Effects of Adrenomedullin on Human Myocyte Contractile Function and β-Adrenergic Response

Mukherjee, Rupak, Multani, M. Marlina, Sample, Jeffrey A., Dowdy, Kathryn B., Zellner, James L., Hoover, Donald B., Spinale, Francis G.

01 January 2002

Background: Adrenomedullin has been demonstrated to cause systemic vasodilation, and increased plasma adrenomedullin levels have been observed in cardiovascular disease states such as heart failure. While adrenomedullin receptors have been localized to the myocardium, the effects of adrenomedullin on human myocyte contractility remained unknown. Methods and Results: Left ventricular myocytes were isolated from myocardial biopsies of patients (n = 16) undergoing elective coronary artery bypass surgery with normal left ventricular ejection fractions (51 ± 1%). A total of 233 left ventricular myocytes were studied by videomicroscopy. Myocyte shortening velocity (μm/s) was measured at baseline and following the addition of either 3 nM, 30 nM, or 60 nM of adrenomedullin. The change in myocyte shortening velocity with increasing concentrations of adrenomedullin was computed. At all concentrations, adrenomedullin reduced myocyte shortening velocity from baseline values (P < 0.05). Next, the potential interaction of adrenomedullin with the β-adrenergic receptor system was examined using 25 nM isoproterenol. The β-adrenergic receptor-mediated increase in the myocyte shortening velocity was blunted with adrenomedullin (29 ± 7 vs 63 ± 13 μm/s, P < 0.05). Conclusions: These unique findings demonstrate that adrenomedullin reduced contractility in isolated human left ventricular myocytes and exhibited a negative interaction with the β-adrenergic receptor system. Past studies have shown that adrenomedullin induces nitric oxide synthesis and that nitric oxide can uncouple myocyte metabolism. Thus, while adrenomedullin causes systemic vasodilation, this peptide can also exert a negative contractile effect in human left ventricular myocytes.

adrenomedullin

human

inotropy

left ventricular myocytes

The Role of Transient Outward Current in Regulating Cardiomyocytes Electrical and Mechanical Functions

Dong, Min

03 August 2010

No description available.

Biophysics

transient outward current

Brugada syndrome

dynamic clamp

ventricular myocytes

contraction

calcium transient

Dynamic Action Potential Restitution Contributes to Mechanical Restitution in Right Ventricular Myocytes From Pulmonary Hypertensive Rats

Hardy, Matthew E., Pervolaraki, E., Bernus, O., White, E.

2018 February 1923

Yes / We investigated the steepened dynamic action potential duration (APD) restitution of rats with pulmonary artery hypertension (PAH) and right ventricular (RV) failure and tested whether the observed APD restitution properties were responsible for negative mechanical restitution in these myocytes. PAH and RV failure were provoked in male Wistar rats by a single injection of monocrotaline (MCT) and compared with saline-injected animals (CON). Action potentials were recorded from isolated RV myocytes at stimulation frequencies between 1 and 9Hz. Action potential waveforms recorded at 1Hz were used as voltage clamp profiles (action potential clamp) at stimulation frequencies between 1 and 7Hz to evoke rate-dependent currents. Voltage clamp profiles mimicking typical CON and MCT APD restitution were applied and cell shortening simultaneously monitored. Compared with CON myocytes, MCT myocytes were hypertrophied; had less polarized diastolic membrane potentials; had action potentials that were triggered by decreased positive current density and shortened by decreased negative current density; APD was longer and APD restitution steeper. APD90 restitution was unchanged by exposure to the late Na+-channel blocker (5μM) ranolazine or the intracellular Ca2+ buffer BAPTA. Under AP clamp, stimulation frequency-dependent inward currents were smaller inMCTmyocytes and were abolished by BAPTA. In MCT myocytes, increasing stimulation frequency decreased contraction amplitude when depolarization duration was shortened, to mimic APD restitution, but not when depolarization duration was maintained. We present new evidence that the membrane potential of PAH myocytes is less stable than normal myocytes, being more easily perturbed by external currents. These observations can explain increased susceptibility to arrhythmias. We also present novel evidence that negative APD restitution is at least in part responsible for the negative mechanical restitution in PAH myocytes. Thus, our study links electrical restitution remodeling to a defining mechanical characteristic of heart failure, the reduced ability to respond to an increase in demand.

