Effects of taurine depletion on intrinsic contractility of rat ventricular papillary muscles

Contractile parameters in Krebs-Henseleit media containing various calcium concentrations were compared in left ventricular papillary muscles of two groups of rats: control and taurine depleted. All tests were carried out with the muscles at initial length, Lmax, the length that produced maximal active tension. From measurements of after- and un-loaded contractions, the velocity-tension curves and the derived maximum velocity of shortening were not different between the groups. Time to peak shortening and extent of shortening were not altered, while relaxation times and contraction duration were significantly prolonged for taurine-depleted muscles. Peak isometric tension and its rate of development were significantly reduced in taurine-depleted muscles compared with controls. Postrest (3 min) stimuli and paired stimuli (200-ms interval) evoked similar potentiated contractile responses in both groups, such that the ratio of their peak tensions remained unchanged. For taurine-depleted muscles the force-frequency relationship (a negative staircase) was parallel to, but lower than, control. These experiments suggest that taurine deficiency leads to reductions in action potential triggered calcium release from internal stores, and deficits in calcium sequestration. This may result from disfacilitation of calcium binding to the sarcoplasmic reticulum and other storage sites during taurine deficiency.     

Isometric contraction induces rapid myocyte remodeling in cultured rat right ventricular papillary muscles

The hypothesis that elevated systolic stress induces myocyte thickening has been difficult to test directly. We tested this hypothesis in working rat right ventricular papillary muscles using a recently developed technique for long-term muscle culture. Muscles were cultured for 36 h either isometrically at different levels of systolic stress or at physiological amounts and rates of shortening. Isometric contraction induced rapid increases in myocyte diameter regardless of the level of systolic stress, whereas control myocyte dimensions were maintained if physiological amounts and rates of systolic shortening were imposed. Myocyte thickening was accompanied by a significant decrease in cell length and number of sarcomeres in series along the long axis of the myocyte, suggesting that thickening may have occurred in part by rearrangement of existing sarcomeres. We conclude that the pattern of systolic shortening and/or diastolic lengthening regulates myocyte shape in working rat right ventricular papillary muscles, whereas systolic stress plays little or no role.     

Modulation of ICa-L by alpha1-adrenergic stimulation in rat ventricular myocytes

We found when L-type calcium current (ICa-L) was recorded with the perforated patch-clamp method in rat ventricular myocytes that bath application of phenylephrine (with propranolol) evoked a biphasic response characterized by an initial transient suppression followed by a sustained potentiation. The transient suppression occurred 30-60 s after phenylephrine perfusion and reached peak inhibition at approximately 2 min. The biphasic modulation of ICa-L was also elicited by methoxamine, and the effects of phenylephrine were blocked by prazosin, indicating that the responses were mediated through alpha1-adrenoceptors. Pretreatment of cells with H7 (100 micromol/L), a broad-spectrum protein kinase inhibitor that inhibits both protein kinase C and A, eliminated potentiation but did not affect transient suppression. The transient suppression occurred concurrently with the acceleration of the fast component of ICa-L inactivation. Depletion of intracellular Ca2+ stores by ryanodine plus caffeine or thapsigargin eliminated the transient suppression. When ICa-L was recorded with whole-cell patch-clamp and with 0.05 mmol/L EGTA in the pipette solution to allow intracellular Ca2+ to fluctuate, phenylephrine evoked a transient suppression as in the perforated patch recordings. Heparin, a specific blocker of IP3 (inositol 1,4,5-trisphosphate) receptors, eliminated the phenylephrine-induced transient suppression of ICa-L when added to the pipette solution. Intensive chelation of intracellular Ca2+ by 5 mmol/L BAPTA (1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid) in the pipette solution also eliminated the phenylephrine-induced transient suppression of ICa-L. We conclude that transient increase in the concentration of intracellular calcium ([Ca2+]i) caused by Ca2+ release from intracellular stores underlies the transient suppression of ICa-L, whereas the potentiation of ICa-L is a result of activation of protein kinases.     

