BACKGROUND: Hypertension, a major cause of cardiovascular morbidity and mortality, can result from chronic hypoxia; however, the pathogenesis of this disorder is unknown. We hypothesized that downregulation of the maxi-K+ channel beta1-subunit by hypoxia decreases the ability of these channels to hyperpolarize arterial smooth muscle cells, thus favoring vasoconstriction and hypertension. METHODS AND RESULTS: Lowering O2 tension produced a decrease of maxi-K+ beta1-subunit mRNA levels in rat (aortic and basilar) and human (mammary) arterial myocytes. This was paralleled by a reduction of the beta1-subunit protein level as determined by immunocytochemistry and flow cytometry. Exposure to hypoxia also produced a decrease of open probability, mean open time, and sensitivity to the xenoestrogen tamoxifen of single maxi-K+ channels recorded from patch-clamped dispersed myocytes. The number of channels per patch and the single-channel conductance were not altered. The vasorelaxing force of maxi-K+ channels was diminished in rat and human arterial rings exposed to low oxygen tension. CONCLUSIONS: These results indicate that a decrease of the maxi-K+ channel beta1-subunit expression in arterial myocytes is a key factor in the vasomotor alterations induced by hypoxia.
BACKGROUND:Hypertension, a major cause of cardiovascular morbidity and mortality, can result from chronic hypoxia; however, the pathogenesis of this disorder is unknown. We hypothesized that downregulation of the maxi-K+ channel beta1-subunit by hypoxia decreases the ability of these channels to hyperpolarize arterial smooth muscle cells, thus favoring vasoconstriction and hypertension. METHODS AND RESULTS: Lowering O2 tension produced a decrease of maxi-K+ beta1-subunit mRNA levels in rat (aortic and basilar) and human (mammary) arterial myocytes. This was paralleled by a reduction of the beta1-subunit protein level as determined by immunocytochemistry and flow cytometry. Exposure to hypoxia also produced a decrease of open probability, mean open time, and sensitivity to the xenoestrogen tamoxifen of single maxi-K+ channels recorded from patch-clamped dispersed myocytes. The number of channels per patch and the single-channel conductance were not altered. The vasorelaxing force of maxi-K+ channels was diminished in rat and human arterial rings exposed to low oxygen tension. CONCLUSIONS: These results indicate that a decrease of the maxi-K+ channel beta1-subunit expression in arterial myocytes is a key factor in the vasomotor alterations induced by hypoxia.
Authors: Xiaoxiao Tao; Mike T Lin; Glyne U Thorington; Sean M Wilson; Lawrence D Longo; David A Hessinger Journal: Am J Physiol Heart Circ Physiol Date: 2015-01-16 Impact factor: 4.733