Global ETD Search

151	Cav1.2 pore structure using the substituted-cysteine accessibility method / Breeze, Liam J. January 2006 (has links) Thesis (Ph.D. in Neuroscience) -- University of Colorado at Denver and Health Sciences Center, 2006. / Typescript. Includes bibliographical references (leaves 108-118). Free to UCD Anschutz Medical Campus. Online version available via ProQuest Digital Dissertations;
152	Drift-Diffusion Simulation of the Ephaptic Effect in the Triad Synapse of the Retina January 2013 (has links) abstract: A general continuum model for simulating the flow of ions in the salt baths that surround and fill excitable neurons is developed and presented. The ion densities and electric potential are computed using the drift-diffusion equations. In addition, a detailed model is given for handling the electrical dynamics on interior membrane boundaries, including a model for ion channels in the membranes that facilitate the transfer of ions in and out of cells. The model is applied to the triad synapse found in the outer plexiform layer of the retina in most species. Experimental evidence suggests the existence of a negative feedback pathway between horizontal cells and cone photoreceptors that modulates the flow of calcium ions into the synaptic terminals of cones. However, the underlying mechanism for this feedback is controversial and there are currently three competing hypotheses: the ephaptic hypothesis, the pH hypothesis and the GABA hypothesis. The goal of this work is to test some features of the ephaptic hypothesis using detailed simulations that employ rigorous numerical methods. The model is first applied in a simple rectangular geometry to demonstrate the effects of feedback for different extracellular gap widths. The model is then applied to a more complex and realistic geometry to demonstrate the existence of strictly electrical feedback, as predicted by the ephaptic hypothesis. Lastly, the effects of electrical feedback in regards to the behavior of the bipolar cell membrane potential is explored. Figures for the ion densities and electric potential are presented to verify key features of the model. The computed steady state IV curves for several cases are presented, which can be compared to experimental data. The results provide convincing evidence in favor of the ephaptic hypothesis since the existence of feedback that is strictly electrical in nature is shown, without any dependence on pH effects or chemical transmitters. / Dissertation/Thesis / Ph.D. Applied Mathematics 2013 Applied mathematics Neurosciences Cellular biology calcium channels current density drift-diffusion ephaptic effect particle density triad synapse
153	Rôle des canaux calciques Cav3.2 dans les interneurones de la lamina II de la moelle épinière / Role of calcium channels Cav3.2 in the spinal cord lamina II interneurons Candelas, Miriam 12 October 2017 (has links) La douleur est un mécanisme essentiel pour la survie, mais les douleurs chroniques sont souvent invalidantes. Les douleurs de longue durée sont une des premières causes de consultation médicale, et affectent 20% de la population. Par contre, les traitements actuels sont souvent inefficaces au long cours, avec un ratio bénéfice/risque faible. Il est ainsi une priorité majeure la recherche des nouveaux agents thérapeutiques. Pour ce faire, la compréhension de réseaux impliqués dans la douleur est essentielle.Plusieurs études ont montré que Cav3.2, un canal calcique à bas seuil, pourrait être une cible analgésique prometteuse. En fait, Cav3.2 est exprimé tout le long de voies douloureuses, au niveau périphérique ainsi qu’au niveau central. Notamment, Cav3.2 est fortement exprimé dans la corne dorsale de la moelle épinière, qui constitue le premier relai d’intégration de l’information douloureuse. De plus, grâce à son activation aux potentiels proche du repos, Cav3.2 est bien placé pour réguler l’excitabilité neuronale et l’intégration synaptique. Au cours de cette thèse nous avons étudié la distribution de ce canal dans les interneurones de la lamina II de la corne dorsale. Nos résultats montrent que le canal est exprimé dans différentes types d’interneurones (~60%), majoritairement excitateurs, mais aussi inhibiteurs. De façon intéressante, tous les neurones PKCγ, impliqués dans l’allodynie mécanique, expriment le canal Cav3.2. Nous avons ensuite utilisé une approche virale pour marquer et étudier les propriétés électrophysiologiques des neurones exprimant Cav3.2, ainsi que pour réprimer de façon spécifiques le canal dans la partie lombaire de la moelle épinière. Nos résultats montrent que