Effects of acute and chronic exercise on sarcolemmal MCT1 and MCT4 contents in human skeletal muscles: current status

Thomas, Claire; Bishop, David; Lambert, Karen; Mercier, Jacques; Brooks, George A.

doi:10.1152/ajpregu.00250.2011

Cited by 92 publications

(89 citation statements)

References 150 publications

(280 reference statements)

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“…The production of lactate by one tissue and use by another is representative of the lactate shuttle: the mosaic distribution pattern of oxidative and glycolytic fibers is favorable for the exchange of lactate. Exercise may produce greater increases in MCT1 than MCT4 expression (148). On the other hand, denervation for 3 weeks brings about a significant decrease in the expression of MCT4 as well as MCT1 (158).…”

Section: The Musclementioning

confidence: 97%

Cellular distributions of monocarboxylate transporters: a review

Iwanaga

Kishimoto

2015

Biomed. Res.

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Lactate and ketone bodies play important roles as alternative energy substrates, especially in conditions with a decreased utility of glucose. Short-chain fatty acids (acetate, propionate, and butyrate), produced by bacterial fermentation, supply most of the energy substrates in ruminants such as the cow and sheep. These monocarboxylates are transfered through the plasma membrane by proton-coupled monocarboxylate transporters (MCTs) and sodium-coupled MCTs (SMCTs). To reveal the metabolism and functional significance of monocarboxylates, the cellular localization of MCTs and SMCTs together with the expressed intensities holds great importance. This paper reviews the immunohistochemical localization of SMCTs and major MCT subtypes throughout the mammalian body. MCTs and SMCTs display a selective membrane-bound localization with porality. In contrast to the limited expression of SMCTs in the intestine and kidney, MCTs display a broader distribution pattern than GLUTs. The brain, kidney, placenta, and male genital tract express multiple subtypes of the MCT family. Determination of the cellular localization of MCTs is most controversial in the brain, possibly due to regional differences and the transcriptional modification of MCT proteins. Information on the localization of MCTs and SMCTs aids in understanding the nutrient absorption and metabolism throughout the mammalian body. In some cases, the body may use monocarboxylates as signal molecules, like hormones.

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Section: The Musclementioning

confidence: 97%

Cellular distributions of monocarboxylate transporters: a review

Iwanaga

Kishimoto

2015

Biomed. Res.

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“…noradrenaline, insulin, IGF-1, butyrate or by other regulatory factors like exercise, hypoxia or the diabetic state. These modulations were shown to be linked to regulatory proteins like NF-κB, calcineurin, AMPK, PGC1α, HIF-1α and mTOR [22]–[28]. The regulation of the thyroid hormone transporters MCT8 and MCT10 remains virtually unknown [29].…”

Section: Introductionmentioning

confidence: 99%

Tissue-Specific Expression of Monocarboxylate Transporters during Fasting in Mice

et al. 2014

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Monocarboxylates such as pyruvate, lactate and ketone bodies are crucial for energy supply of all tissues, especially during energy restriction. The transport of monocarboxylates across the plasma membrane of cells is mediated by monocarboxylate transporters (MCTs). Out of 14 known mammalian MCTs, six isoforms have been functionally characterized to transport monocarboxylates and short chain fatty acids (MCT1-4), thyroid hormones (MCT8, -10) and aromatic amino acids (MCT10). Knowledge on the regulation of the different MCT isoforms is rare. In an attempt to get more insights in regulation of MCT expression upon energy deprivation, we carried out a comprehensive analysis of tissue specific expression of five MCT isoforms upon 48 h of fasting in mice. Due to the crucial role of peroxisome proliferator-activated receptor (PPAR)-α as a central regulator of energy metabolism and as known regulator of MCT1 expression, we included both wildtype (WT) and PPARα knockout (KO) mice in our study. Liver, kidney, heart, small intestine, hypothalamus, pituitary gland and thyroid gland of the mice were analyzed. Here we show that the expression of all examined MCT isoforms was markedly altered by fasting compared to feeding. Expression of MCT1, MCT2 and MCT10 was either increased or decreased by fasting dependent on the analyzed tissue. MCT4 and MCT8 were down-regulated by fasting in all examined tissues. However, PPARα appeared to have a minor impact on MCT isoform regulation. Due to the fundamental role of MCTs in transport of energy providing metabolites and hormones involved in the regulation of energy homeostasis, we assumed that the observed fasting-induced adaptations of MCT expression seem to ensure an adequate energy supply of tissues during the fasting state. Since, MCT isoforms 1–4 are also necessary for the cellular uptake of drugs, the fasting-induced modifications of MCT expression have to be considered in future clinical care algorithms.

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“…For example, 14 weeks of moderate aerobic exercise training (cycling for 30–40 minutes at an intensity corresponding to 60%–70% of maximal heart rate, 4 times per week) increased the peak cardiac output of MD patients by 15% and the activity of mitochondrial enzymes, citrate synthase and hydroxyacyl CoA dehydrogenase, by 60%–80% [43]. In healthy subjects, it is well known that exercise training increases the expression of glucose [44,45], lactate [46,47], and fatty acid transporters [48,49] in muscle; in contrast, physical inactivity decreases the expression of these substrate transporters [50,51,52]. Although the effects of exercise training on metabolite transporters in MD patients have not yet been investigated, these data suggest that the capacity for delivery and oxidation of blood-borne fuels increases with exercise training in MD patients.…”

Section: Exercise Training As a Possible Treatmentmentioning

confidence: 99%

McArdle Disease and Exercise Physiology

Kitaoka

2014

Biology

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McArdle disease (glycogen storage disease Type V; MD) is a metabolic myopathy caused by a deficiency in muscle glycogen phosphorylase. Since muscle glycogen is an important fuel for muscle during exercise, this inborn error of metabolism provides a model for understanding the role of glycogen in muscle function and the compensatory adaptations that occur in response to impaired glycogenolysis. Patients with MD have exercise intolerance with symptoms including premature fatigue, myalgia, and/or muscle cramps. Despite this, MD patients are able to perform prolonged exercise as a result of the “second wind” phenomenon, owing to the improved delivery of extra-muscular fuels during exercise. The present review will cover what this disease can teach us about exercise physiology, and particularly focuses on the compensatory pathways for energy delivery to muscle in the absence of glycogenolysis.

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Effects of acute and chronic exercise on sarcolemmal MCT1 and MCT4 contents in human skeletal muscles: current status

Cited by 92 publications

References 150 publications

<b>Cellular distributions of monocarboxylate transporters: a r</b><b>eview </b>

<b>Cellular distributions of monocarboxylate transporters: a r</b><b>eview </b>

Tissue-Specific Expression of Monocarboxylate Transporters during Fasting in Mice

McArdle Disease and Exercise Physiology

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