Pulmonary artery hypertension

Mechanical restitution

Right heart failure

Action potential clamp

Right ventricular myocytes

The impact of the β-subunit DPP10 on cardiac action potential and native voltage-gated K+ and Na+ currents

Metzner, Katharina

16 March 2020

Cardiac accessory β-subunits are part of macromolecular ion channel complexes. They can modulate electrophysiological properties of resulting ion currents and action potentials and are supposed to contribute to cardiac disease e.g. arrhythmias or Brugada syndrome. In my thesis, we characterized the functions of dipeptidyl peptidase-like protein 10 (DPP10), a transmembrane β-subunit of cardiac Na+ and K+ channels. Previous studies revealed that DPP10 is expressed in human heart and acts as regulator of Kv channel kinetics. In electrophysiological experiments, we found that DPP10 modulates Ito through Kv4.3 channel complexes by accelerating current densities and the time course of activation, inactivation and recovery from inactivation. Interestingly, co-expression of DPP10 with Kv4.3 and KChIP2 in CHO cells induced a slowly inactivating fraction of Ito, providing evidence for a contribution of Ito on the sustained outward K+ current in cardiomyoctes. Until then, the sustained fraction of K+ currents was thought to be due to IKur. We further studied the contribution of Kv4-mediated Ito to total K+ currents in human atrial myocytes using 4-Aminopyridine to block IKur in combination with Heteropoda toxin 2 to block Kv4 channels. Using this approach, it was possible to separate an Ito fraction of about 19% contributing to the late current component. These data suggest that the generation of a sustained current component of Ito induced by DPP10 may affect the late repolarization phase of an atrial action potential. To further explore the functions of DPP10, we investigated a potential interaction with Nav channels in cardiomyocytes. It was possible to detect DPP10 in human ventricles, with higher expression levels in patients with heart failure. We demonstrated that DPP10 affects cellular action potentials in isolated rat cardiomyocytes after adenoviral gene transfer indicating a reduction in Na+ current density. Voltage-dependent Na+ channel activation and inactivation curve was shifted to more positive potentials with overexpression of DPP10, resulting in enhanced availability of Na+ channels for activation, along with increasing window Na+ current. Thus, we assumed a role of DPP10 on promotion of arrhythmias via interaction with Nav1.5. The results of this study can help to understand the complex interaction pattern between Nav and Kv channels and the role of their β-subunits, especially DPP10. In conclusion, DPP10 was identified as a new modulator of Kv and Nav currents in the human heart, suggesting that this β-subunit may contributes to cardiac arrhythmias and might be a new therapeutic target.:1 Introduction 1.1 The cardiac action potential 1.2 Cardiac potassium channels 1.2.1 The Kv4.3 channel complex 1.2.2 Accessory β subunits of K+ channel 1.2.3 The Kv1.5 channel 1.2.4 Separation of Ito and IKur in native cardiomyocytes 1.3 Cardiac sodium channels 1.3.1 Molecular construction of Nav1.5 channel 1.3.2 Accessory β subunits of Na+ channel 1.3.3 The role of Nav1.5 in cardiac electrical disorders 1.4 Aim of the thesis and systematic approach 2 The research articles 3 Summary 4 Zusammenfassung 6 References 7 Appendices 7.1 Abbreviations

info:eu-repo/classification/ddc/610

ddc:610

Évaluation des propriétés antiarythmiques de dérives oxygénés des acides gras polyinsaturés à longue chaîne / Antiarrhythmic properties of oxygenated metabolites of polyinsaturated fatty acids