Temperature dependency of calcium responses in mammary tumour cells

Changes of intracellular calcium concentration ([Ca²⁺]_i) induced by the extracellular application of ATP and bradykinin in mouse mammary tumour cells (MMT060562) were investigated by image analysis of fluo-3 fluorescence at 24°C and 35°C. ATP (0·1–100 μM ) and bradykinin (0·1 nM –1 μM ) induced the increase of [Ca²⁺]_i at both temperatures and Ca²⁺-depletion did not affect these [Ca²⁺]_i responses. Both [Ca²⁺]_i responses became more sensitive at 35°C than at 24°C. A clear latency of [Ca²⁺]_i increased after the application of the agonists was observed, and it changed with the concentration of the agonist. As concentrations of ATP or bradykinin became lower, the latency and rise time became longer. At higher concentrations, the latency and rise time approached a constant value. The latency shortened remarkably at 35°C. These results suggested the involvement of a regenerative or threshold process in the [Ca²⁺]_i responses in mammary tumour cells. © 1997 John Wiley & Sons, Ltd.     

Effect of calcium overload on the phosphoinositide breakdown in the rat left ventricular papillary muscle

We investigated the effect of Ca²⁺ overload on the phospholipase C-catalyzed hydrolysis of phosphoinositides in the rat left ventricular papillary muscle. Ca²⁺ overload on the papillary muscle was induced by treatment with 0.3 mM ouabain in Ca²⁺-containing medium following either Ca²⁺-containing or Ca²⁺-free superfusion. The phosphoinositide breakdown was evaluated by determining accumulations of [³H]inositol phosphates ([³H]IPs) in the tissues prelabeled with [³H]inositol. Ca²⁺ repletion following Ca²⁺-free superfusion resulted in a rapid but small increase in resting tension that was not followed by contracture, nor was it associated with a significant increase in [³H]IPs accumulations. Treatment with ouabain following Ca²⁺-containing superfusion increased resting tension after a lag period of several minutes and produced contracture associated with an increase in [³H]IPs accumulations. The ouabain induced increases in resting tension, and accumulations of [³H]IPs were significantly potentiated by prior Ca²⁺-free superfusion instead of Ca²⁺-containing superfusion. There was a significant positive correlation between increases in resting tension and the phosphoinositide breakdown. The increased resting tension and the accumulations of [³H]IPs were not antagonized by treatments with prazosin plus atropine or indomethacin, but were abolished by superfusion with Ca²⁺-free buffer solution. Although the enhanced phospholipase C-catalyzed hydrolysis of phosphoinositides appears to be a consequence rather than a cause of increased intracellular Ca²⁺, such a biochemical change may provoke a positive feedback mechanism to develop the muscle contracture through the putative intracellular messenger action of inositol triphosphate and diacylglycerol.Abbreviations [³H]IPs [³H]Inositol Phosphates - IP Inositol Phosphate - IP₂ Inositol Bisphosphate - IP₃ Inositol Trisphosphate - PI Phosphatidylinositol - PI-4-P Phosphatidylinositol-4-phosphate - PI-4,5-P₂ Phosphatidylinositol 4,5-bisphosphate - PRZ Prazosin - ATR Atropine - INDO Indomethacin - min Minutes     

Tension development of normal and hypertrophied-failing papillary muscles following rapid stimulation

Recent studies have shown that numerous cellular alterations exist in hypertrophied-failing (HF) cardiac muscle. Of particular interest is the finding of an altered ability of the Na-K pump to regulate membrane potential in this tissue during periods of transient stimulation. The present study was designed to determine if this altered Na-K pump function is in any way related to the ability of this tissue to develop force. Along these lines the rate of stimulation (6/min) of normal and hypertrophied-failing right ventricular papillary muscles from cats was increased to 60/min for 90 sec. This procedure was repeated in solutions with low Na+, low Na+ and Ca++, and Ouabain. These solutions were utilized to vary the ionic load on the Na-K pump and the Na-Ca exchanger. The results demonstrate that the pattern of changes in tension in HF papillary muscles seen following periods of rapid stimulation are significantly different from those of normal muscles. The pattern of changes in mechanical performance were found to be similar to the membrane potential changes described in previous studies. In addition, lowering the Na+ load presented to HF muscles returned the characteristic pattern of changes in tension, following drive, toward normal. Ouabain was found to inhibit the changes in tension development following increased rates of stimulation that are thought to be produced by activation of the Na-K pump. The results suggest that the ability of the Na-K pump to maintain normal transmembrane ionic gradients may be altered in HF muscles. This alteration appears to be capable of affecting cellular Ca++ possibly through the Na-Ca exchange system.     

