Inhibitors of protein kinase C prolong the falling phase of each free-calcium transient in a hormone-stimulated hepatocyte.

Many cells generate oscillations in cytoplasmic free Ca2+ concentration ('free Ca') when stimulated with Ca-mobilizing hormones. The frequency of repetitive free-Ca transients in a rat hepatocyte is a function of hormone concentration and can be depressed by phorbol esters. We show here that the protein kinase C (PKC) inhibitors staurosporine and sphingosine can reverse the effects of phorbol dibutyrate on the frequency of free-Ca transients induced by phenylephrine or vasopressin. An important feature of the hepatocyte free-Ca oscillator is that the transient's time course, particularly the rate of fall of free Ca from peak to resting, depends on the species of agonist, and is measurably different for phenylephrine, vasopressin, angiotensin II or ATP. We show here that the rate of fall of free Ca in transients induced by phenylephrine or vasopressin is markedly decreased after treatment of the cells with a PKC inhibitor. A receptor-controlled oscillator model is discussed, in which PKC provides negative feedback during the falling phase of free-Ca transients.     

The hepatocyte calcium oscillator

Hepatocytes stimulated with calcium-mobilising agonists generate free Ca transients whose frequency is modulated by hormone concentration. Importantly, the time-course of individual free Ca transients is independent of agonist dose but does change with agonist species. A receptor-controlled model in which protein kinase C provides negative feedback directed against the different receptors, or receptor-specific G proteins, has been proposed in order to explain the agonist-specificity of the falling phase of the free Ca spikes. Here we show further evidence, from mixing of hormones and from the effects of elevated cAMP, of receptor-specific information within the spikes.     

Desensitization and recovery of muscarinic and histaminergic Ca2+ mobilization in 1321N1 astrocytoma cells.

Intracellular free Ca2+ was monitored in suspensions of 1321N1 astrocytoma cells by using the Ca2+ indicator fura-2. The cytoplasmic Ca2+ concentration increased from 237 +/- 6 nM to 1580 +/- 170 nM within 3-5 s of addition of 300 microM-carbachol. After the peak in response, the Ca2+ concentration diminished, establishing a new steady state in about 1 min that was approx. 150 nM above the previous baseline. Histamine increased cytoplasmic Ca2+ to about 40% of the maximal value seen with carbachol. In Ca2+-free buffer each agonist elicited a normal initial increase in cytoplasmic Ca2+, but the sustained portion of the response was abolished. The increase in Ca2+ in response to either carbachol or histamine could be completely inhibited by pretreating the cells with carbachol; the response to carbachol could be partially inhibited by pretreating the cells with histamine. The Ca2+ responses did not recover in the continued presence of carbachol. However, if the carbachol was washed out or if atropine was added after carbachol, the responses to agonist recovered in a time-dependent manner (half-time 3-4 min), and recovery depended on the presence of extracellular calcium. The results indicate that carbachol and histamine stimulate release of Ca2+ from the same intracellular Ca2+ store, that depletion of this store is responsible for heterologous desensitization between these two agonists, and that repletion of the agonist-sensitive Ca2+ pool does not occur in the continued presence of agonist or in the absence of extracellular Ca2+.     

Thimerosal enhances agonist-specific differences between [Ca2+]i oscillations induced by phenylephrine and ATP in single rat hepatocytes.

Single rat hepatocytes, microinjected with the Ca(2+)-sensitive photoprotein aequorin, respond to agonists acting through the phosphoinositide signalling pathway by the generation of oscillations in cytosolic free Ca2+ concentration ([Ca2+]i). The duration of [Ca2+]i transients generated is characteristic of the stimulating agonist; the differences lie in the rate of fall of [Ca2+]i from its peak. We considered that differential sensitivity of the InsP3 receptor may underlie agonist specificity. The thiol reagent, thimerosal, is known to increase the sensitivity of the Ca2+ stores to InsP3 by increasing the affinity of the InsP3 receptor for InsP3 in rat hepatocytes. We show here that a low dose of thimerosal (1 microM), insufficient alone to elevate [Ca2+]i, potentiates [Ca2+]i oscillations induced by phenylephrine or ATP in single, aequorin-injected, rat hepatocytes. Moreover, thimerosal enhances both the frequency and amplitude of phenylephrine-induced oscillations, whereas, in contrast, ATP-induced oscillations undergo an increase in the duration of the falling phase of individual [Ca2+]i transients. Thimerosal, therefore, enhances, rather than eliminates, agonist-specific differences in the hepatocyte [Ca2+]i oscillator.     

