Temperature effects on the Na and Ca currents in rat and hedgehog ventricular muscle

Cardiac transmembrane potentials and Na and Ca currents were recorded at different temperatures in rat and hedgehog ventricular muscle. At 35 degrees C in both species resting potential was about -80 mV and upstroke velocity (Vmax) of the action potential above 100 V/s. The shape of the action potential in hedgehog ventricular cells at 35 degrees C was similar to that in the rat showing a fast repolarization phase. When temperature was decreased, the membrane resting potential depolarized and action potential amplitude and Vmax declined. In rat ventricular cells at 10 degrees C, the resting potential was about -40 to -50 mV and Vmax was reduced to about 5 V/s. In hedgehog ventricular cells, however, the transmembrane potentials and Vmax were better maintained at low temperature. Phase 3 of the action potential was markedly prolonged below 20 degrees C in hedgehog but not in rat ventricular cells. When temperature was decreased to 10 degrees C the availability curve of the Na current shifted toward more negative potentials and ICa.peak declined in rat ventricular cells. In hedgehog cardiac preparations, the Na current was less influenced by the cooling and ICa.peak did not change very much at low temperatures. A transient inward current usually considered to induce cardiac arrhythmias could be recorded in rat ventricular cells below 20 degrees C but not in hedgehog preparations. These features of hedgehog cardiac membranes may contribute to the cold tolerance and the resistance to ventricular fibrillation during the hypothermia in mammalian hibernators.

Acceleration of H+ extrusion via Na(+)-H+ exchange in guinea-pig ventricular papillary muscle under intracellular acidic condition

We investigated mechanisms by which intracellular pH was regulated under intracellular acidic condition in resting guinea-pig ventricular papillary muscles in vitro. Intracellular sodium ion activity (aiNa), intracellular and surface pH (pHi and pHs) were measured with Na(+)- and H(+)-selective microelectrodes and resting tension was measured. By exposure to 0 mM K solution aiNa and resting tension increased progressively while pHi decreased but reached the steady level of pH 6.95. pHs which was lower than external bulk pH (pHo) decreased progressively by exposure to 0 mM K solution. In 4 mM K solution, amiloride (1 mM), an inhibitor of Na(+)-H+ exchange, induced a reversible decrease in both aiNa and pHi, and an increase in pHs. Changes in pHi and pHs induced by application of amiloride in 0 mM K solution were larger than those in 4 mM K solution. The rate of decrease in pHi induced by amiloride became larger at longer exposure to 0 mM K solution. Lowering pHo from 7.4 to 6.4 induced a larger decrease in pHi in 0 mM K solution than that in 4 mM K solution. Lowering pHo from 7.4 to 5.4 reversed the difference between pHs and pHo. These results suggest that in guinea-pig papillary muscle, Na(+)-H+ exchange is active to regulate intracellular H+ under resting condition and under intracellular acidic condition, H+ extrusion via the Na(+)-H+ exchange would be accelerated not only by the net thermodynamic driving force for Na+ and H+ but also by other factors.

Intracellular sodium activity in papillary muscle from diabetic rat hearts

In quiescent papillary muscles isolated from hearts of rats with streptozotocin-induced diabetes resting intracellular sodium activity (aiNa) was about 56% greater than in muscles from controls. An intracellular acid load induced by the NH4+ method caused a rise in aiNa whose maximum amplitude was similar in both groups of muscles. However, the half-time to maximum amplitude was increased by about 56% in diabetic muscles. These results are consistent with a diabetes-induced decrease in the activity of the sarcolemmal Na(+)-H+ exchange.

The effect of acidosis on the interval-force relation and mechanical restitution in ferret papillary muscle

1. The effect of a respiratory acidosis on the interval-force relation and on mechanical restitution was investigated in ferret papillary muscles. 2. Acidosis (pH 6.85) decreased developed force over a range of stimulation frequencies (1.0.06 Hz); the percentage decrease was greatest at the lowest stimulation frequencies. Qualitatively similar effects of acidosis on developed force were observed in the presence of the sarcoplasmic reticulum (SR) inhibitor ryanodine. 3. Mechanical restitution curves were constructed by interpolating extra-systoles at different test intervals following a train of steady-state beats. Mechanical restitution in ferret papillary muscle was triphasic: an initial, rapid, exponential increase in force with test intervals to 2 s, a further increase with test intervals between 60 and 90 s and then a slow decline, with a plateau at about 30 min (0.33 Hz, 30 degrees C). 4. Acidosis slowed the initial phase of mechanical restitution. The degree of slowing depended on the steady-state stimulation frequency, being greatest at low frequencies. 5. Inhibition of the SR abolished the initial phase of mechanical restitution, suggesting that this phase depends on Ca2+ release from the SR. 6. The strength of the first contraction after the extra-systole varied inversely with the size of the extra-systole under all conditions studied. 7. It is concluded that acidosis may inhibit the SR by altering the time required for Ca2+ recycling between contractions. This effect may alter Ca2+ release from the SR during acidosis, and may underlie the mechanical alternans (the alternation of small and large contractions) that can occur during acidosis.

