Single adult rabbit and rat cardiac myocytes retain the Ca2+- and species-dependent systolic and diastolic contractile properties of intact muscle

The systolic and diastolic properties of single myocytes and intact papillary muscles isolated from hearts of adult rats and rabbits were examined at 37 degrees C over a range of stimulation frequencies and bathing [Ca2+]o (Cao). In both rabbit myocytes and intact muscles bathed in 1 mM Cao, increasing the frequency of stimulation from 6 to 120 min-1 resulted in a positive staircase of twitch performance. During stimulation at 2 min-1, twitch performance also increased with increases in Cao up to 20 mM. In the absence of stimulation, both rabbit myocytes and muscles were completely quiescent in less than 15 mM Cao. Further increases in Cao caused the appearance of spontaneous asynchronous contractile waves in myocytes and in intact muscles caused scattered light intensity fluctuations (SLIF), which were previously demonstrated to be caused by Ca2+-dependent spontaneous contractile waves. In contrast to rabbit preparations, intact rat papillary muscles exhibited SLIF in 1.0 mM Cao. Two populations of rat myocytes were observed in 1 mM Cao: approximately 85% of unstimulated cells exhibited low-frequency (3-4 min-1) spontaneous contractile waves, whereas 15%, during a 1-min observation period, were quiescent. In a given Cao, the contractile wave frequency in myocytes and SLIF in intact muscles were constant for long periods of time. In both intact rat muscles and myocytes with spontaneous waves, in 1 mM Cao, increasing the frequency of stimulation from 6 to 120 min-1 resulted, on the average, in a 65% reduction in steady state twitch amplitude. Of the rat myocytes that did not manifest waves, some had a positive, some had a flat, and some had a negative staircase; the average steady state twitch amplitude of these cells during stimulation at 120 min-1 was 30% greater than that at 6 min-1. In contrast to rabbit preparations, twitch performance during stimulation at 2 min-1 saturated at 1.5 mM Cao in both intact rat muscles and in the myocytes with spontaneous waves. We conclude that the widely divergent, Ca2+-dependent systolic and diastolic properties of intact rat and rabbit cardiac muscle are retained with a high degree of fidelity in the majority of viable single myocytes isolated from the myocardium of these species, and that these myocytes are thus a valid model for studies of Ca2+-dependent excitation-contraction mechanisms in the heart.     

Isometric force development, isotonic shortening, and elasticity measurements from Ca(2+)-activated ventricular muscle of the guinea pig

Isometric tension and isotonic shortening were measured at constant levels of calcium activation of varying magnitude in mechanically disrupted EGTA-treated ventricular bundles from guinea pigs. The results were as follows: (a) The effect of creatine phosphate (CP) on peak tension and rate of shortening saturated at a CP concentration more than 10 mM; below that level tension was increased and shortening velocity decreased. We interpreted this to mean that CP above 10 mM was sufficient to buffer MgATP(2-) intracellularly. (b) The activated bundles exhibited an exponential stress-strain relationship and the series elastic properties did not vary appreciably with degree of activation or creatine phosphate level. (c) At a muscle length 20 percent beyond just taut, peak tension increased with Ca(2+) concentration over the range slightly below 10(-6) to slightly above 10(-4)M. (d) By releasing the muscle length-active tension curves were constructed. Force declined to 20 percent peak tension with a decrease in muscle length (after the recoil) of only 11 percent at 10(-4)M Ca(2+) and 6 percent at 4x10(-6)M Ca(2+). (e) The rate of shortening after a release was greater at lower loads. At identical loads (relative to maximum force at a given Ca(2+) level), velocity at a given time after the release was less at lower Ca(2+) concentrations; at 10 M(-5), velocity was 72 percent of that at 10(-4)M, and at 4x10(-6)M, active shortening was usually delayed and was 40 percent of the velocity at 10(-4) M. Thus, under the conditions of these experiments, both velocity and peak tension depend on the level of Ca(2+) activation over a similar range of Ca(2+) concentration.     

Inhibition of aminoacyl-transfer ribonucleic acid synthetases and the regulation of amino acid biosynthetic enzymes in Neurospora crassa.

