Perfil dos peptídeos gastrointestinais na obesidade programada pelo desmame precoce e após a terapia anti-obesidade com cálcio / Profile of gastrointestinal peptides in obesity programmed by early weaning and after anti-obesity therapy with calcium

Fernanda Torres Quitete

19 February 2014

Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro / O desmame precoce (DP) leva ao desenvolvimento tardio de obesidade e de resistência insulínica (RI), sendo essas alterações prevenidas quando os animais são suplementados com cálcio. Sabe-se que os peptídeos gastrointestinais (GI) atuam na regulação do apetite e em diversos outros processos, podendo ter um papel relevante no desenvolvimento da obesidade e RI. Uma vez que os animais programados pelo DP são obesos e hiperfágicos, investigamos o perfil plasmático e tecidual de GLP-1, CCK e PYY (anorexígenos) de grelina (orexígena) e de seus receptores, assim como o efeito da dieta rica em cálcio sobre estes peptídeos a fim de identificar algum distúrbio no controle do apetite. Ao nascimento das proles, ratas lactantes Wistar foram separadas em: grupo DP (desmame precoce, n=20), filhotes cujas mães tiveram as mamas enfaixadas, impedindo o acesso da prole ao leite nos últimos 3 dias de lactação; e grupo C (controle, n=10), filhotes com livre acesso ao leite materno. Aos 120 dias, as proles DP foram subdivididas em: grupo DP, alimentado com ração comercial padrão, e grupo DPCa, alimentado com ração suplementada com cálcio (10g de carbonato de cálcio/Kg de ração). Os animais foram sacrificados aos 21 e 180 dias de vida. Quantificamos: GLP-1, CCK, PYY, grelina e citocinas (IL-6, TNF-&#945; e IL-10) plasmáticas por ELISA; o conteúdo de grelina no estômago por ELISA e imunohistoquímica; o conteúdo de GLP-1 (intestino), GLP1-R (intestino, TA e ARC) e GHSR-1a (estômago e ARC) por Western blotting. Dados significativos quando p<0,05. Aos 21 dias, a prole DP apresentou aumento de GLP-1 no plasma (+168%) e GLP1-R no tecido adiposo (+72%), embora menor conteúdo de GLP-1 (-59%) e GLP1-R (-58%) no intestino. Não observamos alterações plasmáticas de grelina, CCK e PPY e no conteúdo de GHSR-1a no estômago aos 21 dias. Aos 180 dias, não verificamos diferença em nenhum dos peptídeos GI no plasma na prole DP. Porém, observamos menor conteúdo intestinal de GLP-1 tanto no grupo DP (-33%) quanto no DPCa (-32%), e uma tendência da grelina (+20%) e do GHSR-1a (+31%) a estarem elevados no estômago do grupo DP. Além de menor conteúdo de GLP1-R no tecido adiposo no grupo DP (-59%) e maior conteúdo de GLP1-R no intestino da prole DPCa (+62%). Não encontramos diferença entre os grupos na expressão de GLP1-R e GHSR-1a no ARC. O grupo DP apresentou ainda um perfil pró-inflamatório caracterizado por maior TNF-&#945; e menor IL-10 no plasma. O DP alterou o perfil dos peptídeos GI a curto e longo prazos, o que pode ter colaborado para o desenvolvimento da obesidade, hiperfagia e RI neste modelo, uma vez que o GLP-1, único peptídeo alterado no período de imprinting, possui um possível papel adipogênico. A suplementação com cálcio foi capaz de reverter todas as alterações produzidas pelo DP. Evidenciamos, então, a importância do aleitamento materno na formação do comportamento alimentar e do balanço metabólico, bem como o papel da suplementação com cálcio no tratamento da obesidade e seus distúrbios associados, inclusive nas alterações do apetite. / Early weaning (EW) leads to late development of obesity and insulin resistance (IR), and these changes are prevented when EW animals are supplemented with calcium. It is known that gut peptides with regulatory action upon appetite and several other processes with possible role in the obesity development and IR. As the EW programmed animals are obese and hyperphagic, in this study we evaluated plasma and tissue profile of GLP-1, CCK and PYY (anorexigenic peptides), and ghrelin (orexigenic peptide) and their receptors as well as the effects of rich calcium diet on these parameters in order to find some disturbance in the appetite control. At birth, lactating Wistar rats were separated in: EW (Early Weaning, n=20), lactating rats were involved with a bandage to interrupt the lactation during the last 3 days of standard lactation, and C (control, n=20), dams whose pups had free access to milk during all lactation (21 days). At 120 days-old, half of DP group received dietary calcium supplementation (10g of calcium carbonate/Kg of rat chow); DP and C groups received standard diet. Offspring were killed at 21 and 180 days-old. Plasma GLP-1, CCK, PYY, ghrelin and the cytokines (IL-6, TNF-&#945; and IL-10), and ghrelin content in the stomach are analyzed by ELISA; which was also examined by immunohistochemistry; GLP1 content (gut) GLP1-R (gut, adipose tissue and hypothalamus-ARC) and e GHSR-1a (stomach and hypothalamus-ARC) are evaluated by Western blotting. Significant data were p<0.05. At 21 days-old, EW group presented higher plasma GLP1 (+168%) and GLP1-R in adipose tissue (+72%), although lower GLP-1 (-59%) and GLP1-R (-58%) content in gut. We not found changes in plasma ghrelin, CCK and PYY as well as in stomach GHSR-1a content. At 180 days-old, we found no changes in plasma gastrointestinal peptides in EW offspring. However, we observed lower gut GLP1 content in both EW group (-33%) and in EWCa (-32%), and a trend of ghrelin (+20%) and GHSR-1a (+31%) to be increased in EW group. In addition, we detected lower GLP1-R content in adipose tissue in EW group (-59%) and higher gut GLP1-R content in EWCa (+62%). We found no change among groups in GLP1-R and GHSR-1a expression in the ARC. EW group also showed a proinflammatory profile characterized by higher TNF-&#945; and lower IL-10 levels. EW had short and long-term effects on the profile of gastrointestinal peptides, which may have contributed to the development of obesity, hyperphagia and IR, since GLP-1 is the unique peptide changed during the imprinting period, which has an adipogenic role. Calcium supplementation was able to prevent all changes produced by EW. We evidence the importance of breastfeeding on feeding behavior development and metabolic balance as well as the role of calcium supplementation in obesity treatment and other disorders, including changes in appetite.

