Lynley K. Lewis

Beneficial Hemodynamic and Renal Effects of Adrenomedullin in an Ovine Model of Heart Failure

BACKGROUND Adrenomedullin is a recently discovered endogenous peptide with hypotensive and natriuretic actions in normal animals. Circulating and ventricular adrenomedullin are elevated in congestive heart failure, suggesting a possible role in the pathophysiology of this disease. No studies have previously examined the effects of adrenomedullin in heart failure. METHODS AND RESULTS Eight sheep with pacing-induced heart failure received human adrenomedullin(1-52) at 10 and 100 ng x kg(-1) x min(-1) I.V. for 90 minutes each. Compared with vehicle control data, adrenomedullin increased plasma cAMP (high dose, P<.05) in association with dose-dependent falls in calculated peripheral resistance (13 mm Hg x L(-1) x min(-1), P<.001), mean arterial pressure (9 mm Hg, P<.001), and left atrial pressure (5 mm Hg, P<.001) and increases in cardiac output (0.5 L/min, P<.001). Adrenomedullin increased urine sodium (threefold, P<.05), creatinine (P<.05) and cAMP excretion (P<.01), creatinine clearance (P<.05), and renal production of cAMP (P<.05), whereas urine output was maintained during infusion and raised after infusion (P<.05). Adrenomedullin reduced plasma aldosterone levels (P<.05), whereas plasma atrial and brain natriuretic peptide concentrations were unchanged during infusion and rose after infusion (P<.01 and P<.05, respectively). Plasma catecholamine, cortisol, renin, calcium, and glucose concentrations were not significantly altered. CONCLUSIONS Adrenomedullin reduced ventricular preload and afterload and improved cardiac output in sheep with congestive heart failure. Despite the clear fall in arterial pressure, adrenomedullin increased creatinine clearance and sodium excretion and maintained urine output. These results imply an important pathophysiological role for adrenomedullin in the regulation of pressure and volume in heart failure and raise the possibility of a new therapeutic approach to this disease.

Ouabain is not detectable in human plasma.

An enzyme-linked immunosorbent assay is described for the measurement of ouabain in human plasma. This assay is specific for ouabain, strophanthidin, and ouabagenin, with other steroids, including digoxin and vasopressor hormones, exhibiting negligible cross-reactivity. Assay sensitivity was 0.06 nmol/L if 1 mL plasma was extracted and less than 0.005 nmol/L when 20 mL plasma was analyzed. Extracted plasma samples showed ouabainlike immunoreactivity that diluted in parallel with the ouabain standard curve. Repeated extraction and assay of single plasma samples, however, did not produce consistent results in the assay. Increased specificity was obtained by high-performance liquid chromatography of sample extracts before assay. When high-performance liquid chromatographic profiles of plasma spiked with ouabain standard or following bolus intravenous injections of ouabain into normal human volunteers were compared with profiles of unspiked plasma, there was no support for the immunoreactive material in the latter samples being ouabain. We propose that if ouabain is present in the human circulation, its concentration is less than 0.005 nmol/L.

Bioactivity and Interactions of Adrenomedullin and Brain Natriuretic Peptide in Patients With Heart Failure

Plasma concentrations of the recently discovered hormones adrenomedullin (ADM), from vascular tissue, and brain natriuretic peptide (BNP), secreted by myocardium, are elevated in patients with heart failure. We tested the hypotheses that short-term increments in circulating levels of these hormones, within the pathophysiological range, would have biological effects and that the 2 hormone systems interact. Eight patients with heart failure (left ventricular ejection fractions <35%) received 4-hour infusions of BNP (3.0 pmol. kg(-1). min(-1)) alone, ADM (2.7 pmol. kg(-1). min(-1) and 5.4 pmol. kg(-1). min(-1) for 2 hours each) alone, ADM and BNP combined, and placebo. BNP and ADM infusions raised plasma levels of the respective peptide within the pathophysiological range. Arterial blood pressure fell (P<0.05) with all peptide infusions, but cardiac output was unchanged. Heart rate increased with ADM and combined infusions (P<0.01). Sodium excretion rose (P<0.05), and creatinine clearance was sustained during both BNP and combined infusions. Urine volume increased in response to BNP alone (P=0.02). Despite a >2-fold increase in plasma renin with both ADM and combined infusions (P<0.05), plasma aldosterone remained lower than time-matched placebo levels. Plasma noradrenaline was increased by combined, BNP, and higher dose ADM infusions (P<0.05). ADM suppressed plasma cGMP (P<0.05) and inhibited the plasma cGMP response to BNP (P<0.05). The vascular hormones ADM and BNP, produced by myocardium, at plasma concentrations within the pathophysiological range have hemodynamic, renal, and hormonal effects and measurable interactions in patients with heart failure.

