Molecular physiology of signal transmission along the auditory pathway

Butola, Tanvi

16 May 2017

No description available.

570

Piccolo

Bassoon

RIM-BP

LRBA

Cochlea

endbulb of Held

Synaptic transmission

Short-term plasticity

Biologie (PPN619462639)

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

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

Identification de causes génétiques du syndrome d’Evans pédiatrique / Identifying genetic causes of pediatric Evans syndrome

Lévy, Eva

11 May 2016

Le syndrome d'Evans est défini par l'existence concomitante ou séquentielle de cytopénies auto-immunes, le plus souvent, anémie hémolytique et thrombopénie immunologique. Chez l'enfant, il peut être secondaire à une infection, une maladie auto-immune systémique ou un déficit immunitaire primitif. Alternativement, chez une grande partie des patients, l'étiologie n'est pas clairement identifiée. Les patients atteints de syndrome d'Evans présentent parfois d'autres atteintes, telles une auto-immunité d'organe, une lymphoprolifération bénigne ou un déficit immunitaire. L'objectif de ce travail était d'identifier des causes génétiques chez des enfants présentant un syndrome d'Evans sans étiologie sous-jacente identifiée. Nous avons centré notre étude sur des formes sévères à début pédiatrique en faisant l'hypothèse qu'une maladie monogénique serait plus fréquente dans ce groupe de patients. Nous avons mis à profit les technologies de séquençage haut débit « nouvelle génération » (NGS) pour réaliser et analyser le séquençage de l'exome de patients et de certains de leurs apparentés afin de mettre en évidence des gènes candidats potentiels. Ce travail a permis l'identification de 4 gènes candidats : LRBA, CTLA-4, STAT3 (mutations gain de fonction) et NFKBIA. L'implication des 3 premiers gènes dans de nouvelles maladies monogéniques où l'auto-immunité est au premier plan a été confirmée par d'autres équipes au cours de ce travail. Pour chacun de ces gènes, nous avons poursuivi 2 objectifs complémentaires : d'une part, tenter de valider l'implication des gènes identifiés dans la maladie des patients. Nous avons pour cela utilisé des approches et techniques variées : biochimie et protéomique afin d'identifier des partenaires protéiques, microscopie confocale pour localiser les protéines et leurs interactions, tests cellulaires in vitro pour mettre en évidence un défaut fonctionnel, marquages en cytométrie en flux pour identifier des modifications dans les sous-populations lymphocytaires. D'autre part, nous avons recherché d'autres mutations de ces gènes chez des patients de phénotype clinique similaire. Nous avons ainsi constitué et exploré 3 cohortes de patients présentant des mutations de LRBA, CTLA-4 ou STAT3. Nous avons rassemblé une cohorte de 18 patients porteurs d'une mutation de LRBA, répartis dans 11 familles. Cela nous a permis de préciser et d'étendre le spectre clinique de cette maladie de découverte récente, avec en particulier des atteintes articulaires sévères s'associant à un diabète précoce, ou des entéropathies. Nous avons identifié 15 nouvelles mutations de transmission autosomique récessive dans le gène LRBA, codant une protéine de fonction inconnue dont l'absence entraine une maladie principalement caractérisée par une poly-auto-immunité. Nous avons identifié 29 partenaires protéiques potentiels de LRBA et précisé la localisation de LRBA dans les différents compartiments cellulaires. Nous avons également établi une cohorte de 12 patients dans 10 familles présentant un déficit en CTLA-4 par haplo-insuffisance. Au delà de la mise en évidence de 9 nouvelles mutations, nous avons décrit une famille où la variation est transmise de façon autosomique récessive. Dans les déficits en LRBA et CTLA-4, nous avons mis en évidence une diminution du pourcentage de lymphocytes T régulateurs parmi les PBMC et une diminution de l'expression de CTLA-4 dans les lymphocytes T activés. Ceci corrobore l'interaction entre ces 2 protéines décrite en parallèle par une autre équipe. Nous avons montré que les spectres cliniques des déficits en LRBA et CTLA-4, fortement chevauchant dans les premières descriptions publiées, pourraient se différencier, malgré l'implication des lymphocytes T régulateurs dans ces 