Fatty acid cycling in the fasting rat

Kalderon, Bella; Mayorek, Nina; Berry, Elliot M.; Zevit, Noam; Bar‐Tana, Jacob

doi:10.1152/ajpendo.2000.279.1.e221

Cited by 56 publications

(52 citation statements)

References 41 publications

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“…Variation in both primary and secondary cycling is responsible for causing these changes, because fasting does not cause any significant shift in their relative contribution to total reesterification (Fig.5). Under all conditions, rabbits support higher fluxes of secondary than primary cycling (Fig.5) (Reidy and Weber, 2002), as previously reported for humans ) but opposite to the case for rats (Kalderon et al, 2000;McClelland et al, 2001). It is unclear whether body size (or mass-specific metabolic rate) plays a role in setting these interspecific differences in the relative importance of primary vs secondary cycling.…”

Section: Fasting Causes Stimulation Then Inhibition Of Tag/fa Cyclingsupporting

confidence: 48%

“…Calculation of primary and secondary TAG/FA cycling using these equations has been widely used in human studies (Bahr et al, 1990;Elia et al, 1987;Romijn et al, 1993;Vallerand et al, 1999;Wolfe et al, 1987a;Wolfe et al, 1990) and in comparative physiology (Kalderon et al, 2000;McClelland et al, 2001;Reidy and Weber, 2002;Weber et al, 1993). The equations were derived from the fact that glycerol and fatty acids released by lipolysis do not behave similarly.…”

Section: Calculations and Statisticsmentioning

confidence: 99%

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Extending food deprivation reverses the short-term lipolytic response to fasting: role of the triacylglycerol/fatty acid cycle

Weber

Reidy

2012

Journal of Experimental Biology

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SUMMARY The effects of short-term food deprivation on lipid metabolism are well documented, but little is known about prolonged fasting. This study monitored the kinetics of glycerol (rate of appearance, Ra glycerol) and non-esterified fatty acids (Ra NEFA) in fasting rabbits. Our goals were to determine whether lipolysis is stimulated beyond values seen for short-term fasting, and to characterize the roles of primary (intracellular) and secondary (with transit through the circulation) triacylglycerol/fatty acid cycling (TAG/FA cycling) in regulating fatty acid allocation to oxidation or re-esterification. Ra glycerol (9.62±0.72 to 15.29±0.96 μmol kg–1 min–1) and Ra NEFA (18.05±2.55 to 31.25±1.93 μmol kg–1 min–1) were stimulated during the first 2 days of fasting, but returned to baseline after 4 days. An initial increase in TAG/FA cycling was followed by a reduction below baseline after 6 days without food, with primary and secondary cycling contributing to these responses. We conclude that the classic activation of lipolysis caused by short-term fasting is abolished when food deprivation is prolonged. High rates of re-esterification may become impossible to sustain, and TAG/FA cycling could decrease to reduce its cost to 3% of total energy expenditure. Throughout prolonged fasting, fatty acid metabolism gradually shifts towards increased oxidation and reduced re-esterification. Survival is achieved by pressing fuel selection towards the fatty acid dominance of energy metabolism and by slowing substrate cycles to assist metabolic suppression. However, TAG/FA cycling remains active even after prolonged fasting, suggesting that re-esterification is a crucial mechanism that cannot be stopped without harmful consequences.

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Section: Fasting Causes Stimulation Then Inhibition Of Tag/fa Cyclingsupporting

confidence: 48%

Section: Calculations and Statisticsmentioning

confidence: 99%

Extending food deprivation reverses the short-term lipolytic response to fasting: role of the triacylglycerol/fatty acid cycle

Weber

Reidy

2012

Journal of Experimental Biology

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“…In this respect, the effects of several typical treatments such as administration of leptin, [57][58][59][60][61] bezafibrate, 62,63 adrenoreceptor agonists, 48,[64][65][66][67][68] dietary n-3 polyunsaturated FA [69][70][71] or fasting 66,[72][73][74] can be compared with a phenotype of the aP2-Ucp1 transgenic mice. 20,21,26 In all of these situations, fat accumulation is reduced and disturbances related to the metabolic syndrome are improved.…”

