Can maternal physical activity modulate the nutrition-induced fetal programming?

Existe considerável evidência para a indução de diferentes fenótipos em reposta às variações no ambiente fetal e neonatal. O aporte inadequado de nutrientes no período crítico do desenvolvimento está associado ao risco alto de doenças metabólicas na vida adulta, este fenômeno biológico é chamado de programação. A atividade física durante a gestação resulta em adaptações fisiológicas da mãe e no aumento da disponibilidade de nutrientes e oxigênio no espaço feto-placentário. Este trabalho tem como objetivo discutir os mecanismos da indução de programação fetal pela nutrição e o provável efeito modulador da atividade física durante a gestação. Foram utilizadas as bases de dados do Medline Pubmed, Lilacs e Bireme, com publicações entre 1990 até 2008. Os termos de indexação utilizados foram: nutrition, fetal programming, gestation, physical activity, physical exercise, metabolism. Em conclusão, o aporte inadequado de nutrientes programa o aparecimento de doenças metabólicas na vida adulta, enquanto que a atividade física durante a gestação aumenta a disponibilidade de nutrientes e oxigênio, repercutindo positivamente no crescimento fetal e no peso ao nascer.There is considerable evidence for the induction of different phenotypes by variations in fetal and neonatal environment. Undernutrition during this critical development period is associated with risk of metabolic disease in adult life; this biological phenomenon is termed programming. Physical activity during gestation results in maternal physiological adaptations and increased oxygen and nutrients in the fetoplacental compartment. The main goal of this work is to discuss the mechanisms of fetal programming induced by nutrition and the probable modulating effect of physical activity during gestation. Papers published between 1990 and 2008 listed in the Medline Pubmed, Lilacs and Bireme databases were used. The search keywords were: nutrition, fetal programming, gestation, physical activity, physical exercise, and metabolism. In conclusion, undernutrition can program the onset of metabolic diseases in adult life, while physical activity during gestation increases the availability of nutrients and oxygen for the fetus, thereby positively impacting fetal growth and birth weight

Mechanisms underlying skeletal muscle insulin resistance induced by fatty acids: importance of the mitochondrial function

Insulin resistance condition is associated to the development of several syndromes, such as obesity, type 2 diabetes mellitus and metabolic syndrome. Although the factors linking insulin resistance to these syndromes are not precisely defined yet, evidence suggests that the elevated plasma free fatty acid (FFA) level plays an important role in the development of skeletal muscle insulin resistance. Accordantly, in vivo and in vitro exposure of skeletal muscle and myocytes to physiological concentrations of saturated fatty acids is associated with insulin resistance condition. Several mechanisms have been postulated to account for fatty acids-induced muscle insulin resistance, including Randle cycle, oxidative stress, inflammation and mitochondrial dysfunction. Here we reviewed experimental evidence supporting the involvement of each of these propositions in the development of skeletal muscle insulin resistance induced by saturated fatty acids and propose an integrative model placing mitochondrial dysfunction as an important and common factor to the other mechanisms

Metabolic regulation and production of oxygen reactive species during muscule contraction: effect of glycogen on intracellular redox state

O exercício físico prolongado reduz os estoques de glicogênio muscular. Nessas condições, os processos de fadiga muscular são estimulados coincidindo com um aumento na produção de espécies reativas de oxigênio. A suplementação de carboidratos ou de antioxidantes isoladamente contribui para a melhora da performance muscular, sugerindo um efeito importante da depleção de substrato (glicose) e do aumento da produção de EROs no desenvolvimento da fadiga muscular durante a atividade física. Embora o mecanismo seja desconhecido, estamos propondo neste estudo que uma maior disponibilidade de glicogênio poderia favorecer uma maior atividade da via das pentoses fosfato, aumentando a disponibilidade de NADPH e GSH no tecido muscular esquelético. Uma maior capacidade antioxidante aumentaria a capacidade do tecido muscular em atividade, mantendo o equilíbrio redox durante atividade física prolongada e melhorando o desempenho. Neste processo, o ciclo glicose-ácido graxo pode ser importante aumentando a oxidação de lipídio e reduzindo o consumo de glicogênio durante a atividade prolongada. Além disso, um aumento na produção de EROs pode reduzir a atividade de enzimas importantes do metabolismo celular incluindo a aconitase e a a-cetoglutarato desidrogenase, comprometendo a produção de energia oxidativa, via predominante na produção de ATP durante a atividade muscular prolongada.Fatigue is closely related to the depletion of glycogen in the skeletal muscle during prolonged exercise. Under this condition, the production of oxygen reactive species (ROS) is substantially increased. It has been shown that dietary supplementation of carbohydrate or antioxidant attenuates muscle fatigue during contraction. This suggests that glycogen availability and/or elevated ROS production plays an important role on muscle fatigue development during prolonged muscle activity. Although the mechanism is still unknown, we propose that elevated muscle glycogen availability may lead to a high activity of hexose monophosphate pathway, increasing the NADPH and glutathione concentration in the skeletal muscle tissue. Elevated antioxidant capacity would increase the muscle redox balance during muscle contraction, improving performance. In this process, the glucose-fatty acid cycle may be important to increase lipid oxidation and consequently decrease glycogen utilization during prolonged activity. In addition, an elevated ROS production could reduce the activity of key metabolic enzymes including aconitase and a-ketoglutarate dehydrogenase, decreasing the oxidative energy production in the skeletal muscle during prolonged activity.FAPESPCoordenacao de Aperfeicoamento de Pessoal de Nivel Superior (CAPES)CNP

