Uphill sodium transport driven by an inward calcium gradient in heart muscle.

Heart cells were loaded with sodium by treatment with toxic doses of acetyl strophanthidin. After this treatment, an increase in extracellular calcium resulted in a transient net outward sodium flux against its electrochemical gradient and in net cellular uptake of calcium. It is concluded that the free energy for the net outward sodium movement was derived from the increased calcium gradient and that these ion movements took place through the sodium-calcium exchange. While in the normal physiological state the sodium-calcium exchange produces calcium extrusion from the cell, these experiments demonstrate its reversibility.

Relaxation of isolated ventricular cardiomyocytes by a voltage-dependent process.

Cell contraction and relaxation were measured in single voltage-clamped guinea pig cardiomyocytes to investigate the contribution of sarcolemmal Na+-Ca2+ exchange to mechanical relaxation. Cells clamped from -80 to 0 millivolts displayed initial phasic and subsequent tonic contractions; caffeine reduced or abolished the phasic and enlarged the tonic contraction. The rate of relaxation from tonic contractions was steeply voltage-dependent and was significantly slowed in the absence of a sarcolemmal Na+ gradient. Tonic contractions elicited in the absence of a Na+ gradient promptly relaxed when external Na+ was applied, reflecting activation of Na+-Ca2+ exchange. It appears that a voltage-dependent Na+-Ca2+ exchange can rapidly mechanically relax mammalian heart muscle.

The relationship between charge movements associated with ICa and INa-Ca in cardiac myocytes.

Ventricular myocytes exhibit a nifedipine-sensitive inward calcium current (ICa) and contracture when they are voltage clamped from -40 to 0 millivolt in the presence of caffeine and in the absence of extracellular sodium. However, upon repolarization they fail to relax because neither the sarcoplasmic reticulum nor the sodium-calcium exchange can reduce intracellular calcium. Sudden application of extracellular sodium during the contracture (but after repolarization) causes immediate relaxation and activates a transient inward sodium-calcium exchange current (INa-Ca), whose peak slightly precedes mechanical relaxation. The total charge carried by the nifedipine-sensitive ICa is twice the total charge carried by the transient inward INa-Ca. Assuming an exchange stoichiometry of three sodium to one calcium, these results indicate that all the calcium entering the cell during the initial depolarization is extruded by the sodium-calcium exchange.

Alterations in cation homeostasis in cultured chick ventricular cells during and after recovery from adenosine triphosphate depletion.

Alterations in cation homeostasis during and after recovery from myocardial ischemia may account for some of the reversible and irreversible components of myocardial cell injury. To investigate possible mechanisms involved, we exposed cultured layers of spontaneously contracting chick embryo ventricular cells to media containing 1 mM cyanide (CN) and 20 mM 2-deoxyglucose (2-DG), and zero glucose for up to 6 h, and then allowed cultured cells to recover in serum-free culture medium for 24 h. Changes in Na, K, and Ca contents, 42K uptake and efflux, ATP content, cell water content, and lactate dehydrogenase (LDH) release were measured, and compared with changes produced by exposure to 10(-3) M ouabain and severe hypoxia. Exposure to CN and 2-DG caused marked increase in cell Na (sevenfold) and Ca (fivefold) contents, and a decrease in K content (one-fifth normal), coincident with ATP depletion to one-tenth normal levels. This produced only slight cell injury, evidenced by increased LDH release. Recovery for 24 h resulted in return to near normal values (expressed in nanomoles per milligram of protein) of Na, Ca, and ATP contents. However, there was failure of cell K content to return to normal, associated with a persistent reduced net uptake of 42K, and an increase in the rate of 42K efflux. These abnormalities in K homeostasis were associated with a decrease in cell volume and water content per milligram of protein. More marked ATP depletion (to 1/100 normal values) was produced by hypoxia plus 2-DG and zero glucose, and was associated with much more severe cell injury manifested by LDH loss. Ouabain exposure resulted in a much greater Ca gain (20-30-fold), relative to increase in Na content, than did either CN and 2-DG or hypoxia; and ouabain effects were not reversible (after a 15-fold or greater increase in Ca content was produced) and were associated with significant LDH release. We conclude that these cells are resistant to cell injury caused by moderately severe Ca overload and ATP depletion produced by exposure to CN and 2-DG. However, metabolic inhibition of ATP production produces persistent abnormalities in K homeostasis, associated with functional abnormalities.

