Global ETD Search

251	Développement du réseau locomoteur spinal au cours de la métamorphose de l'amphibien Xenopus laevis : coordinations propriospinales, influences vestibulaires et commande mésencéphalique Beyeler, Anna 11 December 2009 (has links) Au cours de la métamorphose, les amphibiens subissent une réorganisation complète de leur anatomie et de leur physiologie. Chez Xenopus laevis le système locomoteur est un des plus affecté au cours de cette phase développementale, l’animal passant d’une nage ondulatoire à une nage appendiculaire. Cette transformation du mode locomoteur implique une réorganisation du réseau locomoteur central. Dans une première étude, nous avons mis en évidence que les muscles axiaux s’activent de manière bilatéralement alternée chez le têtard alors que les muscles équivalents chez l’adulte s’activent de manière synchrone au cours de la nage. Nous avons montré que ce nouveau patron d’activation musculaire, accompagné d’une synchronisation avec les muscles appendiculaires extenseurs, reposent principalement sur la mise en place de nouvelles projections propriospinales lombo-thoraciques. Ces résultats suggèrent l’existence d’un contrôle postural proactif au cours de la locomotion, reposant directement sur le CPG des membres postérieurs. Dans une deuxième étude, nous nous sommes intéressés à l’influence d’un déséquilibre des afférences vestibulaires sur le développement du réseau locomoteur spinal au cours de la métamorphose. Pour cela nous avons réalisé une suppression unilatérale des organes vestibulaires avant ou après la métamorphose. Dans les deux cas, cette lésion aigue génère d’importants troubles locomoteurs et posturaux. Nous avons montré que la lésion chronique au cours de la métamorphose entraîne une modification ipsi-lésionnelle du développement du réseau locomoteur lombo-thoracique, de manière concomitante à une compensation comportementale. De façon intéressante, cette plasticité développementale ainsi que la compensation des troubles locomoteurs sont absentes chez les animaux lésés au stade adulte. Ces résultats suggèrent que les informations sensorielles sont un facteur déterminant pour le développement du réseau locomoteur spinal. Enfin, dans une troisième étude, nous avons analysé le développement du réseau locomoteur supra-spinal et en particulier les propriétés de déclenchement et de contrôle de la région locomotrice mésencéphalique (MLR). Nous avons mis en évidence l’existence fonctionnelle des deux noyaux de cette structure, le noyau pédonculopontin (PPN) et le noyau latérodorsal du tegmentum (LDT) tout au long de la métamorphose du xénope, ainsi qu’une fréquence d’activation optimale de 10-20 Hz pour le PPN. / Throughout the course of metamorphosis, amphibians undergo a complete anatomical and physiological reorganization. In Xenopus laevis, the locomotor system is one of the most affected during this developmental phase where the animal passes from undulatory swimming to limb-based propulsion. This transformation implies a parallel reorganization of the central locomotor network. In an initial study we showed that axial muscles which are activated in bilateral alternation in tadpoles mature to dorsal muscles that are synchronously active during adult locomotion. We found that this new pattern, accompanied by coordination of dorsal and hindlimb muscle activities, is principally sustained by the development of new propriospinal lumbo-thoracic projections, suggesting proactive postural control coming from the hindlimb CPG during ongoing locomotion. In a second study, we examined the influence of disequilibrium in vestibular inputs on the metamorphic development of the spinal locomotor network. To induce this sensory asymmetry we performed unilateral removal of vestibular end organs either before or after metamorphosis. Acutely, in both cases, the lesion induced dramatic postural and locomotor changes. Chronically, the lesion altered the metamorphic development of the lumbo-thoracic network on the lesioned side, concomitantly with compensation for locomotor defects. Interestingly, animals lesioned after metamorphosis neither compensated nor expressed this developmental spinal plasticity. Altogether, these results suggest that descending sensory inputs are crucial cues for the development of the spinal locomotor network. Finally, we studied the metamorphic development of the supra-spinal network, focusing our attention on the locomotor triggering and control properties of the mesencephalic locomotor region (MLR). We showed that both subparts of this structure, the laterodorsal tegmentum (LDT) and the pedunculopontine (PPN) nuclei, are present and functional during the entire period of metamorphosis and that the PPN has an optimal activation frequency of 10-20 Hz. Locomotion Moelle épinière Réseaux de neurones Développement Interaction sensorimotrice Hémilabyrinthectomie Commande motrice Xenopus laevis Métamorphose Locomotion Spinal cord Neural network Development Sensorimotor interaction Hemilabyrinthectomy Motor command Xenopus laevis Metamorphosis
