Clive H. Orchard

Excitation-contraction coupling in rat ventricular myocytes after formamide-induced detubulation

Formamide-induced osmotic shock has been used to detubulate isolated adult rat ventricular myocytes (i.e., disrupt the surface membrane-T tubule junction). Cell volume, calculated from cell length and width, rapidly decreased and increased upon application and removal of formamide, respectively. After treatment with formamide, membrane capacitance decreased by 26.4% (from 199.4 ± 18.7 pF in control cells to 146.7 ± 6.4 pF in formamide-treated cells; n = 13, P < 0.05). However, the amplitude of the L-type Ca2+ current ( I Ca) decreased by a greater extent (from 0.75 ± 0.14 to 0.18 ± 0.03 nA; n = 5, P < 0.05) so that the density of I Ca decreased by 74.5%. Simultaneous measurements of I Ca and Ca2+ transients (monitored using fura 2) showed that both decreased rapidly upon removal of formamide. However, the Ca2+ content of the sarcoplasmic reticulum showed little change. Cross-striations, visualized with the fluorescent dye di-8-aminonaphthylethenylpyridinium, were sparse or absent in cells that had been treated with formamide, suggesting that formamide can successfully detubulate cardiac cells and that I Ca is concentrated in the T tubules, which therefore play an important role in excitation-contraction coupling.

Diastolic, systolic and sarcoplasmic reticulum [Ca2+] during inotropic interventions in isolated rat myocytes.

1. The fluorescent indicator Fura‐2 has been used to monitor intracellular [Ca2+] (Ca2+i) in myocytes isolated from the ventricles of rat hearts. 2. The relationships between diastolic Ca2+i, systolic Ca2+i and the Ca2+ content of the sarcoplasmic reticulum (SR; assayed using caffeine) have been studied during changes of stimulation rate and bathing [Ca2+] (Ca2+o). 3. When stimulation rate was increased, there were increases in diastolic Ca2+i, systolic Ca2+i and the Ca2+ content of the SR. 4. The SR inhibitor ryanodine (1 mumol l‐1) decreased the size of the Ca2+i transient, and abolished the increase of Ca2+i produced by caffeine (10 mmol l‐1). In the presence of ryanodine, increasing stimulation rate increased diastolic Ca2+i but not systolic Ca2+i. 5. Increasing Ca2+o led to increases of diastolic Ca2+i, systolic Ca2+i and SR Ca2+ content similar to those observed during changes in stimulation rate. 6. Ryanodine altered the relationship between systolic and diastolic Ca2+i during changes of Ca2+o. 7. These results are consistent with a change of diastolic Ca2+i leading to an increase in the Ca2+ content of the SR, and hence an increase in the size of the Ca2+i transient during changes in stimulation rate and Ca2+o.

Sarcoplasmic reticulum Ca2+ content, L-type Ca2+ current and the Ca2+ transient in rat myocytes during β-adrenergic Stimulation

1 The effect of β‐adrenergic stimulation on the relationship between the intracellular Ca2+ transient and the amplitude of the L‐type Ca2+ current (ICa) has been investigated in ventricular myocytes isolated from rat hearts. Intracellular [Ca2+] was monitored using fura‐2 during field stimulation and while membrane potential was controlled using voltage clamp techniques. 2 The increase in the amplitude, and the rate of decline, of the Ca2+ transient produced by isoprenaline (1.0 μmol l−1) was not significantly different in myocytes generating action potentials and in those voltage clamped with pulses of constant duration and amplitude. 3 Under control conditions, the current‐voltage (I‐ V) relationship for ICa was bell shaped. The amplitude of the Ca2+ transient also showed a bell‐shaped voltage dependence. In the presence of isoprenaline, the amplitude of both ICa and the Ca2+ transient was greater at all test potentials and the I–V relationship maintained its bell‐shaped voltage dependence. However, the size of the Ca2+ transient was no longer graded with changes in the amplitude of ICa: a small ICa could now elicit a maximal Ca2+ transient. 4 Rapid application of caffeine (10 mmol l−1) was used to elicit Ca2+ release from the sarcoplasmic reticulum (SR). Isoprenaline increased the integral of the subsequent rise in cytoplasmic [Ca2+] to 175 ± 13% of control. 5 Abbreviation of conditioning pulse duration in the presence of isoprenaline was used to reduce the amplitude of the Ca2+ transient to control levels. Under these conditions, the amplitude of the Ca2+ transient was again graded with the amplitude of ICa in the same way as under control conditions. 6 Nifedipine (2 μmol l−1) was also used to decrease Ca2+ transient amplitude in the presence of isoprenaline. In the presence of isoprenaline and nifedipine, the amplitude of the Ca2+ transient again showed a bell‐shaped voltage dependence. 7 The SR Ca2+ ‐ATPase inhibitor thapsigargin (2.5 μmol 1−1) reduced the effect of isoprenaline on the amplitude of the Ca2+ transient. In the presence of thapsigargin, the size of the Ca2+ transient increased as ICa increased in response to isoprenaline. 8 These data suggest that the increase in the amplitude of the Ca2+ transient produced by β‐adrenergic stimulation in cardiac muscle is due to an increase in the gain of the SR Ca2+ release process, due principally to an increase in the Ca2+ content of the SR.