Lactação

Desmame precoce

Programação

Peptídeos gastrointestinais

Lactation

Early weaning

Programming

Gut peptides

NUTRICAO

Perfil dos peptídeos gastrointestinais na obesidade programada pelo desmame precoce e após a terapia anti-obesidade com cálcio / Profile of gastrointestinal peptides in obesity programmed by early weaning and after anti-obesity therapy with calcium

Fernanda Torres Quitete

19 February 2014

Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro / O desmame precoce (DP) leva ao desenvolvimento tardio de obesidade e de resistência insulínica (RI), sendo essas alterações prevenidas quando os animais são suplementados com cálcio. Sabe-se que os peptídeos gastrointestinais (GI) atuam na regulação do apetite e em diversos outros processos, podendo ter um papel relevante no desenvolvimento da obesidade e RI. Uma vez que os animais programados pelo DP são obesos e hiperfágicos, investigamos o perfil plasmático e tecidual de GLP-1, CCK e PYY (anorexígenos) de grelina (orexígena) e de seus receptores, assim como o efeito da dieta rica em cálcio sobre estes peptídeos a fim de identificar algum distúrbio no controle do apetite. Ao nascimento das proles, ratas lactantes Wistar foram separadas em: grupo DP (desmame precoce, n=20), filhotes cujas mães tiveram as mamas enfaixadas, impedindo o acesso da prole ao leite nos últimos 3 dias de lactação; e grupo C (controle, n=10), filhotes com livre acesso ao leite materno. Aos 120 dias, as proles DP foram subdivididas em: grupo DP, alimentado com ração comercial padrão, e grupo DPCa, alimentado com ração suplementada com cálcio (10g de carbonato de cálcio/Kg de ração). Os animais foram sacrificados aos 21 e 180 dias de vida. Quantificamos: GLP-1, CCK, PYY, grelina e citocinas (IL-6, TNF-&#945; e IL-10) plasmáticas por ELISA; o conteúdo de grelina no estômago por ELISA e imunohistoquímica; o conteúdo de GLP-1 (intestino), GLP1-R (intestino, TA e ARC) e GHSR-1a (estômago e ARC) por Western blotting. Dados significativos quando p<0,05. Aos 21 dias, a prole DP apresentou aumento de GLP-1 no plasma (+168%) e GLP1-R no tecido adiposo (+72%), embora menor conteúdo de GLP-1 (-59%) e GLP1-R (-58%) no intestino. Não observamos alterações plasmáticas de grelina, CCK e PPY e no conteúdo de GHSR-1a no estômago aos 21 dias. Aos 180 dias, não verificamos diferença em nenhum dos peptídeos GI no plasma na prole DP. Porém, observamos menor conteúdo intestinal de GLP-1 tanto no grupo DP (-33%) quanto no DPCa (-32%), e uma tendência da grelina (+20%) e do GHSR-1a (+31%) a estarem elevados no estômago do grupo DP. Além de menor conteúdo de GLP1-R no tecido adiposo no grupo DP (-59%) e maior conteúdo de GLP1-R no intestino da prole DPCa (+62%). Não encontramos diferença entre os grupos na expressão de GLP1-R e GHSR-1a no ARC. O grupo DP apresentou ainda um perfil pró-inflamatório caracterizado por maior TNF-&#945; e menor IL-10 no plasma. O DP alterou o perfil dos peptídeos GI a curto e longo prazos, o que pode ter colaborado para o desenvolvimento da obesidade, hiperfagia e RI neste modelo, uma vez que o GLP-1, único peptídeo alterado no período de imprinting, possui um possível papel adipogênico. A suplementação com cálcio foi capaz de reverter todas as alterações produzidas pelo DP. Evidenciamos, então, a importância do aleitamento materno na formação do comportamento alimentar e do balanço metabólico, bem como o papel da suplementação com cálcio no tratamento da obesidade e seus distúrbios associados, inclusive nas alterações do apetite. / Early weaning (EW) leads to late development of obesity and insulin resistance (IR), and these changes are prevented when EW animals are supplemented with calcium. It is known that gut peptides with regulatory action upon appetite and several other processes with possible role in the obesity development and IR. As the EW programmed animals are obese and hyperphagic, in this study we evaluated plasma and tissue profile of GLP-1, CCK and PYY (anorexigenic peptides), and ghrelin (orexigenic peptide) and their receptors as well as the effects of rich calcium diet on these parameters in order to find some disturbance in the appetite control. At birth, lactating Wistar rats were separated in: EW (Early Weaning, n=20), lactating rats were involved with a bandage to interrupt the lactation during the last 3 days of standard lactation, and C (control, n=20), dams whose pups had free access to milk during all lactation (21 days). At 120 days-old, half of DP group received dietary calcium supplementation (10g of calcium carbonate/Kg of rat chow); DP and C groups received standard diet. Offspring were killed at 21 and 180 days-old. Plasma GLP-1, CCK, PYY, ghrelin and the cytokines (IL-6, TNF-&#945; and IL-10), and ghrelin content in the stomach are analyzed by ELISA; which was also examined by immunohistochemistry; GLP1 content (gut) GLP1-R (gut, adipose tissue and hypothalamus-ARC) and e GHSR-1a (stomach and hypothalamus-ARC) are evaluated by Western blotting. Significant data were p<0.05. At 21 days-old, EW group presented higher plasma GLP1 (+168%) and GLP1-R in adipose tissue (+72%), although lower GLP-1 (-59%) and GLP1-R (-58%) content in gut. We not found changes in plasma ghrelin, CCK and PYY as well as in stomach GHSR-1a content. At 180 days-old, we found no changes in plasma gastrointestinal peptides in EW offspring. However, we observed lower gut GLP1 content in both EW group (-33%) and in EWCa (-32%), and a trend of ghrelin (+20%) and GHSR-1a (+31%) to be increased in EW group. In addition, we detected lower GLP1-R content in adipose tissue in EW group (-59%) and higher gut GLP1-R content in EWCa (+62%). We found no change among groups in GLP1-R and GHSR-1a expression in the ARC. EW group also showed a proinflammatory profile characterized by higher TNF-&#945; and lower IL-10 levels. EW had short and long-term effects on the profile of gastrointestinal peptides, which may have contributed to the development of obesity, hyperphagia and IR, since GLP-1 is the unique peptide changed during the imprinting period, which has an adipogenic role. Calcium supplementation was able to prevent all changes produced by EW. We evidence the importance of breastfeeding on feeding behavior development and metabolic balance as well as the role of calcium supplementation in obesity treatment and other disorders, including changes in appetite.

Lactação

Desmame precoce

Programação

Peptídeos gastrointestinais

Lactation

Early weaning

Programming

Gut peptides

NUTRICAO

EFFECT OF GUT PEPTIDES ON HYPOTHALAMIC mRNA CONCENTRATION AND DRY MATTER INTAKE IN RUMINANTS

Relling, Alejandro Enrique

22 July 2009

No description available.

