Your search keyword '"I.D. Greener"' showing total 9 results

1. Ion channel transcript expression at the rabbit atrioventricular conduction axis

Author

Mitsuru Yamamoto, I.D. Greener, Halina Dobrzynski, James O. Tellez, Rudi Billeter, Gillian M. Graham, and Mark R. Boyett

Subjects

Male, Bundle of His, Potassium Channels, Action Potentials, Biology, Connexins, Ion Channels, Sodium Channels, Physiology (medical), medicine, Animals, RNA, Messenger, Ion channel, In Situ Hybridization, Sinoatrial node, Gap junction, Gap Junctions, Anatomy, Atrioventricular node, Cell biology, Electrophysiology, medicine.anatomical_structure, Atrioventricular Node, Calcium, Calcium Channels, Rabbits, Electrical conduction system of the heart, Cardiology and Cardiovascular Medicine, NODAL, Biomarkers

Abstract

Background— Little is known about the distribution of gap junctions and ion channels in the atrioventricular node, even though the physiology and pathology of the atrioventricular node is ultimately dependent on them. Methods and Results— The abundance of 30 transcripts for markers, gap junctions, ion channels, and Ca 2+ -handling proteins in different regions of the rabbit atrioventricular node (nodal extension and proximal and distal penetrating bundle of His as well as atrial and ventricular muscle) was measured using a novel quantitative polymerase chain reaction technique and in situ hybridization. The expression profile of the nodal extension (slow pathway into penetrating bundle) was similar to that of the sinoatrial node. For example, in the nodal extension, in contrast to the atrial muscle and as expected for a slowly conducting tissue with pacemaker activity, there was no or reduced expression of Cx43, Na v 1.5, Ca v 1.2, K v 1.4, KChIP2, and RYR3 and high expression of Ca v 1.3 and HCN4. The expression profile of the penetrating bundle was less specialized. In situ hybridization revealed a transitional zone with reduced expression of Cx43, Na v 1.5, and KChIP2 that may form the fast pathway into the penetrating bundle. Conclusions— At the atrioventricular node, the expression of gap junctions and ion channels in the nodal extension (slow pathway) and a transitional zone (putative fast pathway) as well as the penetrating bundle (output pathway) is specialized and heterogeneous and roughly matches the electrophysiology of the different regions.

Published

2009

2. Computer three-dimensional reconstruction of the atrioventricular node

Author

Igor R. Efimov, Jules C. Hancox, Shin Inada, Mark R. Boyett, Jue Li, Mitsuru Yamamoto, Rudi Billeter, I.D. Greener, Henggui Zhang, Halina Dobrzynski, and Vladimir P. Nikolski

Subjects

Physics, Central fibrous body, Physiology, Sinoatrial node, Models, Cardiovascular, Action Potentials, Anatomy, Reentry, Atrioventricular node, Article, Tendon, medicine.anatomical_structure, Imaging, Three-Dimensional, Ventricle, medicine, Atrioventricular Node, Animals, Computer Simulation, Rabbits, Atrium (heart), Cardiology and Cardiovascular Medicine, NODAL, Electrophysiologic Techniques, Cardiac

Abstract

Because of its complexity, the atrioventricular node (AVN), remains 1 of the least understood regions of the heart. The aim of the study was to construct a detailed anatomic model of the AVN and relate it to AVN function. The electric activity of a rabbit AVN preparation was imaged using voltage-dependent dye. The preparation was then fixed and sectioned. Sixty-five sections at 60- to 340-microm intervals were stained for histology and immunolabeled for neurofilament (marker of nodal tissue) and connexin43 (gap junction protein). This revealed multiple structures within and around the AVN, including transitional tissue, inferior nodal extension, penetrating bundle, His bundle, atrial and ventricular muscle, central fibrous body, tendon of Todaro, and valves. A 3D anatomically detailed mathematical model (approximately 13 million element array) of the AVN and surrounding atrium and ventricle, incorporating all cell types, was constructed. Comparison of the model with electric activity recorded in experiments suggests that the inferior nodal extension forms the slow pathway, whereas the transitional tissue forms the fast pathway into the AVN. In addition, it suggests the pacemaker activity of the atrioventricular junction originates in the inferior nodal extension. Computer simulation of the propagation of the action potential through the anatomic model shows how, because of the complex structure of the AVN, reentry (slow-fast and fast-slow) can occur. In summary, a mathematical model of the anatomy of the AVN has been generated that allows AVN conduction to be explored.

