Uterine cyclic AMP formation: biphasic effect of estrogen on catecholamine sensitivity.

Female, ovariectomized rats were treated with estradiol and then, after various time periods, given an intravenous injection of isoproterenol or epinephrine. 30 seconds later uteri were frozen $\text{in}$$\text{situ}$ and assayed for cyclic AMP and glycogen phosphorylase. The cyclic AMP response to catecholamines was significantly depressed as early as 30 minutes after estrogen and at 6, 12 and 24 hours was 50% of that in non-estrogen-treated controls. Catecholamine-induced glycogen phosphorylase activation was unchanged until 24 hours after estrogen when it was significantly increased over controls. At 48 hours of estrogen both the cyclic AMP and phosphorylase responses to catecholamines were greater than controls. Estrogen regulates uterine β-adrenergic sensitivity but the time courses of estrogen effects on the cyclic AMP and glycogen phosphorylase response changes are different. Catecholamine-induced uterine cyclic AMP formation is biphasic: suppression during the first 24 hours of estrogen followed by recovery and finally augmentation by 48 hours. Catecholamine-induced glycogen phosphorylase activation shows only augmentation after 24–48 hours of estrogen. It is concluded that estrogen has independent effects on the β-adrenergic-glycogen phosphorylase activation pathway at two different points; one prior to cyclic AMP formation and another after cyclic AMP formation.     

Estrogenic regulation of uterine cyclic amp metabolism

Ovariectomized and ovariectomized, estrogen-treated (48 h) rats were injected intravenously with increasing doses of epinephrine. Uteri were frozen in situ 30 s later. Estrogen pre-treatment significantly increased the sensitivity of both cyclic AMP and phosphorylase to epinephrine. The cyclic AMP response to intravenous injection of the pure β-agonist, isoproterenol, was enhanced by estrogen pre-treatment (48 h) and the cyclic AMP response of isolated uteri treated with epinephrine in vitro was also enhanced by in vivo estrogen pre-treatment (48 h). Other groups of ovariectomized rats were treated with estrogen and cyclic AMP levels were estimated at various times after estrogen treatment. 6 h after intraperitoneal injection and 48 h after subcutaneous injection, estrogen caused 20 and 30% increases in cyclic AMP. Estrogen had no effect on cyclic AMP 30 s after intravenous injection or 15 min after intraperitoneal injection. The was also no change in uterine catecholamine sensitivity 30 s after intravenous estrogen injection.The uterine site(s) at which estrogen acts to alter uterine cyclic AMP metabolism could be uterine β-adrenergic receptors, adenyl cyclase, and/or phosphodiesterase.     

Genetic manipulation of cyclic AMP levels in Drosophila melanogaster.

Cyclic AMP levels in $\text{Drosophila}$,$\text{melanogaster}$ adults can be altered genetically by changing the number of doses of chromomere 3D4 contained in the genome, a chromomere previously shown to control the activity of cyclic AMP phosphodiesterase in a dose-dependent manner. Flies completely deficient for chromomere 3D4 have 2–7 times the cyclic AMP level of flies with one or two doses of chromomere 3D4. Cyclic AMP levels are significantly depressed in flies carrying three doses of 3D4. Cyclic GMP levels are not influenced in a dose-dependent manner by chromomere 3D4. The effect on cyclic AMP levels may provide a useful system for investigating physiological and developmental consequences of aberrant cyclic AMP levels in the intact organism.     

