Global ETD Search

111	Sequential in vivo labeling of insulin secretory granule pools in INS-SNAP transgenic pigs Kemter, Elisabeth, Müller, Andreas, Neukam, Martin, Ivanova, Anna, Klymiuk, Nikolai, Renner, Simone, Yang, Kaiyuan, Broichhagen, Johannes, Kurome, Mayuko, Zakhartchenko, Varlie, Kessler, Barbara, Knoch, Klaus-Peter, Bickle, Marc, Ludwig, Barbara, Johnsson, Kai, Lickert, Heiko, Kurth, Thomas, Wolf, Eckhard, Solimena, Michele 09 November 2021 (has links) The failure of β cells to secrete sufficient amounts of insulin is a key feature of diabetes mellitus. Each β cell secretes only a small amount of insulin upon stimulation in a highly regulated fashion: young insulin is preferentially released, whereas old insulin is mainly degraded within the β cell. How this process is regulated in vivo and likely altered in diabetes is currently unknown. We present here a transgenic pig model that allows the in vivo fluorescent labeling of age-distinct insulin secretory granule pools, hence providing a close-to-life readout of insulin turnover. This will enable the study of alterations in β cell function in an animal model close to humans. info:eu-repo/classification/ddc/500 ddc:500
112	CDK4 Rescues Diabetes in IRS2-Deficient Mice: Exploring Novel Roles of a Cell Cycle Regulator in Promoting Beta Cell Differentiation Stamateris, Rachel E. 13 May 2021 (has links) Strategies aimed at expanding functional beta cell mass remain a prime goal of diabetes research. Both the insulin signaling pathway, as well as the G1/S transition of the cell cycle are critically important for the maintenance of beta cell mass. We previously demonstrated in a mouse model of diabetes, insulin receptor substrate 2 (Irs2) deficient mice, that beta cell failure was attributed to reduced islet expression of Cyclin D2, and that overexpressing Cyclin D2 rescued proliferation in Irs2 deficient beta cells in vitro. Since Cyclin D2 partners with CDK4 to drive cell cycle progression, we hypothesized that an activated form of CDK4, Cdk4-R24C (resistant to inhibition by the INK4A cell cycle inhibitor p16), would rescue the in vivo proliferation defect in Irs2 deficient mice. Interestingly, Irs2 knockout mice with the active Cdk4 R24C allele, displayed rescued blood glucose, and normalized glucose tolerance, without affecting peripheral insulin resistance. I found that both and beta cell mass and proliferation were rescued in vivo, contributing to the rescue of glucose tolerance. Interestingly, the dedifferentiated phenotype of Irs2 knockout islets (ALDH1A3+ cells, nuclear FOXO1 and suppressed PDX1) was completely restored with the active Cdk4 allele, suggesting that CDK4 may play a role in promoting beta cell differentiation. Utilizing various in vitro models where FOXO1 represses Pdx1, overexpression of CDK4/CyclinD2 was consistently able to rescue the FOXO1-mediated repression of Pdx1, without significant impacts on FOXO1 subcellular localization. These results suggested that FOXO1 regulation in the beta cell is more complex than previously described, and also suggested that CDK4/Cyclin D2 may be instead modulating the acetylation status of FOXO1, impacting its transcriptional activity. To this end, inhibiting histone acetylate transferases (HATs) partially rescued FOXO1-mediated Pdx1 suppression, while inhibiting histone deacetylase enzymes (HDACs) showed the reverse effect of trending towards blocking the Cyclin D2/CDK4-mediated rescue of Pdx1. Finally, I found that CDK4/Cyclin D2 increases phosphorylation of sirtuin 1 (SIRT1), an HDAC that modulates the acetylation status, and transcriptional activity of FOXO1, and that CDK4/Cyclin D2 promotes FOXO1 degradation. In sum, we conclude that activated CDK4 rescues beta cell failure due to IRS2 deficiency through multiple mechanisms related to not only cell cycle regulation but also to beta cell differentiation status, primarily through modulation of FOXO1 transcriptional activity. beta cell diabetes insulin proliferation differentiation IRS2 FOXO1 PDX1 HDACs SIRT1 Biology Cell Biology Endocrine System Diseases
113	Insights into the Functional Roles of Exercise in Type 2 Diabetes Using in vitro Models Nieuwoudt, Stephan 02 February 2018 (has links) No description available. Physiology Biophysics Biomedical Research Molecular Biology Type 2 Diabetes Exercise Skeletal Muscle In Vitro Myokines Insulin Resistance Beta Cell Function
