Perivascular adipose tissue-derived adiponectin activates BK(Ca) channels to induce anticontractile responses.

This study aims to identify the potential mechanisms by which perivascular adipose tissue (PVAT) reduces tone in small arteries. Small mesenteric arteries from wild-type and large-conductance Ca(2+)-activated K(+) (BKCa) channel knockout mice were mounted on a wire myograph in the presence and absence of PVAT, and contractile responses to norepinephrine were assessed. Electrophysiology studies were performed in isolated vessels to measure changes in membrane potential produced by adiponectin. Contractile responses from wild-type mouse small arteries were significantly reduced in the presence of PVAT. This was not observed in the presence of a BKCa channel inhibitor or with nitric oxide synthase (NOS) inhibition or in BKCa or adiponectin knockout mice. Solution transfer experiments demonstrated the presence of an anticontractile factor released from PVAT. Adiponectin-induced vasorelaxation and hyperpolarization in wild-type arteries were not evident in the absence of or after inhibition of BKCa channels. PVAT from BKCa or adiponectin knockout mice failed to elicit an anticontractile response in wild-type arteries. PVAT releases adiponectin, which is an anticontractile factor. Its effect on vascular tone is mediated by activation of BKCa channels on vascular smooth muscle cells and adipocytes and by endothelial mechanisms.

Effects of diabetes and hypertension on structure and distensibilty of human small coronary arteries.

OBJECTIVES: Previous studies have demonstrated that hypertension and diabetes induce significant structural remodelling of resistance arteries from various vascular beds. The hypothesis of this study is that structural alterations of small coronary arteries may occur during hypertension and diabetes. This study is the first to compare human coronary small resistance artery structure from normotensive and hypertensive patients, with and without diabetes undergoing coronary arterial bypass graft surgery. METHODS: Small arteries were dissected from the atrial appendage removed from nondiabetic normotensive patients, nondiabetic hypertension and diabetic normotensive patients and hypertensive diabetic patients. Arteries were mounted in a pressure myograph and lumen diameter and wall thickness were measured across the pressure range of 3-100 mmHg to assess vessel structure and distensibility. RESULTS: There were no significant differences in the lumen diameter, wall thickness, wall-to-lumen ratio and cross-sectional area of arteries in all groups. Arteries from nondiabetic patients with hypertension demonstrated decreased distensibility compared with nondiabetic normotensive patients. There is no difference in distensibility between vessels from diabetic hypertensive patients and either diabetic or nondiabetic normotensive patients. CONCLUSION: Neither diabetes nor hypertension appears to have influenced arterial structure which may indicate that successful treatment of hypertension is associated with normal vascular structure in coronary small arteries.

Adenosine- and hypoxia-induced dilation of human coronary resistance arteries: evidence against the involvement of K(ATP) channels.

1. The ATP-sensitive potassium (K(ATP)) channel may be an important mediator of metabolic dilation in the human coronary circulation. As adenosine and hypoxia are considered to be major mediators of metabolic dilation in the coronary circulation, we investigated the effect of glibenclamide (a K(ATP) channel blocker) on adenosine and hypoxic dilation of human coronary resistance arteries, with myogenic tone, in vitro. 2. Vessels were dissected from the atrial appendage from consenting patients and studied in vitro using a pressure arteriograph system. Segments of coronary resistance artery were pressurized to 60 mmHg and the vessels studied developed spontaneous myogenic tone. 3. The K(ATP) opener pinacidil (final conc. 5 x 10(-6) M) resulted in dilation, which was completely reversed by 5 x 10(-6) glibenclamide (84+/-14 vs -10+/-9%, pinacidil and pinacidil plus glibenclamide, respectively, P=0.009, n=5). 4. Adenosine (final conc. 10(-5) M) resulted in dilation, glibenclamide (5 x 10(-6) and 10(-5) M) was without effect (118+/-12 vs 104+/-16% adenosine and adenosine plus 10(-5) glibenclamide, respectively, n.s., n=4). 5. Hypoxia (8+/-3 mmHg O2) resulted in a dilation that reversed when normoxic conditions were restored (60+/-9 vs 3+/-11% hypoxia and post-hypoxia, respectively, P=0.014, n=3). The hypoxic dilation was not affected by glibenclamide (63+/-14 vs 55+/-6% hypoxia and hypoxia plus glibenclamide, respectively, n.s., n=4). In a further series of experiments, vessels were incubated with glibenclamide (5 x 10(-6)) prior to a hypoxic challenge; again, glibenclamide was without effect on the hypoxic dilation (-0.008+/-2 vs 95+/-3% glibenclamide and glibenclamide plus hypoxia, respectively, P=0.0005, n=3). 6. These data demonstrate that glibenclamide is without effect on both adenosine and hypoxic dilation of human coronary resistance arteries with myogenic tone, from the right atrial appendage in vitro. Our findings suggest that the K(ATP) channel is unlikely to be a major mediator of metabolic dilation in these arteries.