Effects of carbachol and (-)-N6-phenylisopropyladenosine on myocardial inositol phosphate content and force of contraction

1. The effects of carbachol and the A1-adenosine receptor agonist (-)-N6-phenylisopropyladenosine (PIA) on force of contraction and inositol lipid metabolism were studied in electrically driven left auricles and papillary muscles isolated from guinea-pig hearts. Both carbachol and PIA (0.01-10 microM) had concentration-dependent negative inotropic effects in auricles. In papillary muscles PIA had no inotropic effect. Carbachol also had no inotropic effect at low concentrations (0.01-1 microM) but at 10-100 microM it exerted a slight positive inotropic effect. 2. In auricles and papillary muscles both carbachol and PIA concentration-dependently increased inositol trisphosphate (IP3; significant at 1 microM). Accordingly phosphatidylinositol bisphosphate (PIP2), the precursor of IP3, was reduced. All effects of carbachol and PIA were antagonized by atropine (10 microM) and 1,3-dipropyl-8-cyclopentylxanthine (DPCPX; 20 microM) respectively, indicating receptor-mediated effects. 3. In auricles the negative inotropic effects of carbachol and PIA preceded the increase in IP3. 4. In papillary muscles the increase in IP3 preceded the slight positive inotropic effect of carbachol, indicating that the M-cholinoceptor-mediated increase in IP3 and force of contraction may be related. However, PIA showed a comparable increase in IP3 but no inotropic effect, indicating a dissociation between those parameters. 5. In conclusion, in previous studies a close relation between increases in IP3 and force of contraction has been shown after alpha 1-adrenoceptor stimulation. The present study with carbachol supports this view. However, the present data for PIA could not show such a close relationship, questioning the role of IP3 as an endogenous regulator of force of contraction.

Differential effects of caffeine on skinned fibers from control and hypertrophied ferret hearts

The effects of caffeine on the mechanical properties of detergent-skinned fibers from control and pressure-overloaded ferret hearts have been compared. Right ventricle hypertrophy was studied 6 wk after pulmonary artery ligation, an intervention that increased the right ventricular weight-body weight ratio by 60%. Although no changes were observed in the Ca sensitivity of contraction between control [pCa for one-half-maximal activation (pCa50) = 5.80 +/- 0.05] and hypertrophied (pCa50 = 5.85 +/- 0.02) muscles, the leftward shift of the force-pCa relationship induced by caffeine was more pronounced in hypertrophied fibers than in control; pCa50, was 5.86 +/- 0.02, 5.94 +/- 0.01, 6.03 +/- 0.01 in control and 5.97 +/- 0.03, 6.10 +/- 0.03, 6.24 +/- 0.01 in control and 5.97 +/- 0.03, 6.10 +/- 0.03, 6.24 +/- 0.03 in hypertrophied fibers for 2, 5, 10 mM caffeine, respectively. This was accompanied in the hypertrophied muscles by a decrease in the Hill coefficient. On the other hand, maximal force was not affected by 10 mM caffeine. From these results it is possible that the site of action of caffeine in myofibrillar proteins is the thin filament. The increased responsiveness of hypertrophied fibers to caffeine may be mediated by a pressure overload-induced change in the thin filament regulatory proteins. Moreover, inotropic agents may act differently in hypertrophied than in control myocardium.

Increased susceptibility to hypoxia of prolonged action potential duration in ventricular papillary muscles from diabetic rats

The action potential duration (APD) of ventricular muscles obtained from diabetic animals is reported to be prolonged. We studied the effect of varied periods of diabetes on APD prolongation using isolated ventricular papillary muscles from streptozocin-injected rats. We found that a diabetic period greater than 30 wk was necessary for the evolution of significant prolongation of APD. We then studied the effect of repeated hypoxia (PO2 40 mmHg) and normoxia (PO2 300 mmHg) on prolonged APD of diabetic muscles and compared the findings with those from control rats. Transmembrane potentials were recorded with conventional glass microelectrodes. Under normoxic conditions, the APDs of diabetic muscles were significantly prolonged, the maximum upstroke velocity of action potentials tended to be decreased, and the resting membrane potential was not changed significantly compared with controls. The first hypoxia (20 min) shortened the APD in both diabetic and control rats but more so in diabetic rats, thereby making the APD of diabetic rats virtually identical to the control rat APD during the hypoxia. On subsequent reoxygenation (30 min), these hypoxia-induced changes were almost recovered. The second hypoxia (20 min) produced more severe shortening of the APD in both muscle types, and the effect was again far greater in diabetic rats than controls, ending with a reversed sequence of APDs and the APD of diabetic muscles much shorter than the controls. Excessive shortening of APD in diabetic muscles during hypoxic conditions was speculated to be due to greater increases in the outward K+ current through ATP-regulated K+ channels that may be secondary to the more severe reduction of intracellular ATP concentrations in diabetic versus control hearts.

