Mathematical Simulation of the Rabbit Heterogeneous Intact Sinoatrial Node Using Similitude Theory

Biophysics - Abstract—In this work, the electrical activity of the heterogeneous intact sinoatrial node at interaction with the atrial myocardium is simulated based on a detailed approach....     

Complete Atrial-Specific Knockout of Sodium-Calcium Exchange Eliminates Sinoatrial Node Pacemaker Activity

The origin of sinoatrial node (SAN) pacemaker activity in the heart is controversial. The leading candidates are diastolic depolarization by “funny” current (I_f) through HCN4 channels (the “Membrane Clock“ hypothesis), depolarization by cardiac Na-Ca exchange (NCX1) in response to intracellular Ca cycling (the "Calcium Clock" hypothesis), and a combination of the two (“Coupled Clock”). To address this controversy, we used Cre/loxP technology to generate atrial-specific NCX1 KO mice. NCX1 protein was undetectable in KO atrial tissue, including the SAN. Surface ECG and intracardiac electrograms showed no atrial depolarization and a slow junctional escape rhythm in KO that responded appropriately to β-adrenergic and muscarinic stimulation. Although KO atria were quiescent they could be stimulated by external pacing suggesting that electrical coupling between cells remained intact. Despite normal electrophysiological properties of I_f in isolated patch clamped KO SAN cells, pacemaker activity was absent. Recurring Ca sparks were present in all KO SAN cells, suggesting that Ca cycling persists but is uncoupled from the sarcolemma. We conclude that NCX1 is required for normal pacemaker activity in murine SAN.     

Distinct Patterns of Constitutive Phosphodiesterase Activity in Mouse Sinoatrial Node and Atrial Myocardium

Phosphodiesterases (PDEs) are critical regulators of cyclic nucleotides in the heart. In ventricular myocytes, the L-type Ca²⁺ current (I_Ca,L) is a major target of regulation by PDEs, particularly members of the PDE2, PDE3 and PDE4 families. Conversely, much less is known about the roles of PDE2, PDE3 and PDE4 in the regulation of action potential (AP) properties and I_Ca,L in the sinoatrial node (SAN) and the atrial myocardium, especially in mice. Thus, the purpose of our study was to measure the effects of global PDE inhibition with Isobutyl-1-methylxanthine (IBMX) and selective inhibitors of PDE2, PDE3 and PDE4 on AP properties in isolated mouse SAN and right atrial myocytes. We also measured the effects of these inhibitors on I_Ca,L in SAN and atrial myocytes in comparison to ventricular myocytes. Our data demonstrate that IBMX markedly increases spontaneous AP frequency in SAN myocytes and AP duration in atrial myocytes. Spontaneous AP firing in SAN myocytes was also increased by the PDE2 inhibitor erythro-9-[2-hydroxy-3-nonyl] adenine (EHNA), the PDE3 inhibitor milrinone (Mil) and the PDE4 inhibitor rolipram (Rol). In contrast, atrial AP duration was increased by EHNA and Rol, but not by Mil. IBMX also potently, and similarly, increased I_Ca,L in SAN, atrial and ventricular myocytes; however, important differences emerged in terms of which inhibitors could modulate I_Ca,L in each myocyte type. Consistent with our AP measurements, EHNA, Mil and Rol each increased I_Ca,L in SAN myocytes. Also, EHNA and Rol, but not Mil, increased atrial I_Ca,L. In complete contrast, no selective PDE inhibitors increased I_Ca,L in ventricular myocytes when given alone. Thus, our data show that the effects of selective PDE2, PDE3 and PDE4 inhibitors are distinct in the different regions of the myocardium indicating important differences in how each PDE family constitutively regulates ion channel function in the SAN, atrial and ventricular myocardium.     

Identification of 5'-Adenylylimidodiphosphate-Hydrolyzing Enzyme Activity in Rabbit Taste Bud Cells Using X-Ray Microanalysis

