Blockade Of The Thromboxane/Prostanoid Receptor Prevents Ecg Abnormalities In Rv Pressure Overload

The increased afterload of pulmonary arterial hypertension (PAH) impairs right ventricular function and ultimately leads to failure, as the RV struggles to adapt to increased pressure with remodeling and fibrosis. During PAH, cardiomyocytes upregulate cell-surface expression of the G protein-coupled thromboxane/prostanoid receptor (TPr). Increased myofibroblast and immune cell populations may also contribute to the enhanced TPr expression seen in the PAH RV. Activation of the cardiomyocyte TPr increases intracellular calcium via G αq /IP 3 ; activation of the receptor in other cells leads to fibrosis and vasoconstriction. Preventing signaling through the TPr prevents RV fibrosis in murine models of PAH without affecting arterial pressure. Because infusion of TPr agonist can cause arrhythmia in anesthetized rabbits, and we have previously found that RV pressure overload causes sustained increases in end-diastolic calcium in RV cardiomyocytes that is blocked with TPr antagonist, we hypothesized that endogenous TPr activation can lead to conduction abnormalities in RV pressure overload. Here, we used pulmonary arterial banding (PAB) of female mice to induce fixed pressure overload of the RV. Sham-operated or PAB mice were treated with normal drinking water or water containing 25 mg/kg/day of the TPr antagonist ifetroban and were evaluated at 4 weeks past PAB. RV ejection fraction was similarly depressed in vehicle- and antagonist-treated mice, although spontaneous running, RV fibrosis, and RV relaxation time were improved in PAB mice given ifetroban. ECG abnormalities in PAB mice confirmed a prolonged relaxation and suggested delays in repolarization. These were abolished with TPr antagonism. PAB altered RV expression and localization of connexin-43 (Cx43) in vehicle-treated, but not ifetroban-treated mice. Cx43 derangement is associated with impaired cell-to-cell electrical conduction and impulse propagation. Compiled, our findings suggest that endogenous TPr activation produces alterations in RV calcium handling, signaling, and cell-cell junctions that contribute to early failure in pressure overload. Therapeutic TPr antagonism may prevent this deleterious remodeling and prolong survival in patients with PAH.