Section: Physiological Relevance Of Energy Metabolism and Ampk In Whimentioning

confidence: 99%

Role of energy charge and AMP-activated protein kinase in adipocytes in the control of body fat stores

et al. 2004

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As indicated by in vitro studies, both lipogenesis and lipolysis in adipocytes depend on the cellular ATP levels. Ectopic expression of mitochondrial uncoupling protein 1 (UCP1) in the white adipose tissue of the aP2-Ucp1 transgenic mice reduced obesity induced by genetic or dietary manipulations. Furthermore, respiratory uncoupling lowered the cellular energy charge in adipocytes, while the synthesis of fatty acids (FA) was inhibited and their oxidation increased. Importantly, the complex metabolic changes triggered by ectopic UCP1 were associated with the activation of AMP-activated protein kinase (AMPK), a metabolic master switch, in adipocytes. Effects of several typical treatments that reduce adiposity, such as administration of leptin, b-adrenoceptor agonists, bezafibrate, dietary n-3 polyunsaturated FA or fasting, can be compared with a phenotype of the aP2-Ucp1 mice. These situations generally lead to the upregulation of mitochondrial UCPs and suppression of the cellular energy charge and FA synthesis in adipocytes. On the other hand, FA oxidation is increased. Moreover, it has been shown that AMPK in adipocytes can be activated by adipocyte-derived hormones leptin and adiponectin, and also by insulin-sensitizes thiazolidinediones. Thus, it is evident that metabolism of adipose tissue itself is important for the control of body fat content and that the cellular energy charge and AMPK are involved in the control of lipid metabolism in adipocytes. The reciprocal link between synthesis and oxidation of FA in adipocytes represents a prospective target for the new treatment strategies aimed at reducing obesity.

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“…mitochondria. Mobilization of fat stores, or lipolysis, has been measured as the rate of appearance of glycerol (R a glycerol) in many species including humans (Beylot et al, 1987), other mammals (Himms-Hagen, 1968;Kalderon et al, 2000;McClelland et al, 2001;Shaw et al, 1975;Weber et al, 1993), rainbow trout (Bernard et al, 1999), and one bird: the king penguin (Bernard et al, 2002a;Bernard et al, 2003). R a glycerol can only be measured by continuous infusion of labelled glycerol, and it is therefore not surprising that avian lipolytic rate is only known for large (>13·kg), easy-going penguins.…”

Section: Introductionmentioning

confidence: 99%

Lipid mobilization of long-distance migrant birdsin vivo: the high lipolytic rate of ruff sandpipers is not stimulated during shivering

Vaillancourt

Weber

2007

Journal of Experimental Biology

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For long migrations, birds must rely on high flux capacities at all steps of lipid metabolism, from the mobilization of adipose reserves to fatty acid oxidation in flight muscle mitochondria. Substrate kinetics and indirect calorimetry were used to investigate key parameters of lipid metabolism in a highly aerobic shorebird: the ruff sandpiper Philomachus pugnax. In this study, we have quantified the effects of cold exposure because such measurements are presently impossible during flight. Lipolytic rate was monitored by continuous infusion of 2-[3H]-glycerol and lipid oxidation by respirometry. Plasma lipid concentrations (non-esterified fatty acids, neutral lipids and phospholipids) and their fatty acid composition were also measured to assess whether cold exposure causes selective metabolism of specific lipids. Results show that shivering leads to a 47% increase in metabolic rate (44.4±3.8 ml O2kg–1min–1 to 65.2±8.1 ml O2kg–1 min–1), almost solely by stimulating lipid oxidation (33.3± 3.3 ml O2 kg–1min–1 to 48.2±6.8 ml O2kg–1 min–1) because carbohydrate oxidation remains close to 11.5± 0.5 ml O2 kg–1min–1. Sandpipers support an unusually high lipolytic rate of 55–60 μmol glycerol kg–1 min–1. Its stimulation above thermoneutral rates is unnecessary during shivering when the birds are still able to re-esterify 50% of released fatty acids. No changes in plasma lipid composition were observed, suggesting that cold exposure does not lead to selective metabolism of particular fatty acids. This study provides the first measurements of lipolytic rate in migrant birds and shows that their capacity for lipid mobilization reaches the highest values measured to date in vertebrates. Extending the limits of conventional lipid metabolism has clearly been necessary to achieve long-distance migrations.

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Fatty acid cycling in the fasting rat

Cited by 56 publications

References 41 publications

Extending food deprivation reverses the short-term lipolytic response to fasting: role of the triacylglycerol/fatty acid cycle

Extending food deprivation reverses the short-term lipolytic response to fasting: role of the triacylglycerol/fatty acid cycle

Role of energy charge and AMP-activated protein kinase in adipocytes in the control of body fat stores

Lipid mobilization of long-distance migrant birdsin vivo: the high lipolytic rate of ruff sandpipers is not stimulated during shivering

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