Cav3.2 participe dans les rebonds dépolarisants sous-liminaires, dans les propriétés des potentiels d’action et dans les profils d’activité électrique de ces neurones. Ainsi, Cav3.2 pourrait jouer un rôle important dans les états douloureux au niveau spinal, caractérisés par des changements dans l’excitabilité. / Acute pain is essential for survival, but chronic pain is often invalidating. Prolonged pain states are one of the first causes of medical consultation, and they are experienced by as much as 20% of the population. However, our current analgesics are not fully reliable in alleviating chronic pains, with low beneficial/risk ratio. Thus, finding new pharmacological agents are a primordial objective. A better understanding of pain networks is necessary.Several studies have suggested that the T-type calcium channel, Cav3.2, might be a promising target for analgesics. Indeed, Cav3.2 is expressed all along pain pathways, both within the peripheral nociceptive track and within the central nervous system. Interestingly, Cav3.2 is strongly express in the dorsal horn of the spinal cord, which is the first relay for pain processing. Furthermore, thanks to their activation near resting potentials, Cav3.2 channels fit well in regulating neuronal excitability and synaptic integration.In this thesis, we have analyzed Cav3.2 expression in dorsal horn interneurons. Our results show that Cav3.2 is expressed in different types of interneurons (~60%), mostly excitatory, but also inhibitory. Interestingly, all PKCγ neurons, involved in mechanical allodynia, expressed Cav3.2. We then used a viral approach to label and study electrophysiological properties of Cav3.2-expressing neurons, and also to specifically delete this channel in the lumbar spinal cord. Our results show that Cav3.2 is involved in subthreshold depolarizations, in the properties of the action potentials and in the firing patterns of these neurons. Thus, Cav3.2 might play an important role in pain states at the spinal cord level, characterized by neuronal excitability alterations. Canaux calciques à bas seuil Cav3.2 Lamina II Moelle épinière Douleur Low threshold calcium channels Cav3.2 Lamina II Spinal cord Pain
154	Identification d'un nouveau bloqueur peptidique spécifique du canal sodique Nav1.7 avec des propriétés analgésiques / Identification of a novel peptidic specific blocker of Nav1.7 sodium channel subtype with analgesic properties Lesport, Pierre 07 April 2017 (has links) Les canaux calciques de type T Cav3.2 sont des régulateurs clés des fonctions sensorielles, et de fait sont également des cibles intéressantes pour le développement de nouveaux composés analgésiques pour le traitement et le management de la douleur. Malgré de récentes avancées dans l’identification de petites molécules organiques ciblant la famille des canaux Cav3.x/Type T, il reste encore à identifier un inhibiteur spécifique de Cav3.2. Le venin d’araignées contient une large diversité de neurotoxines incluant des modificateurs de gating des canaux calciques. En utilisant des canaux calciques recombinants, nous avons procédé à un criblage d’une bibliothèque de venins et avons identifié un nouveau peptide de 28 acides aminés (Psp3Tx1). La forme synthétique de ce peptide a été utilisé pour déterminer son profil de selectivité sur un panel de membres proches de la famille des canaux calciques (Cav) et sodiques (Nav) dépendants du voltage. Le peptide est sélectif pour le canal Nav1.7 (une cible largement validée dans le contexte des pathologies de la douleur) avec un effet complémentaire sur Cav3.2 à de fortes doses. In vivo chez la souris, le peptide possède des propriétés analgésiques avec des effets anti-hyperalgésiques et anti-allodyniques dans un contexte de douleur neuropathique. Ce peptide possède également un pouvoir analgésique dans un contexte de douleur spontanée induit par un agoniste des canaux Nav1.7. Les résultats présentés dans cette thèse sont encourageants pour la mise en place d’un projet amenant Psp3Tx1 au niveau clinique. / The T-type calcium channel Cav3.2 emerges as a key regulator of sensory functions, and therefore is an interesting drug target to develop innovative analgesic compounds for improved chronic pain management. Despite recent advances in the identification of small organic molecules targeting the Cav3.x/T-type calcium channel family, to date specific Cav3.2 inhibitors remains to be identified. Spider venoms proved to contain a large diversity of neurotoxins including gating modifiers of calcium channels. Using recombinant Cav3.2 channels, we performed a screening of a Tarantula venom