Mara Ferrandi

Left Ventricular Mass, Stroke Volume, and Ouabain-Like Factor in Essential Hypertension

Many patients with essential hypertension (EH) exhibit increased left ventricular mass. Similarly, elevated circulating levels of an endogenous ouabainlike factor (OLF) have been described in some but not all patients with EH. Moreover, ouabain has a hypertrophic influence on isolated cardiac myocytes. Accordingly, we investigated relationships among plasma OLF, left ventricular mass, and cardiac function in patients with EH. Plasma OLF was determined in 110 normotensive subjects and 128 patients with EH. Echocardiographic parameters and humoral determinants were measured in EH. Plasma OLF levels were increased (P<0.0001) in patients with EH (377+/-19 pmol/L) versus normotensive (253+/-53 pmol/L) subjects. The distribution of plasma OLF was unimodal in normotensives, whereas it was bimodal in EH. Twenty-four-hour diastolic ambulatory blood pressure was slighter higher in EH with high OLF compared with EH with normal OLF (93.2+/-1.14 versus 89.4+/-1.33 mm Hg, P=0.03). Left ventricular mass index and stroke volume in EH with high OLF were greater than in EH with normal OLF (101.9+/-3.3 versus 86.1+/-2.5 g/m(2), P=0.0003, and 57.10+/-1.48 versus 52.30+/-1.14 mL/m(2), P=0. 02, respectively), although heart rate was slower (74.2+/-1.3 versus 80.5+/-1.3 bpm, P=0.005). Multiple regression analysis that tested the influence of body mass index, age, gender, 24-hour blood pressure, and OLF on left ventricular mass revealed independent contributions of systolic (13.2%) and diastolic (12.4%) blood pressure and plasma OLF (11.6%) to left ventricular mass. We conclude that approximately 50% of patients with uncomplicated EH have elevated-high circulating OLF levels, higher diastolic blood pressure, greater left ventricular mass and stroke volume, and reduced heart rate. We propose that the OLF affects cardiovascular function and structure and should be considered as a factor that contributes to the risk of morbid events.

Adducin- and Ouabain-Related Gene Variants Predict the Antihypertensive Activity of Rostafuroxin, Part 2: Clinical Studies