Recovery of vesicular storage and release parameters after high frequency stimulation in rat hippocampus

The replenishment rates estimated from the recovery of synaptic efficacy following synaptic depression are known to be widely scattered. Given the importance of the replenishment during stimulation, especially if it is prolonged, it is important to better understand what influences the recovery of the synaptic efficacy following stimulation. We fit a two-pool model of vesicular secretion to the changes of the excitatory post-synaptic currents recorded in CA1 neurons of rat hippocampal slices to determine how the model parameters change during, and following, long stimulation. The replenishment rate at the end of stimulation inducing synaptic depression differs greatly from that at the beginning of stimulation. It decreases progressively and rapidly (by ~75 % and with a time constant of <10 s) during stimulation, and this is followed by a similarly fast recovery (time constant of ~10 s), but to a steady-state that is approximately twice as large as its pre-stimulation value. Both [Ca⁺⁺]_o and the duration of long stimulation influence the recovery of the replenishment rate. Its new steady-state is significantly higher, if either [Ca⁺⁺]_o is higher or stimulation longer, but the recovery of the replenishment rate becomes clearly slower if [Ca⁺⁺]_o is higher, and faster if stimulation is longer. Many factors thus influence the recovery of the replenishment rate and of the synaptic efficacy, but the stimulation induced [Ca⁺⁺]_i accumulation cannot explain the change of the replenishment rate during recovery. Finally, okadaic acid, which speeds up vesicular trafficking, does not alter the recovery of the replenishment rate. The vesicular replenishment of the RRP following stimulation is thus not likely to be associated with significant vesicular movement.     

Contractile parameters and occurrence of alternans in isolated rat myocardium at supra-physiological stimulation frequency

The cardiac refractory period prevents the heart from tetanic activation that is typically used in noncardiac striated muscle tissue. To what extent the refractory period prevents successive action potentials to activate the excitation-contraction coupling process and contractile machinery at supra-physiological rates, such as those present during ventricular fibrillation, is unknown. Using multicellular trabeculae isolated from rat hearts, we studied amplitude and kinetics of contraction at rates well above the normal in vivo rat heart range. We show that even at twice the maximal heart rate of the rat, little or no mechanical instability is observed; twitch contractions are at steady state, albeit with an elevated active diastolic force. Although the amplitude of contraction increased within in vivo heart rates (positive force-frequency response), at frequencies beyond the maximal heart rate (10-30 Hz) a steady decline of contractile amplitude is observed. Not until 30 Hz do the majority of the isolated muscle preparations show mechanical alternans, where strong and weak beats alternate. Interestingly, unlike striated limb skeletal muscle, fusing of twitch contractions did not cause a continuous increase in peak force: at frequencies of 10 Hz and above, systolic force declines with relatively little elevation in diastolic force. Contractile kinetics continued to accelerate, from 1 Hz up to 30 Hz, whereas the relative speed of contraction and relaxation remained closely coupled, reflected by a singular linear relationship between the maximal and minimal derivative of force (dF/dt). We conclude that cardiac muscle can produce mechanically stable steady-state contractions at supra-physiological pacing rates, while these contractions continue to decline in amplitude and increase in diastolic force past maximal heart rate.     

