Abstract
The pulmonary arteries are exquisitely responsive to oxygen changes. They rapidly and proportionally contract as arterial PO2 decrease, and they relax as arterial PO2 is re-established. The hypoxic pulmonary vasoconstriction (HPV) is intrinsic since it does not require neural or endocrine factors, as evidenced in isolated vessels. On the other hand, pulmonary arteries also respond to sustained hypoxia with structural and functional remodeling, involving growth of smooth muscle medial layer and later recruitment of adventitial fibroblasts, secreted mitogens from endothelium and changes in the response to vasoconstrictor and vasodilator stimuli. Hypoxic pulmonary arterial vasoconstriction and remodeling are relevant biological responses both under physiological and pathological conditions, to explain matching between ventilation and perfusion, fetal to neonatal transition of pulmonary circulation and pulmonary artery over-constriction and thickening in pulmonary hypertension. Store operated channels (SOC) and receptor operated channels (ROC) are plasma membrane cationic channels that mediate calcium influx in response to depletion of internal calcium stores or receptor activation, respectively. They are involved in both HPV and pathological remodeling since their pharmacological blockade or genetic suppression of several of the Stim, Orai, TRP, or ASIC proteins in SOC or ROC complexes attenuate the calcium increase, the tension development, the pulmonary artery smooth muscle proliferation, and pulmonary arterial hypertension. In this Mini Review, we discussed the evidence obtained in in vivo animal models, at the level of isolated organ or cells of pulmonary arteries, and we identified and discussed the questions for future research needed to validate these signaling complexes as targets against pulmonary hypertension.
Highlights
The pulmonary arteries have distinctive properties all along the individual’s life, compared to systemic arteries
Store operated channels (SOC)/receptor operated channels (ROC) in Hypoxic Pulmonary Arteries signaling of vasoconstrictors as well as low oxygen tension (PaO2) in the fetal arterial blood, among other factors, which contribute to the pulmonary high resistance, low flow state
A unique feature of the pulmonary arteries is their intrinsic sensitivity to hypoxia, possessing a vasoconstrictor response to acute hypoxia called “hypoxic pulmonary vasoconstriction” (HPV), which is already present in fetal pulmonary arteries and continues to exist in every life stages
Summary
The pulmonary arteries have distinctive properties all along the individual’s life, compared to systemic arteries. SOCE is evaluated as the rate of fluorescence quenching by Mn2+ which enters the cell after store depletion as Ca2+ surrogate and reduces fluorescence through binding the dye (Bird et al, 2008) Concerning their structure, early studies suggested that SOC were formed by pore-forming subunits of the canonical transient receptor potential (TRPC) proteins. The recruitment of both currents results in a sustained Ca2+ elevation termed the store operated calcium current (Isoc) (Ambudkar et al, 2017; Putney, 2017) This model is consistent with the ability of different sub-types of Stim, TRPC, and Orai proteins to generate SOCE in pulmonary arteries (Fernandez et al, 2012; Earley and Brayden, 2015; Wang et al., 2017). Despite this obvious link between [Ca2+]i and contraction, the relation between pMLC20/MLC20 ratio and SOC has been demonstrated only for TABLE 1 | Current inhibitors of store operated channels and receptor operated channels
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