Abstract
BackgroundVoltage-gated potassium (Kv) channels, especially Kv7 channels, are major potassium channels identified in vascular smooth muscle cells with a great, albeit differential functional impact in various vessels. Vascular smooth muscle Kv7 channels always coexist with other K channels, in particular with BK channels. BK channels differ in the extent to which they influence vascular contractility. Whether this difference also causes the variability in the functional impact of Kv7 channels is unknown. Therefore, this study addressed the hypothesis that the functional impact of Kv7 channels depends on BK channels.Experimental ApproachExperiments were performed on young and adult rat gracilis and saphenous arteries using real-time PCR as well as pressure and wire myography.Key ResultsSeveral subfamily members of Kv7 (KCNQ) and BK channels were expressed in saphenous and gracilis arteries: the highest expression was observed for BKα, BKβ1 and KCNQ4. Arterial contractility was assessed with methoxamine-induced contractions and pressure-induced myogenic responses. In vessels of adult rats, inhibition of Kv7 channels or BK channels by XE991 or IBTX, respectively enhanced arterial contractility to a similar degree, whereas activation of Kv7 channels or BK channels by retigabine or NS19504, respectively reduced arterial contractility to a similar degree. Further, IBTX increased both the contractile effect of XE991 and the anticontractile effect of retigabine, whereas NS19504 reduced the effect of retigabine and impaired the effect of XE991. In vessels of young rats, inhibition of Kv7 channels by XE991 enhanced arterial contractility much stronger than inhibition of BK channels by IBTX, whereas activation of Kv7 by retigabine reduced arterial contractility to a greater extent than activation of BK channels by NS19504. Further, IBTX increased the anticontractile effect of retigabine but not the contractile effect of XE991, whereas NS19504 reduced the effect of retigabine and impaired the effect of XE991.ConclusionKv7 and BK channels are expressed in young and adult rat arteries and function as negative feedback modulators in the regulation of contractility of these arteries. Importantly, BK channels govern the extent of functional impact of Kv7 channels. This effect depends on the relationship between the functional activities of BK and Kv7 channels.
Highlights
In vascular smooth muscle cells (VSMCs), potassium channels evoke membrane hyperpolarization, reduce the entry of extracellular Ca2+ through voltage-dependent Ca2+ channels (VDCCs) and decrease their contractility (Nelson and Quayle, 1995; Coetzee et al, 1999; Jackson, 2000; Thorneloe and Nelson, 2005; Tykocki et al, 2017)
The expression profiles of the subunits of KCNQ and BK channel genes in saphenous arteries were similar to those in gracilis arteries: the highest expression was observed for BKα, BKβ1 and KCNQ4, followed by KCNQ1, KCNQ3 and KCNQ5 at considerably lower expression levels
No differences in KCNQ and BK channel genes were detected between vessel without and with endothelium, except for KCNQ4, which was expressed at a slightly lower level in vessels with endothelium (Figures 1A,B)
Summary
In vascular smooth muscle cells (VSMCs), potassium channels evoke membrane hyperpolarization, reduce the entry of extracellular Ca2+ through voltage-dependent Ca2+ channels (VDCCs) and decrease their contractility (Nelson and Quayle, 1995; Coetzee et al, 1999; Jackson, 2000; Thorneloe and Nelson, 2005; Tykocki et al, 2017). VSMC contractility plays an essential role in the determination of vascular tone. The latter contributes considerably to the setting of blood pressure and the regulation of blood flow distribution to different organs and tissues. Kv7 channels (Kv7.1–7.5), a subfamily of Kv channels (Kv1– 12) (Wulff et al, 2009) are encoded by KCNQ (KCNQ1–5) genes These channels play an important role in vasodilation and contribute to the negative feedback control of vasoconstriction. Voltage-gated potassium (Kv) channels, especially Kv7 channels, are major potassium channels identified in vascular smooth muscle cells with a great, albeit differential functional impact in various vessels. BK channels differ in the extent to which they influence vascular contractility Whether this difference causes the variability in the functional impact of Kv7 channels is unknown. Experimental Approach: Experiments were performed on young and adult rat gracilis and saphenous arteries using real-time PCR as well as pressure and wire myography
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