Regulation of the kinin receptors after induction of myocardial infarction: a mini-review

It is well known that the responses to vasoactive kinin peptides are mediated through the activation of two receptors termed bradykinin receptor B1 (B1R) and B2 (B2R). The physiologically prominent B2R subtype has certainly been the subject of more intensive efforts in structure-function studies and physiological investigations. However, the B1R activated by a class of kinin metabolites has emerged as an important subject of investigation within the study of the kallikrein-kinin system (KKS). Its inducible character under stress and tissue injury is therefore a field of major interest. Although the KKS has been associated with cardiovascular regulation since its discovery at the beginning of the last century, less is known about the B1R and B2R regulation in cardiovascular diseases like hypertension, myocardial infarction (MI) and their complications. This mini-review will summarize our findings on B1R and B2R regulation after induction of MI using a rat model. We will develop the hypothesis that differences in the expression of these receptors may be associated with a dual pathway of the KKS in the complex mechanisms of myocardial remodeling.

Vasopressin and bradykinin receptors in the kidney: implications for tubular function

Vasopressin and bradykinin are two of the most important peptides in regulating vascular tone, water, and ionic balance in the body, adn thus they play a key role in controlling blood pressure. In addition to being a potent vasoconstrictor, Vasopressin also has an antidiuretic activity in the kidney, whereas kinins regulate renal blood flow in addition to their vasodilatory and natriuretic activity. We review here the primary evidence for the localization of the vasopressin and kinin receptors and their role in ionic and water regulation in the kidney.

Mechanism of smooth muscle contraction and relaxation mediated by kinin receptor

The increase in sensitivity of guinea pig preparations to bradykinin (BK) due to stretching occurring with time after mounting was studied by determining the time course of changes in the cell membrane potential, measured with intracellular microelectrodes. A sustained hyperpolarizing effect of BK, which was observed in recently mounted preparations, became transient after 120 min, when it was followed by depolarization, which was much more evident after 4 h of stretching. As a consequence, a parallel increase in the contractile response to BK was also observed. The hyperpolarizing effect was due to the opening of Ca²+-dependent K+ channels sensitive to apamin, since BK dose-response curves done within 1 h of mouting were shifted to the left, becoming similar to dose-response curves obtained 4 h after mounting of the guinea pig ileum preparation. These results were specific for BK, since the potentiating effect of apaming was not observed for acetylcholine. Our results show that the activation of B2 receptors by BK in the isolated guinea pig ileum induce a dual effect - hyperpolarization and depolarization - and that the increase in the contractile response consequent to stretching is probably due to the inactivation of apaminsensitive Ca²+-dependent K+ channels