J. A. Wasserstrom

Alterations in muscarinic K+ channel response to acetylcholine and to G protein-mediated activation in atrial myocytes isolated from failing human hearts.

BACKGROUND A variety of previous studies have demonstrated reduced diastolic potential and electrical activity in atrial specimens from patients with heart disease. Although K+ channels play a major role in determining resting membrane potential and repolarization of the action potential, little is known about the effects of preexisting heart disease on human atrial K+ channel activity. METHODS AND RESULTS We characterized the inwardly rectifying K+ channel (IKI) and the muscarinic K+ channel [IK(ACh)] in atrial myocytes isolated from patients with heart failure (HF) and compared electrophysiological characteristics with those from donors (control) by the patch-clamp technique. Resting membrane potentials of isolated atrial myocytes from HF were more depolarized (-51.1 +/- 9.7 mV, mean +/- SD, n = 30 patients) than those from donors (-73.0 +/- 7.2 mV, n = 4 patients, P < .001). The action potential duration in HF was longer than that in donors. Although acetylcholine (ACh) shortened the action potential, reduced the overshoot, and hyperpolarized the atrial cell membrane in HF, these effects were attenuated compared with those observed in donors. The whole-cell membrane current slope conductance in HF was small, the reversal potential was more positive, and the sensitivity to ACh was less compared with donors. In single-channel recordings from cell-attached patches, IK1 channel conductance and gating characteristics were the same in HF and donor atria. When ACh was included in the pipette solution, IK(ACh) was activated in both groups. Single-channel slope conductance of IK(ACh) averaged 42 +/- 3 pS (n = 28) in HF and 44 +/- 2 pS (n = 4) in donors, and mean open lifetime was 1.3 +/- 0.3 milliseconds (n = 24) in HF and 1.5 +/- 0.4 milliseconds (n = 4) in donors. These values were virtually identical in the two groups (not significantly different, NS), although both single IK1 and IK(ACh) channel densities were less in HF. Channel open probability of IK(ACh) was also less in HF (4.0 +/- 1.2%, n = 24) than in donors (6.8 +/- 1.1%, n = 3, P < .01). The concentration of ACh at half-maximal activation was 0.11 mumol/L in HF and 0.03 mumol/L in donors. In excised inside-out patches, IK(ACh) from HF required higher concentrations of GTP and GTP gamma S to activate the channel compared with donors. These results suggest a reduced IK(ACh) channel sensitivity to M2 cholinergic receptor-linked G protein (Gi) in HF compared with donors. CONCLUSIONS Atrial myocytes isolated from failing human hearts exhibited a lower resting membrane potential and reduced sensitivity to ACh compared with donor atria. Whole-cell and single-channel measurements suggest that these alterations are caused by reduced IK1 and IK(ACh) channel density and reduced IK(ACh) channel sensitivity to Gi-mediated channel activation in HF.

Modification of cardiac Na+ channels by batrachotoxin: effects on gating, kinetics, and local anesthetic binding.

The purpose of the present study was to examine the characteristics of Na+ channel modification by batrachotoxin (BTX) in cardiac cells, including changes in channel gating and kinetics as well as susceptibility to block by local anesthetic agents. We used the whole cell configuration of the patch clamp technique to measure Na+ current in guinea pig myocytes. Extracellular Na+ concentration and temperature were lowered (5-10 mM, 17 degrees C) in order to maintain good voltage control. Our results demonstrated that 1) BTX modifies cardiac INa, causing a substantial steady-state (noninactivating) component of INa, 2) modification of cardiac Na+ channels by BTX shifts activation to more negative potentials and reduces both maximal gNa and selectivity for Na+; 3) binding of BTX to its receptor in the cardiac Na+ channel reduces the affinity of local anesthetics for their binding site; and 4) BTX-modified channels show use-dependent block by local anesthetics. The reduced blocking potency of local anesthetics for BTX-modified Na+ channels probably results from an allosteric interaction between BTX and local anesthetics for their respective binding sites in the Na+ channel. Our observations that use-dependent block by local anesthetics persists in BTX-modified Na+ channels suggest that this form of extra block can occur in the virtual absence of the inactivated state. Thus, the development of use-dependent block appears to rely primarily on local anesthetic binding to activated Na+ channels under these conditions.