Dyssynchronous Ca(2+) sparks in myocytes from infarcted hearts.

The kinetics of contractions and Ca(2+) transients are slowed in myocytes from failing hearts. The mechanisms accounting for these abnormalities remain unclear. Myocardial infarction (MI) was produced by ligation of the circumflex artery in rabbits. We used confocal microscopy to record spatially resolved Ca(2+) transients during field stimulation in left ventricular (LV) myocytes from control and infarcted hearts (3 weeks). Compared with controls, Ca(2+) transients in myocytes adjacent to the infarct had lower peak amplitudes and prolonged time courses. Control myocytes showed relatively uniform changes in [Ca(2+)] throughout the cell after electrical stimulation. In contrast, in MI myocytes [Ca(2+)] increased inhomogeneously and localized increases in [Ca(2+)] occurred throughout the rising and falling phases of the Ca(2+) transient. Ca(2+) content of the sarcoplasmic reticulum did not differ between MI and control myocytes. Peak L-type Ca(2+) current density was reduced in MI myocytes. The macroscopic gain function was not different in control and MI myocytes when calculated as the amplitude of the Ca(2+) transient/peak I:(Ca). However, when calculated as the peak rate of rise of the Ca(2+) transient/peak I:(Ca), the gain function was modestly decreased in the MI myocytes. Application of isoproterenol (100 nmol/L) improved the synchronization of Ca(2+) release in MI myocytes at both 0.5 and 1 Hz. The poorly coordinated production of Ca(2+) sparks in myocytes from infarcted rabbit hearts likely contributes to the diminished and slowed macroscopic Ca(2+) transient. These abnormalities can be largely overcome when phosphorylation of Ca(2+) cycling proteins is enhanced by ss-adrenergic stimulation.

Relationships between the sarcoplasmic reticulum and sarcolemmal calcium transport revealed by rapidly cooling rabbit ventricular muscle.

Rabbit right ventricular papillary muscles were cooled from 30 to approximately 1 degree C immediately after discontinuing electrical stimulation (0.5 Hz). This produced a contracture that was 30-50% of the preceding twitch magnitude and required 20-30 s to develop. The contractures were identical in cooling solutions with normal (144 mM) or low (2.0 mM) Na. They were therefore not Na-withdrawal contractures. Contracture activation was considerably slower than muscle cooling (approximately 2.5 s to cool below 2 degrees C). Cooling contractures were suppressed by caffeine treatment (10.0 mM). Rapid cooling did not cause sufficient membrane depolarization (16.5 +/- 1.2 mV after 30 s of cooling) to produce either a voltage-dependent activation of contracture or a gated entry of Ca from the extracellular space. Contractures induced by treating resting muscles with 5 X 10(-5) M strophanthidin at 30 degrees C exhibited pronounced tension noise. The Fourier spectrum of this noise revealed a periodic component (2-3 Hz) that disappeared when the muscle was cooled. Cooling contractures decayed with rest (t1/2 = 71.0 +/- 9.3 s). This decay accelerated in the presence of 10.0 mM caffeine and was prevented and to some extent reversed when extracellular Na was reduced to 2.0 mM. 20 min of rest resulted in a net decline in intracellular Ca content of 1.29 +/- 0.38 mmol/kg dry wt. I infer that cooling contractures are principally activated by Ca from the sarcoplasmic reticulum (SR). The properties of these contractures suggest that they may provide a convenient relative index of the availability of SR Ca for contraction. The rest decay of cooling contractures (and hence the decay in the availability of activating Ca) is consistent with the measured loss in analytic Ca during rest. The results suggest that contraction in heart muscle can be regulated by an interaction between sarcolemmal and SR Ca transport.

