Global ETD Search

101	DIfférentes espèces d'acide phosphatidique : localisations subcellulaires et fonctions biologiques spécifiques / Different species of phosphatidic acid : specific subcellular localizations and biological functions Kassas, Nawal 11 February 2014 (has links) L’acide phosphatidique (PA) est un lipide simple qui peut exister sous différentes formes. A partir des sondes que j’ai préparé en se basant sur des domaines de liaison au PA : PDE4A1, Spo20p, et OpiQ2, j’ai pu étudier la localisation subcellulaire du PA dans les cellules PC12 et les macrophages RAW264.7. Ces sondes lient différents formes de PA dans les membranes de différents compartiments subcellulaires. De plus, j’ai pu montrer qu’il y a une néosynthèse de PA et de certaines espèces de PA mono- ou bi-insaturé à la membrane plasmique lors de la stimulation de l’exocytose. Nous avons ainsi observé que la PLD1 semble être la source principale de PA dans les glandes surrénales. D’autre part, mes travaux indiquent une augmentation du niveau global de PA à la membrane plasmique et une diminution importante du PA au niveau du RE dans les macrophages après stimulation de la phagocytose frustrée. Ce qui pourrait ainsi valider le concept d’une fusion d’une partie de la membrane du RE avec la membrane plasmique lors de la phagocytose. / The phosphatidic acid (PA) is a simple lipid which may exist in various forms. I have generated probes based on PA binding domains: PDE4A1, Spo20p and OpiQ2 to study the subcellular localization of PA in PC12 cells and RAW264.7 macrophages. These probes bind different form of PA in different subcellular compartments. In addition, I show that PA and certain species mono- or bi-unsaturated of PA are synthesized at the plasma membrane upon stimulation of exocytosis. We observed that the PLD1 seems to be the main source of PA in the adrenal glands. On the other hand, my research indicates an increase in the level of PA at the plasma membrane and a significant decrease in the ER in macrophages after stimulation of phagocytosis frustrated. Thus these results could validate the concept of a fusion of a portion of the ER membrane with the plasma membrane during phagocytosis. Acide phosphatidique Voies de synthèse PLD1 Sondes Localisations subcellulaires Exocytose Phagocytose Phosphatidic acid Synthesis PLD1 Probes Subcellular compartments Exocytosis Phagocytosis 572.4
102	Formation des sites d'exocytose dans les cellules chromaffines : importance fonctionnelle, régulation et externalisation de l'Annexine A2 / Formation of exocytotic sites in chromaffin cells : functional importance, regulation and externalization of Annexin A2 Gabel, Marion 09 September 2016 (has links) L’exocytose est un mécanisme biologique fondamental qui permet la libération du contenu des granules de sécrétion dans le milieu extracellulaire. C’est un processus finement régulé par le calcium qui nécessite entre autre, la réorganisation de la membrane plasmique et la formation de domaines lipidiques. Dans les cellules chromaffines, l’annexine A2, protéine capable de lier les phospholipides et l’actine de manière calcium-dépendante, est responsable de la formation et de la stabilisation de ces plateformes lipidiques. Le résultat majeur de ma thèse concerne l’organisation tridimensionnelle et le rôle de l’actine au niveau des sites d’exocytose. Sachant que la phosphorylation de la tyrosine 23 de l’annexine A2 affecte sa liaison à l’actine et aux membranes, deux acteurs majeurs de l’exocytose, j’ai mis en évidence l’importance fonctionnelle de cette phosphorylation. Une autre conséquence de cette phosphorylation est le passage de l’annexine A2 de la face interne à la face externe de la membrane plasmique. Le mécanisme de sortie et le rôle de l’annexine A2 extracellulaire dans les cellules chromaffines ont également été étudiés. / Exocytosis is a fundamental biological mechanism which allows liberation of the contents of secretory granules into the extracellular medium. This calcium-regulated process requires the formation of lipid domains for the structural and spatial organisation of exocytotic sites. In the chromaffin cell, annexine A2, a calcium-, actin- and lipid-binding protein participates in the formation and stabilization of lipid microdomains. The major advance resulting from my thesis is the elucidation of the three-dimensional organization and the role of actin at the exocytotic site. Phosphorylation of the tyrosine 23 is known to affect the binding of annexin A2 to actin filaments and plasma membrane, two major actors of the exocytotic process and my results highlight the functional importance of this phosphorylation on exocytosis. Furthermore, tyrosine 23 phosphorylation also triggers a translocation of annexin A2 to the external face of the plasma membrane. The role and functional signification of this externalization was also examined. Annexine A2 Exocytose Microdomaines lipidiques Actine Phosphorylation Externalisation Annexin A2 Exocytosis Lipid domains Actin Phosphorylation Externalization 571.6 572.4
