Impaired cardiac function in rats with healed myocardial infarction: cellular vs. myocardial mechanisms.

The inotropic responsiveness of isolated perfused rat hearts and single left ventricular (LV) myocytes to extracellular Ca2+ ([Ca2+]o) was examined 3 wk after ligation of left main coronary artery. Myocytes isolated from myocardial infarcted (MI) hearts were 10% longer. At [Ca2+]o of 1.1 mM, cell shortening as well as intracellular Ca2+ concentration dynamics were similar between MI and sham LV myocytes. At [Ca2+]o of 4.9 mM, maximal extent of cell shortening was significantly less in MI myocytes (16 +/- 1 vs. 22 +/- 1%), and peak intracellular Ca2+ concentration was also substantially lower. Thus, under conditions of high [Ca2+]o, decreased sarcolemmal Ca2+ influx and Ca2+ release during excitation-contraction may contribute to systolic dysfunction in MI hearts. Perfused working hearts and isovolumic heart preparations with infarcted LV displayed depressed maximal systolic pressure and decreased sensitivity to the inotropic effects of [Ca2+]o. Our data also indicate that, in addition to possible abnormalities in the contractile response of single myocytes, global factors such as loss of functional myocardium, altered chamber geometry, tissue fibrosis, and/or subendocardial ischemia contributed to depressed LV function in post-MI hearts perfused at physiological [Ca2+]o.

Effects of cholecystokinin on cytosolic calcium in pancreatic duct segments and ductal cells.

Although the gastrointestinal peptide cholecystokinin (CCK) has been shown to increase bicarbonate and water secretion and potentiate the effects of secretin on pancreatic ducts, CCK receptors have not been identified on pancreatic ductal epithelium. The effects of CCK octapeptide (CCK-8) on cytosolic calcium were evaluated on microscopically dissected rat pancreatic duct segments and single rat duct cells from the established ARIP cell line. By use of fluorescence microscopy in fura-2-loaded duct segments or single cells, intracellular calcium concentration was measured in response to CCK-8 (4 x 10(-12)-4 x 10(-8) M). CCK-8 significantly increased cytosolic calcium up to 50-fold over baseline. The greatest increase occurred with the highest concentration of CCK-8 (4 x 10(-8) M). Oscillations were observed in experiments performed in buffer containing 0.68 mM physiological calcium. In another series of experiments performed in the presence of ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid to deplete extracellular calcium, CCK-8 treatment still resulted in significant increases in cytosolic calcium; however, oscillations were abolished. Since cytosolic calcium increased in the absence of extracellular calcium, the initial calcium rise most likely was from cytosolic stores. Our findings of CCK-8-stimulated increases in cytosolic calcium in microdissected pancreatic ducts suggest the presence of CCK receptors, a characteristic that was not lost in cultured pancreatic ductal cells. In addition, in ARIP cells, the CCK-8-induced increase in cytosolic calcium was abolished by pretreatment with the selective CCK-B receptor antagonist L-365,260 but not by the CCK-A receptor antagonist L-364,718.

Chronic exercise alters contractility and morphology of isolated rat cardiac myocytes.