114	Effets insulino-sécrétoires et protecteurs de la quercétine au niveau de la cellule beta pancréatique : implication du calcium intracellulaire et de ERK1/2 / Effect of quercetin on insulin secretion and protection of pancreatic beta cell : implication of intracellular calcium and ERK1/2 Bardy, Guillaume 12 December 2012 (has links) Dans le diabète de type 2 établi, l'hyperglycémie chronique, un taux élevé d'acides gras libres et l'inflammation induisent un stress oxydatif (SO) au niveau de la cellule beta. Le SO, qui apparaît dès le stade de pré-diabète, peut induire un dysfonctionnement précoce de cette cellule. Ainsi, la protection de la cellule β par des molécules anti-oxydantes pourrait ralentir la progression du pré-diabète au diabète.La quercétine, un flavonoïde, a présenté des propriétés antidiabétiques dans plusieurs études in vivo. Cependant, très peu de données traitent de son mécanisme d'action directement au niveau de la cellule beta. Dans ce contexte, nous avons étudié les effets de la quercétine au niveau de la cellule beta dans des conditions physiologiques et des conditions de SO.Nos résultats montrent qu'en présence de concentrations stimulantes de sécrétagogue, la quercétine potentialise la sécrétion d'insuline par un mécanisme impliquant l'augmentation de calcium intracellulaire et la potentialisation de ERK1/2 via l'activation des voies de la PKA et de la CaMK II. De plus, la quercétine protège la cellule beta du SO en sur-activant ERK1/2. Le resvératrol et la NAC, deux antioxydants de référence, sont inactifs dans ces conditions expérimentales.En absence de concentrations stimulantes de sécrétagogue, la quercétine induit une sécrétion d'insuline modérée en augmentant le calcium intracellulaire suite à une activation directe des CaV de type L. Dans ces conditions, l'activation de ERK1/2 induite par la quercétine, qui est indépendante de l'activation des voies de la PKA et de la CaMK II, ne serait pas impliquée dans le mécanisme sécrétoire. Nos résultats indiquent que le mécanisme d'action de la quercétine au niveau de la cellule β ne repose pas uniquement sur ses capacités anti-oxydantes mais fait intervenir des cibles pharmacologiques et la régulation de voies de signalisation intracellulaires. / In type 2 diabetes, chronic hyperglycaemia, elevated free fatty acids and inflammation induce oxidative stress (OS) in pancreatic β cell. SO, which appears at the stage of pre-diabetes, may induce early dysfunction of this cell. Thus, the β cell protection by antioxidant molecules could slow the progression of pre-diabetes to diabetes.Quercetin, a flavonoid, has shown antidiabetic properties in several in vivo studies. However, very few data address its mechanism of action directly at the β cell. In this context, we studied the effects of quercetin at the β cell under physiological conditions and conditions of OS.Our results show that in the presence of stimulating concentrations of secretagogue, quercetin potentiates insulin secretion by a mechanism involving increased intracellular calcium and potentiation of ERK1 / 2 via activation of the PKA and the CaMK II pathways. In addition, quercetin protects beta cell from OS via a suractivation of ERK1/2. Resveratrol and NAC, two antioxidants of reference are inactive under these experimental conditions.In the absence of stimulating concentration of secretagogue, quercetin induced moderate insulin secretion by increasing the intracellular calcium via a direct activation of L-type CaV Under these conditions, the activation of ERK1/2 induced by quercetin, which is independent of the activation pathways of PKA and CaMK II to, would not be involved in the secretory mechanism.Our results indicate that the mechanism of action of quercetin at the β cell not only based on its antioxidant capacity but involves pharmacological targets and the regulation of intracellular signaling pathways. Quercétine Sécrétion d'insuline Canaux calciques voltage dépendant Erk 1/2 Cellule beta pancréatique Quercetin Insulin secretion Voltage dependent calcium channel Erk 1/2 Pancreatic beta cell 616