Characteristics of cocaine block of purified cardiac sarcoplasmic reticulum calcium release channels

We have examined the effects of cocaine on the SR Ca2+ release channel purified from canine cardiac muscle. Cocaine induced a flicker block of the channel from the cytoplasmic side, which resulted in an apparent reduction in the single-channel current amplitude without a marked reduction in the single-channel open probability. This block was evident only at positive holding potentials. Analysis of the block revealed that cocaine binds to a single site with an effective valence of 0.93 and an apparent dissociation constant at 0 mV (Kd(0)) of 38 mM. The kinetics of cocaine block were analyzed by amplitude distribution analysis and showed that the voltage and concentration dependence lay exclusively in the blocking reaction, whereas the unblocking reaction was independent of both voltage and concentration. Modification of the channel by ryanodine dramatically attenuated the voltage and concentration dependence of the on rates of cocaine block while diminishing the off rates to a lesser extent. In addition, ryanodine modification changed the effective valence of cocaine block to 0.52 and the Kd(0) to 110 mM, suggesting that modification of the channel results in an alteration in the binding site and its affinity for cocaine. These results suggest that cocaine block of the SR Ca2+ release channel is due to the binding at a single site within the channel pore and that modification of the channel by ryanodine leads to profound changes in the kinetics of cocaine block.

Histone Deacetylase 1 Deficiency Impairs Differentiation and Electrophysiological Properties of Cardiomyocytes Derived from Induced Pluripotent Cells

Epigenetic and chromatin modifications play particularly important roles in embryonic and induced pluripotent stem cells (ESCs and iPSCs) allowing for the cells to both differentiate and dedifferentiate back to a pluripotent state. We analyzed how the loss of a key chromatin‐modifying enzyme, histone deacetylase 1 (HDAC1), affects early and cardiovascular differentiation of both ESCs and iPSCs. We also investigated potential differences between these two cell types when differentiation is induced. Our data indicate an essential role for HDAC1 in deacetylating regulatory regions of key pluripotency‐associated genes during early differentiation. Although HDAC1 functions primarily as a HDAC, its loss also affects DNA methylation in ESCs and iPSCs both during pluripotency and differentiation. We show that HDAC1 plays a crucial, nonredundant role in cardiomyocyte differentiation and maturation. Our data also elucidate important differences between ESCs and iPSCs, when levels of this enzyme are reduced, that affect their ability to differentiate into functional cardiomyocytes. As varying levels of chromatin‐modifying enzymes are likely to exist in patient‐derived iPSCs, understanding the molecular circuitry of these enzymes in ESCs and iPSCs is critical for their potential use in cardiovascular therapeutic applications. STEM CELLS2012;30:2412–2422

Elucidation of a novel pathway through which HDAC1 controls cardiomyocyte differentiation through expression of SOX-17 and BMP2.

Embryonic Stem Cells not only hold a lot of potential for use in regenerative medicine, but also provide an elegant and efficient way to study specific developmental processes and pathways in mammals when whole animal gene knock out experiments fail. We have investigated a pathway through which HDAC1 affects cardiovascular and more specifically cardiomyocyte differentiation in ES cells by controlling expression of SOX17 and BMP2 during early differentiation. This data explains current discrepancies in the role of HDAC1 in cardiovascular differentiation and sheds light into a new pathway through which ES cells determine cardiovascular cell fate.

T‐tubule remodeling and increased heterogeneity of calcium release during the progression to heart failure in intact rat ventricle

A highly organized transverse‐tubule (TT) system is essential to normal Ca2+ cycling and cardiac function. We explored the relationship between the progressive disruption of TTs and resulting Ca2+ cycling during the development of heart failure (HF). Confocal imaging was used to measure Ca2+ transients and 2‐D z‐stack images in left ventricular epicardial myocytes of intact hearts from spontaneously hypertensive rats (SHR) and Wistar‐Kyoto control rats. TT organization was measured as the organizational index (OI) derived from a fast Fourier transform of TT organization. We found little decrease in the synchrony of Ca2+ release with TT loss until TT remodeling was severe, suggesting a TT “reserve” characterized by a wide range of TT remodeling with little effect on synchrony of release but beyond which variability in release shows an accelerating sensitivity to TT loss. To explain this observation, we applied a computational model of spatially distributed Ca2+ signaling units to investigate the relationship between OI and excitation‐contraction coupling. Our model showed that release heterogeneity exhibits a nonlinear relationship on both the spatial distribution of release units and the separation between L‐type Ca2+ channels and ryanodine receptors. Our results demonstrate a unique relationship between the synchrony of Ca2+ release and TT organization in myocytes of intact rat ventricle that may contribute to both the compensated and decompensated phases of heart failure.