X-ray microanalysis has been used to characterize the enzyme activity hydrolyzing the ATP analogue 5'-adenylylimidodiphosphate (AMP-PNP) in taste bud cells. Rabbit foliate papillae fixed with paraformaldehyde and glutaraldehyde were incubated cytochemically with AMP-PNP as the substrate and lead ion as capture agent. The reaction product which appeared on the microvilli of taste bud cells was examined using an energy dispersive X-ray microanalyzer connected to an analytical electron microscope. The X-ray spectrum thus obtained was compared with that obtained from the product obtained from the demonstration of ATPase activity. Comparison of the phosphorus/lead ratios in the two products showed that twice as much phosphorus was released from an AMP-PNP molecule by the activity in question compared with that released from an ATP molecule by ATPase activity. This indicates that the enzyme hydrolyzes AMP-PNP into AMP and imidodiphosphate and that the enzyme is adenylate cyclase or ATP pyrophosphohydrolase, which possesses a similar hydrolytic property, but not ATPase or alkaline phosphatase, which hydrolyzes AMP-PNP into ADP-NHj and orthophosphate. This paper provides an example of the use of X-ray microanalysis as a tool for enzyme distinction. The method is applicable to a variety of enzymes and tissues.     

Ca2+/Calmodulin-Dependent Protein Kinase II (CaMKII) Activity and Sinoatrial Nodal Pacemaker Cell Energetics

Ca²⁺-activated basal adenylate cyclase (AC) in rabbit sinoatrial node cells (SANC) guarantees, via basal cAMP/PKA-calmodulin/CaMKII-dependent protein phosphorylation, the occurrence of rhythmic, sarcoplasmic-reticulum generated, sub-membrane Ca²⁺ releases that prompt rhythmic, spontaneous action potentials (APs). This high-throughput signaling consumes ATP.

Aims

We have previously demonstrated that basal AC-cAMP/PKA signaling directly, and Ca²⁺ indirectly, regulate mitochondrial ATP production. While, clearly, Ca²⁺-calmodulin-CaMKII activity regulates ATP consumption, whether it has a role in the control of ATP production is unknown.

Methods and Results

We superfused single, isolated rabbit SANC at 37°C with physiological saline containing CaMKII inhibitors, (KN-93 or autocamtide-2 Related Inhibitory Peptide (AIP)), or a calmodulin inhibitor (W-7) and measured cytosolic Ca²⁺, flavoprotein fluorescence and spontaneous AP firing rate. We measured cAMP, ATP and O₂ consumption in cell suspensions. Graded reductions in basal CaMKII activity by KN-93 (0.5–3 µmol/L) or AIP (2–10 µmol/L) markedly slow the kinetics of intracellular Ca²⁺ cycling, decrease the spontaneous AP firing rate, decrease cAMP, and reduce O₂ consumption and flavoprotein fluorescence. In this context of graded reductions in ATP demand, however, ATP also becomes depleted, indicating reduced ATP production.

Conclusions

CaMKII signaling, a crucial element of normal automaticity in rabbit SANC, is also involved in SANC bioenergetics.     

The Angiotensin-(1-7)/Mas Receptor Axis Is Expressed in Sinoatrial Node Cells of Rats

The authors’ previous studies have indicated that angiotensin(Ang)-(1-7) protects the heart against reperfusion arrhythmias. The aim of this study was to determine whether a functional angiotensin-converting enzyme2 (ACE2)/Ang-(1-7)/Mas receptor axis is present in the sinoatrial node (SAN) of Wistar rats. SAN cells were identified by Masson’s trichrome staining, HCN4 expression, and lack of connexin43 expression. Immunohistochemistry technique was used to detect the expression of ACE2, Ang-(1-7), and Mas in the SAN. To evaluate the role of this axis in the SAN function, atrial tachyarrhythmias (ATs) were induced in isolated rat atria perfused with Krebs-Ringer solution (KRS) alone (control) or KRS containing Ang-(1-7). The specific Mas antagonist, A-779, was used to evaluate the role of Mas in the Ang-(1-7) effects. The findings showed that all components of the ACE2/Ang-(1-7)/Mas branch are present in the SAN of rats. Importantly, it was found that this axis is functional because perfusion of atria with Ang-(1-7) significantly reduced the duration of ATs. Additionally, this anti-arrhythmogenic effect was attenuated by A-779. No significant changes were observed in heart rate, contractile tension, or ±dT/dt. These observations demonstrate that the ACE2/Ang-(1-7)/Mas axis is expressed in SAN cells of rats. They provide the morphological support to the anti-arrhythmogenic effect of Ang-(1-7).     

Cytochemical Localization of Guanylyl Cyclase Activity in Rabbit Taste Bud Cells

Guanylyl cyclase activity was cytochemically demonstrated inrabbit foliate taste buds. The enzymatic activity was localizedin the apical portion (microvilli and neck) of taste bud cells.Especially strong activity was observed on the microvillousmembrane of type I (dark) cells and often on a blunt processof type III cells. The microvilli of type II (light) cells showedweak enzymatic activity. Considering that the apical portionof taste cells is a likely site of interaction between tastestimuli and the cells, the results support the idea that cyclicGMP is involved in taste transduction.     

