The mechanism of alpha-adrenergic agonist action in liver

Ca2(+)-fatty acid interaction in the control of hepatic gluconeogenesis

Calcium depletion induced by perfusing livers with calcium-free buffer did not alter the rates of basal glucose production from pyruvate or from increasing concentrations of lactate. However, calcium deficiency selectively prevented the fatty acid-induced stimulation of gluconeogenesis from lactate. This effect is not related to the higher NAD redox potential consistently observed in Ca2(+)-deficient livers. On the other hand, octanoate was capable of inducing dose-dependent changes in the [pyruvate]0.5 in calcium-depleted livers perfused with lactate, ruling out that low cellular calcium content could perturb the mitochondrial transport of pyruvate. The observation that the effect of calcium deficiency can be overcome by supraphysiological concentrations of pyruvate supports the proposal that stimulation of the maximal capacity of the gluconeogenic pathway by fatty acid relies largely on the tricarboxylic acid cycle activity, restricted in calcium deficiency conditions.

Role of alpha-adrenergic stimuli in the control of rat renal ammoniagenesis

The effects of phenylephrine on renal ammoniagenesis and the involvement of Ca2+ in phenylephrine action were investigated in isolated proximal fragments of rat-kidney tubules. Phenylephrine stimulated renal ammoniagenesis from 1 and 2 mM glutamine whereas no significant changes took place at a higher concentration of glutamine (20 mM). Stimulation of ammonia synthesis by phenylephrine was found to be linear with time and dose-dependent between 10(-9) and 10(-4) M. Phenylephrine-stimulated ammoniagenesis was blocked by phentolamine (10 microM) but not by propranolol (10 microM) confirming that the effect is mediated by alpha-adrenergic stimuli. No stimulatory effect of phenylephrine was observed in Ca2+ depleted proximal tubule fragments, suggesting that Ca2+ is required in this adrenergic response.

Ca2+ mobilization by vasopressin and glucagon in perfused livers. Effect of prior intoxication with bromotrichloromethane

Perfused livers isolated from rats treated with BrCCl3 for up to 15 min were used as an experimental tool to investigate the role of the hepatic endoplasmic reticulum in Ca2+ mobilization elicited by vasopressin and glucagon. BrCCl3-treatment caused extensive impairment (37 to 92%) of Ca2+ pumps of isolated liver microsomes, while Ca2+ pumps of mitochondria and plasma membrane vesicles remained undamaged. In perfused livers of BrCCl3-treated rats, the efflux of Ca2+ and the concomitant stimulation of O2 consumption and glucose release induced by vasopressin were decreased. The extent of the decrease paralleled the duration of BrCCl3-treatment. The decrease of Ca2+ efflux following vasopressin addition was closely correlated with the decrease of active Ca2+ accumulation by isolated microsomes (r = 0.99, P less than 0.001). The Ca2+ efflux elicited by glucagon was also decreased after BrCCl3-treatment, whereas stimulation of O2 consumption and glucose release were retained. The possibility that BrCCl3-treatment might impair the production of the intracellular Ca2+-mobilizing messenger IP3 is unlikely, since vasopressin still induced the formation of inositol phosphates, including IP3, in isolated hepatocytes obtained from BrCCl3-treated rats. Thus, this work supports the hypothesis that the Ca2+ stored in the liver ER is the major pool of intracellular Ca2+ available for mobilization by vasopressin, glucagon and other effectors.