On the role of calcium as second messenger in liver for the hormonally induced activation of glycogen phosphorylase

We have studied the mode of action of three hormones (angiotensin, vasopressin and phenylephrine, an α-adrenergic agent) which promote liver glycogenolysis in a cyclic AMP-independent way, in comparison with that of glucagon, which is known to act essentially via cyclic AMP. The following observations were made using isolated rat hepatocytes: (a) In the normal Krebs-Henseleit bicarbonate medium, the hormones activated glycogen phosphorylase (EC 2.4.1.1) to about the same degree. In contrast to glucagon, the cyclic AMP-independent hormones did not activate either protein kinase (EC 2.7.1.37) or phosphorylase $\text{b}$ kinase (EC 2.7.1.38). (b) The absence of Ca²⁺ from the incubation medium prevented the activation of glycogen phosphorylase by the cyclic AMP-independent agents and slowed down that induced by glucagon. (c) The ionophore A 23187 produced the same degree of activation of glycogen phosphorylase, provided that Ca²⁺ was present in the incubation medium (d) Glucagon, cyclic AMP and three cyclic AMP-independent hormones caused an enhanced uptake of ⁴⁵Ca; it was verified that concentrations of angiotensin and of vasopressin known to occur in haemorrhagic conditions were able to produce phosphorylase activation and stimulate ⁴⁵Ca uptake. (e) Appropriate antagonists (i.e. phentolamine against phenylephrine and an angiotensin analogue against angiotensin) prevented both the enhanced ⁴⁵Ca uptake and the phosphorylase activation.We interpret our data in favour of a role of calcium (1) as the second messenger in liver for the three cyclic AMP-independent glycogenolytic hormones and (2) as an additional messenger for glucagon which, via cyclic AMP, will make calcium available to the cytoplasm either from extracellular or from intracellular pools. The target enzyme for Ca²⁺ is most probably phosphorylase $\text{b}$ kinase.     

Regulation of muscle phosphorylase activity by carnosine and anserine

Carnosine (β-alanyl-L-histidine) activates rabbit muscle phosphorylase $\text{a}$ in the presence and absence of AMP and phosphorylase $\text{b}$ in the presence of AMP in a biphasic manner with a maximal activation at about 50mM carnosine and with phosphorylase $\text{b}$ showing a greater degree of activation than phosphorylase $\text{a}$. Anserine (β-alanyl-L-N^π-methyl-histidine) activates phosphorylase $\text{a}$ to a lesser extent than carnosine up to a concentration of 90mM, whereas with phosphorylase $\text{b}$ a weak activation below 30mM and a concentration-dependent inhibition above this concentration occurs. These effects are specific for the dipeptides and are not shown by their constituent amino acids. Carnosine and anserine activate phosphorylase $\text{a}$ in the presence of the allosteric inhibitors ATP, D-glucose and caffeine, and the inhibition of phosphorylase $\text{b}$ by anserine is also observed in the presence of these inhibitors.     

Control of glycogen synthase and phosphorylase by insulin in rat adipocytes which is unrelated to the concentration of cyclic AMP

Incubation of adipocytes in glucose-free medium with adrenocorticotrophic hormone, epinephrine, isoproterenol, or norepinephrine increased the concentration of cyclic AMP and the percentage of phosphorylase a activity, and decreased the percentage of glycogen synthase I activity. Glucose was essentially without effect on glycogen synthase or phosphorylase in either the presence or absence of epinephrine. Although glucose potentiated the action of insulin to activate glycogen synthase, the hexose did not enhance the effectiveness of insulin in the presence of epinephrine. Likewise, glucose did not increase the ability of insulin to oppose the activation of phosphorylase by epinephrine.The activation of glycogen synthase by insulin was not associated with a decrease in the concentration of cyclic AMP. Insulin partially blocked the rise in cyclic AMP due to isoproterenol, adrenocorticotrophic hormone, and norepinephrine. The maximum effects of isoproterenol on glycogen synthase and phosphorylase were observed when the concentration of cyclic AMP was increased twofold. However, insulin clearly opposed the changes in enzyme activity produced by isoproterenol (and also adrenocorticotrophic hormone, epinephrine and norepinephrine) even though concentrations of cyclic AMP were still increased three- to fourfold. Nicotinic acid opposed the increases in cyclic AMP due to adrenocorticotrophic hormone, isoproterenol and norepinephrine to the same extent as insulin; however, nicotinic acid was ineffective in opposing the activation of phosphorylase and inactivation of glycogen synthase produced by these agents. Thus, it is unlikely that the effects of insulin on glycogen synthase and phosphorylase result from an action of the hormone to decrease the concentration of cyclic AMP.     