252	Signaling Events Leading to CPEB-Mediated Translation: a Dissertation Sarkissian, Madathia 12 July 2004 (has links) Fully grown oocytes' of the African clawed frog, Xenopus laevis, are arrested at the diplotene stage of meiotic prophase I, which resembles the G2 phase of the mitotic cell cycle. Re-entry into the meiotic divisions is initiated by hormonal signaling normally provided by progesterone. Progesterone signaling leads to the activation of maturation promoting factor (MPF), a heterodimer consisting of the protein kinase cdk1 and cyclin B1; this complex promotes the oocyte's entry into M phase of meiosis I. A crucial event required for MPF activation is cytoplasmic polyadenylation element (CPE)-mediated translation of specific dormant mRNAs such as c-mos and cyclin B1. The CPE, which resides in mRNA 3' untranslated region (UTR), is bound by the CPE binding protein (CPEB), which in turn is bound by Maskin. Maskin is bound to the 5' cap binding protein eIF4E. This type of closed-loop mRNA structure inhibits the recruitment and assembly of the translation initiation complex at the 5'UTR of CPE containing mRNAs. To alleviate this inhibition, CPEB undergoes phosphorylation on S174 by the serine/threonine kinase Aurora A. Phosphorylated CPEB promotes the recruitment of specific polyadenylation factors leading to the polyadenylation of the dormant mRNA, resulting in the disassociation of Maskin from eIF4E. eIF4E is subsequently bound by translation initiation factors leading to mRNA assembly into polysomes and synthesis of the encoded protein. Insulin signaling has also been shown to induce oocyte maturation. However, this signaling cascade uniquely requires the activation of two upstream components, PI3 kinase and PKC zeta. In this thesis, I show that insulin induced oocyte maturation requires the same CPE-mediated mRNA translation mechanism as had been described for progesterone signaling. I also show that Aurora A kinase activation and S174 phosphorylation play an essential role in insulin-induced CPE-mediated mRNA translation. Interestingly, inhibition of PI3 kinase and PKC zeta inhibits CPE-mediated polyadenylation only in the insulin-signaling pathway; the progesterone pathway is unaffected. These results clearly indicate that different upstream signaling components control CPE-mediated translation between progesterone and insulin signaling cascades. However, both pathways are antagonized by over expressed GSK-3, leading to inhibition of oocyte maturation. Furthermore, I found that GSK-3 inhibits Aurora A kinase activity by directly phosphorylating Aurora A on serine 290/291, promoting an inhibitory autophosphorylation event on serine 349. The importance of a GSK-3/Aurora A interaction is underscored by the finding that GSK-3, Axin, and Aurora A reside in a complex in immature oocytes. During progesterone or insulin signaling, GSK-3 dissociates from Aurora A allowing Aurora A to become active, leading to CPEB phosphorylation, CPE-mediated mRNA translation and oocyte maturation. Insulin Oocytes Progesterone Protein Kinases Signal Transduction Transcription Factors Protein Biosynthesis Xenopus laevis Xenopus Proteins Academic Dissertations Life Sciences Medicine and Health Sciences
253	Mechanisms of microtubule nucleation in metaphase spindles and how they set spindle size Decker, Franziska 25 September 2018 (has links) Regulation of size and growth is a fundamental problem in biology and often closely related to functionality and fitness. A prominent example is the mitotic spindle, whose size needs to be perfectly tuned to ensure proper chromosome segregation during cell division. It is known that spindle size generally scales with cell volume, most likely as a result of limiting components. However, this relation breaks down in very large cells where spindles have a maximum size. How the size and microtubule mass are set and why spindles show an upper size limit in large cells is still not understood. Spindles mainly consist of highly dynamic short microtubules that turn over very quickly in comparison to the lifetime of the entire structure. Thus, microtubules need to be constantly created throughout the spindle, a process called nucleation. Understanding the role of microtubule nucleation in setting the size of spindles is limited by the fact that little is known about the rate, distribution, and