Pharmacological, immunological, and gene targeting of the renin-angiotensin system for treatment of cardiovascular disease.

Effective blood pressure control with a large arsenal of conventional antihypertensive drugs, such as diuretics, beta-adrenergic blockers, and calcium channel blockers, significantly reduce the morbidity and mortality associated with cardiovascular disease. However, blood pressure control with these drugs does not reduce cardiovascular disease risks to the levels in normotensive persons. Only two drug classes that inhibit or antagonize portions of the renin-angiotensin system (RAS), angiotensin converting enzyme (ACE) inhibitors and angiotensin receptor type-1 (AT(1) receptor) blockers, have protective and beneficial effects unrelated to the degree of blood pressure reduction. These drugs may prevent the blood pressure related functional and structural abnormalities of the cardiovascular system and reduce the end organ-damage. The first part of this review presents the components of the RAS, biological actions of angiotensin peptides, and the functions of the enzymes that generate and metabolize angiotensins, including the likely effect of manipulating them. Special attention is devoted to renin, ACE, ACE2, chymase, and neprilysin. The second part of this review presents the rationale for targeting the RAS, based on clinical studies of the ACE inhibitors and AT(1) receptor blockers. Finally, we present the investigational agents acting on the RAS that have a potential for clinical usage, and give the perspective of pharmacological, immunological and gene targeting of the RAS for treatment of cardiovascular disease.

Role of renin angiotensin system inhibitors in cardiovascular and renal protection: a lesson from clinical trials.

Beneficial effects of angiotensin converting enzyme inhibitors (ACEI) and angiotensin type 1 receptor (AT1) blockers in patients with cardiovascular and renal diseases have been clearly demonstrated in numerous large outcomes studies. In patients with heart failure (HF), ACEI have been shown to reduce overall mortality, mortality from cardiovascular causes, to increase life expectancy, as well as to preserve the renal function (CONSENSUS, SAVE, TRACE, AIRE, AIREX, CATS trials). In addition, in the PROGRESS study ACEI substantially decreased the risk of stroke and transient ischemic attacks in patients with cerebrovascular disorders. The HOPE and EUROPA studies confirmed that long term therapy with ACEI provides significant survival benefit in patients with broad range of atherosclerotic cardiovascular diseases. After these large and well designed clinical studies, ACEI have become standard therapy for routine secondary prevention in all patients with cardiovascular diseases, unless contraindicated. AT1 receptor blockers have been recently added to the cardiovascular therapeutic armamentarium. They are believed to provide additional protection by inhibition of locally synthesized angiotensin II on the level of AT1 receptor. The ELITE II, ValHeFT and CHARM studies have shown that AT1 receptor blockers are equally effective as ACEI in reduction of mortality and morbidity in patients with HF. Importantly, they may be used together with ACEI, or as alternative treatment in ACEI intolerant patients. Renal protection is another important effect of both ACEI and AT1 blockers that has been confirmed in several large clinical trials. The North American Microalbuminemia Study group and EUCLID group demonstrated significant reduction in progression of diabetic nephropathy in patients with insulin dependent diabetes mellitus (IDDM) treated with ACEI. AT1 receptor blockers are mainly studied in the non-insulin dependent diabetes mellitus (NIDDM) nephropathy. Four recent clinical trials (IRMA-2, DETAIL, RENAAL and IDNT) examined the effect of AT1 receptor blockers in patients with NIDDM nephropathy. These studies confirmed the beneficial effect of AT1 receptor blockers in patients with NIDDM nephropathy that was extended beyond the blood pressure reduction. Ongoing studies (ONTARGET, TRANSCEND and PROTECTION) should provide us with additional insights about cardiovascular, renal and other end-organ protective effects of these therapeutics.

Localization of carboxypeptidase A-like enzyme in rat kidney.

