Mutually Independent Cyclic AMP and Sodium Responses to Nerve Growth Factor in Embryonic Chick Dorsal Root Ganglia

Abstract: Chick embryo dorsal root ganglia display a rapid and transient rise in their cyclic AMP content when presented with nerve growth factor. These ganglia also depend on nerve growth factor for control of their intracellular Na⁺ and K⁺ levels. A sequential relationship between the cyclic AMP and Na⁺ responses is not readily apparent. Incubation of chick sensory ganglia in a sodium-free medium does not prevent the cyclic AMP response to nerve growth factor from occurring. When ganglia are first incubated with ouabain for 6 h, presentation of nerve growth factor elicits a cyclic AMP response, but no Na⁺ response. The cyclic AMP response therefore does not depend on the Na⁺ environment. An initial presentation of nerve growth factor to the ganglia for 30 min, followed by its withdrawal and subsequent re-administration at different intervals over several hours failed to result in a second cyclic AMP response. Nevertheless, the expected Na⁺ behaviors were still observed. Dibutyryl cyclic AMP is capable of eliciting a cyclic AMP response in chick sensory ganglia after 6 h of nerve growth factor deprivation. When both agents were presented simultaneously to the ganglia, only a single cyclic AMP response was obtained, corresponding in time to the response elicited by dibutyryl cyclic AMP alone-indicating that this drug acts on the NGF-sensitive cells. At the same time dibutyryl cyclic AMP alone failed to result in a Na⁺ response, leading one to conclude that the cyclic AMP response to nerve growth factor is truly not mediating the Na⁺ response. Additional support for the mutual independence of these two short-latency responses is provided by the apparent inability of nerve growth factor to cause a cyclic AMP response in chick embryo sympathetic ganglia, another traditional target for the factor, which is capable of displaying a Na⁺ response.     

Amiloride inhibits protein synthesis in isolated rat hepatocytes

The effects of amiloride on Na⁺ ion influx, amino acid transport, protein synthesis and RNA synthesis have been studied in isolated rat hepatocytes. The initial rate of ²²Na⁺ uptake and the amount of ²²Na⁺ taken up at later time points were decreased in hepatocytes incubated in the presence of amiloride. Amiloride inhibited by about 25% the influx of α-methylamino[1?¹⁴C]isobutyric acid, a specific substrate for the A (Alanine preferring) system of neutral amino acid transport. By contrast, the activity of system L (Leucine preferring) was not affected by amiloride. Rates of protein synthesis were determined by using high extracellular concentrations of [¹⁴C]valine in order to maintain a constant amino acid precursor pool. Amiloride inhibited protein synthesis by 85% and had no effect on RNA synthesis. Half-maximal inhibition of protein synthesis occurred with amiloride at about 150 μM. In the absence of Na⁺ in the incubation medium, the rate of protein synthesis was reduced by about 35% and no further inhibition was observed with amiloride. These results suggest that in isolated rat hepatocytes protein synthesis is partially dependent on Na⁺, and that amiloride is an efficient inhibitor of protein synthesis.     

Effect of theophylline and Na+ on methionine influx in Na+-depleted intestine

The unidirectional influx of methionine into the brush border epithelium of chicken jejunum has been studied. Tissues leached of Na⁺ transport methionine from a medium devoid of Na⁺ with reduced apparent affinity (K_t) and maximal flux (J_max). Addition of Na⁺ to the medium during a 1-min incubation with substrate, or during a 30-min preincubation, restored K_t but affected J_max slightly. Theophylline was found to maintain J_max in the absence of Na⁺. Essentially complete restoration of K_t and J_max could be attained when theophylline-treated tissue was exposed to Na⁺ for 30 min. Influx from a Na⁺ medium was unaffected by theophylline pretreatment in Na⁺-containing buffer. K_t was increased without an effet upon J_max when influx was studied from choline medium following preincubation in Na⁺.Modifiers of tissue cyclic AMP levels were investigated in conjunction with theophylline. Histamine and carbachol were found to inhibit theophylline-stimulated transport. Secretin was found to stimulate influx in Na⁺-leached tissue, but did not potentiate the theophylline effect. Amino acids in the incubation medium inhibited theophylline-stimulated influx, whereas preloaded lysine or methionine had no effect.The results are interpreted in terms of a model which envisions roles for cellular and external Na⁺ and for cyclic AMP in the activation and regulation of amino acid transport in intestine.     

