Síndrome metabólica e declínio cognitivo: papel do exercício físico / Metabolic syndrome and cognitive decline: role of physical exercise

Natália Gomes Gonçalves

04 May 2018

Evidências disponíveis na literatura sugerem uma conexão entre ingestão de frutose, síndrome metabólica e declínio cognitivo. Na sociedade ocidental, o aumento de casos de síndrome metabólica ocorreu em paralelo ao aumento do consumo de excesso de frutose na dieta. Além disso, animais que consomem excesso de frutose em sua dieta apresentam alterações típicas de resistência à insulina em seus cérebros, além de desenvolverem declínio cognitivo. Sabe-se que exercício físico é capaz de prevenir atrofia do hipocampo e atenuar declínio cognitivo. O objetivo desse estudo foi avaliar se exercício aeróbico é capaz de prevenir o declínio cognitivo associado a um excesso de frutose na dieta e investigar os mecanismos pelos quais isso poderia ocorrer. Ratos Wistar machos foram divididos em quatro grupos: controle sedentário, exercício, frutose sedentário e frutose+exercício. A memória operacional foi testada através do labirinto de Barnes. A sinalização de insulina e de moléculas relacionadas ao exercício foram avaliados no hipocampo e no músculo quadríceps através de Western Blot e PCR em tempo real. A ingestão de excesso de frutose induziu declínio cognitivo que não foi atenuado pelo exercício. O hipocampo dos animais que ingeriram frutose não apresentou deficiência na sinalização de insulina, mas apresentou leve diminuição em BDNF e sinaptofisina, o que foi acompanhado de diminuição significativa da expressão de PGC1alfa tanto no músculo quanto no hipocampo. O musculo quadríceps dos animais alimentados com frutose também mostrou uma diminuição significativa na expressão da miocina irisina (FNDC5) e de genes ligados à autofagia, ao transporte de glicose (GLUT4) e à oxidação de ácidos graxos (NR4A3, PPAR?, Erralfa). Treino aeróbico foi incapaz de reverter todas essas alterações. Em contraste, tratamento metformina foi capaz de prevenir o declínio cognitivo de animais que ingeriram excesso de frutose. Podemos concluir que ingestão de frutose prejudicou a expressão de genes críticos à adaptação do músculo ao exercício e, como resultado, atenuou efeitos benéficos do exercício no cérebro. Tratamento com metformina preveniu a queda na expressão de FNDC5 e BDNF e, consequentemente, o declínio cognitivo em ratos alimentados com frutose através de uma ação direta no cérebro, apesar de não prevenir os efeitos deletérios da frutose no músculo esquelético / Available evidence in the literature suggests a link between fructose ingestion, Metabolic Syndrome and cognitive impairment. In Western society, the rise in the frequency of Metabolic Syndrome was paralleled by a rise in consumption of a high fructose diet. Moreover, molecular alterations typically related to insulin resistance have been found in brains of fructose-induced insulin-resistant rats, and these rodents also develop cognitive deterioration. Physical exercise is well known to prevent hippocampal atrophy and to attenuate cognitive decline. The objective of this study was to evaluate if aerobic training can ameliorate cognitive decline associated with excessive fructose ingestion and to investigate the pathways through which this might occur. Male Wistar rats were divided into four groups: sedentary control, exercise, sedentary fructose, fructose+exercise. Working memory was assessed on the Barnes Maze. Intracellular insulin and exercise-related signaling molecules of the hippocampus and quadriceps femori were assayed using Western blot and Real time PCR. Fructose ingestion induced cognitive decline which was not attenuated by exercise. Insulin signaling was not impaired in the hippocampus in the fructose-fed animals, but there was a slight decrease in BDNF and synaptophysin in the hippocampus, accompanied by a significant decrease in exercise-induced expression of PGC1alpha both in the hippocampus and the muscle of exercised animals that ingested fructose. The quadriceps femori of fructose-fed animals also showed a significant decrease in expression of the myokine irisin (FNDC5) and of genes related to autophagy, glucose transport (GLUT4) and fatty acid oxidation (NR4A3, PPAR?, Err alpha). Exercise training was unable to reverse all of these alterations. Contrarily, metformin administration ameliorated cognitive decline in fructose-fed rats. We conclude that fructose feeding impaired expression of genes that are critical to skeletal muscle adaptation to exercise, which in turn attenuated the beneficial effects of exercise in the brain. Treatment with metformin was able to prevent the decline in expression of FNDC5 and BDNF ameliorating cognitive decline in fructose fed rats by direct action in the brain, despite being unable to reverse the effects of fructose feeding in the muscle