Ca2+ influx pathways mediated by swelling or stores depletion in mouse thymocytes

We used fura-2 video imaging to characterize two Ca2+ influx pathways in mouse thymocytes. Most thymocytes (77%) superfused with hypoosmotic media (60% of isoosmotic) exhibited a sharp, transient rise in the concentration of intracellular free Ca2+ ([Ca2+]i). After a delay of approximately 70 s, these swelling-activated [Ca2+]i (SWAC) transients reached approximately 650 nM from resting levels of approximately 100 nM and declined from a time constant of 20 s. Peak [Ca2+]i during transients correlated with maximum volume during swelling. Regulatory volume decrease (RVD) was enhanced in thymocytes exhibiting SWAC transients. Three lines of evidence indicate that Ca2+ influx, and not the release of Ca2+ from intracellular stores, underlies SWAC transients in thymocytes. First, thymocytes swollen in Ca2+-free media failed to respond. Second, Gd3+ and La3+ inhibited SWAC influx with Kd's of 3.8 and 2.4 microM, respectively. Finally, the depletion of Ca2+ stores with thapsigargin (TG) before swelling did not inhibit the generation, nor decrease the amplitude, of SWAC transients. Cell phenotyping demonstrated that SWAC transients are primarily associated with immature CD4-CD8- and CD4+CD8+ thymocytes. Mature peripheral lymphocytes (mouse or human) did not exhibit SWAC transients. SWAC influx could be distinguished from the calcium release-activated Ca2+ (CRAC) influx pathway stimulated by store depletion with TG. In TG- treated thymocytes, [Ca2+]i rose steadily for approximately 100 s, peaked at approximately 900 nM, and then declined slowly. Simultaneous activation of both pathways produced an additive [Ca2+]i profile. Gd3+ and La3+ blocked Ca2+ entry during CRAC activation more potently (Kd's of 28 and 58 nM, respectively) than Ca2+ influx during SWAC transients. SWAC transients could be elicited in the presence of 1 microM Gd3+, after the complete inhibition of CRAC influx. Finally, whereas SWAC transients were principally restricted to immature thymocytes. TG stimulated the CRAC influx pathway in all four thymic CD4/CD8 subsets and in mature T cells. We conclude that SWAC and CRAC represent separate pathways for Ca2+ entry in thymocytes.     

Novel kinetics of single cell Ca2+ transients in stimulated hepatocytes and A10 cells measured using fura-2 and fluorescent videomicroscopy

The kinetics of agonist-induced increases in cytosolic free Ca2+ have been measured in single A10 vascular smooth muscle cells and rat hepatocytes using fluorescent videomicroscopy with fura-2 as a Ca2+ indicator. At high agonist concentrations there was no difference in the kinetics of the Ca2+ transient measured in vasopressin-stimulated single A10 cells or in cell populations. However, stimulation of single A10 cells with concentrations of vasopressin below 0.5 nM produced characteristic Ca2+ transients composed of two distinct peaks. The two peaks appeared to represent a temporal separation between release of intracellular Ca2+ and influx of extracellular Ca2+. The double transient was not observed in single rat hepatocytes stimulated with low concentrations of vasopressin or phenylephrine. In both A10 cells and hepatocytes, the initial rate of increase in Ca2+ concentrations in response to submaximal agonist concentrations was faster in single cells than in cell populations. This difference was due to asynchrony of the cellular response, where there was a latent period of variable length before onset of a rapid increase in Ca2+ concentration. The duration of the latent period was dependent on the agonist concentration, higher concentrations of agonist giving a reduced latent period. The hormone-stimulated Ca2+ transient measured in single hepatocytes with fura-2 was different from the series of transient spikes as previously reported using aequorin as the Ca2+ indicator, suggesting that fura-2 and aequorin may report different aspects of the Ca2+ response in stimulated cells. Collectively, these results demonstrate that measurement of Ca2+ transients in single cells provide novel information concerning the nature of the Ca2+ transient that is not apparent from studies with cell populations.     

