Conduction velocity in myocardium modulated by strain: measurement instrumentation and initial results.

Quantification of the relationship between strain and excitation velocity in cardiac muscle gives important insights into the significance and contribution of microstructure and several transmembrane proteins to cardiac electrophysiology. In this study we introduce a measurement and analysis system for quantification of the relationship in papillary muscle of small mammals, superfused and kept in a physiological environment. A novelty of the approach is the extensive automation and computerization of the measurement and analysis procedure. Initial results indicate that the conduction velocity is strain dependent in such a manner that several components contribute to establish this relationship. Further studies will help to quantify the relationship and importance of the components.

Location of the initiation site of calcium transients and sparks in rabbit heart Purkinje cells.

1. The distribution and localization of Ca2+ transients and Ca2+ sparks in isolated adult rabbit Purkinje cells were examined using confocal microscopy and the Ca2+ indicator fluo-3. 2. When cells were field stimulated in 2.0 mM Ca2+ buffer, a transverse confocal line scan (500 Hz) showed that the fluorescence intensity was greatest at the cell periphery during the onset of the Ca2+ transient ([Ca2+]i). In contrast, the [Ca2+]i of ventricular cells showed a more uniform pattern of activation across the cell. Staining with di-8-ANEPPS revealed that Purkinje cells lack t-tubules, whereas ventricular cells have an extensive t-tubular system. 3. When we superfused both cell types with a buffer containing 5 mM Ca2+-1 microM isoproterenol (isoprenaline) they produced Ca2+ sparks spontaneously. Ca2+ sparks occurred only at the periphery of Purkinje cells but occurred throughout ventricular cells. Sparks in both cell types could be completely abolished by addition of the SR inhibitor thapsigargin (500 nM). Brief exposure to nifedipine (10 microM) did not reduce the number of spontaneous sparks. 4. Immunofluorescence staining of Purkinje cells with anti-ryanodine antibody revealed that ryanodine receptors (RyRs) are present at both peripheral and central locations. 5.Computer simulations of experiments in which the calcium transient was evoked by voltage clamp depolarizations suggested that the increase in calcium observed in the centre of the cell could be explained by simple buffered diffusion of calcium. These computations suggested that the RyRs deep within the cell do not contribute significantly to the calcium transient. 6. These results provide the first detailed, spatially resolved data describing Ca2+ transients and Ca2+ sparks in rabbit cardiac Purkinje cells. Both types of events are initiated only at subsarcolemmal SR Ca2+ release sites suggesting that in Purkinje cells, Ca2+ sparks only originate where the sarcolemma and sarcoplasmic reticulum form junctions. The role of the centrally located RyRs remains unclear. It is possible that because of the lack of t-tubules these RyRs do not experience a sufficiently large Ca2+ trigger during excitation-contraction (E-C) coupling to become active.

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.

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.

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.

Properties of Ca2+ sparks evoked by action potentials in mouse ventricular myocytes.

1. Calcium sparks were examined in enzymatically dissociated mouse cardiac ventricular cells using the calcium indicator fluo-3 and confocal microscopy. The properties of the mouse cardiac calcium spark are generally similar to those reported for other species. 2. Examination of the temporal relationship between the action potential and the time course of calcium spark production showed that calcium sparks are more likely to occur during the initial repolarization phase of the action potential. The latency of their occurrence varied by less than 1.4 ms (s.d.) and this low variability may be explained by the interaction of the gating of L-type calcium channels with the changes in driving force for calcium entry during the action potential. 3. When fixed sites within the cell are examined, calcium sparks have relatively constant amplitude but the amplitude of the sparks was variable among sites. The low variability of the amplitude of the calcium sparks suggests that more than one sarcoplasmic reticulum (SR) release channel must be involved in their genesis. Noise analysis (with the assumption of independent gating) suggests that > 18 SR calcium release channels may be involved in the generation of the calcium spark. At a fixed site, the response is close to 'all-or-none' behaviour which suggests that calcium sparks are indeed elementary events underlying cardiac excitation-contraction coupling. 4. A method for selecting spark sites for signal averaging is presented which allows the time course of the spark to be examined with high temporal and spatial resolution. Using this method we show the development of the calcium spark at high signal-to-noise levels.

