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Neuronal Development in the Embryonic Retina : Focus on the Characterization, Generation and Development of Horizontal Cell SubtypesEdqvist, Per-Henrik January 2006 (has links)
<p>Horizontal cells are retinal interneurons that modulate the output from photoreceptors. Two horizontal cell (HC) subtypes are commonly identified in the vertebrate retina: axon-bearing and axon-less HCs. In this work, we have identified Isl1 as a novel HC marker and demonstrated that Lim1 and Isl1 distinguish axon-bearing and axon-less HCs, respectively. In the chick retina, axon-less HCs are furthermore split into two different subtypes based on the expression of GABA and TrkA.</p><p>We have demonstrated that during early chick retinogenesis, HCs expressing either Lim1 or Isl1 are generated consecutively as two equally large sub-groups at different time points. Moreover, these newborn HCs undertake an unexpected bi-directional migration before settling in their final laminar position. Different HC subtypes complete this migration at different times.</p><p>We investigated the role of activin signaling during HC subtype generation. Activin or its inhibitor follistatin was administrated during the main phase of HC generation and analyzed when HCs had completed migration. Activin caused a significant decrease in both HC subtypes and decreased the proliferation of retinal precursor cells. Follistatin increased the number of late born (Isl1+) HCs, which migrated to the HC-layer during a prolonged migration period. Both treatments affected retinal histology, but only activin influenced the generation of retinal populations other than HCs. These effects were most likely mediated by altered proliferation in certain retinal precursor cells.</p><p>The data on HC subtype ratios, birth-dates, migration, apoptosis and extrinsic activin modulation favor a scenario where the mature proportions of HC subtypes are generated sequentially from a specific HC-precursor cell lineage early in development and remain stable thereafter. These proportions are not adjusted by apoptosis, but rather by the combined actions of transcription factors and extrinsic signaling. Our studies on HC subtypes and their development promises to facilitate future studies on HC development, evolution and function.</p>
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Neuronal Development in the Embryonic Retina : Focus on the Characterization, Generation and Development of Horizontal Cell SubtypesEdqvist, Per-Henrik January 2006 (has links)
Horizontal cells are retinal interneurons that modulate the output from photoreceptors. Two horizontal cell (HC) subtypes are commonly identified in the vertebrate retina: axon-bearing and axon-less HCs. In this work, we have identified Isl1 as a novel HC marker and demonstrated that Lim1 and Isl1 distinguish axon-bearing and axon-less HCs, respectively. In the chick retina, axon-less HCs are furthermore split into two different subtypes based on the expression of GABA and TrkA. We have demonstrated that during early chick retinogenesis, HCs expressing either Lim1 or Isl1 are generated consecutively as two equally large sub-groups at different time points. Moreover, these newborn HCs undertake an unexpected bi-directional migration before settling in their final laminar position. Different HC subtypes complete this migration at different times. We investigated the role of activin signaling during HC subtype generation. Activin or its inhibitor follistatin was administrated during the main phase of HC generation and analyzed when HCs had completed migration. Activin caused a significant decrease in both HC subtypes and decreased the proliferation of retinal precursor cells. Follistatin increased the number of late born (Isl1+) HCs, which migrated to the HC-layer during a prolonged migration period. Both treatments affected retinal histology, but only activin influenced the generation of retinal populations other than HCs. These effects were most likely mediated by altered proliferation in certain retinal precursor cells. The data on HC subtype ratios, birth-dates, migration, apoptosis and extrinsic activin modulation favor a scenario where the mature proportions of HC subtypes are generated sequentially from a specific HC-precursor cell lineage early in development and remain stable thereafter. These proportions are not adjusted by apoptosis, but rather by the combined actions of transcription factors and extrinsic signaling. Our studies on HC subtypes and their development promises to facilitate future studies on HC development, evolution and function.