103	Úloha vybraných podjednotek komplexu exocyst ve vývoji epidermis Arabidopsis. / Subunits of exocyst complex in the development of Arabidopsis epidermis Vojtíková, Zdeňka January 2013 (has links) Exocyst is protein complex evolutionary conserved in yeasts, animals and plants, which plays a role in control of cell morphogenesis and polarity. It is a tethering complex whose function is to attach secretory vesicles to specifi c foci on plasma membrane. Complex exocyst is formed by eight subunits. Subunit EXO70 is encoded by 23 paralogue genes in genome of Arabidopsis thaliana. Mutation in paralogue subunit EX070H4 causes defect in trichome maturation. Mutant trichomes have thin, not reinforced cell wall, making them soft and elastic. Transcription of EXO70H4 gene is induced by UV radiation, therefore observations of plants cultivated on UV-B radiation were done. Analysis of mutants cultivated on UV-B radiation revealed hyperaccumulation of vesicules in cytoplasm, which were visible by light microscope. Hyperaccumulation was not observed in control plants cultivated on UV-B radiation, but thickening of cell wall was induced. Th is reaction to UV in trichomes hasn't been described yet. Analysis of cellular localization made with YFP tagged constructs revealed that EXO70H4 localizes into mobile corpuscules associating with Golgi apparatus. It was found with yeast two hybrid system that EXO70H4 interacts with TRS120, subunit of tethering complex TRAPPII which is active in Golgi apparatus....
104	Role of Internal Calcium Stores in Exocytosis and Neurotransmission: A Dissertation Lefkowitz, Jason J. 11 May 2010 (has links) A central concept in the physiology of neurosecretion is that a rise in cytosolic [Ca2+] in the vicinity of plasmalemmal Ca2+ channels due to Ca2+ influx, elicits exocytosis. This dissertation examines the effect on both spontaneous and elicited exocytosis of a rise in focal cytosolic [Ca2+] in the vicinity of ryanodine receptors (RYRs) due to release from internal stores in the form of Ca2+ syntillas. Ca2+ syntillas are focal cytosolic transients mediated by RYRs, which we first found in hypothalamic magnocellular neuronal terminals. (Scintilla, Latin for spark, found in nerve terminals, normally synaptic structures.) We have also observed Ca2+ syntillas in mouse adrenal chromaffin cells (ACCs). Here the effect of Ca2+syntillas on exocytosis is examined in ACCs, which are widely used as model cells for the study of neurosecretion. Elicited exocytosis employs two sources of Ca2+, one due to influx from the cell exterior through voltage-gated Ca2+ channels (VGCCs) and another due to release from intracellular stores. To eliminate complications arising from Ca2+ influx, the first part of this dissertation examines spontaneous exocytosis where influx is not activated. We report that decreasing syntillas leads to an increase in spontaneous exocytosis measured amperometrically. Two independent lines of experimentation each lead to this conclusion. In one case release from stores was blocked by ryanodine; in another, stores were partially emptied using thapsigargin plus caffeine after which syntillas were decreased. We conclude that Ca2+syntillas act to inhibit spontaneous exocytosis, and we propose a simple model to account quantitatively for this action of syntillas. The second part of this dissertation examines the role of syntillas in elicited exocytosis whereby Ca2+ influx is activated by physiologically relevant levels of stimulation. Catecholamine and neuropeptide release from ACCs into the circulation is controlled by the sympathetic division of the Autonomic Nervous System. To ensure proper homeostasis tightly controlled exocytic mechanisms must exist both in resting conditions, where minimal output is desirable and under stress, where maximal, but not total release