1 |
Understanding the Role of Hypusine Biosynthesis in Endocrine-Exocrine CrosstalkDale, Dorian J. 08 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Traditionally, the exocrine and endocrine cellular compartments of the pancreas have been considered distinct functional systems. However, recent studies suggest a more intricate relationship between the exocrine and endocrine, which may impact pancreatic growth and health. Additionally, translational control mechanisms have been linked to organ development. Our lab has shown that the mRNA translation factor eukaryotic initiation factor 5A (eIF5A), when in its post-translationally modified “hypusinated” form, plays a role in pancreas development. The hypusination of eIF5A requires the rate-limiting enzyme deoxyhypusine synthase (Dhps) to post- translationally modify a critical lysine residue which in turn produces the active form of eIF5A that functions in mRNA translation. When we generated animals with a deletion of Dhps in the pancreatic progenitor cells, there was no alteration in islet mass but significant exocrine insufficiency at embryonic (E) day 18.5 concomitant with downregulation of proteins required for exocrine pancreas development and function. Resultantly these animals died by 6 weeks-of-age. These observations prompted the question, is the phenotype caused by the absence of hypusinated eIF5A or the increase of unhypusinated eIF5A? To address this, we generated a mouse model wherein Eif5a is deleted in the pancreas (eIF5A∆PANC) and these mutant animals also display exocrine insufficiency. Interestingly, beta cell mass is increased at E18.5, and the mutant animals maintain euglycemia and survive up to 2 years. Ongoing analyses are interrogating the differences between these animal models with the goal to determine if mRNA translation facilitates cellular communication between the exocrine and endocrine pancreas.
|
2 |
Understanding the Role of Hypusine Biosynthesis in Exocrine-Endocrine CrosstalkDorian Dale (13149045) 27 July 2022 (has links)
<p> </p>
<p>Traditionally, the exocrine and endocrine cellular compartments of the pancreas have been considered distinct functional systems. However, recent studies suggest a more intricate relationship between the exocrine and endocrine, which may impact pancreatic growth and health. Additionally, translational control mechanisms have been linked to organ development. Our lab has shown that the mRNA translation factor eukaryotic initiation factor 5A (eIF5A), when in its post-translationally modified “hypusinated” form, plays a role in pancreas development. The hypusination of eIF5A requires the rate-limiting enzyme deoxyhypusine synthase (<em>Dhps</em>) to post-translationally modify a critical lysine residue which in turn produces the active form of eIF5A that functions in mRNA translation. When we generated animals with a deletion of <em>Dhps</em> in the pancreatic progenitor cells, there was no alteration in islet mass but significant exocrine insufficiency at embryonic (E) day 18.5 concomitant with downregulation of proteins required for exocrine pancreas development and function. Resultantly these animals died by 6 weeks-of-age. These observations prompted the question, is the phenotype caused by the absence of hypusinated eIF5A or the increase of unhypusinated eIF5A? To address this, we generated a mouse model wherein <em>Eif5a</em> is deleted in the pancreas (eIF5A∆PANC) and these mutant animals also display exocrine insufficiency. Interestingly, beta cell mass is increased at E18.5, and the mutant animals maintain euglycemia and survive up to 2 years. Ongoing analyses are interrogating the differences between these animal models with the goal to determine if mRNA translation facilitates cellular communication between the exocrine and endocrine pancreas.</p>
|
3 |
Study of interactions between endocrine and exocrine pancreas mediated by microparticles in cystic fibrosis : impact of infections and immunosuppressive drugs / Etude des interactions entre le pancréas endocrine et exocrine promus par les microparticules dans la mucoviscidose : impact des infections et des immunosuppresseursConstantinescu, Andrei 29 September 2014 (has links)