Chronic exercise training elicits positive adaptations in cardiac contractile function and ventricular dimension. The potential contribution of single myocyte morphological and functional adaptations to these global responses to training was determined in this study. Left ventricular cardiac myocytes were isolated from the hearts of sedentary control (Sed) or exercise-trained (TR) rats. Training elicited an approximately 5% increase in resting myocyte length (Sed, 121.0 +/- 2.0 vs. TR, 126.7 +/- 2.0 microns; P < 0.05), whereas resting sarcomere length and midpoint cell width were unaffected. These data suggest that longitudinal myocyte growth contributes to the training-induced increase in end-diastolic dimension. Single myocytes (28 degrees C) were stimulated at 0.067 and 0.2 Hz and shortening dynamics assessed at extracellular Ca2+ concentrations ([Ca2+]o) of 0.6, 1.1, and 2.0 mM. In both groups, maximal extent of myocyte shortening (ESmax) increased as [Ca2+]o increased and decreased as contraction frequency increased. TR myocytes were more strongly influenced by the effects of [Ca2+]o and frequency. At 0.067 Hz and 2.0 mM, ESmax was greater in TR than in Sed myocytes. The magnitude of this difference decreased as [Ca2+]o was reduced. At 0.2 Hz, ESmax was similar in Sed and TR myocytes at 2.0 mM [Ca2+]o. As [Ca2+]o was reduced, ESmax decreased more rapidly in TR than in Sed myocytes; at 0.6 mM, ESmax was greater in Sed than in TR myocytes. Our data indicate that chronic exercise influences cardiac contractile function at the single myocyte level. This study also provides evidence in support of the hypothesis that chronic exercise influences myocyte Ca2+ influx and efflux pathways.(ABSTRACT TRUNCATED AT 250 WORDS)

Relaxation abnormalities in single cardiac myocytes from renovascular hypertensive rats.

In myocardial hypertrophy secondary to renovascular hypertension, the rate of intracellular Ca2+ concentration decline during relaxation in paced left ventricular (LV) myocytes isolated from hypertensive (Hyp) rats is much slower compared with that from normotensive (Sham) rats. By use of a novel liquid-crystal television-based optical-digital processor capable of performing on-line real-time Fourier transformation and the striated pattern (similar to 1-dimensional diffraction grating) of cardiac muscle cells, sarcomere shortening and relaxation velocities were measured in single Hyp and Sham myocytes 18 h after isolation. There were no differences in resting sarcomere length, percent of maximal shortening, time to peak shortening, and average sarcomere shortening velocity between Sham and Hyp cardiac cells. In contrast, average sarcomere relaxation velocity and half-relaxation time were significantly prolonged in Hyp myocytes. Contractile differences between Sham and Hyp myocytes detected by the optical-digital processor are confirmed by an independent method of video tracking of whole cell length changes during excitation-contraction. Despite the fact that freshly isolated myocytes contract more rigorously than 18-h-old myocytes, the relaxation abnormality was still observed in freshly isolated Hyp myocytes, suggesting impaired relaxation is an intrinsic property of Hyp myocytes rather than changes brought about by short-term culture. We postulate that reduced sarcomere relaxation velocity is a direct consequence of impaired Ca2+ sequestration-extrusion during relaxation in Hyp myocytes and may be responsible for diastolic dysfunction in hypertensive hypertrophic myocardium at the cellular level.

Calcium transients during Fc receptor-mediated and nonspecific phagocytosis by murine peritoneal macrophages.

Studies with populations of macrophages have produced conflicting results concerning the possibility that the concentration of intracellular ionized calcium [( Ca2+]i) may act as an important mediator for phagocytosis. Since asynchronous changes in [Ca2+]i in individual cells undergoing phagocytosis may be averaged to undetectability in population studies, we studied single adhering murine macrophages using fura-2 and our previously described digital imaging system. The proportion of macrophages phagocytosing IgG-coated latex beads was greater than for uncoated beads (percent phagocytosing cells: 71 +/- 7 vs. 27 +/- 7, P less than 0.01). Phagocytosis of IgG-coated and uncoated beads was always associated with a calcium transient that preceded the initiation of phagocytosis. No calcium transients were detected in cells that bound but did not phagocytose beads. Four major differences between Fc receptor-mediated and nonspecific phagocytosis were detected: (a) the duration of calcium transients was longer for nonspecific phagocytosis compared with Fc receptor-mediated phagocytosis (69.9 +/- 10.2 vs. 48.7 +/- 4.7 s, P less than 0.05) and the magnitude of calcium transients was less for nonspecific phagocytosis (178 +/- 43 vs. 349 +/- 53 nM, P less than 0.05); (b) removal of extracellular calcium abolished the calcium transients associated with nonspecific phagocytosis but had no effect on those associated with receptor-mediated phagocytosis; (c) in the absence of extracellular calcium, buffering intracellular calcium with a chelator reduced Fc receptor-mediated phagocytosis but had no additive inhibitory effect on nonspecific phagocytosis; and (d) inhibition of protein kinase C (PKC) with staurosporine inhibited nonspecific phagocytosis but had no effect on receptor-mediated phagocytosis. Our observations suggest that despite both types of phagocytosis being associated with intracellular calcium transients, the role played by intracellular calcium in the signaling pathways may differ for Fc receptor-mediated and nonspecific phagocytosis by elicited murine macrophages.