Anatomy and Physiology

Animals

Nutrition

Gut peptides

insulin

sheep

dairy cows

dry matter intake

ruminants

NPY

AgRP

POMC

hypothalamic neuropeptides

appetite

Intestin et défauts métaboliques dans la résistance à l'insuline

Grenier, Émilie

12 1900

En lien avec l’augmentation constante de l’obésité, de plus en plus de personnes sont atteintes de résistance à l’insuline ou de diabète de type 2. Ce projet doctoral s’est surtout intéressé à l’une des conséquences majeures des pathologies cardiométaboliques, soit la dyslipidémie diabétique. À cet égard, les gens présentant une résistance à l’insuline ou un diabète de type 2 sont plus à risque de développer des perturbations lipidiques caractérisées essentiellement par des taux élevés de triglycérides et de LDL-cholestérol ainsi que de concentrations restreintes en HDL-cholestérol dans la circulation. Les risques de maladies cardiovasculaires sont ainsi plus élevés chez ces patients. Classiquement, trois organes sont connus pour développer l’insulino-résistance : le muscle, le tissu adipeux et le foie. Néanmoins, certaines évidences scientifiques commencent également à pointer du doigt l’intestin, un organe critique dans la régulation du métabolisme des lipides postprandiaux, et qui pourrait, conséquemment, avoir un impact important dans l’apparition de la dyslipidémie diabétique. De façon très intéressante, des peptides produits par l’intestin, notamment le GLP-1 (glucagon-like peptide-1), ont déjà démontré leur potentiel thérapeutique quant à l’amélioration du statut diabétique et leur rôle dans le métabolisme intestinal lipoprotéinique. Une autre évidence est apportée par la chirurgie bariatrique qui a un effet positif, durable et radical sur la perte pondérale, le contrôle métabolique et la réduction des comorbidités du diabète de type 2, suite à la dérivation bilio-intestinale. Les objectifs centraux du présent programme scientifique consistent donc à déterminer le rôle de l’intestin dans (i) l’homéostasie lipidique/lipoprotéinique en réponse à des concentrations élevées de glucose (à l’instar du diabète) et à des peptides gastro-intestinaux tels que le PYY (peptide YY); (ii) la coordination du métabolisme en disposant de l’AMPK (AMP-activated protein kinase) comme senseur incontournable permettant l’ajustement précis des besoins et disponibilités énergétiques cellulaires; et (iii) l’ajustement de sa capacité d’absorption des graisses alimentaires en fonction du gain ou de la perte de sa sensibilité à l’insuline démontrée dans les spécimens intestinaux humains prélevés durant la chirurgie bariatrique. Dans le but de confirmer le rôle de l’intestin dans la dyslipidémie diabétique, nous avons tout d’abord utilisé le modèle cellulaire intestinal Caco-2/15. Ces cellules ont permis de démontrer qu’en présence de hautes concentrations de glucose en basolatéral, telle qu’en condition diabétique, l’intestin absorbe davantage de cholestérol provenant de la lumière intestinale par l’intermédiaire du transporteur NPC1L1 (Niemann Pick C1-like 1). L’utilisation de l’ezetimibe, un inhibiteur du NPC1L1, a permis de contrecarrer cette augmentation de l’expression de NPC1L1 tout comme l’élévation de l’absorption du cholestérol, prouvant ainsi que le NPC1L1 est bel et bien responsable de cet effet. D’autre part, des travaux antérieurs avaient identifié certains indices quant à un rôle potentiel du peptide intestinal PYY au niveau du métabolisme des lipides intestinaux. Toutefois, aucune étude n’avait encore traité cet aspect systématiquement. Pour établir définitivement l’aptitude du PYY à moduler le transport et le métabolisme lipidique dans l’intestin, nous avons utilisé les cellules Caco-2/15. Notre étude a permis de constater que le PYY incubé du côté apical est capable de réduire significativement l’absorption du cholestérol et le transporteur NPC1L1. Puisque le rôle de l'AMPK dans l'intestin demeure inexploré, il est important non seulement de définir sa structure moléculaire, sa régulation et sa fonction dans le métabolisme des lipides, mais aussi d'examiner l'impact de l’insulino-résistance et du diabète de type 2 (DT2) sur son