Liposome encapsulated tetracaine lowers blood glucose.

Tetracaine, a local anesthetic, was previously shown to block hormonal stimulation of gluconeogenesis and glycogenolysis ( Friedmann , N. and Rasmussen, H. (1970) Biochim. Biophys. Acta 222, 41-52). In the present studies tetracaine incorporated into liposomes (phospholipid vesicles) was injected into intact rats and epinephrine was administered an hour later. Liposomal tetracaine blocked 50% of the hyperglycemic response. When tetracaine, incorporated into liposomes, was injected into diabetic rats it reduced transiently, but significantly, blood glucose levels. Equivalent doses of free tetracaine were toxic. These studies indicate that liposomal drug administration might be developed into a tool to influence hepatic metabolism and, consequently, blood glucose levels.

A comparison between 45Ca2+ and atomic absorption in calcium flux determinations in perfused rat liver.

Calcium efflux from perfused rat liver following the administration of Ca2+ releasing agents was measured with two methods, 45Ca2+ labeling and atomic absorption. The values obtained with atomic absorption were usually higher than the values obtained with 45Ca2+. These indicate that the intracellular Ca2+ did not equilibrate with the perfusate ca2+ during the 90-minute labeling period. A similar conclusion was reached by measuring the liver 45Ca2+ and 40Ca2+ content. In addition, the types of albumin added to the perfusate influenced the amounts of Ca2+ released.

Calcium sequestration in the liver.

Hepatic parenchymal cells maintain intracellular total and cytosolic free Ca2+ levels by: entry of Ca2+ through channels, extrusion of Ca2+ by an outwardly directed Ca2+ pump, and controlled sequestration into intracellular pools. The mechanism of Ca2+ inflow is poorly characterized. The plasma membrane Ca2+ channels seem to share some of the characteristics of Ca2+ channels in excitable cells, but also differ from them. The outwardly directed plasma membrane Ca2(+)-ATPase is a calmodulin independent, P-type enzyme. Ca2+ uptake into the endoplasmic reticulum is due to the activity of a different Ca2(+)-ATPase, which is similar in molecular weight and shares antigenic determinants with the sarcoplasmic reticulum enzyme. In addition, mitochondria and nuclei also take up calcium. The exact mechanism by which Ca2+ is released from intracellular organelles is not well known. Several mechanisms for Ca2+ release from the endoplasmic reticulum were reported, including IP3 and GTP-induced. The most effective identified way of eliciting Ca2+ release from microsomal fraction is by the oxidation of critical -SH groups. This mechanism is likely to be involved in the rise of cytosolic Ca2+ observed in many situations of hepatocellular injury. In addition to being sequestered into subcellular organelles, some of the intracellular Ca2+ is bound to specific Ca2+ binding proteins. Both calmodulin and members of the annexin family were identified in the liver. Stimulation of the liver with gluconeogenic hormones results in increased Ca2+ entry into the cell, the release of Ca2+ from intracellular pools, and an oscillatory increase in free cytosolic Ca2+ levels. Extensive research is still needed for the elucidation of the exact mechanisms by which these events occur.

Cyclic nucleotide-gated channels in non-sensory organs.

Cyclic nucleotide-gated channels represent a class of ion channels activated directly by the binding of either cyclic-GMP or cyclic-AMP. They carry both mono and divalent cations, but select calcium over sodium. In the majority of the cases studied, binding of cyclic nucleotides to the channel results in the opening of the channel and the influx of calcium. As a consequence, cytosolic free calcium levels increase leading to the modifications of calcium-dependent processes. This represents and important link in the chain of events leading to the physiological response. Cyclic nucleotide-gated channels were discovered in sensory cell types, in the retina, and in olfactory cells, and were extensively studied in those cells. However, it is becoming increasingly evident that such channels are present not only in sensory systems, but in most, if not all, cell types where cyclic nucleotides play a role in signal transduction. A hypothesis is presented here which attributes physiological importance to these channels in non-sensory organs. Four examples of such channels in non-sensory cells are discussed in detail: those in the liver, in the heart, in the brain, and in the testis with the emphasis on the possible physiological roles that these channels might have in these organs.

The effects of Mg2+ on rat liver microsomal Ca2+ sequestration.