Published

2008

3. Connexins in the Sinoatrial and Atrioventricular Nodes

Author

Mark R. Boyett, Igor R. Efimov, Jue Li, Shin Inada, Jie Liu, Haruo Honjo, James O. Tellez, Halina Dobrzynski, Shin Yoo, I.D. Greener, Rudolf Billeter, Ming Lei, and Henggui Zhang

Subjects

Tachycardia, medicine.medical_specialty, Cardiac cycle, Sinoatrial node, business.industry, Connexin, Funny current, Inhibitory postsynaptic potential, Atrioventricular node, medicine.anatomical_structure, Internal medicine, cardiovascular system, medicine, Ventricular muscle, Cardiology, sense organs, medicine.symptom, business

Abstract

The sinoatrial node (SAN) and the atrioventricular node (AVN) are specialized tissues in the heart: the SAN is specialized for pacemaking (it is the pacemaker of the heart), whereas the AVN is specialized for slow conduction of the action potential (to introduce a delay between atrial and ventricular activation during the cardiac cycle). These functions have special requirements regarding electrical coupling and, therefore, expression of connexin isoforms. Electrical coupling in the center of the SAN should be weak to protect it from the inhibitory electrotonic influence of the more hyperpolarized non-pacemaking atrial muscle surrounding the SAN. However, for the SAN to be able to drive the atrial muscle, electrical coupling should be strong in the periphery of the SAN. Consistent with this, in the center of the SAN there is no expression of Cx43 (the principal connexin of the working myocardium) and little expression of Cx40, but there is expression of Cx45 and Cx30.2, whereas in the periphery of the SAN Cx43 as well Cx45 is expressed. In the AVN, there is a similar pattern of expression of connexins as in the center of the SAN and this is likely to be in large part responsible for the slow conduction of the action potential.

Published

2006

4. A detailed 3D model of the rabbit right atrium including the sinoatrial node, atrioventricular node, surrounding blood vessels and valves

Author

Kieran Clarke, M. Yamamoto, Jürgen E. Schneider, I.D. Greener, Halina Dobrzynski, Mark R. Boyett, and Jue Li

Subjects

medicine.medical_specialty, Tricuspid valve, business.industry, Sinoatrial node, Atrioventricular node, Inferior vena cava, medicine.anatomical_structure, medicine.vein, Superior vena cava, Internal medicine, Mitral valve, cardiovascular system, Cardiology, Medicine, Fossa ovalis, cardiovascular diseases, business, Coronary sinus

Abstract

We used multiple techniques to generate a three-dimensional anatomical model of the rabbit right atrium with the sinoatrial node (SAN) and atrioventricular node (AVN). The model includes the right atrium, SAN, AVN, part of right ventricle, aorta with aortic valve, superior vena cava, inferior vena cava, coronary sinus, tricuspid valve, part of mitral valve, fossa ovalis and central fibrous body. The tendon of Todaro and right and left sinoatrial ring bundles were highlighted as landmarks

Published

2005

5. Structure-function relationship in the AV junction

Author

Florence Rothenberg, I.D. Greener, Halina Dobrzynski, Igor R. Efimov, Mark R. Boyett, Jue Li, and Vladimir P. Nikolski

Subjects

Sinoatrial node, Gap junction, Arrhythmias, Cardiac, Reentry, Anatomy, Biology, medicine.disease, Agricultural and Biological Sciences (miscellaneous), Atrioventricular node, Electrophysiology, Structure-Activity Relationship, medicine.anatomical_structure, Optical mapping, medicine, Atrioventricular Node, Animals, Humans, Electrical conduction system of the heart, Junctional rhythm