External Na-independent Ca extrusion in cultured ventricular cells. Magnitude and functional significance.

The relative magnitudes and functional significance of Ca extrusion by Na-Ca exchange and by an Nao-independent mechanism were investigated in monolayer cultures of chick embryo ventricular cells. Abrupt exposure of cells in 0-Nao, nominally 0-Cao solution to 20 mM caffeine produced a large contracture (3.94 +/- 0.90 micron of cell shortening) that relaxed with a t1/2 of 8.60 +/- 1.22 s. An abrupt exposure to caffeine plus 140 mM Na resulted in a contracture that was smaller in amplitude (1.53 +/- 0.50 micron) and relaxed much more rapidly (t1/2 = 0.77 +/- 0.09 s). An abrupt exposure to caffeine in 0-Nao solutions produced an increase in 45Ca efflux that persisted for 20 s, and a net loss of Ca content, determined by atomic absorption spectroscopy (AAS), of approximately 4 nmol/mg protein, within 35 s. A comparable net loss of Ca was demonstrated in the presence of 100 microM [Ca]o. The abrupt exposure of cultured cells to 0 Nao in 1.8 mM Ca produced a Ca uptake, estimated with 45Ca, of 3.2 nmol/mg protein X 15 s, but produced no increase in cell Ca content (AAS). In cells in which a 30% increase in Nai was produced by 5 min exposure to 10(-6) M ouabain, the abrupt exposure to 0 Nao produced a Ca uptake of 6 nmol/mg protein X 15 s and an increase in Ca content (AAS) of 4 nmol/mg protein. We conclude that there is an Nao-independent mechanism for Ca extrusion in these cells, presumably a Ca-ATPase Ca pump, with a limited Ca transport capacity of no more than 2 nmol/mg protein X 15 s. This is five times smaller than the demonstrated maximum capacity of the Na-Ca exchanger in these cells. The relaxation of twitch tension in these cells seems to be dependent primarily on sarcoplasmic reticulum uptake of Ca, with a secondary role provided by the Na-Ca exchanger. The Ca pump appears to contribute little to beat-to-beat relaxation.

Early and delayed afterdepolarizations in rabbit heart Purkinje cells viewed by confocal microscopy.

We investigated action potentials and Ca(2+) transients in rabbit Purkinje myocytes using whole cell patch clamp recordings and a confocal microscope. Purkinje cells were loaded with 5 microM Fluo-3/AM for 30min. Action potentials were elicited by application of a stimulus delivered through the recording pipettes. When Purkinje cells were stimulated in 2.0mM Ca(2+), transverse XT line scans revealed a symmetrical 'U'-shaped Ca(2+) transient demonstrating that the transient was initiated at the cell periphery. When Purkinje cells were superfused with 1 microM isoprenaline, both early and delayed afterdepolarizations were induced. XT line scans of cells exhibiting early afterdepolarizations showed a second symmetrical 'U'-shaped transient. This Ca(2+) transient was initiated at the cell periphery suggesting reactivation of the Ca(2+) current. In contrast, in Purkinje cells exhibiting delayed afterdepolarizations and a corresponding transient inward current, XT line scans revealed a heterogenous rise in Ca(2+) at both peripheral and central regions of the cell. Immunofluorescence staining of Purkinje cells with an antibody to ryanodine receptors (RyRs) revealed that RyRs are located at regularly spaced intervals throughout the interior of Purkinje cells. These results suggest that, although RyRs are located throughout Purkinje cells, only peripheral RyRs are activated to produce transients, sparks and early afterdepolarizations. During delayed afterdepolarizations, we observed a heterogenous rise in Ca(2+) at both peripheral and central regions of the cell as well as large central increases in Ca(2+). Although the latter may result from central release, we cannot exclude the possibility that it reflects Ca(2+) diffusion from subsarcolemmal sites.