statut et son mode d’action gastro-intestinal. En employant les cellules Caco-2/15, nous avons été capables de montrer (i) la présence de toutes les sous-unités AMPK (α1/α2/β1/β2/γ1/γ2/γ3) avec une différence marquée dans leur abondance et une prédominance de l’AMPKα1 et la prévalence de l’hétérotrimère α1/β2/γ1; (ii) l’activation de l’AMPK par la metformine et l’AICAR, résultant ainsi en une phosphorylation accrue de l’enzyme acétylCoA carboxylase (ACC) et sans influence sur l'HMG-CoA réductase; (iii) la modulation négative de l’AMPK par le composé C et des concentrations de glucose élevées avec des répercussions sur la phosphorylation de l’ACC. D’autre part, l’administration de metformine au Psammomys obesus, un modèle animal de diabète et de syndrome métabolique, a conduit à (i) une régulation positive de l’AMPK intestinale (phosphorylation de l’AMPKα-Thr172); (ii) la réduction de l'activité ACC; (iii) l’augmentation de l’expression génique et protéique de CPT1, supportant une stimulation de la β-oxydation; (iv) une tendance à la hausse de la sensibilité à l'insuline représentée par l’induction de la phosphorylation d'Akt et l’inactivation de la phosphorylation de p38; et (v) l’abaissement de la formation des chylomicrons ce qui conduit à la diminution de la dyslipidémie diabétique. Ces données suggèrent que l'AMPK remplit des fonctions clés dans les processus métaboliques de l'intestin grêle. La preuve flagrante de l’implication de l’intestin dans les événements cardiométaboliques a été obtenue par l’examen des spécimens intestinaux obtenus de sujets obèses, suite à une chirurgie bariatrique. L’exploration intestinale nous a permis de constater chez ceux avec un indice HOMA élevé (marqueur d’insulinorésistance) (i) des défauts de signalisation de l'insuline comme en témoigne la phosphorylation réduite d'Akt et la phosphorylation élevée de p38 MAPK; (ii) la présence du stress oxydatif et de marqueurs de l'inflammation; (iii) la stimulation de la lipogenèse et de la production des lipoprotéines riches en triglycérides avec l’implication des protéines clés FABP, MTP et apo B-48. En conclusion, l'intestin grêle peut être classé comme un tissu insulino-sensible et répondant à plusieurs stimuli nutritionnels et hormonaux. Son dérèglement peut être déclenché par le stress oxydatif et l'inflammation, ce qui conduit à l'amplification de la lipogenèse et la synthèse des lipoprotéines, contribuant ainsi à la dyslipidémie athérogène chez les patients atteints du syndrome métabolique et de diabète de type 2. / In relation with the constant increase in obesity, more and more people suffer from insulin resistance and type 2 diabetes (DT2). This doctoral research program especially emphasizes lipid disorders, one of the major consequences of cardiometabolic diseases. In this respect, people with insulin resistance or DT2 are at higher risk of developing lipid disturbances characterized mainly by high levels of triglycerides and LDL-cholesterol concentrations and HDL cholesterol in the blood circulation. The risks of cardiovascular disease are higher in these patients. Classically, three organs are known to develop insulin resistance: muscle, adipose tissue and liver. Nevertheless, important studies begin to point out the small intestine as a major organ in the regulation of postprandial lipids, which may have a significant impact on the development of diabetic dyslipidemia. In addition, the intestine produces peptides, including GLP-1 (glucagon-like peptide-1), that have already demonstrated their therapeutic potential with regard to diabetic status and intestinal lipoprotein metabolism. Further evidence is also is provided by the advent of bariatric surgery that has a positive effect on radical and sustainable weight loss, metabolic control and reduction of comorbidities of DT2, following biliopancreatic diversion. The central objectives of this scientific program are therefore to determine the role of the intestine in (i) lipid/ lipoprotein homeostasis in response to high concentrations of glucose (mimicking diabetes) and to gastrointestinal peptides such as PYY; (ii) the coordination of