High salt diet decreases longevity in the spontaneously hypertensive rat

Combined renin-angiotensin system blockade and dietary sodium restriction impairs cardiomyocyte contractility

INTRODUCTION

Blockade of the renin-angiotensin system (RAS) by combined angiotensin-converting enzyme inhibitor and angiotensin type 1 receptor (AT(1)) antagonist treatment with reduced dietary sodium intake produces suppression of cardiac growth and regression of cardiac hypertrophy. The purpose of this study was to investigate whether cardiac growth suppression by combined RAS blockade under conditions of dietary sodium restriction is associated with cardiomyocyte atrophy and contractile dysfunction and whether this intervention modifies cardiomyocyte inotropic responsiveness to angiotensin II (Ang II).

METHODS

Rats were fed a high (4% w/w) or low (0.2% w/w) NaCl diet for six days. Both groups were then given a combined intraperitoneal injection of perindopril (6 mg/kg/day) and losartan (10 mg/kg/day) with maintained dietary treatment for another seven days. At the end of the treatment period, animals were anaesthetised and their hearts were removed and weighed. Left ventricular cardiomyocytes were isolated by enzymatic dissociation and cell dimensions were evaluated. A line scan camera and digital imaging technique were used to assess cardiomyocyte contraction and inotropic responses to exogenous Ang II (10 to 10(-8) M).

RESULTS

Dietary treatment alone had no effect on body growth, whereas combined RAS blockade suppressed somatic growth in the low sodium (LS) group, compared with the high sodium (HS) group. This growth suppression in the LS group was also evident in the heart at the organ and cellular level. Studies of cardiomyocyte contraction showed that myocytes from the LS group exhibited contractile instability and depression of contractile performance. Compared with the HS group, myocytes from the LS group showed a significant reduction in maximum cell shortening (6.40+0.17 vs. 7.32+0.16% resting length, p<0.05), and maximum rate of shortening (3.85+0.14 vs. 4.29+0.11 cell length/ms, p<0.05). Myocytes of the HS group exhibited negative inotropic responses to Ang II at all concentrations tested, with a significant reduction in maximum cell shortening by 11 16% after 12 minutes peptide exposure (p<0.05 vs. non-treated control). In comparison, Ang II elicited both positive and negative responses in myocytes from the LS group, with a predominant negative inotropic effect.

CONCLUSIONS

This study provides evidence that combined RAS blockade treatment under restricted sodium intake conditions can impair cardiomyocyte contractile function in association with cardiomyocyte growth suppression. Chronic RAS blockade qualitatively alters the intrinsic inotropic status and responsiveness of ventricular cardiomyocytes, and this shift is further modulated by dietary sodium intake conditions.

Interactions between sodium and angiotensin

1. Increased sodium intake causes decreased formation of angiotensin (Ang) II and increased AngII causes increased Na+ retention. 2. Increased sodium intake and increased AngII causes cardiac hypertrophy, but decreased sodium intake regresses cardiac hypertrophy despite high AngII levels. Likewise, decreased Na+ and blockers of the renin-angiotensin system (RAS) in neonatal rats have similar effects on subsequent blood pressure development. 3. Cardiac hypertrophy due to renal hypertension does not regress when the RAS is blocked and rats are on a high salt intake. Likewise, sodium restriction alone does not cause regression; combination of reduced NaCl intake and RAS blockade is required. 4. High doses of perindopril and losartan in combination cause a syndrome in rats on 0.2% NaCl that leads to profound hypotension, polyuria, renal impairment and involution of the heart and death. This is reversed or prevented by a high (4%) NaCl intake, which also prevents the plasma angiotensinogen depletion that occurs with combined blockade on 0.2% NaCl intake. 5. Intake of NaCl and AngII interact at many levels. It is postulated that there is an important interaction at the cellular level that can explain the above events.

Effects of combined administration of ACE inhibitor and angiotensin II receptor antagonist are prevented by a high NaCl intake

BACKGROUND

To prevent the action of angiotensin II by blockade with either an angiotensin converting enzyme inhibitor (ACE I) or an angiotensin receptor antagonist (ARA) is difficult due to the physiological compensations. Combined therapy with both drugs may enable complete blockade, and in rats in high doses this has produced a syndrome that results in death.