Control of gluconeogenesis: role of fatty acids in the alpha-adrenergic response

Phenylephrine increases hepatic gluconeogenesis for as long as it is present in the extracellular medium. This effect is accompanied by a parallel increase in oxygen consumption. No apparent stoichiometric relationship exists between the phenylephrine-stimulated respiration and the energy required to meet the demands of gluconeogenesis. In the absence of extracellular calcium, no sustained stimulation of respiration was observed and phenylephrine failed to enhance gluconeogenesis; however, acute and transient effects of the alpha-adrenergic agonist were still observable. The following observations indicate that fatty acids are not involved in the alpha-adrenergic response: (1) the effects of phenylephrine and octanoate on respiration and gluconeogenesis were found to be additive; (2) unlike phenylephrine, octanoate is capable of stimulating gluconeogenesis in calcium-depleted liver; (3) in the absence of calcium, phenylephrine was incapable of further stimulating respiration or gluconeogenesis in the presence of octanoate. It is concluded that the conditions of increased lipid mobilization and/or oxidation are not sufficient to explain the metabolic response to alpha-adrenergic agonists. Fatty acids and alpha-adrenergic stimulation share a common role of stimulating gluconeogenesis in a manner dependent on their ability to stimulate respiration; however, the additive nature of their effects and distinct calcium requirements indicate that they act to trigger different mechanisms.

Characterization of the alpha-adrenergic stimulation of hepatic respiration

The alpha-adrenergic agonist phenylephrine induces a biphasic stimulation of respiration in perfused isolated rat liver. The first phase, of rapid onset and short duration, is paralleled by increased glycogenolysis, glycolysis, and NAD redox potential. The second phase lasts for as long as the alpha-agonist is present and is accompanied by increased gluconeogenic flux. Only the second phase of sustained increased respiration is clearly dependent on extracellular Ca2+. In contrast, normal respiratory responses were obtained under Ca2+-loading conditions or in the presence of the Ca2+ ionophore A23187, indicating that the alpha-adrenergic action on respiration is not simply mediated by its ability to increase the cytosolic Ca2+ concentration. No stimulation of gluconeogenesis is observed in the absence of a sustained increase of respiration. However, it is not energy support that leads to the stimulation of glucose production. The adrenergic response is influenced by the nutritional status of the animal and the availability of oxidizable fuels. In livers from starved animals, the alpha-adrenergic respiratory response is abolished when long chain fatty acid oxidation is prevented by the addition of tetradecylglycidate. In the presence of pyruvate the respiratory response is partially restored. It is concluded that increased beta-oxidation is not mandatory for the alpha-adrenergic stimulation of respiration; however, maximal respiratory responses are obtained only when fatty acid oxidation is allowed to proceed. The latter finding appears to be the result of a limited flux through the tricarboxylic acid cycle when long chain fatty acid oxidation is impeded, secondary to a limiting acetyl CoA supply.

Exposure to depolarizing concentrations of K+ inhibits hormonally-induced calcium influx in rat liver

The exposure of perfused rat livers to depolarizing concentrations of K+ (60 mM) by partial substitution of the NaCl in the medium with KCl induces glycogenolysis, respiratory changes and vasoconstriction. These responses were found to be inhibited 70-80% by 20 microM indomethacin and by 20 microM bromophenacyl bromide. This suggests that eicosanoids, namely prostaglandins, are involved in mediating these effects, and hence that the action of K+ involves primarily an effect on eicosanoid-producing cells (Kupffer and endothelial cells) within the liver. A 5 min pre-exposure of perfused livers to depolarizing concentrations of K+ (in the presence of indomethacin) was found to inhibit (by approx. 85%) the influx of Ca2+ induced by the co-administration of 10 nM glucagon and 10 nM vasopressin. A similar result was observed in isolated hepatocytes. The inhibition was probably not due to a decrease in the concentration of Na+ in the medium since the substitution of 80 mM NaCl with 80 mM choline chloride resulted in significantly less inhibition (30-40%). These results suggest that under these conditions the influx of Ca2+ in liver occurs through a pathway that is inhibited by high K+ concentration and/or a depolarization of the plasma membrane.

The effects of adrenergic agonists and age on lipogenesis in avian hepatocytes

1. Adrenergic inhibition of lipogenesis was examined in vitro using hepatocytes isolated from chickens 2-9 weeks old. 2. Lipogenesis was inhibited by beta 1, beta 2 and alpha 1 agonists. Greatest inhibition occurred when more than one type of receptor was stimulated. 3. Clonidine (alpha 2-agonist) may have stimulated lipogenesis. 4. Responsiveness to the agonists decreased as the chickens got older.