metabolism by involving AMPK (AMP-activated protein kinase) as an essential sensor for fine tuning of cellular energy needs; and (iii) adjusting absorption capacity of dietary fat in the gain or loss of insulin sensitivity demonstrated in intestinal specimens collected during bariatric surgery. In order to confirm the role of the intestine in diabetic dyslipidemia, we first used the intestinal Caco-2/15 cell model. The use of this epithelial cell line has shown a marked stimulation of cholesterol uptake via the transporter NPC1L1 (Niemann-Pick C1-like 1) in the presence of high glucose concentrations (as is the case in diabetic conditions) in basolateral compartment (compared to apical). The use of ezetimibe, an inhibitor of NPC1L1, helped to counteract this elevation of cholesterol absorption, thus proving that NPC1L1 is indeed behind this effect. If previous reports have identified some clues as to the potential role of intestinal PYY (peptide YY) in lipid metabolism disorders, no study has yet addressed this issue systematically. To definitively establish the ability of PYY to modulate lipid transport and metabolism in the intestine, we have used Caco-2/15 cells. Our recent investigation has shown that PYY (administered in the apical compartment) is able to significantly reduce cholesterol absorption via NPC1L1 transporter. Since the role of AMPK in the intestine remains unexplored, it is important to define not only its molecular structure, regulation and function in lipid metabolism, but also its impact on insulin resistance and T2D on its status and mode of action in the gastrointestinal tract. Using Caco-2/15 cells, we have been able to show (i) the presence of all AMPK subunits (α1/α2/β1/β2/γ1/γ2/γ3) with a marked difference in their abundance, but with a predominance of AMPKα1 and the prevalence of α1/β2/γ1 heterotrimer; (ii) the activation of AMPK by metformin and AICAR, resulting in increased phosphorylation of the downstream target acetylCoA carboxylases (ACC) without no influence on HMG-CoA reductase; (iii) the negative modulation of AMPK by compound C and glucose concentrations with high impact on ACC phosphorylation. On the other hand, administration of metformin to Psammomys obesus with insulin resistance and T2D led to (a) an upregulation of intestinal AMPK signaling pathway essentially typified by ascending AMPKα-Thr172 phosphorylation; (b) a reduction in ACC activity; (c) an elevation in the gene and protein expression of CPT1, supporting a stimulation of β-oxidation; (d) a trend of increase in insulin sensitivity portrayed by augmentation of Akt and GSK3β phosphorylation; (e) an inactivation of the stress-responsive p38-MAPK and /ERK1/2 exemplified by their phosphorylation lessening; and (f) a decrease in diabetic dyslipidemia following lowering of intracellular events that govern lipoprotein assembly. Therefore these data suggest that AMPK fulfills key functions in metabolic processes in the small intestine. The clear evidence for the involvement of the gut in cardiometabolic events has been obtained through the scrutiny of intestinal specimens obtained from obese subjects after bariatric surgery. Intestine of insulin-resistant subjects shows defects in insulin signaling as demonstrated by reduced Akt phosphorylation but increased p38 MAPK phosphorylation. These defects were accompanied with increased oxidative stress and inflammation markers in intestine of insulin-resistant subjects. Enhanced de novo lipogenesis rate and apo B-48 biogenesis along with increased triglyceride-rich lipoprotein production was also observed in the intestine of insulin-resistant subjects. Concomitantly, fatty acid binding proteins (FABP) and microsomal transfer protein (MTP) expression was increased in the intestine of insulin-resistant subjects. In conclusion, the small intestine may be classified as an insulin-sensitive tissue. Its deregulation, possibly triggered by oxidative stress and inflammation, may lead to amplification of lipogenesis and lipoprotein synthesis and may therefore represent a key mechanism for atherogenic dyslipidemia in patients with metabolic syndrome and T2D.