Five genetic variants that affect Na,K-ATPase interactions predict the blood pressure response to rostafuroxin but not to losartan and hydrochlorothiazide. Help for Hypertension As if changing its mind about how best to detoxify the body, the kidney first secretes a filtrate that contains almost everything in the blood but then recaptures much of it by pumping essential water, salts, and other molecules back in. The Na+, K+-ATPase, or sodium pump, recaptures sodium salts, and because Na+ is the prime determinant of extracellular fluid volume in the body, regulation of this pump controls blood pressure. Now a pair of papers describes how an antihypertension drug can correct abnormal sodium pumping and how this understanding of the drug’s mechanism points to a genetic signature that can predict whether a patient will respond to the drug. One cause of hypertension is a particular variant(s) of the protein adducin, a modulator of protein exposure on the cell surface that stimulates the sodium pump; a second is high concentrations of endogenous ouabain, an activating ligand for the pump. Both factors abnormally enhance the pump function through the triggering of the Src signaling pathway. Rostafuroxin, a derivative of digitoxigenin, acts as an antihypertensive agent by interfering with both of these ways to activate the sodium pump, preventing an increase in renal tubular Na+ transport and the resulting hypertension. In the first of the companion papers (Ferrandi et al.), the authors explore how rostafuroxin accomplishes its pressure-lowering feat. They show that the drug inhibits the Na+, K+ ATPase-Src-EGFR-ERK signaling activated by mutant adducin or ouabain, normalizing renal cell sodium transport, in two different rodent models of hypertension and in human cells. Upon closer examination of rostafurotoxin’s effects on Src-related phosphorylation in vitro, it became clear that the drug disrupts the ability of the variant adducin and the oubain-bound sodium pump to bind and activate Src at its SH2 domain. In the second of the companion papers (Lanzani et al.), the authors apply these results to patients by examining genetic variants that control the mechanisms of hypertension explored in the first paper. Lanzani et al. inspected genetic alterations in genes that encode enzymes that control ouabain synthesis and transport as well as two variants of adducin. They then tested the ability of these genetic variants to predict the response to rostafuroxin in a group of never-before treated patients with hypertension. Individuals who carried certain combinations of these genetic variants responded well to rostofuroxin, displaying a mean drop in the placebo-corrected blood pressure of about 14 mmHg, a clinically meaningful value. The same genetic signature did not predict the blood pressure response to other antihypertensive drugs with different mechanisms of action. The authors suggest that this genetic signature may exist in about a quarter of hypertensive patients. Finally, rostfuroxin may do more than lower blood pressure. Organ damage is known to be a downstream effect of an overactive Src signaling pathway—one of the byproducts of the hypertension mechanisms studied in this pair of papers. Because rostafuroxin interferes with Src signaling, the drug may curb the secondary damage to the heart, kidney, and brain caused by high blood pressure. Thus the kidney’s seemingly schizophrenic filtering actually represents a multilevel, fine-tuned control of the sodium pump as a means of managing blood pressure. Rostafuroxin can selectively correct hypertension in patients whose pumping mechanism is out of kilter, an advance toward personalized treatment of high blood pressure. Twenty years of genetic studies have not contributed to improvement in the clinical management of primary arterial hypertension. Genetic heterogeneity, epistatic-environmental-biological interactions, and the pathophysiological complexity of hypertension have hampered the clinical application of genetic findings. In the companion article, we furnished data from rodents and human cells demonstrating two hypertension-triggering mechanisms—variants of adducin and elevated concentrations of endogenous ouabain (within a particular range)—and their selective inhibition by the drug rostafuroxin. Here, we have investigated the relationship between variants of genes encoding enzymes for ouabain synthesis [LSS (lanosterol synthase) and HSD3B1 (hydroxy-δ-5-steroid dehydrogenase, 3β- and steroid δ-isomerase 1)], ouabain transport {MDR1/ABCB1 [ATP-binding cassette, sub-family B (MDR/TAP), member 1]}, and adducin activity [ADD1 (adducin 1) and ADD3], and the responses to antihypertensive medications. We determined the presence of these variants in newly recruited, never-treated patients. The genetic profile defined by these variants predicted the antihypertensive effect of rostafuroxin (a mean placebo-corrected systolic blood pressure fall of 14 millimeters of mercury) but not that of losartan or hydrochlorothiazide. The magnitude of the rostafuroxin antihypertensive effect was twice that of antihypertensive drugs recently tested in phase 2 clinical trials. One-quarter of patients with primary hypertension display these variants of adducin or concentrations of endogenous ouabain and would be expected to respond to therapy with rostafuroxin. Because the mechanisms that are inhibited by rostafuroxin also underlie hypertension-related organ damage, this drug may also reduce the cardiovascular risk in these patients beyond that expected by the reduction in systolic blood pressure alone.

Evidence for an interaction between adducin and Na+-K+-ATPase: relation to genetic hypertension