The hormonal stimulation of ureogenesis in isolated hepatocytes through increases in mitochondrial ATP production

Isolated hepatocytes incubated with 2 mm ornithine-10 mm glutamine as substrates and challenged with either glucagon, epinephrine, or phenylephrine exhibited stimulated rates of urea production, and mitochondria isolated from these cells displayed an increased rate of energy-dependent citrulline formation. There was no change in the total carbamyl phosphate synthetase I activity, nor mitochondrial content of the positive effector N-acetyl glutamate after acute hormonal treatment. The time of onset of ureogenesis and its sensitivity to glucagon were compared with stimulation of glucose production from lactate-pyruvate. No apparent differences in time of onset or sensitivity of the responses were observed indicating both pathways may be stimulated by a common mechanism. Mitochondria prepared from cells treated with catecholamines exhibited increased rates of State 3 respiration and increased uncoupler-dependent ATPase activity, in addition to the increased rates of citrulline formation. There was also an elevated intramitochondrial content of ATP and an increased $\text{ATP}\text{ADP}$ ratio. The catecholamine-induced stimulation of ureogenesis was mediated by an α-adrenergic cyclic AMP independent mechanism. The addition of the α-adrenergic antagonist, dihydroergotamine, blocked both the epinephrine-induced stimulation of ureogenesis and also the stimulated functions in the isolated mitochondria. dl-Propranolol, a β-antagonist, inhibited the rise in cyclic AMP due to epinephrine, but had no effect on any of the other reactions measured. The effects of catecholamines on citrulline formation and urea production are correlated with the increased capacity of the mitochondria to generate ATP. It is suggested that both glucagon and catecholamines, acting via independent mechanisms, stimulate electron transport and the activity of the ATP-forming enzyme complex. The consequent elevated intramitochondrial ATP levels and $\text{ATP}\text{ADP}$ ratio enhance the rate of citrulline formation and hence ureogenesis.     

Parallel activation of cyclic AMP phosphodiesterase and cyclic AMP-dependent protein kinase in two human gut adenocarcinoma cells (HT 29 and HRT 18) in culture,by vasoactive intestinal peptide (VIP) and other effectors activating the cyclic AMP system

Vasoactive intestinal peptide (VIP), secretin, catecholamines and prostaglandin E₁ (PGE₁) in the presence of a cyclic nucleotide phosphodiesterase inhibitor stimulate the accumulation of cyclic AMP in two colorectal carcinoma cell lines (HT 29 and HRT 18) with subsequent activation of the cyclic AMP-dependent protein kinases. In HT 29 cells incubated without phosphodiesterase inhibitor, 10^?9 M VIP promotes a rapid and specific activation of the low $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ cyclic AMP phosphodiesterase (1.7-fold); at 25°C the effect is maintained for more than 15 min, while at 37°C the activity returns to basal value within 15 min. As shown by dose-response studies, VIP is by far the most effective inducer ($\text{K}{}_{\mathrm{<mtext>a</mtext>}}\text{= 4 · 10}{}^{\mathrm{?10}}\text{M}$) of the cyclic AMP phosphodiesterase activity; partial activation of the enzyme is obtained by 3 · 10^?7 M secretin, 10^?5 M isoproterenol and 10^?5 M PGE₁; PGE₂ and epinephrine are without effect. In HRT 18 cells VIP is less active ($\text{K}{}_{\mathrm{<mtext>a</mtext>}}\text{= 2 · 10}{}^{\mathrm{?9}}\text{M}$) whereas 10^?6 M PGE₁, 10^?6 M PGE₂ and 10^?5 M epinephrine are potent inducers of the phosphodiesterase activity. The positive cell response to dibutyryl-cyclic AMP further indicates that cyclic AMP is a mediator in the phosphodiesterase activation process. The incubation kinetics and dose response effects of the various agonists on the cyclic AMP-dependent protein kinase activity determined for both cell types in the same conditions show a striking similarity to those of phosphodiesterase. Thus coordinate regulation of both enzymes by cyclic AMP was observed in all incubation conditions.     

