Nck1 is required for ER stress-induced insulin resistance and regulation of IRS1-dependent insulin signalling

Laberge, Marie-Kristine.

January 2008

No description available.

Protein Folding.

Insulin -- metabolism.

Insulin Resistance.

Insulin Receptor Substrate Proteins

Endoplasmic Reticulum -- metabolism.

RNA Expression of Receptors for Growth Hormone, Insulin-like Growth Factor 1, and Insulin in Mouse Whole Adipose Tissue, Stromal Vascular Fraction, and Adipocytes

Lesende , Vivian A.

January 2015

No description available.

Biology

Molecular Biology

adipose tissue

stromal vascular fraction

growth hormone

insulin-like growth factor 1

insulin receptor

mouse models

adipocytes

L’expression de SHP-1 induite par l’hyperglycémie inhibe les actions de l’insuline dans les podocytes / Expression of SHP-1 induced by hyperglycemia prevents insulin actions in podocytes

Drapeau, Nicolas

January 2014

Résumé : Les podocytes, cellules épithéliales rénales, sont nécessaires au maintien de la structure et de la fonction de filtration des glomérules rénaux. La dédifférenciation et l’apoptose des podocytes sont des évènements précoces de la néphropathie diabétique. Des études ont rapporté que l’insuline est nécessaire à la survie des podocytes puisque la délétion du récepteur à l’insuline dans les podocytes de souris entraîne une pathologie glomérulaire semblable à la néphropathie. D’autres études ont montré que la protéine tyrosine phosphatase Src homology-2 domain-containing phosphatase-1 (SHP-1) inhibe les voies de signalisation de l’insuline au niveau du foie et du muscle en déphosphorylant la sous-unité bêta du récepteur à l’insuline (IRβ) et la kinase Phosphatidylinositide 3-kinase (PI3K). Il a récemment été démontré que l’expression de SHP-1 est élevée dans les cortex rénaux de souris diabétiques. Nous avons donc émis l’hypothèse que l’expression de SHP-1 induite par l’hyperglycémie altère les actions de l’insuline dans les podocytes. Nous avons premièrement utilisé un modèle in vivo de souris diabétiques de type 1 (Ins2+/C96Y; Akita). Comparées aux souris contrôles (Ins2+/+), les souris Akita présentaient une apoptose élevée des podocytes ainsi qu’une perte des pédicelles. La phosphorylation de la protéine kinase B (Akt) et de Extracellular signal-regulated kinase 1/2 (ERK1/2), suite à une injection systémique d’insuline, était également significativement diminuée dans les cortex rénaux des souris Akita. Cette diminution correspondant à une résistance à l’insuline corrélait avec une augmentation de deux fois de l’expression de SHP-1 dans les glomérules. Nous avons ensuite utilisé une lignée immortalisée de podocytes murins en culture et avons observé que l’exposition à des concentrations élevées de glucose (HG; 25 mM) pendant 96 h, entraînait l’augmentation de l’expression de marqueurs apoptotiques et de l’activité enzymatique de caspase-3/7 en comparaison aux concentrations normales de glucose (NG; 5,6 mM). L’exposition en HG a augmenté l’expression de l’ARNm et protéique de SHP-1, en plus de réduire la signalisation de l’insuline dans les podocytes. La surexpression de la forme dominante-négative de SHP-1 dans les podocytes a permis de renverser les effets de HG et de restaurer les actions de l’insuline. Finalement, l’augmentation de l’expression de SHP-1, tant in vivo qu’in vitro, a été directement corrélée à son association avec IRβ et à la diminution de la phosphorylation de IRβ, Akt et ERK1/2 suite à une stimulation à l’insuline. En conclusion, nous avons montré que l’expression élevée de SHP-1 dans les glomérules cause une résistance à l’insuline et la mort des podocytes contribuant ainsi à la néphropathie diabétique. // Abstract : Podocytes are epithelial renal cells required to preserve glomerular structure and filtration. Their dedifferentiation and apoptosis are early events of diabetic nephropathy progression. Previous studies have shown that insulin action is critical for podocyte survival since deletion of its receptor lead to a glomerular pathology similar to nephropathy. It has also been demonstrated that Src homology-2 domain-containing phosphatase-1 (SHP-1), a protein tyrosine phosphatase, inhibits insulin signaling pathway in liver and muscle by dephosphorylating tyrosine residues on insulin receptor beta-subunit (IRβ) and the Phosphatidylinositide 3-kinase (PI3K). A recent study concluded that SHP-1 is elevated in kidney cortex of type 1 diabetic mice. We hypothesized that hyperglycemia-induced SHP-1 expression may affect insulin actions in podocytes. To confirm this hypothesis, we used type 1 diabetic Akita mice (Ins2+/C96Y). Compared to control littermate mice (Ins2+/+), Akita mice developed elevated podocyte foot process effacement and podocyte apoptosis. In contrast to control mice, insulin-stimulated protein kinase B (Akt) and extracellular signal-regulated kinase 1/2 (ERK1/2) phosphorylation was remarkably reduced in renal podocytes of Akita mice. This phosphorylation diminution associated to a renal insulin resistance was correlated with a two-fold increase of SHP-1 expression in the glomeruli. We then used cultured murine podocytes cell line to confirm our in vivo results. Podocytes exposed to high glucose concentration (HG; 25 mM) for 96 h exhibited high levels of apoptotic markers and caspase-3/7 enzymatic activity as compared to normal glucose concentration (NG; 5,6 mM). HG exposure raised mRNA and protein levels of SHP-1 and reduced the insulin-signaling pathway in podocytes. Overexpression of dominant-negative SHP-1 in podocytes prevented HG effects and restored insulin actions. Finally, elevated SHP-1 expression induced by high glucose levels was directly correlated to an increased association with insulin receptor-β subunit (IRβ) in vitro and in vivo. This association is therefore leading to the reduction of both IRβ phosphorylation and insulin-stimulated Akt and ERK phosphorylation. In conclusion, our results showed that high levels of SHP-1 in glomeruli cause insulin resistance and podocyte loss, thereby contributing to diabetic nephropathy.