Evidence that reverse Na-Ca exchange can trigger SR calcium release.

Several results suggest that the Na-Ca exchange can function as a trigger promoting SR Ca release and ensuing contractions. First, if the Ca current was the sole trigger for contraction we would expect the relationship between triggered contractions and voltage to be similar to the relationship between Ca current and contraction. When Na is present in the pipette this is not observed. Between -40 and +10 mV the relationships between contractions and voltage and current and voltage are similar. At potentials positive to 10 mV the Ca current declines as expected but contractions either decline much more slowly or continue to increase depending upon the concentration of intracellular Na. In addition, we have observed that contractions can be activated when Ca current is largely or completely blocked. Since these contractions are sensitive to the presence of ryanodine and thapsigargin they appear to be triggered by Na-Ca exchange. Also, contractions that are activated in the presence of nifedipine are sensitive to the Na-Ca exchange inhibitor XIP. Finally, rapid removal of extracellular Na apparently stimulates enough reverse exchange triggering of SR Ca release without affecting the SR content. It is clear that the shape of the shortening voltage relationship depends upon the concentration of dialyzing Na. This is likely to occur for two reasons. Either the shape of the shortening voltage relationship depends upon the extent to which Na-Ca exchange contributes a trigger for SR Ca release or alternatively the shape of the shortening voltage relationship depends upon SR Ca content. The latter is known to depend upon the Na concentration. In addition it is now established that the gain of SR Ca release is influenced by SR content. However, we studied triggered contractions in the absence of a Na gradient when the only available trigger is the Ca current. We measured triggered contractions over a range of voltages between -30 and +60 mV. Between each measurement we reestablished the Na gradient and activated a series of conditioning pulses to standardize the SR Ca content. Just before a test pulse we removed extracellular Na and activated either 3 or 6 pulses to produce two different SR Ca loads (in the absence of a Na gradient entering Ca cannot be extruded and therefore changes the SR Ca content). Regardless of the number of prepulses in the absence of a Na gradient the shortening voltage relationship was similar and bell shaped. From this we conclude that the shape of the relationship between shortening and voltage does not depend upon SR Ca content. Therefore, we conclude that the asymmetry in the shortening voltage relationship that depends upon intracellular Na is due to a contribution of reverse Na-Ca exchange. It is too early to say what the physiological significance (if any) of triggering by reverse exchange actually is. However, it does seem likely that it might provide a powerful inotropic mechanism. For example intracellular Na might be expected to change with heart rate and to be elevated at higher heart rates. Presumably this increased intracellular Na would tend to favor triggering by reverse exchange and would therefore enhance contractility at a time when it would be most required.

The cytoplasmic escape and nuclear accumulation of endocytosed and microinjected HPMA copolymers and a basic kinetic study in Hep G2 cells.

The development of macromolecules as drugs and drug carriers requires knowledge of their fate in cells. To this end, we studied the internalization and subcellular Fate of N-(2-hydroxypropyl)methacrylamide (HPMA) copolymers in Hep G2 (human hepatocellular carcinoma) cells. Semiquantitative fluorometry confirmed that galactose was an effective ligand for receptor-mediated endocytosis for Hep G2 cells. The rate of internalization of a galactose-targeted copolymer was almost 2 orders of magnitude larger than that of the nontargeted copolymer. Confocal fluorescent microscopy of both fixed and live cells revealed that the polymer entered the cells by endocytosis. After longer incubation times (typically >8 hours), polymer escaped from small vesicles and distributed throughout the cytoplasm and nuclei of the cells. Polymer that entered the cytoplasm tended to accumulate in the nucleus. Microinjection of the HPMA copolymers into cells' cytoplasm and nuclei indicated that the polymers partitioned to the nucleus. The data from fixed cells was confirmed by microscopy of live, viable cells. To examine the effect of the fluorescent dye on the intracellular fate, polymers with fluorescein, Oregon Green 488, Lissamine rhodamine B, and doxorubicin were tested; no significant differences were observed.

