Dysregulation of glucose transport in hearts of genetically obese (fa/fa) Rats

Zaninetti, D; Crettaz, Marco; Jeanrenaud, B.

doi:10.1007/bf00284464

Cited by 35 publications

(26 citation statements)

References 25 publications

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“…1). These findings corroborate those of others made in other muscle types [4][5][6] and suggest that, although the heart is not representative of the muscle mass, it may undergo -upon the occurrence of insulin resistance -changes that are analogous to those seen in other muscles. This strengthens the observations made during the present study, with regard to the state of the glucose transporters as assessed by the cytochalasin B-binding assay.…”

Section: Discussionsupporting

confidence: 89%

“…With regard to glucose uptake, it has been shown that basal, as well as insulin-stimulated glucose uptake, was decreased in most obesity syndromes studied [2,[4][5][6]. As is now well established in adipocytes [8,9] and also described in muscle [10], glucose transporting molecules (glucose transporters) are present both in the plasma and in some intracellular (microsomal) membranes.…”

mentioning

confidence: 94%

“…It has been demonstrated to be present in vitro as well as in vivo (reviewed in 1), and bears on insulin receptor number [2]; insulin receptor autophosphylation [3]; glucose uptake [4,5]; glycolysis [4][5][6] and glycogen synthesis [7].…”

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confidence: 99%

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Dysregulation of glucose transport and transporters in perfused hearts of genetically obese (fa/fa) rats

Zaninetti

Greco-Perotto

Assimacopoulos-Jeannet

et al. 1989

Diabetologia

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Summary. The regulation of glucose transport in normal and insulin-resistant obese rat hearts have been studied by measuring glucose transport via the efflux of labelled 3-0-methyl-Dglucose. Glucose transporters in obese rat hearts were also investigated using the labelled cytochalasin B-binding assay. Basal, and insulin -or increasing workload-induced stimulation of glucose transport was decreased in obese rat hearts compared to those of normal ones. Total number of glucose transporters (plasma membrane plus microsomal ones) was about half that previously reported for normal rat hearts. Insulin or workload favoured the translocation of glucose transporters from an intercellular pool (microsomes) to the plasma membrane, as they do in normal rats. Due to the measured decrease in total number of transporters of obese rat hearts, those present in the plasma membrane (under basal conditions, or following stimulation by insulin or workload) were less than those previously found[ in normal rat hearts tested under identical conditions. In obese rat hearts, regulation of plasma membrane transporters was perturbed. The Hill coefficient (an index of positive cooperativity amongst glucose transporters) was paradoxically decreased by insulin while leaving affinity values unaltered. The Hill coefficient was unaltered by workload, although the affinity values were increased compared to respective controls. To sum up, obese rat hearts have decreased total transporter number, and although the two stimuli studied favour the translocation of available transporters, they fail to "activate" them adequately once present in the plasma membrane.

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Section: Discussionsupporting

confidence: 89%

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confidence: 94%

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Dysregulation of glucose transport and transporters in perfused hearts of genetically obese (fa/fa) rats

Zaninetti

Greco-Perotto

Assimacopoulos-Jeannet

et al. 1989

Diabetologia

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“…Thus, work-induced hypertrophy was able to compensate for decreased insulin responsiveness observed in GTG-obese muscles. Additive effects of insulin and work induced by pressure were also observed in perfused hearts from obese Zucker rats [29]. The mechanisms of such effects of exercise are unknown.…”

Section: Discussionmentioning

confidence: 98%

Effect of work-induced hypertrophy on muscle glucose metabolism in lean and obese mice