Signalisation de l’insuline

Protéine tyrosine phosphatase

Récepteur à l’insuline

SHP-1

Néphropathie diabétique

Insulin signaling

Protein tyrosine phosphatase

Insulin receptor-β

Diabetic nephropathy

Insulin signalling in human adipocytes : mechanisms of insulin resistance in type 2 diabetes

Danielsson, Anna

January 2007

Prevalensen av fetma ökar drastiskt i stora delar av världen och utgör en stor riskfaktor för att utveckla insulinresistens och typ 2 diabetes. Fettväven kan bli mycket stor om för mycket energi tas upp av kroppen. Vid extrem övervikt är fettväven i kroppen i ett stresstillstånd, vilket gör att risken för att utveckla metabola sjukdomar som t.ex. typ 2 diabetes ökar. Fett lagras i olika fettdepåer i kroppen. Inlagringen i djupare kroppsdelar, runt och i inre organ s.k. visceralt fett, skiljer sig från fettväven som lagras direkt under huden s.k. subkutant fett. Nyare rön visar att mer visceral fettväv ökar risken för att utveckla insulinresistens och typ 2 diabetes. Fettcellen är tillsammans med muskel- och leverceller de viktigaste för glukosmetabolismen. Fettcellen är en stor cell, som man lätt kan se med blotta ögat. Storleken på ellerna varierar dock kraftigt i en och samma fettvävnad. Upptag av glukos från maten vi äter regleras av hormonet insulin. Insulinresistens är ett tillstånd då cellerna svarar dåligt på insulin, vilket gör att glukoshalten i blodet ökar. Detta förekommer vid typ 2 diabetes, men även vid andra tillstånd där cellerna blir stressade, t.ex. kirurgiska ingrepp. Insulinsignaleringen i fettcellen är komplex och signalöverföringen inne i cellen sker främst via en kaskad av fosforyleringar, där olika proteiner i en signalkedja fosforyleras eller defosforyleras. Slutligen leder denna fosforyleringskaskad till insulinets sluteffekter som t.ex. upptag av glukos, proteinsyntes och celltillväxt. Efter att insulin bundit till och fosforylerat/aktiverat insulinreceptorn delas signalen upp inne i cellen i två huvudvägar; den metabola signalvägen och den mitogena signalvägen. Insulinreceptorsubstrat 1, IRS1, är ett stort protein som insulinreceptorn verkar direkt på. Fosforylering av aminosyran tyrosin på IRS1 är mycket viktigt för fortsatt insulinsignalering i fettcellen. IRS1 fosforyleras även på aminosyran serin som svar på bl.a. insulin. Serinfosforyleringen av IRS1 hämmar eller stimulerar insulinsignaleringen, ofta genom återkoppling av insulinsignalen. Syftet med den här avhandlingen är att beskriva möjliga cellulära mekanismer i insulinsignaleringen vid insulinresistens som resultat av kirurgisk stress eller vid typ 2 diabetes i fettceller från människa. Häri har upptaget av glukos analyserats och jämförts i fettceller från olika fettdepåer. Viscerala fettceller har högre basalt och insulinstimulerat glukosupptag och mer glucostransportörprotein än subkutana fettceller. Däremot är det ingen skillnad i insulinkänslighet angående glukosupptaget i de olika typerna av fettceller. Vidare fann vi att den kirurgiskt orsakade insulinresistensen hos subkutana fettceller från människa återgår till det normala efter övernattinkubering av cellerna i odlingsmedium. Insulinresistensen vid typ 2 diabetes är däremot permanent och har en annan mekanism än den reversibla, stress-relaterade insulinresistensen. Insulinresistansen vid typ 2 diabetes beror på att signalöverföringen mellan olika proteiner i cellen är defekt. Insulinreceptorns förmåga att fosforylera IRS1 på aminosyran tyrosin är nedsatt hos patienter med typ 2 diabetes. Fosforyleringen av IRS1 på serin 307 (i den humana sekvensen) ökar snabbt hos icke-diabetiska fettceller som svar på insulin. Denna serinfosforylering verkar behövas för att IRS1 effektivt ska tyrosinfosforyleras och därmed leda insulinsignalen vidare inne i cellen. Fosforyleringen av IRS1 på serin 307 är kraftigt nedsatt hos subkutana fettceller från patienter med typ 2 diabetes. Fosforyleringen av IRS1 på serin 312 är däremot liknande i fettceller från icke-diabetiker och diabetiker (Öst et.al. (2007) Faseb.J. doi: 10.1096/fj.07-8173com). Fosforyleringen av IRS1 på serin 312 är mest involverad i insulinsignaleringens negativa återkoppling. Fosforyleringen av serin 307 sker snabbt och vid låga insulinkoncentrationer, medan fosforyleringen på serin 312 sker först efter lång inkubering och vid höga insulinkoncentrationer. Detta är en ny mekanism på cellulär nivå som möjligen kan beskriva insulinresistansen i fettceller från människa. Tillsammans styrs återkopplingen via den stimulerande fosforyleringen (serin 307) eller den hämmande fosforyleringen (serin 312) och kontrollerar insulinsignaleringen i cellen. Fosforyleringarna sker möjligen via samma proteinkinas och/eller proteinfosfatas och kan bli mål för terapeutiska läkemedel mot typ 2 diabetes i framtiden. / The prevalence of obesity is increasing in most parts of the world and is a strong risk factor for the development of insulin resistance and type 2 diabetes. Adipose tissue is important in whole body energy balance and grows in size with excess energy intake. Adipose tissue in different regions of the body has different characteristics and adipocytes coming from intraabdominal fat depots, are more associated with insulin resistance than adipocytes from subcutaneous fat depots. Insulin signalling is complex and consists of two major signalling pathways in the cell; the metabolic signalling pathway and the mitogenic signalling pathway. After insulin binding to the insulin receptor a cascade of protein phosphorylations and dephosphorylations is started, eventually leading to the target effects of the hormone. Tyrosine phosphorylation of insulin receptor substrate 1 (IRS1), a protein directly downstream of the insulin receptor, is essential for further insulin signalling. Serine phosphorylation of IRS1 also affects insulin signalling through inhibitory or stimulatory effects. Adipocytes are together with muscle cells and liver cells central in the development of type 2 diabetes. The focus of this thesis is to describe mechanisms in insulin signalling in primary human adipocytes in insulin resistant states, surgical stress or type 2 diabetes. Visceral adipocytes from humans were analysed and compared to subcutaneous adipocytes. Visceral adipocytes were slightly bigger than subcutaneous adipocytes. Furthermore, visceral adipocytes had an increased level of the glucose transporterprotein GLUT4 and a higher basal and insulin-stimulated glucose uptake, but the sensitivity to insulin was the same. Here it was found that surgical insulin resistance is reversible after overnight incubation of the adipocytes and the impaired insulin sensitivity is at the level between IRS1 and PKB/Akt in insulin signalling. In contrast, the insulin resistance in type 2 diabetes is irreversible and the impaired insulin sensitivity is at the level of insulin receptor-mediated tyrosine phosphorylation of IRS1. Adipocytes from patients with type 2 diabetes were investigated and it was found that diabetic adipocytes have an attenuated insulin-stimulated phosphorylation of IRS1 at serine 307 (corresponding to serine 302 in the mouse sequence). In adipocytes from non-diabetic individuals, the phosphorylation of IRS1 at serine 307 occurred rapidly at low concentrations of insulin. This phosphorylation was associated with the tyrosine phosphorylation of IRS1. The phosphorylation of IRS1 at serine 312 (corresponding to serine 307 in the mouse sequence) in response to insulin was similar in adipocytes from non-diabetic individuals and from patients with type 2 diabetes (Öst et.al. (2007) Faseb.J. doi: 10.1096/fj.07-8173com) and occurred only at high concentrations after prolonged incubation with insulin. This thesis reports the investigation of mechanisms in insulin signalling at a cellular and molecular level in primary human adipocytes. The insulin resistance resulted from surgical stress is different from that in type 2 diabetes and adipocytes from patients with type 2 diabetes have impaired insulin sensitivity at the level of IRS1. Together, the phosphorylation of IRS1 at serine 307 and serine 312 may control insulin signalling through feedback mechanisms in primary human adipocytes.