The effects of Mg2+ on the hepatic microsomal Ca2(+)-sequestering system was tested. Ca2(+)-ATPase activity and Ca2+ uptake were both dependent on the concentration of free Mg2+, reaching maximum levels at 2 mM. The effects of Mg-ATP were also influenced by the concentration of free Mg2+, being maximally effective at a ratio of 1:1. The results suggest that Mg2+ influences Ca2+ sequestration at various steps, namely in addition to forming the substrate of the Ca2(+)-ATPase reaction, Mg-ATP, Mg2+ stimulates the reaction at an additional step, as indicated by its stimulatory effect on the Ca2(+)-ATPase reaction and on Ca2+ uptake, even at optimal Mg-ATP levels. The stimulatory effect of Mg2+ was evident at various pH levels tested, and it was nucleotide specific. The stimulatory effect of Mg2+ might be exerted at the dephosphorylation step of the enzymatic reaction or at an other, yet undefined, site. The results demonstrate a plural effect of Mg2+ on the hepatic microsomal sequestration system. This indicates that, depending on its magnitude, changes in Mg2+ distribution might influence cytosolic Ca2+ levels.

45Ca2+ uptake and phospholipid methylation in isolated rat liver microsomes.

The effects of glucagon, epinephrine and insulin on hepatic phospholipid methylation were studied. Glucagon, either injected into rats or added to perfused livers, stimulated methylation in subsequently isolated microsomes. Epinephrine also increased phospholipid methylation. Insulin by itself did not influence the rate of the reaction, but, when administered prior to glucagon, it blocked the effect of the latter. The possibility that the observed stimulation of phospholipid methylation might be causally linked to the reported stimulation by glucagon of 45Ca2+ uptake in subsequently isolated liver microsomes was examined. Both the substrate and the competitive inhibitor of the methylation reaction, S-adenosylmethionine and S-adenosylhomocysteine, had profound effect on the rate of phospholipid methylation, without having comparable effects on Ca2+ uptake. S-adenosylmethionine in increasing concentration stimulated methylation four-fold, while no significant changes in 45Ca2+ uptake were seen. S-adenosylhomocysteine did not inhibit 45Ca2+ uptake even at levels causing more than 95% decrease in methylation. In conclusion, while both phospholipid methylation and 45Ca2+ uptake seem to be hormonally controlled, the correlation between these two processes was not sufficient to support the notion that the changes in 45Ca2+ uptake are caused by the changes in phospholipid methylation.

Different localization of inositol 1,4,5-trisphosphate and ryanodine binding sites in rat liver.

The distribution of inositol 1,4,5-trisphosphate and ryanodine binding sites between plasma membrane, microsomal, and mitochondrial fractions of rat liver were compared. IP3 bound mostly to the plasma membrane fraction (Kd = 6 nM; Bmax = 802 fmol/mg protein). Some IP3 binding sites were also present in the microsomal and mitochondrial fractions (Kd = 2.5 and 2.9 nM; Bmax = 35 and 23 fmol/mg protein respectively). The possibility that these binding sites are due to contamination of the fractions with plasma membrane cannot be excluded. Binding of IP3 to the plasma membrane was inhibited by heparin but not by either caffeine or tetracaine. High-affinity ryanodine binding sites were present mostly in the microsomal fraction (Kd = 13 nM; Bmax = 301 fmol/mg protein). Lower affinity binding sites were also found to be present in the mitochondrial and plasma membrane fractions. Binding of ryanodine to the microsomal fraction was inhibited by both caffeine and tetracaine but not by heparin. These data demonstrate that IP3 and ryanodine binding sites are present in different cellular compartments in the liver. These differences in the localization of the binding sites might be indicative of their functional differences.

Glucagon-stimulated respiration and intracellular Ca2+.

The effects of extra- and intracellular Ca2+ on glucagon-stimulated respiration were examined in perfused rat liver. Glucagon increased the uptake of O2 to a significantly greater extent in Ca2+-containing perfusate than in Ca2+-free perfusate. If, however, the livers were perfused first with Ca2+-containing perfusate for 60 min in order to load the hormone-sensitive Ca2+ pool(s) and subsequently with Ca2+-free perfusate, glucagon was able to stimulate O2 uptake to the same extent in Ca2+-free, as in Ca2+-containing perfusate. These experiments support previous observations of a connection between Ca2+ and the hormonal stimulation of respiration, but indicate a role for intracellular, rather than extracellular, Ca2+ in the process.