In this study we demonstrate that carboxypeptidase A (CPA)-like enzyme is expressed in rat kidney. The major metabolites of angiotensin (Ang) I by the rat renal mesangial cell extract at 37 degrees C, pH 7.4, were Ang 1-9 and Ang II. Quinaprilat did not influence the formation of Ang 1-9, but it inhibited formation of Ang II. The formation of Ang 1-9 was inhibited by potato carboxypeptidase inhibitor, 1,10-phenanthroline or EDTA. Lowering the pH from 7.4 to 4.0 also inhibited the formation of this nonapeptide. These findings suggest that a metallocarboxypeptidase is responsible for Ang 1-9 production. Using monoclonal antibodies to CPA, Western blot showed the presence of CPA-like enzyme in the extracts prepared from the mesangial cells or kidney cortex of the rat. Immunohistochemistry showed that CPA-like enzyme is localized in the mesangial glomerular cells and adventitia of kidney blood vessels, whereas it was absent in the renal tubules. Our data suggest that a CPA-like enzyme could be added to a repertoire of enzymes present in the rat mesangial cells and adventitia of renal blood vessels.

Properties and distribution of angiotensin I converting enzyme.

This review summarizes some basic properties and distribution of angiotensin I converting enzyme (ACE). ACE is one of several biologically important ectoproteins that exists in both membrane-bound and soluble forms. Localized on the surface of various cells, ACE is inserted at the cell membrane via its carboxyl terminus. Human plasma ACE originates from endothelial cells while other body fluids may contain ACE that originates from epithelial, endothelial or germinal cells. The two isoforms of ACE, the two-domain somatic form and the single domain germinal form, convert angiotensin I to angiotensin II, and metabolize kinins and many other biologically active peptides, including substance P, chemotactic peptide and opioid peptides. The broad spectrum of substrates for ACE and its wide distribution throughout the body indicates that this enzyme, in addition to an important role in cardiovascular homeostasis, may be involved in additional physiologic processes such as neovascularization, fertilization, atherosclerosis, kidney and lung fibrosis, myocardial hypertrophy, inflammation and wound healing. Future research should explore the possible functions of tissue ACE and its systemic role as a pressor agent. ACE inhibitors have achieved widespread use in the treatment of hypertension and the protection of end-organ damage in cardiovascular and renal diseases. Potential problems related to side effects and compliance of such therapy need to be addressed. A safer way of producing therapeutic effects is promised by the delivery of the ACE antisense sequences by a vector producing a permanent inhibition of ACE and long-term control of blood pressure in hypertensive patients.

Angiotensin-converting enzyme inhibitors: mechanisms of action and implications in anesthesia practice.

This review summarizes physiology of circulating and local renin-angiotensin system (RAS), enzymatic properties and mechanism of action of angiotensin I converting enzyme inhibitors (ACEIs) on RAS, and implications of ACEIs in anesthetic management of patients treated with these drugs. ACEIs, through their effect on RAS, may improve cardiovascular functions, pulmonary dynamics, and body fluid homeostasis. Thus, ACEIs have become an integral part of management of patients with hypertension, congestive heart failure (CHF) and chronic renal disease. ACEIs, due to differences in their chemical structure, exert different pharmacological actions and can have protective or occasional damaging effects on different organs. The anesthesiologists are commonly involved in the management of patients treated with ACEIs. Thus, the role of ACEIs and their possible interaction with anesthetic agents must be an integral part of clinical decision-making during anesthesia Hemodynamic variation during anesthesia is mainly related to specific effects of anesthetic agents on sympathetic nervous system. Those with preoperative fasting, volume depletion and extended sympathetic blockade can have reduced vascular capacitance resulting in decreased venous return, reduced cardiac output and severe arterial hypotension. Angiotensin II (ANG2) a potent vasoconstrictor may counterbalance such hypotensive effect. During ACE inhibition ANG2 cannot counterbalance this hypotension. Thus, induction of anesthesia may cause severe hypotension in hypovolemic patients specifically in those receiving diuretics as a complement to ACEIs. Recent advances in RAS and the pharmacology of ACEIs have identified some predisposing factors and risks associated with anesthesia in patients treated with ACEIs. Practitioners should be vigilant, and readily have vasopressors, necessary fluids and other resuscitative measures for treatment of unexpected hemodynamic instability during anesthesia and surgery.