Disruption of vascular Ca2+-activated chloride currents lowers blood pressure
Christoph Heinze, … , Björn C. Schroeder, Christian A. Hübner
Christoph Heinze, … , Björn C. Schroeder, Christian A. Hübner
Published January 9, 2014
Citation Information: J Clin Invest. 2014;124(2):675-686. https://doi.org/10.1172/JCI70025.
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Research Article Vascular biology

Disruption of vascular Ca2+-activated chloride currents lowers blood pressure

Abstract

High blood pressure is the leading risk factor for death worldwide. One of the hallmarks is a rise of peripheral vascular resistance, which largely depends on arteriole tone. Ca2+-activated chloride currents (CaCCs) in vascular smooth muscle cells (VSMCs) are candidates for increasing vascular contractility. We analyzed the vascular tree and identified substantial CaCCs in VSMCs of the aorta and carotid arteries. CaCCs were small or absent in VSMCs of medium-sized vessels such as mesenteric arteries and larger retinal arterioles. In small vessels of the retina, brain, and skeletal muscle, where contractile intermediate cells or pericytes gradually replace VSMCs, CaCCs were particularly large. Targeted disruption of the calcium-activated chloride channel TMEM16A, also known as ANO1, in VSMCs, intermediate cells, and pericytes eliminated CaCCs in all vessels studied. Mice lacking vascular TMEM16A had lower systemic blood pressure and a decreased hypertensive response following vasoconstrictor treatment. There was no difference in contractility of medium-sized mesenteric arteries; however, responsiveness of the aorta and small retinal arterioles to the vasoconstriction-inducing drug U46619 was reduced. TMEM16A also was required for peripheral blood vessel contractility, as the response to U46619 was attenuated in isolated perfused hind limbs from mutant mice. Out data suggest that TMEM16A plays a general role in arteriolar and capillary blood flow and is a promising target for the treatment of hypertension.

Authors

Christoph Heinze, Anika Seniuk, Maxim V. Sokolov, Antje K. Huebner, Agnieszka E. Klementowicz, István A. Szijártó, Johanna Schleifenbaum, Helga Vitzthum, Maik Gollasch, Heimo Ehmke, Björn C. Schroeder, Christian A. Hübner

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Figure 3

TMEM16A is expressed in the aorta and modulates its contractility but absent from medium-sized arteries.

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TMEM16A is expressed in the aorta and modulates its contractility but ab...
(A and B) Western blot analysis of protein lysates of isolated arterial blood vessels of non-induced control mice revealed that TMEM16A expression is particularly strong in the aorta as compared with carotid and mesenteric arteries. In tamoxifen-induced conditional Tmem16a knockout mice, the bands corresponding to TMEM16A were shifted to a smaller size. (C) Tail currents as a measure for the size of CaCCs in VSMCs isolated from different blood vessels differed significantly in size. In the induced conditional knockout, currents were abolished (n = 10–15 in each group). mes., mesenteric. (DF) Whereas vascular smooth muscle cells in cryosections of the aorta of control mice were robustly stained (D), staining was less intense in large (E) and almost absent in small mesenteric arteries (F). Endothelial cells were stained with an antibody recognizing CD31. Scale bars: 30 εm. (G, H, J, and K) Dose-response curves for the contractile effects of angiotensin II (G and H) and U46619 (J and K) for aortic (G and J; n = 6 in each group) and first/second-order mesenteric artery rings (H and K; n = 16–24 in each group), as determined by wire myography. (I and L) Changes in diameter of pressurized third/fourth-order mesenteric arteries in response to different concentrations of angiotensin II (I) and U46619 (L), as determined by videomicroscopy (n = 4–6 in each group). Arteries of the two genotypes showed comparable dilator responses of roughly 25% to Ca2+-free solutions (data not shown). 2-way ANOVA; *P < 0.05; **P < 0.01.