Nuclear calcium gradients in cultured rat hepatocytes.

Ca2+ concentrations ([Ca2+]) in cytosol and nucleus in fura-2-loaded cultured rat hepatocytes were determined by three-dimensional (3-D) optical-sectioning microscopy. After determining the empirical 3-D point spread function of the fluorescence microscope-coupled digital video imaging system, contaminating light arising from optical planes above and below the plane of interest was removed by deconvolution using the nearest-neighboring approach (NNA) algorithm. Although deconvolution resulted in substantial improvement in accuracy of fluorescence intensity determinations in single-wavelength excitation images as well as sharper delineation of boundaries between cellular compartments, the complicated mathematical process did not significantly enhance the precision of [Ca2+] values derived from ratiometric (ratio of dual-wavelength excitation) images. In resting hepatocytes, cytosolic Ca2+ (210 +/- 15 nM) was 1.6- to 2-fold higher than nuclear Ca2+ (128 +/- 12 nM). This difference in Ca2+ between the two compartments was detected both in raw ratiometric images and in those processed with NNA algorithm. Addition of arginine vasopressin or epidermal growth factor resulted in significant increases (2- to 3-fold) in both cytosolic and nuclear Ca2+; however, the nuclear-to-cytosolic Ca2+ gradient was preserved in hepatocytes stimulated with mitogens. We conclude that the hepatocyte nuclear membrane contains Ca2+ permeability barriers and Ca2+ transport mechanisms that may be hormonally sensitive. We postulate that the increase in nuclear Ca2+ may be important in regulation of cell proliferation induced by mitogens, possibly by activating Ca(2+)-dependent endonucleases, nuclear calmodulin, or nuclear protein kinase C.

Altered Ca2+ dynamics in single cardiac myocytes from renovascular hypertensive rats.

Several functional and biochemical characteristics of hypertrophied hearts isolated from rats with renovascular hypertension provide indirect evidence that cellular Ca2+ dynamics during myocardial contraction-relaxation are altered. In this study, intracellular Ca2+ concentration ([Ca2+]i) dynamics were examined in paced left ventricular (LV) myocytes isolated from rats with hypertension (HYP) induced by partial occlusion of the left renal artery and from normotensive rats (Sham). Characteristic myocardial changes produced by renovascular hypertension included a 40% increase in LV weight and a 3.6-fold increase in the fractional expression of the beta-heavy chain of myosin in isolated LV myocytes. In periods of mechanical quiescence between contractions, basal [Ca2+]i values were similar in Sham and HYP LV myocytes. During a contraction-relaxation cycle in HYP myocytes, peak [Ca2+]i, +d[Ca2+]i/dt, and -d[Ca2+]i/dt were reduced, whereas the time required for [Ca2+]i to rise from a basal value to a peak value (time-to-peak [Ca2+]i) was unaffected. In both Sham and HYP myocytes, the fall in [Ca2+]i from peak to basal values could be approximated by a monoexponential rate constant, kf. Values for kf were significantly smaller in HYP than in Sham myocytes. After treatment with 4 microM isoproterenol, peak [Ca2+]i, +[Ca2+]i/dt, -d[Ca2+]i/dt, and kf increased in both Sham and HYP myocytes. In contrast, basal [Ca2+]i and time-to-peak [Ca2+]i did not change. Thus, despite recent reports of inefficiencies of beta-adrenergic receptor coupling, there was no evidence of blunted beta-adrenergic responsiveness in HYP myocytes with respect to [Ca2+]i dynamics during contraction-relaxation. Finally, no Sham vs. HYP differences in the number of specific [3H]-PN200-110 binding sites per cell in quiescent, rod-shaped myocytes were detected, but a significant reduction in [3H]-PN200-110 binding sites in an enriched sarcolemmal membrane fraction isolated from HYP animals was observed. These observations are suggestive of a reduction in slow, Ca2+ channel surface density in HYP myocytes. The results of this study clearly indicate that [Ca2+]i dynamics during contraction-relaxation in single left ventricular myocytes are affected by residence in a chronic setting of renovascular hypertension. In addition, the prolonged [Ca2+]i removal phase observed in HYP myocytes can be restored toward normal by beta-adrenergic agonists.