Hemodynamic, Hormone, and Urinary Effects of Adrenomedullin Infusion in Essential Hypertension

We examined the effects of the vasodilator peptide adrenomedullin (AM) infused intravenously into subjects with essential hypertension. Eight men 39 to 58 years old with uncomplicated hypertension (147/96±5/3 mm Hg at baseline) were studied in a placebo-controlled, crossover design. Each subject received intravenous AM in a low and a high dose (2.9 and 5.8 pmol · kg−1 · min−1 for 2 hours each) or vehicle-control (Hemaccel) infusion in a random order on day 4 of a controlled metabolic diet (80 mmol/d Na+, 100 mmol/d K+). Plasma AM reached pathophysiological levels during infusion (18±4 pmol/L in low dose, 34±9 pmol/L in high dose) with a concurrent rise in plasma cAMP (+8.4±1.2 pmol/L, P <0.05 compared with control). Compared with control, high-dose AM increased peak heart rate (+17.8±2.3 bpm, P <0.01), lowered systolic (−24.6±0.9 mm Hg;P <0.01) and diastolic (−21.9±1.4 mm Hg;P <0.01) blood pressure, and increased cardiac output (+1.0±0.1 L/min in low dose, +2.9±0.2 L/min in high dose;P <0.01 for both). Despite a rise in plasma renin activity during high dose (P <0.05), aldosterone levels did not alter. Plasma norepinephrine levels increased 1295±222 pmol/L (P <0.001) and epinephrine increased 74±15 pmol/L (P <0.05) with high-dose AM compared with control. AM had no significant effect on urine volume and sodium excretion. In subjects with essential hypertension, the intravenous infusion of AM to achieve pathophysiological levels produced significant falls in arterial pressure, increased heart rate and cardiac output, and stimulated the sympathetic system and renin release without concurrent increase in aldosterone. Urinary parameters were unaltered. Although AM has potent hemodynamic and neurohumoral effects in subjects with essential hypertension, the threshold for urinary actions is set higher.

Degradation of Human Adrenomedullin(1-52) by Plasma Membrane Enzymes and Identification of Metabolites

Very little is known about degradation or metabolism of adrenomedullin. To this end, we incubated adrenomedullin with ovine adrenal, kidney and lung plasma membrane preparations and showed the major degradation products were ADM(2-52) and ADM(8-52). Smaller amounts of ADM(26-52), (27-52), (28-52) and (33-52) were also produced. Degradation was inhibited by EDTA and 1,10 phenanthroline but not by phosphoramidon, leupeptin and pepstatin. The above data are consistent with initial hydrolysis adjacent to hydrophobic residues by a metalloprotease, generating ADM(8-52), (26-52) and (33-52), followed by an aminopeptidase action to produce ADM(2-52), (27-52) and (28-52). Improved understanding of the metabolism of ADM may have therapeutic implications, for example in the treatment of heart failure.

Ouabain, a circulating hormone secreted by the adrenals, is pivotal in cardiovascular disease. Fact or fantasy?