adipocytes

type 2 diabetes

insulin

insulin resistance

insulin signalling

phosphorylation

insulin receptor substrate 1

feedback control

Medical cell biology

Medicinsk cellbiologi

ROLE OF SECOND MESSENGER SIGNALING PATHWAYS IN THE REGULATION OF SARCOPLASMIC RETICULUM CALCIUM-HANDLING PROPERTIES IN THE LEFT VENTRICLE AND SKELETAL MUSCLES OF DIFFERENT FIBRE TYPE COMPOSITION

Duhamel, Todd A D

January 2007

The overall objective of this thesis was to examine mechanisms involved in the acute regulation of sarcoplasmic reticulum (SR) Ca2+-handling properties by second messenger signaling pathways in skeletal and cardiac muscle. The aim of the first study (Chapter Two) was to characterize changes in the kinetic properties of sarco(endo)-plasmic reticulum Ca2+-ATPase (SERCA) proteins in cardiac and skeletal muscles in response to b-adrenergic, Ca2+-dependent calmodulin kinase II (CaMKII) and protein kinase C (PKC) signaling. The aim of the second study (Chapter Three) was to determine if insulin signaling could acutely regulate SERCA kinetic properties in cardiac and skeletal muscle. The aim of the final study (Chapter Four) was to determine if alterations in plasma glucose, epinephrine and insulin concentrations during exercise are able to influence SR Ca2+-handling properties in contracting human skeletal muscle. Data collected in Chapter Two and Chapter Three were obtained using tissue prepared from a group of 28 male Sprague-Dawley rats (9 weeks of age; mass = 280 ?? 4 g: X ?? S.E). Crude muscle homogenates (11:1 dilution) were prepared from selected hind limb muscles (soleus, SOL; extensor digitorum longus, EDL; the red portion of gastrocnemius, RG; and the white portion of gastrocnemius, WG) and the left ventricle (LV). Enriched SR membrane fractions, prepared from WG and LV, were also analyzed. A spectrophotometric assay was used to measure kinetic properties of SERCA, namely, maximal SERCA activity (Vmax), and Ca2+-sensitivity was characterized by both the Ca50, which is defined as the free Ca2+-concentration needed to elicit 50% Vmax, and the Hill coefficient (nH), which is defined as the relationship between SERCA activity and Ca2+f for 10 to 90% Vmax. The observations made in Chapter Two indicated that b-adrenergic signaling, activated by epinephrine, increased (P<0.05) Ca2+-sensitivity, as shown by a left-shift in Ca50 (i.e. reduced Ca50), without altering Vmax in LV and SOL but had no effect (P<0.05) on EDL, RG, or WG. Further analysis using a combination of cAMP, the PKA activator forskolin, and/or the PKA inhibitor KT5270 indicated that the reduced Ca50 in LV was activated by cAMP- and PKA-signaling mechanisms. However, although the reduced Ca50 in SOL was cAMP-dependent, it was not influenced by a PKA-dependent mechanism. In contrast to the effects of b-adrenergic signaling, CaMKII activation increased SERCA Ca2+-sensitivity, as shown by a left-shift in Ca50 and increased nh, without altering SERCA Vmax in LV but was without effect in any of the skeletal muscles examined. The PKC activator PMA significantly reduced SERCA Ca2+-sensitivity, by inducing a right-shift in Ca50 and decreased nH in the LV and all skeletal muscles examined. PKC activation also reduced Vmax in the fast-twitch skeletal muscles (i.e. EDL, RG and WG), but did not alter Vmax in LV or SOL. The results of Chapter Three indicated that insulin signaling increased SERCA Ca2+-sensitivity, as shown by a left-shift in Ca50 (i.e. reduced Ca50) and an increased nH, without altering SERCA Vmax in crude muscle homogenates prepared from LV, SOL, EDL, RG, and WG. An increase in SERCA Ca2+-sensitivity was also observed in enriched SERCA1a and SERCA2a vesicles when an activated form of the insulin receptor (A-INS-R) was included during biochemical analyses. Co-immunoprecipitation experiments were conducted and indicated that IRS-1 and IRS-2 proteins bind SERCA1a and SERCA2a in an insulin-dependent manner. However, the binding of IRS proteins with SERCA does not appear to alter the structural integrity of the SERCA Ca2+-binding site since no changes in NCD-4 fluorescence were observed in response to insulin or A-INS-R. Moreover, the increase in SERCA Ca2+-sensitivity due to insulin signaling was not associated with changes in the phosphorylation status of phospholamban (PLN) since Ser16 or Thr17 phosphorylation was not altered by insulin or A-INS-R in LV tissue. The data described in Chapter Four was collected from 15 untrained human participants (peak O2 consumption, VO2peak= 3.45 ?? 0.17 L/min) who completed a standardized cycle test (~60% VO2peak) on two occasions during which they were provided either an artificially sweetened placebo (PLAC) or a 6% glucose (GLUC) beverage (~1.00 g CHO per kg body mass). Muscle biopsies were collected from the vastus lateralis at rest, after 30 min and 90 min of exercise and at fatigue in both conditions to allow assessment of metabolic and SR data. Glucose supplementation increased exercise ride time by ~19% (137 ?? 7 min) compared to PLAC (115 ?? 6 min). This performance increase was associated with elevated plasma glucose and insulin concentrations and reduced catecholamine concentrations during GLUC compared to PLAC. Prolonged exercise reduced (p<0.05) SR Ca2+-uptake, Vmax, Phase 1 and Phase 2 Ca2+-release rates during both PLAC and GLUC. However, no differences in SR Ca2+-handling properties were observed between conditions when direct comparisons were made at matched time points between PLAC and GLUC. In summary, the results of the first study (Chapter Two) indicate that b-adrenergic and CaMKII signaling increases SERCA Ca2+-sensitivity in the LV and SOL; while PKC signaling reduces SERCA Ca2+-sensitivity in all tissues. PKC activation also reduces Vmax in the fast-twitch skeletal muscles (i.e. EDL, RG, and WG) but has no effect on Vmax in the LV and SOL. The results of the second study (Chapter Three) indicate that insulin signaling acutely increases the Ca2+-sensitivity of SERCA1a and SERCA2a in all tissues examined, without altering the Vmax. Based on our observations, it appears that the increase in SERCA Ca2+-sensitivity may be regulated, in part, through the interaction of IRS proteins with SERCA1a and SERCA2a. The results of the final study (Chapter Four) indicate that alterations in plasma glucose, epinephrine and insulin concentrations associated with glucose supplementation during exercise, do not alter the time course or magnitude of reductions in SERCA or Ca2+-release channel (CRC) function in working human skeletal muscle. Although glucose supplementation did increase exercise ride time to fatigue in this study, our data does not reveal an association with SR Ca2+-cycling measured in vitro. It is possible that the strength of exercise signal overrides the hormonal influences observed in resting muscles. Additionally, these data do not rule out the possibility that glucose supplementation may influence E-C coupling processes or SR Ca2+-cycling properties in vivo.

