Daniel F. Catanzaro

Mechanism of Repetitive Monomorphic Ventricular Tachycardia

BACKGROUND The most common form of idiopathic ventricular tachycardia (VT) is repetitive monomorphic VT (RMVT), which is characterized by frequent ventricular ectopy and salvos of nonsustained VT with intervening sinus rhythm. Unlike most other forms of idiopathic VT, this tachycardia typically occurs at rest and is nonsustained. The mechanism of RMVT is undefined. Because of a common site of origin, the right ventricular outflow tract (RVOT), we hypothesized that RMVT is mechanistically related to paroxysmal sustained, exercise-induced VT, which has been shown to be consistent with cAMP-mediated triggered activity. Therefore, in this study, we sought to identify (1) the mechanism of RMVT at the cellular level by using electropharmacological probes known to activate either stimulatory or inhibitory G proteins and thereby modify intracellular cAMP levels, (2) potential autonomic triggers of RMVT through analysis of heart rate variability, and (3) whether well-characterized somatic activating mutations in the stimulatory G protein, G alpha s, underlie RMVT. METHODS AND RESULTS Twelve patients with RMVT underwent electrophysiological study. Sustained monomorphic VT was reproducibly initiated and terminated with programmed stimulation and/or isoproterenol infusion in 11 of the 12 patients (the other patient had incessant RMVT). Induction of VT demonstrated cycle length dependence and was facilitated by rapid atrial or ventricular pacing. Termination of VT occurred in response to interventions that either lowered stimulated levels of intracellular cAMP (and thus decreased intracellular Ca2+)--ie, adenosine (12 of 12), vagal maneuvers or edrophonium (8 of 9), and beta-blockade (3 of 5)--or directly decreased the slow-inward calcium current--ie, verapamil (10 of 12). Analysis of heart rate variability during 24-hour ambulatory monitoring in 7 patients showed that the sinus heart rate is increased and accelerates before nonsustained VT (P < .05), whereas high-frequency heart rate variability is unchanged. These findings are consistent with transient increases in sympathetic tone preceding nonsustained VT. Finally, myocardial biopsy samples were obtained from the site of origin of the VT (typically the RVOT) and from the right ventricular apex from 9 patients. Genomic DNA was extracted from each biopsy sample, and three exons of G alpha s in which activating mutations have previously been described were amplified by polymerase chain reaction. All sequences from these regions were found to be identical to that of control. CONCLUSIONS Although the arrhythmia occurs at rest, the constellation of findings in idiopathic VT that is characterized by RMVT is consistent with the mechanism of cAMP-mediated triggered activity. Therefore, the spectrum of VT resulting from this mechanism includes not only paroxysmal exercise-induced VT but also RMVT.

Renin is not synthesized by cardiac and extrarenal vascular tissues. A review of experimental evidence.

A comprehensive review of physiological and molecular biological evidence refutes claims for synthesis of renin by cardiac and vascular tissues. Cardiovascular tissue renin completely disappears after binephrectomy. Residual putative reninlike activity, where investigated, has had the characteristics of lysosomal acid proteases. Occasional reports of renin or renin mRNA in vascular and cardiac tissues can be ascribed to failure to remove the kidneys 24 hours beforehand, overloading of detection systems, problems with stringency in identification, and illegitimate transcripts after more than 25 cycles of polymerase chain reaction. Others, using more stringent criteria, have failed to detect cardiac and vascular renin mRNA. Accordingly, a growing number of investigators have concluded that the kidneys are the only source of cardiovascular tissue renin. Although prorenin is secreted from extrarenal tissues as well as from the kidneys, there is no evidence that it is ever converted to renin in the circulation. The kidney is the only tissue with known capacity to convert prorenin to renin and to secrete active renin into the circulation. Accordingly, renin of renal origin determines plasma and hence, extracellular fluid renin levels. In these loci, angiotensin (Ang) I, formed by renin cleavage of circulating and interstitial fluid angiotensinogen, is in turn cleaved by angiotensin converting enzyme, located in plasma and extracellular fluids and on the luminal surface of pulmonary and systemic vascular endothelial cells, to Ang II, which perfuses and bathes the heart and vasculature. Consistent with this model, plasma renin and angiotensin and the antihypertensive action of renin inhibitors, converting enzyme inhibitor, or Ang II antagonists all disappear after binephrectomy. Thus, the plasma renin level, via Ang II formation, determines renin system vasoconstrictor activity, the antihypertensive potential of anti-renin system drugs, and the risk of heart attack in hypertensive patients. This analysis redirects renin research to renal mechanisms that create the plasma renin level, to renal prorenin biosynthesis and its processing to renin, and to their regulated secretion, extracellular distribution, and possible binding to by target tissues. In this context, it is still possible that changes in circulating and interstitial renin substrate or available converting enzyme might exert subtle modulating influences on Ang II formation. However, this analysis redefines the importance of plasma renin measurements to assess clinical situations, because plasma renin is the only known initiator driving the cardiovascular renin-angiotensin system, and its strength can be measured.