library and identified a new 28 amino acid peptide (Psp3Tx1). The synthetic form of the peptide was used to determine its selectivity profile over a panel of closely related members of the voltage gated calcium (Cav) and sodium (Nav) channels. The peptide proved to be selective for the Nav1.7 channel (largely validated target in the context of pain pathologies) with an additional effect on Cav3.2 at more elevated doses. In vivo in mice, the peptide demonstrated to be an efficient analgesic molecule with anti hyperalgesic and antiallodynic properties in the context of neuropathic pain. This peptide also possess analgesic properties in a context of spontaneous pain induced by a Nav1.7 agonist. The results presented in this thesis are encouraging for the setup of a project taking Psp3Tx1 into clinical tests. Canaux calciques Système nerveux périphérique Douleur Canaux sodiques Toxines Calcium channels Peripheral nervous system Pain Sodium channels Toxins
155	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
156	Study of pharmacological and physiological factors regulating store operated calcium channels in a neuronal cell line Bose, Diptiman Dipen 01 January 2006 (has links) (PDF) Generation of Ca 2+ signals in cells involves regulation by multiple components controlling Ca 2+ release from the internal stores, Ca 2+ influx across the plasma membrane (PM), elicitation of Ca 2+ sensitive processes and finally the removal of Ca 2+ from the cell. One such mode of facilitating Ca 2+ entry is called store-operated Ca 2+ entry (SOCE) mediated by the store operated Ca 2+ channels (SOCs). SOCE, wherein the depletion of internal Ca 2+ stores triggers the influx of Ca 2+ across the PM, not only plays a vital role in refilling the Ca 2+ stores, but also regulates a multitude of downstream Ca 2+ regulated signalling events. Despite recent advances in elucidating the entry pathway, its molecular identity, biophysical properties and store-depletion signal remains undefined. The most potent inducer of SOCE, thapsigargin (TG), fails to induce Ca 2+ influx in the NG115-401L (401L) cells. This unusual phenotype of the cell makes it a useful model to study the mechanisms and components underlying the SOCE pathway. Although TG failed to induce SOCE in the 401L cells, we report that the activation of intracellular release channels such as the inositol-1,4,5-trisphosphate (fP3Rs) and ryanodine receptors (RyRs) were able to activate Ca 2+ influx upon store depletion. This is in keeping with mechanisms proposed to explain SOCE, namely the conformational coupling hypothesis, wherein depletion of the ER stores signals the release channels to physically interact with the PM SOCs. We found that disrupting the communication between the ER and the PM channels induced by actin disassembly affected both Ca 2+ release and influx. Our study shows that Ca 2+ release and influx is dependent on cortical actin organization and that the RyR mediated release is less regulated by cortical actin than the IP3R induced Ca 2+ release. Studies conducted using 2-aminoethoxy diphenylborate (2-APB), a commonly used SOC blocker, revealed that 2-APB stimulated Ca 2+ release in the 401L cells. This release of Ca 2+ was also found to be dependent on the conformational coupling between the ER and PM SOCs. We also studied the effect of overexpressing various isoforms of the transient receptor potential (TRP) channels. We found that protein kinase C (PKC) differentially regulated the activity of the TRP channels in the 401L cells. PKC activation prolonged the Ca 2+ influx in the wild type cells while attenuating the same in the TRP transfected cells. We also found that influx of surrogate cations (Ba 2+ ) is augmented in the TRPC transfected cells. Our studies reveal that the activation of ER release channels followed by conformational coupling with the PM channels may be a mechanism by which the 401L cells or neurons in general maintain a rigid control over intracellular Ca 2+ concentrations and thus regulate Ca 2+ homeostasis. Pharmacology Health and environmental sciences Actin Calcium channels Inositol-1 4 5-trisphosphate Neuronal cell Pharmacological Ryanodine Pharmacy and Pharmaceutical Sciences
157	Regulation of Neuronal L-type Voltage-Gated Calcium Channels by Flurazepam and Other Positive Allosteric GABA<sub>A</sub> Receptor Modulators Earl, Damien E. 31 August 2011 (has links) No description available. Neurosciences CNS depressants benzodiazepines GABA receptor recombinant calcium channels CaMKII electrophysiology electron microscopy neuronal plasticity Western blot Cav1.2 Cav1.3 hippocampus