Impact of the papillary muscles on cardiac magnetic resonance image analysis of important left ventricular parameters in hypertrophic cardiomyopathy

Purpose

The use of cardiac magnetic resonance (CMR) analysis has increased in patients with hypertrophic cardiomyopathy (HCM). Quantification of left ventricular (LV) measures will be affected by the inclusion or exclusion of the papillary muscles as part of the LV mass, but the magnitude of effect and potential consequences are unknown.

Methods

We performed Cine-CMR in (1) clinical HCM patients (n?=?55) and (2) subclinical HCM mutation carriers without hypertrophy (n?=?14). Absolute and relative differences in LV ejection fraction (EF) and mass were assessed between algorithms with and without inclusion of the papillary muscles.

Results

Papillary muscle mass in group 1 was 6.6?±?2.5 g/m² and inclusion of the papillary muscles resulted in significant relative increases in LVEF of 4.5?±?1.8?% and in LV mass of 8.7?±?2.6?%. For group 2 these figures were 4.0?±?0.9 g/m², 3.8?±?1.0?% and 9.5?±?1.8?%, respectively. With a coefficient of variation of 4?%, this 9?% difference in LV mass during CMR follow-up will be considered a change, while in fact the exact same mass may have been assessed according to two different algorithms.

Conclusions

In clinical HCM patients, CMR quantification of important LV measures is significantly affected by inclusion or exclusion of the papillary muscles. In relative terms, the difference was similar in subjects without hypertrophy. This underscores a general need for a uniform approach in CMR image analysis.

     

Performance of papillary muscles from the aging spontaneously hypertensive rat: temporal changes in isometric contraction parameters

Myocardial mechanics in the male spontaneously hypertensive rat (SHR) and Wistar-Kyoto rat (WKY) at 18 months of age were studied. Left ventricular hypertrophy was documented in the SHR by an increase in left ventricle/body weight and left ventricle/tibial length ratios when compared to the WKY (P less than 0.001). Isolated left ventricular papillary muscles were studied at 28 degrees C while contracting 12 times/min at the apex of the length-tension curve. Active and passive length-tension relations were measured at relatively early (65 +/- 3 min) and late (200 +/- 5 min) times following sacrifice. No significant differences in passive length-tension relations between strains were observed. Between early and late measurements, a significant decrease in passive tension within the length spectrum 89-100% Lmax occurred in both SHR and WKY, accompanied by a significant increase in passive stiffness (P less than 0.01, SHR; P less than 0.001, WKY). Isometric performance was measured at relatively early (81 +/- 3 min) and later (190 +/- 5 min) times following sacrifice. Strain differences in active muscle performance were of a greater electromechanical delay time (EMD) (P less than 0.05, early: P less than 0.001, late) and time-to-peak tension (TPT) (P less than 0.001, late) in SHR compared to WKY. Between early and late measurements, decreases in EMD (P less than 0.01, SHR; P less than 0.001, WKY), TPT (P less than 0.001; P less than 0.001), the half-time of relaxation (P less than 0.001; P less than 0.001), and the resting tension (P less than 0.01; P less than 0.001) were observed, and the maximum rate of fall of tension increased (P less than 0.01; P less than 0.01). We conclude that studies must be precisely referenced from the time of sacrifice of the animal in order to accurately evaluate the effects of experimental hypertrophy on isolated muscle performance. No evidence for the depression of papillary muscle isometric performance was seen in the 18-month SHR when compared to the WKY, although prolonged EMD and TPT were observed.     

kappa-Opioid receptor stimulation increases intracellular free calcium in isolated rat ventricular myocytes.

The effect of two specific kappa-agonists, dynorphinA1-13 and U50,488H, on intracellular free calcium [Ca]i in isolated rat ventricular myocytes was studied. A spectrofluorimetric method using fura 2 as calcium indicator was employed. It was found that both agonists increased [Ca]i dose-dependently. The effect was attenuated by Mr 2266, a kappa-antagonist, indicating that the effect is a kappa-receptor mediated event. The effect was abolished by pretreatment with ryanodine, a drug that mobilizes calcium from the sarcoplasmic reticulum. It was, however, not affected by nifedipine, a calcium antagonist or removal of external calcium. The results indicate that the increase in [Ca]i due to kappa-opioid receptor stimulation results primarily from mobilization of calcium from an intracellular pool.     