Na+-Ca2+ Exchange Activity Is Localized in the T-Tubules of Rat Ventricular Myocytes

Abstract— Detubulation of rat ventricular myocytes has been used to investigate the role of the t-tubules in Ca2+ cycling during excitation-contraction coupling in rat ventricular myocytes. Ca2+ was monitored using fluo-3 and confocal microscopy. In control myocytes, electrical stimulation caused a spatially uniform increase in intracellular [Ca2+] across the cell width. After detubulation, [Ca2+] rose initially at the cell periphery and then propagated into the center of the cell. Application of caffeine to control myocytes resulted in a rapid and uniform increase of intracellular [Ca2+]; the distribution and amplitude of this increase was the same in detubulated myocytes, although its decline was slower. On application of caffeine to control cells, there was a large, rapid, and transient rise in extracellular [Ca2+] as Ca2+ was extruded from the cell; this rise was significantly smaller in detubulated cells, and the remaining increase was blocked by the sarcolemmal Ca2+ ATPase inhibitor carboxyeosin. The treatment used to produce detubulation had no significant effect on Ca2+ efflux in atrial cells, which lack t-tubules. Detubulation of ventricular myocytes also resulted in loss of Na+-Ca2+ exchange current, although the density of the fast Na+ current was unaltered. It is concluded that Na+-Ca2+ exchange function, and hence Ca2+ efflux by this mechanism, is concentrated in the t-tubules, and that the concentration of Ca2+ flux pathways in the t-tubules is important in producing a uniform increase in intracellular Ca2+ on stimulation.

Changes in [Ca2+]i, [Na+]i and Ca2+ current in isolated rat ventricular myocytes following an increase in cell length.

Isolated rat ventricular myocytes were stretched using carbon fibres to investigate the mechanisms underlying the increase in contraction following stretch. 2. [Ca2+]i and [Na+]i were monitored using the fluorescent indicators fura‐2 and sodium‐binding benzofuran isophthalate, respectively. The L‐type Ca2+ current was recorded simultaneously with contraction using the perforated patch‐clamp technique. 3. Mechanical stretch caused an immediate increase in contraction, followed by a slow increase. Contraction was prolonged immediately after the stretch, but did not change during the slow phase. 4. The Ca2+ transient did not change immediately after the stretch. The slow increase in contraction was accompanied by an increase in the amplitude of the Ca2+ transient. However, diastolic [Ca2+]i did not change significantly following stretch. 5. [Na+]i did not change significantly either immediately, or during the slow increase in contraction, after the stretch. 6. The L‐type Ca2+ current was not significantly altered either by mechanical loading of the cell with carbon fibres or by stretching the cell. 7. These results suggest that: (1) the rapid increase in contraction following a stretch is due to an increase in myofilament Ca2+ sensitivity rather than to changes in the L‐type Ca2+ current or [Na+]i; and (2) a slow increase in the Ca2+ transient underlies the slow increase in contraction in isolated myocytes, but is not caused by either an increase in diastolic [Ca2+]i or a change in [Na+]i (and hence Ca2+ influx via Na(+)‐Ca2+ exchange) or a change in myofilament Ca2+ sensitivity.