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Grass carp activin: molecular cloning and functional role in regulating growth hormone gene expression in grasscarp pituitary cellsFung, Sai-kit., 馮世傑. January 2004 (has links)
published_or_final_version / abstract / toc / Zoology / Master / Master of Philosophy
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Characterization of TGFb signaling during epimorphic tissue regeneration: an example using the leopard gecko (Eublepharis macularius) tail regeneration model.Gilbert, Richard W.D. 02 May 2013 (has links)
The transforming growth factor beta (TGFβ)/activin signaling pathway has a number of documented roles during wound healing and is becoming increasingly appreciated as a vital component of multi-tissue regeneration. The leopard gecko (Eublepharis macularius) is able to spontaneously, and repeatedly, regenerate its tail following tail loss. We thus examined the expression and localization of several key components of the TGFβ/activin signaling pathway during tail regeneration of the leopard gecko. We observed a marked increase in phosphorylated-Smad2 expression among regenerating tissues corresponding to the location of the regenerate blastema. Interestingly, we observe that during early regeneration there appears to be an absence of TGFβ family member TGFβ1 and instead a strong upregulation of activin-βA. We also observe the expression of EMT transcription factors Snail1 and Snail2 in blastemal tissue. These observations combined with other data provide strong support for the importance of unique and non-overlapping expression patterns of different TGFβ ligands during multi-tissue regeneration
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The role and mechanism of BMP-15, activin and TGF-beta in regulating zebrafish oocyte maturation /Tan, Qian. January 2009 (has links)
Thesis (M.Sc.)--York University, 2009. Graduate Programme in Biology. / Typescript. Includes bibliographical references (leaves 53-57). Also available on the Internet. MODE OF ACCESS via web browser by entering the following URL: http://gateway.proquest.com/openurl?url_ver=Z39.88-2004&res_dat=xri:pqdiss&rft_val_fmt=info:ofi/fmt:kev:mtx:dissertation&rft_dat=xri:pqdiss:MR51603
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Fer et immunité innée : vers une meilleure compréhension des mécanismes développés par l'hôte pour réduire le fer accessible aux pathogènes / Iron and innate immunity : toward a better understanding of the mechanisms developped by the host to reduce the iron availability for pathogensGineste, Aurélie 26 September 2016 (has links)
Le fer est un élément essentiel à de nombreux processus physiologiques fondamentaux. Lors d'une infection, une forte compétition entre l'hôte et l'agent pathogène a lieu ; alors que la bactérie a besoin d'acquérir le fer de l'hôte, pour son développement et sa virulence, l'hôte déploie de nombreux mécanismes pour protéger ses stocks de fer. Il sécrète notamment un peptide capable de moduler l'homéostasie du fer au niveau systémique, l'hepcidine, qui va causer une diminution de la quantité de fer sérique, une rétention intracellulaire du fer et donc une restriction du fer accessible aux pathogènes. Lors d'une inflammation, l'expression de l'hepcidine est décrite dans la littérature pour être principalement induite via l'activation de deux voies de signalisation : la voie STAT3 et la voie BMP/SMAD, l'altération de chacune de ces voies conduisant à un défaut d'induction d'hepcidine. Cependant, nos précédentes observations publiées ont infirmé le rôle de l'IL6, ligand de la voie STAT3, dans la régulation de l'hepcidine en réponse au LPS, et ont suggéré l'implication d'un peptide appartenant à la famille du TGFb, l'activine B, dans la régulation de l'hepcidine via l'activation de la voie BMP/SMAD in vivo. Dans cette étude, nous nous sommes intéressés au rôle de l'activine B dans la régulation de l'hepcidine in vivo, lors d'une infection. Grâce à l'utilisation de souris invalidées pour le gène codant l'activine B (Inhbb-/-), nous avons confirmé que l'activine B était un ligand endogène de la voie BMP/SMAD dans le foie, puisqu'elle induit la phosphorylation des effecteurs SMAD en réponse au LPS. Cependant, nous avons pu clairement démontrer que l'activine B, et donc l'augmentation de la phosphorylation des effecteurs SMAD, ne participaient pas à la régulation de l'hepcidine in vivo, en réponse à l'infection. Nous nous sommes alors intéressés à l'implication de l'IL6 dans la régulation de l'hepcidine. Alors que l'absence d'Il6 n'altère pas l'induction de l'hepcidine in vivo en réponse au LPS, cette cytokine semble jouer un rôle clé pour la réponse de l'hôte lors d'une infection par une bactérie. Dans ce contexte, la littérature décrit l'importance de l'IL6 pour une réponse immunitaire protectrice de l'hôte lors d'une infection. Lors d'une infection, nous proposons donc l'implication d'une nouvelle voie de signalisation dans l'expression de