L’implication de SHP-1 en condition élevée de glucose inhibe la signalisation de l’insuline et du PDGF-BB dans les cellules musculaires lisses vasculaires hypoxiques / SHP-1 implication in high glucose concentration inhibits insulin and PDGF-BB signaling in hypoxic vascular smooth muscle cells

Paré, Martin

January 2016

Résumé : Bien que l’hypoxie soit un puissant inducteur de l’angiogenèse, l’activation des facteurs de croissance est perturbée en hyperglycémie au niveau du pied et du cœur. Cette perturbation entraîne la perte de prolifération et de migration chez les cellules endothéliales, musculaires lisses vasculaires et péricytes empêchant la formation de nouveaux vaisseaux qui mènera à l’amputation des membres inférieurs chez les patients diabétiques. Une étude a démontré qu’une augmentation de la protéine tyrosine phosphatase Src homology-2 domain-containing phosphatase-1 (SHP-1) en condition hyperglycémique chez les péricytes entraînait l’inhibition de la signalisation du PDGF-BB, ce qui résultait en le développement d’une rétinopathie diabétique. Nous avons alors soulevé l’hypothèse que l’expression de SHP-1 dans les cellules musculaires lisses vasculaires affecte la prolifération et la migration cellulaire par l’inhibition de la signalisation de l’insuline et du PDGF-BB en condition diabétique. Nos expérimentations ont été effectuées principalement à l’aide d’une culture primaire de cellules musculaires lisses primaires provenant d’aortes bovines. Comparativement aux concentrations normales de glucose (NG : 5,6 mM), l’exposition à des concentrations élevées de glucose (HG : 25 mM) pendant 48 h a résulté en l’inhibition de la prolifération cellulaire par l’insuline et le PDGF-BB autant en normoxie (20% O2) qu’en hypoxie (24 dernières heures à 1% O2). Lors des essais de migration cellulaire, aucun effet de l’insuline n’a été observé alors que la migration par le PDGF-BB fut inhibée en HG autant en normoxie qu’en hypoxie. L’exposition en HG à mener à l’inhibition de la signalisation de la voie PI3K/Akt de l’insuline et du PDGF-BB en hypoxie. Aucune variation de l’expression de SHP-1 n’a été observée mais son activité phosphatase en hypoxie était fortement inhibée en NG contrairement en HG où on observait une augmentation de cette activité. Finalement, une association a été constatée entre SHP-1 et la sous-unité bêta du récepteur au PDGF. En conclusion, nous avons démontré que l’augmentation de l’activité phosphatase de SHP-1 en hypoxie cause l’inhibition des voies de l’insuline et du PDGF-BB réduisant les processus angiogéniques des cellules musculaires lisses vasculaires dans la maladie des artères périphériques. / Abstract : Even though hypoxia is a strong angiogenic inducer, pro-angiogenic factor signaling pathways in peripheral limb and heart are altered by hyperglycemia. This disruption leads to loss of endothelial cells, vascular smooth muscle cells and pericytes proliferation and migration preventing new blood vessel formation which results in amputation of lower extremities in diabetic patients. A study has shown that increase expression of the protein tyrosine phosphatase Src homology-2 domain-containing phosphatase-1 (SHP-1) in hyperglycemic condition in pericytes caused PDGF-BB signaling inhibition resulting in the development of diabetic retinopathy. Our hypothesis is that SHP-1 expression in vascular smooth muscle cells inhibits cell proliferation and migration induced by insulin and PDGF-BB in diabetic condition. Our experiments were performed using primary culture of vascular smooth muscle cells (SMC) from bovine aortas. As compared to normal glucose concentrations (NG:5,6 mM), high glucose level (HG: 25 mM) exposure for 48h inhibited SMC proliferation induced by insulin and PDGF-BB in both normoxia (20% O2) or hypoxia (1% O2 for the last 24h). During cell migration assays, no effect of insulin was observed while PDGF-BB action of SMC migration was reduced in HG in both normal and low oxygen concentrations. HG exposure lead to inhibition of insulin- and PDGF-BB-stimulated PI3K/Akt signaling pathway in hypoxia. No variation of SHP-1 expression was observed in HG condition. However, SHP-1 phosphatase activity was elevated in HG condition during hypoxia as compared to NG concentrations. Finally, our data showed an association between SHP-1 and the PDGF receptor beta subunit. In conclusion, our results demonstrated that the increase of SHP-1 phosphatase activity in hyperglycemia and hypoxia environment caused inhibition of insulin and PDGF-BB signaling pathways reducing angiogenic processes in vascular smooth muscle cells contributing to peripheral arterial disease in diabetes.

