The effect of starvation on phosphodiesterase activity and the content of adenosine 3′:5′-cyclic monophosphate in isolated mouse pancreatic islets

1. The concentration of cyclic AMP and the activity of phosphodiesterase were measured in isolated pancreatic islets from fed or 48h-starved mice. 2. Two different phosphodiesterases were detected. Neither the maximum activity nor the K(m) values of these enzymes were changed by starvation. 3. The concentration of cyclic AMP in non-incubated islets was the same in islets from fed and starved mice. 4. Incubation with 3.3mm-glucose for 5-30min had no effect on the concentration of cyclic AMP, irrespective of the nutritional state of the mice. Incubation with 16.7mm-glucose for 5-30min raised the concentration of cyclic AMP by about 30% in islets from fed mice. This rise was prevented by addition of mannoheptulose (3mg/ml). Incubation with 16.7mm-glucose had no effect on the cyclic AMP content in islets from starved mice. 5. In islets from fed mice 10min incubation with 5mm-caffeine had no effect on the concentration of cyclic AMP in the presence of 3.3 or 16.7mm-glucose, whereas the cyclic AMP content was increased approx. 150% in islets from starved mice. 6. After 10min incubation with 1mm-3-isobutyl-1-methylxanthine in the presence of 3.3 or 16.7mm-glucose the concentration of cyclic AMP was raised by 250% in islets from fed mice and by 400% in islets from starved mice. 7. A threefold function of glucose in the insulin-secretory process is suggested, according to which the decreased islet glucose metabolism is the primary defect in the insulin-secretory mechanism during starvation.     

The effect of glucose, insulin and noradrenaline on lipolysis and on the concentrations of adenosine 3′:5′-cyclic monophosphate and adenosine 5′-triphosphate in adipose tissue

1. The deoxyfluoro-d-glucopyranose 6-phosphates were prepared from the corresponding deoxyfluoro-d-glucoses and ATP by using hexokinase. 2. 3-Deoxy-3-fluoro- and 4-deoxy-4-fluoro-d-glucose 6-phosphate were substrates for glucose phosphate isomerase, and in addition the products of this reaction, 3-deoxy-3-fluoro- and 4-deoxy-4-fluoro-d-fructose 6-phosphate respectively, were good substrates for phosphofructokinase. 3. Some C-2-substituted derivatives of d-glucose 6-phosphate were found to be competitive inhibitors of glucose phosphate isomerase. 4. The possible role of the hydroxyl groups in the binding of d-glucose 6-phopshate to glucose phosphate isomerase is discussed.     

The effect of prostaglandins on ox pituitary content of adenosine 3′:5′-cyclic monophosphate and the release of growth hormone

1. An assay, based on competition between adenosine 3':5'-cyclic monophosphate (cyclic AMP) and cyclic [(3)H]AMP for binding to a rabbit skeletal muscle protein, has been used to measure tissue contents of cyclic AMP. The assay has a sensitivity of 0.05pmol of cyclic AMP. Cyclic GMP and cyclic CMP have 0.5%, and cyclic IMP 6.5%, of the ability of cyclic AMP to displace cyclic [(3)H]AMP from binding protein; AMP, ADP and ATP have no effect. 2. By using this method, the cyclic AMP content of ox pituitary slices exposed to prostaglandin was determined; release of growth hormone was measured by radioimmunoassay. 3. Release of growth hormone was increased by 45min incubation in 1mum-prostaglandin E(2) in the absence of theophylline, or in 10nm-prostaglandin E(2), 0.1mum-prostaglandin A(1) or 1mum-prostaglandin B(1) in the presence of 0.5mm-theophylline. 4. Pituitary cyclic AMP content was increased by 10min incubation in 1mum-prostaglandin E(2) in the absence of theophylline, or in 0.1mum-prostaglandin E(2) in the presence of 0.5mm-theophylline. 5. The maximum increase in cyclic AMP content was observed 10min, and significant changes in growth hormone release 30min, after introduction of prostaglandin E(2). 6. The increase in pituitary cyclic AMP content, but not in the rate of release of growth hormone, was observed in the absence of external Ca(2+). 7. The stimulation of release of growth hormone by prostaglandin was decreased by preincubation of tissue for 2h in colchicine (100mum) or cytochalasin B (10mug/ml). 8. These results support the suggestion that increased release of growth hormone after treatment with prostaglandin is the result of increased tissue cyclic AMP content, and possibly involves a microfilamentous or microtubular protein.     