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(1) Cyclic AMP stimulated alanine transport in isolated hepatocytes by approx. 30%, in the range 0.2–5 mM alanine. (2) Alanine utilisation was also stimulated by cyclic AMP. The rates of transport and metabolism were comparable, both in the presence and absence of cyclic AMP. (3) At concentrations of alanine above 1 mM, addition of ouabain, or the reduction of the Na⁺ concentration, could partially inhibit transport without affecting the rate of metabolism. (4) At these alanine concentrations, stimulation of metabolism by cyclic AMP was associated with a decrease in the intracellular to extracellular alanine concentration ratio. (5) At alanine concentrations below 0.5 mM, or at higher concentrations when transport was inhibited by reducing the Na⁺ concentration, cyclic AMP caused an increase in the alanine concentration ratio. (6) It is concluded that at concentrations of alanine above 1 mM, alanine transport is not rate-limiting for alanine metabolism in hepatocytes from fed rats, and cyclic AMP stimulates alanine metabolism primarily by an effect on an intracellular reaction. At physiological concentrations of alanine, however, alanine transport appears to be rate-limiting in agreement with a previous report.     

Prostaglandin F2alpha and insulin stimulate phosphate uptake and (Na+, K+) ATPase activity in resting mouse fibroblast cultures.

The (Na⁺, K⁺)ATPase transport system in resting 3T3 Swiss mouse fibroblasts is rapidly activated by prostaglandin F₂α and insulin, which initiate DNA synthesis in these cells. Prostaglandin F₂α, but not insulin, promotes a rapid increase in P_i uptake which is partially coupled to the Na⁺ pump. This rapid activation of both transport systems occurs by a mechanism which does not require fluctuation of cyclic AMP levels or new protein synthesis. A subsequent protein synthesis-dependent increase in P_i uptake is stimulated by insulin and prostaglandin F₂α. These results suggest that different types of control of membrane transport occur during growth stimulation.     

Na movements and their oscillations during fertilization and the cell cycle in sea urchin eggs

We have analysed in detail the Na⁺ content and Na⁺ influx during fertilization and first divisions of the sea urchin egg (Paracentrotus lividus) using a filtration technique devised to eliminate rapidly contamination by the Na⁺ of external sea water. In the first 5 min following fertilization the egg fills up with Na⁺ (+ 30%). Thereafter Na⁺ is extruded and the Na⁺ content stabilizes at about 60% of the unfertilized egg level by the second cleavage (2 h). The initial increase in Na⁺ content is due to a large increase in Na⁺ influx already detected at 20 sec. The Na⁺ influx reaches its maximum at 1 min and its minimum at 5 min. H⁺ excretion follows the same kinetics. A second increase in Na⁺ influx is noted 5–10 min after fertilization; it reaches its maximum at prophase metaphase (30 min) and its minimum during cleavage (60 min). These oscillations in Na⁺ influx were observed for the first three divisions. Fertilization also immediately stimulates the Na⁺ efflux which remains elevated throughout the cell cycle and is responsible for the depletion of the Na⁺ content of the embryos. Activation of the eggs by weak amine bases (5 mM NH₄Cl) which bypasses the early cortical reaction produces only a depletion in the Na⁺ content of the egg similar to that produced by fertilization. NH₄Cl also increases the Na⁺ influx soon after fertilization, although no transient variations are noted.     

Chloroquine and monensin inhibit induction of DNA synthesis in rat arterial smooth muscle cells stimulated with platelet-derived growth factor

Summary The weak base chloroquine and the Na⁺/H⁺ ionophore monensin were used to study the role of lysosomes in the induction of DNA synthesis by platelet-derived growth factor (PDGF) in rat arterial smooth muscle cells cultivated in vitro. The results show that PDGF initiates DNA synthesis in a defined, serum-free medium. This indicates that a single factor may control, directly or indirectly, the transition from the G0 to the G1 phase, the progress through the G1 phase, and the entrance into the S phase of the cell cycle. It is further demonstrated that PDGF has to be present throughout most of the prereplicative period (12–16 h) to induce DNA synthesis in the maximum number of cells, suggesting that one or more processes need to be stimulated continually or successively to push the cell into the S phase. Chloroquine and monensin inhibit induction of DNA replication by PDGF, with maximum effect at 50 M and 5 M, respectively. To be fully active, the drugs have to be added within 4–8 h after the growth factor, but a partial inhibition persists if they are added at any time during the prereplicative period. Both drugs reduce PDGF-stimulated RNA and protein synthesis, and suppress degradation of [³H]leucine-labeled cellular protein and [¹²⁵I]-labeled PDGF. Fine-structurally, they give rise to an accumulation of lysosomes or prelysosomal vacuoles with inclusions of incompletely degraded material. These findings suggest that the mitogenic effect of PDGF is dependent on a normal function of lysosomes during the prereplicative phase, especially its first half (0–8 h).     