l'hepcidine. De plus, nous suggérons un rôle important de l'IL6, non pas dans la régulation transcriptionnelle de l'hepcidine, mais pour la protection de l'hôte lors d'une infection bactérienne. Enfin, nos résultats montrent qu'un niveau d'activation basal de la voie BMP/SMAD est requis pour une induction d'hepcidine lors d'inflammation, et que l'augmentation de la phosphorylation des effecteurs SMAD observée en réponse à l'inflammation ne participe pas à cette régulation. / Iron is essential for several fundamental metabolic processes. During infection, a strong competition between the host and the pathogen occurs; while the bacteria needs to acquire iron from the host, for its growth and virulence, hosts have developed several mechanisms to protect its iron stores. In particular, the host produces a peptide in order to modulate systemic iron homeostasis, hepcidin. Hepcidin decreases the amount of circulating iron, causes intracellular iron retention and thus a restriction of accessible iron to pathogens. During inflammation, hepcidin expression is described in the literature to be mainly mediated through activation of two signaling pathways: the STAT3 and the BMP/SMAD pathways. Impairment of one of these pathways leads to an impaired hepcidin induction. However, our previous published observations did not support the role of IL6, the major ligand of STAT3 pathway, in the regulation of hepcidin in response to LPS, but suggested the involvement of another protein, that belongs to the TGFb family, activin B, in the regulation of hepcidin via the activation of the BMP/SMAD pathway in vivo. In this study, we investigated the role of activin B in the regulation of hepcidin in vivo, during infection. By using knockout mice for the gene encoding activin B (Inhbb-/-), our results suggest that activin B is not involved in the regulation of hepcidin in vivo in response to infection. We then investigated the function of IL6 in the regulation of hepcidin. Although the absence of IL6 does not affect the induction of hepcidin in vivo in response to LPS, this cytokine appears to play a key role in the host response during bacterial infection. Indeed, the literature describes the importance of IL6 for a protective immune response of the host during infection. During infection, we hypothesize that another signaling pathway regulates hepcidin expression. In addition, we suggest an important role of IL6, not in the transcriptional regulation of hepcidin, but for the host protection during a bacterial infection. Finally, our results also show that basal level of BMP/SMAD pathway is required for an appropriate induction of hepcidin during inflammation.
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The role of alsin in early Xenopus developmentGill, Pendeep January 2012 (has links)
Mutation within the human ALS2 gene, which encodes the protein Alsin, causes a number of recessive motor neuron diseases. The ALS2 gene encodes a 180kDa protein, which has been shown to localize to early endosomes. The Alsin protein comprises three predicted guanine exchange factor (GEF) domains, the best characterised of which is the VPS9 domain for Rab5 GTPase, which is involved in the endocytosis membrane trafficking pathway, particularly in the docking and fusion of early endosomes. Furthermore, Alsin contains a Rho-GEF domain which specifically interacts with Rac-1 GTPase in the PI3K/AKT signal transduction pathway. This pathway has been implicated in numerous biological processes, including control of protein translation, via the mTOR branch of the pathway. To date, most work on the human ALS2 disease phenotypes has focused on the role of alsin in membrane trafficking, and neglected alsin’s potential role in signalling via its Rho-GEF domain. The focus of this project was to study the role of alsin in signalling during early Xenopus development, a period rich in well-characterised cell-cell signalling. I have shown that alsin is maternally loaded and zygotically expressed in the early Xenopus embryo. In cell culture, alsin is localised to early endosomes. Knockdown of alsin protein through the use of mopholinos (MO), resulted in a gastrulation defect, in particular, failure to close the blastopore caused by disrupted mesoderm induction and convergent extension movements. An animal cap assay was used to study mesoderm induction in the presence of als2-MO and activin protein, a potent mesoderm inducer. These animal caps extended normally, indicating proper mesoderm induction. By contrast, als2-MO animal caps failed to extend when co-injected with activin mRNA suggesting that alsin is important for the production and/or secretion of the activin ligand in the source cell. Subsequently it was determined that knockdown of alsin reduced the precursor protein levels of TGF-β family members activin and Xnr-2. These results suggest a novel role for alsin in mRNA stability, translational regulation or post-translational control of specific mesoderm-inducer mRNAs.
