gene expression patterns in KO cells suggested impaired proliferation and response to reactive oxygen species (ROS), a finding which was confirmed in cell culture experiments. In contrast, KI cells displayed enrichment for genes associated with the unfolded protein response, consistent with p62’s role in ubiquitin-mediated protein degradation via proteolysis and autophagy. These studies have therefore generated several novel hypotheses concerning the role of p62 in both normal bone homeostasis and Paget’s disease of bone. sequestosome 1 p62 Paget's disease of bone microarray RANKL osteoclastogenesis osteoclast formation Medical Genetics Medical Sciences Medicine and Health Sciences
29	Regulation and impact of adaptor protein SQSTM1/p62 in the replication cycle of Respiratory Syncytial Virus in Airway Epithelial Cells Cervantes Ortiz, Sandra Liliana 06 1900 (has links) Introduction: le Virus Respiratoire Syncytial humain (RSV) induit un taux élevé de morbidité et de mortalité chez les enfants, les personnes immunodéprimées et les personnes âgées. Il existe un besoin urgent d'un nouveau traitement antiviral et d'un vaccin efficaces. Les cellules épithéliales des voies aériennes (AEC) sont la cible principale de RSV et constituent la première ligne de défense grâce à des mécanismes distincts, qui incluent une réponse antivirale autonome cellulaire. La protéine p62/SQSTM1 a de multiples fonctions cellulaires, y compris la séquestration spécifique de la cargaison ubiquitinée (c'est-à-dire, les protéines/organelles et les bactéries intracellulaires) pour leur clairance par autophagie. Des données publiées ont mis en évidence un rôle important de p62 dans la régulation de plusieurs virus (par exemple, le virus de la grippe et la dengue), favorisant ou restreignant sa réplication en fonction du virus. L'objectif de notre étude est de déterminer le rôle de p62 dans la régulation du cycle infectieux de RSV. Méthodes et résultats: L'analyse de l'expression de p62 dans les cellules A549 a montré que p62 est induit et phosphorylé au début de l'infection par RSV. Il est ensuite dégradé plus tardivement durant l’infection. La déplétion des niveaux de p62 a diminué l'accumulation intracellulaire des protéines virales, tandis que la relâche des virions infectieux a été augmentée. De plus, nous avons observé que la réplication de recRSV-GFP est diminuée dans des cellules exprimant de façon stable la protéine associée aux microtubules 1A/1B, chaîne légère 3 (LC3). LC3 recrute p62 et ses cargaisons à l'autophagosome pour qu'ils soient dégradés par autophagie. Des études sont actuellement en cours pour déterminer les mécanismes moléculaires, dépendant de p62, impliqués dans la régulation de la réplication de RSV. Conclusion: nos résultats mettent en évidence un rôle clé de p62 dans la réplication et la propagation de RSV. Ces études aideront à définir si p62 pourrait représenter une cible thérapeutique potentielle pour lutter contre l'infection à RSV. / Introduction: Human respiratory syncytial virus (RSV) causes a high rate of morbidity and mortality worldwide in children, immunocompromised and elderly people. There is an urgent need for effective antiviral treatments and vaccines for RSV. Airway epithelial cells (AECs) are the primary target of RSV and constitute the first line of defense through distinct mechanisms, including intrinsic antiviral responses. The p62/SQSTM1 protein has multiple cellular functions including cell signaling and sequestration of specific ubiquitinated cargo (i.e. proteins/organelles and intracellular bacteria) for autophagic degradation. The replication of several viruses has been shown to be sensitive to p62 levels. The goal of our study is to investigate the role of p62 in the regulation of RSV replication. Methods and Results: Analysis of p62 expression in A549 cells showed that p62 is induced and phosphorylated during early stages of RSV infection, followed by degradation at later times. P62 silencing diminished the intracellular accumulation of viral proteins, while causing increased release of infectious virions. Additionally, we observed that the stable expression of Microtubule-associated protein 1A/1B-light chain 3 (LC3), which recruits p62 and its cargos to the autophagosome for autophagy degradation, reduces recRSV-GFP replication. Studies are currently undertaken to determine the molecular mechanisms involved in p62-dependent regulation of RSV replication. Conclusion: Our results highlight a key role of p62 in the replication of RSV. These studies will help to define whether p62 might represent a potential therapeutic target to fight RSV infection. p62/SQSTM1 Respiratory syncytial virus RSV Airway epithelial cells Antiviral response UPS Autophagy Viral replication Virus respiratoire syncytial humain Réponse antivirale Autophagie Réplication virale
30	Rôles de TRIM5 et Atg5 dans la réponse immune innée de cellules infectées par le VIH-1 Khalfi, Soumia January 2020 (has links) (PDF) No description available. UQTR Biologie cellulaire et moléculaire Activité antirétrovirale Activité pro-inflammatoire AP-1 Autophagie ATG5 Cellules infectées CRISPR Flavivirus IFN-bêta Immunité innée NF-kB p62 Réponse immune innée Restriction SiDA TRIM5 Trim5a Trim5alpha VIH-1 Virus de l'immunodéficience humaine

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