Characteristics of an amiloride-sensitive sodium entry pathway in cultured rodent glial and neuroblastoma cells

We have studied the induction of an amiloride-sensitive sodium influx into C6 glioma, NIE, and NB2A neuroblastoma cell lines. In late log phase, cells grown continuously in the presence of 10% fetal calf serum showed Na⁺ influxes of approximately 25–30 nmol/mg protein min; < 5% of this flux was inhibited by amiloride. Removal of serum for 24 h caused a decrease in the total Na⁺ influx to 15–20 nmol/mg protein/min. Upon readdition of serum to the incubation medium, there was an increase in total Na⁺ influx, depending on the cell type, of 20–400% within 2 min. This increment in Na⁺ influx represented an increase in amiloride-sensitive Na⁺ transport with an apparent K′, of 0.4 mM. By adding serum back at various times after serum deprivation, it was determined that 4 h was required to observe a detectable increase in the amiloride-sensitive Na⁺ flux. Thus, serum removal results in the induction of the amiloride transport system which, however, remains latent until the reintroduction of serum to the medium. Addition of 5 μg/ml of cycloheximide blocked the increase in Na⁺ transport, indicating that de novo protein synthesis mediated this serum deprivation–induced increase in Na⁺ transport. Moreover, inhibition of de novo lipid synthesis by 0.1 mM fenfluramine also blocked the induction of this transport activity, suggesting that a coordinated synthesis of lipid and protein is required for the expression of this sodium transport site. We have also found that this serum stimulated Na⁺ influx did not saturate with Na⁺ concentration, up to 140 mM. Also, among commonly used inhibitors of passive Na⁺ entry into epithelial tissues, only amiloride was capable of inhibiting this transport system in these neural cell lines.     

A possible role for cyclic AMP in the initiation of DNA synthesis by isoproterenol-activated parotid gland cells

An intraperitoneal injection of the β-adrenergic agonist dl-isoproterenol hydrochloride (100 mg/Kg body weight) into a rat caused an early, very large (400-fold) cyclic AMP surge (peaking at 10 minutes) in the parotid gland which was followed by a second, much smaller (two-fold) surge 12 to 16 hours later. DNA synthesis began about 16 to 20 hours after the isoproterenol injection and peaked between 24 and 28 hours. The maximum level of DNA-synthetic activity at 24 hours was correlated positively to the magnitude of the small cyclic AMP surge at 12 hours, but not to the size of the much larger cyclic AMP surge at 10 minutes. An intraperitoneal injection of dl-propranolol hydrochloride (59 mg/Kg body weight) at 8 hours after isoproterenol injection abolished the second cyclic AMP surge at 12 hours and markedly (65-75%) reduced the incorporation of [³H]-thymidine into DNA. Injection of dibutyryl cyclic AMP (6.3 mg/Kg body weight) and theophylline (25 mg/Kg body weight) at 8 hours prevented propranolol from inhibiting DNA synthesis. Propranolol appeared specifically to affect the cyclic AMP-dependent pre-DNA-synthetic step because it did not reduce [³H]-thymidine incorporation when injected after the second cyclic AMP surge had passed and DNA synthesis had just begun. Thus, the initial, large cyclic AMP surge following β-adrenergic stimulation may not be necessary for the initiation of prereplicative development, while the much smaller second surge may be needed for the initiation of DNA synthesis.     