The effects of mechanical loading and changes of length on single guinea-pig ventricular myocytes.

1. The effects of mechanical loading and changes of length on the contraction of single guinea‐pig ventricular myocytes has been investigated. 2. Cell shortening was monitored during isotonic contractions (in which the cell shortened freely) and after attaching carbon fibres of known compliance to the ends of the cell, so that the cell contracted auxotonically (the cell both shortened and developed force). 3. Mechanically loading the cells decreased the amount of shortening during a contraction and abbreviated the contraction. There were, however, no consistent changes in the action potential or the [Ca2+]i transient (measured with the fluorescent dye fura‐2). 4. Increasing stimulation rate increased the size of the contraction and the [Ca2+]i transient in both isotonic and auxotonic conditions. The increase in the size of the contraction induced by an increase in stimulation rate was greater in auxotonic conditions but the increase in the size of the [Ca2+]i transient was not. 5. When cells were stretched, there was a step increase in the size of the contraction and a prolongation of its time course. However, neither the size nor the time course of the accompanying [Ca2+]i transient was significantly altered by this intervention. 6. When a stretch was maintained, a further, slow increase in the size of the contraction occurred during the following 3‐11 min, in about half the cells studied. The probability of this slow response occurring was increased if the initial degree of activation of the cell was decreased. 7. These data suggest that the mechanisms underlying the responses to mechanical loading and changes of length are the same in both multicellular and single cell preparations of cardiac muscle.

Mechanical alternans during acidosis in ferret heart muscle.

Acidosis leads to mechanical alternans (i.e., alternation of large and small contractions) in ferret papillary muscles. This alternation in the size of the contraction is paralleled by alternation in the size of the intracellular Ca2+ transient (monitored using the photoprotein aequorin). In isolated myocytes, the large contraction is accompanied by a prolonged action potential. Mechanical alternans also can be induced by acidosis in isolated myocytes during a train of voltage-clamp pulses. Thus, it appears unlikely that the mechanical alternans is secondary to changes in action potential duration; it is more likely that the observed changes in action potential duration are secondary to changes in the size of the Ca2+ transient. The observation that a Ca2(+)-activated inward current also shows alternation during mechanical alternans provides a possible mechanism for the link between Ca2+ and action potential duration. The alternation in the size of the Ca2+ transient may be secondary to the slowed mechanical restitution observed in papillary muscles during acidosis. This also could explain the observation that decreasing stimulation rate can abolish the alternans.

The negative inotropic effect of acetylcholine on ferret ventricular myocardium.

1. The effects of acetylcholine (ACh) on developed tension and intracellular Ca2+ concentration (as measured with aequorin) were studied in ferret papillary muscles, and on twitch shortening, the action potential and membrane currents in ferret ventricular myocytes. 2. Addition of ACh to ferret papillary muscles resulted in decreases in developed tension and the intracellular Ca2+ transient, both of which then partially recovered in the continued presence of ACh (fade of the response). On wash‐off of ACh both developed tension and the intracellular Ca2+ transient increased above control (rebound) before returning to control values. 3. Addition of ACh to ferret ventricular myocytes resulted in a membrane hyperpolarization of 2 +/‐ 0.5 mV (mean +/‐ S.E.M.; n = 9), a decrease in action potential duration to 23 +/‐ 6% of control and a decrease in twitch shortening to 31 +/‐ 5% of control. In the continued presence of ACh these responses to ACh faded. Thirty seconds after the maximal effect of ACh, action potential duration had partially recovered to 34 +/‐ 6% of control and twitch shortening to 46 +/‐ 7% of control. 4. The effects of ACh on twitch shortening could be mimicked under voltage clamp by varying voltage clamp pulse duration to simulate the ACh‐induced changes in action potential duration. 5. When ACh was applied during a train of voltage clamp pulses of constant duration, 81% of the cells showed less than a 20% decrease in Ca2+ current and twitch shortening. However in 19% of the cells twitch shortening and the apparent Ca2+ current decreased by more than 30%. 6. In the 81% of cells, the normal decrease in twitch shortening was wholly the result of the shortening of the action potential. This in turn was the result of an increase in an outward background current which increased the rate of repolarization during the action potential. The ACh‐induced background current reversed at ‐89 +/‐ 2 mV and showed inward‐going rectification; these properties suggest that it was carried by K+. 7. In the 19% of cells, the normal decrease in twitch shortening was only partly the result of the shortening of the action potential (due to both the increase in outward background current as well as the apparent decrease in Ca2+ current). In these cells the decrease in twitch shortening may also have been partly the direct result of the apparent decrease of Ca2+ current.