Adrenergic stimulation of rat resistance arteries affects Ca(2+) sparks, Ca(2+) waves, and Ca(2+) oscillations

Confocal laser scanning microscopy and fluo 4 were used to visualize local and whole cell Ca(2+) transients within individual smooth muscle cells (SMC) of intact, pressurized rat mesenteric small arteries during activation of alpha1-adrenoceptors. A method was developed to record the Ca(2+) transients within individual SMC during the changes in arterial diameter. Three distinct types of "Ca(2+) signals" were influenced by adrenergic activation (agonist: phenylephrine). First, asynchronous Ca(2+) transients were elicited by low levels of adrenergic stimulation. These propagated from a point of origin and then filled the cell. Second, synchronous, spatially uniform Ca(2+) transients, not reported previously, occurred at higher levels of adrenergic stimulation and continued for long periods during oscillatory vasomotion. Finally, Ca(2+) sparks slowly decreased in frequency of occurrence during exposure to adrenergic agonists. Thus adrenergic activation causes a decrease in the frequency of Ca(2+) sparks and an increase in the frequency of asynchronous wavelike Ca(2+) transients, both of which should tend to decrease arterial diameter. Oscillatory vasomotion is associated with spatially uniform synchronous oscillations of cellular [Ca(2+)] and may have a different mechanism than the asynchronous, propagating Ca(2+) transients.     

Cytoplasmic calcium transients due to single action potentials and voltage-clamp depolarizations in mouse pancreatic B-cells.

Changes in the cytoplasmic free calcium concentration ([Ca2+]i) in pancreatic B-cells play an important role in the regulation of insulin secretion. We have recorded [Ca2+]i transients evoked by single action potentials and voltage-clamp Ca2+ currents in isolated B-cells by the combination of dual wavelength emission spectrofluorimetry and the patch-clamp technique. A 500-1000 ms depolarization of the B-cell from -70 to -10 mV evoked a transient rise in [Ca2+]i from a resting value of approximately 100 nM to a peak concentration of 550 nM. Similar [Ca2+]i changes were associated with individual action potentials. The depolarization-induced [Ca2+]i transients were abolished by application of nifedipine, a blocker of L-type Ca2+ channels, indicating their dependence on influx of extracellular Ca2+. Following the voltage-clamp step, [Ca2+]i decayed with a time constant of approximately 2.5 s and summation of [Ca2+]i occurred whenever depolarizations were applied with an interval of less than 2 s. The importance of the Na(+)-Ca2+ exchange for B-cell [Ca2+]i maintenance was evidenced by the demonstration that basal [Ca2+]i rose to 200 nM and the magnitude of the depolarization-evoked [Ca2+]i transients was markedly increased after omission of extracellular Na+. However, the rate by which [Ca2+]i returned to basal was not affected, suggesting the existence of additional [Ca2+]i buffering processes.     

The Ca2+-dependent actions of the alpha-adrenergic agonist phenylephrine on hepatic glycogenolysis differ from those of vasopressin and angiotensin

The stimulation of hepatic glycogenolysis by the Ca2+-dependent hormones phenylephrine, vasopressin and angiotensin II was studied as a function of intracellular and extracellular Ca2+. In the isolated perfused rat liver the decline in glucose formation was monophasic ('half-life' approximately equal to 3 min) with vasopressin (1 nM) or angiotensin II (0.05 microM), but biphasic (half-life of 4.8 min and 17.6 min) in the presence of the alpha-agonist phenylephrine (0.01 mM), indicating either a different mode of mobilization or the mobilization of additional intracellular calcium stores. Under comparable conditions an elevated [Ca2+] level was maintained in the cytosol of hepatocytes for at least 10 min in the presence of phenylephrine, but not vasopressin. Titration experiments performed in the isolated perfused liver to restore cellular calcium revealed differences in the hormone-mediated uptake of Ca2+. The onset in glucose formation above that seen in the absence of exogenous calcium occurred at approximately 30 microM or 70-80 microM Ca2+ in the presence of phenylephrine or vasopressin respectively. The shape of the response curve was sigmoidal for vasopressin and angiotensin II, but showed a distinct plateau between 0.09 mM and 0.18 mM in the presence of phenylephrine. The plateau was also observed at phenylephrine concentrations as low as 0.5 microM. The formation of plateaus observed after treatment of the liver with A 23187, but not after EGTA, is taken as an indication that intracellular calcium stores are replenished. A participation of the mitochondrial compartment could be excluded by pretreatment of the liver with the uncoupler 2,4-dinitrophenol. Differences in the Ca2+ dependence of the glycogenolytic effects of these hormones were also revealed by kinetic analysis. It is concluded that phenylephrine differs from vasopressin and angiotensin II in that, in addition to a more common, non-mitochondrial pool, which is also responsive to the vasoactive peptides, the agonist mobilizes Ca2+ from a second, non-mitochondrial pool. The results are consistent with the proposal that Ca2+ transport across subcellular membranes may be subject to different hormonal control.     