115	Identification de nouvelles stratégies thérapeutiques renforçant le rôle des analogues du GLP-1 pour préserver et/ou restaurer la masse fonctionnelle β pancréatique / Identification of new therapeutic strategies to strengthening GLP-1 effects to preserve and/or to restore the functional pancreatic beta cell mass Varin, Elodie 19 September 2013 (has links) Les cellules β pancréatiques synthétisent et sécrètent l'insuline, seule hormone hypoglycémiante de l'organisme. Dans le cas du diabète de type 2, du diabète de type 1 et suite à une greffe d'îlots de Langherans, on observe une diminution drastique de cette masse fonctionnelle β. L'hyperglycémie chronique et la libération de cytokines proinflammatoires jouent un rôle cytotoxique prépondérant dans ces phénomènes. Dans le but de préserver ou de restaurer cette masse fonctionnelle β chez les patients diabétiques, notre objectif était d'identifier des outils permettant de protéger des effets délétères de l'hyperglycémie chronique et des cytokines proinflammatoires, en s'intéressant à 3 cibles potentielles. Nous montrons tout d'abord que les activités du système ubiquitine protéasome (UPS), impliqué dans la dégradation de protéines, sont altérées en condition d'hyperglycémie chronique. Ces altérations sont corrélées à l'émergence d'un programme apoptotique au sein des cellules β. L'activation du récepteur du GLP-1 (Glucagon-Like Peptide-1), stratégie thérapeutique majeure dans le diabète de type 2, protège l'UPS des effets délétères de l'hyperglycémie chronique. Le facteur de transcription CREB (cAMP Response Element Binding Protein), essentiel pour la survie et la fonction des cellules β, est dégradé par l'hyperglycémie chronique et l'inflammation. Nous montrons que la prévention de sa dégradation prévient les effets de l'hyperglycémie chronique, mais pas de l'inflammation. Ces observations nous ont amenés à étudier la MAP3 kinase Tpl2 (Tumor progression locus 2), impliquée, notamment via l'activation de ERK1/2 (Extra-cellular Regulated Kinases 1/2), dans les processus inflammatoires d'autres types cellulaires. Nous montrons que Tpl2 est exprimé dans la lignée cellulaire β INS-1E, et dans les îlots murins et humains, et qu'elle gouverne spécifiquement l'activation des kinases ERK1/2 induite par les cytokines proinflammatoires IL-1β, TNFα et IFNγ. Cette protéine est surexprimée dans des conditions d'inflammation (in vitro et modèle de diabète murin). L'inhibition de Tpl2 protège contre l'apoptose induite par les cytokines, dans les INS-1E et les îlots de souris et restaure la capacité sécrétrice d'insuline des ilots de souris altérée suite à une exposition aux cytokines. En combinaison avec un analogue du GLP-1, l'inhibition pharmacologique de cette kinase protège totalement contre les effets délétères des cytokines sur la fonction et la survie des îlots humains. Ces données suggèrent que l'inhibition pharmacologique de la kinase Tpl2, seule ou en combinaison avec un analogue du GLP-1, pourrait constituer de nouvelles stratégies thérapeutiques pour protéger contre l'altération de la masse fonctionnelle β pouvant survenir chez des patients diabétiques de type 2 ou après la transplantation d'îlots. / Pancreatic β cells synthesize and secrete insulin, the sole hormone of the organism able to reduce glycemia. In the course of type 2 and type 1 diabetes, and after islet transplantation, there is a drastic loss of function and mass of these cells. Among the common origins of this decrease, chronic hyperglycemia and the release of proinflammatory cytokines play major roles. With the aim to preserve or to restore this functional β cell mass in diabetic patients, our objective was to identify tools able to protect against deleterious effects of these two phenomenons, interesting in three potential targets. We first demonstrated that the ubiquitin-proteasome system (UPS) activities, that degrade proteins, are altered in β cells exposed to chronic hyperglycemia, and correlated with apoptosis. Activation of the GLP-1 (Glucagon-Like Peptide-1) receptor, a key therapeutic strategy in type 2 diabetes, protects UPS from deleterious effects of chronic hyperglycemia. The transcription factor CREB (cAMP Response Element Binding Protein), crucial for β cell survival and function, is involved in deleterious effects of chronic hyperglycemia and inflammation. We demonstrated that prevention of CREB degradation protects β cells from chronic hyperglycemia, but