Excitation-contraction coupling in ventricular myocytes: effects of angiotensin II.

The effects of the vasoactive peptide angiotensin II (AII) on contractility and excitation-contraction coupling in isolated adult rabbit ventricular myocytes were investigated. In most ventricular myocytes, AII (10(-8) M) induced a significant increase in fractional shortening which was not associated with an increase in the calcium transient measured with indo-1. AII did increase the intracellular pH by approximately 0.2 5 pH units coincident with the positive inotropic effect. Effects of AII on pH and contractility were blocked by inhibitors of Na+/H+ exchange. AII also increased the rate of pHi recovery from intracellular acidosis at pHi values above 6.9. AII was shown not to affect the L-type inward calcium current. However, in an occasional cell, AII was observed to cause a slight increase in the calcium transient. We hypothesize that this response may reflect an increase of calcium influx on the sodium calcium exchanger, as a consequence of an increase in subsarcolemmal sodium concentration resulting from enhanced Na(+)-H+ exchange.

Relaxation of rabbit ventricular muscle by Na-Ca exchange and sarcoplasmic reticulum calcium pump. Ryanodine and voltage sensitivity.

We studied relaxation during rapid rewarming of rabbit ventricular muscles that had been activated by rapid cooling. Rewarming from 1 degree to 30 degrees C (in less than 0.5 second) activates mechanisms that contribute to the reduction of intracellular calcium concentration and thus relaxation (e.g., sarcoplasmic reticulum [SR] calcium pump and sarcolemmal Na-Ca exchange and calcium pump). Rapid rewarming in normal Tyrode's solution induces relaxation with a half-time (t1/2) of 217 +/- 14 msec (mean +/- SEM). During cold exposure, changing the superfusate to a sodium-free, calcium-free medium with 2 mM CoCl2 (to eliminate Na-Ca exchange) slightly slows relaxation upon rewarming in the same medium (t1/2 = 279 +/- 44 msec). Addition of 10 mM caffeine (which prevents SR calcium sequestration) to normal Tyrode's solution during cold superfusion slows relaxation somewhat more (t1/2 = 376 +/- 31 msec) than sodium-free, calcium-free solution. However, if both interventions are combined (sodium-free + caffeine) during the cold exposure and rewarming, the relaxation is greatly slowed (t1/2 = 2,580 +/- 810 msec). These results suggest that either the SR calcium pump or, to a lesser extent, sarcolemmal Na-Ca exchange can produce rapid relaxation, but if both systems are blocked, relaxation is very slow. If muscles are equilibrated with 500 nM ryanodine before cooling, relaxation upon rewarming is not greatly slowed (t1/2 = 266 +/- 37 msec) even if sodium-free, calcium-free solution is applied during the cold and rewarming phases (t1/2 = 305 +/- 66 msec). This result suggests that ryanodine does not prevent the SR from accumulating calcium to induce relaxation.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of acetylstrophanthidin on twitches, microscopic tension fluctuations and cooling contractures in rabbit ventricle.