Ce travail scientifique a abordé la problématique de la communication cellulaire entre le pancréas exocrine et endocrine dans la mucoviscidose. La contribution des infections pulmonaires chroniques et des traitements immunosuppresseurs sur la dégénerescence pancréatique a été aussi étudiée. Les résultats obtenus ont montré que le LPS disséminé par des infections récurrentes peut cibler les cellules pancréatiques exocrines, en conduisant à la formation des microparticules membranaires qui sont nuisibles pour la survie et le fonctionnement des cellules endocrines. Dans cette communication intercellulaire, la protéine CFTR est un médiateur essentiel de la sévérité des signaux délivrés par les microparticules et de la réponse cellulaire à l'inflammation du pancréas, en participant à l'équilibre de la sécrétion d'insuline des cellules endocrines. En outre, les données ont mis en évidence que l'administration prolongée d’immunosuppresseurs chez les patients greffés pourrait différemment induire l'apoptose de manière dépendante de la mitochondrie, cela en favorisant l'entrée des cellules en sénescence prématurée, un état métabolique du dysfonctionnement cellulaire. / This scientific work tackled the issue of the communication between exocrine and endocrine pancreas in cystic fibrosis. Also, the contribution of recurrent lung infections and immunosuppressive therapy to the pancreatic cell degenerescence was studied in vitro. Results obtained showed that disseminated LPS released by recurrent infections could target pancreatic exocrine cells, leading to the formation of membrane microparticles that are deleterious for endocrine cell survival and function. In this intercellular cross-talk, CFTR is a critical mediator for the severity of the MP-delivered signals and for the pancreatic cell response to inflammation, also participating to the balance of insulin secretion of endocrine cells. Furthermore, data evidenced that long-term administration of immunosuppressive drugs in grafted patients may differently induce apoptosis in a mitochondrial-dependent fashion, possibly favoring cells to enter premature senescence, which is a metabolic state of cellular dysfunction.
|
4 |
Étude du rôle biologique et oncosuppressif du gène de prédisposition aux Néoplasies Endocriniennes Multiples de type 1 (MEN1) dans les cellules endocrines pancréatiques / Study of biological and oncosuppressive role of Multiple Endocrine Neoplasia type I gene (MEN1) in pancreatic endocrine cellsLu, Jieli 22 September 2009 (has links)
Le syndrome des Néoplasies Endocriniennes Multiples de type 1 (NEM1) est une maladie à transmission autosomique dominante liée à l’inactivation du gène MEN1. Le but de mon travail de thèse était d’étudier le rôle biologique et oncosuppressif du gène Men1 dans le pancréas endocrine. La caractérisation d’un nouveau modèle m’a permis de démontrer que l’invalidation du gène Men1 spécifiquement dans les cellules alpha conduit à la fois au développement de glucagonomes et d’insulinomes par un mécanisme de transdifférenciation de cellules exprimant le glucagon en cellules exprimant l’insuline. Parallèlement, en explorant les modèles murins où le gène Men1 est invalidé respectivement dans les cellules alpha et beta Pancréatiques, j’ai pu identifier l’expression altérée de certains facteurs de transcription ayant des fonctions vitales dans ces cellules, notamment Foxa2 et MafB, dans les lésions précoces des cellules endocrines pancréatiques correspondantes. En conclusion, mon travail de thèse a permis de mieux clarifier la fonction biologique du gène Men1 dans les cellules pancréatiques endocrines et de mieux comprendre les mécanismes impliqués dans la survenue du syndrome MEN1 / Multiple endocrine neoplasia type 1 (MEN1) is an autosomal dominant inherited syndrome caused by mutations of the MEN1 gene. The aim of my work is to investigate the biological and oncosuppressive roles of the Men1 gene in the pancreatic endocrine cells. The analyses carried out in a new mouse model showed that Men1 ablation in alpha cells trigged the development of both glucagonoma and insulinoma by the transdifferentiation from glucagon-producing cells to insulin-expressing cells. Furthermore, the data obtained from the characterization of both alpha- and beta-cell-specific Men1 mutant mice allowed to identify the altered expression of several important endocrine specific transcriptional factors, including Foxa2 and MafB, found in the early lesions of the corresponding pancreatic endocrine cells. Overall, my thesis work provides interesting clues for better understanding the mechanisms involved in the tumorigenesis of MEN1 syndrome
|
Page generated in 0.0593 seconds