Résistance à l'insuline

Diabète de type 2

Intestin

Dyslipidémie diabétique

Transporteurs du cholestérol

Peptides gastro-intestinaux

Insulin resistance

Type 2 diabetes

Intestine

Diabetic dyslipidemia

Cholesterol transporters

Gut peptides

Intestin et défauts métaboliques dans la résistance à l'insuline

Grenier, Émilie

12 1900

En lien avec l’augmentation constante de l’obésité, de plus en plus de personnes sont atteintes de résistance à l’insuline ou de diabète de type 2. Ce projet doctoral s’est surtout intéressé à l’une des conséquences majeures des pathologies cardiométaboliques, soit la dyslipidémie diabétique. À cet égard, les gens présentant une résistance à l’insuline ou un diabète de type 2 sont plus à risque de développer des perturbations lipidiques caractérisées essentiellement par des taux élevés de triglycérides et de LDL-cholestérol ainsi que de concentrations restreintes en HDL-cholestérol dans la circulation. Les risques de maladies cardiovasculaires sont ainsi plus élevés chez ces patients. Classiquement, trois organes sont connus pour développer l’insulino-résistance : le muscle, le tissu adipeux et le foie. Néanmoins, certaines évidences scientifiques commencent également à pointer du doigt l’intestin, un organe critique dans la régulation du métabolisme des lipides postprandiaux, et qui pourrait, conséquemment, avoir un impact important dans l’apparition de la dyslipidémie diabétique. De façon très intéressante, des peptides produits par l’intestin, notamment le GLP-1 (glucagon-like peptide-1), ont déjà démontré leur potentiel thérapeutique quant à l’amélioration du statut diabétique et leur rôle dans le métabolisme intestinal lipoprotéinique. Une autre évidence est apportée par la chirurgie bariatrique qui a un effet positif, durable et radical sur la perte pondérale, le contrôle métabolique et la réduction des comorbidités du diabète de type 2, suite à la dérivation bilio-intestinale. Les objectifs centraux du présent programme scientifique consistent donc à déterminer le rôle de l’intestin dans (i) l’homéostasie lipidique/lipoprotéinique en réponse à des concentrations élevées de glucose (à l’instar du diabète) et à des peptides gastro-intestinaux tels que le PYY (peptide YY); (ii) la coordination du métabolisme en disposant de l’AMPK (AMP-activated protein kinase) comme senseur incontournable permettant l’ajustement précis des besoins et disponibilités énergétiques cellulaires; et (iii) l’ajustement de sa capacité d’absorption des graisses alimentaires en fonction du gain ou de la perte de sa sensibilité à l’insuline démontrée dans les spécimens intestinaux humains prélevés durant la chirurgie bariatrique. Dans le but de confirmer le rôle de l’intestin dans la dyslipidémie diabétique, nous avons tout d’abord utilisé le modèle cellulaire intestinal Caco-2/15. Ces cellules ont permis de démontrer qu’en présence de hautes concentrations de glucose en basolatéral, telle qu’en condition diabétique, l’intestin absorbe davantage de cholestérol provenant de la lumière intestinale par l’intermédiaire du transporteur NPC1L1 (Niemann Pick C1-like 1). L’utilisation de l’ezetimibe, un inhibiteur du NPC1L1, a permis de contrecarrer cette augmentation de l’expression de NPC1L1 tout comme l’élévation de l’absorption du cholestérol, prouvant ainsi que le NPC1L1 est bel et bien responsable de cet effet. D’autre part, des travaux antérieurs avaient identifié certains indices quant à un rôle potentiel du peptide intestinal PYY au niveau du métabolisme des lipides intestinaux. Toutefois, aucune étude n’avait encore traité cet aspect systématiquement. Pour établir définitivement l’aptitude du PYY à moduler le transport et le métabolisme lipidique dans l’intestin, nous avons utilisé les cellules Caco-2/15. Notre étude a permis de constater que le PYY incubé du côté apical est capable de réduire significativement l’absorption du cholestérol et le transporteur NPC1L1. Puisque le rôle de l'AMPK dans l'intestin demeure inexploré, il est important non seulement de définir sa structure moléculaire, sa régulation et sa fonction dans le métabolisme des lipides, mais aussi d'examiner l'impact de l’insulino-résistance et du diabète de type 2 (DT2) sur son statut et son mode d’action