Anti-anabolic effects of adenosine 3′:5′-cyclic monophosphate. Inhibition of protein synthesis

1. Evidence is presented that cyclic AMP inhibits the incorporation of l-[4,5-(3)H]leucine into protein in a cell-free system from rat liver. This inhibition occurs after aminoacyl-tRNA formation. 2. Microsomal fractions, isolated after the incubation of postmitochondrial supernatant with cyclic AMP and ATP, show a diminished ability to synthesize protein. Both cyclic AMP and ATP are required for this effect. 3. A possible physiological role for the anti-anabolic action of cyclic AMP is discussed in terms of the control of gluconeogenesis.     

The effects of glucagon and insulin on adenosine 3′:5′-cyclic monophosphate concentrations in an organ culture of mature rat liver

1. A modified radioimmunoassay for cyclic AMP was developed from the method of Steiner et al. (1969). Cyclic [(3)H]AMP was used as the radioactive tracer. Free and antibody-bound nucleotides were separated by adsorption of protein to Millipore filters. The assay was used to measure amounts of cyclic AMP down to 0.1pmol in 50mul. 2. The effect of glucagon on cyclic AMP content in pieces of mature rat liver maintained for 6 days in organ culture was studied. 3. Cyclic AMP content in the tissue reached a maximum in 5-15min and then decreased. This may have been partly due to an inhibitor of glucagon action formed in the tissue. Small amounts of cyclic AMP were released into the incubation medium. 4. The maximal increase in cyclic AMP content produced by glucagon decreased over 6 days in culture. However, liver pieces cultured for 2 and 6 days were more sensitive to low concentrations of glucagon than were fresh liver pieces. Glucagon concentrations for half-maximal effects were approx. 1mum and 0.05mum for fresh liver and 2-day cultured liver respectively. 5. Insulin (3.5mum) lowered the cyclic AMP content by 30% in the presence of a submaximal glucagon concentration in liver cultured for 2 days. No effect of insulin was demonstrated on fresh liver pieces. 6. Insulin and glucagon were rapidly destroyed by fresh liver pieces.     

The role of adenosine 3′:5′-cyclic monophosphate in the regulation of insulin release by isolated rat islets of Langerhans

1. Concentrations of cyclic AMP (adenosine 3':5'-cyclic monophosphate) and rates of insulin release were measured in islets of Langerhans isolated from rat pancreas and incubated for various times in the presence of glucose, 3-isobutyl-1-methylxanthine, caffeine, theophylline, adrenaline and diazoxide. 2. Caffeine and theophylline produced small but significant increases in both cyclic AMP and release of insulin when they were incubated in the presence of 10mm-glucose. 3. 3-Isobutyl-1-methylxanthine produced a marked increase in the intracellular concentration of cyclic AMP in the presence of 5mm- and 10mm-glucose. However, insulin release was stimulated only in the presence of 10mm-glucose. 4. In response to rising concentrations of extracellular glucose (5-20mm) there was no detectable increase in the intracellular concentration of cyclic AMP even though there was a marked increase in the rate of insulin release. 5. In response to 10mm-glucose insulin release occurred in two phases and 3-isobutyl-1-methylxanthine potentiated the effect of glucose on both phases. The intracellular concentration of cyclic AMP remained constant with glucose and rose within 10min to its maximum value with 3-isobutyl-1-methylxanthine. 6. Adrenaline and diazoxide inhibited insulin release and lowered the intracellular concentration of cyclic AMP when islets were incubated with glucose or 3-isobutyl-1-methylxanthine. 7. It is suggested that glucose does not stimulate insulin release by increasing the concentration of cyclic AMP in islet cells. However, the concentration of cyclic AMP in islet cells may modulate the effect of glucose on the release process.     