Quantitation of Na/Ca exchanger function in single ventricular myocytes.

A Na/Ca exchange current can be elicited in voltage clamped single ventricular myocytes by the abrupt removal of extracellular Na+ by means of a rapid switcher device. We measured this reverse Na/Ca exchange current in isolated mouse ventricular myocytes from wild-type mice, and from transgenic mice with hearts overexpressing the Na/Ca exchanger. In mouse ventricular myocytes, the current was sensitive to nickel, and was eliminated by removal of intracellular Na+. It was not influenced by 3 m m ouabain, and thus not contaminated by Na pump currents. The magnitude of the current reached a plateau within 10-15 min after obtaining a whole cell patch with the pipettes containing EGTA, to buffer [Ca2+]i and in zero extracellular K+ concentration to completely inhibit the Na pump, and allow equilibration of pipette Na+ with subsarcolemmal [Na+]. The magnitude of the current increased with increases in pipette [Na+]. Comparison of the current magnitudes in wild-type and transgenic myocytes showed a 2.5 and 2.7 fold increase in the current in transgenic myocytes at pipette [Na+] of 10 and 20 m m. The magnitude of this increase in Na/Ca exchanger currents in single transgenic myocytes compares well with the reported 2.5 fold increase in Na+-dependent 45Ca2+ uptake measured in ventricular sarcolemmal vesicles obtained from transgenic animals. With this approach, we found variation in exchanger current densities in different species, with values for mouse>rat>rabbit>dog>human. This technique should also be useful in quantifying changes in Na/Ca exchanger current density as a consequence of pathologic processes, and exposure to drugs.

Abnormal myocyte Ca2+ homeostasis in rabbits with pacing-induced heart failure.

To determine whether there are abnormalities in myocyte excitation-contraction coupling and intracellular Ca2+ concentration ([Ca2+]i) homeostasis in pacing-induced heart failure (PF), we measured L-type Ca2+ current (ICa,L) and Na+/Ca2+ exchanger current (INa/Ca) with voltage clamp and measured intracellular Na+ concentration ([Na+]i) and [Ca2+]i with the use of sodium-binding benzofuran isophthalate (SBFI) and fluo 3 in ventricular myocytes isolated from control and paced rabbits. The peak systolic and diastolic levels and the amplitude of electrically stimulated [Ca2+]i transients (0.25 Hz, extracellular Ca2+ concentration = 1.08 mM) were significantly less in PF myocytes. Also, there was prolongation of the times to peak and decline of [Ca2+]i transients. ICa,L density was markedly decreased in PF myocytes. INa/Ca at -40 mV elicited by rapid exposure to 0 Na+ solution with a rapid solution switcher was significantly reduced in PF myocytes, suggesting that the function of the Na+/Ca2+ exchanger is impaired in these myocytes. In PF myocytes the decline of the [Ca2+]i transient when the Na+/Ca2+ exchanger was abruptly disabled was markedly prolonged compared with the decline in control myocytes, consistent with depressed sarcoplasmic reticulum (SR) Ca2+-ATPase function. RNase protection assay showed decreased levels of Na+/Ca2+ exchanger and SR Ca2+-ATPase mRNA in PF hearts, consistent with the function studies. We conclude that the functions of L-type Ca2+ channels, Na+/Ca2+ exchanger, and SR Ca2+-ATPase are impaired in myocytes from rabbit hearts with failure induced by rapid pacing. These abnormalities result in reduced [Ca2+]i transients and systolic and diastolic dysfunction and appear to account for the abnormal ventricular function observed.

Na-Ca exchange and the trigger for sarcoplasmic reticulum Ca release: studies in adult rabbit ventricular myocytes.

