Connexin Hemichannels: Methods for Dye Uptake and Leakage.

It is now clear that connexin-based, gap junction "hemichannels" in an undocked state are capable of opening and connecting cytoplasm to the extracellular milieu. Varied studies also suggest that such channel activity plays a vital role in diverse cell processes and abnormal hemichannel activity contributes to pathogenesis. To pursue fundamental questions in this area, investigators require methods for studying hemichannel permeability and dynamics that are quantitative, sensitive, versatile, and available to most cellular and molecular laboratories. Here we first provide a theoretical background for this work, including the role of cellular membrane potentials. We then describe in detail our computer-assisted methods for both dye uptake and leakage along with illustrative results from different cell systems. A key feature of our protocol is the inclusion of a mechanical stimulation step. We describe dye uptake, interpreted as connexin dependent, that is shown to be enhanced with reduced extracellular Ca2+, mechanically responsive, inhibited by TPA, inhibited by EL186 antibodies for Cx43 and sustained for more than 15 min following mechanical stimulation. We describe dye leakage that displays these same properties, with estimates of hemichannel numbers per cell being derived from leakage rates. We also describe dye uptake that is shown to be unaffected by a reduction in external Ca2+, insensitive to EL186 antibodies and relatively short-lived following mechanical stimulation; this uptake may occur via pannexin 1 channels expressed in the cells studied here. It is unlikely that cell damage plays a significant role in dye uptake following mechanical stimulation, given compelling results from various control experiments.

[Characteristics of the action potentials and the underlying ionic mechanisms in the cardiomyocytes from rabbit pulmonary vein sleeves].

To investigate the characteristics of action potentials and their ionic mechanism in cardiomyocytes from rabbit pulmonary vein sleeves (PVC), and to compare them with those in left atrial cardiomyocytes (LAC), the technique of whole-cell patch clamp was applied. We used current-clamp technique to record action potentials, and voltage-clamp technique to record ionic currents. PVC had longer action potential duration (APD) than LAC, and therefore a second plateau response could be induced easily, suggesting a strong tendency of early afterdepolarization (EAD) genesis in PVC. Non-selective cation current (I(NSCC)) was first recorded in both LAC and PVC. This I(NSCC)was permeable to K(+), Na(+) and Cs(+), sensitive to GdCl3 but not sensitive to 4-AP. The current densities of inward rectifier potassium current (I(K1)), transient outward potassium current (I(To)) and I(NSCC) were all significantly less in PVC than those in LAC. These differences in repolarizing ionic currents between PVC and LAC form a basis of the differences in their action potential configurations and might be an important ionic mechanism of the arrhythmogenic characteristics of pulmonary vein muscle sleeves.

[An nonselective cation current in rabbit ventricle myocytes].

OBJECTIVE: Currents contributing repolarization in rabbit ventricular myocyte are very complex since the I(To.s) covers almost the whole repolarization phase of the action potential. The other components of repolarizing currents, as I(Kr) and I(Ks) are small. The purpose of this study is to investigate whether or not there are other currents in rabbit ventricular repolarization. METHODS: Ion currents of rabbit ventricular myocyte were recorded using the whole-cell patch-clamp technique. RESULTS: In the present work, an nonselective cation current was identified by replacing the K(+) with Cs(+) in the bathing and pipette solutions. The outward current elicited by depolarizing potentials could be inhibited by Gd(3+), an effective inhibitor of nonselective cation currents. Depleting Ca(2+) and Mg(2+) in the bathing solution, the amplitudes of this outward current increased by 40%-116% at +60 mV, and adding 2 micromol/L insulin to the solution (with normal concentration of Ca(2+) and Mg(2+) in Tyrode's solution), the amplitude increased by 30%-60% at +60 mV. CONCLUSION: It is suggested that a nonselective cation current in rabbit ventricular myocytes may play an important role in the repolarization of the action potential in rabbit ventricle. Changes of nonselective cation current will lead to induce or inhibit arrhythmia.