Involvement of adenosine 3′:5′-cyclic monophosphate in lipid mobilization in Locusta migratoria

The rôle of cyclic AMP in hormone-induced lipid mobilization in Locusta migratoria was investigated. Injection of a corpus cardiacum extract into adult female locusts resulted in an increased level of cyclic AMP in the fat body. The cAMP concentration is maximal at about 5 min of incubation and returns to the resting level after about 10 min. The dose-response curve is linear up to about 0.01 corpus cardiacum pair equivalents.Dibutyryl-cyclic AMP mimics the lipid mobilizing effect of corpus cardiacum extract. After flight the cyclic AMP concentration in fat body increased. Injection of corpus cardiacum extract had no effect on flight muscle cyclic AMP concentration.     

Direct effects of adenosine 3′,5′-cyclic monophosphate and adenosine 5′-monophosphate upon tyrosinase activity

1. The direct actions of cAMP and 5′-AMP upon goldfish integumental and mushroom tyrosine activity were examined.2. cAMP and 5′-AMP produce similar alterations in goldfish enzyme activity, being stimulatory at low concentrations (5′-AMP being more effective than cAMP) and inhibitory at high concentrations.3. Theophylline stimulates goldfish tyrosinase activity.4. Mushroom tyrosinase activity is inhibited by cAMP and by theophylline.5. cAMP and 5′-AMP stimulation of goldfish tyrosinase activity may result from the direct action of these nucleotides on the enzyme in addition to cAMP stimulation of cAMP-dependent protein kinase.6. 5′-AMP stimulation of goldfish tyrosinase activity may indicate a key regulatory role of this nucleotide in cAMP-mediated events.     

Some properties of adenosine 3′,5′-cyclic monophosphate phosphodiesterase in the superior cervical ganglion of the guinea pig

Adenosine 3,5-cyclic monophosphate (cAMP) phosphodiesterase activity in crude guinea-pig superior cervical ganglion homogenates was assayed under a variety of experimental conditions. Two forms of cAMP phosphodiesterase were found, one with high and the other with low affinity for the substrate. TheK _m values were about 1 and 110 M respectively. Imidazole slightly but constantly stimulated the former enzyme form over a wide range of concentrations and l-methyl-3-isobutylxanthine was a weak competitive inhibitor with aK _i value of 90 M. Low affinity cAMP phosphodiesterase activity was increased by calmodulin and Ca²⁺. This stimulation was not observed in the presence of trifluoperazine, a specific inhibitor of calmodulin. On the other hand, neither [d-Ala²]met-enkephalinamide nor prostaglandin E₂, alone or in combination, influenced high affinity cAMP phosphodiesterase.     

Synthesis and release of adenosine 3′: 5′-cyclic monophosphate by Chlamydomonas reinhardtii

One of the labeled compounds synthesized by Chlamydomonas reinhardtii when ³²Pi was supplied was isolated from both the cells and the medium in which the cells had grown. This compound copurified with authentic [8-³H]cAMP by TLC to a constant ratio of ³²P/³H. The compound was degraded by beef heart cyclic nucleotide phosphodiesterase to a product which cochromatographed with authentic 5′AMP, at the same rate as the hydrolysis of authentic cAMP-[³H] to 5′AMP-[³H]. In both cases, 1-Me-3-isoBu-xanthine, a specific inhibitor of the phosphodiesterase, totally blocked the reaction. It is concluded that the compound synthesized by C. reinhardtii was cAMP, 85% of which was released into the medium.     