Expression of photoreceptor cyclic nucleotide-gated cation channel alpha subunit (CNGCalpha) in the liver and skeletal muscle.

Glucagon and beta-adrenergic agents increase cAMP levels and stimulate Ca2+ influx in liver cells. There is no consensus as to the mechanism by which these hormones stimulate the influx of Ca2+. Using mouse retinal rod CNGCalpha cDNA probes, we cloned rat liver and skeletal muscle, and human hepatic CNGCalpha subunit sequences showing 97-100% identity with the human rod channel. In order to assess channel activity, the effect of cyclic nucleotides on free intracellular Ca2+ levels of isolated hepatocytes was measured. Dibutyryl-cAMP was more effective in increasing free Ca2+ levels than dibutyryl-cGMP. These data indicate that the CNGCalpha subunit is expressed in both the liver and skeletal muscle possibly mediating hormonal effects on ion fluxes.

Reduction of ryanodine binding and cytosolic Ca2+ levels in liver by the immunosuppressant FK506.

The mechanism of action of the immunosuppressant FK506 in the liver was studied. The hypothesis was tested that FK506 exerts its effect in the liver by interacting with the ryanodine-binding Ca2+ release channel. Two types of experiments were carried out: (1) [3H]-ryanodine binding studies with isolated microsomal fractions, and (2) cytosolic-free Ca2+ ([Ca2+]i) measurements with the intracellular Ca(2+)-indicator fura-2. The inclusion of FK506 in the incubation medium significantly decreased the binding of [3H]-ryanodine to liver microsomes. The Bmax of binding in control experiments was 405 fmol/mg protein; the presence of FK506 decreased the Bmax to 157 fmol/mg protein. Measurements of [Ca2+]i in the presence and absence of FK506 showed a decrease in [Ca2+]i in the presence of FK506. The data support the notion that FK506 interacts with the ryanodine binding Ca2+ channel in the liver and suggest a critical role for the ryanodine-binding Ca2+ channel in the hepatic responses to FK506. The interaction between FKBP-12 (FK506 binding protein) and the ryanodine-binding Ca2+ channel may be an essential link in the chain of events by which FK506 alters Ca(2+)-dependent cellular processes.

Effects of ryanodine on calcium sequestration in the rat liver.

Ryanodine, a highly toxic alkaloid known to react specifically with the Ca2+ release channels in sarcoplasmic reticulum (SR), was employed to study Ca2+ sequestration in the liver. Ryanodine at a 200 microM concentration increased cytosolic free Ca2+ levels and phosphorylase a activity in isolated hepatocytes. These effects may involve microsomal Ca2+ sequestration, because ryanodine, in the presence of inhibitors of mitochondrial Ca2+ uptake, at concentrations of 1 nM, 1 microM, 50 microM and 100 microM decreased 45Ca2+ retention in permeabilized hepatocytes. This inhibition of Ca2+ retention by ryanodine was not due to inhibition of the microsomal Ca(2+)-ATPase. Dantrolene, a compound shown previously to inhibit ryanodine binding in the liver, also decreased 45Ca2+ retention in permeabilized hepatocytes, and activated phosphorylase a. These results show that ryanodine administration alters calcium sequestration in liver. The possibility of the existence of a ryanodine-sensitive Ca(2+)-release channel in liver is discussed.

Demonstration of ryanodine-induced metabolic effects in rat liver.

The effects of ryanodine, a plant alkaloid which alters Ca2+ sequestration in the liver, on O2 uptake and gluconeogenesis were measured. Ryanodine administration to perfused rat liver resulted in the stimulation of O2 uptake and of gluconeogenesis. Because ryanodine does not affect directly mitochondrial respiration, its stimulatory effect on O2 uptake in the whole cell is likely to be secondary to the increased cytosolic free Ca2+ levels.

Mechanism of action of GTP in the induction of Ca2+ release from hepatic microsomes.