Roy, Jérôme

11 September 2015

L'infarctus du myocarde constitue la première cause de mortalité cardiovasculaire. Dans ce contexte, depuis plus de 40 ans et les premières études sur les populations du Groenland, il est connu qu'une consommation de poisson riche en acide gras polyinsaturés de type omégas 3 (AGPI n-3) a des effets cardioprotecteurs. De très nombreuses études cliniques, animales et cellulaires ont ensuite confirmé ces résultats cardioprotecteurs des AGPI n-3 qui semblent passer par une prévention des arythmies cardiaques post infarctus.Cependant, du fait de leurs nombreuses doubles liaisons carbone-carbone, les principaux AGPI n-3 que sont l'acide eicosapentaénoïque et l'acide docosahexaénoïque sont très sensibles à l'oxygénation à l'air et peuvent subir une peroxydation non enzymatique spontanée sous condition de stress oxydant qui accompagne notamment l'ischémie/reperfusion lors d'un infarctus du myocarde.Dans ce travail de thèse, nous posons la question de savoir quelle forme d'AGPI a des effets cardioprotecteur : la forme réduite ou oxydée. En effet, les effets des AGPI n-3 sur la fonction cardiaque sont très controversés, notamment due au manque d'information sur les mécanismes impliqués. Particulièrement, on ne sait pas quel lipide est actif : les AGPI n-3 ou un des leurs métabolites oxygénés.Durant l'ischémie reperfusion puis dans les mois qui suivent l'infarctus du myocarde, le stress oxydant est élevé et de nombreux métabolites non enzymatiques dérivés des AGPI n-3 comme les NeuroProstanes sont alors produits à tel point qu'ils sont reconnus comme biomarqueurs du stress oxydant. Ainsi, dans ce travail de recherche, nous spéculons que les NeuroProstanes ne sont pas seulement des biomarqueurs du stress oxydant mais auraient un rôle biologiquement actif qui expliqueraient les effets cardioprotecteurs connus de leurs précurseurs ; les AGPI n-3.Le but de cette thèse est dans un premier temps d'investiguer l'influence de la peroxydation lipidique du DHA sur ses propriétés antiarythmiques in cellulo sur des cellules ventriculaires cardiaques isolées puis in vivo sur des souris ayant subit un infarctus du myocarde par ligature de l'artère coronaire gauche. De la même manière, nous avons évalué les propriétés antiarythmiques des métabolites non enzymatique des AGPI n-3 et notamment le 4(RS)-4F4t-NeuroProstane. Dans un second temps et de manière plus précoce, nous avons observé si une infusion préventive de 4(RS)-4F4t-NeuroP chez le rat, 20 minutes avant un épisode d'ischémie reperfusion peut protéger le myocarde des dommages ischémiques (morts cellulaires), des arythmies et des altérations morpho-fonctionnelles.L'ensemble de ce travail de thèse a ainsi permis de mettre en évidence que un des médiateurs lipidiques des AGPI n-3 ; le 4(RS)-4-F4t-NeuroP peut exercer des effets biologiquement actifs qui passent par une prévention des arythmies dans les mois qui suivent l'infarctus du myocarde ; effets passant par une prévention des modifications post-translationnelles du RyR2 et in fine d'une régulation de l'homéostasie calcique. De manière plus précoce durant l'ischémie reperfusion, nos résultats montrent que le 4(RS)-4-F4t-NeuroP réduit les arythmies ventriculaires, la taille de la zone infarcie et la dysfonction cardiaque, effets cardioprotecteurs qui passent par des mécanismes mitochondriaux.Le travail de cette thèse démontre pour la première fois que le DHA n'exerce pas d'effets cardioprotecteurs mais que ce serait les produits issus de son oxydation non enzymatique tel le 4(RS)-4-F4t-NeuroP pouvant ainsi expliquer l'ensemble des effets connus des AGPI n-3. Cette découverte ouvre de nouvelles perspectives sur les produits oxydés non enzymatiques des AGPI n-3 comme des potentiels médiateurs dans les maladies comme durant l'infarctus du myocarde ou le stress oxydant qui est généré joue un rôle prépondérant dans les altérations physiopathologiques qui en découlent. / Since 40 years, ω3 poly-unsaturated fatty acids (n-3 