One-Dimensional Mathematical Model of the Atrioventricular Node Including Atrio-Nodal, Nodal, and Nodal-His Cells

Mathematical models are a repository of knowledge as well as research and teaching tools. Although action potential models have been developed for most regions of the heart, there is no model for the atrioventricular node (AVN). We have developed action potential models for single atrio-nodal, nodal, and nodal-His cells. The models have the same action potential shapes and refractoriness as observed in experiments. Using these models, together with models for the sinoatrial node (SAN) and atrial muscle, we have developed a one-dimensional (1D) multicellular model including the SAN and AVN. The multicellular model has slow and fast pathways into the AVN and using it we have analyzed the rich behavior of the AVN. Under normal conditions, action potentials were initiated in the SAN center and then propagated through the atrium and AVN. The relationship between the AVN conduction time and the timing of a premature stimulus (conduction curve) is consistent with experimental data. After premature stimulation, atrioventricular nodal reentry could occur. After slow pathway ablation or block of the L-type Ca²⁺ current, atrioventricular nodal reentry was abolished. During atrial fibrillation, the AVN limited the number of action potentials transmitted to the ventricle. In the absence of SAN pacemaking, the inferior nodal extension acted as the pacemaker. In conclusion, we have developed what we believe is the first detailed mathematical model of the AVN and it shows the typical physiological and pathophysiological characteristics of the tissue. The model can be used as a tool to analyze the complex structure and behavior of the AVN.     

Different Profile of mRNA Expression in Sinoatrial Node from Streptozotocin-Induced Diabetic Rat

BackgroundExperiments in isolated perfused heart have shown that heart rate is lower and sinoatrial node (SAN) action potential duration is longer in streptozotocin (STZ)–induced diabetic rat compared to controls. In sino-atrial preparations the pacemaker cycle length and sino-atrial conduction time are prolonged in STZ heart. To further clarify the molecular basis of electrical disturbances in the diabetic heart the profile of mRNA encoding a wide variety of proteins associated with the generation and transmission of electrical activity has been evaluated in the SAN of STZ-induced diabetic rat heart.Conclusions/SignificanceCollectively, this study has demonstrated differences in the profile of mRNA encoding a variety of proteins that are associated with the generation, conduction and regulation of electrical signals in the SAN of STZ-induced diabetic rat heart. Data from this study will provide a basis for a substantial range of future studies to investigate whether these changes in mRNA translate into changes in electrophysiological function.     

A Study of the Proliferative Response of Rabbit T Cells Using the Brdu-Hoechst Method

Con-A- and PHA-induced proliferation of cells from rabbit thymus, spleen and mesenteric lymph node was studied with the DNA-fluorescent probe 33258 Hoechst. the fluorescence of this probe is quenched when 5-bromo-2′-deoxy-uridine is incorporated into nascent DNA during the S phase. Fluorescence decreased with increasing content of newly formed DNA per cell. Proliferation kinetics and the number of Con-A- and PHA-reactive cells (C⁺ and P⁺ cells) were determined cytofluorometrically. Lymphocytes from control and dexamethasone (DX)-treated animals start their proliferation early: after 42 hr about 25% of the control and the majority of the DX-resistant cells finished their second cell division. Small numbers of C⁺ (12.0%) and P⁺ (3.5%) cells were found in control thymus, while these percentages were enhanced in DX thymus: 32.5 and 27.0% respectively; 50% of the spleen T cells in control and DX animals are C⁺ or P⁺ and 75% of the lymph-node T cells are C⁺ (after DX 45%) and 50% are P⁺ (after DX also 50%). It is concluded that in thymus and lymph nodes, a steroid sensitive (Ss) C⁺P^-, and in lymph nodes a Ss C⁺P⁺ cell pool is present. A mitogen non-proliferative cell pool (C^-P^-) is present in control and DX thymus.     

Beat-to-Beat Variation in Periodicity of Local Calcium Releases Contributes to Intrinsic Variations of Spontaneous Cycle Length in Isolated Single Sinoatrial Node Cells

Spontaneous, submembrane local Ca²⁺ releases (LCRs) generated by the sarcoplasmic reticulum in sinoatrial nodal cells, the cells of the primary cardiac pacemaker, activate inward Na⁺/Ca²⁺-exchange current to accelerate the diastolic depolarization rate, and therefore to impact on cycle length. Since LCRs are generated by Ca²⁺ release channel (i.e. ryanodine receptor) openings, they exhibit a degree of stochastic behavior, manifested as notable cycle-to-cycle variations in the time of their occurrence.