The importance of Na-Ca exchange as a trigger for sarcoplasmic reticulum (SR) Ca release remains controversial. Therefore, we measured whole-cell Ca currents (ICa), Na-Ca exchange currents (INaCa), cellular contractions, and intracellular Ca transients in adult rabbit cardiac myocytes. We found that changing pipette Na concentration markedly affected the relationship between cell shortening (or Ca transients) and voltage, but did not affect the Ca current-voltage relationship. We then inhibited Na-Ca exchange and varied SR content (by changing the number of conditioning pulses before each test pulse). Regardless of SR Ca content, the relationship between contraction and voltage was bell-shaped in the absence of Na-Ca exchange. Next, we rapidly and completely blocked ICa by applying nifedipine to cells. Cellular shortening was variably reduced in the presence of nifedipine. The component of shortening blocked by nifedipine had a bell-shaped relationship with voltage, whereas the "nifedipine-insensitive" component of contraction increased with voltage. With the SR disabled (ryanodine and thapsigargin pretreatment), ICa could initiate late-peaking contractions that were approximately 70% of control amplitude. In contrast, nifedipine-insensitive contractions could not be elicited in the presence of ryanodine and thapsigargin. Finally, we recorded reverse Na-Ca exchange currents that were activated by membrane depolarization. The estimated sarcolemmal Ca flux occurring by Na-Ca exchange (during voltage clamp steps to +30 mV) was approximately 10-fold less than that occurring by ICa. Therefore, Na-Ca exchange alone is unlikely to raise cytosolic Ca concentration enough to directly activate the myofilaments. We conclude that reverse Na-Ca exchange can trigger SR Ca release. Because of the sigmoidal relationship between the open probability of the SR Ca release channel and pCa, the effects of ICa and INaCa may not sum in a linear fashion. Rather, the two triggers may act synergistically in the modulation of SR release.

Effects of overexpression of the Na+-Ca2+ exchanger on [Ca2+]i transients in murine ventricular myocytes.

We measured [Ca2+]i and [Na+]i in isolated transgenic (TG) mouse myocytes overexpressing the Na+-Ca2+ exchanger and in wild-type (WT) myocytes. In TG myocytes, the peak systolic level and amplitude of electrically stimulated (ES) [Ca2+]i transients (0.25 Hz) were not significantly different from those in WT myocytes, but the time to peak [Ca2+]i was significantly prolonged. The decline of ES [Ca2+]i transients was significantly accelerated in TG myocytes. The decline of a long-duration (4-s) caffeine-induced [Ca2+]i transient was markedly faster in TG myocytes, and [Na+]i was identical in TG and WT myocytes, indicating that the overexpressed Na+-Ca2+ exchanger is functionally active. The decline of a short-duration (100-ms) caffeine-induced [Ca2+]i transient in 0 Na+/0 Ca2+ solution did not differ between the two groups, suggesting that the sarcoplasmic reticulum (SR) Ca2+-ATPase function is not altered by overexpression of the Na+-Ca2+ exchanger. There was no difference in L-type Ca2+ current density in WT and TG myocytes. However, the sensitivity of ES [Ca2+]i transients to nifedipine was reduced in TG myocytes. This maintenance of [Ca2+]i transients in nifedipine was inhibited by Ni2+ and required SR Ca2+ content, consistent with enhanced Ca2+ influx by reverse Na+-Ca2+ exchange, and the resulting Ca2+-induced Ca2+ release from SR. The rate of rise of [Ca2+]i transients in nifedipine in TG myocytes was much slower than when both the L-type Ca2+ current and the Na+-Ca2+ exchange current function together. In TG myocytes, action potential amplitude and action potential duration at 50% repolarization were reduced, and action potential duration at 90% repolarization was increased, relative to WT myocytes. These data suggest that under these conditions, overexpression of the Na+-Ca2+ exchanger in TG myocytes accelerates the decline of [Ca2+]i during relaxation, indicating enhanced forward Na+-Ca2+ exchanger function. Increased Ca2+ influx also appears to occur, consistent with enhanced reverse function. These findings provide support for the physiological importance of both these modes of Na+-Ca2+ exchange.

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.

Sarcoplasmic reticulum and Na+/Ca2+ exchanger function during early and late relaxation in ventricular myocytes.