Substantial evidence points to the presence in human plasma of an inhibitor of the sodium/potassium pump which plays a central role in the pathophysiology of circulatory disorders, including essential hypertension. Studies from the 1980/90s claimed that this inhibitor was identical or very similar in structure to plant-derived ouabain and was synthesized by the adrenal cortex. However, the physical evidence in studies reporting isolation and identification of ouabain in human plasma appears insecure on closer examination. Additionally, reported circulating levels of immunoreactive ouabain in humans vary greatly, the ability of the human adrenal glands to secrete ouabain is questionable and the original commercial assay for measuring immunoreactive ouabain is no longer available. We submit that the position of ouabain as an endogenous, adrenally produced regulator of the sodium pump is of such importance that the current evidence needs either to put on a more secure footing or to lose its current status.

Prolonged Urocortin 2 Administration in Experimental Heart Failure: Sustained Hemodynamic, Endocrine, and Renal Effects

Although acute administration of urocortin 2 has beneficial actions in heart failure, the integrated hemodynamic, hormonal, and renal effects of sustained urocortin 2 treatment in this disease have not been investigated. In the current study, we administered a 4-day infusion of a vehicle control (0.9% saline; n=6) or urocortin 2 (0.75 &mgr;g/kg per hour; n=6) to sheep with pacing-induced heart failure. Compared with time-matched controls, infusion of urocortin 2 produced rapid (30-minute) and persistent (4-day) improvements in cardiac contractility (day 4: control 905±73 versus urocortin 2 1424±158 mm Hg/s; P<0.001) and output (2.6±0.1 versus 3.8±0.3 L/min; P<0.001), together with reductions in left atrial pressure (28±1 versus 12±1 mm Hg; P<0.001) and peripheral resistance (30±2 versus 20±2 mm Hg/L per min; P<0.001). In contrast, urocortin 2–induced falls in mean arterial pressure were not established until the second day (day 4: 74±2 versus 72±2 mm Hg; P<0.05). Prolonged urocortin 2 administration was associated with sustained (days 0 to 4) declines in plasma renin activity (day 4: 1.33±0.27 versus 0.73±0.20 nmol/L per hour; P<0.001), aldosterone (970±383 versus 396±96 pmol/L; P<0.05), vasopressin (2.4±0.8 versus 1.3±0.1 pmol/L; P<0.05), endothelin 1 (7.2±0.7 versus 4.5±0.4 pmol/L; P<0.01), and atrial (269±27 versus 150±19 pmol/L; P<0.001) and B-type (65±9 versus 29±6 pmol/L; P<0.001) natriuretic peptides, as well as an acute transient rise in plasma cortisol (day 1: P<0.001). Chronic urocortin 2 also persistently augmented urinary sodium (day 4: 4-fold increase; P<0.001) and creatinine (1.4-fold; P<0.001) excretion and creatinine clearance (1.5-fold; P<0.01) compared with control. Food consumption was temporarily suppressed (P<0.05). In conclusion, 4-day urocortin 2 administration induces sustained improvements in hemodynamics and renal function, in association with inhibition of multiple vasoconstrictor/volume-retaining systems. These findings support the therapeutic potential for urocortin 2 in heart failure.

Endogenous Ouabain Is Not Ouabain

The concept of a circulating digitalis-like inhibitor of the sodium pump, Na+, K+-ATPase, evolved from studies performed in the 1960s. De Wardener et al1 addressed the question of whether a small increase in the glomerular filtration rate together with changes in the concentration of the more recently discovered hormone aldosterone could explain the natriuresis that generally followed salt (sodium) loading. In their studies, dogs had their renal blood flow reduced significantly by constricting the aorta above the renal arteries and were given supramaximal doses of fludrocortisone, a synthetic analogue of aldosterone, and vasopressin before being challenged with intravenous saline. Their ability to develop a natriuresis clearly demonstrated that a third factor (beyond changes in glomerular filtration rate and aldosterone concentrations) was involved in the natriuresis of salt loading. Subsequent experiments demonstrated that the responsible agent could be transmitted by the plasma of the volume-expanded animal.2 Although we may now ask whether in these experiments the effect was mediated, at least in part, by the release of atrial and B-type natriuretic peptide from the heart, it was nearly 2 decades before those hormones were discovered during which time it was demonstrated that the plasma of volume-expanded animals had the ability to inhibit the sodium pump3—which is not a target of atrial natriuretic peptide and B-type natriuretic peptide. Essentially parallel studies were performed by Welt and colleagues4 in uremia where inhibition of the sodium pump of erythrocytes was demonstrated along with the ability of uremic plasma to induce such a defect in normal erythrocytes. In 1975, it was shown that patients with essential hypertension had, as a group, reduced activity of the sodium pump of leukocytes, with corresponding elevated values for intracellular sodium.5 This finding proved to be reproducible in various laboratories, …