158	Synthèse, évaluation biologique et structurale d'analogues cyclopeptidiques de l'ω-agatoxine IVB : etude des canaux calciques CaV2.1 et des conséquences de leur déficience (canalopathies) / Synthesis, biological and structural evaluation of cyclopeptidic analogues of ω-agatoxin IVB : study of calcium channels CaV2.1 and the consequences of their déficiencies (channelopathies) Pringos, Emilie 16 December 2010 (has links) Ce manuscrit décrit la synthèse et l'évaluation biologique d'analogues de l'ω-agatoxine IVB dans le but de trouver de nouveaux outils pour l'étude de l'activité des canaux calciques. L'ω-agatoxine IVB est une neurotoxine peptidique isolée du venin d'araignée Agelenopsis aperta qui à ce jour est l'inhibiteur spécifique et sélectif des canaux calciques voltage-dépendants de type P/Q. Ces canaux sont impliqués dans la neurotransmission dépendante du Glutamate dans le système nerveux central. La synthèse de structures peptidiques simplifiées, en comparaison avec celle de la toxine native est décrite. La méthodologie de synthèse de différents analogues cycliques de cette neurotoxine est présentée. Les composés sont synthétisés par synthèse peptidique sur phase solide en stratégie Fmoc, avec une étude particulière sur les conditions de cyclisation et le choix des groupements protecteurs appropriés. Les modifications d es peptides naturels pour obtenir de nouveaux composés biologiquement actifs incluent l'insertion d'aminoacides non naturels et de liaisons pseudopeptidiques. Les analogues synthétisés ont été testés par des méthodes d'électrophysiologie (patch clamp) et d'imagerie calcium ; les activités biologiques des peptides sont corrélées à l'aide d'analyses structurales par RMN et modélisation moléculaire. / This manuscript describes the synthesis and biological valuation of w-agatoxin IVB mimetics with the intention of finding new tools for the study of calcium channels activity. w-Agatoxin IVB is a peptide neurotoxin isolated from the venom of spider Agelenopsis aperta which is a specific and selective inhibitor of P/Q-type voltage-dependent calcium channels. These channels are involved in Glutamate-dependent neurotransmission in the central nervous system. The synthesis of structurally simplified peptides, in comparison with native toxin is described. The methodology of synthesis of different cyclic analogues of this neurotoxin is presented. The compounds were synthesized by solid phase peptide chemistry and Fmoc strategy, with particular consideration for cyclization conditions and an insight into selection of protecting groups. The modifications of the natural peptide to get new biologically active compounds included the insertion of unnatura l amino acids and pseudopeptides bonds. The synthesized analogues were tested by methods of electrophysiology (patch clamp) and calcium imagery; the biological activities of peptides are compared with the aid of structural analyses by RMN and molecular modeling. Agatoxines Canaux calciques Neurotoxine Neurophysiologie Peptides Agatoxins Calcium Channels Neurotoxins Neurophysiology Peptides Solid support synthesis Structure-Activity Relationship
159	Modulation de l’adressage membranaire et de la fonction du canal CaV2.3 par les résidus leucine du domaine guanylate kinase impliqués dans la liaison à forte affinité de CaVβ Shakeri, Behzad 09 1900 (has links) Les canaux Ca2+ activés par le voltage (CaV) sont des protéines membranaires qui génèrent des courants Ca2+ dans les cellules excitables suite à une dépolarisation membranaire. Ces complexes oligomériques sont classifiés selon les propriétés structurelles de la sous-unité principale qui forme le pore du canal, soit la sous-unité CaVα1. La sous-unité auxiliaire CaVβ module l’expression membranaire et la dépendance au voltage du « gating » de la sous-unité CaVα1 des canaux HVA (« high-voltage-activated ») CaV1 et CaV2. La sous-unité CaVβ est formée par un domaine SH3 (« Src homology-3 ») connecté à un domaine GK (« guanylate kinase-like ») par le biais d’un domaine variable HOOK. Dans le but d’identifier les résidus dans la CaVβ3 qui sont responsables de la densité membranaire du CaV2.3, nous avons produit des mutants de la sous-unité auxiliaire le long de ses domaines fonctionnels. Cela dit, la délétion complète du domaine SH3 ainsi que la délétion du domaine HOOK n’ont pas modifié la densité membranaire de CaV2.3 ni ses propriétés d’activation. Cependant, la délétion de cinq résidus dans le domaine GK interrompt l’expression membranaire et l’expression fonctionnelle de CaV2.3. La mutation de résidus identifiés précédemment comme soutenant