1985

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Summary. The effect of work-induced hypertrophy (without any concomitant change in circulating parameters) on skeletal muscle metabolism was studied in lean mice and in goldthioglucose obese-mice. Soleus muscle was functionally overloaded in one leg by tenotomy of gastrocnemius muscle 4 days before muscle isolation, muscle in the other leg being used as control. Basal deoxyglucose uptake and glycolysis were markedly increased in overloaded muscles compared with control muscles, together with a ten-fold increase in fructose 2-6 bisphosphate content. In the presence of maximally effective insulin concentrations, deoxyglucose uptake and glycolysis were identical in overloaded and control muscles of lean mice, while the effects of overload and insulin were partly additive in muscles of goldthioglucose-obese mice. The sensitivity to insulin and insulin binding to muscles were not modified in overloaded muscles. Insulin-stimulated glycogenogenesis was decreased by about 50% probably due to a lower amount of glycogen synthase in overloaded than in control muscles. Thus, in muscles of goldthioglucose-obese mice work-induced hypertrophy increased the response to maximal insulin concentrations without modifying the altered insulin sensitivity and decreased insulin binding. Key words:Insulin, insulin resistance, obesity, exercise, glucose metabolism, glycogen synthase, fructose 2-6 bisphosphate, skeletal muscle, goldthioglucose obese mice, hypertrophy.Muscle tissue from obese hyperinsulinaemic animals displays a number of abnormalities including a defect in glucose transport and utilization, an altered aminoacid transport and a decrease in insulin binding [1][2][3][4][5]. This results in decreased insulin sensitivity and responsiveness of this tissue, which largely contribute to the marked insulin resistance observed in genetically-or experimentally-induced obese syndromes. In normal man and animals it has been demonstrated repeatedly that physical training is associated with an increase in overall insulin sensitivity in vivo [6][7][8][9][10][11]; skeletal muscle seems to contribute essentially to this increased insulin sensitivity [9][10][11]. In obese animals, although physical training by treadmill running or by swimming improves tolerance, insulin resistance in muscle is either unchanged [7,8] or partly reversed [7].In the present study, we used the following approach. By cutting the connection of the gastrocnemius muscle to the ankle of one single leg, an important work load is applied to the soleus muscle which undergoes rapid compensatory hypertrophy [12]. Taking advantage of this experimental technique, we compared a hypertrophied, overloaded muscle in one leg with a control muscle in the other within the same animal, and we studied the effect of this form of exercise on glucose uptake and metabolism in lean and goldthioglucose-obese mice. Materials and methods AnimalsMale Swiss albino mice (age 7-8 weeks) were fed ad libitum with laboratory chow (Usine d'Alimentation Rationnelle, Villemoisson, Epinay/Orge, France)...

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“…Fhe genetically obese OCa/fa) Zucker rat is a well-documented animal model for insulin resistance in skeletal [1,2] and cardiac m~tscle [3,4]. It has been suggested that a defect of the glucose ur take itself may contribute besides other defects to this insulin re,4stance [5,6].…”

Section: Introductionmentioning

confidence: 99%

Insulin‐dependent translocation of the small GTP‐binding protein rab3C in cardiac muscle: studies on insulin‐resistant Zucker rats

1995

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The failure of insufin-regulated recruitment of the GLUT4 glucose transporter in cardiac muscle of obese Zucker rats is associated with alterations of the subcellular distribution of the small-molecular-mass GTP-binding protein rab4A. Here, we show by subcellular fractionation and Western blotting a translocation of the smull-molecular-mass GTP-binding protein rab3C from microsomul membranes to plasma membranes in lean control rats following in vivo insulin stimulation. However, in cardiac muscle of obese animals no significant effect of the hormone on the subcellular distribution of rab3C was observed. In GLUT4-enriched membrane vesicles, obtained from cardiac microsomes of the obese group as well as of lean controls, rab3C was not detectable. It is suggested that the altered behaviour of rah3C may contribute to an impaired trafficking of GLUT4 in the insulin-resistant state.

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Dysregulation of glucose transport in hearts of genetically obese (fa/fa) Rats

Cited by 35 publications

References 25 publications

Dysregulation of glucose transport and transporters in perfused hearts of genetically obese (fa/fa) rats

Dysregulation of glucose transport and transporters in perfused hearts of genetically obese (fa/fa) rats

Effect of work-induced hypertrophy on muscle glucose metabolism in lean and obese mice

Insulin‐dependent translocation of the small GTP‐binding protein rab3C in cardiac muscle: studies on insulin‐resistant Zucker rats

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