Rôle du jeûne et de la perturbation de la cascade de signalisation de l'insuline sur le clivage du précurseur de la protéine amyloïde (APP)

Licea, Sara

09 1900

La maladie d’Alzheimer est majoritairement sporadique et peu est connu sur les mécanismes déclenchant le développement de cette forme de la maladie. Les études sur la forme familiale ont attribué une importance particulière à la bêta-amyloïde (Aβ), un produit de clivage du précurseur de la protéine amyloïde (APP). Plusieurs facteurs de risques ont été identifiés comme déclencheurs potentiels du développement de la maladie d’Alzheimer dont le diabète de type II (T2D). En effet, la déficience de la signalisation de l’insuline par la désensibilisation des récepteurs de l’insuline (IR) dans le cerveau semble être une caractéristique commune aux deux maladies. Les effets à long terme de la résistance à l’insuline sur l’accumulation d’Aβ et sur la phosphorylation de Tau ont été étudiés, mais les effets de la perturbation aiguë des IR sont moins bien caractérisés. Aussi, les désordres métaboliques sont également des caractéristiques communes aux deux maladies. Le but de notre étude est de déterminer si la perturbation aiguë des IR peut affecter le clivage de l’APP et si la privation énergétique par le jeûne peut sensibiliser ce clivage à la perturbation aiguë des IR. Pour évaluer ceci, nous avons utilisé la Tyrphostin AG1024 à faible dose pour simuler une perturbation des IR plutôt qu’un blocage complet des récepteurs. Pour quantifié le clivage de l’APP, nous avons mesuré les changements de la quantité d’APP taille pleine totale par immunobuvardage de type Western. Pour s’assurer que les changements de la quantité d’APP taille pleine traduisait bien un clivage, nous avons développé un système de lecture par luciférase. Ce système nous permet de suivre le clivage de l’APP via l’expression de la luciférase Firefly puisque le facteur de transcription GAL4 est lié à la portion C-terminale de l’APP . Tout d’abord, nous avons observé que la perturbation aiguë des IR par la Tyrphostin mène au clivage de l’APP et que le jeûne augmente la vulnérabilité au clivage de l’APP suite à une plus petite dose de Tyrphostin. Ce clivage serait imputable à la voie amyloïdogénique puisque l’inhibition de la β-secrétase et de la γ-secrétase empêche le clivage de l’APP. Nous avons aussi montré que la perturbation des IR est nécessaire alors que la perturbation spécifique des IGF-1R n’est pas suffisante. De plus, ni l’autophagie, ni les caspases et ni le protéasomes ne semblent impliqués dans le clivage de l’APP suivant la combinaison du jeûne et de la petite perturbation des IR. L’activité de mTOR n’est également pas requise. Cependant, l’activité de la GSK3 est nécessaire au clivage et semble affecter le clivage par la γ-secrétase. Nous avons ensuite confirmé dans des cultures primaires neuronales que la combinaison du jeûne et de la perturbation aiguë des IR cause le clivage de l’APP et que la GSK3 est encore une fois fortement active. Ainsi, nos résultats suggèrent que la perturbation de la signalisation de l’insuline tel qu’observé dans le T2D augmente le clivage de l’APP via la voie amyloïdogénique et, donc, contribue à la pathologie de la maladie d’Alzheimer. / Little is known about the mechanisms that trigger the onset of Alzheimer’s disease (AD), a primarily sporadic disease. Studies on the familial form of AD attributed a particular importance to Amyloid beta (Aβ), a cleavage product of the Amyloid precursor protein (APP). Many risk factors have been identified as potential triggers of the development of AD including Type 2 diabetes (T2D). Indeed, the impairment of insulin signaling by the desensitization of insulin receptors (IR) in the brain seems to be a common hallmark of both diseases. The long term effects of IR resistance on the accumulation of Aβ and Tau hyperphosphorylation have been studied, but the acute effects of IR perturbation is less characterized. Also, both diseases show metabolic defects. Our research aimed to determine whether acute perturbation of IR signaling affects APP processing and if starving (energy deprivation) could sensitize this processing to acute perturbation of IR. To assess this, we used small doses of Tyrphostin AG1024 to simulate IR perturbations rather than a complete blocakade of the receptors. To quantify APP processing, we measured the change of total full- lenght APP by Western blot. To ensure that this change reflected APP processing we developed a luciferase based readout system. This system allowed us to monitor the occurrence of APP cleavage via GAL4-UAS Firefly luciferase driven expression because we linked GAL4 transcription factor to the C-terminal region of APP. First, we showed that IR perturbation with Tyrphostin leads to APP processing and that starving increased IR susceptibility to a smaller doses of Tyrphostin. This APP processing occurs via the amyloidogenic pathway because inhibition of β- and γ-secretase inhibited APP processing. We showed that this processing absolutely requires IR perturbation, while IGF-1R perturbation alone is insufficient. Furthermore, neither autophagy, caspases nor proteasome seemed to be implicated in APP processing following starvation and small IR perturbation. The activity of mTOR is also not required. On the contrary, GSK3 activation is necessary for the processing and seems to affect γ-secretase cleavage. We then confirmed in primary cultured neurons that the combination of acute starvation and small IR perturbation causes APP cleavage and GSK3 is again strongly activated. Taken together, our results suggest that the impairment of IR signalling seen in T2D increases the processing of APP via the amyloidogenic pathway and thereby contributes to the pathology of AD.