Nucleotide activation of glycogen phosphorylase b occurs only when the nucleotide phosphate is in a dianionic form

Adenosine monophosphofluoridate has been synthesised and purified to remove all contaminating AMP. This AMP analogue fails to activate glycogen phosphorylase $\text{b}$, even at high concentration, but inhibits the AMP activation with a Ki value of 3 mM. Activation of phosphorylase $\text{b}$ by adenosine phosphoramidate has been re-investigated in the light of these findings and a purified sample of this nucleotide analogue has been shown to produce little or no activation of the enzyme. These findings are interpreted in terms of an absolute requirement of the nucleotide activatorsite in phosphorylase for a nucleotide with a dianionic phosphate. The implications of this for the role of the phosphate moiety in the proposed mechanism of activation are discussed.     

Interaction of cyclic nucleotides and ecdysterone in breaking the pupal diapause of the bertha armyworm, Mamestra configurata WLK.

Cyclic GMP and cyclic AMP have distinct and opposite effects upon the action of ecdysterone in diapausing pupae of the Bertha armyworm, $\text{Mamestra}$$\text{configurata}$. Cyclic GMP enhanced the effectiveness of suboptimal doses of ecdysterone in breaking diapause; the amount of cyclic GMP required to lower the ED50 of ecdysterone by half was 80 μg/g. Dibutyryl cyclic GMP had no apparent effect on the action of ecdysterone over a wide dose range (0.07 – 70 μg/g). On the other hand, cyclic AMP and dibutyryl cyclic AMP effectively blocked the diapause-breaking action of ecdysterone when administered simultaneously with the steroid hormone. The amount of cyclic AMP required to reduce the incidence of diapause termination from 100% to 50% was 60 μg/g; for dibutyryl cyclic AMP the amount required was only 14 μg/g. No cyclic nucleotide tested in the study could by itself break the pupal diapause of $\text{M.}$$\text{configurata}$. The concept that cyclic GMP and cyclic AMP provide at least different if not opposing regulatory influences in certain insect systems is discussed briefly in the light of these observations.     

Interaction between alpha and beta adrenergic receptors and cholinergic receptors in isolated perfused rat heart: effects on cAMP-protein kinase and phosphorylase

The ability of acetylcholine to antagonize catecholamine-induced activation of myocardial cyclic AMP dependent protein kinase and glycogen phosphorylase activity was assessed using isolated perfused rat hearts. Perfused hearts were treated with either saline, epinephrine, epinephrine plus phentolamine or isoproterenol. After 1 minute of infusion of the indicated drug a second infusion containing acetylcholine was started. After an additional minute hearts were frozen and analyzed for cyclic nucleotide content and enzyme activity. In the presence of the alpha receptor blocking agent, phentolamine, epinephrine is a more effective activator of protein kinase than in its absence. Under these conditions the antagonistic action of acetylcholine on protein kinase activation is more pronounced. In the presence of epinephrine plus phentolamine or in the presence of isoproterenol the antagonistic action of acetylcholine on phosphorylase activity can be accounted for by a reduction in cyclic AMP-protein kinase. This same action of acetylcholine on epinephrine-stimulated phosphorylase in the aabsence of phentolamine, however, cannot be totally accounted for by a reduction in cyclic AMP content or in protein kinase activity.     