not from the deleterious effects of the proinflammatory cytokines. These observations prompted us to study the MAP3 kinase Tpl2 (Tumor progression locus 2), known to be implicated in inflammatory process in other cell types, through the activation of the kinases ERK1/2 (Extra-cellular Regulated Kinases 1/2). We showed that Tpl2 is expressed in INS-1E clonal β cells and in mouse and human islets, and that it governs specifically the activation of ERK1/2 in response to proinflammatory cytokines IL-1β, TNFα and IFNγ. This protein is overexpressed by inflammatory conditions and in a rat type 2 diabetes model. Inhibition of Tpl2 protects against cytokine-induced apoptosis in INS-1E and in mouse islets. Furthermore, the capacity of mouse islets to secrete insulin in response to glucose, that is altered by a chronic exposure to cytokines, is restored by Tpl2 inhibitor. Finally, we showed that in combination with GLP-1 analog (Exendin-4), Tpl2 inhibitor can entirely restore the survival and function in human islets cultured in pro-inflammatory conditions. These results suggest that pharmacological inhibition of Tpl2, alone or in combination with Exendin-4, may be novel therapeutic strategies to alleviate β-cell failure observed in Type 2 diabetes and islets transplantation. Diabète Cellule bêta pancréatique Inflammation Stratégie thérapeutique Glp-1 Signalisation intracellulaire Diabetes Pancreatic beta cell Inflammation Therapeutic strategies Glp-1 Intracellular signaling
116	Biocommunication entre le tissu adipeux viscéral et la cellule bêta-pancréatique : isoprostanes et microARNs / Biocommunication between visceral adipose tissue and pancreatic beta-cell : isoprostanes and microRNAs Laget, Jonas 05 June 2019 (has links) Le diabète de type 2 résulte d’un déséquilibre entre les capacités de sécrétion de l’insuline par les cellules bêta-pancréatiques et son action au niveau de ses tissus cibles. Dans le prédiabète, l’hypersécrétion d’insuline compense l’insulino-résistance et cet état est généralement associé à l’obésité et à l’accumulation de tissu adipeux.L’objectif de ma thèse a été d’étudier la biocommunication entre le tissu adipeux viscéral et la cellule bêta-pancréatique lors du prédiabète et du diabète de type 2, en me focalisant sur deux médiateurs originaux, les isoprostanes et les miARNs. Nous avons observé une diminution de la sécrétion d’isoprostanes par le tissu adipeux péripancréatique au cours de l’obésité chez le rat Zucker fa/fa. Spécifiquement observé dans ce tissu adipeux ectopique, ce résultat s’explique par une induction des principales enzymes antioxydantes et une réduction de l’expression de la sPLA2 IIA chez les animaux obèses. Remarquablement, une des isoprostanes, la 15-F2t-Isoprostane ainsi que son épimère aux concentrations de 10 nM et 10 μM inhibent la sécrétion d’insuline gluco-stimulée dans les îlots pancréatiques isolés de rat Wistar. Cet effet pourrait s’expliquer par la liaison de cette isoprostane avec le récepteur au thromboxane A2, dont l’expression génétique et protéique a été mise en évidence pour la première fois dans les îlots de Langerhans et les cellules bêta. La réduction de l’inhibition de la sécrétion d’insuline chez le rat Zucker fa/fa, par une biocommunication paracrine, pourrait favoriser les mécanismes de compensation bêta-cellulaire. Par ailleurs, la production de miARNs, contenus dans des vésicules extracellulaires, par le tissu adipeux omental a été analysée chez l’homme par small RNAseq. Chez des patients obèses, la production de miARNs est modifiée lors de l’insulino-résistance et du diabète de type 2 avec des conséquences possibles sur la fonctionnalité des cellules bêta. Des miARNs différentiellement exprimés lors du diabète de type 2 pourraient ainsi participer à son apparition et représenter de nouveaux biomarqueurs et cibles thérapeutiques. Pour conclure, ces travaux de thèse ont permis de mettre en évidence de nouveaux mécanismes de biocommunication entre le tissu adipeux et les cellules bêta-pancréatiques. / Type 2 diabetes occurs as a result of an unability of pancreatic beta-cells to meet the insulin demand in its target tissues. During prediabetes insulin hypersecretion compensate for insulin resistance and this state is usually associated with obesity and excess body fat.The aim of my