Barbara E. Hasek scite author profile

(DR) in the sense that MR increases rodent longevity, but without food restriction. We report here that MR also persistently increases total energy expenditure (EE) and limits fat deposition despite increasing weightspecific food consumption. In Fischer 344 (F344) rats consuming control or MR diets for 3, 9, and 20 mo, mean EE was 1.5-fold higher in MR vs. control rats, primarily due to higher EE during the night at all ages. The day-to-night transition produced a twofold higher heat increment of feeding (3.0°C vs. 1.5°C) in MR vs. controls and an exaggerated increase in respiratory quotient (RQ) to values greater than 1, indicative of the interconversion of glucose to lipid by de novo lipogenesis. The simultaneous inhibition of glucose utilization and shift to fat oxidation during the day was also more complete in MR (RQ ϳ0.75) vs. controls (RQ ϳ0.85). Dietary MR produced a rapid and persistent increase in uncoupling protein 1 expression in brown (BAT) and white adipose tissue (WAT) in conjunction with decreased leptin and increased adiponectin levels in serum, suggesting that remodeling of the metabolic and endocrine function of adipose tissue may have an important role in the overall increase in EE. We conclude that the hyperphagic response to dietary MR is matched to a coordinated increase in uncoupled respiration, suggesting the engagement of a nutrient-sensing mechanism, which compensates for limited methionine through integrated effects on energy homeostasis. energy expenditure; metabolic efficiency; oxidative metabolism; futile cycles; adipose tissue; dietary restriction DIETARY METHIONINE RESTRICTION (MR) extends lifespan by 30 -35% in rats (28, 31) and mice (27) by delaying all causes of death. The increase in lifespan is accompanied by a reduction in adiposity that occurs despite a paradoxical increase in weight-specific food consumption (25,28,46). Pair-feeding studies comparing rats fed the control diet to the amount of MR diet consumed by the MR group clearly show that dietary MR decreases metabolic efficiency (25, 46), but the underlying basis for the metabolic responses to dietary MR remains poorly understood. Short-(12 wk) and long-term (80 wk) consumption of the MR diet after weaning also reduced circulating triglyceride, insulin, and leptin while increasing plasma adiponectin (25, 29). Collectively, work to date makes a compelling case that limitation of fat deposition by dietary MR is associated with preservation of insulin sensitivity and significant improvements in metabolic markers of lipid metabolism. Using the tools of metabolic phenotyping to examine energy homeostasis and peripheral substrate utilization, we found that dietary MR produced a significant long-term increase in EE that was temporally linked to exaggerated thermogenic responses to feeding and modest increases in resting EE. These physiological responses to MR limited fat deposition and were associated with significant changes in the metabolic and endocrine function of brown and white adipose tissue. MR effectively increas...

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Remodeling the Integration of Lipid Metabolism Between Liver and Adipose Tissue by Dietary Methionine Restriction in Rats

Hasek

et al. 2013

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Dietary methionine restriction (MR) produces an integrated series of biochemical and physiological responses that improve biomarkers of metabolic health, limit fat accretion, and enhance insulin sensitivity. Using transcriptional profiling to guide tissue-specific evaluations of molecular responses to MR, we report that liver and adipose tissue are the primary targets of a transcriptional program that remodeled lipid metabolism in each tissue. The MR diet produced a coordinated downregulation of lipogenic genes in the liver, resulting in a corresponding reduction in the capacity of the liver to synthesize and export lipid. In contrast, the transcriptional response in white adipose tissue (WAT) involved a depot-specific induction of lipogenic and oxidative genes and a commensurate increase in capacity to synthesize and oxidize fatty acids. These responses were accompanied by a significant change in adipocyte morphology, with the MR diet reducing cell size and increasing mitochondrial density across all depots. The coordinated transcriptional remodeling of lipid metabolism between liver and WAT by dietary MR produced an overall reduction in circulating and tissue lipids and provides a potential mechanism for the increase in metabolic flexibility and enhanced insulin sensitivity produced by the diet.

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Role of β-adrenergic receptors in the hyperphagic and hypermetabolic responses to dietary methionine restriction

Plaisance

Henagan

Echlin

et al. 2010

American Journal of Physiology-Regulatory, Integrative and Comp

147

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Dietary methionine restriction (MR) limits fat deposition and decreases plasma leptin, while increasing food consumption, total energy expenditure (EE), plasma adiponectin, and expression of uncoupling protein 1 (UCP1) in brown and white adipose tissue (BAT and WAT). beta-adrenergic receptors (beta-AR) serve as conduits for sympathetic input to adipose tissue, but their role in mediating the effects of MR on energy homeostasis is unclear. Energy intake, weight, and adiposity were modestly higher in beta(3)-AR(-/-) mice on the Control diet compared with wild-type (WT) mice, but the hyperphagic response to the MR diet and the reduction in fat deposition did not differ between the genotypes. The absence of beta(3)-ARs also did not diminish the ability of MR to increase total EE and plasma adiponectin or decrease leptin mRNA, but it did block the MR-dependent increase in UCP1 mRNA in BAT but not WAT. In a further study, propranolol was used to antagonize remaining beta-adrenergic input (beta(1)- and beta(2)-ARs) in beta(3)-AR(-/-) mice, and this treatment blocked >50% of the MR-induced increase in total EE and UCP1 induction in both BAT and WAT. We conclude that signaling through beta-adrenergic receptors is a component of the mechanism used by dietary MR to increase EE, and that beta(1)- and beta(2)-ARs are able to substitute for beta(3)-ARs in mediating the effect of dietary MR on EE. These findings are consistent with the involvement of both UCP1-dependent and -independent mechanisms in the physiological responses affecting energy balance that are produced by dietary MR.

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The Components of Age‐Dependent Effects of Dietary Methionine Restriction on Energy Balance in Rats

Wanders

Forney

Stone

et al. 2018

Obesity

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ObjectiveDietary methionine restriction (MR) improves biomarkers of metabolic health, in part through coordinated increases in energy intake and energy expenditure (EE). Some metabolic benefits of dietary MR are secondary to its effects on energy balance so this study’s purpose was to examine how age at initiation of MR influences its effects on energy balance and body composition.MethodsEnergy balance was examined in rats provided Control or MR diets for 9 months after weaning or in rats between 6 and 12 months of age.ResultsRats provided the Control diet for 9 months after weaning increased their body weight (BW) and fat mass by 5- and 8-fold, respectively, while BW and fat accumulation were reduced to 50% of Controls in the MR group. In adult rats fed the respective diets between 6 and 12 months of age, dietary MR increased energy intake by ~23% but the 15% increase in EE was sufficient to prevent increases in BW or fat mass.ConclusionsDietary MR produces comparable increases in EE in young, growing animals and in mature animals, but young animals continue to deposit new tissue because of the proportionately larger effect of MR on energy intake relative to maintenance requirements.

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Barbara E. Hasek

Dietary methionine restriction enhances metabolic flexibility and increases uncoupled respiration in both fed and fasted states

Remodeling the Integration of Lipid Metabolism Between Liver and Adipose Tissue by Dietary Methionine Restriction in Rats

Role of β-adrenergic receptors in the hyperphagic and hypermetabolic responses to dietary methionine restriction

The Components of Age‐Dependent Effects of Dietary Methionine Restriction on Energy Balance in Rats

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