Cyclic AMP-dependent protein kinase of Neurospora crassa

$\text{Neurospora}\text{crassa}$ was surveyed for cyclic AMP-dependent protein kinase activity. Two peaks (I and II) of protein kinase activity were demonstrated by DEAE-cellulose chromatography of wild type $\text{Neurospora}$ extracts. Peak I was stimulated by cyclic AMP, eluted below 60 mM NaCl and had high activity using histone H2B as substrate. Peak II eluted at 200–250 mM NaCl; its activity was not cyclic AMP stimulated and was highest with dephosphorylated casein as a substrate. Cyclic AMP binding to a protein associated with the protein kinase is specifically inhibited by certain cyclic AMP analogs.     

Adrenergic regulation of pyruvate kinase and gluconeogenesis in hepatocytes from phosphorylase kinase-deficient (gsdgsd) rats

Hepatocytes were prepared from a strain of rats deficient in hepatic phosphorylase $\text{b}$ kinase and were used to assess the role of this enzyme in the adrenergic regulation of pyruvate kinase and gluconeogenesis. Epinephrine (10 μM) stimulated glucose output and gluconeogenesis from 1.8 mM lactate but did not significantly affect the concentration of hepatocyte glycogen. In addition epinephrine treatment led to an inhibition of pyruvate kinase. The stimulation of gluconeogenesis and the inhibition of pyruvate kinase by epinephrine were blocked by both α- and β-antagonists: similar effects with epinephrine were observed in cells from control animals. It is concluded that mechanisms for the adrenergic regulation of pyruvate kinase and gluconeogenesis are similar in hepatocytes from both phosphorylase kinase-deficient and normal rats.     

The dextro and levorotatory isomers of N-phenylisopropyladenosine: stereospecific effects on cyclic AMP-formation and evoked synaptic responses in brain slices.

The stereoisomers of N⁶-phenylisopropyladenosine elicit accumulations of cyclic AMP in brain slices via interaction with adenosine-receptors. The response in guinea pig cerebral cortical slices and in rat hippocampal slices is blocked by theophylline and potentiated by biogenic amines. A chelator, EGTA, potentiates the response to phenylisopropyladenosine in guinea pig cerebral cortical slices. The $\text{1}$-isomer (EC₅₀ 25 μM) is four- to five-fold more potent than the $\text{d}$-isomer in eliciting accumulations of cyclic AMP in brain slices. In a rat coronal hippocampal slice $\text{in vitro}$, $\text{1}$-phenylisopropyladenosine (IC₅₀ ～ 0.7 μM) reduces the amplitude of evoked synaptic responses generated $\text{via}$ a monosynaptic pathway to the CA1 pyramidal neurons. The $\text{d}$-isomer is nearly one hundred-fold less potent. Thus, the adenosine-receptors involved in the electrophysical response appear much more stereoselective for the $\text{1}$-isomer of phenylisopropyladenosine than the adenosine-receptors involved in cyclic AMP-generation in brain slices.     

In vivo activation of cyclic adenosine 3':5'-phosphate-dependent protein kinase in Chinese hamster ovary cells treated with N-6, O-2'-diburyl cyclic adenosine 3':5'-phosphate.

Treatment of Chinese hamster ovary cells with dibutyryl cyclic AMP, which results in a net increase of the intracellular cyclic AMP level, converts the epithelial-like cells to a fibroblast-like shape. Protein kinase activity in cells treated with 1 mM dibutyryl cyclic AMP show a 3-fold increase in V_max but no appreciable changes in the apparent K_m for ATP. When cells are treated with dibutyryl cyclic AMP, there is a time-dependent conversion of cyclic AMP-stimulable protein kinase to cyclic AMP-independent catalytic subunits, as demonstrated by Sephadex G-100 gel filtration. These experiments demonstrate the activation of the cyclic AMP-dependent protein kinase $\text{in vivo}$. This activation may lead to phosphorylation of certain cellular constituent(s) and thus may be involved in the observed morphological transformation.     

