Transgenic mice overexpressing human KvLQT1 dominant-negative isoform. Part I: Phenotypic characterisation.

OBJECTIVES: The KCNQ1 gene encodes the KvLQT1 potassium channel, which generates in the human heart the slow component of the cardiac delayed rectifier current, I(Ks). Mutations in KCNQ1 are the most frequent cause of the congenital long QT syndrome. We have previously cloned a cardiac KCNQ1 human isoform, which exerts a strong dominant-negative effect on KvLQT1 channels. We took advantage of this dominant-negative isoform to engineer an in vivo model of KvLQT1 disruption, obtained by overexpressing the dominant-negative subunit under the control of the alpha-myosin heavy chain promoter. RESULTS: Three different transgenic lines demonstrated a phenotype with increasing severity. Functional suppression of KvLQT1 in transgenic mice led to a markedly prolonged QT interval associated with sinus node dysfunction. Transgenic mice also demonstrated atrio-ventricular block leading to occasional Wenckebach phenomenon. The atrio-ventricular block was associated with prolonged AH but normal HV interval in His recordings. Prolonged QT interval correlated with prolonged action potential duration and with reduced K(+) current density in patch-clamp experiments. RNase protection assay revealed remodeling of K(+) channel expression in transgenic mice. CONCLUSIONS: Our transgenic mouse model suggests a role for KvLQT1 channels not only in the mouse cardiac repolarisation but also in the sinus node automaticity and in the propagation of the impulse through the AV node.

Expression of laminin alpha2 chain during normal and pathological growth of myocardium in rat and human.

OBJECTIVES: Fibrosis is a classical feature of cardiac hypertrophy. To date changes within the basal lamina during normal and pathological cardiac growth have been poorly investigated. The goal of the present study was to determine if the expression of the muscle specific subunit of merosin (laminin alpha2 chain) together with that of fibronectin (FN) is modified in the diseased human heart. Laminin alpha2 chain expression was also investigated during physiological and pathological cardiac growth in the rat. METHODS: In ten normal human hearts and ten hearts with idiopathic dilated cardiomyopathy (IDCM), the laminin-alpha2 and FN mRNA levels were quantified by slot-blot using total RNA and the protein distribution was analysed using an immunofluorescence approach. In Wistar rats, laminin alpha2 and FN mRNA expression was analyzed using RNase protection assay (RPA) and slot-blot assays. RESULTS: The amount of laminin alpha2 mRNA did not vary in normal and pathological human hearts whereas it was significantly decreased in renovascular hypertensive rats (-20%) P<0.05 versus normal tissue). The amount of fibronectin mRNA increased in IDMC patients (x2, P<0.05 versus normal tissue), but was unchanged in hypertensive rats. A negative correlation was found between the cardiac laminin-alpha2 level and the age of the patients whatever the cardiac status. During postnatal development in the rat, a similar decrease in cardiac laminin-alpha2 level was observed between 3 and 30 weeks of age. Finally, the immunofluorescent approach failed to detect any alteration in laminin alpha2 distribution within the human myocardium. CONCLUSION: These data indicate that an imbalance between myocyte hypertrophy and the level of laminin-alpha2 might contribute to alterations in sarcolemmal properties, which occur during the development of cardiac hypertrophy and its transition to cardiac failure.

Sulfonylureas and sulfonylcarbamates as new non-tetrazole angiotensin II receptor antagonists. Discovery of a highly potent orally active (imidazolylbiphenylyl)sulfonylurea (HR 720).

The synthesis and pharmacological activity of new potent nonpeptide non-tetrazole angiotensin II (AII) receptor antagonists are described. These compounds are 4-thioimidazole derivatives linked on N1 to a biphenylsulfonyl fragment by a methylene spacer. Different acidic sulfonamides such as sulfonylureas 12, sulfonylcarbamates 15, sulfonylamides 16, and sulfonylsulfonamides 17 have been investigated as replacements to the known potent tetrazole moiety at the 2'-biphenyl position. Their activity were evaluated by AII receptor binding assay as well as by in vivo (i.v. and po) assays such as inhibition of the AII-induced pressor response in pithed rats. Most of the synthesized sulfonyl derivatives showed nanomolar affinity for the AT1 receptor subtype. The N-propylsulfonylurea 12d and the ethyl sulfonylcarbamate 15b as representative members of this series exhibited high oral activity in the pithed rat model with ID50 values of 0.38 and 0.4 mg/kg, respectively. Structure-activity relationships on the imidazole ring linked to the methylbiphenyl N-propylsulfonylurea fragment demonstrated similar features to those found in the corresponding tetrazole series. For both class of compounds, the linear butyl chain in position 2 and a carboxylic acid in position 5 were important for high in vitro and in vivo activity. In most cases, replacement of the carboxylic acid was detrimental to in vivo activity while maintaining the in vitro binding affinity. Introduction of a methylthio group in position 4 was found to enhance oral activity compared to compounds with chloro or other alkylthio, (polyfluoroalkyl)thio, and arylthio groups. 2-Butyl-4-(methylthio)-1-[[2'- [[[(propylamino)carbonyl]amino[sulfonyl](1,1'-biphenyl)-4- yl]methyl]-1-H-imidazole-5-carboxylic acid (12d) as the most promising example of the series was synthesized as its dipotassium salt (50, HR 720). This compound 50 inhibited the specific binding of [125I]-AII to rat liver membranes with an IC50 value of 0.48 nM. In vivo, 50 dose-dependently inhibited the AII-induced pressor response in normotensive pithed rats (ID50 = 0.11 mg/kg i.v. and 0.7 mg/kg po). In addition, this compound produced a marked and long-lasting decrease in blood pressure in high renin animal models and proved to be superior to the corresponding tetrazole 45 as well as to DuP 753 or its active metabolite EXP 3174. Compound 50 has been selected for in-depth investigations and is currently undergoing phase II clinical trials.

