Hypoxic vasodilatory defect and pulmonary hypertension in mice lacking hemoglobin β-cysteine93 S-nitrosylation
Rongli Zhang, Alfred Hausladen, Zhaoxia Qian, Xudong Liao, Richard T. Premont, Jonathan S. Stamler
Rongli Zhang, Alfred Hausladen, Zhaoxia Qian, Xudong Liao, Richard T. Premont, Jonathan S. Stamler
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Research Article Cardiology Vascular biology

Hypoxic vasodilatory defect and pulmonary hypertension in mice lacking hemoglobin β-cysteine93 S-nitrosylation

Abstract

Systemic hypoxia is characterized by peripheral vasodilation and pulmonary vasoconstriction. However, the system-wide mechanism for signaling hypoxia remains unknown. Accumulating evidence suggests that hemoglobin (Hb) in RBCs may serve as an O2 sensor and O2-responsive NO signal transducer to regulate systemic and pulmonary vascular tone, but this remains unexamined at the integrated system level. One residue invariant in mammalian Hbs, β-globin cysteine93 (βCys93), carries NO as vasorelaxant S-nitrosothiol (SNO) to autoregulate blood flow during O2 delivery. βCys93Ala mutant mice thus exhibit systemic hypoxia despite transporting O2 normally. Here, we show that βCys93Ala mutant mice had reduced S-nitrosohemoglobin (SNO-Hb) at baseline and upon targeted SNO repletion and that hypoxic vasodilation by RBCs was impaired in vitro and in vivo, recapitulating hypoxic pathophysiology. Notably, βCys93Ala mutant mice showed marked impairment of hypoxic peripheral vasodilation and developed signs of pulmonary hypertension with age. Mutant mice also died prematurely with cor pulmonale (pulmonary hypertension with right ventricular dysfunction) when living under low O2. Altogether, we identify a major role for RBC SNO in clinically relevant vasodilatory responses attributed previously to endothelial NO. We conclude that SNO-Hb transduces the integrated, system-wide response to hypoxia in the mammalian respiratory cycle, expanding a core physiological principle.

Authors

Rongli Zhang, Alfred Hausladen, Zhaoxia Qian, Xudong Liao, Richard T. Premont, Jonathan S. Stamler

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Figure 2

Right ventricular and pulmonary artery signs of pulmonary arterial hypertension in C93A mice with age.

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Right ventricular and pulmonary artery signs of pulmonary arterial hyper...
(A) Total heart weight (HW) to body weight (BW) ratio in young and in aged C93A versus C93 mice. (B) Right ventricle (RV) to BW ratio in young and in aged C93A versus C93 mice. (C) Left ventricle (LV) to BW ratio in young and in aged C93A versus C93 mice. (D) RV to LV + septum weight (LV+S) ratio in young and in aged C93A versus C93 mice. (E) Pulmonary artery (PA) blood flow velocity-time integral (VTI) in young and in aged C93A versus C93 mice. (F) PA diameter in young and in aged C93A versus C93 mice. (G) Mean velocity of PA blood flow in young and in aged C93A versus C93 mice. (H) Peak velocity of PA blood flow in young and in aged C93A versus C93 mice. For panels AD, young mice (n = 31 C93, 3.4 ± 0.6 months of age, and n = 36 C93A, 3.4 ± 0.4 months of age) and aged mice (n = 28 C93, 19.5 ± 1.8 months of age, and n = 21 C93A, 19.7 ± 3.1 months of age) were assessed. For panels EH, young mice (n = 16 C93, 3.8 ± 1.3 months of age, and n = 19 C93A, 3.0 ± 0.8 months of age) and aged mice (n = 15 C93, 20.9 ± 1.6 months of age, and n = 23 C93A, 21.8 ± 1.2 months of age) were assessed. Differences were assessed using Student’s t test (2 tailed). *P < 0.05, **P < 0.01 C93A vs. C93, for young or aged animals compared separately.