Difference in the mechanism of action of alpha-adrenergic agonists and vasopressin or angiotensin II in stimulating hepatic glycogenolysis; a role of extracellular calcium concentration

The role of extracellular calcium in hormone-induced glycogenolysis was examined in a rat liver perfusion system by manipulating the perfusate calcium concentration and by using calcium antagonistic drugs. When the perfusate contained 1 mM CaCl2, 5 microM phenylephrine, 20 nM vasopressin, and 10 nM angiotensin II caused a persistent increase in glucose output and phosphorylase activity as well as a transient increase in 45Ca efflux from 45Ca preloaded liver. Verapamil hydrochloride (20-100 microM) inhibited the activation of glucose output by these hormones in a dose-dependent manner. This inhibitory effect was also associated with the inhibition of hormone-induced activation of phosphorylase and 45Ca efflux. In the absence of CaCl2 in the perfusate, the glycogenolytic effect of phenylephrine and its inhibition by verapamil were obtained equally as in the presence of CaCl2. However, the effects of vasopressin and angiotensin II were markedly attenuated and were not inhibited any further by verapamil. The substitution of diltiazem hydrochloride for verapamil produced essentially identical results. Cyclic AMP concentrations in the tissue did not change under any of these test conditions. The results indicate that the glycogenolytic effect of alpha-adrenergic agonists depends on intracellular calcium but those of vasopressin and angiotensin II on extracellular calcium, and support the concept that calcium antagonistic drugs inhibit the glycogenolytic effects of calcium-dependent hormones at least by inhibiting the mobilization of calcium ion from cellular pools.     

Calcium ion fluxes induced by the action of alpha-adrenergic agonists in perfused rat liver.

Phenylephrine (2.0 microM) induces an alpha 1-receptor-mediated net efflux of Ca2+ from livers of fed rats perfused with medium containing physiological concentrations (1.3 mM) of Ca2+. The onset of efflux (7.1 +/- 0.5 s; n = 16) immediately precedes a stimulation of mitochondrial respiration and glycogenolysis. Maximal rates of efflux are observed between 35 s and 45 s after alpha-agonist administration; thereafter the rate decreases, to be no longer detectable after 3 min. Within seconds of terminating phenylephrine infusion, a net transient uptake of Ca2+ by the liver is observed. Similar effects were observed with vasopressin (1 m-unit/ml) and angiotensin (6 nM). Reducing the perfusate [Ca2+] from 1.3 mM to 10 microM had little effect on alpha-agonist-induced Ca2+ efflux, but abolished the subsequent Ca2+ re-uptake, and hence led to a net loss of 80-120 nmol of Ca2+/g of liver from the tissue. The administration at 5 min intervals of short pulses (90 s) of phenylephrine under these conditions resulted in diminishing amounts of Ca2+ efflux being detected, and these could be correlated with decreased rates of alpha-agonist-induced mitochondrial respiration and glucose output. An examination of the Ca2+ pool mobilized by alpha-adrenergic agonists revealed that a loss of Ca2+ from mitochondria and from a fraction enriched in microsomes accounts for all the Ca2+ efflux detected. It is proposed that the alpha-adrenergic agonists, vasopressin and angiotensin mobilize Ca2+ from the same readily depleted intracellular pool consisting predominantly of mitochondria and the endoplasmic reticulum, and that the hormone-induced enhanced rate of mitochondrial respiration and glycogenolysis is directly dependent on this mobilization.     