Alzheimer

APP

GSK3

diabète

signalisation de l'insuline

vulnérabilité

jeûne

Alzheimer’s disease

Diabetes

Starving

Susceptibility

Insulin receptor signaling

Couplage "complexe récepteur de l'élastine / récepteur de l'insuline" : la désialylation des glycanes comme facteur d'insulino résistance / Elastin complex receptor / Insulin receptor : the glycan desialylation as an insulin-resistance factor

Guillot, Alexandre

30 January 2017

Longtemps considérée comme un simple support mécanique, la matrice extracellulaire (MEC) est un élément majeur dans le maintien de l’homéostasie. Ainsi l’élastine, principal constituant de la MEC des gros vaisseaux élastiques, est dégradée au cours du vieillissement, produisant ainsi des peptides d’élastine bioactifs (PE). Plusieurs études ont démontré l'implication des PE en physiopathologies tels que l’invasion tumorale, l’athérosclérose ou l’insulino-résistance (IRes). Ces effets s’expliquent par l’activation du complexe récepteur de l’élastine (CRE), composé par : une sous-unité extracellulaire liant les PE (EBP, elastin binding protein), la cathepsine A (dont le rôle reste inconnu), et la neuraminidase 1 (induisant la signalisation intracellulaire). L'IRes décrite, pourrait être associée à l’activité de désialylation de la neuraminidase-1 sur les chaines de N-glycosylation (Ng-c) du récepteur de l’insuline (RI). Sur la base de cette hypothèse, notre objectif a donc été de confirmer ce mécanisme et ses conséquences in silico (sur le RI), in vitro (pré-adipocytes 3T3-L1) et in vivo (aorte de souris). Nous montrons ainsi in vitro que les PE provoquent un dysfonctionnement de l’autophosphorylation du RI se répercutant sur plusieurs processus cellulaires comme l’entrée du glucose ou encore la différenciation adipocytaire. In silico, nous montrons pour la première fois le rôle des acides sialiques sur le comportement des Ng-c d'une part et sur le RI d'autre part. Enfin, in vivo, cette interaction CRE / IR engendre une hypertension artérielle par une diminution de la vasorelaxation des cellules endothéliales. / Often considered as a simple mechanical support, the extracellular matrix (ECM) is a major element of homeostasis regulation. Thus, elastin, the main constituent of large elastic vessels, is degraded during aging, producing bioactive elastin-derived-peptides (EDP). Several studies have demonstrated the EDP effects in physiopathologies such as tumor invasion, atherosclerosis, or insulin resistance (IRes) development. Those effects are explained by the activation of the elastin receptor complex (CRE), composed of: an extracellular subunit binding EDP (EBP, elastin binding protein), cathepsin A (its role is still unknown) and the sialidase neuraminidase-1 (Neu-1, involved in signaling pathway induction). Interestingly, the lab suggested that IRes may be induced by the desialylation of the N-glycan chains (Ng-c) on the insulin receptor (IR). The aim of this study was to confirm this hypothesis by demonstrating the consequence of desialylation on the IR in silico, on a 3T3-L1 pre-adipocyte cell in vitro, and on vascular complications in vivo. We show that EDP induce in vitro an impairment of IR autophosphorylation, affecting glucose uptake and adipocyte differentiation. In silico approach demonstrates the role of sialic acids on the behavior of Ng-c in the one hand and in other hand of IR. Finally, the IRes induced by ERC-IR interaction increase the vascular complication such as arterial hypertension by endothelial cell impairment. To conclude, Ng-c alteration would likely be responsible for structural changes in the IR at the origin of insulin resistance.