is necessary. It is thought that sympathetic discharge accomplishes this task by regulating the frequency of Ca2+ influx through VGCCs, which serves as a direct trigger for exocytosis. But our studies on spontaneous release in ACCs revealed the presence of Ca2+ syntillas, which had the opposite effect of inhibiting release. Therefore, assuming Ca2+-induced Ca2+ release (CICR) via RYRs due to Ca2+ influx through VGCCs, we are confronted with a contradiction. Sympathetic discharge should increase syntilla frequency and that in turn should decreaseexocytosis, a paradox. A simple “explanation” might be that the increase in syntillas would act as a brake to prevent an overly great exocytic release. But upon investigation of this question a different finding emerged. We examined the role of syntillas under varying levels of physiologic stimulation in ACCs using simulated action potentials (sAPs) designed to mimic native input at frequencies associated with stress, 15 Hz, and the basal sympathetic tone, 0.5 Hz. Surprisingly, we found that sAPs delivered at 15 Hz or 0.5 Hz were able to completely abolish Ca2+ syntillas within a time frame of two minutes. This was not expected. Further, a single sAP is all that was necessary to initiate suppression of syntillas. Syntillas remained inhibited after 0.5 Hz stimulation but were only temporarily suppressed (for 2 minutes) by 15 Hz stimulation, where global [Ca2+]i was raised to 1 – 2 μM. Thus we propose that CICR, if present in these cells, is overridden by other processes. Hence it appears that inhibition of syntillas by action potentials in ACCs is due to a new process which is the opposite of CICR. This process needs to be investigated, and that will be one of the very next steps in the future. Finally we conclude that syntilla suppression by action potentials is part of the mechanism for elicited exocytosis, resolving the paradox. In the last chapter speculation is discussed into the mechanisms by which physiologic input in the form of an action potential can inhibit Ca2+ syntillas and furthermore, how the Ca2+ syntilla can inhibit exocytic output. Calcium Channels Exocytosis Chromaffin Cells Neurosecretion Synaptic Transmission Biological Factors Cells Inorganic Chemicals Neuroscience and Neurobiology
105	Palmitoylation and Oxidation of the Cysteine Rich Region of SNAP-25 and their Effects on Protein Interactions Martinez, Derek Luberli 17 July 2007 (has links) (PDF) Neurons depend upon neurotransmitter release through regulated exocytosis to accomplish the immense processing performed within the central nervous system. The SNARE hypothesis points to a family of proteins that are thought to enable the membrane fusion that leads to exocytosis. The secondary structure of SNAP-25 is unique among SNARE proteins in that it has two alpha helical SNARE motifs and a cysteine rich (C85, C88, C90, C92) membrane interacting region but notransmembrane domain. The cysteines may be modified by palmitoylation or oxidation but the role of these modifications in vivo is not well understood. Our goal is to elucidate possible regulatory roles of SNAP-25 that relate to its unique structure and these reversible modifications. However, the study of SNAP-25 in reconstituted systems is hampered by a lack of readily available palmitoylated SNAP-25. A method for in vitro palmitoylation of SNAP-25 by HIP14, a neuronal acyltransferase, is described along with the application of a biotinylation streptavidin assay to verify palmitoylation. Palmitoylation increases the extent to which SNAP-25 interacts with lipids as observed with an environment sensitive trpytophan fluorescence assay. Palmitoylation also alters the phase transition of DPPC lipids differently than unpalmitoylated SNAP-25.This effect on the membrane may influence fusion events. Oxidation of the cysteine residues may be responsible for the sensitivity of SNAP-25 to reactive oxygen species. Our data suggests that, when oxidized, SNAP-25 does not interact with membranes to the same extent as palmitoylated SNAP-25. This may provide a mechanism for reducing exocytosis during oxidative stress. Also, oxidized SNAP-25 is not susceptible to Botulinum Neurotoxin E. The effects of oxidation and palmitoylation on the protein interactions of SNAP-25 may shed light on its role in the SNARE complex and membrane fusion. SNAP-25 palmitoylation SNARE N-Ethylmaleimide biotin exocytosis membrane fusion Botulinum Neurotoxin differential scanning calorimetry tryptophan fluorescence oxidation Neuroscience and Neurobiology
