Outward sodium current in beating heart cells.

This article is a study of the fast Na current during action potentials. We have investigated the outward Na current (Mazzanti, M., and L.J. DeFelice. 1987. Biophys. J. 52:95-100) in more detail, and we have asked whether it goes through the same channels associated with the rapid depolarization phase of action potentials. We address the question by patch clamping single, spontaneously beating, embryonic chick ventricle cells, using two electrodes to record the action potential and the patch current simultaneously. The chief limitation is the capacitive current, and in this article we describe a new method to subtract it. Varying the potential and the Na concentration in the patch pipette, and fitting the corrected currents to a standard model (Ebihara, L., and E.A. Johnson. 1980. Biophys. J. 32:779-790), provides evidence that the outward current is carried by the same channels that conduct the inward current. We compare the currents in beating cells to currents in nonbeating cells using whole-cell and cell-attached patch clamp recordings. The latter tend to show more positive Na reversal potentials, with the implication that internal Na is higher in beating cells. We propose that the plateau of the action potential, which is partly due to an inward Ca current, exceeds Na action current reversal potentials, and that this driving force gives rise to an outward movement of Na ions. The existence of such a current would imply that the fast repolarization phase after the upstroke of cardiac action potentials is partly due to the Na action current.     

Photoelectric monitoring of single beating heart cells in culture

This paper characterizes a photoelectric recording system which monitors individual beating heart cells in vitro. A culture procedure which supports continued beating for up to three months without confluent overgrowth or aggregation is described.     

Partial and incomplete oxidation of palmitate by cultured beating cardiac cells from neonatal rats.

The discrepancy in the rate of [14C]O2 formation from either [1-14C]- or [16-14C]palmitate is demonstrated and could be explained by the preferential formation of L-(+)-3-hydroxybutyrate from the four carbon atoms at the omega terminus. The identity of this product as L(+)-3-hydroxybutyrate was established and shown to be the major component of the radioactive products in the extracellular medium from palmitate based on (a) ion-exchange chromatographical properties, (b) gas-liquid chromatography, (c) mass spectrometric analysis, (d) stereoisomeric separation, and (e) its very low rate of utilization by the cells. We therefore propose a shunt to the oxidation of palmitate in these cells occurring at the stage of L(+)-hydroxybutyryl-CoA which undergoes deacylation causing the product to be transported outside the cell.     

Compartmentation of high-energy phosphates in resting and beating heart cells

The subcellular distribution of ATP, ADP, creatine phosphate and creatine has been analyzed by fast detergent fractionation of isolated frog heart cells. Digitonin fractionation (0.5 mg/ml, 10 s at 2 degrees C in 20 mM 4-morpholinepropanesulfonic acid/3 mM EDTA/230 mM mannitol medium) was used to separate mitochondria and myofilaments from cytosol. To separate myofilaments from the other cellular compartments. Triton X-100 was used (2%, 15 s in the same medium as digitonin). For either resting or beating cells the total cellular contents of ATP, ADP, creatine phosphate and creatine was similar, nevertheless the O2 consumption was 6-times higher. The compartmentation of these metabolites was also identical. Myofilaments contain 1.1 nmol ADP per mg total cellular proteins. In the cytosolic compartment the metabolite concentrations, all measured in nmol per mg total cellular proteins, were: ATP, 13; ADP, 0.25-0.05; creatine phosphate, 18.5 and creatine, 14. This indicated that the reaction catalyzed by creatine kinase was in a state of (or near) equilibrium.     

Growth of dissociated beating human heart cells in tissue culture

Fetal human heart cells have been dissociated by trypsinization and successfully grown in tissue culture on two occassions. The characteristics of the growth and mitotic activity were quite similar to those previously found for rodent heart cells. The maximum beating rates seen in the cultures from each specimen were 33 and 75 per minute.     

Closed loop television tracking of beating heart cells in vitro

The motion of beating heart cells in vitro has been used as a sensitive indicator of the presence of drugs. The combination of closed loop television video tracking and latex microspheres placed on the cells as markers results in an improved measurement of cell motion. Latex microspheres, 5.2 micrometers, are allowed to settle onto beating myocardial heart cells in vitro, where they move in concert with the cell motion. These microspheres, when viewed by televised transmission microscopy with normal optics, present high contrast circular targets that are excellent for closed loop television video tracking techniques. With video tracking, an analog voltage is generated proportional to the horizontal center of intensity of the target being tracked. This signal represents the location of a video demodulator gate that is maintained centered over the video target by feedback control.     

Dispersion and isolation of beating cells from adult rat heart

The cells of adult rat heart ventricles were dispersed using crude bacterial collagenase. An investigation into the effect of shaking speed, stroke length, concentration of enzyme, ionic composition, and pH of the dispersing medium permitted the development of optimal conditions for obtaining beating myocytes. Approximately one-quarter of the initial protein content of ventricular chunks could be routinely recovered as single cells after such dispersion. Centrifugation through solutions of Ficoll in phosphate buffer selectively concentrated the beating myocytes and removed contaminating cells and tissue debris.     

Carbocyanine dyes stain the sarcoplasmic reticulum of beating heart cells

In search of a fluorescent dye suitable for monitoring membrane potentials of beating heart cells, we noticed that the carbocyanine dyes, CC₅ and CC₆, show a unique pattern of intracellular distribution in vital and glutaraldehyde-fixed cardiomyoblasts. This distribution is clearly different from that observed in fibroblasts. In heart cells, it parallels the localization of actin-myosin containing myofilaments as visualized by fluorescent antibody staining but it does not correspond to the localization of actin filaments or the microtubules. In fibroblasts these dyes stain only fine filaments and granules in the perinuclear space which correspond to the endoplasmic reticulum. This observation is evidence in support of the hypothesis that carbocyanine dyes accumulate selectively in the sarcoplasmic reticulum. It indicates that certain carbocyanine dyes may be useful tools to differentiate between muscle cells and connective tissue cells in cell cultures.     

The influence of hypertonic solutions on cultured beating rat heart cells

Hypertonic stress caused by sucrose and sorbitol followed by reincubation in isotonic medium causes irreversible damage to synchronously beating heart cells. These results can be explained by a “Minimum Cell Volume” theory as proposed by Meryman. During exposure to hypertonic NaCl solutions damage to the contractility depends on the incubation time. Damage to the individual cell survival seems to be less dependent on the incubation period.