une affinité de liaison de l’ordre du nanomolaire dans le domaine GK de CaVβ n’a pas modifié de manière significative l’adressage membranaire de CaV2.3. Toutefois, les mutations de quatre résidus leucine dans les régions α3, α6, β10 et α9 du domaine GK ont grandement réduit l’adressage membranaire du canal CaV2.3. Nos résultats confirment que le domaine GK contient les déterminants moléculaires responsables de la fonction chaperone de CaVβ. Cela dit, l’adressage membranaire induit par CaVβ semble être déterminé par des éléments structuraux qui ne sont pas strictement dépendants d’une liaison à haute affinité de CaVβ sur CaVα1. / Voltage-activated Ca2+ channels (CaV) are membrane proteins that play a key role in promoting Ca2+ influx in response to membrane depolarization in excitable cells. They form oligomeric complexes that are classified according to the structural properties of the pore-forming CaVα1 subunit. Auxiliary CaVβ subunits modulate cell-surface expression and voltage-dependent gating of high-voltage-activated (HVA) CaV1 and CaV2 α1 subunits. CaVβ subunits are formed by a Src homology-3 (SH3) domain and a guanylate kinase-like (GK) domain connected through a variable HOOK-domain. In order to identify the residues responsible for the CaVβ3-induced membrane density of CaV2.3, we produced mutants along CaVβ3’s fonctionnal domains. Complete deletion of the SH3 domain as well as deletion of the HOOK domain did not alter plasma membrane targeting of CaV2.3 nor its typical activation gating. In contrast, 5-residue deletions in the GK domain disrupted cell surface trafficking and functional expression of CaV2.3. Mutations of residues known to carry nanomolar affinity binding in the GK domain of CaVβ did not significantly alter cell surface density. Mutations of a quartet of leucine residues in the α3, α6, β10, and α9 regions of the GK domain, each expected to curtail protein-protein interaction, were found to significantly impair cell surface targeting of CaV2.3 channels. Altogether, our results confirm that the GK domain includes the molecular determinants carrying the chaperone function of CaVβ. However, CaVβ-induced cell surface targeting appears to be determined by structural elements that are not strictly dominated by high-affinity binding of CaVβ onto CaVα1. Canaux calciques Calcium channels Adressage membranaire Targeting Gating Modélisation par homologie Homology modeling Électrophysiologie Electrophysiology Cytométrie de flux Flow cytometry
160	Biochemical and functional characterisation of phospholipase C-η2 Popovics, Petra January 2013 (has links) Phospholipase C enzymes are important cell signalling enzymes that catalyse the cleavage of phosphatidylinositol 4,5-bisphophate PI(4,5)P₂ into two biologically active second messenger molecules. These are the inositol 1,4,5-trisphosphate which initiates Ca²⁺ release from the endoplasmic reticulum and the diacylglycerol that activates protein kinase C. Although this basic function is shared between the different isoforms, the PLC family encompasses a diverse collection of proteins with various domain structures in addition to the PLC-specific domains. The neuron-specific “6th family” of these enzymes, PLCηs have most recently been identified with two members, PLCη1 and PLCη2. The aim of the thesis is to characterise the PLCη2 variant from several aspects. Firstly, it describes that PLCη2 possesses a high sensitivity towards Ca²⁺. Secondly, it investigates how the Ca²⁺-induced enzymatic activity of PLCη2 is controlled by its different domains. Also it provides evidence that the pleckstrin homology domain targets PLCη2 to membranes by recognising PI(3,4,5)P₃. Moreover, the uniquely structured EF-hand is responsible for the Ca²⁺-sensitivity of the enzyme. Finally, it is demonstrated that the C2 domain is important for activity. The initial biochemical characterisation is followed by the description of a physiological role for PLCη2. It is shown using a neuroblast model that PLCη2 is crucial for neuronal differentiation and neurite growth. Further efforts were made to assess how PLCη2 is responsible for this effect. It was revealed that it might be involved in regulating intracellular Ca²⁺ dynamics, transcriptional activity and actin reorganisation in differentiating neurons. As the functions of PLCη2 are just beginning to come to light, more aspects for future research are also suggested in the thesis. Hopefully, this and the data presented within the thesis will stimulate even greater interest in this fascinating new field of research. 572

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