Abstract

In the normal heart, the atrioventricular node (AVN) is part of the sole pathway between the atria and ventricles. Under normal physiological conditions, the AVN controls appropriate frequency-dependent delay of contractions. The AVN also plays an important role in pathology: it protects ventricles during atrial tachyarrhythmia, and during sinoatrial node failure an AV junctional pacemaker can drive the heart. Finally, the AV junction provides an anatomical substrate for reentry. Using fluorescent imaging with voltage-sensitive dyes and immunohistochemistry, we have investigated the structure-function relationship of the AV junction during normal conduction, reentry, and junctional rhythm. We identified molecular and structural heterogeneity that provides a substrate for the dual-pathway AVN conduction. We observed heterogeneity of expression of three isoforms of connexins: Cx43, Cx45, and Cx40. We identified the site of origin of junctional rhythm at the posterior extension of the AV node in 79% (n = 14) of the studied hearts. This structure was similar to the compact AV node as determined by morphologic and molecular investigations. In particular, both the posterior extension and the compact node express the pacemaking channel HCN4 (responsible for the I(F) current) and neurofilament 160. In the rabbit heart, AV junction conduction, reentrant arrhythmia, and spontaneous rhythm are governed by heterogeneity of expression of several isoforms of gap junctions and ion channels. Uniform neurofilament expression suggests that AV nodal posterior extensions are an integral part of the cardiac pacemaking and conduction system. On the other hand, differential expression of Cx isoforms in this region provides an explanation of longitudinal dissociation, dual-pathway electrophysiology, and AV nodal reentrant arrhythmogenesis.

Published

2004

6. Site of origin and molecular substrate of atrioventricular junctional rhythm in the rabbit heart

Author

A.T. Sambelashvili, Igor R. Efimov, Mark R. Boyett, I.D. Greener, Vladimir P. Nikolski, Mitsuru Yamamoto, and Halina Dobrzynski

Subjects

Optics and Photonics, Periodicity, Potassium Channels, Physiology, Connexin, Cesium, Cyclic Nucleotide-Gated Cation Channels, Muscle Proteins, Pyridinium Compounds, Biology, In Vitro Techniques, Connexins, Ion Channels, Pacemaker potential, Biological Clocks, Heart Rate, Neurofilament Proteins, medicine, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels, Animals, Heart Atria, Coronary sinus, Sinoatrial Node, Tricuspid valve, Sinoatrial node, Body Surface Potential Mapping, Anatomy, Reentry, medicine.disease, Atrial Function, Atrioventricular node, medicine.anatomical_structure, Connexin 43, Atrioventricular Node, Rabbits, Cardiology and Cardiovascular Medicine, Electrophysiologic Techniques, Cardiac, Junctional rhythm

Abstract

During failure of the sinoatrial node, the heart can be driven by an atrioventricular (AV) junctional pacemaker. The position of the leading pacemaker site during AV junctional rhythm is debated. In this study, we present evidence from high-resolution fluorescent imaging of electrical activity in rabbit isolated atrioventricular node (AVN) preparations that, in the majority of cases (11 out of 14), the AV junctional rhythm originates in the region extending from the AVN toward the coronary sinus along the tricuspid valve (posterior nodal extension, PNE). Histological and immunohistochemical investigation showed that the PNE has the same morphology and unique pattern of expression of neurofilament160 (NF160) and connexins (Cx40, Cx43, and Cx45) as the AVN itself. Block of the pacemaker current, I f , by 2 mmol/L Cs + increased the AV junctional rhythm cycle length from 611±84 to 949±120 ms (mean±SD, n=6, P I f channel protein, HCN4, is abundant in the PNE. As well as the AV junctional rhythm, the PNE described in this study may also be involved in the slow pathway of conduction into the AVN as well as AVN reentry, and the predominant lack of expression of Cx43 as well as the presence of Cx45 in the PNE shown could help explain its slow conduction.

