Malonyl-CoA, fuel sensing, and insulin resistance

Ruderman, Neil B.; Saha, Asish K.; Vavvas, Demetrios G.; Witters, Lee A.

doi:10.1152/ajpendo.1999.276.1.e1

Cited by 457 publications

(525 citation statements)

References 125 publications

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“…Visceral obesity has since been reproducibly implicated as an independent risk factor for insulin resistance and glucose intolerance, which predict type 2 diabetes and cardiovascular disease in different ethnic populations [1,2]. One of the hypotheses proposed to explain the link between visceral obesity and the chronic complex metabolic diseases is the visceral/portal hypothesis, in which: (1) an increased hepatic uptake of the 'first pass' of NEFAs released from visceral fat lipolysis into the portal vein may reduce the hepatic extraction of insulin and thus impair insulin-induced suppression of hepatic gluconeogenesis, leading to increased endogenous glucose production; (2) an increased hepatic lipase activity may remove lipids from LDL and HDL, which, in combination with the decreased degradation of apolipoprotein B and the increased esterification of NEFAs, results in the increased synthesis and secretion of VLDL and smaller, denser LDL and HDL particles into the systemic circulation, distorting the circulating lipid profile; and (3) an increased systemic NEFA flux may impair insulin action in skeletal muscle and other key tissues via malonyl-CoA/acetyl-CoA carboxylase β fuel-sensing and regulation mechanisms [1,2,6].…”

Section: Adipose Tissue Between-depot Issuesmentioning

confidence: 99%

Adipose tissue distribution and risk of metabolic disease: does thiazolidinedione-induced adipose tissue redistribution provide a clue to the answer?

2007

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The relative effect of visceral and subcutaneous obesity on the risk of chronic metabolic disease has been a matter of long-term dispute. While ample data support either of the fat depots being causative or associative, valid argument for one depot often automatically belittles the other. Paradigms such as the visceral/portal hypothesis and the acquired lipodystrophy/ectopic fat storage and endocrine hypothesis have been proposed. Nevertheless, neither hypothesis alone explains the entire pathophysiological setting. Treatment of diabetes with thiazolidinediones selectively increases fat partitioning to the subcutaneous adipose depot but does not change visceral fat accumulation. This is in contrast to the preferential visceral fat mobilisation by diet and exercise. Surgical removal of visceral or subcutaneous adipose tissue yields relatively long-lasting metabolic improvement only when combined with procedures that ameliorate adipose tissue cell composition. These studies illustrate that human adipose tissue in different anatomic locations does not work in isolation, and that there is a best-fit relationship in terms of volume and function among different fat depots that needs to be met to maintain the systemic energy balance and to prevent the complications related to obesity.

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Section: Adipose Tissue Between-depot Issuesmentioning

confidence: 99%

Adipose tissue distribution and risk of metabolic disease: does thiazolidinedione-induced adipose tissue redistribution provide a clue to the answer?

2007

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“…Inhibition of ACC, with consequent lowering of tissue malonyl-CoA, occurs as a result of the increased deficit between the rate of ATP production and ATP utilization that leads to increased formation of AMP and activation of AMPK. The ensuing fall in tissue malonylCoA content activates fatty acid oxidation [4,62,63]. Moreover, in untrained rats and humans, graded exercise results in a fall in …”

Section: Role Of Malonyl-coa-acyl-coa Axis In Fuel Selection By Musclementioning

confidence: 99%

“…In insulin-resistant states the TAG content of muscle is increased [112], presumably due to the combination of the chronic elevation of the rate of delivery of plasma NEFA and glucose to the tissue (see Scheme 5). It has been pointed out that muscle malonyl-CoA content is also elevated in several models of insulin resistance [4,113]. This is expected to predispose muscle cells to accumulate intracellular TAG when plasma NEFA are elevated, especially when blood glucose is also elevated.…”

Section: Synthesis Of Glycerolipids In Muscle and Pancreatic β-Cellsmentioning

confidence: 99%

“…However, it is possible that other malonyl-CoAutilizing enzymes may be involved in terminating the malonylCoA signal to the cell in non-lipogenic tissues. Such a role has been suggested for the fatty acid chain-elongation system [17] and for malonyl-CoA decarboxylase [4,18]. However, malonylCoA decarboxylase is not thought to have a cytosolic distribution in mammalian tissues [19].…”

Section: Introductionmentioning

confidence: 99%

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The malonyl-CoA–long-chain acyl-CoA axis in the maintenance of mammalian cell function

Zammit

1999

Biochemical Journal

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Long-chain acyl-CoA esters have potent specific actions (e.g. on gene transcription, membrane trafficking) as well as non-specific ones (e.g. on phospholipid bilayers). They are synthesized on the cytosolic aspects of several intracellular membranes, to give rise to (a) cytosolic pool(s) to which a variety of enzymes and processes have access, including some localized in the nucleus. Their concentration in cells is highly regulated, interconversion with corresponding acylcarnitines being the most important mechanism involved. This reaction is catalysed by cytosol-accessible carnitine long-chain acyl (palmitoyl) transferase activities that are themselves located on multiple membrane systems. Regulation of these activities is through the inhibitory action of malonyl-CoA. Hence the existence of a potent malonyl-CoA-acyl-CoA axis through which many processes involved in the maintenance of mammalian cell function are regulated. The molecular, topographical and physiological interactions that make this possible are described and discussed.

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“…It has indeed been proposed that intracellular fatty acyl CoA may directly inhibit muscle glucose transport by impairing insulin signaling . According to this scheme, impaired muscle lipid oxidation, possibly related to a low muscle oxidative capacity (as often observed in insulin resistant individuals; Kelley & Simoneau, 1997) would lead to accumulation of muscle fatty acyl CoA and insulin resistance (Ruderman et al, 1999). Recent interest has focused on the potential role of intramyocellular lipids (ie lipids stored within the skeletal muscle fibers) in the pathogenesis of insulin resistance.…”

Section: Dietary and Lifestyle Interventionsmentioning

confidence: 99%

Dietary and lifestyle interventions in the management of the metabolic syndrome: present status and future perspective

Minehira

Tappy

2002

Eur J Clin Nutr

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Objective: To review the mechanisms underlying the metabolic syndrome, or syndrome X, in humans, and to delineate dietary and environmental strategies for its prevention. Design: Review of selected papers of the literature. Results: Hyperinsulinemia and insulin resistance play a key role in the development of the metabolic syndrome. Strategies aimed at reducing insulin resistance may be effective in improving the metabolic syndrome. They include low saturated fat intake, consumption of low-glycemic-index foods, physical exercise and prevention of obesity. Conclusions: Future research, in particular the genetic basis of the metabolic syndrome and the interorgan interactions responsible for insulin resistance, is needed to improve therapeutic strategies for the metabolic syndrome.

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Malonyl-CoA, fuel sensing, and insulin resistance

Cited by 457 publications

References 125 publications

Adipose tissue distribution and risk of metabolic disease: does thiazolidinedione-induced adipose tissue redistribution provide a clue to the answer?

Adipose tissue distribution and risk of metabolic disease: does thiazolidinedione-induced adipose tissue redistribution provide a clue to the answer?

The malonyl-CoA–long-chain acyl-CoA axis in the maintenance of mammalian cell function

Dietary and lifestyle interventions in the management of the metabolic syndrome: present status and future perspective

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