2 maladies. (...) / Evans syndrome is defined by the occurence of autoimmune cytopenias, either at the same time or sequential, mainly autoimmune hemolytic anemia and immune thrombocytopenia. In children, it may be secondary to infections, systemic autoimmune disease, or primary immune deficiency, though in most patients, its etiology isn't obvious. Patients affected with Evans syndrome can also present other features, such as autoimmunity toward a particular organ, benign lymphoproliferation or immunodeficiency. The main goal of this work was to identify genetic causes in children presenting an Evans syndrome without a known underlying etiology. We focused our study on severe, early onset forms of the disease, with the hypothesis that a monogenic disease would be more frequent in this group of patients. Taking advantage of high throughput "Next Generation" sequencing (NGS) techniques, we sequenced and analyzed exome from patients and their relatives in search for adequate candidate genes. We identified 4 candidate genes: LRBA, CTLA-4, STAT3 (gain-of-function mutations), and NFKBA. Implication of the first 3 genes in new monogenic diseases with autoimmunity as a key feature was also confirmed by others during the course of this work. For each gene, we pursued 2 complementary goals: First, we sought to validate the implication of the gene in the patients' disease. To do so, we used various techniques and approaches: biochemistry and proteomics to identify protein partners, confocal microscopy to localize proteins and interactions, in vitro cellular assays to bring to light functional defect, flow cytometry to identify changes in lymphocytes subpopulations. We also looked for other mutations of each gene in patients with a similar clinical presentation. Hence we created and explored 3 cohorts of patients presenting with mutations of LRBA, CTLA-4 or STAT3. We constituted a cohort of 18 patients with LRBA mutations within 11 families. We then were able to precise and extend the clinical spectrum of this recently described disease. In particular, we observed patients with severe chronic arthritis associated with diabetes mellitus or enteropathies. We identified 15 new mutations of autosomal recessive transmission in the LRBA gene, coding a protein of unknown function, which absence is responsible for a disease mainly characterized by autoimmune features. We identified 29 candidate protein partners of LRBA and precized LRBA localisation in cell compartiments. We also established a cohort of 12 patients within 10 families presenting CTLA-4 haploinsufficiency. Beyond describing 9 new mutations, we report a family with autosomal recessive transmission.In LRBA and CTLA-4 deficiencies, we showed a decrease of regulatory T lymphocyte subset proportion among PBMC and a decrease of CTLA-4 expression in activated T cells. These results support the interaction between these 2 proteins, described concurrently by another team. We showed that the clinical spectra of these 2 diseases, although widely overlapping in first published reports, could be different despite a role of regulatory T cells in both. Hence, organ-specific autoimmunity and lymphoproliferation are more frequent in LRBA deficiency whereas granuloma and hypogammaglobulinemia are more present in CTLA-4 deficiency. Theses results suggests a role of genetic modifyers, which remain to identify. Among our cohort of patients with Evans syndrome, we also identified 5 patients within 5 families presenting gain-of-function mutations of STAT3. 3 of those mutations were reported by others during our work and appeared de novo in our patients. Functional validation of the 4th one is in progress. The last mutation follows a recessive transmission and could exemplify a new transmission modality of this disease. (...)

Syndrome d'Evans

Anémie hémolytique auto-immune

Purpura thrombopénique immunologique

Auto-immunité

Maladie génétique

Séquençage de l'exome

LRBA

CTLA-4

STAT3 gain de fonction

Lymphocytes T régulateurs

Pédiatrie

Déficit immunitaire

Evans syndrome

Autoimmune hemolytic anemia

Immune thrombocytopenia

Autoimmunity

Genetic disease

Exome sequencing

LRBA

CTLA-4

STAT3 gain-of-function

Regulatory T lymphocytes

Pediatrics

Immune deficiency

571.96