Chantale Simard

ATP acts as a survival signal and prevents the mineralization of aortic valve

Calcific aortic valve disease (CAVD) is a disorder related to progressive mineralization of valvular tissue that is a leading cause of heart disease. Thus far, there is no medical treatment to prevent the mineralization of aortic valves. It is generally thought that pathologic mineralization is linked to apoptosis of vascular cells. However, the role of apoptosis during mineralization as well as the survival signals for valvular interstitial cells (VICs), the main cellular component of aortic valves, remains to be identified. Here, through several lines of evidence, we show that bioavailability of extracellular ATP is a signal which determines survival or apoptosis of VICs and, in doing so, plays a major role in the development of CAVD. Specifically, in CAVD and in VIC cultures undergoing mineralization, we found a high level of the ectonucleotidase ENPP1. In addition, a genetic polymorphism in the intron 9 of the ENPP1 gene was associated with CAVD in a case-control cohort as well as with mRNA expression levels of ENPP1 in aortic valves. A high level of ENPP1 in CAVD promoted apoptosis-mediated mineralization of VICs by depleting the extracellular pool of ATP. We then documented that release of ATP by VICs promoted cell survival via the P2Y(2) receptor and the PI3K/Akt signaling pathway. Hence, our results show that level of ENPP1 modulates extracellular concentration of ATP, which is an important survival signal for VICs. These findings may help to develop novel pharmacological treatment for CAVD.

Ezetimibe-associated myopathy in monotherapy and in combination with a 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitor.

Two cases of myopathy associated with ezetimibe are reported. In the first case, a woman on ezetimibe monotherapy presented with muscle pain and an elevated concentration of creatine kinase (CK) on two occasions, with ezetimibe 10 mg and with ezetimibe 5 mg after a washout period. The recurrence of muscle pain after washout and the CK increase both supported the hypothesis that ezetimibe alone can be linked to myalgia. In the second case, a man had been treated with atorvastatin, and ezetimibe 10 mg was added to improve his lipid profile. Two months later, the patient complained of muscle pain and a CK increase was noted. The appearance of symptoms when adding ezetimibe to atorvastatin supports a potential pharmacokinetic and/or a pharmacodynamic interaction between these two drugs. These cases suggest that ezetimibe monotherapy as well as ezetimibe associated with the use of a statin may induce myalgia. The mechanism by which ezetimibe could cause muscle pain is not known.

Human cardiac potassium channel DNA polymorphism modulates access to drug-binding site and causes drug resistance.

Expression of voltage-gated K channel, shaker-related subfamily, member 5 (KCNA5) underlies the human atrial ultra-rapid delayed rectifier K current (I(Kur)). The KCNA5 polymorphism resulting in P532L in the C terminus generates I(Kur) that is indistinguishable from wild type at baseline but strikingly resistant to drug block. In the present study, truncating the C terminus of KCNA5 generated a channel with wild-type drug sensitivity, which indicated that P532 is not a drug-binding site. Secondary structure prediction algorithms identified a probable alpha-helix in P532L that is absent in wild-type channels. We therefore assessed drug sensitivity of I(Kur) generated in vitro in CHO and HEK cells by channels predicted to exhibit or lack this C-terminal alpha-helix. All constructs displayed near-identical I(Kur) in the absence of drug challenge. However, those predicted to lack the C-terminal alpha-helix generated quinidine-sensitive currents (43-51% block by 10 microM quinidine), while the currents generated by those constructs predicted to generate a C-terminal alpha-helix were inhibited less than 12%. Circular dichroism spectroscopy revealed an alpha-helical signature with peptides derived from drug-resistant channels and no organized structure in those associated with wild-type drug sensitivity. In conclusion, we found that this secondary structure in the KCNA5 C terminus, absent in wild-type channels but generated by a naturally occurring DNA polymorphism, does not alter baseline currents but renders the channel drug resistant. Our data support a model in which this structure impairs access of the drug to a pore-binding site.

Impact of weight-loss medications on the cardiovascular system: focus on current and future anti-obesity drugs.

Overweight and obesity have been rising dramatically worldwide and are associated with numerous comorbidities such as cardiovascular disease (CVD), type 2 diabetes mellitus, hypertension, certain cancers, and sleep apnea. In fact, obesity is an independent risk factor for CVD and CVD risks have also been documented in obese children. The majority of overweight and obese patients who achieve a significant short-term weight loss do not maintain their lower bodyweight in the long term. This may be due to a lack of intensive counseling and support from a facilitating environment including dedicated healthcare professionals such as nutritionists, kinesiologists, and behavior specialists. As a result, there has been a considerable focus on the role of adjunctive therapy such as pharmacotherapy for long-term weight loss and weight maintenance. Beyond an unfavorable risk factor profile, overweight and obesity also impact upon heart structure and function. Since the beginning, the quest for weight loss drugs has encountered warnings from regulatory agencies and the withdrawal from the market of efficient but unsafe medications. Fenfluramine was withdrawn from the market because of unacceptable pulmonary and cardiac adverse effects.Nevertheless, there is extensive research directed at the development of new anti-obesity compounds. The effect of these molecules on CVD risk factors has been studied and reported but information regarding their impact on the cardiovascular system is sparse. Thus, instead of looking at the benefit of weight loss on metabolism and risk factor management, this article discusses the impact of weight loss medications on the cardiovascular system. The potential interaction of available and potential new weight loss drugs with heart function and structure is reviewed.