The energy cost of relaxation in control and hypertrophic rabbit papillary muscles

The energy cost of the onset and relaxation phases of cardiac isometric contractions has been investigated by ergometer controlled-length releases occurring at different times during the contraction cycle, to test the hypothesis that the energy cost of relaxation is normally small. Energy flux has been measured myothermically in 20 or 30 contractions of rabbit papillary muscles. The ergometer releases took place after different delays, starting during the latency period and incrementing in 50 ms steps, until eventually, releases were occurring late into the relaxation phase. The release step was kept constant and of a magnitude sufficient to prevent significant redevelopment of active stress at any release interval. The rate of release was several times greater than the maximum shortening velocity of the papillary muscle preparations. The heat production in each train of contractions was measured, but in order to estimate the total energy output, the elastic energy in the muscle-lever system which was removed by the ergometer release had to be added to the heat. This was estimated by integration of the stress-strain relationship found for each muscle. In normal animals the contraction peak, at 27 degrees C and a 1.0 Hz stimulus rate, was located between the 215 and 265 ms release times, at which point the total energy flux was estimated to be 80%-90% of that measured in a normal isometric contraction. Additional experiments were performed in a group of volume-overloaded hearts and the data were compared with results from sham-operated controls.(ABSTRACT TRUNCATED AT 250 WORDS)

Intracellular free magnesium and its regulation, studied in isolated ferret ventricular muscle with ion-selective microelectrodes

Intracellular free magnesium ([Mg2+]i) was measured in isolated ferret papillary muscles using ion-selective microelectrodes filled with the new magnesium sensor ETH 5214. This new sensor, unlike its predecessor ETH 1117, does not react to marked changes in K+, Na+ or pH. Reducing Ca2+ from 20 microM to around 10 nM also did not affect the response so these electrodes are ideally suited to study intracellular Mg2+ and its regulation. The mean value for the [Mg2+]i from thirty-two experiments (forty-two impalements) was 0.85 mM, confirming previous estimates from this laboratory. Intracellular Mg2+ is not passively distributed and the possibility that Mg2+ is transported out of the cell by a Na(+)-Mg2+ exchanger was investigated. An increase in [Mg2+]o caused an increase in [Mg2+]i, as did stepwise reduction in the [Na+]o. However, this increase in [Mg2+]i on Na+ reduction also occurred in Mg2(+)-free solution suggesting that the increase in [Mg2+]i was due to the increase in intracellular Ca2+ on Na+ reduction. Moreover, increasing [Na+]i by strophanthidin did not change the [Mg2+]i and on increasing [Mg2+]o there was no reduction in the [Na+]i. Blocking ATP production lead to small increases in the [Mg2+]i. These results are not consistent with a Na(+)-Mg2+ exchanger as being the main outward transport mechanism for Mg2+ in this tissue.

Energy demand, supply, and utilization in hypoxia, and force recovery after reoxygenation in rabbit heart muscle

In rabbit papillary muscle contracting at 20 degrees C in nitrogen at 0.2 Hz, glycolytic ATP formation is just enough to support the diminished contractile activity. Basal metabolism, important to maintain cellular function and integrity, is strongly inhibited. In the present study, we address the question of whether the inhibition of basal processes in hypoxia determines redevelopment of force in reoxygenation. By not stimulating the muscle during hypoxia, we try to make more ATP available for basal processes. Isometric force of papillary muscles (0.2-Hz stimulation) is measured before, during, and after 40 minutes of hypoxia. ATP formation and utilization in hypoxia are estimated from lactate production and changes in nucleotides and creatine compounds. After reoxygenation, muscles stimulated during hypoxia produce a steady-state force of 78% of the aerobic control; resting muscles recover to 94%. In contrast to expectation, lactate production in hypoxic resting muscles is only 30% of that in contracting ones. The findings indicate that basal metabolic rate of hypoxic muscles at rest is 14% of that of quiescent, well-oxygenated myocardium. We conclude that in hypoxic myocardium little ATP is available for basal metabolism, irrespective of the energy demand of the contractile system. It is therefore unlikely that the lower force found after reoxygenation in muscles stimulated during hypoxia is related to the degree of inhibition of basal processes.