106	Contribution of Purinergic Receptors to Calcium Signaling in Salivary Gland Bhattacharya, Sumit January 2012 (has links) No description available. Biology Neurobiology Neurology Neurosciences Pharmacology Physiology ATP purinergic exocytosis calcium p2x4 p2x7 saliva parotid acinar cells cAMP
107	Exploration du rôle des différents domaines C2 de l'otoferline et des isoformes des canaux calciques CaV1.3 dans la transmission synaptique des cellules ciliées auditives / Exploring the role of the various C2 domains of otoferlin and isoforms of calcium channels CaV1.3 in synaptic transmission of auditory hair cells Tertrais, Margot 19 December 2018 (has links) L'encodage du signal acoustique en impulsions nerveuses se réalise au niveau des synapses à ruban des cellules ciliées internes (CCI) de la cochlée. Une dépolarisation déclenche l'exocytose des vésicules synaptiques suite à l'activation des canaux calciques CaV1.3 et à l'action d'un senseur calcique particulier, l'otoferline, une grande protéine se composant d'un domaine transmembranaire en C-terminal et de six domaines C2 (A-F) pouvant lier le Ca2+ et les phospholipides. Afin de caractériser le rôle de ces différents domaines C2, nous avons utilisé des vecteurs viraux (AAV) permettant l'expression de formes raccourcies de l'otoferline (mini-Otof) in vivo dans les CCI de souris dépourvues d'otoferline (Otof -/-). Nous montrons que les mini-Otof contenant les domaines C2-EF, C2-DEF ou C2-ACEF sont suffisantes pour restaurer l'exocytose rapide des CCI Otof -/-, sans toutefois restaurer l'audition car le recrutement des vésicules synaptiques reste altéré. Nous révélons pour la première fois la présence d'une endocytose ultra-rapide (t < 20 ms) dynamine- et otoferline-dépendante, une fonction certainement essentielle à l'homéostasie membranaire des CCI. L'expression des mini-Otof C2-EF et C2-DEF a également permis de restaurer partiellement la composante rapide de l'inactivation du courant calcique des CCI, celle-ci étant absente chez les souris Otof -/-. Cette inactivation rapide est réalisée par les isoformes courtes Cav1.3S qui ont leur partie C-terminale régulatrice tronquée, contrairement aux isoformes longues Cav1.3L dépourvues d'inactivation. Afin de différencier les rôles spécifiques de ces isoformes dans le cycle des vésicules synaptiques, nous avons utilisé la technologie CRISPR-Cas9, nous permettant d'éditer spécifiquement la partie C-terminale régulatrice des canaux Cav1.3L. Nos résultats montrent que les souris CRISPR-Cav1.3L présentent une surdité sévère expliquée au niveau des CCI par un défaut de recrutement vésiculaire aux zones actives, alors que les Cav1.3S inaltérés contrôlent la fusion rapide des vésicules synaptiques. / The precise encoding of acoustic signals into nerve impulses is achieved at the ribbon synapses of inner hair cells (IHC) of the cochlea. Exocytosis of synaptic vesicles by IHC is triggered by voltage-activation of Cav1.3 calcium channels and the action of a specific calcium sensor, otoferlin, a large protein with a single C-terminal transmembrane domain and six C2 (A-F) domains which binds Ca2+ and interacts with phospholipids. In order to characterize the function of the various otoferlin C2 domains, we used viral vectors (AAV) allowing the expression of shortened forms of otoferlin (mini-Otof), in vivo, in IHC from mice lacking otoferlin (Otof -/-). We show that mini-Otof containing C2-EF, C2-DEF or C2-ACEF domains are sufficient to restore fast synaptic vesicle exocytosis in Otof -/- IHC, but without restoring hearing because vesicular replenishment remains impaired. For the first time, we also uncover an ultra-fast endocytosis (t < 20 ms) dynamin- and otoferlin-dependant, a function that is certainly essential for a fast regulation of IHC membrane homeostasis. Furthermore, the expression of the mini-Otof C2-EF and C2-DEF also partially restored the fast component of the Ca2+ current inactivation in Otof -/- IHC. This rapid inactivation is carried out by Cav1.3S short isoforms which have a truncated C-terminal regulatory domain, unlike Cav1.3L long isoforms which display no inactivation. To characterize the specific role of these Cav1.3 isoforms, we used CRISPR-Cas9 technology, allowing a specific removal of the C-terminal regulatory part of the Cav1.3L channels in IHC. Our results show that CRSIPR- Cav1.3L mice display severe deafness explained at the IHC level by a defect in vesicular replenishment of the active zones, while Cav1.3S are sufficient to ensure fast and transient exocytosis of docked synaptic vesicles. Cellules ciliées internes Otoferline Exocytose-Endocytose Canaux calciques Cav1.3 Aav CRISPR-Cas9 Inner hair cells Otoferlin Exocytosis-Endocytosis Calcium channels Cav1.3 Aav CRISPR-Cas9
