Cardiac myocyte‐specific HIF‐1α deletion alters vascularization, energy availability, calcium flux, and contractility in the normoxic heart

Y Huang, RP Hickey, JL Yeh, D Liu, A Dadak… - The FASEB …, 2004 - Wiley Online Library
Y Huang, RP Hickey, JL Yeh, D Liu, A Dadak, LH Young, RS Johnson, FJ Giordano
The FASEB journal, 2004Wiley Online Library
At a resting pulse rate the heart consumes almost twice‐as much oxygen per gram tissue as
the brain and more than 43 times more than resting skeletal muscle (1). Unlike skeletal
muscle, cardiac muscle cannot sustain anaerobic metabolism. Balancing oxygen demand
with availability is crucial to cardiac function and survival, and regulated gene expression is
a critical element of maintaining this balance. We investigated the role of the hypoxia‐
inducible transcription factor HIF‐1α in maintaining this balance under normoxic conditions …
Abstract
At a resting pulse rate the heart consumes almost twice‐as much oxygen per gram tissue as the brain and more than 43 times more than resting skeletal muscle (1). Unlike skeletal muscle, cardiac muscle cannot sustain anaerobic metabolism. Balancing oxygen demand with availability is crucial to cardiac function and survival, and regulated gene expression is a critical element of maintaining this balance. We investigated the role of the hypoxia‐inducible transcription factor HIF‐1α in maintaining this balance under normoxic conditions. Cardiac myocyte‐specific HIF‐ 1α gene deletion in the hearts of genetically engineered mice caused reductions in contractility, vascularization, high‐energy phosphate content, and lactate production. This was accompanied by altered calcium flux and altered expression of genes involved in calcium handling, angiogenesis, and glucose metabolism. These findings support a central role for HIF‐1α in coordinating energy availability and utilization in the heart and have implications for disease states in which cardiac oxygen delivery is impaired.
Heart muscle requires a constant supply of oxygen. When oxygen supply does not match myocardial demand cardiac contractile dysfunction occurs, and prolongation of this mismatch leads to apoptosis and necrosis. Coordination of oxygen supply and myocardial demand involves immediate adaptations, such as coronary vasodilatation, and longer‐term adaptations that include altered patterns of gene expression (2–4). How the expression of multiple genes is coordinated with oxygen availability in the heart and the impact of oxygen‐dependent gene expression on cardiac function are insufficiently understood. Further elucidating these relationships may help clarify the molecular pathology of various cardiovascular disease states, including ischemic cardiomyopathy and myocardial hibernation (5, 6).
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