Signalisation de l'insuline

Signalisation du PDGF-BB

Protéine tyrosine phosphatase

Récepteur à l'insuline

Récepteur au PDGF

SHP-1

Maladie des artères périphériques

Insulin signaling

PDGF-BB signaling

Protein tyrosine phosphatase

Insulin receptor

PDGF receptor

Peripheral arterial disease

O efeito do treinamento intervalado de alta intensidade em componentes celulares e moleculares relacionados ? resist?ncia ? insulina em indiv?duos obesos

Matos, Mariana Aguiar de

20 October 2016

Submitted by Jos? Henrique Henrique (jose.neves@ufvjm.edu.br) on 2017-04-27T15:00:50Z No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) mariana_aguiar_matos.pdf: 2901378 bytes, checksum: 40dbd704043d49a1eee587bb086c4eb4 (MD5) / Approved for entry into archive by Rodrigo Martins Cruz (rodrigo.cruz@ufvjm.edu.br) on 2017-05-16T19:24:00Z (GMT) No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) mariana_aguiar_matos.pdf: 2901378 bytes, checksum: 40dbd704043d49a1eee587bb086c4eb4 (MD5) / Made available in DSpace on 2017-05-16T19:24:00Z (GMT). No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) mariana_aguiar_matos.pdf: 2901378 bytes, checksum: 40dbd704043d49a1eee587bb086c4eb4 (MD5) Previous issue date: 2016 / Funda??o de Amparo ? Pesquisa do Estado de Minas Gerais (FAPEMIG) / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico (CNPq) / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior (CAPES) / O excesso de gordura corporal caracter?stico da obesidade est? relacionado a diversas altera??es metab?licas, que incluem a resist?ncia ? insulina. Dentre as medidas n?o farmacol?gicas empregadas para a melhora da sensibilidade ? insulina est? o treinamento f?sico aer?bio, como o treinamento intervalado de alta intensidade (HIIT, do ingl?s high intensity interval training). Sendo assim, esse estudo avaliou os efeitos do HIIT em componentes bioqu?micos, celulares e moleculares relacionados ? resist?ncia ? insulina em obesos. Indiv?duos obesos sens?veis (n=9) e resistentes ? insulina (n=8) foram submetidos a 8 semanas de HIIT, em cicloerg?metro, realizado 3 vezes por semana, com intensidade e volume progressivos (8 a 12 est?mulos; 80 a 110% da pot?ncia m?xima). Amostras de sangue venoso e do m?sculo vasto lateral foram obtidas antes e ap?s o programa de HIIT. Ap?s o programa de treinamento houve aumento da sensibilidade ? insulina nos obesos resistentes ? insulina, mas n?o houve redu??o da massa de gordura. A concentra??o de citocinas no soro, o estresse oxidativo sist?mico e frequ?ncia das c?lulas imunes n?o foram modificadas ap?s o treinamento. No m?sculo esquel?tico, o HIIT promoveu aumento da fosforila??o do substrato do receptor de insulina (IRS) (Tyr612), da Akt (Ser473) e da prote?na quinase dependente de c?lcio/calmodulina (CAMKII) (Thr286), e aumento do conte?do da ?-hidroxiacil-CoA desidrogenase (?-HAD) e citocromo C oxidase (COX-IV). Houve ainda, redu??o da fosforila??o da quinase regulada por sinal extracelular (ERK1/2) nos obesos resistentes ? insulina. Conclu?mos que 8 semanas de HIIT promoveram melhora da sensibilidade ? insulina, modificou componentes da via de sinaliza??o da insulina e do metabolismo oxidativo no m?sculo esquel?tico. Essas altera??es ocorreram independentes de mudan?as na gordura corporal total e de par?metros inflamat?rios sist?micos. / Tese (Doutorado) ? Programa Multic?ntrico de P?s-Gradua??o em Ci?ncias Fisiol?gicas, Universidade Federal dos Vales do Jequitinhonha e Mucuri, 2016. / Obesity is characterized by excess of body fat, and its development can lead to a variety of metabolic disorders, including insulin resistance. Exercise is recognized as a non-pharmacological approach to increasing skeletal muscle insulin sensitivity, although the mechanisms are not elucidated. Additionally, the understanding of high intensity interval training (HIIT, high intensity interval training) treat insulin resistance is less understood. Therefore, this study evaluated the effects of HIIT on biochemical, molecular, and cellular markers related to insulin resistance in sedentary obese individuals. Sensitive (n=9) and insulin resistant (n=8) obese individuals (body mass index ? 30 kg/m-2) were engaged in 8 weeks of HIIT using a cycle ergometer. The HIIT was performed 3 times a week, and its intensity and volume progressively increased throughout the training period (from 8 to 12 stimuli; from 80 to 110% of the maximum power). Venous blood and the vastus lateralis muscle samples were obtained before and after the HIIT. HIIT enhanced insulin sensitivity in insulin-resistant obese individuals without changing body fat mass. Cytokine concentration in serum, blood oxidative stress, and frequency of some immune cells were not altered by HIIT. In skeletal muscle, HIIT increased the phosphorylation of insulin receptor substrate (IRS) (Tyr612), Akt (Ser473), and protein kinase dependent calcium/calmodulin (CaMKII) (Thr286). HIIT also increased the expression of ?-hydroxyacyl-CoA dehydrogenase (?-HAD) and cytochrome C oxidase (COX-IV). A reduction of the kinase phosphorylation of extracellular signal-regulated (ERK1/2) was only seen in obese insulin resistant individuals. The results show that 8 weeks of HIIT enhanced insulin sensitivity, modified components of the insulin-signaling pathway, and improved skeletal muscle oxidative metabolism. These changes were independent of alterations in body fat and inflammatory parameters.