A cyclic AMP dependent protein kinase in Dictyostelium discoideum

A cyclic AMP-dependent protein kinase was found to appear during the time course of development of $\text{Dictyostelium}\text{discoideum}$. No cyclic AMP dependency was observed at any stage of development in crude 110,000 X G soluble extracts. After partial purification, however, extracts from post-aggregation stages contained enzyme that was activated up to 6-fold by cyclic AMP, whereas protein kinase from earlier stages was not affected by cyclic AMP. Likewise, cyclic AMP binding activity increased from the aggregation to the slug stage of development. Approximately one-half of the total cyclic AMP binding activity co-purified with the cyclic AMP dependent protein kinase. The enzyme from $\text{Dictyostelium}$ showed similarities to mammalian protein kinases with respect to its kinetic properties but differed in its behavior on ion-exchange chromatography.     

Attenuation of epinephrine-induced increase in liver cyclic AMP by endogeneous insulin in vivo.

1. Epinephrine-induced increase in rat liver cyclic AMP in vivo was potentiated when the circulating insulin was suppressed by injection of anti-insulin serum or by induction of diabetes. Consequently, phosphorylase was activated, glycogen synthetase was inactivated and glycogen accumulation induced by glucose load was prevented by epinephrine in the insulin-deficient rats to a much larger extent than in normal rats. 2. Insulin lack was effective in potentiating epinephrine-induced increase in liver and muscule cyclic AMP even after the treatment of rats with theophylline; the potentiation could not be solely accounted for by the inhibition of cyclic AMP phosphodiesterase. Thus, it is likely that insulin lack enhaces epinephrine activation of adenylate cyclase. 3. Unlike epinephrine, glucagon increased liver cyclic AMP to essentially the same extent whether the rat was treated with anti-insulin serum or not. 4. Based on the difference in dose-response curves between normal and insulin-deficient rats, a possibility is discussed that there are two adenylate cylase in the liver with higher and lower affinities for epinephrine and that circulating insulin blocks the high affinity enzyme selectively.     

Nitration of functional tyrosyl residues in rabbit muscle phosphorylase b

Upon reaction of rabbit muscle phosphorylase $\text{b}$ with tetranitromethane in a stoichiometric ratio with respect to the tyrosyl content, 2 out of 34 phenolic groups per mole of monomer (M.W. 95,000) were nitrated with an almost complete loss of activity. Only one residue per monomer was nitrated in the presence of AMP, the major part of the activity being preserved. The sedimentation pattern of modified phosphorylase $\text{b}$ showed that, following nitration in the absence of AMP, the enzyme was fully dissociated into monomers, whereas, when the enzyme was nitrated in its presence, the dimeric structure was retained.     

Opposite effects of acute and repeated administration of desmethylimipramine on adrenergic responsiveness in rat pineal gland.

The effect of acute and repeated desmethylimipramine (DMI) treatment on catecholamine-stimulated production of adenosine 3', 5'-monophosphate (cyclic AMP) in rat pineal gland was studied $\text{in}$$\text{vivo}$. In rats exposed to continuous illumination, the administration of isoproterenol (2μmol/kg) to control animals produced a marked increase in the concentration of cyclic AMP in pineal gland. In contrast, norepinephrine (2μmol/kg) failed to increase the levels of cyclic AMP. After acute treatment with DMI (single injection, 38μmol/kg, i. p.), the isoproterenol-induced rise in cyclic AMP was not significantly different from that measured in control animals. However, acute DMI treatment did allow a significant elevation in the concentration of cyclic AMP in pineal gland in response to norepinephrine. In rats given nine injections of DMI (38μmol/kg, i.p., twice daily) neither isoproterenol nor norepinephrine caused a significant increase in the concentration of cyclic AMP in pineal glands. Although acute treatment with DMI had no significant effect on [³H] dihydroalprenolol binding, chronic treatment with DMI significantly reduced [³H] dihydroalprenolol binding in the pineal gland. The results of this study suggest that while a single administration of DMI can enhance adrenergic responses elicited by norepinephrine, chronic administration of DMI leads to compensatory decreases in receptor density and adrenergic responsiveness.