OBJECTIVE

To determine the effect of combined blockade using losartan (10 mg/kg per day) and perindopril (6 mg/kg per day) on blood pressure, cardiac growth, renal function and behaviour, and to determine how this is influenced by different salt intakes in normotensive Sprague Dawley rats.

METHODS

Rats were fed an 0.2 or 4% NaCl diet and received the above drugs intraperitoneally. Blood pressure was measured by telemetry. Cardiac weight was measured after 10 days of therapy. Renal function was assessed by plasma creatinine and electrolytes, plasma renin and angiotensinogen concentrations were measured.

RESULTS

On 0.2% NaCl intake, combined blockade lowered blood pressure progressively; at day 7, rats on 0.2% NaCl developed a syndrome of listlessness and failure to eat which led to loss of weight and death. Cardiac size was dramatically reduced. Plasma creatinine was elevated to 50% above normal. There was a polyuria. The syndrome was reversed by adding NaCl to the drinking water or prevented in rats on a 4% NaCl intake. In rats on 0.2% NaCl plasma renin rose dramatically with medication and angiotensinogen became depleted. Haematocrit in all groups of rats did not differ.

CONCLUSION

Combined blockade of the renin-angiotensin system can cause death in rats on a reduced NaCl intake. This was prevented by a high salt intake. The syndrome may result from depletion of angiotensinogen and the failure to synthesize sufficient angiotensin II that may be critical for normal cardiac growth and function and critical for survival.

Regression of cardiac hypertrophy in the SHR by combined renin-angiotensin system blockade and dietary sodium restriction

Altered operation of the renin-angiotensin-aldosterone system (RAAS) and dietary sodium intake have been identified as independent risk factors for cardiac hypertrophy. The way in which sodium intake and the operation of the renin-angiotensin-aldosterone system interact in the pathogenesis of cardiac hypertrophy is poorly understood. The aims of this study were to investigate the cardiac effects of the renin-angiotensin system (RAS) blockade in the spontaneously hypertensive rat (SHR), using co-treatment with an angiotensin II receptor blocker (ARB) and an angiotensin-converting enzyme (ACE) inhibitor with different sodium intakes. Our experiments with SHR show that, at high levels of sodium intake (4.0%), aggressive RAS blockade treatment with candesartan (3 mg/kg) and perindopril (6 mg/kg) does not result in regression of cardiac hypertrophy. In contrast, RAS blockade coupled with reduced sodium diet (0.2%) significantly regresses cardiac hypertrophy, impairs animal growth and is associated with elevated plasma renin and dramatically suppressed plasma angiotensinogen levels. Histological analyses indicate that the differential effect of reduced sodium on heart growth during RAS blockade is not associated with any change in myocardial interstitial collagen, but reflects modification of cellular geometry. Dimensional measurements of enzymatically-isolated ventricular myocytes show that, in the RAS blocked, reduced sodium group, myocyte length and width were decreased by about 16—19% compared with myocytes from the high sodium treatment group. Our findings highlight the importance of `titrating' sodium intake with combined RAS blockade in the clinical setting to optimise therapeutic benefit.

The renin-angiotensin system and the heart: beyond 2000

Renin-angiotensin is both a circulatory and a local tissue system. However, in most circumstances, renin present in the heart and blood vessels is taken up from the plasma, and the kidney is the prime source of this renin. Tissues can then modulate and control the production of angiotensin II. In various organs, angiotensin II has local actions. In the heart, working through the AT1 receptor, it increases contractility and may cause cardiocyte hypertrophy. Indirectly, the heart is also very much affected by the vascular actions of angiotensin II. However, the net result on the heart is the product of an important interaction between a large number of factors. There is little doubt that an inappropriately high plasma (and tissue) level of renin, related to sodium balance, is associated with increased left ventricular hypertrophy and cardiovascular complications. The genetic approach will lead to an understanding of genomic risk factors in hypertension and may identify control systems--at present unknown--which will lead to a new approach to the prevention of cardiovascular death. It is, however, unlikely that such a factor will clearly predict an individual's prognosis, but it will, rather, identify groups at risk. Constellations of genomic interactions with multiple environment factors reduce this power. Modification of the response to angiotensin II using present treatment, or interrupting the response at more distal sites, may enable us to achieve the beneficial effects on cardiac hypertrophy without the detrimental effects.