Reloading of Ca(2+)-depleted sarcoplasmic reticulum during rest in guinea pig ventricular myocytes

Effects of Sarcolemmal Background Ca2+ Entry and Sarcoplasmic Ca2+ Leak Currents on Electrophysiology and Ca2+ Transients in Human Ventricular Cardiomyocytes: A Computational Comparison

The intricate regulation of the compartmental Ca²⁺ concentrations in cardiomyocytes is critical for electrophysiology, excitation-contraction coupling, and other signaling pathways. Research into the complex signaling pathways is motivated by cardiac pathologies including arrhythmia and maladaptive myocyte remodeling, which result from Ca²⁺ dysregulation. Of interest to this investigation are two types of Ca²⁺ currents in cardiomyocytes: 1) background Ca²⁺ entry, i.e., Ca²⁺ transport across the sarcolemma from the extracellular space into the cytosol, and 2) Ca²⁺ leak from the sarcoplasmic reticulum (SR) across the SR membrane into the cytosol. Candidates for the ion channels underlying background Ca²⁺ entry and SR Ca²⁺ leak channels include members of the mechano-modulated transient receptor potential (TRP) family. We used a mathematical model of a human ventricular myocyte to analyze the individual contributions of background Ca²⁺ entry and SR Ca²⁺ leak to the modulation of Ca²⁺ transients and SR Ca²⁺ load at rest and during action potentials. Background Ca²⁺ entry exhibited a positive relationship with both [Ca²⁺]_i and [Ca²⁺]_SR. Modulating SR Ca²⁺ leak had opposite effects of background Ca²⁺ entry. Effects of SR Ca²⁺ leak on Ca²⁺ were particularly pronounced at lower pacing frequency. In contrast to the pronounced effects of background and leak Ca²⁺ currents on Ca²⁺ concentrations, the effects on cellular electrophysiology were marginal. Our studies provide quantitative insights into the differential modulation of compartmental Ca²⁺ concentrations by the background and leak Ca²⁺ currents. Furthermore, our studies support the hypothesis that TRP channels play a role in strain-modulation of cardiac contractility. In summary, our investigations shed light on the physiological effects of the background and leak Ca²⁺ currents and their contribution to the development of disease caused by Ca²⁺ dysregulation.

Interaction of background Ca2+ influx, sarcoplasmic reticulum threshold and heart failure in determining propensity for Ca2+ waves in sheep heart

Ventricular arrhythmias can cause death in heart failure (HF). A trigger is the occurrence of Ca²⁺ waves which activate a Na⁺ -Ca²⁺ exchange (NCX) current, leading to delayed after-depolarisations and triggered action potentials. Waves arise when sarcoplasmic reticulum (SR) Ca²⁺ content reaches a threshold and are commonly induced experimentally by raising external Ca²⁺ , although the mechanism by which this causes waves is unclear and was the focus of this study. Intracellular Ca²⁺ was measured in voltage-clamped ventricular myocytes from both control sheep and those subjected to rapid pacing to produce HF. Threshold SR Ca²⁺ content was determined by applying caffeine (10  mM) following a wave and integrating wave and caffeine-induced NCX currents. Raising external Ca²⁺ induced waves in a greater proportion of HF cells than control. The associated increase of SR Ca²⁺ content was smaller in HF due to a lower threshold. Raising external Ca²⁺ had no effect on total influx via the L-type Ca²⁺ current, I_Ca-L , and increased efflux on NCX. Analysis of sarcolemmal fluxes revealed substantial background Ca²⁺ entry which sustains Ca²⁺ efflux during waves in the steady state. Wave frequency and background Ca²⁺ entry were decreased by Gd³⁺ or the TRPC6 inhibitor BI 749327. These agents also blocked Mn²⁺ entry. Inhibiting connexin hemi-channels, TRPC1/4/5, L-type channels or NCX had no effect on background entry. In conclusion, raising external Ca²⁺ induces waves via a background Ca²⁺ influx through TRPC6 channels. The greater propensity to waves in HF results from increased background entry and decreased threshold SR content. KEY POINTS: Heart failure is a pro-arrhythmic state and arrhythmias are a major cause of death. At the cellular level, Ca²⁺ waves resulting in delayed after-depolarisations are a key trigger of arrhythmias. Ca²⁺ waves arise when the sarcoplasmic reticulum (SR) becomes overloaded with Ca²⁺ . We investigate the mechanism by which raising external Ca²⁺ causes waves, and how this is modified in heart failure. We demonstrate that a novel sarcolemmal background Ca²⁺ influx via the TRPC6 channel is responsible for SR Ca²⁺ overload and Ca²⁺ waves. The increased propensity for Ca²⁺ waves in heart failure results from an increase of background influx, and a lower threshold SR content. The results of the present study highlight a novel mechanism by which Ca²⁺ waves may arise in heart failure, providing a basis for future work and novel therapeutic targets.

