Literature DB >> 20554934

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

Eric P Plaisance1, Tara M Henagan, Haley Echlin, Anik Boudreau, Kasey L Hill, Natalie R Lenard, Barbara E Hasek, Norman Orentreich, Thomas W Gettys.   

Abstract

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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Year:  2010        PMID: 20554934      PMCID: PMC2944424          DOI: 10.1152/ajpregu.00838.2009

Source DB:  PubMed          Journal:  Am J Physiol Regul Integr Comp Physiol        ISSN: 0363-6119            Impact factor:   3.619


  45 in total

1.  Reduction of dietary obesity in aP2-Ucp transgenic mice: physiology and adipose tissue distribution.

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Journal:  Am J Physiol       Date:  1996-05

2.  Influence of cell type upon the desensitization of the beta 3-adrenergic receptor.

Authors:  A Chaudhry; J G Granneman
Journal:  J Pharmacol Exp Ther       Date:  1994-12       Impact factor: 4.030

3.  Expression of the mitochondrial uncoupling protein gene from the aP2 gene promoter prevents genetic obesity.

Authors:  J Kopecky; G Clarke; S Enerbäck; B Spiegelman; L P Kozak
Journal:  J Clin Invest       Date:  1995-12       Impact factor: 14.808

4.  Genetically lean mice result from targeted disruption of the RII beta subunit of protein kinase A.

Authors:  D E Cummings; E P Brandon; J V Planas; K Motamed; R L Idzerda; G S McKnight
Journal:  Nature       Date:  1996-08-15       Impact factor: 49.962

5.  Transgenic mice overexpressing the beta 1-adrenergic receptor in adipose tissue are resistant to obesity.

Authors:  V Soloveva; R A Graves; M M Rasenick; B M Spiegelman; S R Ross
Journal:  Mol Endocrinol       Date:  1997-01

6.  Age-dependent changes in beta-adrenergic receptor subtypes and adenylyl cyclase activation in adipocytes from Fischer 344 rats.

Authors:  T W Gettys; E M Rohlfs; V Prpic; K W Daniel; I L Taylor; S Collins
Journal:  Endocrinology       Date:  1995-05       Impact factor: 4.736

7.  Impaired expression and functional activity of the beta 3- and beta 1-adrenergic receptors in adipose tissue of congenitally obese (C57BL/6J ob/ob) mice.

Authors:  S Collins; K W Daniel; E M Rohlfs; V Ramkumar; I L Taylor; T W Gettys
Journal:  Mol Endocrinol       Date:  1994-04

8.  Phosphorylation and desensitization of the human beta 1-adrenergic receptor. Involvement of G protein-coupled receptor kinases and cAMP-dependent protein kinase.

Authors:  N J Freedman; S B Liggett; D E Drachman; G Pei; M G Caron; R J Lefkowitz
Journal:  J Biol Chem       Date:  1995-07-28       Impact factor: 5.157

9.  Targeted disruption of the beta 3-adrenergic receptor gene.

Authors:  V S Susulic; R C Frederich; J Lawitts; E Tozzo; B B Kahn; M E Harper; J Himms-Hagen; J S Flier; B B Lowell
Journal:  J Biol Chem       Date:  1995-12-08       Impact factor: 5.157

10.  Methionine restriction increases blood glutathione and longevity in F344 rats.

Authors:  J P Richie; Y Leutzinger; S Parthasarathy; V Malloy; N Orentreich; J A Zimmerman
Journal:  FASEB J       Date:  1994-12       Impact factor: 5.191
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  44 in total

1.  Cellular and molecular remodeling of inguinal adipose tissue mitochondria by dietary methionine restriction.

Authors:  Yuvraj N Patil; Kelly N Dille; David H Burk; Cory C Cortez; Thomas W Gettys
Journal:  J Nutr Biochem       Date:  2015-07-22       Impact factor: 6.048

2.  Short-term methionine deprivation improves metabolic health via sexually dimorphic, mTORC1-independent mechanisms.

Authors:  Deyang Yu; Shany E Yang; Blake R Miller; Jaclyn A Wisinski; Dawn S Sherman; Jacqueline A Brinkman; Jay L Tomasiewicz; Nicole E Cummings; Michelle E Kimple; Vincent L Cryns; Dudley W Lamming
Journal:  FASEB J       Date:  2018-01-30       Impact factor: 5.191

3.  Dietary protein source influence on body size and composition in growing zebrafish.

Authors:  Daniel L Smith; R Jeff Barry; Mickie L Powell; Tim R Nagy; L R D'Abramo; Stephen A Watts
Journal:  Zebrafish       Date:  2013-05-08       Impact factor: 1.985

Review 4.  Sensing and signaling mechanisms linking dietary methionine restriction to the behavioral and physiological components of the response.

Authors:  Laura A Forney; Kirsten P Stone; Desiree Wanders; Thomas W Gettys
Journal:  Front Neuroendocrinol       Date:  2017-12-21       Impact factor: 8.606

5.  FGF21 Mediates the Thermogenic and Insulin-Sensitizing Effects of Dietary Methionine Restriction but Not Its Effects on Hepatic Lipid Metabolism.

Authors:  Desiree Wanders; Laura A Forney; Kirsten P Stone; David H Burk; Alicia Pierse; Thomas W Gettys
Journal:  Diabetes       Date:  2017-01-17       Impact factor: 9.461

6.  Sexually Dimorphic Effects of Dietary Methionine Restriction are Dependent on Age when the Diet is Introduced.

Authors:  Laura A Forney; Kirsten P Stone; Amanda N Gibson; Alicia M Vick; Landon C Sims; Han Fang; Thomas W Gettys
Journal:  Obesity (Silver Spring)       Date:  2020-02-03       Impact factor: 5.002

7.  Dietary methionine restriction increases fat oxidation in obese adults with metabolic syndrome.

Authors:  Eric P Plaisance; Frank L Greenway; Anik Boudreau; Kasey L Hill; William D Johnson; Rozlyn A Krajcik; Carmen E Perrone; Norman Orentreich; William T Cefalu; Thomas W Gettys
Journal:  J Clin Endocrinol Metab       Date:  2011-02-23       Impact factor: 5.958

8.  UCP1 is an essential mediator of the effects of methionine restriction on energy balance but not insulin sensitivity.

Authors:  Desiree Wanders; David H Burk; Cory C Cortez; Nancy T Van; Kirsten P Stone; Mollye Baker; Tamra Mendoza; Randall L Mynatt; Thomas W Gettys
Journal:  FASEB J       Date:  2015-03-05       Impact factor: 5.191

Review 9.  Cutting back on the essentials: Can manipulating intake of specific amino acids modulate health and lifespan?

Authors:  Holly M Brown-Borg; Rochelle Buffenstein
Journal:  Ageing Res Rev       Date:  2016-08-26       Impact factor: 10.895

10.  Dietary Methionine Restriction Signals to the Brain Through Fibroblast Growth Factor 21 to Regulate Energy Balance and Remodeling of Adipose Tissue.

Authors:  Laura A Forney; Han Fang; Landon C Sims; Kirsten P Stone; Leighann Y Vincik; Alicia M Vick; Amanda N Gibson; David H Burk; Thomas W Gettys
Journal:  Obesity (Silver Spring)       Date:  2020-10       Impact factor: 5.002
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