The mechanism by which GTP induces Ca2+ release from Ca2(+)-preloaded rat hepatic microsomes was studied. In the same concentration range as that for Ca2+ release, GTP inhibited the initial rate of ATP-driven Ca2+ uptake. It also inhibited the formation by ATP of the phosphorylated intermediate of Ca2(+)-ATPase, which had previously been identified by us as a 97-116 kDa protein (Fleschner, C.R., et al. (1985) Biochem. J. 226, 839). Vanadate, an inhibitor of Ca2(+)-ATPase, also caused Ca2+ release in a similar fashion, but its effect was not additive to that of GTP. Although the non-metabolizable GTP analogues, GMPPNP and GTP gamma S, did not cause Ca2+ release by themselves, GTP gamma S completely and GMPPNP partially blocked the effect of GTP. Pretreatment of vesicles with either cholera or pertussis toxin did not alter the responsiveness to GTP. These results indicate that GTP inhibits microsomal Ca2(+)-ATPase, independently of the Gs and Gi proteins. Because a decrease in Ca2+ uptake results in a net increase in Ca+ release, this effect of GTP seems to account, at least partially, for the GTP-induced Ca2+ release from microsomes.

The role of intracellular Ca2+ in the regulation of gluconeogenesis.

A hypothesis for the hormonal regulation of gluconeogenesis, in which increases in cytosolic free-Ca2+ levels ([Ca2+]i) play a major role, is presented. This hypothesis is based on the observation that gluconeogenic hormones evoke a common pattern of Ca2+ redistribution, resulting in increases in [Ca2+]i. Current concepts of hormonally evoked Ca2+ fluxes are presented and discussed. It is suggested that the increase in [Ca2+]i is functionally linked to stimulation of gluconeogenesis. The stimulation of gluconeogenesis is accomplished in two ways: (1) by increasing the activities of the Krebs cycle and the electron-transfer chain, thereby supplying adenosine triphosphates (ATP) and reducing equivalents to the process; and (2) by stimulating the activities of key gluconeogenic enzymes, such as pyruvate carboxylase. The hypothesis presents a conceptual framework that ties together two interrelated manifestations of hormone action: signal transduction and metabolism.

Disruption of filamentous actin diminishes hormonally evoked Ca2+ responses in rat liver.

Previous studies have suggested a role for the actin cytoskeleton in hormonally evoked Ca2+ signaling in the liver. Here, we present evidence supporting a connection between filamentous actin (F-actin) organization and the ability of vasopressin and glucagon to increase cytosolic free-Ca2+ ([Ca2+]i) levels. F-actin was disrupted in hepatic cells by perfusion of rat liver with cytochalasin D. Epifluorescence microscopy of subsequently isolated cells showed reduced cortical fluorescent phalloidin staining in cytochalasin D-treated liver cells. Cytochalasin D pretreatment of liver cells reduced the vasopressin-stimulated elevation of [Ca2+]i by 60% and of glucagon by 50%. Experiments performed on cytochalasin D-treated cells using Mn2+ as an indicator of Ca2+ influx quenched fura-2 fluorescence signals following vasopressin administration. This indicates that a structurally intact cortical F-actin web is not a prerequisite for the influx of calcium. Therefore, the attenuation of the increase in cytosolic calcium observed in cytochalasin D-treated liver cells was likely caused either by the depletion of the calcium store by treatment with cytochalasin D or by the need for an intact cytoskeletal structure for its release. Because the resting level of calcium did not change in cells exposed to cytochalasin D, the latter is likely. The reduced [Ca2+]i response may be the mechanism by which cytochalasin D pretreatment inhibits vasopressin-induced metabolic effects. Cytochalasin D pretreatment also decreased the ability of glucagon to stimulate gluconeogenesis and reduced the stimulation of O2 uptake usually observed following glucagon administration. In conclusion, these results suggest that the hormonal elevation of [Ca2+]i and resultant activation of specific metabolic pathways require normal F-actin organization.

Hormonal regulation of cytosolic calcium levels in the liver.

Regulation of free cytosolic Ca2+ level in the liver is important because of the many Ca2(+)-dependent processes in the liver, such as respiration, gluconeogenesis, glycogenolysis, cell division, etc. Free cytosolic Ca2+ levels are maintained in the unstimulated state below 1 microM. This level is maintained by an outwardly directed Ca2(+)-ATPase in the plasma membrane, sequestration into the endoplasmic reticulum by a Ca2(+)-ATPase, binding of Ca2+ to specific Ca2(+)-binding proteins, such as calmodulin, and membrane potential-driven uptake into the mitochondria. Upon stimulation by hormones which act by increasing cytosolic free Ca2+ levels, both Ca2+ influx and the release of stored Ca2+ from the endoplasmic reticulum contribute to the increases in cytosolic free Ca2+ levels. The exact mechanism(s) by which these events occur is being intensively studied and debated. Here, it is suggested that hormones activate through a second messenger 1) a ligand-gated Ca2+ channel present in the plasma membrane, and 2) a different Ca2+ channel present in the endoplasmic reticulum. As a result, cytosolic-free Ca2+ levels increase and Ca2(+)-dependent processes are activated. A role for the cytoskeleton in the activation of the ryanodine-binding channel is proposed. Future studies are needed to identify the molecular identity of the hepatic ryanodine receptor and to define the role of the cytoskeleton in signal transduction.