thesis was to study the biocommunication between visceral adipose tissue and pancreatic beta-cells during prediabetes and type 2 diabetes, with a focus on two original mediators, isoprostanes and miRNAs. We observed a decrease in isoprostane secretion by peripancreatic adipose tissue during obesity in Zucker fa/fa rats. In this ectopic adipose tissue, this observation may be related to an induction of some antioxidant enzymes and a reduction of the expression of sPLA2 IIA in obese animals. Remarkably, 15-F2t-Isoprostane as well as its epimer used at concentrations of 10 nM and 10 μM inhibited glucose-stimulated insulin secretion in isolated pancreatic islets. This effect could be explained by the binding of isoprostanes to the thromboxane A2 receptor, whose gene and protein expression has been demonstrated for the first time in islets and beta-cells. In Zucker fa/fa rats, less inhibition of insulin secretion through a paracrine biocommunication, could favor beta-cell compensatory mechanisms. Furthermore, the production of miRNAs, contained in extracellular vesicles released by omental adipose tissue, was analyzed in humans by small RNAseq. In obese patients, miRNAs production is altered during insulin resistance and type 2 diabetes with possible consequences for beta-cell function. Differentially expressed miRNAs in type 2 diabetes may participate in its development and represent novel biomarkers and therapeutic targets. In conclusion, this thesis highlighted new biocommunication mechanisms between adipose tissue and beta-pancreatic cells. Diabète de type 2 Biocommunication Cellule bêta-Pancréatique Tissu adipeux Isoprostanes MiARNs Type 2 diabetes Biocommunication Pancreatic beta-Cell Adipose tissue Isoprostanes MiRNAs
117	Étude de la régulation transcriptionnelle de Mlxipl par RFX6 et identification des gènes cibles dans les cellules bêta pancréatiques / Study of the transcriptional regulation of Mlxipl by RFX6 and identification of target genes in pancreatic beta cells Grans, Julia 05 April 2019 (has links) La fonction endocrine du pancréas est essentielle pour l'homéostasie du glucose parce que les îlots pancréatiques contiennent le seul type des cellules endocrines, nommées cellules bêta, qui sont capable de produire et sécréter de l’insuline. Le facteur de transcription RFX6, maintenu dans toutes les cellules endocrines matures, est essentiel pour le développement, l'identité et la fonction des cellules bêta. Chez l'homme, des mutations de RFX6 causent le syndrome de Mitchell-Riley, un trouble du développement caractérisé par un diabète néonatal et des malformations du système gastro-intestinal. La recherche des cibles de RFX6 dans les îlots murins a révélé que le facteur de transcription Mlxipl est directement régulé par RFX6. Dans cette thèse, nous avons étudié le mécanisme de la régulation transcriptionnelle de Mlxipl par RFX6 ainsi que les rôles de RFX6 et MLXIPL dans les cellules bêta adultes. Nous avons démontré que RFX6 se lie au premier intron de Mlxipl qui contient un motif de liaison (xbox) critique, et nous avons identifié les cofacteurs de ce processus. En comparant l’effet de la répression de Rfx6 et Mlxipl dans des milieux riches ou faibles en glucose dans la lignée cellulaire bêta Ins-1 832/13 sur le transcriptome, nous avons déterminé les programmes génétiques contrôlés par RFX6 et MLXIPL. / Pancreatic endocrine function is critical for glucose homeostasis because pancreatic islets contain the only cells of the body, the beta cells, capable of producing and secreting insulin. The transcription factor RFX6 is maintained in all mature islet cells and is as an essential regulator of beta cell development, identity and function. In humans, RFX6 mutations cause Mitchell-Riley syndrome, a developmental disorder characterized by neonatal diabetes and malformations of the digestive tract. The search for RFX6 targets in murine islets revealed that the transcription factor Mlxipl is directly regulated by RFX6. In this thesis, we investigated the mechanism of Mlxipl transcriptional regulation by RFX6, and the respective roles of RFX6 and its downstream target MLXIPL in adult beta cells. We demonstrated that RFX6 binds to the first intron of Mlxipl that contains a critical RFX binding motif (xbox), and we identified cofactors of this process. By comparing the changes in the transcriptomes linked to the loss of RFX6 or MLXIPL in the pancreatic beta cell line Ins-1 832/13 and the glucose level, we determined the genetic programs controlled by RFX6 and MLXIPL. Cellules bêta pancréatiques Diabète néonatal Régulation transcriptionnelle Expression Syndrome de Mitchell-Riley RFX6 Pancreatic beta cell Neonatal diabetes Transcriptional regulation Expression Mitchell-Riley syndrom RFX6 572.8 616.4