Different patterns of agonist-stimulated increases of 3H-inositol phosphate isomers and cytosolic Ca2+ in bovine adrenal chromaffin cells: comparison of the effects of histamine and angiotensin II

Bovine adrenal chromaffin cells (BCC) were used to compare histamine- and angiotensin II-induced changes of inositol mono-, bis-, and trisphosphate (InsP1, InsP2, and InsP3, respectively) isomers, intracellular free Ca2+ ([Ca2+]i), and the pathways of inositol phosphate metabolism. Both agonists elevated [Ca2+]i by 200 nM 3-4 s after addition, but afterwards the histamine response was much more prolonged. Histamine and angiotensin II also produced similar four- to fivefold increases of Ins(1,4,5)P3 that peaked within 5 s. Over the first minute of stimulation, however, Ins(1,4,5)P3 formation was monophasic after angiotensin II, but biphasic after histamine, evidence supporting differential regulation of angiotensin II- and histamine-stimulated signal transduction. The metabolism of Ins(1,4,5)P3 by BCC homogenates was found to proceed via (a) sequential dephosphorylation to Ins(1,4)P2 and Ins(4)P, and (b) phosphorylation to inositol 1,3,4,5-tetrakisphosphate, followed by dephosphorylation to Ins(1,3,4)P3, Ins(1,3)P2, and Ins(3,4)P2, and finally to Ins(1 or 3)P. In whole cells, Ins(1 or 3)P only increased after histamine treatment. Additionally, Ins(1,3)P2 was the only other InsP2 besides Ins(1,4)P2 to accumulate within 1 min of agonist treatment [Ins(3,4)P2 did not increase]. These results support a correlation between the time course of Ins(1,4,5)P3 formation and the time course of [Ca2+]i transients and illustrate that Ca2(+)-mobilizing agonists can produce distinguishable patterns of inositol phosphate formation and [Ca2+]i changes in BCC. Different patterns of second-messenger formation are likely to be important in signal recognition and may encode agonist-specific information.     

Alpha 1-adrenergic stimulation and cytoplasmic free calcium concentration in cultured renal proximal tubular cells: evidence for compartmentalization of quin-2 and fura-2

This study was designed to examine the role of changes in cytoplasmic free calcium concentration ([Ca2+]i) during the response to alpha 1-adrenergic agonists in cultured renal proximal tubular cells. Experiments were carried out on primary cultures of canine proximal tubular cells grown in defined culture medium on a solid support, on collagen-coated polycarbonate membranes, or on collagen-coated glass coverslips. Quin-2 and fura-2 were used to monitor [Ca2+]i. The basal level of [Ca2+]i was 101 nM, as measured with quin-2, and 122 nM, as determined using fura-2. Fluorescence flow cytometry revealed that about 85% of the population of proximal tubular cells responded to phenylephrine with an increase in [Ca2+]i. Phenylephrine (10(-5) M) caused an immediate actual increase in [Ca2+]i by 18 and 24%, as determined with quin-2 and fura-2, respectively, with the peak increase in [Ca2+]i averaging 22% and 44% over the basal level (180-300 sec). This effect did not require extracellular calcium. The effect of phenylephrine was abolished by prazosin and verapamil. Fluorescence microscopy of quin-2 or fura-2 loaded cells revealed punctate areas of fluorescence within the cytoplasm suggesting vesicular uptake of the dyes. Pinocytotic entrapment of the dyes was demonstrated by the transfer of cell-impermeant fura-2 across tubular cell monolayers mounted in Ussing chambers. The transfer of the dye was similar to that of a marker of fluid-phase pinocytosis, Lucifer Yellow (LY). This pinocytotic entrapment of Ca2+-indicators would lead to underestimation of the actual calcium transients. Microfluorometric study of single proximal tubular cells "scrape-loaded" with fura-2 revealed a four-fold increase in [Ca2+]i concentration following stimulation with phenylephrine.     

Phorbol-ester-induced alterations of free calcium ion transients in single rat hepatocytes.