Possible involvement of eicosanoids in the zymosan and arachidonic-acid-induced oxygen uptake, glycogenolysis and Ca2+ mobilization in the perfused rat liver

Exposure of perfused rat livers to zymosan, arachidonic acid and phenylephrine, but not to latex particles, induces pronounced oxygen uptake, glycogenolysis and Ca2+ mobilization. The oxygen uptake induced by arachidonic acid and by zymosan remains elevated even after the agents have been removed. NaN3 was found to be much more effective in inhibiting the oxygen uptake induced by phenylephrine than that induced by zymosan or arachidonic acid. Glucose release induced by zymosan and by arachidonic acid reaches a maximum after about 2 min and then declines very rapidly even while the agents are still being infused. In contrast, glucose release induced by phenylephrine remains elevated for the duration of the infusion. Ca2+ fluxes induced by arachidonic acid are similar to those induced by phenylephrine in that efflux occurs when the agent is administered and influx occurs only when the agent is removed. This contrasts to the Ca2+ flux changes induced by zymosan where both Ca2+ efflux and Ca2+ influx occur even while zymosan is still being infused. Glucose release induced by zymosan is inhibited by bromophenacylbromide and nordihydroguaiaretic acid, but not by indomethacin. Indomethacin, however inhibits the arachidonic-acid-induced glucose release which is also inhibited by nordihydroguaiaretic acid but not by bromophenacylbromide. Indomethacin inhibits also the arachidonic-acid-induced Ca2+ flux changes whereas the zymosan- and the phenylephrine-induced Ca2+ flux changes are not inhibited by the cyclooxygenase inhibitor. The data presented in this paper suggest that in the perfused rat liver the zymosan-induced glycogenolysis, as well as the Ca2+ flux changes and glycogenolysis induced by arachidonic acid, are mediated by eicosanoids.

A water-soluble derivative of prazosin prazosinamine hydrochloride [1-(4'-amino-6',7'-dimethoxyquinazolin-2'-yl)-4-(6''-aminohexanoyl) piperazine hydrochloride], reversibly inhibits the calcium-mobilizing action of alpha 1-adrenergic agonists in the perfused rat liver

A newly-synthesized derivative of prazosin, prazosinamine hydrochloride, was examined for its ability to antagonize the interaction of the alpha 1-adrenergic agonist phenylephrine with liver cells. Using a Ca2--selective electrode to measure changes in perfusate Ca2+ concentration, prazosinamine was found to be as effective as prazosin in inhibiting the phenylephrine-induced efflux of Ca2+ from the perfused liver. Maximal and half-maximal inhibition occurred at 150 nM and 25 nM prazosinamine, respectively. Prazosinamine appears to share the alpha 1-specificity of prazosin, but has other unique and desirable properties. Its solubility in aqueous media is about three orders of magnitude higher than that of prazosin. Also, its antagonistic effects are rapid in onset, and are reversed within seconds of terminating its infusion into the liver. These attributes seem to make this agent more useful than prazosin for adrenergic receptor studies in perfused tissues. The molecule can also be readily coupled to other ligands.

Sexual dimorphism in adrenergic regulation of hepatic glycogenolysis

The total phosphorylase a plus b of hepatocytes isolated from females and incubated in the absence or presence of estradiol and progesterone at concentrations found in vivo does not vary during the estrous cycle. However, there is a slight but significant influence of the estrous cycle on basal and epinephrine-stimulated phosphorylase a activity, with a nadir being seen on diestrus. The relative contributions of the alpha- and beta-mediated pathways to phosphorylase a activation do not vary with the estrous cycle but are constant at 75 and 56%, respectively, of the response to 5 X 10(-8) M epinephrine. When the epinephrine-stimulated glucose release from glycogen stores in cells from females and males is compared, the release from the female is greater than that from the male, while the alpha-receptor-mediated stimulation in the female is comparable with that in the male. The beta-mediated pathway causes glucose release which averages 45% of that stimulated by epinephrine alone in cells from females. Basal cytosolic free calcium is similar in cells from males and females (142 vs. 149 nM, respectively). The epinephrine-stimulated increase in cytostolic free calcium (Cai) is greater in the male than the female at 10(-6) M (489 vs. 380 nM) but greater in the female than the male at 5 X 10(-9) M (54 vs. 27 nM). The changes in Cai are equivalent at intermediate epinephrine concentrations. When considered with our prior analysis of 45Ca efflux after adrenergic stimulation, this suggests there may be a sexual dimorphism in hepatocyte calcium transport systems. The glucose release for a given increase in Cai is greater in the female than the male probably due to the concomitant action of the beta-mediated increase in cAMP and the alpha-mediated increase in Cai. This supports the conclusion that the beta-mediated component does make a significant contribution to the catecholamine regulation of glycogenolysis in hepatocytes from adult female rats.