Regulation of glucose and fatty acid metabolism in skeletal muscle during contraction

O ciclo glicose-ácido graxo explica a preferência do tecido muscular pelos ácidos graxos durante atividade moderada de longa duração. Em contraste, durante o exercício de alta intensidade, há aumento na disponibilidade e na taxa de oxidação de glicose. A produção de espécies reativas de oxigênio (EROs) durante a atividade muscular sugere que o balanço redox intracelular é importante na regulação do metabolismo de lipídios/carboidratos. As EROs diminuem a atividade do ciclo de Krebs e aumentam a atividade da proteína desacopladora mitocondrial. O efeito oposto é esperado durante a atividade moderada. Assim, as questões levantadas nesta revisão são: Por que o músculo esquelético utiliza preferencialmente os lipídios no estado basal e de atividade moderada? Por que o ciclo glicose-ácido graxo falha em exercer seus efeitos durante o exercício intenso? Como o músculo esquelético regula o metabolismo de lipídios e carboidratos em regime envolvendo o ciclo contração-relaxamento.The glucose-fatty acid cycle explains the preference for fatty acid during moderate and long duration physical exercise. In contrast, there is a high glucose availability and oxidation rate in response to intense physical exercise. The reactive oxygen species (ROS) production during physical exercise suggests that the redox balance is important to regulate of lipids/carbohydrate metabolism. ROS reduces the activity of the Krebs cycle, and increases the activity of mitochondrial uncoupling proteins. The opposite effects happen during moderate physical activity. Thus, some issues is highlighted in the present review: Why does skeletal muscle prefer lipids in the basal and during moderate physical activity? Why does glucose-fatty acid fail to carry out their effects during intense physical exercise? How skeletal muscles regulate the lipids and carbohydrate metabolism during the contraction-relaxation cycle

Macadamia Oil Supplementation Attenuates Inflammation and Adipocyte Hypertrophy in Obese Mice

Excess of saturated fatty acids in the diet has been associated with obesity, leading to systemic disruption of insulin signaling, glucose intolerance, and inflammation. Macadamia oil administration has been shown to improve lipid profile in humans. We evaluated the effect of macadamia oil supplementation on insulin sensitivity, inflammation, lipid profile, and adipocyte size in high-fat diet (HF) induced obesity in mice. C57BL/6 male mice (8 weeks) were divided into four groups: (a) control diet (CD), (b) HF, (c) CD supplemented with macadamia oil by gavage at 2g/Kg of body weight, three times per week, for 12 weeks (CD + MO), and (d) HF diet supplemented with macadamia oil (HF + MO). CD and HF mice were supplemented with water. HF mice showed hypercholesterolemia and decreased insulin sensitivity as also previously shown. HF induced inflammation in adipose tissue and peritoneal macrophages, as well as adipocyte hypertrophy. Macadamia oil supplementation attenuated hypertrophy of adipocytes and inflammation in the adipose tissue and macrophages.Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)Univ São Paulo, Dept Biol Celular & Desenvolvimento, BR-05508000 São Paulo, BrazilUniv Estadual Paulista, UNESP, Dept Educ Fis, Programa Posgrad Ciencia Motricidad, BR-13506900 Rio Claro, SP, BrazilUniv São Paulo, Inst Ciencias Biomed, Dept Fisiol & Biofis, BR-05508000 São Paulo, BrazilUniv Sao Judas Tadeu, Dept Ciencias Biol, Lab Movimento Humano, BR-05503001 São Paulo, BrazilUniversidade Federal de São Paulo, Dept Fisiol, Disciplina Fisiol Nutr, BR-04023901 São Paulo, BrazilUniv São Paulo, Inst Biociencias, Dept Fisiol Geral, BR-05508090 São Paulo, BrazilUniv Cruzeiro Sul, Inst Ciencias Atividade Fis & Esporte, Programa Posgrad Ciencia Movimento Humano, BR-01506000 São Paulo, BrazilUniversidade Federal de São Paulo, Dept Fisiol, Disciplina Fisiol Nutr, BR-04023901 São Paulo, BrazilWeb of Scienc