The functional motility of motor units of the gastrocnemius and soleus muscles in the rat under indirect stimulation depending on the stimulus frequency]

With increasing pulse rate (up to 150 square pulses/sec) applied for 1 second at the gastrocnemius and soleus muscle the amplitude of electromyographic response was found to decrease. An amplitude decrease of sum action potentials (AP) recorded from the muscle surface occurred already at pulse rates below 100 pulses/sec. For the gastrocnemius muscle, this amplitude fall in the medium pulse-rate region can be described by the relation: amplitude = -log-pulse rate. At the soleus muscle, the amplitude fall is shifted towards the higher frequencies. After intensive swimming of the animal the amplitude depression of AP at the gastrocnemius muscle occurs already at a lower rate, and departs from the aforementioned relation. The causes are looked for in the differential properties of the various muscle fibres.     

Adenosine A2A and beta-adrenergic calcium transient and contractile responses in rat ventricular myocytes

The adenosine A2A receptor (A2AR) enhances cardiac contractility, and the adenosine A1R receptor (A1R) is antiadrenergic by reducing the adrenergic beta1 receptor (beta1R)-elicited increase in contractility. In this study we compared the A2AR-, A1R-, and beta1R-elicited actions on isolated rat ventricular myocytes in terms of Ca transient and contractile responses involving PKA and PKC. Stimulation of A2AR with 2 microM (approximately EC50) CGS-21680 (CGS) produced a 17-28% increase in the Ca transient ratio (CTR) and maximum velocities (Vmax) of transient ratio increase (+MVT) and recovery (-MVT) but no change in the time-to-50% recovery (TTR). CGS increased myocyte sarcomere shortening (MSS) and the maximum velocities of shortening (+MVS) and relaxation (-MVS) by 31-34% with no change in time-to-50% relengthening (TTL). beta1R stimulation using 2 nM (approximately EC50) isoproterenol (Iso) increased CTR, +MVT, and -MVT by 67-162% and decreased TTR by 43%. Iso increased MSS, +MVS, and -MVS by 153-174% and decreased TTL by 31%. The A2AR and beta1R Ca transient and contractile responses were not additive. The PKA inhibitor Rp-adenosine 3',5'-cyclic monophosphorothioate triethylamonium salt prevented both the CGS- and Iso-elicited contractile responses. The PKC inhibitors chelerythrine and KIE1-1 peptide (PKCepsilon specific) prevented the antiadrenergic action of A1R but did not influence A2AR-mediated increases in contractile variables. The findings suggest that cardiac A2AR utilize cAMP/PKA like beta1R, but the Ca transient and contractile responses are less in magnitude and not equally affected. Although PKC is important in the A1R antiadrenergic action, it does not seem to play a role in A2AR-elicited Ca transient and contractile events.     

Effect of inhibitors of slow calcium current on resting calcium efflux from cat papillary muscles

Examination of influence of divalent cations (Co2+, Ni2+, Mn2+) and organic blockers (verapamil and D600) on calcium efflux from resting mammalian myocardium shows that they either inhibit or increase transiently 45Ca2+ efflux, depending on the site of action. It seems that those agents whose sites of action are limited to the sarcolemma inhibit Ca2+ efflux. Co2+, Ni2+, verapamil and D600 belong to this group. Mn2+ ions which act also apparently on intracellular structures increase transiently Ca2+ efflux. Such a finding illustrates a diversity in mechanisms of action in a group of agents generally classified as calcium channel blockers.     