The effects of cocaine on intracellular Ca2+ handling and myofilament Ca2+ responsiveness of ferret ventricular myocardium

1. When ferret right ventricular papillary muscles were stimulated with threshold punctate pulses (0.33 Hz; 30 degrees C), cocaine, 10(-5) M, increased peak tension development from 815 +/- 120 to 1125 +/- 180 mg (P less than 0.05) and increased the rate of relaxation from peak tension (time to 80% decline from peak tension decreased from 155 +/- 11 to 144 +/- 11 ms; P less than 0.05). These changes in the twitch were associated with comparable changes in the amplitude and time course of the calcium transient measured with aequorin (amplitude increased from 62 +/- 4 to 90 +/- 7% (P less than 0.05) of maximal values; time to 80% decline from peak amplitude decreased from 84 +/- 8 to 64 +/- 3 ms; P less than 0.05). These effects were markedly attenuated in the presence of the beta-adrenoceptor-blocking agent, propranolol, 6 x 10(-7) M, or by maximization of catecholamine release from the adrenergic nerve endings with field pulses of suprathreshold strength, indicating that catecholamine release from the adrenergic nerve endings is responsible for the positive inotropic and lusitropic responses to low and moderate doses of cocaine (i.e., less than or equal to 10(-5) M). 2. High doses of cocaine (i.e., greater than 10(-5) M) produced negative inotropic and lusitropic effects that were associated with a decreased amplitude and prolonged duration of the calcium transient. 3. In aequorin-loaded intact fibres, cocaine 10(-5) M did not affect the force-calcium relationship unless catecholamines were present. Cocaine, 10(-5) M, significantly shifted the force-calcium relationship of saponin-skinned muscles (pCa50 = 6.14 +/- 0.05 versus 5.92 +/- 0.07; P less than 0.05), indicating reduced responsiveness of the myofilaments to calcium. F. (maximal Ca2+-activated force) was reduced to 58% of control in the presence of 10- M cocaine, while the slope of the calcium-force curve remained unchanged. These data indicate that cocaine may also decrease myofilament calcium sensitivity and maximal calciumactivated force, via mechanisms independent of catecholamines, when cellular diffusion barriers are eliminated.

Transmural high energy phosphate distribution and response to alterations in workload in the normal canine myocardium as studied with spatially localized 31P NMR spectroscopy

Spatially localized phosphorus-31 nuclear magnetic resonance (31P NMR) spectroscopy has been applied to the study of the normal canine myocardium to measure the relative content of high energy phosphates across the left ventricular wall. Transmural NMR data were acquired in five voxels spanning the wall of the left ventricle using the FLAX-ISIS technique. The validity of the FLAX-ISIS approach in acquiring localized spectra for transmural studies and in providing quantitative information from the localized spectra was examined rigorously by studies involving phantoms, intact rats, and the canine myocardium in vivo. The results indicated that (1) this technique yields spatially resolved spectra with partial overlap between adjacent voxels and virtually no overlap between every other voxel; (2) in the canine heart, signals from subepicardium, midwall, and subendocardium can be detected separately without cross contamination; and (3) relative metabolite contents within a voxel and among voxels can be quantitated. Transmural 31P NMR spectra were acquired with cardiac gating on 29 separate animals either at early systole or late diastole, and at three different workloads with the heart rate peak systolic pressure product (RPP) increasing from 6000 mmHg/min to 35,000 mmHg/min. The data revealed that in the normal canine myocardium, the creatine phosphate (CP) content and the CP/ATP ratio was significantly lower in the subendocardium than in the subepicardium. ATP levels were transmurally constant. Both the CP content and the CP/ATP ratio measured for each voxel remained unaltered in relation to either the phase of the cardiac cycle or approximately fourfold increase in workload. Free ADP levels calculated for each voxel showed that ADP was relatively higher in the subendocardium than the subepicardium, and in all transmural layers was higher than its apparent Km for oxidative phosphorylation. In this domain changes in ADP content with workload and MVO2 are not expected and were not observed.

Excitation-contraction coupling model to estimate the recirculating fraction of activator calcium in intact cardiac muscle