Effects of glucagon and vasopressin on hepatic Ca2+ release.

The effects of physiological levels of glucagon on Ca2+ efflux were examined in the perfused rat liver. Two methods were used to estimate Ca2+ efflux: prior labeling of the calcium pools with 45Ca2+ and measurement of perfusate Ca2+ with atomic absorption. According to both methods, glucagon administration at the physiological level evoked Ca2+ release. The released Ca2+ originated mostly from a carbonylcyanide p-trifluoromethoxyphenylhydrazone (FCCP)-depletable pool and also from an FCCP-insensitive pool from which Ca2+ could be released with A23187. Maximally effective doses of glucagon and vasopressin had no additive effect on Ca2+ release. Prior administration of vasopressin resulted in markedly reduced Ca2+ release by glucagon. These results indicate that glucagon releases Ca2+ from the same pool that vasopressin does.

The effect of Mg2+ on hepatic microsomal Ca2+ and Sr2+ transport.

The ATP-dependent uptake of Ca2+ by rat liver microsomal fraction is dependent upon Mg2+. Studies of the Mg2+ requirement of the underlying microsomal Ca2+-ATPase have been hampered by the presence of a large basal Mg2+-ATPase activity. We have examined the effect of various Mg2+ concentrations on Mg2+-ATPase activity, Ca2+ uptake, Ca2+-ATPase activity and microsomal phosphoprotein formation. Both Mg2+-ATPase activity and Ca2+ uptake were markedly stimulated by increasing Mg2+ concentration. However, the Ca2+-ATPase activity, measured concomitantly with Ca2+ uptake, was apparently unaffected by changes in the Mg2+ concentration. In order to examine the apparent paradox of Mg2+ stimulation of Ca2+ uptake but not of Ca2+-ATPase activity, we examined the formation of the Ca2+-ATPase phosphoenzyme intermediate and formation of a Mg2+-dependent phosphoprotein, which we have proposed to be an attribute of the Mg2+-ATPase activity. We found that Ca2+ apparently inhibited formation of the Mg2+-dependent phosphoprotein both in the absence and presence of exogenous Mg2+. This suggests that Ca2+ may inhibit (at least partially) the Mg2+-ATPase activity. However, inclusion of the Ca2+ inhibition of Mg2+-ATPase activity in the calculation of Ca2+-ATPase activity reveals that this effect is insufficient to totally account for the stimulation of Ca2+ uptake by Mg2+. This suggests that Mg2+, in addition to stimulation of Ca2+-ATPase activity, may have a direct stimulatory effect on Ca2+ uptake in an as yet undefined fashion. In an effort to further examine the effect of Mg2+ on the microsomal Ca2+ transport system of rat liver, the interaction of this system with Sr2+ was examined. Sr2+ was sequestered into an A23187-releasable space in an ATP-dependent manner by rat liver microsomal fraction. The uptake of Sr2+ was similar to that of Ca2+ in terms of both rate and extent. A Sr2+-dependent ATPase activity was associated with the Sr2+ uptake. Sr2+ promoted formation of a phosphoprotein which was hydroxylamine-labile and base-labile. This phosphoprotein was indistinguishable from the Ca2+-dependent ATPase phosphoenzyme intermediate. Sr2+ uptake was markedly stimulated by exogenous Mg2+, but the Sr2+-dependent ATPase activity was unaffected by increasing Mg2+ concentrations. Sr2+ uptake and Sr2+-dependent ATPase activity were concomitantly inhibited by sodium vanadate. In contrast to Ca2+, Sr2+ had no effect on Mg2+-dependent phosphoprotein formation. Taken together, these data indicate that Mg2+ stimulated Ca2+ and Sr2+ transport by increasing the Ca2+ (Sr2+)/ATP ratio.(ABSTRACT TRUNCATED AT 400 WORDS)