Insulino-Résistance

Récepteur de l'insuline

Peptides d'élastine

Cre

N-Glycosylations

Insulin resistance

Insulin receptor

Elastin derived peptides

Cre

N-Glycan chains

610.72

Investigação do efeito da inibição farmacológico de IGF1R-IRS1/2 no fenótipo de células leucêmicas BCR-ABL1+ / Investigation of the effects of IGF1R-IRS1/2 pharmacological inhibition on the phenotype of BCR-ABL1+ leukemic cells

Ribeiro, Renata Scopim

19 September 2017

Leucemia mieloide crônica (LMC) é uma neoplasia hematológica maligna associada à atividade tirosinoquinase da oncoproteína BCR-ABL1. A maioria dos casos de LMC é tratada com sucesso com inibidores tirosinoquinase de BCR-ABL1, mas uma porcentagem significativa de pacientes desenvolve resistência ao fármaco. Estudos recentes indicam que a célula-tronco leucêmica é resistente ao tratamento com imatinibe. A identificação de outras proteínas que cooperam com as vias de sinalização BCR-ABL1 podem indicar novos alvos terapêuticos. Os substratos do receptor de insulina (IRS) têm emergido como proteínas importantes na fisiopatologia de neoplasias sólidas e hematológicas. Um inibidor farmacológico de IGF1R-IRS1/2, NT157, foi desenvolvido e mostrou resultados promissores em estudos pré-clínicos com tumores sólidos. A associação constitutiva de IRS1 com BCRABL1 e o efeito antineoplásico resultante do silenciamento espefício de IRS1 em células K562 BCR-ABL1+ suportam a hipótese deste trabalho. O objetivo do presente estudo foi investigar o efeito da inibição farmacológica de IGF1R-IRS1/2 no fenótipo de células hematopoéticas leucêmicas BCR-ABL1+ utilizando células primárias, células K562 e modelos murinos. IRS1, mas não IRS2, apresentou-se menos expresso em amostras de medula óssea de pacientes com diagnóstico de LMC quando comparadas às amostras de células hematopoéticas normais (p<0,0001). NT157 reduziu a formação de colônias de células primárias de pacientes com LMC, mas não de células hematopoéticas de indivíduos saudáveis. Em células K562, o tratamento com o inibidor farmacológico de IGF1R-IRS1/2, NT157, reduziu a viabilidade e proliferação celular e induziu apoptose (p<0,05), inibiu a fosforilação de IGF1R, STAT3, STAT5, 4EBP1, P70S6K e ERK1/2, aumentou a expressão dos genes supressores de tumor CDKN1A, FOS e JUN e reduziu a expressão dos oncogenes MYC e BCL2 (p<0,05); a inibição específica de IRS1 através de lentivírus, mas não de IRS2, reduziu a viabilidade celular (p<0,05). Em células murinas Ba/F3 BCR-ABL1 e BCRABL1T315I, o inibidor farmacológico de IGF1R-IRS1/2, NT157, induziu apoptose e reduziu ativação de ERK1/2 in vitro. Na dose de 50mg/kg/dia, NT157 intraperitoneal e/ou imatinibe por gavagem falharam em reduzir o crescimento tumoral in vivo em modelo de tumor alográfico induzido por células Ba/F3 BCR-ABL1 e BCR-ABL1T315I. Em modelo animal de leucemia induzido por transplante de células hematopoéticas transduzidas com BCR-ABL1: (i) o tratamento com NT157 100mg/kg intraperitoneal, 3 vezes por semana, combinado com imatinibe 100mg/kg/dia por gavagem, reduziu significativamente o peso do baço, e preveniu a perda de peso comparado com veículo (p<0,05); apenas a monoterapia com imatinibe prolongou a sobrevida dos animais, (ii) o tratamento com NT157 70mg/kg intraperitoneal, 3 vezes por semana, e/ou imatinibe 70mg/kg/dia por gavagem não teve impacto no peso do baço e na variação do peso corporal; o tratamento com imatinibe em monoterapia ou combinado com NT157 prolongou a sobrevida dos animais (p<0,05). Em conclusão, o inibidor farmacológico de IGF1R-IRS1/2 representa uma droga potencialmente eficaz no tratamento da LMC, especialmente em casos de resistência com mutação BCR-ABL1 T315I. A avaliação da eficácia do inibidor farmacológico NT157 em modelos animais de LMC exige ajustes nos modelos murinos utilizados no presente estudo, melhor entendimento da farmacodinâmica e farmacocinética do composto e ajustes no esquema terapêutico utilizado. / Chronic myeloid leukemia (CML) is a hematological malignancy associated with the tyrosine kinase activity of the BCR-ABL1 oncoprotein. Most cases of CML are successfully treated with BCR-ABL1 tyrosine kinase inhibitors, but a significant percentage of patients develop resistance. Recent studies indicate that leukemic stem cell is resistant to imatinib treatment. The identification of other proteins that cooperate with the BCR-ABL1 signaling pathway may indicate novel therapeutic targets. Insulin receptor substrates (IRS) have emerged as important proteins in the pathophysiology of solid and hematological neoplasms. A pharmacological inhibitor of IGF1R-IRS1/2, NT157, has been developed and shown promising results in preclinical studies with solid tumors. The constitutive association of IRS1 with BCR-ABL1, and the antineoplastic effects resulting from IRS1-specific silencing in K562 BCR-ABL1+ cells, support the hypothesis of this work. The aim of the present study was to investigate the effect of pharmacological inhibition of IGF1R-IRS1/2 on the phenotype of BCR-ABL1+ leukemia cells, using primary cells, K562 cell line and murine models. IRS1, but not IRS2, was downregulated in bone marrow samples from CML patients compared to bone marrow cells from healthy donors (p<0.0001). NT157 reduced colony formation of primary cells from CML patients but not from healthy donors. In K562 cells, treatment with the pharmacological inhibitor IGF1R-IRS1/2, NT157, reduced cell viability and proliferation, induced apoptosis (p<0.05), inhibited the phosphorylation of IGF1R, STAT3, STAT5, 4EBP1, P70S6K and ERK1/2, increased expression of tumor suppressor genes CDKN1A, FOS and JUN, and reduced expression of oncogenes MYC and BCL2 (p<0.05); IRS1 silencing mediated by lentivirus, but not IRS2, reduced cell viability (p<0.05). In murine Ba/F3 BCRABL1 and Ba/F3 BCR-ABL1T315I cells, the pharmacological inhibitor of IGF1R-IRS1/2, NT157, induced apoptosis and reduced ERK1/2 activation in vitro. At 50mg/kg/day, NT157 intraperitoneally and/or imatinib orally, failed to reduce tumor burden in vivo in an allographic tumor model induced by Ba/F3 BCR-ABL1 and Ba/F3 BCR-ABL1T315I cells . In an animal leukemia model induced by transplantation of BCR-ABL1-transduced hematopoietic cells : (i) treatment with NT157 100mg/kg intraperitoneally, 3 times per week, combined with imatinib 100mg/kg/day per gavage, significantly reduced spleen weight, and prevented weight loss compared to vehicle (p<0.05); only imatinib monotherapy prolonged survival (p<0.05), (ii) treatment with NT157 70 mg/kg intraperitoneally, 3 times per week, and/or imatinib 70 mg/kg/day per gavage had no impact on spleen weight and body weight; treatment with imatinib alone or combined with NT157 prolonged survival (p<0.05). In conclusion, the pharmacological inhibitor of IGF1R-IRS1/2 represents a potential effective drug in CML therapy, especially in cases of resistant BCR-ABL1 T315I mutation. The evaluation of the NT157 pharmacological efficacy in CML animal models requires adjustments in the murine models used in the present study, better understanding of the pharmacodynamics and pharmacokinetics of the compound and adjustments in the therapeutic scheme used.