regulation of microtubule nucleation in these structures. This is partly due to the lack of methods to measure microtubule nucleation in spindles. During this work, I developed an assay based on laser ablation to probe microtubule nucleation in monopolar spindles assembled in Xenopus laevis egg extract. Using this new method in combination with quantitative microscopy, I found that microtubule nucleation in these structures is spatially regulated. Furthermore, I observed that nucleation is stimulated by pre-existing microtubules leading to new microtubule growth in their physical proximity. Combining my experimental results on nucleation with theory and further biochemical perturbations, I show that this autocatalytic nucleation mechanism is limited by the availability of active nucleators. In spindles, the amount of active nucleators decreases with distance from the chromosomes. Thus, this mechanism provides an upper limit to spindle size even when resources are not limiting. info:eu-repo/classification/ddc/570 ddc:570
254	Temperature-dependence of microtubule dynamics across Xenopus species de Gaulejac, Ella 17 May 2023 (has links) Eukaryontische Zellen besitzen ein Zytoskelett, ein zelluläres Netzwerk aus Biopolymeren. Unter diesen Biopolymeren sind die Mikrotubuli weitgehend konserviert. Diese aus Tubulin aufgebauten Filamente sind dynamisch und wechseln zwischen Phasen des Wachstums und der Schrumpfung. Die genauen Mechanismen, die die dynamische Instabilität der Mikrotubuli bestimmen, werden noch erforscht. Die Allgegenwart von Mikrotubuli wirft die Frage auf, wie sie in verschiedenen thermischen Umgebungen konservierte Funktionen ausführen können. Um dieser Fragestellung nachzugehen, habe ich verwandte Froscharten mit unterschiedlich temperierten Lebensräumen untersucht: Xenopus laevis (16-22 °C), Xenopus borealis (19-23 °C) und Xenopus tropicalis (22-30 °C). Um zu untersuchen, ob sich die biochemischen Eigenschaften von Tubulin und die Dynamik der Mikrotubuli bei den drei Arten an die Temperatur angepasst hat, habe ich die Methoden der Tubulin-Affinitätsreinigung und die temperaturgesteuerte TIRF-Mikroskopie zur Rekonstitution der Mikrotubuli-Dynamik kombiniert. Dabei habe ich festgestellt, dass bei einer Temperatur von 25°C die Wachstumsgeschwindigkeit der Mikrotubuli im Bezug zur thermischen Nische der einzelnen Arten negativ korreliert. Die Verwendung der Arrhenius-Gleichung zum Vergleich der Aktivierungsenergie der Mikrotubuli-Polymerisation für jede Spezies ergab, dass die freie Energie des Tubulins umso höher ist, je kälter die thermische Nische der Spezies ist. Die Mikrotubuli von X. laevis und X. borealis zeigten eine längere Lebensdauer und wurden häufiger zerstört als die von X. tropicalis. Die Tubuline von X. laevis und X. borealis sind phosphoryliert, im Gegensatz zu X. tropicalis. Die Ergebnisse zeigen, dass sich Xenopus Tubulin und die Dynamik der Mikrotubuli an die Temperatur angepasst haben. Kalt lebende Arten kommen mit der niedrigeren Energie des Milieus zurecht, durch verbessertes Wachstum und Stabilität. / Eukaryotic cells hold a cytoskeleton, a cellular network of biopolymers. Among the filaments of the cytoskeleton, microtubules are widely conserved. Built from tubulin, those filaments are dynamic, alternating between phases of growth and shrinkage. The biochemical properties of tubulin shape the dynamic behavior of microtubules, which is crucial for many cellular processes. The precise mechanisms determining microtubule dynamic instability are still under investigation. The ubiquity of microtubules raises the question of how they can perform conserved functions within various thermal environments. To address this, I turned to closely related frog species living at different temperatures, Xenopus laevis (niche: 16-22°C), Xenopus borealis (19-23°C) and Xenopus tropicalis (22-30°C). To probe whether the biochemical properties of tubulin and microtubule dynamics adapted to temperature across those three species, I combined tubulin affinity purification and temperature-controlled TIRF microscopy of in vitro reconstitution of microtubule dynamics. I found that at 25°C, the microtubule growth velocity inversely correlates with the thermal niche of each species. Adjusting temperature to each species’ endogenous condition modulates the growth rate differences across species. Using the Arrhenius equation to compare the activation energy of microtubule polymerization for each species suggested that the colder the thermal niche of the species, the higher the free energy of its tubulin. Microtubules from the cold-adapted species X. laevis and X. borealis have longer lifetimes and rescue more often than those of X. tropicalis, both at 25°C and at each species’ endogenous condition. X. laevis and X. borealis tubulins are phosphorylated, contrary to X. tropicalis. My results show that Xenopus tubulin and microtubule dynamics have adapted to temperature. Cold-living species cope with the lower energy of the milieu by facilitating growth and stability. Tubulin Thermische Adaptation Xenopus TIRF Mikroskopie Tubulin Thermal adaptation Xenopus TIRF microscopy Microtubules Dynamic instability in vitro assay 572 Biochemie ddc:572