108	Estudo do envolvimento da neuraminidase 1 no processo de autofagia na musculatura esquelética / Larina Neto R. Neuraminidase 1 involvement in the autophagy process in the skeletal muscles Larina Neto, Rubens de 18 July 2019 (has links) INTRODUÇÃO:A neuraminidase 1 (chamada a seguir por Neu1) regula o catabolismo de sialoglicoconjugados nos lisossomos. A deficiência congênita da Neu1 é a base da sialidose, doença neurossomática grave associada a deformidades osteoesqueléticas, hipotonia e fraqueza muscular. Camundongos com deficiência de Neu1 desenvolvem uma forma atípica de degeneração muscular caracterizada porproliferação anormal de fibroblastoslevando a invasão nas fibras musculares, expansão da matriz extracelular (MEC), fragmentação do citoplasma, formação vacuolar e atrofia muscular. A ocorrência de atrofia muscular indica que a deficiência da Neu1 podeestar relacionada com o controle da massa muscular, a qual é dependente do equilíbrio entre síntese e degradação proteica.Uma característica principalnaMacroautofagia (denominada a seguir por autofagia) é a principal via de degradação intracelular sendo expressamente essencial para a homeostase celular e remoção de materiais citoplasmáticos. Objetivos: Avaliarseos efeitos da deficiência da Neuraminidase 1 afetama indução de autofagia e a formação de autofagossomos e determinar os efeitos do bloqueio da função lisossomal sobre o fenótipo muscular na deficiência da Neuraminidase1.Metodologia:Camundongos Neu1+/-foram cruzados e os filhotes genotipados, onde camundongos Neu1-/-(nocaute) e Neu1+/+(normal),foram utilizados no estudon total=90, sendo 10 em padronizações, 20 para coleta de fibroblastos e 60 para procedimentos in vivo, os grupos experimentais foram divididos em privação alimentar por 2 dias que, por meio da inibição do mTOR, induz a autofagia;grupo detratamento com Colchicina por 4 dias onde irá impedir a junção autofagossomo/lisossomonão havendo a degradaçãolisossomaleadicionado nos dois últimos dias de privação alimentar e o grupo de tratamento comRapamicina por 7 dias, droga com função de inibir seletivamente o mTOR.Após os tratamentos, os animais foram eutanasiadospara coleta dos músculos gastrocnêmios e tibiais anterior. Os músculos foram analisados apósas coloraçõeshistológicas porHematoxilina & Eosina e Fosfatase Ácida; Imunofluorescência de LC3-I/II; Western Blottingdas proteínas LC3-I/II, Lamp-1 e p62/SQSTM e a análise Ultra-estrutural. Além disso, foi realizada cultura de fibroblastos, os quais foram submetidos à privação de nutrientes e ao tratamento com Rapamicina, seguidos dasmesmas metodologias de análise invivo. Resultados:As análises histológicas através de H&E e Fosfatase Ácida não revelaram alterações consistentes na musculatura esquelética de animais submetidos aos tratamentos, mostrando em animais com deficiência de Neu1 um aumento anormal do espaço endomisial, e aumento da atividade lisossomalintracitoplasmáticos. Na análise ultra-estruturalobservou-se em todos os grupos, a presença de diversas estruturas com aspecto autofágico, de diferentes tamanhos, formas e constituintes. Naanálise da expressão do LC3 através de Western Blottingmostrou importante ativação do LC3-II na privação alimentar (com e sem administração de Colchicina) tanto em animais controles quanto em animais com deficiência de Neu1 e uma importante ativação do LC3-I em Rapamicina em ambos os grupos mostrando assim que houve um aumento da via da autofagia através do bloqueio do mTOR. Já na análise de Imunofluorescência não foi possível observar diferença consistenteentre os grupos.A análise in vitrode Western Blottingmostrou que tal ativação foi similar entre fibroblastos Neu1+/+e Neu1-/-. Conclusão:Os experimentos relacionados com a ativação ou inibição da autofagia, não resultaram em diferenças consideráveis entre músculos normais e músculos com deficiência de Neu1. Desta forma, podemos concluir com estes experimentos que aparentemente a Neu1, apesar de ser uma importante enzima lisossomal, não interfere com o processo de