118	Studies of neuropeptides in pancreatic beta cell function with special emphasis on islet amyloid polypeptide (IAPP) Karlsson, Ella January 2000 (has links) <p>The presence of protein amyloid in pancreas and its association to diabetes was first described 100 years ago in 1901, but was not identified as Islet Amyloid Polypeptide (IAPP) until 1986. The aim of the present work was to determine the role of the beta cell hormone, IAPP, in normal pancreatic islet physiology and during early disturbances of islet function.</p><p>Intra-islet peptides, i.e. chromogranin peptides and an extra-islet peptide, i.e. leptin, were studied to identify possible endogenous regulators of IAPP and insulin secretion. Chromogranin-B, but not chromogranin-A or pancreastatin, had the ability to inhibit islet IAPP and insulin release, suggesting that chromogranin-B may serve as an autocrine regulator of IAPP and insulin secretion. </p><p>Leptin had a more potent effect on IAPP secretion than on insulin secretion, which was dissociated from effects on islet glucose metabolism. Glucose oxidation rates were increased at physiological leptin concentrations, whereas higher leptin concentrations showed an inhibitory effect and chronically high leptin concentrations had no effect.</p><p>Female NOD mice were studied to investigate the release of IAPP in the progression to type 1 diabetes. The release of IAPP was lower than that of insulin from immune cell infiltrated islets, indicating preferential insulin release during the early course of the disease. </p><p>IAPP is expressed at an early embryonic stage. The effect of IAPP on cell proliferation in neonatal rat islets was studied in the search for a physiological role of IAPP. IAPP concentrations of (1-1000) nM stimulated neonatal islet cell proliferation mostly in beta cells and to a lesser extent in alpha cells. IAPP did not have any marked effect on the islet cell death frequency. These data indicate a role for IAPP as a potential regulator of beta cell proliferation in neonatal pancreatic islet.</p><p>It is concluded that IAPP may be involved in regulation of pancreatic beta cell function both in fetal and adult life.</p> Cell biology alpha cell amylin beta cell chromogranin growth IAPP insulin islet amyloid polypeptide leptin NOD mice pancreastatin pancreatic islet proliferation Cellbiologi Cell biology Cellbiologi
119	The Stress Hypothesis : Implications for the induction of diabetes-related autoimmunity in children? Sepa, Anneli January 2004 (has links) Background: Second to Finland, Sweden has the world’s highest incidence of type 1 diabetes. Experiences of serious life events have retrospectively been shown to constitute a risk factor for the development of this disease, probably via the biological stress response. Parenting stress and maternal attachment insecurity are other important sources of stress in early childhood. Psychological stress increases the need for insulin and may induce insulin resistance, which might add extra pressure on the insulin-producing beta cells in the pancreas (beta-cell stress). The aim of the current thesis was to propose and start investigating a stress hypothesis – namely that psychological stress may induce insulin resistance leading to beta-cell stress, which could trigger an autoimmune reaction towards beta-cells in genetically predisposed children. When all the beta cells have been destroyed, insulin can no longer be produced in the body and type 1 diabetes becomes manifest. Methods: Families from the prospective population-based ABIS-project, which follows approximately 17 000 children, participated in the empirical studies of the current thesis. The mothers completed questionnaires, including various measures of psychological stress (e.g. parenting stress and experiences of serious life events) and socio-demographic background, at the