Kinetic mechanisms by which nickel alters the calcium (Ca2+) transport in intact rat liver

In the present work, the multiple-indicator dilution (MID) technique was used to investigate the kinetic mechanisms by which nickel (Ni²⁺) affects the calcium (Ca²⁺) transport in intact rat liver. ⁴⁵Ca²⁺ and extra- and intracellular space indicators were injected in livers perfused with 1 mM Ni²⁺, and the outflow profiles were analyzed by a mathematical model. For comparative purposes, the effects of norepinephrine were measured. The influence of Ni²⁺ on the cytosolic Ca²⁺ concentration ([Ca²⁺]_c) in human hepatoma Huh7 cells and on liver glycogen catabolism, a biological response sensitive to cellular Ca²⁺, was also evaluated. The estimated transfer coefficients of ⁴⁵Ca²⁺ transport indicated two mechanisms by which Ni²⁺ increases the [Ca²⁺]_c in liver under steady-state conditions: (1) an increase in the net efflux of Ca²⁺ from intracellular Ca²⁺ stores due to a stimulus of Ca²⁺ efflux to the cytosolic space along with a diminution of Ca²⁺ re-entry into the cellular Ca²⁺ stores; (2) a decrease in Ca²⁺ efflux from the cytosolic space to vascular space, minimizing Ca²⁺ loss. Glycogen catabolism activated by Ni²⁺ was transient contrasting with the sustained activation induced by norepinephrine. Ni²⁺ caused a partial reduction in the norepinephrine-induced stimulation in the [Ca²⁺]_c in Huh7 cells. Our data revealed that the kinetic parameters of Ca²⁺ transport modified by Ni²⁺ in intact liver are similar to those modified by norepinephrine in its first minutes of action, but the membrane receptors or Ca²⁺ transporters affected by Ni²⁺ seem to be distinct from those known to be modulated by norepinephrine.

The Control of Diastolic Calcium in the Heart: Basic Mechanisms and Functional Implications

Normal cardiac function requires that intracellular Ca²⁺ concentration be reduced to low levels in diastole so that the ventricle can relax and refill with blood. Heart failure is often associated with impaired cardiac relaxation. Little, however, is known about how diastolic intracellular Ca²⁺ concentration is regulated. This article first discusses the reasons for this ignorance before reviewing the basic mechanisms that control diastolic intracellular Ca²⁺ concentration. It then considers how the control of systolic and diastolic intracellular Ca²⁺ concentration is intimately connected. Finally, it discusses the changes that occur in heart failure and how these may result in heart failure with preserved versus reduced ejection fraction.

Modulation of membrane potential by an acetylcholine-activated potassium current in trout atrial myocytes

Application of the current-clamp technique in rainbow trout atrial myocytes has yielded resting membrane potentials that are incompatible with normal atrial function. To investigate this paradox, we recorded the whole membrane current ( Im) and compared membrane potentials recorded in isolated cardiac myocytes and multicellular preparations. Atrial tissue and ventricular myocytes had stable resting potentials of −87 ± 2 mV and −83.9 ± 0.4 mV, respectively. In contrast, 50 out of 59 atrial myocytes had unstable depolarized membrane potentials that were sensitive to the holding current. We hypothesized that this is at least partly due to a small slope conductance of Imaround the resting membrane potential in atrial myocytes. In accordance with this hypothesis, the slope conductance of Imwas about sevenfold smaller in atrial than in ventricular myocytes. Interestingly, ACh increased Imat −120 mV from 4.3 pA/pF to 27 pA/pF with an EC50of 45 nM in atrial myocytes. Moreover, 3 nM ACh increased the slope conductance of Imfourfold, shifted its reversal potential from −78 ± 3 to −84 ± 3 mV, and stabilized the resting membrane potential at −92 ± 4 mV. ACh also shortened the action potential in both atrial myocytes and tissue, and this effect was antagonized by atropine. When applied alone, atropine prolonged the action potential in atrial tissue but had no effect on membrane potential, action potential, or Imin isolated atrial myocytes. This suggests that ACh-mediated activation of an inwardly rectifying K+current can modulate the membrane potential in the trout atrial myocytes and stabilize the resting membrane potential.