Specific prorenin/renin binding (ProBP). Identification and characterization of a novel membrane site.

Renin can be detected in cardiovascular and other tissues but it disappears after bilateral nephrectomy indicating that tissues can take up or bind renal renin from the circulation. If renin uptake is the result of specific binding, plasma prorenin may be a natural antagonist of tissue directed renin-angiotensin systems. To investigate if specific prorenin/renin uptake occurs in rat tissues, binding studies were performed, with rat microsomal membrane preparations using recombinant rat prorenin metabolically labeled with 35S-methionine as a probe. A high affinity binding site for both renin and prorenin was identified. Affinities for prorenin and renin were approximately 200 and 900 pmol/L, respectively. Binding was reversible, saturable, and pH and temperature dependent. The relative binding capacities of membranes from various rat tissues were as follows (fmol/mg): renal cortex (55), liver (54), testis (63), lung (31), brain (18), renal medulla (15), adrenal (17), aorta (7), heart (4), and skeletal muscle (1). Bound prorenin was displaced by rat and human renin or prorenin but not by the prosequence of rat prorenin, angiotensin I or II, rat or human angiotensinogen, the renin inhibitor SQ30697, atrial natriuretic factor, amylase, insulin, bovine serum albumin, hemoglobin, heparin, lysozyme, ovalbumin, cytochrome C, pepsin, pepsinogen, ribonuclease A, mannose-6-phosphate, alpha-methyl mannoside, gonadotropin releasing hormone, or an antibody to hog renin binding protein. these results demonstrate specific binding of prorenin to a site in rat tissues, herein named ProBP, that also binds renin. It is possible that differences in prorenin/renin binding capacity determine the activity of tissue-directed renin-angiotensin systems and that prorenin is a natural antagonist. Alternatively, a prorenin/renin receptor may have been identified that may function by transducing an intracellular signal.

Right ventricular outflow tract tachycardia due to a somatic cell mutation in G protein subunitalphai2.

Idiopathic ventricular tachycardia is a generic term that describes the various forms of ventricular arrhythmias that occur in patients without structural heart disease and in the absence of the long QT syndrome. Many of these tachycardias are focal in origin, localize to the right ventricular outflow tract (RVOT), terminate in response to beta blockers, verapamil, vagal maneuvers, and adenosine, and are thought to result from cAMP-mediated triggered activity. DNA was prepared from biopsy samples obtained from myocardial tissue from a patient with adenosine-insensitive idiopathic ventricular tachycardia arising from the RVOT. Genomic sequences of the inhibitory G protein Galphai2 were determined after amplification by PCR and subcloning. A point mutation (F200L) in the GTP binding domain of the inhibitory G protein Galphai2 was identified in a biopsy sample from the arrhythmogenic focus. This mutation was shown to increase intracellular cAMP concentration and inhibit suppression of cAMP by adenosine. No mutations were detected in Galphai2 sequences from myocardial tissue sampled from regions remote from the origin of tachycardia, or from peripheral lymphocytes. These findings suggest that somatic cell mutations in the cAMP-dependent signal transduction pathway occurring during myocardial development may be responsible for some forms of idiopathic ventricular tachycardia.

Plasma and Renal Prorenin/Renin, Renin mRNA, and Blood Pressure in Dahl Salt-Sensitive and Salt-Resistant Rats