PUFA) are known to have cardioprotective properties in ischemic disease such as cardiac infarction following ischemia/reperfusion period. Many studies in isolated cells or in animals confirmed these effects and it has been suggested that n-3 PUFA have direct effects on targeted proteins such as ionic channels. However, due to the abundance of double carbone bounds, the main n-3 PUFA; eicosapentaenoic acid (C20: 5 n-3, EPA) and docosahexaenoic acid (C22: 6 n-3, DHA) are very sensitive to free radical oxidation and can undergo non-enzymatic spontaneous peroxidation under oxidative stress conditions as it occurs in ischemia/reperfusion. In the present work, we addressed the question of the form of DHA having cardioprotective properties: reduced or oxidized. Indeed, the effects of n-3 PUFA on cardiac function are controversial, notably due to the lack of information on the mechanisms involved. Particularly, it is not well understood which is the active lipid: the PUFA or one of its oxygenated metabolites. In the context of oxidative stress, during ischemia/reperfusion and in month following cardiac infarction, a lot of oxygenated metabolites of PUFA like Neuroprostane; 4(RS)-4F4t-NeuroP are produced and used as biomarkers of oxidative stress. This metabolite is associated to a lower atherosclerosis risk suggesting a beneficial role in cardiovascular diseases. In this context we speculate that Neuroprostane are not just a markers of stress conditions but have biological activities.The aim of this thesis was in first time to investigate the influence of DHA peroxidation on its potentially anti-arrhythmic properties in isolated ventricular cardiomyocytes and in vivo in post-myocardial infarcted (PMI) mice. In same way, we investigated in cellulo and in vivo anti-arrhythmic properties of oxygenated metabolites of n-3 PUFA such as 4(RS)-4F4t-NeuroP. In second time we investigated if the pericardial delivery 20 minutes before occlusion of 4F4t-NeuroP protects in prevention the myocardium from ischemic damages and arrhythmias during and following an I/R episode in rats.In this study, we challenged the paradigm that spontaneously formed oxygenated metabolites of lipids are undesirable as they are unconditionally toxic. This study reveals that the lipid mediator 4(RS)-4-F4t-NeuroP derived from non-enzymatic peroxidation of DHA, can counteract such deleterious effects through cardiac anti-arrhythmic properties in month following cardiac infarction by preventing deleterious post-translational modification of RyR2 and thus regulating calcium homeostasis. More early, during ischemia/reperfusion, our results show that pericardial delivery of 4(RS)-4-F4t-NeuroP reduced ischemia-induced ventricular arrhythmias, infarct sizes, and cardiac dysfonction ; cardioprotective effects involving mitchondria mecanisms.This thesis demonstrate for the first time that DHA per se has no anti-arrhythmic effects and 4(RS)-4-F4t-NeuroP as a mediator of the cardioprotection characteristics of DHA. This discovery opens new perspectives for products of non-enzymatic oxidized n-3 PUFA as potent mediators in oxidative stress diseases like during a cardiac infarction, where oxidative stress generated play fundamental role in pathophysiological alterations.

Myocytes ventriculaires murins

Extrasystoles ventriculaires

Canaux ioniques

Infarctus du myocarde

Long chain (Omega 3)

Ventricular myocytes

Ventricular extrasystoles

Ion channels

Myocardial infarction

Die Na+/H+-Austauscher-abhängige pH-Regulation in Vorhof- und Ventrikelmyozyten / The Na+/H+-exchanger (NHE-1)-dependent pHi regulation in atrial and ventricular myocytes

Yan, Hui

26 October 2011

No description available.

610 Medizin, Gesundheit

Medicine

Der Na+/H+-Austauscher (NHE)

Vorhof- und Ventrikelmyozyten

HOE642 (Cariporide)

5-Carboxy-SNARF®-1

Die NHE-1-

the Na+/H+-exchanger (NHE)

HOE642 (Cariporide)

5-Carboxy-SNARF®-1

the rate of H+ efflux at pH 6.9 (JpH6,9)

expression

44.85

MED 411: Kardiologie