Homocysteine alters vasoreactivity of human internal mammary artery by affecting the KCa channel family

Hyperhomocysteinemia is an independent risk factor for atherosclerotic heart disease. We previously demonstrated that disruption of calcium-activated potassium (KCa) channel activity is involved in homocysteine-induced dilatory dysfunction of porcine coronary arteries. Recently we reported that the KCa channel family, including large-, intermediate-, and small-conductance KCa (BKCa, IKCa, and SKCa) subtypes, are abundantly expressed in human internal mammary artery (IMA). In this study, we further investigated whether homocysteine affects the expression and functionality of the KCa channel family in this commonly used graft for coronary artery bypass surgery (CABG).

Homocysteine reduces the expression of BKCa β1-subunit and compromises the vasodilating activity of BKCa channels in IMA. Unlike BKCa, IKCa and SKCa subtypes are unessential for IMA vasoregulation, whereas the loss of BKCa functionality in hyperhomocysteinemia enhances the role of IKCa and SKCa subtypes in mediating endothelial dilator function. Targeting BKCa channels may form a strategy to improve the postoperative graft performance in CABG patients with hyperhomocysteinemia who receive IMA grafting.

Residual IMA segments obtained from patients undergoing CABG were studied in a myograph for the role of KCa subtypes in both vasorelaxation and vasoconstriction. The expression and distribution of KCa subtypes were detected by Western blot and immunohistochemistry.

Both the BKCa channel activator NS1619 and the IKCa/SKCa channel activator NS309 evoked significant IMA relaxation. Homocysteine exposure suppressed NS1619-induced relaxation whereas showed no influence on NS309-induced response. Blockade of BKCa but not IKCa and SKCa subtypes significantly suppressed acetylcholine-induced relaxation and enhanced U46619-induced contraction. Homocysteine compromised the vasodilating activity of the BKCa subtype in IMA, associated with a lowered protein level of the BKCa β1-subunit. Homocysteine potentiated the role of IKCa and SKCa subtypes in mediating endothelium-dependent relaxation without affecting the expression of these channels. Conclusions: Homocysteine reduces the expression of BKCa β1-subunit and compromises the vasodilating activity of BKCa channels in IMA. Unlike BKCa, IKCa and SKCa subtypes are unessential for IMA vasoregulation, whereas the loss of BKCa functionality in hyperhomocysteinemia enhances the role of IKCa and SKCa subtypes in mediating endothelial dilator function. Targeting BKCa channels may form a strategy to improve the postoperative graft performance in CABG patients with hyperhomocysteinemia who receive IMA grafting.