BCR-ABL1

BCR-ABL1

Chronic Myeloid Leukemia

Insulin receptor substrates

IRS1

IRS1

Leucemia Mieloide Crônica

NT157

NT157

Substratos do receptor de insulina

T315I

T315I

Investigação do efeito da inibição farmacológico de IGF1R-IRS1/2 no fenótipo de células leucêmicas BCR-ABL1+ / Investigation of the effects of IGF1R-IRS1/2 pharmacological inhibition on the phenotype of BCR-ABL1+ leukemic cells

Renata Scopim Ribeiro

19 September 2017

Leucemia mieloide crônica (LMC) é uma neoplasia hematológica maligna associada à atividade tirosinoquinase da oncoproteína BCR-ABL1. A maioria dos casos de LMC é tratada com sucesso com inibidores tirosinoquinase de BCR-ABL1, mas uma porcentagem significativa de pacientes desenvolve resistência ao fármaco. Estudos recentes indicam que a célula-tronco leucêmica é resistente ao tratamento com imatinibe. A identificação de outras proteínas que cooperam com as vias de sinalização BCR-ABL1 podem indicar novos alvos terapêuticos. Os substratos do receptor de insulina (IRS) têm emergido como proteínas importantes na fisiopatologia de neoplasias sólidas e hematológicas. Um inibidor farmacológico de IGF1R-IRS1/2, NT157, foi desenvolvido e mostrou resultados promissores em estudos pré-clínicos com tumores sólidos. A associação constitutiva de IRS1 com BCRABL1 e o efeito antineoplásico resultante do silenciamento espefício de IRS1 em células K562 BCR-ABL1+ suportam a hipótese deste trabalho. O objetivo do presente estudo foi investigar o efeito da inibição farmacológica de IGF1R-IRS1/2 no fenótipo de células hematopoéticas leucêmicas BCR-ABL1+ utilizando células primárias, células K562 e modelos murinos. IRS1, mas não IRS2, apresentou-se menos expresso em amostras de medula óssea de pacientes com diagnóstico de LMC quando comparadas às amostras de células hematopoéticas normais (p<0,0001). NT157 reduziu a formação de colônias de células primárias de pacientes com LMC, mas não de células hematopoéticas de indivíduos saudáveis. Em células K562, o tratamento com o inibidor farmacológico de IGF1R-IRS1/2, NT157, reduziu a viabilidade e proliferação celular e induziu apoptose (p<0,05), inibiu a fosforilação de IGF1R, STAT3, STAT5, 4EBP1, P70S6K e ERK1/2, aumentou a expressão dos genes supressores de tumor CDKN1A, FOS e JUN e reduziu a expressão dos oncogenes MYC e BCL2 (p<0,05); a inibição específica de IRS1 através de lentivírus, mas não de IRS2, reduziu a viabilidade celular (p<0,05). Em células murinas Ba/F3 BCR-ABL1 e BCRABL1T315I, o inibidor farmacológico de IGF1R-IRS1/2, NT157, induziu apoptose e reduziu ativação de ERK1/2 in vitro. Na dose de 50mg/kg/dia, NT157 intraperitoneal e/ou imatinibe por gavagem falharam em reduzir o crescimento tumoral in vivo em modelo de tumor alográfico induzido por células Ba/F3 BCR-ABL1 e BCR-ABL1T315I. Em modelo animal de leucemia induzido por transplante de células hematopoéticas transduzidas com BCR-ABL1: (i) o tratamento com NT157 100mg/kg intraperitoneal, 3 vezes por semana, combinado com imatinibe 100mg/kg/dia por gavagem, reduziu significativamente o peso do baço, e preveniu a perda de peso comparado com veículo (p<0,05); apenas a monoterapia com imatinibe prolongou a sobrevida dos animais, (ii) o tratamento com NT157 70mg/kg intraperitoneal, 3 vezes por semana, e/ou imatinibe 70mg/kg/dia por gavagem não teve impacto no peso do baço e na variação do peso corporal; o tratamento com imatinibe em monoterapia ou combinado com NT157 prolongou a sobrevida dos animais (p<0,05). Em conclusão, o inibidor farmacológico de IGF1R-IRS1/2 representa uma droga potencialmente eficaz no tratamento da LMC, especialmente em casos de resistência com mutação BCR-ABL1 T315I. A avaliação da eficácia do inibidor farmacológico NT157 em modelos animais de LMC exige ajustes nos modelos murinos utilizados no presente estudo, melhor entendimento da farmacodinâmica e farmacocinética do composto e ajustes no esquema terapêutico utilizado. / Chronic myeloid leukemia (CML) is a hematological malignancy associated with the tyrosine kinase activity of the BCR-ABL1 oncoprotein. Most cases of CML are successfully treated with BCR-ABL1 tyrosine kinase inhibitors, but a significant percentage of patients develop resistance. Recent studies indicate that leukemic stem cell is resistant to imatinib treatment. The identification of other proteins that cooperate with the BCR-ABL1 signaling pathway may indicate novel therapeutic targets. Insulin receptor substrates (IRS) have emerged as important proteins in the pathophysiology of solid and hematological neoplasms. A pharmacological inhibitor of IGF1R-IRS1/2, NT157, has been developed and shown promising results in preclinical studies with solid tumors. The constitutive association of IRS1 with BCR-ABL1, and the antineoplastic effects resulting from IRS1-specific silencing in K562 BCR-ABL1+ cells, support the hypothesis of this work. The aim of the present study was to investigate the effect of pharmacological inhibition of IGF1R-IRS1/2 on the phenotype of BCR-ABL1+ leukemia cells, using primary cells, K562 cell line and murine models. IRS1, but not IRS2, was downregulated in bone marrow samples from CML patients compared to bone marrow cells from healthy donors (p<0.0001). NT157 reduced colony formation of primary cells from CML patients but not from healthy donors. In K562 cells, treatment with the pharmacological inhibitor IGF1R-IRS1/2, NT157, reduced cell viability and proliferation, induced apoptosis (p<0.05), inhibited the phosphorylation of IGF1R, STAT3, STAT5, 4EBP1, P70S6K and ERK1/2, increased expression of tumor suppressor genes CDKN1A, FOS and JUN, and reduced expression of oncogenes MYC and BCL2 (p<0.05); IRS1 silencing mediated by lentivirus, but not IRS2, reduced cell viability (p<0.05). In murine Ba/F3 BCRABL1 and Ba/F3 BCR-ABL1T315I cells, the pharmacological inhibitor of IGF1R-IRS1/2, NT157, induced apoptosis and reduced ERK1/2 activation in vitro. At 50mg/kg/day, NT157 intraperitoneally and/or imatinib orally, failed to reduce tumor burden in vivo in an allographic tumor model induced by Ba/F3 BCR-ABL1 and Ba/F3 BCR-ABL1T315I cells . In an animal leukemia model induced by transplantation of BCR-ABL1-transduced hematopoietic cells : (i) treatment with NT157 100mg/kg intraperitoneally, 3 times per week, combined with imatinib 100mg/kg/day per gavage, significantly reduced spleen weight, and prevented weight loss compared to vehicle (p<0.05); only imatinib monotherapy prolonged survival (p<0.05), (ii) treatment with NT157 70 mg/kg intraperitoneally, 3 times per week, and/or imatinib 70 mg/kg/day per gavage had no impact on spleen weight and body weight; treatment with imatinib alone or combined with NT157 prolonged survival (p<0.05). In conclusion, the pharmacological inhibitor of IGF1R-IRS1/2 represents a potential effective drug in CML therapy, especially in cases of resistant BCR-ABL1 T315I mutation. The evaluation of the NT157 pharmacological efficacy in CML animal models requires adjustments in the murine models used in the present study, better understanding of the pharmacodynamics and pharmacokinetics of the compound and adjustments in the therapeutic scheme used.

