High-Energy Phosphate Metabolism and Creatine Kinase in Failing Hearts : A New Porcine Model

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Circulation. 2001;103:1570-1576

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	Heart failure - basic studies

(Circulation. 2001;103:1570.)
© 2001 American Heart Association, Inc.

Basic Science Reports

High-Energy Phosphate Metabolism and Creatine Kinase in Failing Hearts

A New Porcine Model

Yun Ye, MD, MS; Guangrong Gong, MD, MS; Koichi Ochiai, MD, PhD; Jingbo Liu, MD, PhD; Jianyi Zhang, MD, PhD

From the Cardiovascular Division, Department of Medicine, University of Minnesota Medical School, Minneapolis.

Correspondence to Jianyi Zhang, MD, PhD, Cardiovascular Division, Department of Medicine, University of Minnesota Medical School, Mayo Mail Code 508, UMHC, Minneapolis, MN 55455. E-mail zhang047{at}tc.umn.edu

Background—This study aimed to create a pig model of heartfailure secondary to severe aortic stenosis and to examine therelationship between the alterations in myocardial high-energyphosphate (HEP) metabolism and protein expression of creatinekinase (CK) isoforms.

Methods and Results—Sixteen pigs with left ventricularhypertrophy (LVH) secondary to ascending aortic banding and10 normal pigs (N) were studied. Myocardial protein levels ofCK isoforms (Western blot), HEP levels, and CK kinetics (³¹PMR spectroscopy) were measured under basal conditions. Nineof the 16 animals with LVH developed congestive heart failure(CHF), as evidenced by ascites (100 to 2000 mL). LV weight/bodyweight ratio (g/kg) was 2.18±0.15 in N hearts, 3.04±0.14in hearts with LVH (P<0.01), and 4.23±0.36 in heartswith CHF (P<0.01 versus LVH). Right ventricle weight/bodyweight ratio and LV end-diastolic pressure were significantlyhigher in hearts with CHF (each P<0.01 versus N or LVH).Myocardial phosphocreatine/ATP ratios and the CK forward flux rateswere decreased in LVH hearts, most severely in hearts with CHF. CK-M/ß-actinratios were 2.21±12 (N), 1.69±0.15 (LVH), and 1.39±0.27(CHF, P<0.05 versus N). CK-mitochondria (CK-Mt)/ß-actinratios were 1.40±0.09 (N), 1.24±0.09 (LVH), and1.02±0.08 (CHF, P<0.05 versus N or LVH). The severityof the reduction of CK flux rate was linearly related to the severityof the decrease of CK-Mt/ß-actin (r=0.68, P<0.01).

Conclusions—In this new model of heart failure/hypertrophy,the abnormal myocardial HEP metabolism is related to the decreasedCK-Mt protein level, which in turn is related to the severityof the hypertrophy.

Key Words: heart failure • hypertrophy • creatine kinase • phosphates • spectroscopy

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