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.

Calcium, cyclic AMP and protein kinase C--partners in mitogenesis

Evidence is steadily mounting that the proto-oncogenes, whose products organize and start the programs that drive normal eukaryotic cells through their chromosome replication/mitosis cycles, are transiently stimulated by sequential signals from a multi-purpose, receptor-operated mechanism (consisting of internal surges of Ca2+ and bursts of protein kinase C activity resulting from phosphatidylinositol 4,5-bisphosphate breakdown and the opening of membrane Ca2+ channels induced by receptor-associated tyrosine-protein kinase activity) and bursts of cyclic AMP-dependent kinase activity. The bypassing or subversion of the receptor-operated Ca2+/phospholipid breakdown/protein kinase C signalling mechanism is probably the basis of the freeing of cell proliferation from external controls that characterizes all neoplastic transformations.

Calcium transport from blood into the bile in normal and regenerating rat liver

We have studied calcium movement from blood into the bile by injecting 45Ca2+ intravenously and measuring the radioactivity appearing in the bile. 45Ca2+ started to appear in the bile at 3 min and maximum values were observed at 5 min after its administration. The amount of calcium secreted into the bile was proportional to the blood calcium concentration indicating that the main pathway involved in calcium movement behaved as a non-saturable system. We have also studied the 45Ca2+ circulation from blood into the bile in rats subjected to a partial hepatectomy. Thereafter, the calcium transported into the bile per gram of liver increased by about 50 per cent. Since bile flow behaved in a similar way, the biliar calcium concentration remained unmodified after hepatectomy. Determination of the activities of the Ca2+ transporting systems in isolated plasma membrane fractions from regenerating livers showed no modification in these activities suggesting that the elevation in calcium movement observed after hepatectomy is not due to an increase in the circulation of Ca2+ through the transhepatocyte pathway, an observation compatible with the absence of saturation in the transport.

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.

The Ca2+-mobilizing actions of vasopressin and angiotensin differ from those of the alpha-adrenergic agonist phenylephrine in the perfused rat liver

A Ca2+-sensitive electrode was used to study net Ca2+-flux changes induced by the administration of phenylephrine, vasopressin and angiotensin to the perfused rat liver. The studies reveal that, although the Ca2+ responses induced by vasopressin and angiotensin are similar, they are quite different from the Ca2+ fluxes induced by phenylephrine. The administration of phenylephrine is accompanied by a stimulation of a net amount of Ca2+ efflux (140 nmol/g of liver). A re-uptake of a similar amount of Ca2+ occurs only after the hormone is removed. In contrast, the administration of vasopressin or angiotensin to livers perfused with 1.3 mM-Ca2+ induces the release of a relatively small amount of Ca2+ (approx. 40 nmol/g of liver) during the first 60 s. This is followed by a much larger amount of Ca2+ uptake (70-140 nmol/g of liver) after 1-2.5 min of hormone administration, and a slow efflux or loss of a similar amount of Ca2+ over a period of 6-8 min. At lower concentrations of perfusate Ca2+ (less than 600 microM) these hormones induce only a net efflux of the ion. These results suggest that at physiological concentrations of extracellular Ca2+ the mechanism by which alpha-adrenergic agonists mobilize cellular Ca2+ is different from that involving vasopressin and angiotensin. It seems that the hormones may have quite diverse effects on Ca2+ transport across the plasma membrane and perhaps organellar membranes in liver.