Functional and metabolic remodelling in GLUT4-deficient hearts confers hyper-responsiveness to substrate intervention

Huggins, CE; Domenighetti, AA; Ritchie, ME; Khalil, N; Favaloro, JM; Proletto, J; Smyth, GK; Pepe, S; Delbridge, LMD

Author(s): Huggins, CE; Domenighetti, AA; Ritchie, ME; Khalil, N; Favaloro, JM; Proletto, J; Smyth, GK; Pepe, S; Delbridge, LMD;
Details: Publication Year 2008-02,Volume 44,Issue #2,Page 270-280
Journal Title: JOURNAL OF MOLECULAR AND CELLULAR CARDIOLOGY
Publication Type: Journal Article
Abstract: Impaired glucose uptake is associated with both cardiac hypertrophy and contractile dysfunction, but whether there are common underlying mechanisms linking these conditions is yet to be determined. Using a 'gene dose' Cre-Lox GLUT4-deficient murine model, we examined the effect of suppressed glucose availability on global myocardial gene expression and glycolysis substrate bypass on the function of isolated perfused hearts. Performance of hearts from 22- to 60-week-old male GLUT4 knockout (KO, >95% reduction in GLUT4), GLUT4 knockdown (KD, 85% reduction in cardiac GLUT4) and C57BI/6 wild-type (WT) controls was measured ex vivo in Langendorff mode perfusion. DNA microarray was used to profile mRNA expression differences between GLUT4-KO and GLUT4-KD hearts. At 22 weeks, GLUT4-KO hearts exhibited cardiac hypertrophy and impaired contractile function ex vivo, characterized by a 40% decrease in developed pressure. At 60 weeks, dysfunction was accentuated in GLUT4-KO hearts and evident in GLUT4-KD hearts. Exogenous pyruvate (5 mM) restored systolic pressure to a level equivalent to WT (GLUT4-KO, 176.8 +/- 13.2 mmHg vs. WT, 146.4 +/- 9.56 mmHg) in 22-week-old GLUT4-KO hearts but not in 60-week-old GLUT4-KO hearts. In GLUT4-KO, DNA microarray analysis detected downregulation of a number of genes centrally involved in mitochondrial oxidation and upregulation of other genes indicative of a shift to cytosolic beta-oxidation of long chain fatty acids. A direct link between cardiomyocyte GLUT4 deficiency, hypertrophy and contractile dysfunction is demonstrated. These data provide mechanistic insight into the myocardial metabolic adaptations associated with short and long-term insulin resistance and indicate a window of opportunity for substrate intervention and functional 'rescue'. (c) 2007 Elsevier Inc. All rights reserved.
Publisher: ACADEMIC PRESS LTD ELSEVIER SCIENCE LTD
Keywords: RETICULUM CA2+ RELEASE; CARDIAC-HYPERTROPHY; INSULIN-RESISTANCE; ENERGY-METABOLISM; PRESSURE-OVERLOAD; MICROARRAY DATA; PYRUVATE; FAILURE; GLUCOSE; GLUT4
Publisher's Version: https://doi.org/10.1016/j.yjmcc.2007.11.020
Terms of Use/Rights Notice: Refer to copyright notice on published article.

Creation Date: 2008-02-01 12:00:00