The relative importance of the Na+/Ca2+ exchanger in the initial and terminal phases of relaxation and the decline in the [Ca2+]i transient was investigated in adult rabbit ventricular myocytes loaded with the Ca2+ indicator fluo 3. For electrically stimulated contractions, the peak intracellular Ca2+ concentration ([Ca2+]i) was 700 +/- 87 nM and end-diastolic [Ca2+]i was 239 +/- 30 nM (0.25 Hz, 37 degrees C, 1.08 mM extracellular Ca2+ concentration; n = 14). Abrupt inhibition of Na+/Ca2+ exchange was produced by removal of extracellular Na+ (KCl substitution) and Ca2+ [2 mM Ca(2+)-free ethylene glycol-bis(beta-aminoethyl either)-N,N,N',N'-tetraacetic acid] by means of a rapid switcher device (SW). Abrupt exposure to high K+ induced an action potential, although sufficient Ca2+ remained adjacent to the sarcolemma to induce a contraction (SW beat) and [Ca2+]i transient that were identical in amplitude to those induced by electrical stimulation (ES beat). The initial relaxation and decline in the [Ca2+]i transient was not significantly prolonged by abrupt elimination of the Na+/Ca2+ exchanger, but the rate and extent of the terminal phase of the decline in the [Ca2+]i transient were significantly reduced. The first derivative of [Ca2+]i with respect to time versus [Ca2+]i during the decline of the [Ca2+]i transient attributable to sarcoplasmic reticulum (SR) function was estimated from the average SW transients, and that attributable to Na+/Ca2+ exchange was estimated from the difference between SW and ES transients. By this analysis, the Na+/Ca2+ exchanger produces 13% of the first half of the decline in [Ca2+]i and 45% of the second half of the decline. We conclude that abrupt inhibition of forward Na+/Ca2+ exchange does not significantly affect the amplitude or the initial rate of decline of the [Ca2+]i transient and relaxation. However, its contribution to the reduction of [Ca2+]i becomes apparent late during the [Ca2+]i transient, when cytosolic [Ca2+]i has been reduced.

Effect on the indo-1 transient of applying Ca2+ channel blocker for a single beat in voltage-clamped guinea-pig cardiac myocytes.

1. We used rapid solution changes to investigate the mechanisms which trigger Ca2+ release from the sarcoplasmic reticulum (SR) in guinea-pig ventricular myocytes. We patch-clamped myocytes at 36 degrees C and used indo-1 to monitor intracellular Ca2+. Before each test pulse, we established a standard level of SR Ca2+ load by applying a train of conditioning pulses. 2. We switched rapidly to 32 microM nifedipine (an L-type Ca2+ current (ICa,L) blocker) 8 s before a test pulse, and just after applying nifedipine we applied a ramp depolarization to pre-block Ca2+ channels. We found that ICa,L elicited by the following test pulse was inhibited almost completely (98-99% inhibition). 3. The indo-1 transient elicited by an 800 ms depolarizing pulse showed a rapid initial rise which was inhibited by ryanodine-thapsigargin. This indicated that the rapid rise was due to Ca2+ release from the SR, and therefore provides an index of SR Ca2+ release. 4. In cells dialysed internally with 10 mM Na(+)-containing solution, nifedipine application before a +10 mV test pulse blocked 62% of the rapid initial phase of the indo-1 transient. Calibration curves of indo-1 for intracellular Ca2+ (using a KD of indo-1 for Ca2+ of either 250 or 850 nM, the reported range) indicated that between 67 and 76% of the Ca2+i transient was inhibited by nifedipine. Thus, in cells dialysed with 10 mM Na+ and depolarized to +10 mV, and in the absence of ICa,L, this suggests that another trigger mechanism for SR release is able to trigger between 33 and 24% of the Ca2+i transient. 5. For a given dialysing Na+ concentration, the fraction of indo-1 transient which was inhibited by nifedipine decreased as test potential became more positive. In cells dialysed with 10 mM Na+ and pulsed to +110 mV, 24% of the rapid phase of the indo-1 transient was inhibited by nifedipine (equivalent to between 27 and 37% of the Ca2+i transient). 6. For a given test potential, the fraction of the indo-1 transient which was inhibited by nifedipine decreased as dialysing Na+ concentration increased. In cells dialysed with Na(+)-free solution and pulsed to +10 mV, 84% of the indo-1 transient was inhibited by nifedipine (equivalent to between 88 and 91% of the Ca2+i transient). In contrast, in cells dialysed with 20 mM Na+ and pulsed to +10 mV, 41% of the indo-1 transient was inhibited by nifedipine (equivalent to between 47 and 57% of the Ca2+i transient). 7. Dialysing cells with different Na+ concentrations could lead to a different SR Ca2+ content. We therefore manipulated the conditioning train before each test pulse to change the extent of SR loading. For each dialysing Na+ concentration, we found no change in the degree to which nifedipine blocked the indo-1 transient when SR content was either increased or decreased. 8. The results support the idea that both ICa, L and a second mechanism are able to trigger SR release and the resulting Ca2+i transient. When ICa, L was blocked with nifedipine, the fraction of Ca2+i transient which remained increased with more positive test potential and higher internal Na+. This is consistent with the hypothesis that the second SR trigger mechanism is Ca2+ entry via reverse Na(+)-Ca2+ exchange, elicited by a step change in membrane potential.