Adducin point mutations are associated with genetic hypertension in Milan hypertensive strain (MHS) rats and in humans. In transfected cells, adducin affects actin cytoskeleton organization and increases the Na+-K+-pump rate. The present study has investigated whether rat and human adducin polymorphisms differently modulate rat renal Na+-K+-ATPase in vitro. We report the following. 1) Both rat and human adducins stimulate Na+-K+-ATPase activity, with apparent affinity in tens of nanomolar concentrations. 2) MHS and Milan normotensive strain (MNS) adducins raise the apparent ATP affinity for Na+-K+-ATPase. 3) The mechanism of action of adducin appears to involve a selective acceleration of the rate of the conformational change E2 (K) → E1 (Na) or E2(K) ⋅ ATP → E1Na ⋅ ATP. 4) Apparent affinities for mutant rat and human adducins are significantly higher than those for wild types. 5) Recombinant human α- and β-adducins stimulate Na+-K+-ATPase activity, as do the COOH-terminal tails, and the mutant proteins display higher affinities than the wild types. 6) The cytoskeletal protein ankyrin, which is known to bind to Na+-K+-ATPase, also stimulates enzyme activity, whereas BSA is without effect; the effects of adducin and ankyrin when acting together are not additive. 7) Pig kidney medulla microsomes appear to contain endogenous adducin; in contrast with purified pig kidney Na+-K+-ATPase, which does not contain adducin, added adducin stimulates the Na+-K+-ATPase activity of microsomes only about one-half as much as that of purified Na+-K+-ATPase. Our findings strongly imply the existence of a direct and specific interaction between adducin and Na+-K+-ATPase in vitro and also suggest the possibility of such an interaction in intact renal membranes.Adducin point mutations are associated with genetic hypertension in Milan hypertensive strain (MHS) rats and in humans. In transfected cells, adducin affects actin cytoskeleton organization and increases the Na(+)-K(+)-pump rate. The present study has investigated whether rat and human adducin polymorphisms differently modulate rat renal Na(+)-K(+)-ATPase in vitro. We report the following. 1) Both rat and human adducins stimulate Na(+)-K(+)-ATPase activity, with apparent affinity in tens of nanomolar concentrations. 2) MHS and Milan normotensive strain (MNS) adducins raise the apparent ATP affinity for Na(+)-K(+)-ATPase. 3) The mechanism of action of adducin appears to involve a selective acceleration of the rate of the conformational change E(2) (K) --> E(1) (Na) or E(2)(K). ATP --> E(1)Na. ATP. 4) Apparent affinities for mutant rat and human adducins are significantly higher than those for wild types. 5) Recombinant human alpha- and beta-adducins stimulate Na(+)-K(+)-ATPase activity, as do the COOH-terminal tails, and the mutant proteins display higher affinities than the wild types. 6) The cytoskeletal protein ankyrin, which is known to bind to Na(+)-K(+)-ATPase, also stimulates enzyme activity, whereas BSA is without effect; the effects of adducin and ankyrin when acting together are not additive. 7) Pig kidney medulla microsomes appear to contain endogenous adducin; in contrast with purified pig kidney Na(+)-K(+)-ATPase, which does not contain adducin, added adducin stimulates the Na(+)-K(+)-ATPase activity of microsomes only about one-half as much as that of purified Na(+)-K(+)-ATPase. Our findings strongly imply the existence of a direct and specific interaction between adducin and Na(+)-K(+)-ATPase in vitro and also suggest the possibility of such an interaction in intact renal membranes.

Ouabain-like Factor Quantification in Mammalian Tissues and Plasma Comparison of Two Independent Assays

The resolution of controversies that concern the detectability of an endogenous ouabain-like factor (OLF) in mammalian tissues and plasma was approached by the application of a standardized method for its extraction and quantification. Two independent assays were used to quantify the OLF: (1) a radioimmunoassay, which used a polyclonal anti-ouabain antiserum, and (2) a radioenzymatic assay based on the inhibition of dog kidney Na+,K+-ATPase. Plasma and tissues were obtained from the Milan hypertensive strain (MHS) and the Milan normotensive strain (MNS) of rats and from healthy human volunteers. Results indicate that (1) a single high-performance liquid chromatography (HPLC) fraction identical to that of ouabain was identified by both assay methods in the rat hypothalamus and hypophysis and in both rat and human plasma; (2) dilution curves of OLF and standard ouabain were parallel and with a similar Kd, both in radioimmunoassay (3 nmol/L) and ATPase assay (14 nmol/L); (3) after HPLC, OLF was similarly quantified by the two methods in the hypothalamus, hypophysis, adrenals, and plasma of rats and in human plasma; (4) OLF was present in larger amounts in the hypothalamus, hypophysis, and plasma of MHS rats than that of MNS rats; (5) the HPLC fraction of human plasma was quantified similarly by both assays (range, 60 to 150 pmol/L); (6) recovery of standard ouabain in pre-HPLC plasma extracts was approximately 90%; and (7) pre-HPLC OLF concentrations in human plasma ranged between 0.05 and 0.75 nmol/L. Rat cerebral tissues and both rat and human plasma contained measurable amounts of OLF, which were quantified similarly by radioimmunoassay and ATPase assay, both before and after HPLC fractionation. The increased MHS tissue and plasma levels of OLF are in keeping with the pathogenetic role of this factor in MHS hypertension.