255	Computational study of the mechanisms underlying oscillation in neuronal locomotor circuits Merrison-Hort, Robert January 2014 (has links) In this thesis we model two very different movement-related neuronal circuits, both of which produce oscillatory patterns of activity. In one case we study oscillatory activity in the basal ganglia under both normal and Parkinsonian conditions. First, we used a detailed Hodgkin-Huxley type spiking model to investigate the activity patterns that arise when oscillatory cortical input is transmitted to the globus pallidus via the subthalamic nucleus. Our model reproduced a result from rodent studies which shows that two anti-phase oscillatory groups of pallidal neurons appear under Parkinsonian conditions. Secondly, we used a population model of the basal ganglia to study whether oscillations could be locally generated. The basal ganglia are thought to be organised into multiple parallel channels. In our model, isolated channels could not generate oscillations, but if the lateral inhibition between channels is sufficiently strong then the network can act as a rhythm-generating ``pacemaker'' circuit. This was particularly true when we used a set of connection strength parameters that represent the basal ganglia under Parkinsonian conditions. Since many things are not known about the anatomy and electrophysiology of the basal ganglia, we also studied oscillatory activity in another, much simpler, movement-related neuronal system: the spinal cord of the Xenopus tadpole. We built a computational model of the spinal cord containing approximately 1,500 biologically realistic Hodgkin-Huxley neurons, with synaptic connectivity derived from a computational model of axon growth. The model produced physiological swimming behaviour and was used to investigate which aspects of axon growth and neuron dynamics are behaviourally important. We found that the oscillatory attractor associated with swimming was remarkably stable, which suggests that, surprisingly, many features of axonal growth and synapse formation are not necessary for swimming to emerge. We also studied how the same spinal cord network can generate a different oscillatory pattern in which neurons on both sides of the body fire synchronously. Our results here suggest that under normal conditions the synchronous state is unstable or weakly stable, but that even small increases in spike transmission delays act to stabilise it. Finally, we found that although the basal ganglia and the tadpole spinal cord are very different systems, the underlying mechanism by which they can produce oscillations may be remarkably similar. Insights from the tadpole model allow us to predict how the basal ganglia model may be capable of producing multiple patterns of oscillatory activity. 612.8
256	Mitochondrial differentiation during the early development of the amphibian embryo Nelson, Lennart January 1981 (has links) Mitochondria from Xenopus laevis and Ambystoma mexica- num embryos between fertilization and the beginning of feeding were studied: the former with respect to metabolic behaviour, enzyme pattern and carrier activity, and the latter with respect to morphological parameters. The metabolic behaviour of mitochondria was studied by assessing the rates of oxygen uptake in presence of various substrates. The rates of oxidation of most substrates change during development. The only substrate to be readily metabolized is glutamate (in presence of malate), whose rate of oxidation presents a peak during gastrulation and declines during larval development. The high rate of oxidation of glutamate and a high aspartate aminotransferase activity indicate that the glutamate- aspartate cycle may be predominant in early embryonic mitochondria. The activity of enzymes from the matrix, the inner membrane and the outer membrane were studied. During early development activities of enzymes in the various compartments change independently of each other. Furthermore, enzymes within one compartment may vary independently. Measurements of carrier activity reveal that the carrier for dicarboxylic acids displays a high activity before gastrulation and decreases thereafter, while the tricarboxylic