Binding proteins for adenosine 3′:5′-cyclic monophosphate in bovine adrenal cortex

Five peaks of cyclic AMP-binding activity could be resolved by DEAE-cellulose chromatography of bovine adrenal-cortex cytosol. Two of the binding peaks co-chromatographed with the catalytic activities of cyclic AMP-dependent protein kinases (ATP-protein phosphotransferase, EC 2.7.1.37) of type I or type II respectively. A third binding protein was eluted between the two kinases, and appeared to be the free regulatory moiety of protein kinase I. Two of the binding proteins for cyclic AMP, sedimenting at 9S in sucrose gradients, could also bind adenosine. They bound cyclic AMP with an apparent equilibrium dissociation constant (K(d)) of about 0.1mum, and showed an increased binding capacity for cyclic AMP after preincubation in the presence of K(+), Mg(2+) and ATP. The two binding proteins differed in their apparent affinities for adenosine. The isolated regulatory moiety of protein kinase I had a very high affinity for cyclic AMP (K(d)<0.1nm). At low ionic strength or in the presence of MgATP, the high-affinity binding of cyclic AMP to the regulatory subunit of protein kinase I was decreased by the catalytic subunit. At high ionic strength and in the absence of MgATP the high-affinity binding to the regulatory subunit was not affected by the presence of catalytic subunit. Under all experimental conditions tested, dissociation of protein kinase I was accompanied by an increased affinity for cyclic AMP. To gain some insight into the mechanism by which cyclic AMP activates protein kinase, the interaction between basic proteins, salt and the cyclic nucleotide in activating the kinase was studied.     

The relationship between the concentration of adenosine 3′:5′-cyclic monophosphate and the anti-lipolytic action of insulin in isolated rat fat-cells

The relationship between cyclic AMP content and lipolysis, as measured by glycerol formation, was studied in isolated rat fat-cells. Inhibition of lipolysis by insulin in the presence of a low concentration of adrenaline was accompanied by little or no lowering of cyclic AMP content, measured after 15min incubation. The time-course of cyclic AMP content after addition of adrenaline showed that the effect of insulin in lowering cyclic AMP content measured after 2-5min was gradually lost over the next hour, mainly because of the fall in cyclic AMP content after an early peak in the presence of adrenaline alone. There was a 44% loss of immunoreactive insulin, from an initial concentration of 0.3nm, during a 1h incubation with fat-cells. Insulin did not affect partitioning of cyclic AMP between cells and incubation medium. When the correlation between cyclic AMP content and rate of lipolysis was investigated for a wide range of adrenaline concentrations, it was found that the lowering of cyclic AMP content by insulin was much less than that required to account for the amount of inhibition of lipolysis. It is concluded that inhibition of adrenaline-stimulated lipolysis by insulin involves factors in addition to a decrease in intracellular cyclic AMP concentration.     

The mode of action of adenosine 3′:5′-cyclic monophosphate in mammalian islets of Langerhans. Effects of insulin secretagogues on islet-cell protein kinase activity

1. Protein kinase activity was measured in islets of Langerhans that had been incubated in the presence of agents known to affect insulin release. 2. Glucagon, theophylline, caffeine and 3-isobutyl-1-methylxanthine, agents that raise cyclic AMP concentrations in islet cells and stimulate insulin release, increased protein kinase activity. Adrenaline and diazoxide, agents that decrease cyclic AMP concentrations and inhibit insulin secretion, decreased the activity. 3. The increase in protein kinase activity produced by different concentrations of 3-isobutyl-1-methylxanthine was apparently related to the increase in intracellular concentrations of cyclic AMP. 4. The sulphonylureas, tolbutamide and glibenclamide, agents that increase insulin release, also increased the protein kinase activity; however, leucine, arginine and xylitol, which also stimulate insulin release, were without effect on the kinase activity. 5. Increasing the glucose concentration of the incubation medium from 2 to 20mm had no effect on protein kinase activity. Further, the ability of 3-isobutyl-1-methylxanthine to increase the protein kinase activity was not affected by the glucose concentration of the incubation medium. 6. These results suggest that agents which affect insulin secretion by altering cyclic AMP concentrations may exert their effects on hormone release by altering the activity of a cyclic AMP-dependent protein kinase in islet cells.     

