Sandra Kanani scite author profile

The atrioventricular node controls cardiac impulse conduction and generates pacemaker activity in case of failure of the sino-atrial node. Understanding the mechanisms of atrioventricular automaticity is important for managing human pathologies of heart rate and conduction. However, the physiology of atrioventricular automaticity is still poorly understood. We have investigated the role of three key ion channel-mediated pacemaker mechanisms namely, Ca(v)1.3, Ca(v)3.1 and HCN channels in automaticity of atrioventricular node cells (AVNCs). We studied atrioventricular conduction and pacemaking of AVNCs in wild-type mice and mice lacking Ca(v)3.1 (Ca(v)3.1(-/-)), Ca(v)1.3 (Ca(v)1.3(-/-)), channels or both (Ca(v)1.3(-/-)/Ca(v)3.1(-/-)). The role of HCN channels in the modulation of atrioventricular cells pacemaking was studied by conditional expression of dominant-negative HCN4 channels lacking cAMP sensitivity. Inactivation of Ca(v)3.1 channels impaired AVNCs pacemaker activity by favoring sporadic block of automaticity leading to cellular arrhythmia. Furthermore, Ca(v)3.1 channels were critical for AVNCs to reach high pacemaking rates under isoproterenol. Unexpectedly, Ca(v)1.3 channels were required for spontaneous automaticity, because Ca(v)1.3(-/-) and Ca(v)1.3(-/-)/Ca(v)3.1(-/-) AVNCs were completely silent under physiological conditions. Abolition of the cAMP sensitivity of HCN channels reduced automaticity under basal conditions, but maximal rates of AVNCs could be restored to that of control mice by isoproterenol. In conclusion, while Ca(v)1.3 channels are required for automaticity, Ca(v)3.1 channels are important for maximal pacing rates of mouse AVNCs. HCN channels are important for basal AVNCs automaticity but do not appear to be determinant for β-adrenergic regulation.

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Pacemaker activity and ionic currents in mouse atrioventricular node cells

Marger

Mesirca²,

Alig³

et al. 2011

Channels

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It is well established that Pacemaker activity of the sino-atrial node (SAN) initiates the heartbeat. However, the atrioventricular node (AVN) can generate viable pacemaker activity in case of SAN failure, but we have limited knowledge of the ionic bases of AVN automaticity. We characterized pacemaker activity and ionic currents in automatic myocytes of the mouse AVN. Pacemaking of AVN cells (AVNCs) was lower than that of SAN pacemaker cells (SANCs), both in control conditions and upon perfusion of isoproterenol (ISO). Block of I(Na) by tetrodotoxin (TTX) or of I(Ca,L) by isradipine abolished AVNCs pacemaker activity. TTX-resistant (I(Nar)) and TTX-sensitive (I(Nas)) Na(+) currents were recorded in mouse AVNCs, as well as T-(I(Ca,T)) and L-type (I(Ca,L)) Ca(2+) currents I(Ca,L) density was lower than in SANCs (51%). The density of the hyperpolarization-activated current, (I(f)) and that of the fast component of the delayed rectifier current (I(Kr)) were, respectively, lower (52%) and higher (53%) in AVNCs than in SANCs. Pharmacological inhibition of I(f) by 3 µM ZD-7228 reduced pacemaker activity by 16%, suggesting a relevant role for I(f) in AVNCs automaticity. Some AVNCs expressed also moderate densities of the transient outward K(+) current (I(to)). In contrast, no detectable slow component of the delayed rectifier current (I(Ks)) could be recorded in AVNCs. The lower densities of I(f) and I(Ca,L), as well as higher expression of I(Kr) in AVNCs than in SANCs may contribute to the intrinsically slower AVNCs pacemaking than that of SANCs.

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Genetically engineered cardiac pacemaker: Stem cells transfected with HCN2 gene and myocytes—A model

2008

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Artificial biological pacemakers were developed and tested in canine ventricles. Next steps will require obtaining oscillations sensitive to external regulations, and robust with respect to long term drifts of expression levels of pacemaker currents and gap junctions. We introduce mathematical models intended to be used in parallel with the experiments.The models describe human mesenchymal stem cells (hMSC ) transfected with HCN2 genes and connected to myocytes. They are intended to mimic experiments with oscillation induction in a cell pair, in cell culture and in the cardiac tissue. We give examples of oscillations in a cell pair, in a one dimensional cell culture and dependence of oscillation on number of pacemaker channels per cell and number of gap junctions. The models permit to mimic experiments with levels of gene expressions that are not achieved yet and to predict if the work to achieve this levels will significantly increase the quality of oscillations. This give arguments for selecting the directions of the experimental work. Impressive results were obtained with stem cells to create an artificial biological pacemaker [4]: human mesenchymal stem cells (hMSC) transfected with HCN2 genes injected in canine left bundle branch provide ventricular escape rhythms that were mapped to the site of the injection. This experimental success shows great promises for future therapy.In a recent review article [5], the question : "What characteristics should be embodied in a biological pacemaker?" was put forward. The creation of a stable physiological rhythm was listed as one of the most important properties for future biopacemakers. The present article describes the mathematical models intended to be runned in parallel with the experiments to achieve this goal.The oscillations should be reasonably stable with respect to inevitable variations of the parameters affecting the biological pacemaker. Indeed, many factors can affect the period of the pacemaker namely: decreasing the expression levels of pacemaker channels or gap junctions, modification of the peptides regulating gene expressions, loss of genes, migration of small percentage of stem cells to other sites or differentiation into other cell types; loss of pacemaker function by some cells.In order to obtain a stable pacemaker, many time consuming experiments should be performed. In exploring such systems, we believe that an adequate combination of experiments with theoretical predictions can lead to a much faster results, by reaching a better quantitative understanding and in so doing, in reducing the number of

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A link between ECM plasticity and synaptic morphological evolution

Kanani¹,

Robbins²,

Biben³

et al. 2007

Preprint

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Sandra Kanani

Functional roles of Ca_v1.3, Ca_v3.1 and HCN channels in automaticity of mouse atrioventricular cells

Pacemaker activity and ionic currents in mouse atrioventricular node cells

Genetically engineered cardiac pacemaker: Stem cells transfected with HCN2 gene and myocytes—A model

A link between ECM plasticity and synaptic morphological evolution

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Sandra Kanani

Functional roles of Cav1.3, Cav3.1 and HCN channels in automaticity of mouse atrioventricular cells

Pacemaker activity and ionic currents in mouse atrioventricular node cells

Genetically engineered cardiac pacemaker: Stem cells transfected with HCN2 gene and myocytes—A model

A link between ECM plasticity and synaptic morphological evolution

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Product

Resources

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Functional roles of Ca_v1.3, Ca_v3.1 and HCN channels in automaticity of mouse atrioventricular cells