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The Role of Activin B in Skeletal Muscle Injury and RegenerationMelissa A Yaden (11798105) 20 December 2021 (has links)
Activin B, a member of the transforming growth factor-β superfamily, is ubiquitously expressed in diverse tissues and is a regulator of reproduction, embryonic development, and adult tissue homeostasis. We aimed to determine whether activin B is involved in skeletal muscle injury and if selective inhibition of activin B would provide a regenerative benefit. The local introduction of activin B into normal skeletal muscle increased the expression of inflammatory and muscle atrophy genes TWEAK, TNFα, GDF3 and TRIM63, by 2-, 10-, 10-, and 4-fold, respectively. The data indicate a sensitive response of skeletal muscle to activin B. Six hours after cardiotoxin-induced skeletal muscle damage, circulating activin B protein expression in serum increased by 9-fold and InhβB gene expression increased by 30-fold in muscle. After cardiotoxin-induced skeletal muscle damage, activin B protein expression in muscle was significantly increased at 48- and 120-hours by 1.5 and 2-fold, respectively. Muscle histopathological features showed that activin B antibody–treated mice displayed a reduction in necrotic debris, with a concomitant reduction in intramyocellular space at 9-days after injury. Activin B treated C2C12 myoblasts also displayed a dose-dependent reduction in active myogenesis. Furthermore, the increased presence of activin B early in muscle injury impedes muscle repair and remodeling. In summary, acute muscle injury leads to increases in activin B levels and when selectively neutralized with a monoclonal antibody, there is augmented skeletal muscle repair.
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The Role of Activin A Signaling in Gastric Reflux-Related Diseases and the Progression to Esophageal AdenocarcinomaRoudebush, Cedric J. 01 January 2019 (has links)
Gastroesophageal reflux disease (GERD), or acid reflux, affects 6-9 million people in the United States. It is characterized by a reflux of gastric acid and bile salts from the stomach into the esophagus, causing injuries to the esophagus known as Barrett's esophagus (BE). BE is the main risk factor for the development of esophageal adenocarcinoma (EAC), a devastating cancer in the esophagus whose molecular roots remain poorly understood. In recent years, evidence points to the esophageal epithelium itself as responsible for causing and promoting inflammation upon injury by gastric reflux, namely via an increase in inflammatory cytokine secretion. This project was focused on a cytokine of interest, Activin A, which is known for its importance during embryogenesis and stem cell differentiation. It has recently been studied for its role in inflammation and tumor formation, but not in the case of esophageal diseases. Here, we demonstrate that Activin A signaling in esophageal epithelial cells is heavily upregulated shortly after exposure to bile salts and acid. We show evidence that this upregulation causes an increase in cell migration upon a reconstituted extracellular matrix. We also provide further evidence that bile and acid injury causes epithelial cells to secrete cytokines, which drive inflammation. We show that the upregulated Activin A secretion and signaling plays an important role in promoting this inflammatory state. Finally, we provide evidence that bile salts and acid exposure, as well as increased Activin A signaling, causes esophageal epithelial cells to upregulate stem cell and transdifferentiation markers, supporting the latest theories on the origin of Barrett' esophagus stem cells as well as paligenosis.
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Activin A Reduces Brain Injury After StrokeMukerji, Shibani Sharon 10 January 2009 (has links)
No description available.
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