We measured plasma prorenin and renin levels, renal renin mRNA, renal anti-renin and anti-prorenin-prosequence immunoreactivity, and blood pressure in maturing Brookhaven Dahl salt-sensitive (Dahl S) and salt-resistant (Dahl R) rats during 14 days of low (0%), medium (0.4%), or high 4%) NaCl diets. Blood pressure was higher in Dahl S rats and did not increase with high NaCl. Seven-week-old Dahl R rats had twofold and sixfold higher levels of plasma prorenin and renal prosequence immunoreactivity, respectively, which by 9 weeks were the same as in Dahl S rats. The anti-renin antiserum, BR1-5, was found to detect prorenin better than renin; Dahl S rats had suppressed renal anti-renin immunoreactivity relative to Dahl-R rats. Dahl R rats were unresponsive to high NaCl, whereas in Dahl S rats, plasma renin and renal prosequence immunoreactivity fell by 90% (P < .01), renal anti-renin immunoreactivity and renal renin MRNA fell by 35% (P < .05 for both), and plasma prorenin fell by 30% (P = NS). NaCl depletion increased prorenin/renin parameters similarly in both strains. There were direct relationships among all of the prorenin/renin parameters. Between low and high salt diets in Dahl S rats, plasma renin increased 20-fold, plasma total renin (renin plus prorenin) and renal renin mRNA both increased threefold, and plasma prorenin increased twofold. The results indicate that under steady-state conditions, plasma and renal renin/prorenin parameters change concordantly and that plasma total renin (renin plus prorenin) reflects changes in renal renin mRNA. The lower blood pressure of Dahl R rats is associated with later maturation-related declines in plasma and renal prorenin. Suppression of plasma renin may delay the salt-induced blood pressure rise in Dahl S rats. Finally, the renin system and blood pressure of Dahl R rats have remarkable disregard for a high salt diet.

Plasma renin activity in the emergency department and its independent association with acute myocardial infarction.

Elevated plasma renin activity (PRA) is associated with increased risk of future myocardial infarction (MI) in ambulatory hypertensive patients. The present study evaluated the relationship of PRA to the diagnosis of acute MI in patients presenting to an emergency department with suspected acute MI. PRA was measured upon entry to the emergency department, before any acute treatment, as part of the standard evaluation of 349 consecutive patients who were hospitalized for suspected MI. Diagnosis of acute MI was confirmed in 73 patients, and ruled out in 276. They did not differ in age (65.9 +/- 2 v 66.1 +/- 1 years), systolic (143 +/- 4 v 140 +/- 2 mm Hg), or diastolic (81 +/- 2 v 81 +/- 1 mm Hg) pressures. Median PRA was 2.7-fold higher in acute MI (0.89 v 0.33 ng/L/s; P < .001). In a multivariate analysis controlling for other cardiac risk factors and prior drug therapy, PRA as a continuous variable was the predominant independent factor associated with acute MI (P < .0001), followed by white race (P = .002) and history of hypertension (P = .047). The height of the PRA level upon entry to the emergency department was directly and independently associated with the diagnosis of acute MI. These new findings extend earlier reports because they encompass acute MI patients, include both hypertensive and normotensive patients, and control for potentially confounding variables. Based on these observations, a randomized clinical trial is warranted to determine whether measurement of PRA in acute MI could refine the process by which treatments are applied.

Appropriate Regulation of Renin and Blood Pressure in 45-kb Human Renin/Human Angiotensinogen Transgenic Mice

The renin-angiotensin system is normally subject to servo control mechanisms that suppress plasma renin levels in response to increased blood pressure and increase plasma renin levels when blood pressure falls. In most species, renin is rate limiting, and angiotensinogen circulates at a concentration close to the Km, so varying the concentration of either can affect the rate of angiotensin formation. However, only the plasma renin level responds to changes in blood pressure and sodium balance to maintain blood pressure homeostasis. Therefore, the high plasma human renin levels and the hypertension of mice and rats containing both human renin and angiotensinogen transgenes indicate inappropriate regulation of renin and blood pressure. These anomalies led us to develop new lines of transgenic mice with a longer human renin gene fragment (45 kb) than earlier lines (13 to 15 kb). Unlike their predecessors, the 45-kb hREN mice secrete human renin only from the kidneys, and both the human and mouse renins respond appropriately to physiological stimuli. To determine whether blood pressure is also regulated appropriately, we crossed these new 45-kb hREN mice with mice containing the human angiotensinogen gene. All doubly transgenic mice were normotensive like their singly transgenic and nontransgenic littermates. Moreover, among doubly transgenic mice, both human and mouse plasma renin concentrations were suppressed relative to the singly transgenic 45-kb hREN mice. These findings demonstrate the importance of appropriate cell and tissue specificity of gene expression in constructing transgenic models and affirm the pivotal role played by renal renin secretion in blood pressure control.

