Iptakalim: a new or just another KCO?

Cardiac hypertrophy, especially left ventricular hypertrophy (LVH), is a major compensatory mechanism in response to pressure overload derived from hypertension. Also, tissue remodelling through LVH is known to lead to heart failure if the increased workload is sustained over a long period of time. In a nutshell, hypertension can result in hypertrophy which, if sustained, leads to heart failure. Hypertension is also a risk factor for vascular accidents leading to ischaemia. Endothelial cell (dys)function has been shown to play important roles in the pathophysiological events related to the establishment and progression of hypertensive heart disease. Nitric oxide (NO) production by endothelial cells inhibits the progression of cardiac hypertrophy, whereas endothelin generation promotes hypertrophy. Actually, the imbalance between these two systems is one of the underlying causes of cardiac tissue remodelling. Antihypertensive drugs that increase NO generation or that inhibit endothelin production have been shown to decrease cardiac hypertrophy (mostly by decreasing LVH), thus preventing heart failure induced by a pressure overload. However, despite intense research, drugs able to ameliorate hypertension and, at the same time, protect against the associated heart diseases are still lacking. A promising candidate in this area is iptakalim, a recently developed Kþ channel opener (KCO) that has been shown to be antihypertensive in different models of hypertension in rats, dogs, and humans. This issue of Cardiovascular Research brings an interesting contribution to the field of hypertension and heart disease, uncovering some new properties of iptakalim. Gao et al. show that iptakalim possesses antihypertrophic properties, preventing the progression of LVH to heart failure induced by pressure overload. They also show that iptakalim helps maintain several haemodynamic parameters, such as heart rate, blood pressure, and ventricular function. Additionally, iptakalim reduces myocardial and perivascular fibrosis as well as mRNA expression of two important molecular markers of heart failure, atrial natriuretic peptide, and B-type natriuretic peptide. Their most interesting results concern the signalling pathway that might underlie the whole-organ effects. Gao et al. show that iptakalim treatment substantially increases serum content of NO and decreases that of endothelin-1 protein. These data parallel an increase in the content of endothelial NO synthase and a decrease in endothelin-converting enzyme. The results suggest that iptakalim’s effects on cardiac hypertrophy induced by pressure overload occur through the maintenance of the balance between the NO and endothelin signalling systems. Based on previous studies, they claim that iptakalim protects endothelial function by preferential activation of the SUR2B/Kir6.1 subtype of plasma membrane KATP channels (cellKATP, or sarcKATP in muscle tissues) expressed in the endothelium. As often is the case, new questions are expected to arise from solid research. The present work by Gao et al. raises several questions that must be addressed concerning iptakalim’s intracellular effects. Several articles point to a link between mitochondrial KATP channels (mitoKATP) activity and hypertrophy. Diazoxide, a mitoKATP agonist, has been shown to inhibit phenylephrine-induced hypertrophy. The mitoKATP antagonist 5-hydroxydecanoate (5HD) has been shown to block the inotropic effects of calcium and other known inotropic drugs, such as ouabain or dobutamine. These data strongly support the hypothesis that mitoKATP activity is intrinsically involved in the intracellular signalling pathways leading to hypertrophy. Additionally, the protection afforded by iptakalim against MPPþ or H2O2 is abolished by 5HD, which suggests that iptakalim’s protective mechanisms occur via mitoKATP activation. 10,11 Indeed, all cardioprotective KCOs described thus far have been shown to be mitoKATP agonists. Cardioprotective protocols such as ischaemic preor postconditioning also operate via mitoKATP opening. However, Gao et al. claim that cardioprotective doses of iptakalim do not open cardiac muscle mitoKATP. Even though no data are shown, the unpublished data regarding mitoKATP activity were obtained using techniques that are not sensitive enough for that purpose, which could lead to misleading interpretations. For The opinions expressed in this article are not necessarily those of the Editors of Cardiovascular Research or of the European Society of Cardiology. * Corresponding author. Tel: þ55 41 3316 3238; fax: þ55 41 3316 3267. E-mail address: [email protected]