Cardiovascular Research

Cardiovascular Research 2004 62(1):7-8; doi:10.1016/j.cardiores.2004.01.034
© 2004 by European Society of Cardiology

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Copyright © 2004, European Society of Cardiology

Angiotensin AT₂ receptor: the younger sibling attracts attention

Elisabetta Cerbai and Alessandro Mugelli^*

Department of Preclinical and Clinical Pharmacology, University of Firenze, Viale Pieraccini 6, Florence 50139, Italy

^* Corresponding author. Tel.: +39-554271264; fax: +39-554271285. Email address: alessandro.mugelli{at}unifi.it

Received 26 January 2004; accepted 29 January 2004

See article by Caballero et al. [6] (pages 86–95) in this issue.

Electrical remodeling is a crucial aspect of the general process of cardiac remodeling associated with left ventricular hypertrophy and heart failure [1], and it is thought to contribute to an increased risk of ventricular fibrillation and sudden cardiac death. Angiotensin II has long been recognized as a major factor in cardiac remodeling in a variety of cardiovascular and non-cardiovascular diseases—from hypertension to diabetes [2]. Two receptor subtypes for angiotensin II have been identified in the heart, AT₁ and AT₂, which apparently share two features: the endogenous ligand and the gross molecular structure, belonging both to the seven transmembrane-domain receptor family [3]. Because of its well-documented action on myocyte hypertrophy, collagen deposition, aldosterone production, and many other functions, the AT₁ receptor has long monopolized the attention of researchers [4]. Experimental observations have provided the rationale for development and clinical use of angiotensin receptor blockers (ARB), with the aim of offering a better protection than angiotensin-converting enzyme inhibitors (ACE-I) against angiotensin II by directly blocking AT₁. Due to the activity of peptidases other than ACE (e.g., chymase) that convert angiotensin I to angiotensin II, ACE-I block less than 15% of the total production of angiotensin II in the heart.

The number of patients receiving ACE-I is much larger than that corresponding to those treated with ARB; nevertheless, it is generally agreed that AT₁ blockade may represent a safe and valuable option that can reduce mortality and adverse cardiovascular events in a variety of clinical settings [5].

From a pharmacological point of view, the two classes of drugs (ACE-I or ARB) have different profiles mainly because AT₁ antagonists leave intact the interaction of angiotensin II with the sibling receptor, AT₂. The implications of this fact are unknown, since the effect of AT₂ stimulation on cardiac tissue remains largely unexplored.

In this issue, Caballero et al. [6] are the first to attempt to investigate the effects of AT₂ stimulation on cellular cardiac function from an electrophysiological point of view. They found something unexpected: To understand why their results are surprising, it is necessary to go one step back, to the electrophysiological actions mediated by angiotensin II via AT₁ stimulation.

	1. Angiotensin receptors and electrophysiological remodeling

Top 1. Angiotensin receptors and... 2. Physiological and clinical... References

 
In animal models of cardiac hypertrophy and failure, AT₁ antagonists (as well as ACE-I) prevent or even reverse cardiac electrophysiological remodeling [7]. These data are in agreement with the clinical evidence of a protection against sudden cardiac death in patients treated with ARB [8]. The effect on remodeling seems to be due to the prevention or reversal of the prolongation of the action potential, which occurs in all cardiomyopathies and is strictly related to the lengthening of the QT interval observed in the ECG. The ionic basis of electrical remodeling involves the repolarizing potassium currents: the transient outward current, I_to, appears to be an obligatory link between the angiotensin II effect and prolongation of the action potential. I_to is finely regulated by angiotensin II: Indeed, the molecular and functional expression of transient outward current(s) is depressed in cardiac hypertrophy and failure [1,9]. This effect is reversed by long-term treatment with AT₁ antagonists [7]. The transcription factors activated by myocardial hypertrophy (GATA and FOG2) also control the expression of the Kv4.2 gene [10], whose product is one of the proteins coding for I_to channels. The role of I_to as an electrophysiological target of angiotensin II is shown by data obtained in other pathophysiological settings. AT₁ stimulation is associated with I_to downregulation in type-1 diabetes in rats and with a parallel action potential prolongation [11]. The same mechanism seems to underlie the transmural gradient of I_to density in the canine ventricle and the related difference in action potential profile between endocardium and epicardium [12]: endocardial cells, where I_to is small, develop a large I_to as found in epicardial cells in the presence of the AT₁ antagonist losartan. Vice versa, epicardial cells are "converted" into endocardial myocytes by incubation with angiotensin II. This transcriptional or post-transcriptional modulation of I_to channel proteins by angiotensin II has been attributed to the well-known signaling that occurs downstream of the AT₁ receptor.

The AT₂ receptor has long been considered not only the "younger sibling" of AT₁, but also its opponent. In a variety of cells types, AT₂ exert contrasting effects (reviewed in Ref. [13]), including an increase in outward potassium currents in cultured neurons [14]. These results, in the absence of similar studies in cardiac cells, could have led to the belief that AT₂ stimulation in the myocardium causes an increase in potassium currents.

The paper by Caballero et al. [6] shows that this is not the case: AT₂ stimulation causes a 20% decrease in I_to and a corresponding action potential prolongation in rat ventricular myocytes. Interestingly, the AT₂-mediated decrease in I_to was observed only in the perforated-patch configuration, probably because the conventional whole-cell configuration of the patch-clamp technique altered the intracellular milieu and the signaling pathway. Their results demonstrated that one of the intracellular steps between the AT₂ receptor and the I_to channel involves the activation of the serine/threonine phosphatase type 2A (PP2A) that may act by dephosphorylating the channel and decreasing current amplitude. Moreover, by transfecting Kv4.2 channels into CHO cells, Caballero et al. identified this channel protein as the target (or one of the targets) of angiotensin II via AT₂ stimulation.

	2. Physiological and clinical implications and open questions

Top 1. Angiotensin receptors and... 2. Physiological and clinical... References

 
This paper raises a number of interesting questions. Some of these, such as the species dependence and the role of this pathway in modulating other cardiac channels, will likely be answered soon by further investigation. However, other aspects will require more intensive research.

Keeping in mind that angiotensin II contributes to the regulation of potassium channels in the evolution of the so-called "cardiac memory" [15], the physiological implications of AT₂ stimulation on I_to channels should be addressed (e.g., does the transient, acute inhibition of I_to by locally released angiotensin II play a role in regulating beat-to-beat action potential duration?) Furthermore, the role of AT₂ stimulation during chronic treatment with ARB should be investigated by clarifying whether (i) the acute effect is maintained over time and (ii) the electrophysiological effects in hypertrophied or failing myocytes are similar to those described by Caballero et al. [6] in normal myocardial cells. Until then, it will be difficult to speculate as to the possible clinical implications of AT₂-mediated electrophysiological effects. However, the results by Caballero et al. should be kept in mind when looking at clinical data that compare treatment with ACE-I and ARB.

	References

Top 1. Angiotensin receptors and... 2. Physiological and clinical... References

 

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