The influence on platelet aggregation of drugs that affect the accumulation of adenosine 3′:5′-cyclic monophosphate in platelets

1. The involvement of intracellular 3':5'-cyclic AMP in the inhibition of platelet aggregation by prostaglandin E(1), isoprenaline and adenosine has been examined by a radiochemical technique. Platelet-rich plasma was incubated with radioactive adenine to incorporate (14)C radioactivity into platelet nucleotides. Pairs of identically treated samples were taken, one for the photometric measurement of platelet aggregation induced by ADP, the other for estimation of the radioactivity of 3':5'-cyclic AMP. 2. Theophylline, papaverine, dipyridamole and 2,6-bis-(diethanolamino)-4-piperidinopyrimido[5,4d]pyrimidine (compound RA233) were found to inhibit 3':5'-cyclic AMP phosphodiesterase from platelets. At concentrations of 3':5'-cyclic AMP greater than 50mum the most active inhibitor was dipyridamole; at 3':5'-cyclic AMP concentrations less than 19mum, papaverine and compound RA233 were more active than dipyridamole. 3. In the presence of compound RA233 (50mum), the effectiveness of prostaglandin E(1) as an inhibitor of platelet aggregation was increased tenfold. Compound RA233 also increased the stimulation by prostaglandin E(1) of the incorporation of radioactivity into 3':5'-cyclic AMP. 4. Compound RA233 (50mum) increased the effectiveness of both adenosine and 2-chloroadenosine as inhibitors of aggregation by 70-100-fold, and in the presence of compound RA233 both adenosine and 2-chloroadenosine stimulated the incorporation of radioactivity into 3':5'-cyclic AMP; the extent of the stimulation was proportional to the logarithm of the nucleoside concentration. 5. Compound RA233 (100-500mum) inhibited platelet aggregation by itself and caused small increases in the radioactivity of 3':5'-cyclic AMP. Partial positive correlations were found between the radioactivity of 3':5'-cyclic AMP in platelets measured at the time of addition of the aggregating agent (ADP) and the extent to which the aggregation was inhibited. 6. The results are interpreted as indicating that adenosine, 2-chloroadenosine, isoprenaline, prostaglandin E(1) and drugs that inhibit platelet 3':5'-cyclic AMP phosphodiesterase all inhibit aggregation by a common mechanism involving intracellular 3':5'-cyclic AMP.     

Regulation of renal gluconeogenesis by calcium ions, hormones and adenosine 3′:5′-cyclic monophosphate

1. The effect of Ca(2+), glucagon, adrenaline and adenosine 3':5'-cyclic monophosphate on gluconeogenesis by rat kidney-cortex slices was studied. 2. Glucose formation from a range of substrates, with the exception of glycerol, was increased by an increase in extracellular Ca(2+) concentration. 3. Hormones and adenosine 3':5'-cyclic monophosphate, at low Ca(2+) concentrations, stimulated glucose production from several substrates, but not from glycerol, fructose, malate or fumarate. 4. Hormonal stimulation was not detected in the absence of Ca(2+) or at 2.5mm-Ca(2+). 5. Ca(2+), hormones and adenosine 3':5'-cyclic monophosphate had no effect on phosphoenolpyruvate carboxylase activity. 6. It is proposed that Ca(2+) and adenosine 3':5'-cyclic monophosphate-mediated hormone action activate the same rate-limiting step in gluconeogenesis: this step is tentatively identified as the rate of transfer of substrates across the mitochondrial membrane.     