Endogenous ouabain and hemodynamic and left ventricular geometric patterns in essential hypertension

We sought to evaluate the relationships among circulating levels of an endogenous ouabain-like factor (EO) and systemic hemodynamics and left ventricular (LV) geometry in patients with recently diagnosed essential hypertension. We selected 92 never-treated patients with essential hypertension. Blood samples were drawn for estimation of plasma EO (radioimmunoassay) and subjects underwent echocardiographic examination to evaluate LV end-systolic and end-diastolic wall thickness and internal dimensions. LV volumes, stroke volume, cardiac output, total peripheral resistance, LV mass, and relative wall thickness were calculated, and all except the last parameter were indexed by body surface area. LV mass also was indexed by height. On the basis of the values of LV mass index (body surface area or height) and relative wall thickness, subjects were divided into groups with either normal geometry, concentric remodeling, concentric hypertrophy, or eccentric nondilated hypertrophy. In the study population as a whole, circulating EO levels were significantly and directly correlated with mean blood pressure (r = 0.21, P = .048), relative wall thickness (r = 0.34, P = .001), and total peripheral resistance index (r = 0.37, P = .0003). Plasma EO also was significantly and inversely correlated with LV end-diastolic volume index (r = -0.32, P = .002), stroke index (r = -0.34, P = .0009), and cardiac index (r = -0.35, P = .0007). In multiple regression analysis, plasma EO was an independent correlate of total peripheral resistance index, cardiac index, and relative wall thickness. Regardless of the indexation method used for LV mass, plasma EO was higher in patients with concentric remodeling than in those with either normal geometry or concentric hypertrophy. Plasma EO tended to be higher (indexation by body surface area) or was significantly higher (indexation by height) in subjects with concentric remodeling than in those with eccentric nondilated hypertrophy. Patients with concentric remodeling showed the highest total peripheral resistance index and the lowest cardiac index. Our data suggest that EO plays a role in regulating systemic hemodynamics and LV geometry in patients with essential hypertension.

Plasma Ouabain-Like Factor During Acute and Chronic Changes in Sodium Balance in Essential Hypertension

Abstract—An ouabain-like factor has been implicated repeatedly in salt-sensitive hypertension as a natriuretic agent. However, the response of plasma ouabain-like factor to acute and chronic variation of body sodium is unclear. We studied 138 patients with essential hypertension who underwent an acute volume expansion/contraction maneuver (2 days) and 20 patients who entered a blind randomized crossover design involving chronically controlled sodium intake and depletion (170 to 70 mmol/d; 2 weeks each period). In both studies, plasma levels of ouabain-like factor were higher during sodium depletion (acute: 338.8±17.4 and 402.7±22.8 pmol/L for baseline and low sodium, respectively, P <0.01; chronic: 320.4±32.0 versus 481.0±48.1 pmol/L, P =0.01). No significant change in plasma ouabain-like factor was observed after a 2-hour saline infusion (333.4±23.9 pmol/L) or controlled sodium (402.1±34.9 pmol/L). When patients were divided into salt-sensitive or salt-resistant groups, no differences in plasma ouabain-like factor were observed in the 2 groups at baseline or in response to the 2 protocols: salt resistant (n=69, 340.1±25.9 pmol/L) versus salt sensitive (n=69, 337.4±23.6 pmol/L) and chronic salt resistant (n=11, 336.0±53.2) versus salt sensitive (n=9, 301.1±331.4 pmol/L). However, circulating ouabain-like factor was increased by sodium depletion in both groups. These results demonstrate that circulating ouabain-like factor is raised specifically by maneuvers that promote the loss of body sodium. Acute expansion of body fluids with isotonic saline is not a stimulus to plasma ouabain-like factor. Moreover, basal levels of plasma ouabain-like factor do not differ among patients with salt-sensitive or salt-resistant hypertension. Taken together, these new results suggest that ouabain-like factor is involved in the adaptation of humans to sodium depletion and argue against the hypothesis that ouabain-like factor is a natriuretic hormone.