Potentiated contractions were evoked with rapid pace pause maneuver in 14 length-clamped ferret papillary muscles paced 12 times/min at 25 degrees C. At 1.25 mM [Ca2+]o the average steady-state force was 2.94 +/- 1.08 g/mm2 and the potentiated contraction averaged 10.96 +/- 1.61 g/mm2. At 5.0 mM [Ca2+]o the steady-state force increased to 6.18 +/- 1.23 g/mm2 and the potentiated contraction averaged 12.08 +/- 1.15 g/mm2. Under the conditions of these experiments the potentiated contraction obtained at 5.0 mM [Ca2+]o is equal to the maximum twitch tension (Fmax) these muscles can generate. We have previously shown that Fmax is an equivalent of maximal calcium activated force. Since there is a beat to beat nearly exponential decay of the evoked potentiation, the fraction (= fraction x) of the potentiation that is not dissipated with each beat is nearly constant. Using an excitation-contraction coupling model we have previously found that x reflects a measure of the recirculating fraction of activator calcium. Because the tension-calcium relationship is better characterized by a sigmoidal curve, we have now incorporated the Hill equation in the model. To account for the inverse relationship between [Ca2+]i and the magnitude of the slow inward current, a term for negative feedback (h) was also included. We have determined the quantity (x-h) because x and h could not be determined separately. The quantity (x-h) was denoted as x'. The average values of x' at 1.25 and 5.0 mM [Ca2+]o were significantly different (p less than 0.0001), approximately 20% at the lower [Ca2+]o and about 50% at the higher [Ca2+]o.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacological and biochemical effects of the cardiotonic agent Org10325 in isolated cardiac and vascular tissue preparations

1. The pharmacological and biochemical effects of a novel cardiotonic agent, Org10325 have been studied in isolated cardiac and vascular tissue preparations. 2. Org10325 produced concentration-dependent (0.15-4.8 mM) positive inotropic, positive chronotropic and vascular relaxant responses in rabbit isolated papillary, atrial and aortic preparations, respectively. The maximal chronotropic effect (45%) was significantly less than the isoprenaline maximum. The inotropic effects of Org10325 were not modified by alpha- or beta-adrenoceptor blockade or by pretreatment with reserpine. Org10325 was at least 23 times more potent at relaxing aortic strips pre-contracted with phenylephrine than with KCl. 3. Org10325 (74 microM) potentiated (10-14 fold) the positive inotropic effects of isoprenaline in rabbit isolated papillary muscles. Carbachol inhibited the positive inotropic effect of Org10325. Both the positive inotropic and vasorelaxant effects of Org10325 were accompanied by increases in cyclic AMP but not cyclic GMP. 4. In rat perfused heart preparation Org10325 increased phosphorylase a, cyclic AMP-dependent protein kinase activities and stimulated phosphorylation of contractile proteins (troponin-I and C-protein). 5. Org10325 selectively inhibited the cyclic AMP hydrolytic activity of cyclic AMP high affinity cyclic nucleotide phosphodiesterase (PDE) isoenzymes, PDE III (IC50 65 microM) and PDE IV (IC50 71 microM), from rabbit cardiac ventricle. Weak inhibition (IC50 greater than 250 microM) of PDE I and PDE II was observed. 6. The results show that the cardiac and vascular effects of Org10325 are mediated by an increase in cellular cyclic AMP due to inhibition of PDE III and PDE IV activities. However, in contrast to other PDE-inhibitors OrglO325 produced a marked increase in relaxation time of isolated papillary muscle suggesting the involvement of additional cyclic AMP-independent mechanisms of action.

Acidification and intracellular sodium ion activity during stimulated myocardial ischemia

With the use of microelectrodes, intracellular pH (pHi), surface pH (pHs), and intracellular Na+ activity (aiNa) were measured in isolated guinea pig papillary muscles during normal superfusion and during a reversible condition of simulated ischemia. Acid loading by NH+4 prepulse or by CO2-HCO3- addition during superfusion with pH 7.4 solutions caused internal acidification followed by a recovery of pHi, which could be inhibited by amiloride. pHi recovery was associated with an amiloride-sensitive peak rise of aiNa and membrane hyperpolarization, indicative of Na(+)-H+ exchange. Peak increase of aiNa was absent if the pH of the superfusion solution was concomitantly lowered. Imposed ischemia after control superfusion caused membrane depolarization and acidification of pHi and pHs. The change of pHs consistently was larger than that of pHi. aiNa decreased from 5.5 to 4.6 mM after 10-min ischemia. Enlarging the pHi (and pHs) decrease in ischemia by prior reduction of the tissue buffer capacity (CO2-HCO3(-)-free superfusion) was unable to induce a rise of aiNa during the subsequent ischemic period. Amiloride had no significant effect on aiNa during ischemia. It is concluded that the important acidification of pHs reduces the rate of pHi regulatory Na(+)-H+ exchange and thereby contributes to a longer maintenance of the Na+ electrochemical gradient in ischemic cardiac muscle.