Pregnancy-Induced Changes in Renin Gene Expression in Mice

Abstract A puzzling feature of the renin-angiotensin system during pregnancy is the appearance in the maternal circulation of a large increase in the concentration of prorenin and renin. The physiologic role of these changes is not understood. We determined that high levels of renin protein occur in the circulation of pregnant mice, thereby establishing the mouse as a valuable model for understanding gestation-induced changes in the renin-angiotensin system. We used the murine model to show that high levels of renin gene expression occur at the mother-fetus interface, first in maternal decidua and subsequently in placentas. These results were obtained using ICR mice that have 2 related renin genes, Ren1 and Ren2. We also examined renin gene expression in C57Bl/6 mice that have only the Ren1 gene. In these mice, very little renin gene expression was observed in placentas but instead was upregulated in kidneys during pregnancy. In both ICR and C57Bl/6 mice, there is an increase in renin protein in the maternal circulation during pregnancy. However, these mice differ with regard to gestation-induced sites of increased renin gene expression. These studies suggest that mice are a convenient and valuable model for studying renin gene expression during pregnancy.

Physiological Relevance of Renin/Prorenin Binding and Uptake

There is compelling physiological evidence of binding and uptake of renin and prorenin in tissues. A number of molecules with the ability to bind renin and prorenin have been identified and have been characterized to varying degrees. It remains unclear, however, just how many renin/prorenin binding proteins and receptors exist and what their physiological functions may be. The possible functions of renin/prorenin binding and uptake are manifold, and include clearance of renin and prorenin from the circulation, local generation of angiotensins, activation of prorenin on the cell surface, trafficking of prorenin between cellular and extracellular compartments as part of a complex processing machinery, and signal transduction both via direct receptor mediated signaling, and via modulation of O-linkage of N-acetyl-glucosamine to cellular proteins. Some of these functions may involve single renin/prorenin binding sites or receptors, while others may require multiple binding sites and receptors. This review describes the physiological studies that have provided evidence of renin/prorenin uptake from the circulation, summarizes our knowledge of renin/prorenin binding proteins and receptors, and postulates new roles for renin/prorenin binding and uptake in tissues.

Identical hemodynamic and hormonal responses to 14-day infusions of renin or angiotensin II in conscious rats

Objective To investigate whether plasma angiotensin II (Ang II) determines the effects of the renin-angiotensin system or whether tissue uptake of renin and localized production of Ang II might account for any cardiovascular, renal, hormonal or drinking effect of circulating renin. Design Intravenous infusions of renin (0.6 ng/min; n = 10) and Ang II (3.5 ng/min; n = 10) that produce similar plasma Ang II levels were compared for 2 weeks with vehicle (n = 7) in conscious rats after a 1-week control period. Mean arterial pressure (MAP) and the heart rate were measured continuously. Hormones and renal function were measured twice weekly. Plasma Ang II and recovery data were measured in seven additional rats. Results In renin and Ang II-infused rats, respectively, plasma Ang II increased similarly from 4.5 ± 0.8 and 4.4 ± 0.9 to 10.8 ± 0.7 and 10.6 ± 0.7 pg/ml and declined similarly in the second week to 7.0 ± 1.1 and 7.0 ± 1.5 pg/ml. Plasma renin increased from 4.2 ± 0.7 to 21.7 ± 1.3 and fell from 5.9 ± 0.5 to 0.6 ± 0.2 ng/ml per h respectively. Plasma prorenin fell similarly (> 70%); angiotensinogen was unchanged. MAP rose initially by 25.6 ± 1.2 and 23.3 ± 0.9 mmHg and by an additional 21.1 ± 2.4 and 27.4 ± 1.8 mmHg on days 5–8. The heart rate fell gradually but transiently by -11% in both. Although the initial MAP rise was slower in renin-infused rats (P < 0.05) MAP returned to baseline within 2 h after both infusions were stopped. Changes in renal vascular resistance, renal blood flow, glomerular filtration rate, urinary sodium, potassium and water excretion and water intake were not significantly different between renin-and Ang II-infused rats. Conclusions Intravenous infusions of low doses of renin or Ang II into conscious rats increase MAP identically. MAP increases in two phases 5–8 days apart, in coordination with transient falls in the heart rate. Reninand Ang II-induced chronic hypertension are identically sustained by very small increases in plasma Ang II. Blood pressure increases more slowly with renin infusions, consistent with tissue binding. Notwithstanding, no evidence was obtained for a physiological role of tissue-bound renin in causing the cardiovascular, renal, hormonal and drinking responses measured in this study.