gastro-intestinal. En employant les cellules Caco-2/15, nous avons été capables de montrer (i) la présence de toutes les sous-unités AMPK (α1/α2/β1/β2/γ1/γ2/γ3) avec une différence marquée dans leur abondance et une prédominance de l’AMPKα1 et la prévalence de l’hétérotrimère α1/β2/γ1; (ii) l’activation de l’AMPK par la metformine et l’AICAR, résultant ainsi en une phosphorylation accrue de l’enzyme acétylCoA carboxylase (ACC) et sans influence sur l'HMG-CoA réductase; (iii) la modulation négative de l’AMPK par le composé C et des concentrations de glucose élevées avec des répercussions sur la phosphorylation de l’ACC. D’autre part, l’administration de metformine au Psammomys obesus, un modèle animal de diabète et de syndrome métabolique, a conduit à (i) une régulation positive de l’AMPK intestinale (phosphorylation de l’AMPKα-Thr172); (ii) la réduction de l'activité ACC; (iii) l’augmentation de l’expression génique et protéique de CPT1, supportant une stimulation de la β-oxydation; (iv) une tendance à la hausse de la sensibilité à l'insuline représentée par l’induction de la phosphorylation d'Akt et l’inactivation de la phosphorylation de p38; et (v) l’abaissement de la formation des chylomicrons ce qui conduit à la diminution de la dyslipidémie diabétique. Ces données suggèrent que l'AMPK remplit des fonctions clés dans les processus métaboliques de l'intestin grêle. La preuve flagrante de l’implication de l’intestin dans les événements cardiométaboliques a été obtenue par l’examen des spécimens intestinaux obtenus de sujets obèses, suite à une chirurgie bariatrique. L’exploration intestinale nous a permis de constater chez ceux avec un indice HOMA élevé (marqueur d’insulinorésistance) (i) des défauts de signalisation de l'insuline comme en témoigne la phosphorylation réduite d'Akt et la phosphorylation élevée de p38 MAPK; (ii) la présence du stress oxydatif et de marqueurs de l'inflammation; (iii) la stimulation de la lipogenèse et de la production des lipoprotéines riches en triglycérides avec l’implication des protéines clés FABP, MTP et apo B-48. En conclusion, l'intestin grêle peut être classé comme un tissu insulino-sensible et répondant à plusieurs stimuli nutritionnels et hormonaux. Son dérèglement peut être déclenché par le stress oxydatif et l'inflammation, ce qui conduit à l'amplification de la lipogenèse et la synthèse des lipoprotéines, contribuant ainsi à la dyslipidémie athérogène chez les patients atteints du syndrome métabolique et de diabète de type 2. / In relation with the constant increase in obesity, more and more people suffer from insulin resistance and type 2 diabetes (DT2). This doctoral research program especially emphasizes lipid disorders, one of the major consequences of cardiometabolic diseases. In this respect, people with insulin resistance or DT2 are at higher risk of developing lipid disturbances characterized mainly by high levels of triglycerides and LDL-cholesterol concentrations and HDL cholesterol in the blood circulation. The risks of cardiovascular disease are higher in these patients. Classically, three organs are known to develop insulin resistance: muscle, adipose tissue and liver. Nevertheless, important studies begin to point out the small intestine as a major organ in the regulation of postprandial lipids, which may have a significant impact on the development of diabetic dyslipidemia. In addition, the intestine produces peptides, including GLP-1 (glucagon-like peptide-1), that have already demonstrated their therapeutic potential with regard to diabetic status and intestinal lipoprotein metabolism. Further evidence is also is provided by the advent of bariatric surgery that has a positive effect on radical and sustainable weight loss, metabolic control and reduction of comorbidities of DT2, following biliopancreatic diversion. The central objectives of this scientific program are therefore to determine the role of the intestine in (i) lipid/ lipoprotein homeostasis in response to high concentrations of glucose (mimicking diabetes) and to gastrointestinal peptides such as PYY; (ii) the coordination of metabolism by involving AMPK (AMP-activated protein kinase) as an essential sensor for fine tuning of cellular energy needs; and (iii) adjusting