Dual effects of glucagon and cyclic AMP on DNA synthesis in cultured rat hepatocytes: stimulatory regulation in early G1 and inhibition shortly before the S phase entry

Although several lines of evidence implicate cyclic AMP in the humoral control of liver growth, its precise role is still not clear. To explore further the role of cyclic AMP in hepatocyte proliferation, we have examined the effects of glucagon and other cyclic AMP-elevating agents on the DNA synthesis in primary cultures of adult rat hepatocytes, with particular focus on the temporal aspects. The cells were cultured in a serum-free, defined medium and treated with epidermal growth factor (EGF), insulin, and dexamethasone. Exposure of the hepatocytes to low concentrations (10 pM-1 nM) of glucagon in the early stages of culturing (usually within 6 h from plating) enhanced the initial rate of S phase entry without affecting the lag time from the plating to the onset of DNA synthesis, whereas higher concentrations inhibited it. In contrast, glucagon addition at later stages (24-45 h after plating) produced only the inhibition. Thus, if glucagon was added at a time when there was a continuous EGF/insulin-induced recruitment of cells to S phase, the rate of G1-S transition was markedly decreased within 1-3 h. This inhibitory effect occurred at low glucagon concentrations (ID50 less than 1 nM) and was mimicked by cholera toxin, forskolin, isobutyl methylxanthine, and 8-bromo cyclic AMP. The results indicate that cyclic AMP has dual effects on hepatocyte proliferation with a stimulatory modulation early in the prereplicative period (G0 or early G1), and a marked inhibition exerted immediately before the transition from G1 to S phase.     

Reserve of vasopressin-sensitive adenylate cyclase in toad urinary bladder

Studies have been performed on the effect of vasopressin on cyclic AMP content of toad bladders. A prompt increase in cyclic AMP content occurred after exposure to vasopressin, which reached maximal values within 8 min and remained elevated up to 30 min. By a comparison of the dose-response characteristics of vasopressin on cyclic AMP content, with those Na⁺ transport and osmotic water flow, it was shown that supramaximal concentrations of vasopressin with respect to physiological function generate more cyclic AMP than is required for maximal stimulation of Na⁺ transport and water flow. Thus, it would seem that a reverse of hormone-sensitive adenylate cyclase is present in this tissue.     

Activation of Na+,H+-Exchange in Erythrocytes of the River Lamprey Lampetra fluviatilis

To study H⁺ transport, the lamprey red blood cells were acidified to pH 6.0 by a pretreatment with an ionophore, nigericin. Incubation of the acidified cells in NaCl-medium at pH 8.0 was accompanied by a rapid H⁺ efflux from the erythrocytes. There was a tenfold decrease of the H⁺ efflux rate on addition to NaCl-medium of dimethylamiloride or on replacing Na⁺ in the medium (KCl-medium, pH 8.0). A high rate of Na+ influx into the acidified erythrocytes occurred only in the presence of H⁺ gradient (pH medium 8.0), but not in its absence (pH medium 6.0). The Na⁺-dependent H⁺ efflux from the cells and H⁺-dependent Na⁺ influx into the cells were quantitatively similar (about 700 mmol/l cells/h). A rapid elevation of the intracellular Na⁺ concentration as measured by flame photometry was also observed during incubation of the acidified cells in NaCl-medium (pH 8.0). The H⁺-dependent Na⁺ influx and an increase of the Na⁺ content in the acidified cells were significantly inhibited by amiloride. The data obtained for the first time prove with certainty the presence of the Na⁺/H⁺ exchanger in erythrocytes of the river lamprey.     

Regulation of Sodium Influx in the NaCl-Resistant (NaClr) Mutant Strain of the Cyanobacterium Anabaena variabilis

A NaCl^r mutant of the diazotrophic cyanobacterium Anabaena variabilis has been isolated by NTG mutagenesis and selection for NaCl resistance. The NaCl^r strain has been characterized with respect to its mechanism of NaCl tolerance and regulation of Na⁺ influx. NaCl^r strain exhibits low Na⁺ influx, accumulated high level of glycine betaine as a compatible solute, and persistent synthesis of SSPs at a higher rate than its wild-type counterpart. DCMU, an inhibitor of PS-II, inhibited Na⁺ influx, suggesting that Na⁺ influx is an energy-dependent process and that the energy is derived from photophosphorylation. This contention is further supported by the inhibition of Na⁺ influx under dark conditions. The inhibition of Na⁺ influx by KCN, DNP, NaN₃ also supports the involvement of oxidative phosphorylation in the regulation of active Na⁺ influx. Thus, it appears that the synthesis of SSPs, accumulation of compatible solutes, and exhibition of low Na⁺ influx in the NaCl^r strain made this organism NaCl tolerant. Received: 6 July 2000 / Accepted: 11 August 2000     