Prolongation of cardiac ventricular repolarization under paliperidone: how and how much?

Introduction: Paliperidone (9-hydroxyrisperidone) is a second-generation antipsychotic. As observed with risperidone, QT interval prolongation was reported with paliperidone. Objective: The aim was to evaluate the effects of paliperidone on cardiac ventricular repolarization. Methods: (1) Patch-clamp experiments: Human ether-a-go-go-related gene (HERG)- or KCNQ1 + KCNE1-transfected cells were exposed to 0.1-100 μmol/L paliperidone (N = 39 cells, total) to assess the drug effect on HERG and KCNQ1 + KCNE1 currents. (2) Langendorff perfusion experiments: Hearts isolated from male Hartley guinea pigs (N = 9) were exposed to 0.1 μmol/L paliperidone to assess drug-induced prolongation of monophasic action potential duration measured at 90% repolarization. (3) In vivo cardiac telemetry experiments: Guinea pigs (N = 8) implanted with transmitters were injected a single intraperitoneal dose of 1 mg/kg of paliperidone, and 24-hour electrocardiogram recordings were made. Results: (1) The estimated concentration at which 50% of the maximal inhibitory effect is observed (IC50) for paliperidone on HERG current was 0.5276 μmol/L. In contrast, 1 μmol/L paliperidone had hardly any effect on KCNQ1 + KCNE1 current (4.0 ± 1.6% inhibition, N = 5 cells). (2) While pacing the hearts at cycle lengths of 150, 200, or 250 milliseconds, 0.1 μmol/L paliperidone prolonged monophasic action potential duration measured at 90% repolarization by, respectively, 6.1 ± 3.1, 9.8 ± 2.7, and 12.8 ± 2.7 milliseconds. (3) Paliperidone (1 mg/kg) intraperitoneal caused a maximal 15.7 ± 5.3-millisecond prolongation of QTc. Conclusions: Paliperidone prolongs the QT interval by blocking HERG current at clinically relevant concentrations and is potentially unsafe.

Decreased CYP3A expression and activity in guinea pig models of diet-induced metabolic syndrome: is fatty liver infiltration involved?

Background: In humans, CYP3A drug-metabolizing enzyme subfamily is the most important. Numerous pathophysiological factors, such as diabetes and obesity, were shown to affect CYP3A activity. Often considered a precursor state for type II diabetes, metabolic syndrome exerts a modulating role on CYP3A, in our hypothesis. Objective: To evaluate the effect of metabolic syndrome on CYP3A drug-metabolizing activity/expression in guinea pigs. Methods: Hepatic microsomes were prepared from male Hartley guinea pigs fed with a control, a high-fat high sucrose (HFHS) or a high-fat high fructose diet (HFHF). Domperidone was selected as a probe substrate of CYP3A and formation of four of its metabolites was evaluated using high-performance liquid chromatography. CYP3A protein and mRNA expression were assessed by Western blot and reverse-transcription quantitative polymerase chain reaction, respectively. Hepatic fatty infiltration was evaluated using standard Oil Red O staining. Triglyceride and free fatty acid liver content were also quantified. Results: Microsomal CYP3A activity was significantly decreased in both HFHS and HFHF diet groups versus the control diet group. Significant decreases of CYP3A mRNA and protein expression were observed in both HFHS and HFHF diet groups. Oil Red O staining showed a massive liver fatty infiltration in the HFHS and HFHF diet groups, which was not observed in the control diet group. Both triglyceride and free fatty acid liver content were significantly increased in the HFHS and HFHF diet groups. Conclusion: Diet-induced metabolic syndrome decreases CYP3A expression/activity in guinea pigs. This may ultimately lead to variability in drug response, ranging from lack of effect to life-threatening toxicity.

QRS widening and QT prolongation under bupropion: a unique cardiac electrophysiological profile

QRS widening and QT prolongation are associated with bupropion. The objectives were to elucidate its cardiac electrophysiological properties. Patch‐clamp technique was used to assess the IKr‐, IKs‐, and INa‐blocking effects of bupropion. Langendorff retroperfusion technique on isolated guinea‐pig hearts was used to evaluate the MAPD90‐, MAP amplitude‐, phase 0 dV/dt‐, and ECG‐modulating effects of bupropion and of two gap junction intercellular communication inhibitors: glycyrrhetinic acid and heptanol. To evaluate their effects on cardiac intercellular communication, fluorescence recovery after photobleaching (FRAP) technique was used. Bupropion is an IKr blocker. IC50 was estimated at 34 μm. In contrast, bupropion had hardly any effect on IKs and INa. Bupropion had no significant MAPD90‐modulating effect. However, as glycyrrhetinic acid and heptanol, bupropion caused important reductions in MAP amplitude and phase 0 dV/dt. A modest but significant QRS‐widening effect of bupropion was also observed. FRAP experiments confirmed that bupropion inhibits gap junctional intercellular communication. QT prolongation during bupropion overdosage is due to its IKr‐blocking effect. QRS widening with bupropion is not related to cardiac sodium channel block. Bupropion rather mimics the QRS‐widening, MAP amplitude‐ and phase 0 dV/dt ‐reducing effect of glycyrrhetinic acid and heptanol. Unlike class I anti‐arrhythmics, bupropion causes cardiac conduction disturbances by reducing cardiac intercellular coupling.