Regulation of glucose and fatty acid metabolism in skeletal muscle during contraction

O ciclo glicose-ácido graxo explica a preferência do tecido muscular pelos ácidos graxos durante atividade moderada de longa duração. Em contraste, durante o exercício de alta intensidade, há aumento na disponibilidade e na taxa de oxidação de glicose. A produção de espécies reativas de oxigênio (EROs) durante a atividade muscular sugere que o balanço redox intracelular é importante na regulação do metabolismo de lipídios/carboidratos. As EROs diminuem a atividade do ciclo de Krebs e aumentam a atividade da proteína desacopladora mitocondrial. O efeito oposto é esperado durante a atividade moderada. Assim, as questões levantadas nesta revisão são: Por que o músculo esquelético utiliza preferencialmente os lipídios no estado basal e de atividade moderada? Por que o ciclo glicose-ácido graxo falha em exercer seus efeitos durante o exercício intenso? Como o músculo esquelético regula o metabolismo de lipídios e carboidratos em regime envolvendo o ciclo contração-relaxamento555303313CONSELHO NACIONAL DE DESENVOLVIMENTO CIENTÍFICO E TECNOLÓGICO - CNPQCOORDENAÇÃO DE APERFEIÇOAMENTO DE PESSOAL DE NÍVEL SUPERIOR - CAPESFUNDAÇÃO DE AMPARO À PESQUISA DO ESTADO DE SÃO PAULO - FAPESPsem informaçãoThe glucose-fatty acid cycle explains the preference for fatty acid during moderate and long duration physical exercise. In contrast, there is a high glucose availability and oxidation rate in response to intense physical exercise. The reactive oxygen species (ROS) production during physical exercise suggests that the redox balance is important to regulate of lipids/carbohydrate metabolism. ROS reduces the activity of the Krebs cycle, and increases the activity of mitochondrial uncoupling proteins. The opposite effects happen during moderate physical activity. Thus, some issues is highlighted in the present review: Why does skeletal muscle prefer lipids in the basal and during moderate physical activity? Why does glucose-fatty acid fail to carry out their effects during intense physical exercise? How skeletal muscles regulate the lipids and carbohydrate metabolism during the contraction-relaxation cycle

Maternal Moderate Physical Training during Pregnancy Attenuates the Effects of a Low-Protein Diet on the Impaired Secretion of Insulin in Rats: Potential Role for Compensation of Insulin Resistance and Preventing Gestational Diabetes Mellitus

The effects of pregestational and gestational low-to-moderate physical training on insulin secretion in undernourished mothers were evaluated. Virgin female Wistar rats were divided into four groups as follows: control (C, n = 5); trained (T, n = 5); low-protein diet (LP, n = 5); trained with a low-protein diet (T + LP, n = 5). Trained rats ran on a treadmill over a period of 4 weeks before mate (5 days week(-1) and 60 min day(-1), at 65% of VO2max). At pregnancy, the intensity and duration of the exercise were reduced. Low-protein groups were provided with an 8% casein diet, and controls were provided with a 17% casein diet. At third day after delivery, mothers and pups were killed and islets were isolated by collagenase digestion of pancreas and incubated for a further 1 h with medium containing 5.6 or 16.7 mM glucose. T mothers showed increased insulin secretion by isolated islets incubated with 16.7 mM glucose, whereas LP group showed reduced secretion of insulin by isolated islets when compared with both C and LP + T groups. Physical training before and during pregnancy attenuated the effects of a low-protein diet on the secretion of insulin, suggesting a potential role for compensation of insulin resistance and preventing gestational diabetes mellitus.National Council for Scientific and Technological Development (CNPq)National Council for Scientific and Technological Development (CNPq)Foundation to Support Science and Research from Pernambuco State (FACEPE)Foundation to Support Science and Research from Pernambuco State (FACEPE)Sao Paulo Research Foundation (FAPESP)Sao Paulo Research Foundation (FAPESP)Coordination for the Improvement of Higher Level Personnel (CAPES)Coordination for the Improvement of Higher Level Personnel (CAPES)Deans Office for Research/University of Sao PauloDean's Office for Research/University of Sao Paul