BACKGROUND: Achieving successful myocardial preservation of hypertrophied hearts remains a difficult problem. Despite reportedly higher glycolytic potential, we have achieved limited benefit in hypertrophied hearts with strategies that successfully promote anaerobic glycolysis and long-term ischemic preservation in nonhypertrophied models. We therefore tested the hypotheses that (l) glucose transport into myocytes is a critical limiting factor in hypertrophied heart and (2) stimulation of glucose transport with vanadyl sulfate would improve postischemic recovery. METHODS AND RESULTS: Left ventricular hypertrophy in rabbits was created by aortic banding of 7- to 10-day-old rabbits. At 4 weeks of age, 1 group of animals received oral vanadyl sulfate for 3 to 4 weeks. Glucose transport (measured by the conversion of 2-deoxyglucose to 2-deoxyglucose-6-phosphate; 31P-nuclear magnetic resonance), myocardial glucose transporter content (GLUT-1 and GLUT-4 by immunoblotting), and functional recovery from ischemia-reperfusion (isolated perfused Langendorff model) were measured. Myocardial glucose transport rate was significantly reduced in hypertrophied hearts without significant reductions in glucose transporter content; these hearts were significantly less tolerant of ischemia-reperfusion than age-matched controls. Vanadyl sulfate normalized glucose transport rate and improved tolerance to ischemia-reperfusion so that postischemic function equaled that seen in controls. Lactate production during ischemia, an indication of anaerobic glycolysis, was significantly higher in hearts from vanadate-treated animals. CONCLUSIONS: Despite reportedly higher glycolytic enzyme activities, maximal glucose transport appears to be reduced and is rate limiting in hypertrophied heart. Stimulation of membrane glucose transport with vanadyl sulfate significantly improved glycolytic flux and ischemic preservation in hypertrophied hearts.
BACKGROUND: Achieving successful myocardial preservation of hypertrophied hearts remains a difficult problem. Despite reportedly higher glycolytic potential, we have achieved limited benefit in hypertrophied hearts with strategies that successfully promote anaerobic glycolysis and long-term ischemic preservation in nonhypertrophied models. We therefore tested the hypotheses that (l) glucose transport into myocytes is a critical limiting factor in hypertrophied heart and (2) stimulation of glucose transport with vanadyl sulfate would improve postischemic recovery. METHODS AND RESULTS:Left ventricular hypertrophy in rabbits was created by aortic banding of 7- to 10-day-old rabbits. At 4 weeks of age, 1 group of animals received oral vanadyl sulfate for 3 to 4 weeks. Glucose transport (measured by the conversion of 2-deoxyglucose to 2-deoxyglucose-6-phosphate; 31P-nuclear magnetic resonance), myocardial glucose transporter content (GLUT-1 and GLUT-4 by immunoblotting), and functional recovery from ischemia-reperfusion (isolated perfused Langendorff model) were measured. Myocardial glucose transport rate was significantly reduced in hypertrophied hearts without significant reductions in glucose transporter content; these hearts were significantly less tolerant of ischemia-reperfusion than age-matched controls. Vanadyl sulfate normalized glucose transport rate and improved tolerance to ischemia-reperfusion so that postischemic function equaled that seen in controls. Lactate production during ischemia, an indication of anaerobic glycolysis, was significantly higher in hearts from vanadate-treated animals. CONCLUSIONS: Despite reportedly higher glycolytic enzyme activities, maximal glucose transport appears to be reduced and is rate limiting in hypertrophied heart. Stimulation of membrane glucose transport with vanadyl sulfate significantly improved glycolytic flux and ischemic preservation in hypertrophied hearts.
Authors: Kazuo Kitahori; Huamei He; Mitsuhiro Kawata; Douglas B Cowan; Ingeborg Friehs; Pedro J Del Nido; Francis X McGowan Journal: Circ Heart Fail Date: 2009-09-24 Impact factor: 8.790
Authors: Carlos Zaragoza; Carmen Gomez-Guerrero; Jose Luis Martin-Ventura; Luis Blanco-Colio; Begoña Lavin; Beñat Mallavia; Carlos Tarin; Sebastian Mas; Alberto Ortiz; Jesus Egido Journal: J Biomed Biotechnol Date: 2011-02-16
Authors: Yeong-Hoon Choi; Douglas B Cowan; Meena Nathan; Dimitrios Poutias; Christof Stamm; Pedro J del Nido; Francis X McGowan Journal: PLoS One Date: 2008-12-29 Impact factor: 3.240