Published

2003

7. Distribution of ion channel transcripts in the rabbit atrioventricular node as studied using in situ hybridisation and quantitative PCR

Author

Halina Dobrzynski, Mark R. Boyett, Mitsuru Yamamoto, R. Billeter-Clark, I.D. Greener, and James O. Tellez

Subjects

medicine.anatomical_structure, Real-time polymerase chain reaction, Chemistry, In situ hybridisation, medicine, Distribution (pharmacology), Rabbit (nuclear engineering), Cardiology and Cardiovascular Medicine, Molecular Biology, Atrioventricular node, Molecular biology, Ion channel

Published

2006

8. Expression of Kir2.1 and Kir6.2 transgenes under the control of the alpha-MHC promoter in the sinoatrial and atrioventricular nodes in transgenic mice

Author

I.D. Greener, Rudi Billeter, Thomas P. Flagg, Anatoli N. Lopatin, Colin G. Nichols, N.J. Chandler, Halina Dobrzynski, James O. Tellez, and Mark R. Boyett

Subjects

Protein subunit, Mice, Transgenic, Biology, Mice, Biological Clocks, medicine, Animals, Transgenes, Potassium Channels, Inwardly Rectifying, Promoter Regions, Genetic, Molecular Biology, Ion channel, Sinoatrial Node, Myosin Heavy Chains, Sinoatrial node, Inward-rectifier potassium ion channel, Myocardium, Kir2.1, Kir6.2, Molecular biology, medicine.anatomical_structure, Gene Expression Regulation, cardiovascular system, Atrioventricular Node, Heterologous expression, Electrical conduction system of the heart, Cardiology and Cardiovascular Medicine

Abstract

Kir2.1 and Kir6.2 are ion channel subunits partly responsible for the background inward rectifier and ATP-sensitive K(+) currents (I(K1) and I(KATP)) in the heart. Very little is known about how the distribution of ion channel subunits is controlled. In this study, we have investigated the expression (at protein and mRNA levels) of GFP-tagged Kir2.1 and Kir6.2 transgenes under the control of the alpha-MHC promoter in the sinoatrial node (SAN), atrioventricular node (AVN), His bundle and working myocardium of transgenic mice. After dissection, serial 10-microm cryosections were cut. Histological staining was carried out to identify tissues, confocal microscopy was carried out to map the distribution of the GFP-tagged ion channel subunits and in situ hybridization was carried out to map the distribution of corresponding mRNAs. We demonstrate heterologous expression of the ion channel subunits in the working myocardium, but not necessarily in the SAN, AVN or His bundle; the distribution of the subunits does not correspond to the expected distribution of alpha-MHC. Both protein and mRNA expression does, however, correspond to the expected distributions of native Kir6.2 and Kir2.1 in the SAN, AVN, His bundle and working myocardium. The data demonstrate novel transcriptional and/or post-transcriptional control of ion channel subunit expression and raise important questions about the control of regional expression of ion channels.

9. Development of 3-D anatomically-detailed mathematical models of the sinoatrial and atrioventricular nodes

Author

M. Yamamoto, Jue Li, Halina Dobrzynski, Igor R. Efimov, Rudi Billeter, I.D. Greener, Mark R. Boyett, and Vladimir P. Nikolski

Subjects

Sinus Node Artery, medicine.medical_specialty, Sinoatrial node, business.industry, Connective tissue, Anatomy, Atrioventricular node, Tendon, medicine.anatomical_structure, Internal medicine, cardiovascular system, medicine, Ventricular muscle, Cardiology, cardiovascular diseases, business, Cellular biophysics

Abstract

We used multiple techniques to construct 3D anatomical models of the rabbit sinoatrial node (SAN) and atrioventricular node (AVN). The 3D SAN model includes atrial muscle (only atrial cells), central SAN (only central SAN cells), peripheral SAN (a mixture of peripheral SAN cells, 'central' SAN cells and atrial cells), connective tissue and the sinus node artery. The 3D AVN model includes atrial muscle, ventricular muscle, AVN, a possible transitional zone (loosely packed atrial cells) and connective tissue (including the tendon of Todaro).