absorption capacity of dietary fat in the gain or loss of insulin sensitivity demonstrated in intestinal specimens collected during bariatric surgery. In order to confirm the role of the intestine in diabetic dyslipidemia, we first used the intestinal Caco-2/15 cell model. The use of this epithelial cell line has shown a marked stimulation of cholesterol uptake via the transporter NPC1L1 (Niemann-Pick C1-like 1) in the presence of high glucose concentrations (as is the case in diabetic conditions) in basolateral compartment (compared to apical). The use of ezetimibe, an inhibitor of NPC1L1, helped to counteract this elevation of cholesterol absorption, thus proving that NPC1L1 is indeed behind this effect. If previous reports have identified some clues as to the potential role of intestinal PYY (peptide YY) in lipid metabolism disorders, no study has yet addressed this issue systematically. To definitively establish the ability of PYY to modulate lipid transport and metabolism in the intestine, we have used Caco-2/15 cells. Our recent investigation has shown that PYY (administered in the apical compartment) is able to significantly reduce cholesterol absorption via NPC1L1 transporter. Since the role of AMPK in the intestine remains unexplored, it is important to define not only its molecular structure, regulation and function in lipid metabolism, but also its impact on insulin resistance and T2D on its status and mode of action in the gastrointestinal tract. Using Caco-2/15 cells, we have been able to show (i) the presence of all AMPK subunits (α1/α2/β1/β2/γ1/γ2/γ3) with a marked difference in their abundance, but with a predominance of AMPKα1 and the prevalence of α1/β2/γ1 heterotrimer; (ii) the activation of AMPK by metformin and AICAR, resulting in increased phosphorylation of the downstream target acetylCoA carboxylases (ACC) without no influence on HMG-CoA reductase; (iii) the negative modulation of AMPK by compound C and glucose concentrations with high impact on ACC phosphorylation. On the other hand, administration of metformin to Psammomys obesus with insulin resistance and T2D led to (a) an upregulation of intestinal AMPK signaling pathway essentially typified by ascending AMPKα-Thr172 phosphorylation; (b) a reduction in ACC activity; (c) an elevation in the gene and protein expression of CPT1, supporting a stimulation of β-oxidation; (d) a trend of increase in insulin sensitivity portrayed by augmentation of Akt and GSK3β phosphorylation; (e) an inactivation of the stress-responsive p38-MAPK and /ERK1/2 exemplified by their phosphorylation lessening; and (f) a decrease in diabetic dyslipidemia following lowering of intracellular events that govern lipoprotein assembly. Therefore these data suggest that AMPK fulfills key functions in metabolic processes in the small intestine. The clear evidence for the involvement of the gut in cardiometabolic events has been obtained through the scrutiny of intestinal specimens obtained from obese subjects after bariatric surgery. Intestine of insulin-resistant subjects shows defects in insulin signaling as demonstrated by reduced Akt phosphorylation but increased p38 MAPK phosphorylation. These defects were accompanied with increased oxidative stress and inflammation markers in intestine of insulin-resistant subjects. Enhanced de novo lipogenesis rate and apo B-48 biogenesis along with increased triglyceride-rich lipoprotein production was also observed in the intestine of insulin-resistant subjects. Concomitantly, fatty acid binding proteins (FABP) and microsomal transfer protein (MTP) expression was increased in the intestine of insulin-resistant subjects. In conclusion, the small intestine may be classified as an insulin-sensitive tissue. Its deregulation, possibly triggered by oxidative stress and inflammation, may lead to amplification of lipogenesis and lipoprotein synthesis and may therefore represent a key mechanism for atherogenic dyslipidemia in patients with metabolic syndrome and T2D.

Résistance à l'insuline

Diabète de type 2

Intestin

Dyslipidémie diabétique

Transporteurs du cholestérol

Peptides gastro-intestinaux

Insulin resistance

Type 2 diabetes

Intestine

Diabetic dyslipidemia

Cholesterol transporters

Gut peptides