Amiloride blocks cell-free protein synthesis at levels attained inside cultured rat hepatocytes

Amiloride, a passive Na⁺ influx inhibitor, lowers initial rates and plateau levels of [³⁵S]met uptake into proteins in cell-free rabbit reticulocyte lysates (ID₅₀∽0.4 mM). Isolated hepatocytes take up amiloride through a saturable (K_m∽0.02 mM; V_max∽1.43 nmol/ 10⁶ cells/min) Na⁺-dependent process. Similar temperature dependent uptake occurs in cultured hepatocyte monolayers. In chemically defined media, under growth reinitiation conditions, amiloride lowers overall rates of cellular protein and albumin synthesis (ID₅₀∽0.4 and ∽0.028 mM, respectively). Amiloride concentrations (0.02 mM) that half-maximally inhibit reinitiation of hepatocyte DNA synthesis reach, within 30 min, cellular levels (∽0.14 mM) that block reticulocyte lysate protein synthesis by 25%. These findings complicate interpretations, from studies in many eukaryotic systems, of cause and effect between mitogen-activated membrane Na⁺ influxes and the reinitiation of DNA synthesis.     

Cyclic AMP increase the Na+ permeability of the avian erythrocyte membrane by a process which does not involve protein phosphorylation

Summary Preparations of avian erythrocyte plasma membranes have been made which are in the form of sealed vesicles. Using these preparations the permeability of the membranes to Na⁺ K⁺, Mg⁺ and Ca⁺ was measured. Monobutyryl cyclic AMP and cyclic AMP increased the permeability to Na⁺ and Ca⁺ under conditions where no protein phosphorylation could occur. The only effect of phosphorylation of membrane proteins was to reduce Ca⁺ permeability. It is thus concluded that cyclic AMP increases Na⁺ permeability in the avian erythrocyte by a direct effect which does not involve protein phosphorylation.     

Demonstration of a late amiloride-sensitive event as a necessary step in initiation of DNA synthesis by thrombin

Amiloride, a Na⁺ influx inhibitor, has been shown to inhibit initiation of DNA synthesis by thrombin in mouse embryo fibroblast-like cells. Long exoosures (24 hr) to high concentrations of amiloride inhibited incorporation of thymidine into the DNA of both thrombin-stimulated and nonstimulated cells, suggesting that this inhibition might not be specific for thrombin-initiated DNA synthesis. Fluorescence microscopy and spectrofluorimetry showed that amiloride was internalized with an apparent mitochondrial association and that the internalized amiloride was readily released from the cells after removing amiloride from the medium. Based on this reversibility, cells were exposed to amiloride for short periods of time during thrombin treatment to determine the temporal relationship between any amiloride-sensitive event(s) and initiation of DNA synthesis. The presence of amiloride (100 μM) during a 12-hr exposure to thrombin did not block thrombin-initiated DNA synthesis or cell division but did delay the onset of DNA synthesis and the peak of thymidine incorporation into DNA by approximately 3 hr, suggesting that early initiation events might proceed in the presence of amiloride. ⁸⁶Rb⁺ transport studies demonstrated that in this system ouabain-sensitive K⁺ uptake via the Na, K-ATPase was stimulated by thrombin during both an early and a late period. This stimulation was amiloride-sensitive under the same conditions used for growth experiments, suggesting that amiloride was inhibiting thrombin-stimulated Na⁺ transport in this system. Additional experiments showed that exposing cells to amiloride only during the first 8 hr after thrombin addition did not inhibit initiation. The presence of amiloride from 8–12 hr after thrombin addition maximally inhibited thrombin-stimulated DNA synthesis. Together these results demonstrate that amiloride inhibits thrombin-initiated DNA synthesis not by inhibiting an early event occurring during the first 8 hr, but rather by inhibiting some later event 8–12 hr after thrombin addition.     