Obesidade

Resist?ncia ? insulina

HIIT

Via de sinaliza??o da insulina

Metabolismo oxidativo

Obesity

Insulin resistance

Insulin signaling pathway

Mitogen-activated protein kinases

Oxidative metabolism

Neuroendocrine Modulation of Complex Behavior and Physiology in C. elegans

Florman, Jeremy T.

30 September 2020

To survive, animals must adapt to a complex and challenging world in a way that is flexible and responsive, while maintaining internal homeostasis. Neuromodulators provide a means to systemically alter behavioral or physiological state based on intrinsic or extrinsic cues, however dysregulated neuroendocrine signaling has negative consequences for fitness and survival. Here I examine neuroendocrine function and dysfunction using the escape response in Caenorhabditis elegans. The RFamide neuropeptide FLP-18 is a co-transmitter with the monoamine tyramine and functions both synergistically and antagonistically to tyramine in coordinating escape behavior. Using behavioral analysis and calcium imaging, I show that FLP-18 functions primarily through the G-protein coupled receptor (GPCR) NPR-5 to increase calcium levels in muscle, enhancing locomotion rate, bending and reversal behavior during the escape response. Furthermore, I examine the relationship between persistent acute stress and resilience using repeated activation of the escape response as a model of neuroendocrine dysregulation. Repeated activation of the escape response shortens lifespan and renders animals more susceptible to thermal, oxidative, and nutritional stress. Tyramine release is necessary and sufficient for this effect and activity of the tyraminergic RIM neurons is differentially regulated by acute versus long-term stressors. Impaired stress resistance requires both the GPCR TYRA-3 in the intestine and intestinal neuropeptide release. Activation of the insulin receptor DAF-2 is downstream of TYRA-3 and inhibits the transcription factors DAF-16/FOXO, SKN-1/Nrf2 and HSF-1, linking monoamine signaling in acute stress to the insulin signaling pathway and impaired resilience to long-term stressors.

neuropeptides

neuromodulation

C. elegans

co-transmission

biogenic amines

fight or flight response

behavior

neuropeptide receptors

arousal

G-protein signaling

stress

insulin signaling

daf-16/FOXO

longevity

neural circuits

compound motor sequence

calcium

Behavioral Neurobiology

Endocrinology

Rôle des points de contact Réticulum Endoplasmique-Mitochondrie (MAMs) dans la régulation du métabolisme glucido-lipidique du foie et importance du Monoxyde d’Azote (NO) / Role of Endoplasmic Reticulum-Mitochondria Contact Points (MAMs) in the regulation of glucose and lipid metabolisms in the liver and the importance of nitric oxide (NO)