Growth conditions that result in the accumulation of the tryptophan intermediate indoleglycerol phosphate or of the histidine intermediate imidazoleglycerol phosphate cause mycelia of Neurospora crassa to exhibit an immediate and sustained increase in the differential rate at which the biosynthetic enzymes of the tryptophan, histidine, and arginine pathways are synthesized. These accumulated intermediates are shown to be inhibitors of the activity of aminoacyltransfer ribonucleic acid (tRNA) synthetases, as judged by an in vitro esterification assay. The tryptophan intermediate is shown to inhibit the charging of tryptophan, and the histidine intermediate is shown to inhibit charging of histidine. The inhibitions noted are consistent with the finding that the level of charged tRNATrp is decreased significantly in cells that have accumulated indoleglycerol phosphate and that of tRNAHis is decreased significantly in cells that have accumulated imidazoleglycerol phosphate. These results are interpreted as support for the involvement of aminoacyl-tRNA species in mediating cross-pathway regulation of the tryptophan, histidine, and arginine biosynthetic pathways as proposed in Lester's polyrepressor hypothesis (G. Lester, 1971). the correlations noted lead to the conclusion that Neurospora utilizes regulatory mechanisms that have the ability to react to changes in the level of charging of tRNA species.     

High-level expression of the 32.5-kilodalton calelectrin in ductal epithelia as revealed by immunocytochemistry

Abstract. Calelectrins are a family of antigenically related Ca²⁺-binding proteins that have only recently been described. They have the important property of binding to membranes only in the presence of Ca²⁺. We systematically studied the tissue localization of one calelectrin, the 32.5-kilodalton species, in rats using immunocytochemistry. We found that high levels were exclusively present in the epithelial cells of bile and pancreatic ducts, renal collecting ducts, bronchial epithelia, and brain ependyma. In all of these organs, the other cells were not immunoreactive. In addition, strong immunoreactivity was found in the intercalated disks of myocardial cells, and mild immunoreactivity was observed in several endocrine tissues. In contrast, the cellular distribution of the 67-kilodalton calelectrin was more diffuse, involving most parenchymal cells in addition to the already-mentioned cells. Due to the presence of high levels of 32.5-kilodalton calelectrin in some cell types, this protein may be used as a histochemical marker for differentiated ductal epithelial cells, some specialized epithelia, myocardial cells, and Paneth cells.     

G(i)-dependent localization of beta(2)-adrenergic receptor signaling to L-type Ca(2+) channels

A plausible determinant of the specificity of receptor signaling is the cellular compartment over which the signal is broadcast. In rat heart, stimulation of beta(1)-adrenergic receptor (beta(1)-AR), coupled to G(s)-protein, or beta(2)-AR, coupled to G(s)- and G(i)-proteins, both increase L-type Ca(2+) current, causing enhanced contractile strength. But only beta(1)-AR stimulation increases the phosphorylation of phospholamban, troponin-I, and C-protein, causing accelerated muscle relaxation and reduced myofilament sensitivity to Ca(2+). beta(2)-AR stimulation does not affect any of these intracellular proteins. We hypothesized that beta(2)-AR signaling might be localized to the cell membrane. Thus we examined the spatial range and characteristics of beta(1)-AR and beta(2)-AR signaling on their common effector, L-type Ca(2+) channels. Using the cell-attached patch-clamp technique, we show that stimulation of beta(1)-AR or beta(2)-AR in the patch membrane, by adding agonist into patch pipette, both activated the channels in the patch. But when the agonist was applied to the membrane outside the patch pipette, only beta(1)-AR stimulation activated the channels. Thus, beta(1)-AR signaling to the channels is diffusive through cytosol, whereas beta(2)-AR signaling is localized to the cell membrane. Furthermore, activation of G(i) is essential to the localization of beta(2)-AR signaling because in pertussis toxin-treated cells, beta(2)-AR signaling becomes diffusive. Our results suggest that the dual coupling of beta(2)-AR to both G(s)- and G(i)-proteins leads to a highly localized beta(2)-AR signaling pathway to modulate sarcolemmal L-type Ca(2+) channels in rat ventricular myocytes.