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.

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.

Effects of angiotensin II on intracellular Ca2+ and pH in isolated beating rabbit hearts and myocytes loaded with the indicator indo-1.

1. Angiotensin II increases myocardial contractility in several species, including the rabbit and man. However, it is controversial whether the predominant mechanism is an increase in free cytosolic [Ca2+]i or a change in myofilament Ca2+ sensitivity. To address this question, we infused angiotensin II in isolated perfused rabbit hearts loaded with the Ca2+ indicator indo-1 AM and measured changes in beat-to-beat surface transients of the Ca2+i-sensitive 400:500 nm ratio and left ventricular contractility. The effects of angiotensin II were compared with the response to a Ca(2+)-dependent increase in the inotropic state produced by a change in the perfusate [Ca2+] from 0.9 to 3.6 nM. 2. In the isolated beating heart, an increase in perfusate [Ca2+] caused an increase in left ventricular pressure +dP/dt in association with an increase in peak systolic [Ca2+]i. Angiotensin II perfusion caused a similar increase in left ventricular +dP/dt in the absence of any increase in peak systolic [Ca2+]i. 3. To exclude any contribution of non-myocyte sources of Ca(2+)-sensitive fluorescence which may be present in the intact heart, we also compared the effects of angiotensin II and a change in superfusate [Ca2+] in collagenase-dissociated paced adult rabbit ventricular myocytes loaded with indo-1 AM. In the isolated rabbit myocytes a change in perfusate [Ca2+] from 0.9 to 3.6 mM caused an increase in peak systolic cell shortening coincident with an increase in peak systolic [Ca2+]i. In contrast, angiotensin II caused a similar increase in peak systolic cell shortening whereas there was no increase in peak systolic [Ca2+]i. There was also no change in inward Ca2+ current (ICa) in response to angiotensin II. 4. To investigate further the mechanism of the positive inotropic action of angiotensin II, its effects on intracellular pH were studied in isolated rabbit myocytes loaded with the fluorescent H+ probe SNARF 1. These experiments demonstrated that angiotensin II induced a 0.2 pH unit increase coincident with the development of a positive inotropic effect in isolated rabbit myocytes. 5. In summary, angiotensin II has a direct positive inotropic effect in beating rabbit hearts and in isolated paced rabbit myocytes. These experiments provide support for the hypothesis that the predominant mechanism is not an increase in free cytosolic Ca2+ but is due in part to an increase in myofilament Ca2+ sensitivity due to intracellular alkalosis.

Depolarization-induced Ca entry via Na-Ca exchange triggers SR release in guinea pig cardiac myocytes.