Modulation of a neuronal network by electrical high frequency stimulation in striatal slices of the rat in vitro

The effects of the GABA(A) receptor antagonist bicuculline, the D2-like receptor antagonist sulpiride and the D1-like receptor antagonist SCH-23390 on the electrical high frequency stimulation (HFS)-evoked gamma-aminobutyric acid (GABA) and dopamine (DA) release were measured from slices of the rat striatum by means of HPLC method with electrochemical detection. HFS with 130Hz stimulated veratridine-activated GABAergic neurons resulting in an increased GABA outflow while DA outflow decreased. In the presence of the GABA(A) receptor antagonist bicuculline extracellular GABA and DA outflow were enhanced. When the competitive dopamine D2-like receptor antagonist S-(-)-sulpiride was added to incubation medium, the HFS-evoked stimulatory effect on GABA outflow declined to values found after veratridine (1microM) without HFS. After co-incubation of sulpiride and the competitive D1-like receptor antagonist R-(+)-SCH-23390, the effect of sulpiride on HFS plus veratridine-evoked GABA outflow was completely reversed. Neither sulpiride nor SCH-23390 had any influence on the effect of HFS on veratridine-induced DA outflow. No effect of HFS on glutamate outflow was observed in all experiments. These results led us to suggest that in our model HFS primarily affects GABAergic neurons. These neurons are embedded in a neuronal network with a GABA-dopamine circuit, and thus, HFS interacts with a neuronal network, not only with one neurotransmitter system or one neuron population.     

Effects of rapid application of caffeine on intracellular calcium concentration in ferret papillary muscles

In this paper we investigate the effects of caffeine (5-20 mM) on ferret papillary muscle. The intracellular Ca2+ concentration ( [Ca2+]i) was measured from the light emitted by the photoprotein aequorin, which had previously been microinjected into superficial cells. Isometric tension was measured simultaneously. The rapid application of caffeine produced a transient increase of [Ca2+]i, which decayed spontaneously within 2-3 s and was accompanied by a transient contracture. The removal of extracellular Na+ or an increase in the concentration of intracellular Na+ (produced by strophanthidin) increased the magnitude of the caffeine response. Cessation of stimulation for several minutes or stimulation at low rates decreased the magnitude of the stimulated twitch and Ca2+ transient. These maneuvers also decreased the size of the caffeine response. These results are consistent with the hypothesis that the caffeine-releasable pool of Ca2+ (sarcoplasmic reticulum) is modulated by maneuvers that affect contraction. Ryanodine (10 microM) decreased the magnitude of the caffeine response as well as that of the stimulated twitch. In contrast, the rapid removal of external Ca2+ abolished the systolic Ca2+ transient within 5 s, but had no effect on the caffeine response. From this we conclude that the abolition of twitch by Ca2+-free solutions is not due to depletion of the sarcoplasmic reticulum of Ca2+, but may be due to a requirement of Ca2+ entry into the cell to trigger Ca2+ release from the sarcoplasmic reticulum.     

Modulation of functional activities in cultured rat hepatocytes

Rat hepatocytes isolated by enzymatic dissociation of the liver must attach in order to survive for more than a few hours. In conventional culture conditions, they rapidly lose their highly differentiated functions, e.g. adult isozymic forms, enzyme response to specific hormones and cytochrome P-450-dependent monooxygenase activities. Incompletely differentiated cells such as perinatal and regenerating hepatocytes, can transiently exhibit a more differentiated state. Therefore, regulation of hepatic functions, particularly enzyme activities cannot be studied for more than a few days. Hepatocyte survival rate and maintenance of specific functions are dependent on nutrient composition of the medium as well as the substrate. Complex matrices, particularly that derived from the connective liver biomatrix, appear to have an important favorable effect. However, regardless of culture conditions specific functions cannot be quantitatively maintained for more than several days. Recent observations strongly suggest that such a problem may be overcome by mimicking in vivo specific cell-cell interactions. Thus when co-cultured with a liver epithelial cell line, probably derived from biliary ductular cells, adult hepatocytes remain able to synthesize high levels of albumin and to conjugate drugs. In these conditions, the cells secrete an abundant heterogeneous extracellular material. The co-cultures can be maintained in a serum-free medium and specific liver functions can be altered experimentally. Such a model could be appropriate for studying long-term induction and modulation of liver enzyme activities under defined experimental conditions.