Literature DB >> 10845091

Functional consequences of altering myocardial adrenergic receptor signaling.

W J Koch1, R J Lefkowitz, H A Rockman.   

Abstract

From the ability to successfully manipulate the mouse genome has come important transgenic and gene-targeted knockout models that impact many areas of biomedical research. Genetically engineered mouse models geared toward the study of cardiovascular regulation have recently been described and provide powerful tools to study normal and compromised cardiac physiology. The genetic manipulation of the adrenergic receptor (AR) signaling system in the heart, including its regulation by desensitizing kinases, has shed light on the role of this signaling pathway in the regulation of cardiac contractility. One major finding, supported by several mouse models, is that in vivo contractility can be enhanced via alteration of myocardial AR signaling. Thus genetic manipulation of this critical receptor system in the heart represents a novel therapeutic approach for improving function of the failing heart.

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Year:  2000        PMID: 10845091     DOI: 10.1146/annurev.physiol.62.1.237

Source DB:  PubMed          Journal:  Annu Rev Physiol        ISSN: 0066-4278            Impact factor:   19.318


  28 in total

Review 1.  Myocardial gene transfer.

Authors:  D C White; W J Koch
Journal:  Curr Cardiol Rep       Date:  2001-01       Impact factor: 2.931

Review 2.  [Antiarrhythmic therapy with β-receptor antagonists].

Authors:  G C Grönefeld; D Bänsch
Journal:  Herzschrittmacherther Elektrophysiol       Date:  2010-11-24

Review 3.  G Protein-coupled Receptor Biased Agonism.

Authors:  Sima Y Hodavance; Clarice Gareri; Rachel D Torok; Howard A Rockman
Journal:  J Cardiovasc Pharmacol       Date:  2016-03       Impact factor: 3.105

4.  Analysis of Rab1 function in cardiomyocyte growth.

Authors:  Catalin M Filipeanu; Fuguo Zhou; Guangyu Wu
Journal:  Methods Enzymol       Date:  2008       Impact factor: 1.600

5.  Beta-arrestin-mediated beta1-adrenergic receptor transactivation of the EGFR confers cardioprotection.

Authors:  Takahisa Noma; Anthony Lemaire; Sathyamangla V Naga Prasad; Liza Barki-Harrington; Douglas G Tilley; Juhsien Chen; Philippe Le Corvoisier; Jonathan D Violin; Huijun Wei; Robert J Lefkowitz; Howard A Rockman
Journal:  J Clin Invest       Date:  2007-09       Impact factor: 14.808

6.  Phosphorylation of Src by phosphoinositide 3-kinase regulates beta-adrenergic receptor-mediated EGFR transactivation.

Authors:  Lewis J Watson; Kevin M Alexander; Maradumane L Mohan; Amber L Bowman; Supachoke Mangmool; Kunhong Xiao; Sathyamangla V Naga Prasad; Howard A Rockman
Journal:  Cell Signal       Date:  2016-05-08       Impact factor: 4.315

7.  Uncoupling of myocardial beta-adrenergic receptor signaling during coronary artery bypass grafting: the role of GRK2.

Authors:  Christian F Bulcao; Prakash K Pandalai; Karen M D'Souza; Walter H Merrill; Shahab A Akhter
Journal:  Ann Thorac Surg       Date:  2008-10       Impact factor: 4.330

Review 8.  Cardiac sodium-calcium exchange and efficient excitation-contraction coupling: implications for heart disease.

Authors:  Joshua I Goldhaber; Kenneth D Philipson
Journal:  Adv Exp Med Biol       Date:  2013       Impact factor: 2.622

9.  The Arf GAP AGAP2 interacts with β-arrestin2 and regulates β2-adrenergic receptor recycling and ERK activation.

Authors:  Yuanjun Wu; Yu Zhao; Xiaojie Ma; Yunjuan Zhu; Jaimin Patel; Zhongzhen Nie
Journal:  Biochem J       Date:  2013-06-15       Impact factor: 3.857

10.  beta-Arrestin-dependent activation of Ca(2+)/calmodulin kinase II after beta(1)-adrenergic receptor stimulation.

Authors:  Supachoke Mangmool; Arun K Shukla; Howard A Rockman
Journal:  J Cell Biol       Date:  2010-04-26       Impact factor: 10.539
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