In mammalian heart muscle, Ca entry through L-type Ca channels is thought to be the primary trigger for the sarcoplasmic reticulum (SR) Ca release, which initiates contraction. The results of this study show that, in guinea pig myocytes with a normal internal Na (10 mM Na in pipette), another trigger mechanisms for SR release and contraction exists. A crucial feature of these experiments was the ability to change rapidly the extracellular environment of a single myocyte so that alterations of intracellular Ca and SR Ca load were minimized for each solution change. We found the following results. 1) A switch to Na-free solution 50 ms before depolarization led to an increase of phasic contraction without increasing L-type Ca current (Ica) or Ca loading of the SR. 2) Although rapid application of 20 microM nifedipine 3 s before a + 10-mV pulse blocked ICa completely, 43 +/- 11 (SE) % of the phasic contraction remained. Similar results were obtained by rapid switching to 150 microM Cd to block ICa. 3) Phasic contraction and ICa had different voltage dependence. With steps to positive potentials there was little ICa but still a substantial phasic contraction. 4) Under action potential conditions, 64.6 +/- 7.9% of the control phasic contraction remained after switching to 20 microM nifedipine to block ICa. 5) The contraction remaining with nifedipine was unaffected by adding 100 microM Ni. Because 100 microM Ni blocks T-type Ca channels, this shows that Ca entry via T-type Ca channels is not involved in triggering SR release. 6) The phasic contraction remaining after a rapid switch to nifedipine was blocked completely by adding 5 mM Ni. Because this concentration of Ni is known to block the Na-Ca exchange, this result suggests that the exchange plays a role in triggering SR release. Taken together, the present results indicate that depolarization-induced Ca entry on the Na-Ca exchange is able to trigger SR release and phasic contraction. This explanation can account for increased phasic contraction after a rapid switch to Na-free solution, persistence of a phasic contraction in the complete absence of ICa, substantial phasic contraction at positive test potentials where there is no ICa, and abolition of nifedipine-resistant contraction by 5 mM Ni.

Relation between reverse sodium-calcium exchange and sarcoplasmic reticulum calcium release in guinea pig ventricular cells.

Exchange-inhibitory peptide (XIP) can inhibit sodium-calcium exchange without inhibiting L-type calcium current (ICa). We therefore used this compound to test the hypothesis that reverse sodium-calcium exchange can trigger contraction in guinea pig ventricular myocytes. When cells were dialyzed with 20 mmol/L sodium, rapid blockade of ICa with nifedipine had little effect on cell shortening. However, if reverse exchange was inhibited by first dialyzing the cells with XIP, blockade of ICa largely inhibited cell shortening. In cells dialyzed with 10 mmol/L sodium, about 51% of the maximum cell shortening remained after ICa was blocked. When both ICa and reverse exchange were significantly inhibited with nifedipine and XIP, only 24% of the cell shortening remained; ie, 27% was XIP inhibitable. Cells dialyzed with solutions deficient in sodium exhibited contractions that were largely dependent on ICa (ie, not XIP inhibitable). If the sarcoplasmic reticulum (SR) was disabled with ryanodine and thapsigargin, reverse exchange could not cause contraction. We therefore conclude that with intact SR, reverse sodium-calcium exchange activates contraction by triggering calcium release from the SR in cells dialyzed with either 10 or 20 mmol/L sodium. A scrambled sequence of XIP, sXIP, caused no measurable effect on contraction.

Intracellular calcium homeostasis in cardiac myocytes.

Calcium homeostasis in cardiac myocytes results from the integrated function of transsarcolemmal Ca2+ influx and efflux pathways modulated by membrane potential and from intracellular Ca2+ uptake and release caused predominantly by SR function. These processes can be importantly altered in different disease states as well as by pharmacological agents, and the resulting changes in systolic and diastolic [Ca2+]i can cause clinically significant alterations in contraction and relaxation of the heart. It may be anticipated that a rapid increase in our understanding of the pathophysiology of Ca2+ homeostasis in cardiac myocytes will be forthcoming as the powerful new tools of molecular and structural biology are used to investigate the regulation of Ca2+ transport systems.