Arrhythmia after the release of inhibited oxidative phosphorylation

Automaticities due to delayed afterdepolarizations, elicited upon reoxygenation, are thought to be caused by Ca overload. Since tissue Ca uptake upon reoxygenation has been reported to be closely related to metabolic inhibition during hypoxic perfusion, the relationship between the degree of metabolic inhibition during hypoxia and reoxygenation-induced arrhythmias was investigated in guinea pig papillary muscles. (1) Arrhythmias occurred after 60 min substrate-free hypoxia, but not after 30 min hypoxia. The chance of automaticities was closely related with the increase in resting tension achieved during hypoxic period. The incidence of arrhythmias was, however, lower after 90 or 120 min hypoxia. (2) There were arrhythmias after 20-30 min hypoxia with glycolytic inhibition (20 mM 2-deoxyglucose + 5 mM acetate). On the other hand, 60-min hypoxia in the presence of 5 mM glucose did not elicit arrhythmias on reoxygenation. (3) Stimulation of glycolysis (50 mM glucose) during substrate-free hypoxia prolonged the action potential duration, but did not cause arrhythmias. Washout of cyanide (1 mM) after 60 min perfusion in the presence of oxygen, caused arrhythmias and aftercontractions. These results suggest that the degree of metabolic inhibition during hypoxia is closely related to Ca overload and the resultant arrhythmias upon reoxygenation. The release of inhibited oxidative phosphorylation, rather than the reintroduction of oxygen per se, was thought to be the key mechanism of reoxygenation-induced arrhythmias.

Passive electrical properties, mechanical activity, and extracellular potassium in arterially perfused and ischemic rabbit ventricular muscle. Effects of calcium entry blockade or hypocalcemia

The relation among passive electrical resistive properties, longitudinal conduction velocity, extracellular potassium concentration, [K+]o, and mechanical activity was investigated in the isolated rabbit papillary muscle during normal arterial perfusion and no-flow ischemia in the presence and absence of verapamil, or a reduced extracellular Ca2+ concentration [Ca2+]o. During normal arterial perfusion, verapamil (0.5 microM, free [Ca2+]o = 1.0 mM) and hypocalcemic blood perfusate (free [Ca2+]o = 0.4 mM) reduced the maximal isometric twitch tension by 48% and 78%, depolarized the resting membrane by +3 and +7 mV, decreased the extracellular longitudinal resistance (ro) by 15% and 26%, and increased conduction velocity by 4% and 6%, respectively. The changes in conduction velocity during these interventions were consistent with those predicted by linear cable theory (+3% and +9%) for the observed changes in ro. In contrast, verapamil shortened whereas a reduced [Ca2+]o lengthened action potential duration. Comparison of simultaneously measured longitudinal whole tissue resistance (rt), intracellular longitudinal resistance (ri), [K+]o, and resting tension during ischemia showed a close association between abrupt cell-to-cell electrical uncoupling, development of ischemic contracture, and the secondary rise of [K+]o, which all started to develop after approximately 15 minutes of ischemia. Electrical cell-to-cell uncoupling was completed within 15 minutes. In the presence of verapamil, the relation among the onset of electrical cell-to-cell uncoupling, secondary rise of [K+]o, and onset of ischemic contracture in ischemia was qualitatively the same as in its absence; however, these events were postponed by approximately 10 minutes, and the rates of contracture development and uncoupling were diminished. Conduction velocity decreased after 12 minutes of ischemia from 54 to 36 cm/sec in the absence of and from 61 to 46 cm/sec in the presence of verapamil. This slowing effect on impulse conduction could not be attributed to changes of electrical cell-to-cell coupling because at this time an increase in ri had not yet taken place. In the presence of a reduced [Ca2+]o, the resting tension and ri increased almost immediately after the onset of ischemia. Although the resting tension rose progressively throughout the course of ischemia, the ri showed a biphasic increase characterized by an early transient increase that reached a peak at 8 minutes (+87%) and a second, irreversible increase beginning at approximately 12 minutes. This final onset of electrical cell-to-cell uncoupling and the secondary rise of [K+]o were not different from the findings with a normal [Ca2+]o.(ABSTRACT TRUNCATED AT 400 WORDS)

Striated muscle tropomyosin-enriched microfilaments of developing muscles of chicken embryos