acid, pyruvate and glutamate/OH carriers show the opposite pattern of change, their activities being low or undetectable during early development. This implies that a mitochondrial differentiation takes place ' during development, beginning at gastrulation when the first differentiated cells appear. In order to correlate mitochondrial and cellular differentiation, morphological parameters of mitochondria from undifferentiated and differentiated cells - Ruffini cells and epidermal cells - were analyzed. Mitochondria from the differentiated cells are significantly different from those in undifferentiated cells. Thus the processes of cell differentiation are accompanied by morphological and biochemical differentiation of the mitochondria. / <p>Diss. (sammanfattning) Umeå : Umeå universitet, 1981, härtill 5 uppsatser</p> / digitalisering@umu Amphibia Xenopus laevis Ambystoma mexicanum mitochondria differentiation enzymes carriers oxidation development
257	Optical characterization of ligand-induced staining of olfactory receptor neurons in Xenopus laevis Mgbor, Nwadiuto Amara 30 September 2015 (has links) No description available. 610 Xenopus laevis ligand-induced endocytosis Medizin (PPN619874732)
258	Characterization of HSP47 Expression in <i>Xenopus Laevis</i> Cell Culture and Embryos Hamilton, Amanda January 2005 (has links) The heat shock or stress response is a transient response to stressful stimuli that protects vital cellular proteins from damage and irreversible aggregation. Heat shock proteins (Hsps) are molecular chaperones that bind to unfolded protein and inhibit their aggregation, thereby maintaining their solubility until they can be refolded to their native conformation. Hsp47 is an endoplasmic reticulum (ER)-resident protein that serves as a molecular chaperone during collagen production. Collagen is the major class of insoluble fibrous protein found in the extracellular matrix and in connective tissues. It is the single most abundant protein of the animal kingdom; at least 14 different forms exist, each with distinct structures and binding properties. The various types of collagen all possess protein regions with the distinct triple helical conformation. This complex physical structure requires very organized assembly and HSP47 has been established as an integral component of this process for collagen types I-V. Most of the previous studies examining the expression and function of hsp47 have been conducted with mammalian cultured cells. The present study represented the first investigation of the expression of hsp47 in the poikilothermic vertebrate, <i>Xenopus laevis</i>. Full-length <i>Xenopus</i> hsp47 nucleotide and amino acid sequences were obtained from Genbank and compared with hsp47 from chicken, mouse, rat, human and zebrafish. <i>Xenopus</i> HSP47 protein had an identity of approximately 77% with chicken, 73% with mouse, 72% with rat and human, and 70% with zebrafish. Most of the sequence identity between HSP47 from all investigated organisms occurred centrally in the amino acid sequence and in several carboxyl terminal regions. Three key features were conserved between HSP47 proteins from most species investigated: a hydrophobic leader sequence, two potential glycosylation sites and the ER-retention signal, RDEL. A partial cDNA clone encoding <i>Xenopus</i> hsp47 was obtained from the American Type Culture Collection (ATCC) and used to generate hsp47 antisense riboprobe for the purpose of investigating hsp47 mRNA accumulation in <i>Xenopus</i> A6 kidney epithelial cells and embryos. Northern blot analysis detected hsp47 mRNA constitutively in A6 cells. The expression pattern for hsp47 mRNA was compared with two other <i>Xenopus</i> heat shock proteins that have been previously characterized in our laboratory: hsp70, a cystolic/nuclear hsp and BiP, an ER-resident hsp. The results of hsp47 mRNA accumulation in A6 cells suggested that the expression pattern for <i>Xenopus</i> hsp47 was unique but, with respect to some stressors, resembled that of a cytosolic hsp rather than an ER-resident hsp. HSP47 protein levels were also examined in A6 cells. Heat shock, sodium arsenite and b-aminopropionitrile fumerate treatments enhanced hsp47 accumulation. In some experiments, western blot analysis revealed the presence of two closely sized protein bands. It is possible that minor differences in HSP47 protein size may be due to post-translational modification, namely phosphorylation or glycosylation. The present study also examined the accumulation and spatial pattern of hsp47 mRNA accumulation during <i>Xenopus laevis</i> early development. Hsp47 was constitutively expressed throughout <i>Xenopus</i> early development. Constitutive levels of