autofagia / Introduction:Neuraminidase 1 (hereinafter Neu1) regulates the catabolism of sialoglycoconjugates in lysosomes. The congenital deficiency of Neu1 is the basis of sialidosis, a severe neurosomatic disease associated with osteo-skeletal deformities, hypotonia, and muscle weakness. Mice with Neu1deficient develop an atypical form of muscle degeneration characterized by abnormal fibroblast proliferation leading to muscle fiber invasion, extracellular matrix expansion (ECM), cytoplasm fragmentation, vacuolar formation, and muscle atrophy. The occurrence of muscle atrophy indicates that deficiencyofNeu1 may be related to the control of muscle mass, which is dependent on the balance between synthesis and protein degradation. A major feature in Macroautophagy (hereinafter referred to as autophagy) is the main pathway of intracellular degradation being expressly essential for cellular homeostasis and removal of cytoplasmic materials. Objectives:To evaluate whether the effects of neuraminidase 1 deficiency affect autophagy induction and autophagosome formation and to determine the effects of lysosomal function block on muscle phenotype in neuraminidase 1 deficiency. Methodos:Mice Neu1+/-were crossbred and the genotyped pups, where mice Neu1-/-(knockout) and Neu1+/+(normal), were used in the study ntotal = 90, 10 for standardization, 20 for fibroblast collection and 60 for in vivo procedures, experimental groups were divided into food deprivation for 2 days that, through mTOR inhibition, induces autophagy; Colchicine treatment group for 4 days whereit will prevent autophagosome/lysosome junction without lysosomal degradation and added in the last two days of food deprivation and Rapamycin treatment group for 7 days, drug with function to selectively inhibit mTOR. After the treatments, the animals were euthanized to collect the anterior gastrocnemius and tibial muscles. The muscles were analyzed after histological staining by Hematoxylin & Eosin and Acid Phosphatase; LC3-I/II immunofluorescence; Western Blottingof LC3-I/II, Lamp-1 and p62/SQSTM proteins and Ultra-structural analysis. In addition, fibroblasts were cultured and subjected to nutrient deprivation and Rapamycin treatment, followed by the same in vivo analysis methodologies. Results:Histological analyzes by H&E and Acid Phosphatase did notreveal consistent changes in skeletal muscle of animals submitted to treatments, showing in animals with Neu1 deficiency an abnormal increase in endomysial space and increased intracytoplasmic lysosomal activity.In ultrastructural analysis, it was observed in all groups, the presence of several structures with autophagic aspect, of different sizes, shapes and constituents. The analysis of LC3 expression by Western Blottingshowed important activation of LC3-II in food deprivation (with and without Colchicine administration) in both control and Neu1 deficient animals and an important activation of LC3-I in Rapamycininboth groups,thus showing an increase in the autophagy pathway through mTOR blockade. In the immunofluorescence analysis, it was not possible to observe consistent difference between the groups. In vitro Western Blottinganalysis showed that such activation was similar between Neu1+/+and Neu1-/-fibroblasts. Conclusion: Experiments related to activation or inhibition of autophagy did not result in considerable differencesbetween normal muscles and Neu1 deficient muscles. Thus, we can conclude from these experiments that apparently Neu1, despite being an important lysosomal enzyme, does not interfere with the autophagy process Atrofia muscular Autofagia Autophagy Colchicina Colchicine Exocitose lisossomal Food deprivation Lysosomal exocytosis Mucolipidases Mucolipidoses Muscular atrophy Neuraminidase Neuraminidase Privação de alimentos Sialidase Sialidosis Sirolimo Sirolimus
109	SNAREs in evoked and spontaneous neurotransmission / SNAREs in evozierter und spontaner Neurotransmission Weber, Jens P. 16 October 2009 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science 42 Biologie W
110	Biochemistry and physiological role of otoferlin / Biochemie und physiologische Funktion von Otoferlin Reuter, Kirsten 10 October 2011 (has links) No description available. 000 Allgemeines, Wissenschaft Biology (incl. Psychology) Otoferlin C2 Domänen Ca2+ Sensor Exozytose pHluorin Otoferlin C2 Domain Ca2+ sensor exocytosis pHluorin 42.3 W

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