Modulation of CYP3a expression and activity in mice models of type 1 and type 2 diabetes

CYP3A4, the most abundant cytochrome P450 enzyme in the human liver and small intestine, is responsible for the metabolism of about 50% of all marketed drugs. Numerous pathophysiological factors, such as diabetes and obesity, were shown to affect CYP3A activity. Evidences suggest that drug disposition is altered in type 1 (T1D) and type 2 diabetes (T2D). The objective was to evaluate the effect of T1D and T2D on hepatic and intestinal CYP3a drug‐metabolizing activity/expression in mice. Hepatic and intestinal microsomes were prepared from streptozotocin‐induced T1D, db/db T2D and control mice. Domperidone was selected as a probe substrate for CYP3a and formation of five of its metabolites was evaluated using high performance liquid chromatography. Hepatic CYP3a protein and mRNA expression were assessed by Western blot and reverse‐transcription quantitative polymerase chain reaction respectively. Hepatic microsomal CYP3a activity was significantly increased in both T1D and T2D groups versus control group. Intestinal CYP3a activity was also significantly increased in both T1D and T2D groups. Moreover, significant increases of both hepatic CYP3a mRNAs and protein expression were observed in both T1D and T2D groups versus control group. Additional experiments with testosterone further validated the increased activity of CYP3a under the effect of both T1D and T2D. Although differences exist in the pathophysiological insults associated with T1D and T2D, our results suggest that these two distinct diseases may have the same modulating effect on the regulation of CYP3a, ultimately leading to variability in drug response, ranging from lack of effect to life‐threatening toxicity.

Metabolic syndrome potentiates the cardiac action potential-prolonging action of drugs: A possible ‘anti-proarrhythmic’ role for amlodipine

Type II diabetes was shown to prolong the QT interval on the ECG and to promote cardiac arrhythmias. This is not so clear for metabolic syndrome, a precursor state of type II diabetes. The objectives of the present study were to generate a guinea pig model of metabolic syndrome by long-term exposure to diabetogenic diets, and to evaluate the monophasic action potential duration (MAPD)-modulating effects of drugs in these animals. Male Hartley guinea pigs were fed with either the control, the High Fat High Sucrose (HFHS) or the High Fat High Fructose (HFHF) diet for 150 days. Evolution of weight, blood cholesterol, triglycerides, urea and glucose tolerance were regularly monitored. Histopathological evolution was also evaluated in target organs such as pancreas, heart, liver and kidneys. Ex vivo experiments using the Langendorff retroperfusion technique, isolated hearts from guinea pigs either fed with the control, the HFHS or the HFHF diet were exposed to dofetilide 20 nM (D), chromanol 293B 10 μM (C) and amlodipine 100 nM (A) in different drug combinations and monophasic action potential duration was measured at 90% repolarization (MAPD₉₀). Our data show that it is possible to generate a guinea pig model of metabolic syndrome by chronic exposure to diabetogenic diets. Minor histopathological abnormalities were observed, mainly in the pancreas and the liver. Metabolic syndrome potentiates the MAPD-prolonging actions of I(Kr)-blocking (dofetilide) and I(Ks)-blocking (chromanol 293B) drugs, an effect that is reversible upon administration of the calcium channel blocker amlodipine.

Impact of glucose concentration on cardiac ventricular repolarization under IKr/IKs blocking agents

Drug-induced QT interval prolongation is a condition likely to be aggravated by diabetes. The objective of this study was to evaluate how glucose concentration may modulate drug effects on ventricular repolarization and on cardiac repolarizing potassium currents. Guinea pig hearts were Langendorff-retroperfused and monophasic action potential duration (MAPD) was measured. Glucose (1, 5 or 20 mmol/L) was tested with either dofetilide (a specific I(Kr) blocker), chromanol 293B (a specific I(Ks) blocker) or both. Effects of glucose (1, 5 or 20 mmol/L) on I(Kr) blockade mediated by dofetilide were also measured in HERG-transfected HEK293 cells in the absence vs presence of the P-glycoprotein drug transporter, using the whole cell patch-clamp technique. Our results suggest that both hypo- and hyperglycemia potentiate the MAPD-prolonging and I(Kr)-blocking properties of dofetilide. P-glycoprotein drug extrusion efficacy appears as a key determinant of dofetilides I(Kr)-blocking effect. This efficacy appears to be affected by glucose concentration, particularly hyperglycemia.