Three-dimensional intracellular calcium gradients in single human burst-forming units-erythroid-derived erythroblasts induced by erythropoietin.

We have previously shown that the intracellular free Ca2+ increase induced by erythropoietin is likely related to differentiation rather than proliferation in human BFU-E-derived erythroblasts (1989. Blood. 73:1188-1194). Since cell differentiation involves transcription of specific regions of the genome, and since nuclear endonucleases responsible for single strand DNA breaks observed in cells undergoing differentiation are Ca2+ dependent, we investigated whether the erythropoietin-induced calcium signal is transmitted from cytosol to nucleus in this study. To elucidate subcellular Ca2+ gradients, the technique of optical sectioning microscopy was used. After determining the empirical three-dimensional point spread function of the video imaging system, contaminating light signals from optical planes above and below the focal plane of interest were removed by deconvolution using the nearest neighboring approach. Processed images did not reveal any discernible subcellular Ca2+ gradients in unstimulated erythroblasts. By contrast, with erythropoietin stimulation, there was a two- to threefold higher Ca2+ concentration in the nucleus compared to the surrounding cytoplasm. We suggest that the rise in nuclear Ca2+ may activate Ca2(+)-dependent endonucleases and initiate differentiation. The approach described here offers the opportunity to follow subcellular Ca2+ changes in response to a wide range of stimuli, allowing new insights into the role of regional Ca2+ changes in regulation of cell function.

Cytosolic free calcium concentration in individual cardiac myocytes in primary culture.

Cytosolic free Ca2+ concentration, [Ca2+]i, of single isolated Ca2+-tolerant rat ventricular myocytes in primary culture was determined by digital video imaging of intracellular fura-2 fluorescence. In deenergized myocytes in which contractile elements were uncoupled by 2,3-butanedione monoxime, the maximum and minimum fluorescence intensity ratio values of fura-2 in the cell were similar when compared with those of fura-2 solutions observed in the microscope. Through the use of in vitro calibration, [Ca2+]i in quiescent, rod-shaped myocytes was 90 +/- 6 nM. There was no detectable spatial heterogeneity in [Ca2+]i in resting myocytes. Localized regions of [Ca2+]i elevation were observed in cells undergoing spontaneous rhythmic contractions or when subjected to mild depolarization by KCl. Additions of gramicidin or veratridine resulted in massive increases in [Ca2+]i (greater than 1 microM) and immediate cell hypercontracture. Ruthenium red elicited a modest increase in [Ca2+]i but extracellular ATP or epinephrine had no effect. We conclude the following: 1) digital video imaging of resting cardiac cells did not reveal any subcellular Ca2+ gradients; 2) the fluorescence properties of intracellular fura-2 were similar to that in free solution; and 3) subcellular heterogeneity of [Ca2+]i in isolated myocytes was observed in cells undergoing spontaneous rhythmic contraction.