Bassot, Arthur

04 December 2019

Le réticulum endoplasmique et la mitochondrie sont deux organites majeurs impliqués dans la régulation du métabolisme glucido-lipidique. Ces structures interagissent au niveau de points de contact étroits appelés Mitochondria-Associated Endoplasmique Reticulum Membranes (MAMs). Les MAMs sont une zone de communication et d’échanges, de lipides et de calcium entre autre, indispensables à l’activité des deux organites et au maintien de l’homéostasie cellulaire. Des connexions physiques sont assurées par l’interaction de protéines complémentaires, comme le canal anionique voltage-dépendant (VDAC)-1, la protéine chaperonne (Grp)-75 et le récepteur de l'inositol 1,4,5-triphosphate (IP3R)-1, constituant un complexe impliqué dans le transfert de calcium. D’autres acteurs comme les mitofusines 1 et 2 (MFN1/2) assurent également un rapprochement entre les deux organites et semblent jouer un rôle dans les échanges des lipides. Récemment, les MAMs sont apparues comme un nouveau carrefour de la signalisation de l’insuline dans le foie. Le monoxyde d’azote (NO) participe également au contrôle de la réponse à l’insuline hépatique et a une action spécifique sur la mitochondrie. Mes travaux de thèse ont montré que le NO à des concentrations physiologiques module les interactions entre le RE et la mitochondrie dans le foie et que son action sur les MAMs implique la voie de signalisation sGC/cGMP/PKG. J’ai également démontré que la modulation des MAMs par le NO semble jouer un rôle clé dans la régulation de la voie de signalisation à l’insuline (projet1). Par ailleurs, j’ai exploré l’importance des MAMs dans la régulation du métabolisme lipidique. Pour cela, j’ai modulé l’expression protéique de Grp75 et Mfn2 sur un modèle d’hépatocarcinome humain (Huh7). Mes résultats ont montré qu’une surexpression des deux protéines améliore les MAMs et la β-oxydation mitochondriale mais conduit à une accumulation intracellulaire de lipides. Ceci serait dû à un défaut de sécrétion des lipides dans les lipoprotéines VLDL et pourrait impliquer l’apparition d’un stress mitochondrial et une altération des échanges de phospholipides entre les deux organites (projet 2). Par conséquence mon travail confirme le rôle physiologique des MAMs et éclaire les mécanismes d’actions de cette plateforme cellulaire dans la régulation du métabolisme glucido-lipidique hépatique. A plus long terme ces connaissances participeront peut-être à l’identification de potentielles cibles thérapeutiques afin de prévenir la stéatose et la résistance à l’insuline hépatiques et leurs complications / The endoplasmic reticulum and mitochondria are two major organelles involved in the regulation of glucose and lipid metabolism. These structures interact at close contact points called Mitochondria-Associated Endoplasmic Reticulum Membranes (MAMs). MAMs constitute an area of communication and exchange, of lipids and calcium among others, essential for the activity of both organelles and the maintenance of cellular homeostasis. Physical connections are ensured by the interaction of complementary proteins, such as the voltage-dependent anionic channel (VDAC)-1, the chaperone protein (Grp)-75 and the inositol 1,4,5-triphosphate receptor (IP3R)-1, constituting a complex involved in calcium transfer. Other actors such as mitofusins 1 and 2 (MFN1/2) also connect the two organelles and are involved in lipid exchanges. Recently, MAMs have emerged as a new carrefour for insulin signaling in the liver. Nitric oxide (NO) also helps control the response to hepatic insulin and has a specific action on mitochondria. My thesis work showed that NO at physiological concentrations modulates the interactions between RE and mitochondria in the liver and that its action on MAMs involves the sGC/cGMP/PKG signalling pathway. I also demonstrated that NO modulation of MAMs plays a key role in regulating the insulin signaling pathway (project 1). In addition, I explored the importance of MAMs in the regulation of lipid metabolism. For that purpose, protein expression of Grp75 and Mfn2 was modulated in a human hepatocarcinoma model (Huh7). Results showed that overexpression of both proteins improves MAMs and mitochondrial β-oxidation but leads to intracellular lipid accumulation. This could be due to a defect in lipid secretion in VLDL lipoproteins and could imply the appearance of mitochondrial stress and an alteration of phospholipid exchanges between the two organelles (project 2). Consequently, my work confirms the physiological role of MAMs and sheds light on the mechanisms of action of this cellular platform in the regulation of glucose and lipid metabolism in the liver. In the longer term, this knowledge may contribute to the identification of potential therapeutic targets to prevent steatosis and hepatic insulin resistance and their complications

Foie

Réticulum endoplasmique

Mitochondrie

MAMs

Monoxyde d’azote (NO)

Voie de signalisation de l’insuline

Métabolisme Glucido-lipidique

Stéatose

Liver

Endoplasmic reticulum

Mitochondria

MAMs

Nitric oxide (NO)

Insulin signaling pathway

Glucido-lipid metabolism

Steatosis

570

Insulin Stimulates Protein Synthesis via RTK-Induction of the Akt-s6k Pathway in Human and Canine Corneal Cells

Peterson, Cornelia WM

24 June 2019

No description available.

Biomedical Research

Cellular Biology

Molecular Biology

Ophthalmology