Exercício físico

Frutose

Hipocampo

Memória operacional

Metformina

Músculo esquelético

Exercise training

Fructose

Hippocampus

Metformin

Muscle skeletal

Working memory

Rôle de la ghréline dans la régulation du coactivateur transcriptionnel PGC-1alpha

Keil, Sarah

12 1900

L’adaptation de l’organisme à son environnement est essentielle à sa survie. L’homéostasie énergétique permet l’équilibre entre les apports, les dépenses et le stockage d’énergie. Un surplus calorique important dérègle ce processus et mène au développement du syndrome métabolique caractérisé, entre autres, par une obésité, un diabète de type II, des maladies cardiovasculaires et des dyslipidémies. La ghréline participe au maintien de l’équilibre énergétique durant le jeûne en stimulant la production de glucose par le foie et le stockage lipidique dans le tissu adipeux. Le coactivateur transcriptionnel PGC-1alpha, surexprimé en situation de jeûne, est impliqué dans l’induction de la production de glucose par le foie et l’oxydation des acides gras. Notre hypothèse est que ces deux acteurs clés du métabolisme énergétique constituent un axe de régulation commun. Dans cette étude, nous montrons que la ghréline participe à la régulation de PGC-1alpha. Son récepteur GHS-R1a, possédant une forte activité constitutive, est également impliqué de façon indépendante au ligand. GHS-R1a réduit l’activité transcriptionnelle de PGC-1alpha tandis que l’ajout du ligand inverse modérément cette action. L’effet de GHS-R1a corrèle avec l’acétylation de PGC-1alpha qui est fortement augmentée de façon dose-dépendante. La stabilité de PGC-1alpha est également augmentée par le GHS-R1a indépendamment de l’ubiquitine. La ghréline diminue la capacité de PGC-1alpha à lier PPARbeta, un récepteur nucléaire partenaire de PGC-1alpha. De plus, la ghréline réduit, de façon ligand-dépendante, la capacité de coactivation de PGC-1alpha sur PPARbeta dans les hépatocytes. L’ensemble de ces résultats identifie PGC-1alpha comme cible du signal de la ghréline et suggère un axe de régulation ghréline/PGC-1alpha/PPARbeta.Une meilleure compréhension de cet axe de régulation va permettre la mise en évidence de nouvelles cibles thérapeutiques pour faire face aux pathologies associées au syndrome métabolique. / The adaptation of an organism to its environment is essential to its survival. Energy homeostasis is defined as the balance between intakes, expenses and storage of energy. An excess of calories disrupts this process and leads to the development of the metabolic syndrome that is characterized by obesity, type II diabetes, cardiovascular diseases and dyslipidemia. During fasting, ghrelin participates in the maintenance of energy balance by stimulating hepatic production of glucose and lipid storage in adipose tissue. The transcriptional coactivator PGC-1alpha is overexpressed in the liver during fasting and is involves in the induction of the hepatic glucose production and fatty acid oxidation. Our hypothesis is that these two key performers in the energy metabolism constitute a common axis control. In this study, we show that ghrelin plays a role in the regulation of PGC-1alpha. The ghrelin receptor GHS-R1a is also involved because of its strong constitutive activity in absence of ligand. We found that GHS-R1a inhibited PGC-1alpha transcriptional activity whereas adding ghrelin to cells moderated this effect. PGC-1alpha activation by GHS-R1a correlated with a dose-dependent increase of PGC-1alpha acetylation. The stability of PGC-1alpha was also increased by ghrelin receptor in a manner involving the ubiquitin-independent proteasome pathway. Ghrelin decreased the ability of PGC-1alpha to bind to PPARbeta, one of its nuclear receptor partners. Furthermore, ghrelin decreased the ability of PGC-1alpha to coactivate PPARbeta in a ligand-dependent manner in hepatocytes. Together, these results identify PGC-1alpha as a metabolic target of GHSR-1a signaling and defines a new regulatory axis involving ghrelin/PGC-1alpha/PPARbeta in hepatocytes. A better understanding of this regulation axis will provide novel aspects in therapeutic targeting of diseases associated with the metabolic syndrome.