The effect of the phorbol esters phorbol 12-myristate 13-acetate (TPA) and phorbol 12,13-dibutyrate (PDB) on changes in free Ca2+ concentration ([Ca2+]i) in single rat hepatocytes, microinjected with the photoprotein aequorin, were investigated. [Arg8]vasopressin and phenylephrine induced a series of repetitive [Ca2+]i transients. Phorbol esters inhibited the alpha 1-adrenoceptor-induced response; sub-nanomolar concentrations decreased the transient frequency, and higher concentrations abolished the transients. The inhibitory effect of PDB was readily reversible. Phorbol esters were less effective in decreasing the frequency of [Arg8]-vasopressin-induced transients, and the inhibition could be overcome by high [Arg8]vasopressin concentrations.     

Regulation of calcium efflux from isolated rat parotid cells

Calcium efflux from isolated rat parotid acinar cells was studied with 45Ca. Carbachol, phenylephrine, substance P, monobutyryl cyclic AMP and isoproterenol stimulated 45Ca efflux. It is suggested that carbachol, phenylephrine and substance P mobilize the same pool of cellular Ca. This suggestion is based on two observations. Firstly, combinations of any two of these three agonists at saturating concentrations result in no more 45Ca efflux than either agonist alone. Secondly, stimulation of 45Ca efflux by any one of the three agonists prevents further stimulation of 45Ca efflux by the same or one of the other two agonists. The pool of calcium mobilized by isoproterenol or monobutyryl cyclic AMP is different from the pool mobilized by carbachol. This conclusion is based on the observation that stimulation of 45Ca efflux by a saturating concentration of carbachol did not inhibit stimulation of 45Ca efflux by isoproterenol. Furthermore the effect of a saturating concentration of isoproterenol on 45Ca efflux is additive with that caused by a saturating concentration of carbachol. The effect of carbachol, phenylephrine and substance P on 45Ca2+ efflux did not require extracellular Ca2+.     

The relationship between the free concentrations of Ca2+ and Ca2+-calmodulin in intact cells

Using stably expressed fluorescent indicator proteins, we have determined for the first time the relationship between the free Ca2+ and Ca2+-calmodulin concentrations in intact cells. A similar relationship is obtained when the free Ca2+ concentration is externally buffered or when it is transiently increased in response to a Ca2+-mobilizing agonist. Below a free Ca2+ concentration of 0.2 microM, no Ca2+-calmodulin is detectable. A global maximum free Ca2+-calmodulin concentration of approximately 45 nM is produced when the free Ca2+ concentration exceeds 3 microM, and a half-maximal concentration is produced at a free Ca2+ concentration of 1 microM. Data for fractional saturation of the indicators suggest that the total concentration of calmodulin-binding proteins is approximately 2-fold higher than the total calmodulin concentration. We conclude that high-affinity calmodulin targets (Kd /= 100 nM) occurs only where free Ca2+-calmodulin concentrations can be locally enhanced.     

Comparison of the changes in cytoplasmic free calcium concentration induced by phenylephrine, vasopressin and angiotensin II in hepatocytes

Effects of phenylephrine, vasopressin and angiotensin II on cytoplasmic free calcium concentration, [Ca2+]c, were examined by monitoring aequorin bioluminescence in isolated hepatocytes preloaded with aequorin. In the presence of 0.5 mM calcium in the medium, the pattern of changes in aequorin bioluminescence induced by phenylephrine was different from that induced by vasopressin or angiotensin II. When extracellular calcium concentration was reduced to 1 microM, however, these three agents induced identical changes in aequorin bioluminescence. These results suggest that the mode of action of phenylephrine on cytoplasmic free calcium concentration differs from that of either vasopressin or angiotensin II and that the difference in ability to increase calcium influx may account for the distinct patterns induced by these agents.     