Bioactivity of adrenomedullin and proadrenomedullin N-terminal 20 peptide in man

Although the biological effects of adrenomedullin (AM) and PAMP have been reported extensively in animal studies and from in-vitro experiments, relatively little information is available on responses to the hormone administered to man. This review summarizes data from the few studies carried out in man. In healthy volunteers, i.v. infusion of AM reduces arterial pressure, probably at a lower rate of administration than is required to elicit other responses. AM stimulates heart rate, cardiac output, plasma levels of cAMP, prolactin, norepinephrine and renin whilst inhibiting any concomitant response in plasma aldosterone. Little or no increase in urine volume or sodium excretion has been observed. Patients with essential hypertension differ only in showing a greater fall in arterial pressure and in the development of facial flushing and headache. In patients with heart failure or chronic renal failure, i.v. AM has similar effects to those seen in normal subjects but also induces a diuresis and natriuresis, depending on the dose administered. Infusion of AM into the brachial artery results in a dose-related increase in forearm and skin blood flow, more prominent and more dependent on endogenous nitric oxide in healthy volunteers than in patients with cardiac failure. When infused into a dorsal hand vein, AM partially reversed the venoconstrictor action of norepinephrine. Although much more information is required to clarify the role of AM under physiological and pathophysiological circumstances, it is clear that it has prominent hemodynamic and neurohormonal effects, though generally lesser urinary effects when administered short-term in doses sufficient to raise its levels in plasma to those seen in a number of clinical disorders. The only study of PAMP in man showed that its skeletal muscle vasodilator potency, when infused into the brachial artery of healthy volunteers, was less than one hundredth that of AM, and it was without effect on skin blood flow.

Combined angiotensin-converting enzyme inhibition and adrenomedullin in an ovine model of heart failure.

Advances in the treatment of heart failure may require manipulation of neurohumoral responses to cardiac impairment in addition to the established strategy of angiotensin-converting enzyme (ACE) inhibition. Importantly, since new treatments are likely to be used in conjunction with ACE inhibition therapy, the effects of the combination of agents need to be assessed. Adrenomedullin (ADM) is a peptide with potent vasodilator and natriuretic actions. ADM and an ACE inhibitor (captopril) were administered for 3 h both separately and together in eight sheep with heart failure. Both ADM and captopril alone reduced arterial pressure, left atrial pressure (greater with captopril) and peripheral resistance, and increased cardiac output (greater with ADM). Compared with either treatment separately, combined ADM+captopril produced directionally similar but significantly greater changes in all haemodynamic variables (particularly falls in blood pressure). ADM increased renal sodium and creatinine excretion and creatinine clearance, and maintained urine output. Captopril and ADM+captopril reduced creatinine excretion and creatinine clearance, while urine volume and sodium excretion were not significantly altered. Plasma renin activity rose with all active treatments, whereas angiotensin II levels rose during ADM, but fell during captopril and ADM+captopril. Aldosterone was reduced by all active treatments. ADM+captopril reduced plasma noradrenaline (norepinephrine). In conclusion, short-term co-treatment with ADM and an ACE inhibitor produced significantly greater decreases in ventricular filling pressures and cardiac afterload, and increases in cardiac output, compared with either treatment alone. Despite the greater falls in blood pressure (and presumably renal perfusion pressure), renal function was maintained at a level similar to that observed with captopril alone.