The striated muscle tropomyosin-enriched microfilaments were isolated from developing muscles in ovo by the previously described method with a monoclonal antibody against striated muscle isoforms of tropomyosin (Lin & Lin, 1986). Two-dimensional gel analysis of the isolated microfilaments from developing heart, thigh and breast muscles revealed the coexistence of non-muscle isoforms of tropomyosin and actin throughout all stages of embryogenesis. A small but significant amount of skeletal muscle isoforms (alpha, beta) of tropomyosins and their phosphorylated forms was detected in the microfilaments isolated from hearts of 6-15-day-old embryos. These skeletal isoforms of tropomyosins disappeared after this stage of embryogenesis. In addition, we also detected both embryonic and adult isoforms of troponin T in early developing hearts. In developing thigh and breast muscles, the presence of non-muscle tropomyosin isoforms 2, 3a and 3b in the isolated microfilaments was apparent. The contents of tropomyosin isoform 2 were decreased with development and this non-muscle isoform completely disappeared at the 15th day of embryogenesis. On the other hand, the non-muscle tropomyosin isoforms 3a and 3b were present throughout all stages of development. Double-label immunofluorescence microscopy with monoclonal CH1 (anti-striated muscle isoforms of tropomyosin) and CG beta 6 (anti-non-muscle isoforms of tropomyosin) on the isolated, glycerinated skeletal and cardiac muscle cells of 10-day-old or 13-day-old embryos confirmed the colocalization of muscle and non-muscle isoforms of tropomyosins within the same cells. These results suggest that different isoforms of actin and tropomyosin can assemble into a class of microfilaments (i.e. striated muscle tropomyosin-enriched microfilaments) in ovo, which may transform into the thin filaments of mature muscle cells.

The effects of an extra-stimulation on post-extra-systolic potentiation in papillary muscle of rats

The mechanism of post-extrasystolic potentiation (PESP) is unclear. It has previously been suggested that changes in both the calcium release from the sarcoplasmic reticulum (SR) and the transsarcolemmal calcium influx are factors in the development of PESP in guinea-pigs. This experiment investigated the effects of a resting interval and a coupling interval on PESP in rat papillary muscles, which have a well-developed SR. An extra-stimulation was induced at various coupling intervals and a variety of post-extrasystolic intervals were set. The PESP was not dependent on the coupling interval. The post-extrasystolic interval at which the maximal % PESP was obtained was about 90 sec, and post-extrasystolic interval-% potentiation of the PESP relationship curve consisted of an ascending limb and a descending limb. Caffeine eliminated the PESP in a concentration-dependent manner. These findings suggest that SR calcium release plays an important role in the mechanism of PESP in rats. This is consistent with results from guinea-pigs, and implies that the calcium capacity and/or retention of the SR may characterize the post-extrasystolic interval-% PESP relationship in muscle from different species.

The role of reduced potassium conductance in generating triggered activity in guinea-pig ventricular muscle

This study investigates the role of reducing potassium conductance (gK) in generating delayed afterdepolarizations and triggered activity in small preparations of ventricular muscle from guinea-pig hearts. We used agents believed to reduce gK (low or absent K0, tetraethylammonium (TEA), CsCl) and we used ouabain (10(-6) M) to induce delayed afterdepolarizations. Treatment with ouabain only caused subthreshold delayed afterdepolarizations or occasionally non-sustained triggered activity. Exposure to Tyrode's solution with K reduced from 4 to 2 mM or K-free Tyrode's solution, with or without ouabain, caused subthreshold delayed afterdepolarizations and sometimes non-sustained triggered activity. Exposure to Tyrode's solution containing TEA and ouabain caused sustained triggered activity, supporting the hypothesis that accumulation of extracellular K inhibits the development of triggered activity. Presumably, the reduction in gK caused by TEA is not reversed by accumulation of extracellular K so that the delayed afterdepolarizations in the presence of persistently reduced gK are large enough to induce sustained triggered activity. Under extreme conditions, when Cs replaced K and half the NaCl was replaced by TEA, delayed afterdepolarizations occurred in the presence of markedly reduced gK, the result being the rapid development of sustained triggered activity, even at the basic drive rate of 1 Hz. Our results suggest that reduced gK plays an important role in the development of triggered activity.

Dynamic calcium requirements for activation of rabbit papillary muscle calculated from tension-independent heat

The heat generated by right ventricular papillary muscles of rabbits was measured after adenosine triphosphate (ATP) splitting by the contractile proteins was chemically inhibited. This tension-independent heat (TIH) (1 mJ/g wet weight) was used to calculate the total calcium (Ca) cycled in a muscle twitch by assuming that 87% of TIH was due to Ca2+ transport by the sarcoplasmic reticulum with a coupling ratio of 2 Ca2+/ATP split; the enthalpy of creatine phosphate hydrolysis buffering ATP was taken as -34 KJ/mol. The estimated Ca turnover per muscle twitch at 21 degrees C, 0.2 Hz pacing rate, and 2.5 mM Ca in the Krebs solution was approximately equal to 50 nmol/g wet weight. There was a tight positive correlation between TIH and mechanical activation during steady-state measurements but no correlation during the sharp increase in mechanical activation (treppe) when stimulation was resumed after a rest period. It is suggested that while total Ca cycling remains unchanged during the initial period of tension treppe, the free Ca2+ transient and mechanical activation increase sharply due to resaturation of high affinity Ca2+ buffers, other than troponin C, depleted of Ca2+ during the rest period.