1. We have measured the effect of the aglycone acetylstrophanthidin (ACS) on twitches, cooling contractures and microscopic tension fluctuations in rabbit ventricular muscle. 2. Both developed twitches and cooling contractures are strengthened by applications of ACS in the range 1-4 microM. This positive inotropy averages 150-160% of control (zero ACS) in both twitches and cooling contractures. Cooling contracture magnitude is assumed to reflect the availability of sarcoplasmic reticulum (SR) Ca2+ for contraction (Bridge, 1986). We infer that ACS increases the availability of SR Ca2+ by enlarging SR Ca2+ stores and this may contribute to the positive inotropy. 3. However, twitches appear to increase at lower concentrations of ACS than those required to increase cooling contractures. This observation suggests that the initial ACS inotropy may be achieved without an increase in SR Ca2+. Furthermore, low doses of ACS produce positive inotropy in the presence of 10.0 mM-caffeine where cooling contractures are abolished. This also suggests that positive inotropy occurs in the absence of SR Ca2+ accumulation. 4. Rest decay of both cooling contractures and twitches is significantly slowed in 4 and 8 microM-ACS. We infer that ACS slows the rate of decline of SR Ca2+ available for contraction by slowing the rate at which Ca2+ is lost from the cell during rest. This suggests that ACS produces a net slowing of Ca2+ efflux during activity which in the absence of altered Ca2+ influx will result in net Ca2+ gain and presumably enlarged SR Ca2+ stores. 5. Increasing the concentration of ACS (6-10 microM) results in a decline in developed twitch tension, total tension and an increase in rest tension. Measurement of microscopic tension fluctuations indicates that as developed twitches decline, the root mean square (r.m.s.) of the tension fluctuations increases in a reciprocal manner. This supports the suggestion of others that the decline in developed twitch tension and the appearance of tension fluctuations are causally related. 6. Although ACS (6-10 microM) causes a decline in twitch tension, rapid cooling contractures remain elevated. We suggest that in the presence of Ca2+ oscillations the magnitude of cooling contractures reflects the sum of cytosolic Ca2+ and Ca2+ that is available for release. If microscopic tension fluctuations do represent Ca2+ moving between the SR and cytosol the sum of SR and cytosolic Ca2+ and hence cooling contracture might not decline.(ABSTRACT TRUNCATED AT 400 WORDS)

Enhanced Na(+)-Ca2+ exchange in the infarcted heart. Implications for excitation-contraction coupling.

Cellular Ca2+ regulation is abnormal in diseased hearts. We designed this study to assess the role of the Na(+)-Ca2+ exchanger in excitation-contraction coupling in surviving myocardium of the infarcted heart. We measured cellular contractions and whole-cell currents in single left ventricular myocytes isolated from the hearts of rabbits with healed myocardial infarction (MI). Eight weeks after MI, rabbits had left ventricular dysfunction without overt heart failure. Myocytes isolated from regions adjacent to the infarcted zone were significantly longer than cells from control hearts. At low stimulation rates (0.5 Hz), the amplitude of field-stimulated contractions was increased (11.6 +/- 0.5% versus 10.2 +/- 0.6% resting cell length), whereas the time to peak shortening and action potential duration were prolonged in the MI cells. When stimulation frequency was increased to 2.0 Hz, cellular shortening did not change or decreased in myocytes from infarcted hearts, whereas control cells had a positive shortening-interval relationship. Cells from infarcted hearts had a significantly decreased (31%) L-type Ca2+ current (ICa) density but no change in the current-voltage relationship or the kinetics of ICa inactivation. Maximal Na(+)-Ca2+ exchange current density was significantly increased (32%) in the cells from infarcted hearts. Sarcoplasmic reticulum (SR) Ca2+ content during a stable train of contractions, as estimated from caffeine-induced inward currents, was slightly increased (P = NS) in the MI myocytes. To determine whether Na(+)-Ca2+ exchange influenced SR Ca2+ content, cells were clamped at potentials between -70 and +90 mV for 400 ms. The amplitude of the contraction during a subsequent clamp step to +10 mV was then measured as an index of SR loading that occurred during the preceding clamp step. Steps to positive potentials produced greater augmentation of the subsequent contraction in MI than in control myocytes. In myocytes from the infarcted heart, increased activity of the Na(+)-Ca2+ exchanger may promote Ca2+ entry or decrease Ca2+ extrusion. This relative augmentation of inward Ca2+ flux by the exchanger may enhance SR Ca2+ loading and thus support contractility that would otherwise be impaired as a result of decreased Ca2+ current. However, Ca2+ influx by the exchanger may contribute to the prolongation of contractions in myocytes from infarcted hearts.