Differential effects of the optical isomers of EMD 53998 on contraction and cytoplasmic Ca2+ in isolated ferret cardiac muscle

EMD 53998 (a thiadiazinone) is a novel inotropic substance that increases the Ca2+ sensitivity of the myofilaments in skinned cardiac fibers and has been found to have similar effects in intact cardiac muscle. However, the compound also possesses the ability to inhibit phosphodiesterase III, indicating that its actions in intact cardiac muscle are likely to be complex. The present study was carried out to investigate the possibility that the optical isomers of EMD 53998--(+)EMD 57033 and (-)EMD 57439--which have recently been shown to possess a separation of sensitization and phosphodiesterase inhibition in subcellular preparations, might also demonstrate this separation of activities in intact cardiac muscle. The experiments were performed on isolated ferret papillary muscles, which were contracting isometrically. In some preparations, the photoprotein aequorin was injected into superficial cells to measure intracellular Ca2+ as well as force. (+)EMD 57033 caused a substantial positive inotropic effect that was associated with prolongation of the twitch, reduction in the amplitude of the Ca2+ transient, and abbreviation of the Ca2+ transient. This is the profile expected of a Ca(2+)-sensitizing compound. Conversely, (-)EMD 57439 caused a less marked positive inotropic effect that was associated with an abbreviation of the twitch, an increase in the amplitude of the Ca2+ transient, and an abbreviation of the Ca2+ transient. This is the profile expected of an agent producing its inotropic effect by increasing cAMP (e.g., phosphodiesterase inhibition). The results indicate that the optical isomers of EMD 53998 possess a remarkable separation of Ca(2+)-sensitizing and phosphodiesterase-inhibiting activities in intact cardiac muscle. These actions were additive and could account for the effects observed with EMD 53998. (+)EMD 57033 appears to be the first inotropic agent that acts predominantly by increasing myofilament calcium sensitivity.

EFFECTS OF THE PROTEIN KINASE A INHIBITOR H-89 ON CA2+ REGULATION IN ISOLATED FERRET VENTRICULAR MYOCYTES

Abstractu2002We investigated the effects of a protein kinase A (PKA) inhibitor, H-89 {N-[2-(p-bromocinnamylamino)ethyl]-5-iso-quinolinesulphonamide}, on Ca2+ regulation in Fura-2-loaded ferret myocytes. H-89 (10 µmol/l) decreased the amplitude of the Fura-2 transient to 28.2±4.3% (P<0.001) of control and prolonged its duration, characterized by a decrease in the rate of decline of Ca2+ to diastolic levels: t1/2 increased from 311±35 ms to 547±43 ms (P<0.001, n=7). Reduced Ca2+ uptake by the sarcoplasmic reticulum (SR) in the presence of H-89 was also indicated by a decrease in the SR Ca2+ content, as assessed with caffeine. The apparent slowing of the SR Ca2+-ATPase was not caused by changes in phosphorylation of phospholamban (PLB). However, Ca2+ uptake in microsomal vesicles prepared from canine hearts and fast-twitch rat skeletal muscle (which lacks PLB) was decreased by 34.1 and 46.8% (n=3), respectively, suggesting that H-89 has a direct inhibitory effect on the SR Ca2+-ATPase. In electrophysiological experiments, 5.0 µmol/l H-89 decreased the L-type Ca2+ current (ICa) by 39.5% (n=6) and slowed the upstroke of the action potential and, in some cases, caused loss of excitability without changes in the resting membrane potential. In summary, data show that [Ca2+ ]i regulation, and hence contraction, is sustained by PKA-mediated phosphorylation, even in the absence of β-agonists. However, the use of H-89 as a tool to study the role of this signalling pathway is limited by the non-specific effects of H-89 on the SR Ca2+-ATPase.