BCR-ABL1

IRS1

Leucemia Mieloide Crônica

NT157

Substratos do receptor de insulina

T315I

BCR-ABL1

Chronic Myeloid Leukemia

Insulin receptor substrates

IRS1

NT157

T315I

Efeito in vitro do deidroepiandrosterona (DHEA) sobre a via IRS/PI3-K/Akt e secreção de insulina em ilhotas pancreáticas de ratos. / Effect in vitro of dehydroepiandrosterone (DHEA) on IRS/PI3-K/Akt pathway and insulin secretion on rats pancreatic islets.

Camporez, João Paulo Gabriel

28 April 2008

A administração de deidroepiandrosterona (DHEA) tem resultado em efeitos anti-diabetogênicos em animais de experimentação e no homem. Assim, o objetivo desse trabalho é avaliar o efeito do DHEA in vitro na expressão protéica do IR, do IRS-1, IRS-2, PI3-K, Akt, ERK-1/2; na expressão gênica do PDX-1, do PGC-1, da insulina, do GLUT-2 e da glicocinase; e avaliar a secreção estática de insulina de ilhotas pancreáticas de ratos. O cultivo das ilhotas por 24 horas com DHEA, não induziu nenhuma alteração tanto na expressão das proteínas quanto na secreção estática de insulina estimulada por glicose. Ocorreu aumento da fosforilação de ERK-1/2 e na expressão gênica do PGC-1. As células RINm5F, cultivadas por 72 horas com DHEA, apresentaram aumento da expressão total de IRS-1 e IRS-2. Concluímos, que 24 horas de cultura com ilhotas não é tempo suficiente para observar nenhuma alteração induzida pelo DHEA, na secreção de insulina, e na expressão das proteínas da via IRS/PI3-K/Akt. Células RINm5F podem ser um modelo alternativo para investigar os efeitos diretos do DHEA. / The dehydroepiandrosterone (DHEA) administration has resulted in reduction of abdominal fat and protection against insulin resistance from experimental animals and humans. So, the purpose of this project is measure the in vitro effects from DHEA: on protein expression of insulin receptor, the proteins IRS-1, IRS-2, PI3-K, Akt, and ERK-1/2; on gene expression of transcriptional factors PDX-1 and PGC-1, insulin, glucose transport GLUT-2 and glicocinase; and to measure the static insulin secretion, on cultured pancreatic islets of the rat. The culture of pancreatic islet for 24 hours with DHEA, did not induce nothing alteration on protein expression of the IR, IRS-1, IRS-2, PI3-K, Akt-1 and ERK-1/2, and static insulin secretion induced by glucose. However, happened increase ERK-1/2 phosphorylation and PGC-1 gene expression. The RINm5F cells, cultured by 72 hours, showed increase of the IRS-1 and IRS-2 expression. We conclude that 24 hours of the pancreatic islets culture are not sufficient time to look any alteration induced by DHEA, on insulin secretion, and on protein expression involved on IRS/PI3-K/Akt pathway. RINm5F cells can be an alternative model to research the direct effects from DHEA.

Diabetes Mellitus

Diabetes Mellitus

Expressão gênica

Gene expression

Homônios sexuais

Ilhotas de Langerhans

Insulin receptor

Insulin signaling

Langerhans islets

Receptores da insulina

Sexual hormone

Sinalização da insulina