The effects of 2,3-butanedione monoxime on initial heat, tension, and aequorin light output of ferret papillary muscles

At low concentrations (up to 5 mM) the compound 2,3-butanedione monoxime (BDM) was found to reduce twitch tension and initial heat production in isolated papillary muscles without significantly affecting the size of the intracellular Ca2+ transient measured with aequorin luminescence. Higher concentrations of BDM caused further inhibition of twitch tension and heat production with a fall in the size of the Ca2+ transient. The size of the aequorin transient was 50% of the control value at 15 mM BDM while twitch tension was negligible. These results suggest that BDM selectively inhibits Ca2+ activated force in cardiac muscle at low concentrations with additional effects on intra-cellular calcium at concentrations above 5 mM.

Oxidative and glycolytic ATP formation of rabbit papillary muscle in oxygen and nitrogen

Contraction-related O2 consumption of rabbit papillary muscles was determined at 20 degrees C by measuring change in saline PO2 during and after trains of 120 twitches at 0.125-1 Hz in a microrespirometer. Although anoxic cores occurred at twitch frequencies greater than 0.2 Hz, no lactate was found in saline after twitch train. To measure lactate accumulation in muscle, fully oxygenated muscles were frozen at rest and during steady-state twitches at 0.2 Hz. We also measured nucleotides and creatine (Cr) compounds. There were no differences in lactate, ATP, and phosphocreatine (PCr) content between the resting and active muscles. When a P-to-O2 ratio of 6.3 is assumed, aerobic ATP formation was compared with glycolytic ATP formation during anoxia at a stimulus frequency of 0.2 Hz. The latter value was obtained by freezing muscles between 6 and 25 min after changing from O2- to N2-saturated saline. Withdrawal of O2 caused the ratio of PCr to total Cr to fall in less than 6 min from 0.77 to 0.23, while ATP remained at approximately 15 mumol/g dry wt. Force fell initially within 4 min to approximately 70% of control value, decreasing thereafter more slowly to approximately 40% at 20 min. From the relationship between amount of lactate formed and duration of anoxia, rate of anaerobic ATP formation was calculated assuming a P-to-lactate ratio of 1. We found that despite continuing contractile activity, anaerobic ATP formation was less than that required by a fully oxygenated resting muscle and was about the same magnitude as the estimated ATP hydrolysis for the contractions in N2. We conclude that in fully oxygenated rabbit papillary muscles no net lactate is produced during stimulation and that in anoxia anaerobic glycolytic capacity may not provide sufficient ATP for processes other than the uptake of Ca by the sarcoplasmic reticulum and cross-bridge cycling.

Modulation of Ca2+ transients and contractile properties by beta-adrenoceptor stimulation in ferret ventricular muscles

1. The mechanism of modulation of Ca2+ transients and contraction by beta-adrenoceptor stimulation was studied in ferret ventricular muscles using aequorin to measure intracellular Ca2+. 2. Peaks of tension and light transients were increased by isoprenaline (10(-9) - 5 x 10(-7) M) which also abbreviated their time courses. 3. Time-to-peak tension was significantly shortened by 5 x 10(-9) M-isoprenaline and time-to-peak light was abbreviated by 10(-9) M-isoprenaline. 4. The time for the light to decay was shortened at 10(-9) M-isoprenaline. However, a higher concentration of isoprenaline (10(-8) M) was required for significant shortening of the half-relaxation time (TR50). 5. When isoprenaline was removed and beta-blocker (bupranolol, 1 microM) was applied, the time course of the light transients recovered but the time course of relaxation did not recover. 6. The relationship between [Ca2+]i and tension in tetanic contraction produced in the presence of ryanodine (5 microM) was shifted to the right by isoprenaline (10(-8) M). This was recovered by the replacement of isoprenaline with bupranolol (1 microM). 7. Isoprenaline (10(-7) M) added to the solution containing 20 mM [Ca2+]O and Bay K 8644 (1 microM), which produced maximal tension, caused a large light signal and enhancement of the initial phasic tension in tetanic contraction. However, the replacement of isoprenaline with bupranolol after immersing the preparation in 20 mM [Ca2+]O solution with Bay K 8644 and isoprenaline, did not significantly change the tension level, although the light signal decreased. Similar results were obtained in the ventricular muscle of young rats. 8. These results suggest that the dose dependence of modulation of the contractile element and sarcoplasmic reticulum (SR) by beta-adrenoceptor stimulation differs, and that additional factors, other than the faster Ca2+ uptake by SR and the decrease in Ca2+ sensitivity of the contractile element, might be involved in the shortening of the half-relaxation time by beta-adrenoceptor stimulation. In addition, beta-adrenoceptor stimulation does not produce a marked change in the maximal tension level.