Aim

The present study tested whether variation in LCR periodicity contributes to intrinsic (beat-to-beat) cycle length variability in single sinoatrial nodal cells.

Methods

We imaged single rabbit sinoatrial nodal cells using a 2D-camera to capture LCRs over the entire cell, and, in selected cells, simultaneously measured action potentials by perforated patch clamp.

Results

LCRs begin to occur on the descending part of the action potential-induced whole-cell Ca²⁺ transient, at about the time of the maximum diastolic potential. Shortly after the maximum diastolic potential (mean 54±7.7 ms, n = 14), the ensemble of waxing LCR activity converts the decay of the global Ca²⁺ transient into a rise, resulting in a late, whole-cell diastolic Ca²⁺ elevation, accompanied by a notable acceleration in diastolic depolarization rate. On average, cells (n = 9) generate 13.2±3.7 LCRs per cycle (mean±SEM), varying in size (7.1±4.2 µm) and duration (44.2±27.1 ms), with both size and duration being greater for later-occurring LCRs. While the timing of each LCR occurrence also varies, the LCR period (i.e. the time from the preceding Ca²⁺ transient peak to an LCR’s subsequent occurrence) averaged for all LCRs in a given cycle closely predicts the time of occurrence of the next action potential, i.e. the cycle length.

Conclusion

Intrinsic cycle length variability in single sinoatrial nodal cells is linked to beat-to-beat variations in the average period of individual LCRs each cycle.     

Importance of Gradients in Membrane Properties and Electrical Coupling in Sinoatrial Node Pacing

The sinoatrial node (SAN) is heterogeneous in terms of cell size, ion channels, current densities, connexins and electrical coupling. For example, Na_v1.5 (responsible for I _Na) and Cx43 (responsible for electrical coupling) are absent from the centre of the SAN (normally the leading pacemaker site), but present in the periphery (at SAN-atrial muscle junction). To test whether the heterogeneity is important for the functioning of the SAN, one- and two-dimensional models of the SAN and surrounding atrial muscle were created. Normal functioning of the SAN (in terms of cycle length, position of leading pacemaker site, conduction times, activation and repolarization sequences and space constants) was observed when, from the centre to the periphery, (i) cell characteristics (cell size and ionic current densities) were changed in a gradient fashion from a central-type (lacking I _Na) to a peripheral-type (possessing I _Na) and (ii) coupling conductance was increased in a gradient fashion. We conclude that the heterogeneous nature of the node is important for its normal functioning. The presence of Na_v1.5 and Cx43 in the periphery may be essential for the node to be able to drive the atrial muscle: Na_v1.5 provides the necessary depolarizing current and Cx43 delivers it to the atrial muscle.     

Prospects for Using the Theory of Activity in Ethnopsychology

The question of the causes of differences in mental activity among different peoples has a long history. Each of the different branches of psychology deals with this question in its own way, but the basic factors that they identify are the same. Those analyzed in ethnopsychology, for instance, may be divided into several basic groups.     

Detecting Enzymatic Activity in Cells Using Fluorogenic Substrates

Fluorogenic substrates can detect enzymatic activity associated with cells. It is difficult, however, to detect activity within a single cell or in an organelle since hydrolytic substrates yield products that rapidly leak from the cell. Several new solutions are presented including trapping the fluorescent product in membranes, in cell organelles, or as a glutathione conjugate. Novel substrates also are described that directly yield highly fluorescent precipitates at the site of enzymatic activity. These can be used for detecting endogenous activity in cells or for enzyme-amplified histochemical detection. Some of these substrates can be used in live cells.     

NALCN: A Regulator of Pacemaker Activity

Pacemaker cells play a fundamental role in generating or regulating many essential biological rhythms. Spontaneous pacemaker activity is dependent on the function of an array of ion channels expressed in these cells. Recent characterization of a Na(+) leak channel (NALCN) has linked to its role in conducting the background Na(+) current that depolarizes resting membrane properties of pacemaker neurons. NALCN, along with Unc79 and Unc80, forms a protein complex that is involved in regulating intrinsic membrane and synaptic activities. In this review, we will discuss the current understanding of NALCN channel physiology and its role in regulating cell excitability and pacemaker activity.