Fibronectin expression during physiological and pathological cardiac growth.

Fibronectin (FN) is a dimeric glycoprotein found in the extracellular matrix of most tissues that serves as a bridge between cells and the interstitial collagen meshwork and influences diverse processes including cell growth, adhesion, migration, and wound repair. Multiple FN forms arise by the alternative splicing of a primary transcript originating from a single gene. The spatial and temporal alterations in FN expression in the myocardium has been studied in models of cardiac growth in vivo such as fetal development, and hypertrophy secondary to pressure overload. This review focuses on the differential expression of FN isoforms that are observed in different models of cardiac growth. Using a combination of qualitative and quantitative analyses it is shown that in the rat myocardium: (1) the FN phenotype is developmentally regulated, (2) the re-expression of the fetal FN isoforms is observed in different models of cardiac hypertrophy secondary to a sudden or progressive hypertension and (3) the changes in cardiac FN expression affect mostly the coronary artery smooth muscle cells.

Effects of 4 weeks of treatment with trandolapril on renal hypertension and cardiac and vascular hypertrophy in the rat.

The effects of the angiotensin-converting enzyme inhibitor trandolapril were studied using a Goldblatt (two-kidney, one-clip) rat model of renovascular hypertension after 4 weeks of oral treatment at 0.3 or 1 mg/kg/day. The effects of trandolapril on blood pressure and on cardiac and vascular hypertrophy were analyzed in comparison with the control group. Trandolapril produced a rapid, dose-dependent decrease in blood pressure, which plateaued after 2 weeks of treatment. Complete normalization of blood pressure was observed at a daily dose of 1 mg/kg. Dose-dependent inhibition of cardiac hypertrophy was also observed, heart:body weight ratio being decreased by 17 and 30% at 0.3 and 1 mg/kg, respectively, leading to a normalization of this parameter at the higher dose compared with normotensive controls. Similarly, trandolapril produced a marked decrease in vascular wall hypertrophy in both the mesenteric artery and the aorta. Indeed, complete normalization of media thickness was observed, compared with the normotensive control group, at 1 mg/kg of trandolapril. These results show that short-term treatment with trandolapril can induce complete regression of cardiac and vascular hypertrophy, which is associated with the development of renal hypertension.

Evidence for a direct noncholinergic effect of an organophosphorous compound on guinea-pig papillary muscles: are ventricular arrhythmias related to a Na+/K+ ATPase inhibition?

The purpose of this study was to determine whether an anticholinesterase organophosphorous compound, methylphosphonothiolate (VX), could display direct effects on isolated guinea-pig ventricular muscle, and to compare these possible effects with those of carbachol (CCH) and physostigmine (PHYS). Our results confirm the direct positive inotropic effect of CCH (stimulation frequency; 2 Hz) in a concentration range from 10(-7) to 10(-3) M; lack of PHYS or VX-induced modifications was set. In the presence of an adrenergic agonist, isoproterenol (ISO) 10(-7) M, CCH or PHYS modulated the positive inotropic effect of ISO. Even with elevated concentrations of CCH (10(-4) M) or PHYS (10(-3) M), arrhythmias were never depicted. VX-induced modifications are different. Under VX, the development of (1) a positive inotropic effect and (2) two contractile events in response to each stimulation were observed. Electrophysiological studies revealed that VX led to the development of delayed after-depolarizations, and eventually triggered activity. We conclude that, in addition to its anticholinesterase activity, VX could induce a Na+/K+ ATPase inhibition. This effect could be at the onset of ventricular arrhythmias that are observed in vivo in organophosphorous compounds poisoning.

Evidence for two transient sodium currents in the frog node of Ranvier.

Na current (INa) was monitored in isolated voltage-clamped frog nodes of Ranvier in order to analyse the pharmacological and kinetic properties of fast and slow phases of inactivation. Niflumic acid (0.1-10 mM) and tetrodotoxin (0.3-30 nM) did not alter fast and slow inactivation time courses but preferentially reduced the amplitude of the fast phase of inactivation. The block of both phases of inactivation by niflumic acid and tetrodotoxin was well described if one assumed that more than one molecule of drug reacted with one channel. Fast and slow currents, corresponding respectively to fast and slow phases of inactivation, reversed at different potentials, had different threshold voltages of activation and the slopes of their steady-state inactivation curves were different. The recovery from inactivation of the compound INa could be described by the sum of two exponentials (plus a delay) corresponding respectively to fast and slow currents. When calculated from INa recorded without and with niflumic acid or tetrodotoxin, the slow current activated about three times more slowly than the fast current. Large prehyperpolarizations delayed both the activation and the inactivation of the fast current but only the activation of the slow current. Lowering the temperature decreased the fast current but increased the slow current. We conclude that the inactivatable Na current of the nodal membrane is made up of two components (INa,f and INa,s) corresponding to two different and interconvertible forms of the Na channel.