Role of extracellular calcium and calcium efflux in the activation of hepatic glycogenolysis by calcium-dependent hormones

The role of extracellular calcium in the glycogenolytic effects of calcium-dependent hormones was examined in a rat liver perfusion system. Decreasing the perfusate CaCl2 concentration resulted in a concentration-dependent inhibition of glucose output by maximal concentrations of vasopressin (20 nM) and angiotensin II (10 nM), but not of glucagon (1.4 nM), cyclic AMP (100 microM), dibutyryl cyclic AMP (10 microM) or phenylephrine (5 microM). However, the effect of phenylephrine was inhibited when livers were perfused with CaCl2-free perfusate containing 0.5 mM EGTA in a duration-dependent manner. These effects were exerted through the inhibition of the maximal response of each hormone, and were associated with a parallel decrease in phosphorylase activation but not with changes in tissue cyclic AMP concentrations. When livers were preloaded with 45Ca for 45 min and then washed for either 15 min or 45 min, these hormones elicited a rapid and transient 45Ca efflux regardless of the perfusate calcium concentration. The sequential perfusion of two hormones resulted in the loss of 45Ca efflux by the second hormone. These results suggest that the glycogenolytic effects of vasopressin and angiotensin II depend on the extracellular calcium and that of phenylephrine primarily on the cellular calcium. It was also demonstrated that these calcium-dependent hormones mobilize calcium from the same pools. However, the mobilization of cellular calcium does not necessarily correlate directly with the glycogenolytic actions of vasopressin and angiotensin II.     

Hormonal regulation of the tricarboxylic acid cycle in the isolated perfused rat liver

The effect of Ca2+-mobilizing hormones, vasopressin, angiotensin II and the alpha-adrenergic agonist phenylephrine, on the metabolic flux through the tricarboxylic acid cycle was investigated in isolated perfused rat livers. All three Ca2+-mobilizing agonists stimulated 14CO2 production and gluconeogenesis in livers of 24-h-fasted rats perfused with [2-14C]pyruvate. Prazosin blocked the phenylephrine-elicited stimulation of 14CO2 and glucose production from [2-14C]pyruvate whereas the alpha 2-adrenergic agonist, BHT-933, did not affect the rates of 14CO2 and glucose production from [2-14C]pyruvate indicating that the phenylephrine-mediated response involved alpha 1-adrenergic receptors. Phenylephrine, vasopressin and angiotensin II stimulated 14CO2 production from [2-14C]acetate in livers derived from fed rats but not in livers of 24-h-fasted rats. In livers of 24-h-fasted rats, perfused with [2-14C]acetate, exogenously added pyruvate was required for an increase in the rate of 14CO2 production during phenylephrine infusion. This last observation suggests increased pyruvate carboxylation as one of the mechanisms involved in stimulation of tricarboxylic acid cycle activity by the Ca2+-mobilizing agonists, vasopressin, angiotensin II and phenylephrine.     

Mobilization of intracellular calcium by alpha 1-adrenergic receptor activation in muscle cell monolayers

The fluorescent chelating agent quin 2 has been employed to monitor alterations of intracellular free Ca2+ concentrations ([Ca2+]i) in response to alpha 1-adrenergic receptor activation in adherent BC3H-1 cells. To correlate the kinetics of [Ca2+]i changes with transmembrane fluxes of this ion, continuous monitoring of [Ca2+]i has been undertaken on a monolayer of cells. Previous measurements of the transmembrane efflux of Ca2+ show a distinct lag in the response over a range of phenylephrine concentrations. By contrast, the elevation of [Ca2+]i is rapid (t1/2 approximately 2 s) and maintained for 30 s before it begins to decline to basal concentrations. The differences in kinetics indicate that the temporal delay in cellular Ca2+ efflux results from either activation of the transport system for Ca2+ extrusion or translocation of free Ca2+ to the transport site. The decline of [Ca2+]i with continued agonist exposure parallels both the efflux kinetics from the cell and the decline of total cellular Ca2+. At a time when free [Ca2+]i approaches the resting concentration, total cellular Ca2+ is reduced to a steady state value of 60% of that seen prior to stimulation. The Kact for phenylephrine-stimulated elevation in [Ca2+]i on the monolayer is 0.51 microM, which is similar to the Kact of 0.90 microM observed for phenylephrine-activated 45Ca2+ efflux. Addition of phentolamine subsequent to phenylephrine addition immediately reverses the agonist-stimulated Ca2+ mobilization, initiating a rapid return of [Ca2+]i to resting levels. A comparison of the kinetics of Ca2+ mobilization with its transmembrane flux suggests that the agonist augments the rate of recycling of intracellular Ca2+ between the free and bound states rather than causing release as a single bolus from the bound stores.