Renal Na,K-ATPase in Genetic Hypertension

Milan hypertensive rats (MHS) develop hypertension because of a primary renal alteration. Both apical and basolateral sodium transport are faster in membrane vesicles derived from renal tubules of MHS than in those of Milan normotensive control rats (MNS). These findings suggest that the increased renal sodium retention and concomitant development of hypertension in MHS may be linked to an altered transepithelial sodium transport. Since this transport is mainly under the control of the Na-K pump, we investigated whether an alteration of the enzymatic activity and/or protein expression of the renal Na,K-ATPase is detectable in prehypertensive MHS. We measured the Na,K-ATPase activity, Rb+ occlusion, turnover number, alpha 1- and beta 1-subunit protein abundance, and alpha 1 and beta 1 mRNA levels in microsomes from renal outer medulla of young (prehypertensive) and adult (hypertensive) MHS and in age-matched MNS. In both young and adult MHS, the Na,K-ATPase activity was significantly higher because of an enhanced number of active pump sites, as determined by Rb+ occlusion maximal binding. The higher number of pump sites was associated with a significant pretranslational increase of alpha 1 and beta 1 mRNA levels that preceded the development of hypertension in MHS. Since a molecular alteration of the cytoskeletal protein adducin is genetically associated with hypertension in MHS and is able to affect the actin-cytoskeleton and Na-K pump activity in transfected renal cells, we propose that the in vivo upregulation of Na-K pump in MHS is primary and linked to a genetic alteration of adducin.

Red blood cell abnormalities and spontaneous hypertension in the rat. A genetically determined link.

The significance of the erythrocyte abnormalities described in rats and humans with spontaneous hypertension is far from clear. This study, in two highly inbred strains of rats, was designed to evaluate whether these abnormalities are primary and thus genetically related to hypertension. The Milan hypertensive strain (MHS) and its normotensive control strain (MNS) were used to carry out two types of experiments. In two groups of lethally irradiated (MHS X MNS) F1 hybrids, bone marrow from MHS or MNS was transplanted. The differences in red cell function between the recipients of bone marrow from MHS and recipients of bone marrow from MNS were similar to those existing between the parental donor MHS and MNS: Na+-K+ cotransport was increased (p less than 0.02) and intracellular Na+ content (p less than 0.05) and cell volume (p less than 0.02) were decreased in MHS. The same pattern was observed when this experiment was repeated in different groups of F1 hybrids. In individuals of the segregating F2 population, obtained by crossing the (MHS X MNS) F1 hybrids, there was a positive correlation (p less than 0.001) between the red blood cell Na+-K+ cotransport and the mean blood pressure. These results indicate that the erythrocyte abnormalities may well be genetically associated with the primary cause of spontaneous hypertension in rats. Because of the many similarities demonstrated when young prehypertensive MHS or humans prone to develop hypertension are compared with their respective controls, it is possible that the findings described here in rats are relevant to human essential hypertension.

Endogenous ouabain in cardiovascular function and disease

An endogenous ouabain has been isolated and conclusively identified from several mammalian tissues, including human plasma, by a number of independent laboratories. Substantial evidence from independent laboratories in several continents is consistent with an adrenal source for most if not all of the circulating endogenous ouabain. Accumulating evidence suggests that circulating levels of endogenous ouabain in humans are modulated by dietary salt and chronic volume status. Endogenous ouabain is linked significantly with vascular function in hypertension and likely impacts the pathogenesis of heart and renal failure. Moreover, the molecular mechanism of endogenous ouabain-linked hypertension involves the sodium pump/sodium–calcium exchange duet. The outstanding analytical issues include the elucidation of distal events in the biosynthetic pathway for endogenous ouabain and identification of molecular mechanisms that regulate its secretion and clearance.

Relationship between erythrocyte volume and sodium transport in the Milan hypertensive rat and age-dependent changes

The relationship between differences in red blood cell (RBC) volume and ion transport across the erythrocyte cell membrane were investigated in the Milan Hypertensive (MHS) and Milan Normotensive (MNS) rat strains, under different experimental conditions and during ageing. The results obtained indicate that: the difference in Na+/K+ cotransport between MHS and MNS disappear when the RBC volume of the two strains becomes equal under hypotonic swelling; MHS RBCs are osmotically more fragile than those of MNS, probably because of a different membrane structure rather than a different amount of membrane surface, and the smaller volume and the lower Na+ content of MHS RBCs are maintained throughout the life span, while Na+/K+ pump activity and Na+/K+ cotransport undergo age-dependent changes, related to the development of hypertension. All these findings suggest that a primary abnormality of the cell membrane structure of MHS, probably located in the cytoskeleton, is responsible for the cell functional alterations that we previously demonstrated to be genetically associated with MHS hypertension.