hsp47 mRNA in unfertilized eggs, fertilized eggs and cleavage stage embryos indicated that these transcripts were maternally inherited. Constitutive hsp47 mRNA accumulation was enhanced in neurula and tailbud embryos compared to earlier stages. This finding may be explained by the shift towards organogenesis during these stages. Whole mount <i>in situ</i> hybridization revealed hsp47 message along the dorsal region of the embryo, in the notochord and somites, as well as in the head region including the eye vesicle. Hsp47 mRNA induction in <i>Xenopus</i> embryos was also examined in response to heat shock. Hsp47 mRNA accumulated in response to heat shock immediately following the midblastula transition (MBT). In tailbud stages, hsp47 mRNA accumulated in the notochord, somites and head region. Northern blot analysis and whole mount <i>in situ</i> hybridization results revealed an expression pattern that coincided well with the development of collagen-rich tissues thereby substantiating the proposed role of HSP47 as a procollagen molecular chaperone. Molecular Biology Biology hsp47 heat shock proteins endoplasmic reticulum Xenopus laevis
259	Role of Ptf1a in the development of endocrine and exocrine pancreas of Xenopus laevis embryos Jarikji, Zeina January 2006 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Xenopus Pancréas Ptf1a Spécification Transdifférentiation Insuline Îlots de Langerhans Endocrine Exocrine Organogenèse
260	Fonctions biologiques et intégration des signaux BMP, FGF, Nodal et Notch au cours de la différenciation et la morphogenèse de l'embryon de xénope / Biological functions and intergration of BMP, FGF, Nodal and Notch signals durinf differentiation and morphogenesis of the xenopus embryo Luxardi, Guillaume 03 December 2010 (has links) Mon travail de thèse a été principalement de comprendre comment les voies de signalisations contrôlent la différenciation et la morphogenèse de l'embryon de vertébré. Les communications entre cellules sont à la base du développement des métazoaires et de leurs évolutions et sont souvent impliquées dans les pathologies humaines. J'ai profité de la puissance des approches fonctionnelles chez le xenope pour essayer de comprendre comment les signaux BMP, FGF, Nodal et Notch sont intégrés dans le temps et l'espace afin de coordonnées différentes décisions cellulaires. Premièrement, nous avons montré que la voie Nodal est active avant la transition mid-blastuléene et permet l'induction du mesedoderme à travers l'auto régulation de l'expression de ces ligands Xnr5 et Xnr6 (Skirkanish et al. soumis à Development). Deuxièmement, j'ai montré que différent ligand de la voie Nodal contrôlent séquentiellement l'induction du mesendoderm et les mouvements de gastrulation (Luxardi et al., Development, 2010). Troisièmement, j'ai montré qu'un cinquième ligand de la voie Nodal, Xnr4, contrôle la régionalisation médio latérale de la plaque neurale ouverte et la neurogenèse. Quatrièmement, nous avons montré qu'une famille de microARN, nir449, contrôle la différenciation des cellules multi-ciliées à travers son action sur un ligand de la voie Notch, Delta-1 (Marcet et al. Nature Cell Biology, en révision). Enfin, j'ai découvert une nouvelle fonction des signaux BMP dans le control de la spécification des épithéliums muco cilié. / My PhD work generally addressed how signaling pathways control differentiation and morphogenesis in the vertebrate embryo. intercellular communication is the basis of metazoan development and evolution and is often involved in human pathologies. I take advantage of the power of functional approaches in the Xenopus embryo, to try and understand how BMP, FGF, Nodal and Notch signals are intragrated in time ans space to coordinate vatious cellular decisions. First, we showed that Nodal signaling is activated before the mid blastula transition and allow mesendoderm induction through the auro regulation of the expression of its ligands Xnr5 and Xnr6 (Skirkanish et al., submitted to development). Second, I have demonstrated that in a gastrulation movements (Luxardi et al., Development, 2010). Third, I have demonstrated that a fifth Nodal ligand, Xnr4, control medio-lateral patterning of the open neural plate and neurogenesis. Froth, we showed that a microRNA family, mir449, controls differenciation of multiciliated cells through the regulation of the Notch ligand Delta-1 (Marcet et al. Nature Cell Biology, in revision). Last, I have discovered a novel function of the BMP pathway in the control of cell type specification within the epidermal mucocialiary epithelium Bmp Fgf Nodal Notch Xenopus Medoderme Endoderme Gastrulation Cils Neural epiderme

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