PGC-1alpha

GHS-R1a

Ghréline

Coactivateur transcriptionnel

Récepteurs nucléaires

PPARbeta

PGC-1alpha

GHS-R1a

Ghrelin

Nuclear receptors

Transcriptional coactivator

Metabolic syndrome

Syndrome métabolique

PPARbeta

Transcriptional regulation of the hepatic cytochrome <em>P450 2a5</em> gene

Arpiainen, S. (Satu)

25 September 2007

Abstract Cytochrome P450 (CYP) enzymes are the major metabolizers of xenobiotics, e.g. drugs, and environmental toxins. Thus, changes in CYP expression have an important impact on drug metabolism and susceptibility to chemical toxicity. In the present study, the transcriptional mechanisms of both constitutive and inducible regulation of the Cyp2a5 gene in mouse liver were investigated. Mouse primary hepatocyte cultures were used as the main model system together with cell and molecular biology methods. The key activation regions of the Cyp2a5 5' promoter were determined using reporter gene assays. Two major transcription activation sites of the Cyp2a5 5' promoter, called the proximal and the distal, were found. Transcription factors hepatocyte nuclear factor-4 (HNF-4) and nuclear factor I were shown to bind to the proximal promoter. Aryl hydrocarbon receptor nuclear translocator (ARNT) and upstream stimulatory factor bound to a common palindromic E-box element in the distal promoter region. All three response elements were shown to be essential for constitutive expression of CYP2A5 in murine hepatocytes. ARNT appeared to control Cyp2a5 transcription without a heterodimerization partner suggesting active involvement of the ARNT homodimer in mammalian gene regulation. Aryl hydrocarbon receptor (AHR) ligands were shown to induce Cyp2a5 transcriptionally by an AHR-dependent mechanism, and established Cyp2a5 as a novel AHR-regulated gene. The AHR response element and the E-box, identified in these studies, were located near to each other and close to a separately defined nuclear factor (erythroid-derived 2)-like 2 binding site in the distal region of the Cyp2a5 promoter, suggesting cooperation between these elements. Peroxisome proliferator-activated receptor gamma coactivator-1α was shown to up-regulate Cyp2a5 transcription through coactivation of HNF-4α. This indicates that xenobiotic metabolism can be regulated by modification of co-activation. The present results show that CYP2A5 is regulated by several different cross-regulatory pathways. The regulatory mechanisms involved in the transcription of the Cyp2a5 gene may also control other CYP genes, especially the human ortholog CYP2A6, and may explain some of the individual variations in the metabolism of xenobiotics.

CYP2A5

aryl hydrocarbon receptor

cytochrome P450 enzyme system

hepatocyte nuclear factor 4

nuclear factor I

upstream stimulatory factors

Oxidative Stress Induces Mitochondrial Compromise in CD4 T Cells From Chronically HCV-Infected Individuals

Schank, Madison B., Zhao, Juan, Wang, Ling, Nguyen, Lam N., Cao, Dechao, Dang, Xindi, Khanal, Sushant, Zhang, Jinyu, Zhang, Yi, Wu, Xiao Y., Ning, Shunbin, Elgazzar, Mohamed A., Moorman, Jonathan P., Yao, Zhi Q.

01 January 2021

We have previously shown that chronic Hepatitis C virus (HCV) infection can induce DNA damage and immune dysfunctions with excessive oxidative stress in T cells. Furthermore, evidence suggests that HCV contributes to increased susceptibility to metabolic disorders. However, the underlying mechanisms by which HCV infection impairs cellular metabolism in CD4 T cells remain unclear. In this study, we evaluated mitochondrial mass and intracellular and mitochondrial reactive oxygen species (ROS) production by flow cytometry, mitochondrial DNA (mtDNA) content by real-time qPCR, cellular respiration by seahorse analyzer, and dysregulated mitochondrial-localized proteins by Liquid Chromatography-Mass Spectrometry (LC-MS) in CD4 T cells from chronic HCV-infected individuals and health subjects. Mitochondrial mass was decreased while intracellular and mitochondrial ROS were increased, expressions of master mitochondrial regulators peroxisome proliferator-activated receptor 1 alpha (PGC-1α) and mitochondrial transcription factor A (mtTFA) were down-regulated, and oxidative stress was increased while mitochondrial DNA copy numbers were reduced. Importantly, CRISPR/Cas9-mediated knockdown of mtTFA impaired cellular respiration and reduced mtDNA copy number. Furthermore, proteins responsible for mediating oxidative stress, apoptosis, and mtDNA maintenance were significantly altered in HCV-CD4 T cells. These results indicate that mitochondrial functions are compromised in HCV-CD4 T cells, likely the deregulation of several mitochondrial regulatory proteins.

adult

aged

CD4-positive t-lymphocytes (immunology)

DNA

mitochondrial

female

hepatitis c

chronic (immunology)

humans

male

middle aged

mitochondria (genetics

immunology)

oxidative stress

reactive oxygen species (immunology)

young adult

mtDNA

mtTFA

HCV

mitochondrial respiration

oxidative stress

Internal Medicine