Regulation of dog thyroid epithelial cell cycle by forskolin, an adenylate cyclase activator

Dog thyroid epithelial follicular cells in primary culture are quiescent in an insulin-supplemented serum-free medium. They are induced, after a 16- to 20-h prereplicative phase, to synthesize DNA upon stimulation by forskolin, a general adenylate cyclase activator that mimics all the effects of thyrotropin in these cells. The characteristics of adenylate cyclase activation by forskolin make this drug a convenient tool to enhance cellular cyclic AMP levels for well-defined periods of the cell cycle, allowing determination of which parts of the prereplicative phase are controlled by cyclic AMP. We observe that induction of DNA synthesis by forskolin requires its continuous presence for most of the prereplicative phase until a point that little precedes the initiation of DNA replication. Before this point, interruptions in forskolin presence as short as 2 h delay the onset of DNA synthesis, indicating a rapid regression of the cells to an earlier part of G1 from which they can be rescued by forskolin readdition. Similar delays in the onset of S phase are also induced by reversible protein synthesis inhibitions using pulses of cycloheximide. These data suggest that in dog thyrocytes elevated cyclic AMP levels stimulate the progression into G1 phase until a late commitment point before DNA synthesis. This progression depends on peculiarly labile cyclic AMP-stimulated events which might well be the induction by cyclic AMP of the synthesis of labile proteins.     

Effects of ouabain and isoproterenol on potassium influx in the turkey erythrocyte: Quantitative relation to ligand binding and cyclic AMP generation

Studies have been carried out in the turkey erythrocyte to examine: (1) the influence of external K⁺ concentration on both [³H]ouabain binding and the sensitivity of potassium influx to inhibition by ouabain and (2) the quantitative relation between β-adrenergic receptor site occupancy, agonist-directed cyclic AMP generation and potassium influx rate. Both [³H]ouabain binding and the ability of ouabain to inhibit potassium influx are markedly reduced at increasing external K⁺ concentrations, and at each K⁺ concentration the concentrations of ouabain required for half-maximal binding to the erythrocyte membrane and for half-maximal inhibition of potassium influx are identical. Both basal and isoproterenol-stimulated potassium influx rise with increasing external K⁺ concentrations. In contrast to basal potassium influx, which is 50–70% inhibitable by ouabain, the isoproterenol-stimulated component of potassium influx is entirely insensitive to ouabain. At all concentrations of K⁺, inhibition of basal potassium influx by ouabain is linear with ouabain binding, indicating that the rate of transport per unoccupied ouabain binding site is unaffected by simultaneous occupancy of other sites by ouabain. Similarly, the rate of isoproterenol-stimulated cyclic AMP synthesis is directly proportional to β-adrenergic receptor occupancy over the entire concentration-response relationship for isoproterenol, showing that at all levels of occupancy β-adrenergic receptor sites function independently of each other.Analysis of the relation of catecholamine-dependent potassium transport to the number of β-adrenergic receptor sites occupied indicates an extremely sensitive physiological system, in which 50%-maximal stimulation of potassium transport is achieved at less than 3% receptor occupancy, corresponding to fewer than ten occupied receptors per cell.     

INTERRELATIONSHIPS AMONG THE LEVELS OF ATP, ADENOSINE AND CYCLIC AMP IN INCUBATED SLICES OF GUINEA-PIG CEREBRAL CORTEX: EFFECTS OF DEPOLARIZING AGENTS, PSYCHOTROPIC DRUGS AND METABOLIC INHIBITORS

—Adenine nucleotides of guinea-pig cerebral cortical slices were labelled during a 40 min incubation with [¹⁴C]adenine. Subsequent incubation of cortical slices with depolarizing agents, such as veratridine, ouabain, batrachotoxin and high concentrations of potassium ions, or with certain psychotropic drugs such as chlorpromazine, chlorimipramine or prenylamine resulted in a reduction in both endogenous and radioactive ATP, accompanied by a marked increase in levels of both endogenous and radioactive cyclic AMP. Reduction of ATP levels during incubation with depolarizing agents, such as veratridine, is probably associated with increased activity of membranal Na⁺-K⁺-activated ATPase, while the reduction elicited by psychotropic drugs is proposed to be due to inhibition of mitochondrial synthesis of ATP. With both classes of compounds reduction of ATP levels results in enhanced formation and efflux of adenosine which stimulates formation of cyclic AMP from intracellular ATP in the compartments of brain slices which contain the cyclic AMP-generating systems. Certain classical metabolic inhibitors such as 2,4-dinitrophenol, azide, 1,2-naphthoquinone-8-sulfonate and cyanide also reduce ATP levels and in the case of 2,4-dinitrophenol, cyanide, and azide elicit small but significant accumulations of cyclic AMP. With certain metabolic inhibitors reduction of ATP within the cyclic AMP generating compartments would appear to prevent or reduce the accumulation of cyclic AMP elicited by amines, adenosine or veratridine.