Apelin has complex vasomotor actions inasmuch as the peptide may cause either vasodilation or vasoconstriction depending on the vascular bed and experimental conditions. In cerebral arteries, apelin inhibits endothelium-dependent relaxations mediated by nitric oxide (NO); however, its effects on relaxation to other endothelium-derived substances (e.g. prostacyclin, endotheliumderived hyperpolarizing factors(s) (EDHF)) are unknown. The present study was designed to determine effects of apelin on endothelium-dependent relaxations that are independent of NO in rat cerebral arteries. In arterial rings contracted with 5-HT, A23187 caused endothelium-dependent relaxation that was unaffected by inhibitors of eNOS, guanylyl cyclase or cyclooxygenase, but was attenuated by MS-PPOH, a selective inhibitor of cytochrome P450 catalyzed synthesis of epoxyeicosatrienoic acids (EETs) and by 14,15-EE(Z)E, an EET-receptor antagonist. Apelin inhibited A23187-induced relaxation, as well as relaxations evoked by exogenous 11,12-and 14,15-EET. These effects of apelin were mimicked by the selective BK Ca channel blocker, iberiotoxin. The APJ receptor antagonist, F13A abolished the effects of apelin on A23187-induced relaxations. Both 11,12-and 14,15-EET also increased BK Ca channel current density in isolated cerebral artery smooth muscle cells, effects that were inhibited in a similar manner by apelin and iberiotoxin. These findings provide evidence that apelin impairs endothelium-dependent relaxation of cerebral arteries by inhibiting an NO-independent pathway (i.e. "EDHF-like") involving activation of smooth muscle cell BK Ca channels by endothelium-derived EETs. Inhibition of such pathway may create an environment favoring vasoconstriction in cerebral arteries.
Apelin, an endogenous ligand for APJ receptors, causes nitric oxide (NO)-dependent relaxation of coronary arteries. Little is known about the effects of apelin/APJ receptor signaling in the coronary circulation under pathological conditions. Here, we tested the hypothesis that the vasorelaxing effect of apelin is impaired by cigarette smoke extract (CSE), an established model for second-hand smoke exposure. Isolated rat coronary arteries were treated with 2% CSE for 4 hours. Apelin-induced relaxation of coronary arteries was abolished by CSE exposure, while relaxations to acetylcholine (ACh) (endothelium-dependent relaxation) and to diethyl amine NONOate (NO donor) were similar in control and CSE-treated arteries. Immunoblot analysis demonstrated that apelin increased eNOS ser1177 phosphorylation under control conditions but had no effect after exposure to CSE. Moreover, GRK2 expression was increased in CSE-exposed coronary endothelial cells. Pretreatment with CMPD101, a GRK2 inhibitor, improved the relaxation response to apelin in CSE-exposed coronary arteries. CSE treatment failed to inhibit relaxations evoked by CMF-019, an APJ receptor biased agonist that has little effect on GRK2. In arteries exposed to CSE, apelin impaired the response to ACh but not to diethyl amine NONOate. ACh-induced relaxation was unaffected by CMF-019 in either control or CSE-treated coronary arteries. The results suggest that APJ receptor signaling using the GRK2 pathway contributes to both loss of relaxation to apelin itself and the ability of apelin to inhibit endothelium-dependent relaxation to ACh in CSE-exposed coronary arteries, likely because of impaired production of NO from endothelial cells. These changes in apelin/APJ receptor signaling under pathological conditions (eg, exposure to second-hand smoke) could create an environment that favors increased vasomotor tone in coronary arteries.
Hypertension is a major modifiable risk factor for coronary artery disease. The pathophysiological mechanisms underlying hypertension as a risk factor for coronary artery disease are not fully understood. Apelin is a vasoactive peptide that binds to APJ receptors, which are highly expressed throughout the cardiovascular system, including coronary arteries. APJ receptors signal via G‐protein‐dependent and ‐independent pathways, including activation of G‐protein‐coupled‐receptor kinase 2 (GRK2), which can potentially lead to inhibition of eNOS and nitric oxide (NO) production. We have previously shown that apelin causes endothelium‐dependent, NO‐mediated relaxation of coronary arteries from normotensive animals (JPET 366:265, 2018), but its effects in hypertensive coronary arteries are unknown. Here, we tested the hypothesis that apelin‐induced relaxation is impaired in coronary arteries from spontaneously hypertensive rats (SHR). Western blot analysis demonstrated increased expression of GRK2 in cultured coronary endothelial cells from SHR in comparison with normotensive WKY (control) rats. Isolated coronary arterial rings were mounted in wire myographs for isometric tension recording and contracted with 5‐HT (10‐7 M). Apelin (10‐9‐10‐6 M) caused endothelium‐dependent relaxation of WKY coronary arteries (pD2 = 7.00 ± 0.11; Emax = 54 ± 4% relaxation; n=6), but had no effect in rings from SHR. Conversely, endothelium‐dependent relaxations to an APJ receptor biased agonist, CMF‐019 (10‐9‐10‐5 M), which preferentially activates the G‐protein‐dependent pathway with minimal effect on GRK2, did not differ between SHR and WKY. In the presence of apelin (10‐7 M), endothelium‐dependent relaxation to acetylcholine (ACh) (10‐9‐10‐5 M) was impaired in SHR coronary arteries (pD2 = 6.82 ± 0.10 vs 6.52 ± 0.18, and Emax = 81 ± 8 vs 60 ± 10% relaxation, in the absence and presence of apelin, respectively; n=5; p<0.05); however, apelin had no effect on ACh‐induced relaxation of WKY coronary arteries. By contrast, ACh‐induced relaxation of SHR and WKY coronary arterial rings was unaffected by CMF‐019 (10‐7 M). Moreover, the GRK2 inhibitor, CMPD 101 (3 × 10‐5 M), partially restored the relaxation response to apelin in SHR coronary arteries (pD2 = 6.24 ± 0.30; Emax = 42 ± 13% relaxation; n=3). Relaxations in response to the NO‐donor, DEA NONOate (10‐9‐10‐4 M), were not altered by apelin (10‐7 M) treatment in either WKY or SHR coronary arteries. Taken together, the data indicate that apelin failed to cause relaxation in hypertensive coronary arteries, likely due to impaired production or release of NO from endothelial cells rather than interfering with the action of NO on coronary smooth muscle cells. In SHR coronary arteries, apelin instead actively inhibited relaxation to another endothelium‐dependent vasodilator; i.e. ACh. That the effects of the G‐protein biased agonist, CMF‐019, did not differ between WKY and SHR coronary arteries is consistent with a role for GRK2 activation in the altered response to apelin in hypertensive arteri...
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