birth of the child and when the child was 1 as well as 2.5 years of age. Maternal attachment insecurity was assessed with the Adult Attachment Interview. Blood samples drawn from the children at 1 and 2.5 years of age were analyzed for type 1 diabetes-related autoantibodies towards Tyrosine phosphatase (IA-2) and Glutamic Acid Decarboxylase (GAD). Findings and Conclusions: Parenting stress and experiences of serious life events like divorce and maternal exposure to violence were associated with the induction of diabetes-related autoimmunity in early childhood, possibly via insulin resistance and beta-cell stress. The risk of developing diabetesrelated autoimmunity after parental divorce or mothers’ exposure to violence was about threefold. None of the results were explained by any of the potential confounding factors analyzed. These results support and strengthen the stress hypothesis, which warrants further investigation. Mothers’ attachment insecurity was not associated with the induction of diabetes-related autoimmunity in their infants. However, this lack of association was perhaps due to methodological constraints. The vast majority of the parents were calmed or unaffected concerning their participation in the ABIS-project, suggesting that large-scale medical screening-projects in the general population are not in themselves a cause for worry and can be performed without causing increased anxiety. / On the day of the public defence the working title of article III was: Psychosocial correlates of parenting stress, lack of support and lack of confidence – A study of all babies in Southeast Sweden (ABIS). The status of article IV was: Manuscript to be submitted shortly; the status of article V was: Manuscript in preparation. Psychological stress parenting stress attachment security serious life events children attitudes Type I diabetes beta-cell autoantibodies prediction etiology Medicine Medicin
120	Studies of neuropeptides in pancreatic beta cell function with special emphasis on islet amyloid polypeptide (IAPP) Karlsson, Ella January 2000 (has links) The presence of protein amyloid in pancreas and its association to diabetes was first described 100 years ago in 1901, but was not identified as Islet Amyloid Polypeptide (IAPP) until 1986. The aim of the present work was to determine the role of the beta cell hormone, IAPP, in normal pancreatic islet physiology and during early disturbances of islet function. Intra-islet peptides, i.e. chromogranin peptides and an extra-islet peptide, i.e. leptin, were studied to identify possible endogenous regulators of IAPP and insulin secretion. Chromogranin-B, but not chromogranin-A or pancreastatin, had the ability to inhibit islet IAPP and insulin release, suggesting that chromogranin-B may serve as an autocrine regulator of IAPP and insulin secretion. Leptin had a more potent effect on IAPP secretion than on insulin secretion, which was dissociated from effects on islet glucose metabolism. Glucose oxidation rates were increased at physiological leptin concentrations, whereas higher leptin concentrations showed an inhibitory effect and chronically high leptin concentrations had no effect. Female NOD mice were studied to investigate the release of IAPP in the progression to type 1 diabetes. The release of IAPP was lower than that of insulin from immune cell infiltrated islets, indicating preferential insulin release during the early course of the disease. IAPP is expressed at an early embryonic stage. The effect of IAPP on cell proliferation in neonatal rat islets was studied in the search for a physiological role of IAPP. IAPP concentrations of (1-1000) nM stimulated neonatal islet cell proliferation mostly in beta cells and to a lesser extent in alpha cells. IAPP did not have any marked effect on the islet cell death frequency. These data indicate a role for IAPP as a potential regulator of beta cell proliferation in neonatal pancreatic islet. It is concluded that IAPP may be involved in regulation of pancreatic beta cell function both in fetal and adult life. Cell biology alpha cell amylin beta cell chromogranin growth IAPP insulin islet amyloid polypeptide leptin NOD mice pancreastatin pancreatic islet proliferation Cellbiologi Cell biology Cellbiologi

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