The action of local anaesthetics on lipolysis and on adenosine 3′:5′-cyclic monophosphate content in isolated rat fat-cells

1. Local anaesthetics inhibited hormone-stimulated lipolysis in isolated rat fat-cells. The most potent anaesthetic was dibucaine, which inhibited adrenaline-stimulated lipolysis by 50% at a concentration of 0.16mm. 2. The amount of inhibition produced by a given concentration of anaesthetic was very similar with adrenaline, theophylline and dibutyryl cyclic AMP, at submaximal and maximal concentrations. 3. The inhibitory effect of dibucaine on lipolysis was apparent within 5 min and was constant over 1h. 4. Dibucaine inhibited basal, adrenaline-stimulated and insulin-stimulated glucose uptake at concentrations 6-10-fold higher than those inhibiting lipolysis. 5. The effects of dibucaine on lipolysis and glucose uptake were reversed after removal of anaesthetic and washing of cells. 6. Dibucaine further elevated the concentration of cyclic AMP in the presence of adrenaline or adrenaline plus theophylline. 7. Dibucaine had no effect on ATP content at concentrations causing 80% inhibition of lipolysis, but lowered ATP content at higher concentrations. 8. The relative potency of different local anaesthetics as inhibitors of hormone-stimulated lipolysis paralleled their potency as inhibitors of ion movements in other systems. 9. The possibility is discussed that Ca(2+) ions are involved in the regulation of lipolysis, and that local anaesthetics inhibit lipolysis by interfering with Ca(2+) translocation.     

Regulation of heparan sulphate metabolism by adenosine 3′:5′-cyclic monophosphate in hepatocytes in culture

Freshly isolated rat hepatocytes maintained as monolayers in a serum-free medium synthesize sulphated glycosaminoglycans, most of which behave as heparan sulphate and are mainly distributed into intracellular compartments. Cyclic AMP, dibutyryl cyclic AMP, glucagon, noradrenaline, prostaglandin E(1), and theophylline, all drugs and hormones known to increase intracellular cyclic AMP concentrations, decreased the incorporation of (35)SO(4) (2-) into heparan sulphate of intra-, extra- and peri-cellular pools. The inhibition mediated by dibutyryl cyclic AMP was dose-dependent and observed as early as 2h after exposure to the drug. In the presence of 1mm-dibutyryl cyclic AMP, incorporation of (35)SO(4) (2-) or [(14)C]glucosamine into heparan sulphate was decreased to 40-50%, suggesting that dibutyryl cyclic AMP interfered with the synthesis of heparan sulphate. This was further supported by pulse-chase experiments, where dibutyryl cyclic AMP had no effect on the degradation of sulphated glycosaminoglycans. Heparan sulphates synthesized and secreted into the extracellular pool in the presence of dibutyryl cyclic AMP were smaller in size, whereas the degree of sulphation and molecular size of the heparan sulphate chains released by beta-elimination from these proteoglycans were not different from control values. In the presence of 1mm-cycloheximide, (35)SO(4) (2-) incorporation was decreased to 5%. Addition of p-nitrophenyl beta-d-xyloside, an artificial acceptor of glycosaminoglycan chain synthesis, enhanced this incorporation to 18%. Dibutyryl cyclic AMP did not have any inhibitory effect on the synthesis of chains initiated on p-nitrophenyl beta-d-xylosides. Incorporation of [(3)H]serine into heparan sulphate was not affected by dibutyryl cyclic AMP, whereas the degree of substitution of serine residues with heparan sulphate chains was less in heparan sulphate synthesized in the presence of dibutyryl cyclic AMP, suggesting that cyclic AMP exerts its effect on the metabolism of sulphated glycosaminoglycans by affecting the transfer of xylose on to the protein core.     

Stimulation of glucose transport in rat adipocytes by insulin, adenosine, nicotinic acid and hydrogen peroxide. Role of adenosine 3′:5′-cyclic monophosphate

Glucose transport into adipocytes of the rat was measured by monitoring the conversion of [1-(14)C]glucose into (14)CO(2). Glucose transport was made rate-limiting by increasing the flux through the pentose phosphate pathway with phenazine methosulphate, an agent that rapidly reoxidizes NADPH. Under these conditions, the observed rate of glucose disappearance from the incubation medium was about 20% higher than the rate of conversion of the C-1 of glucose into (14)CO(2). Apparent rates of glucose transport were significantly increased by insulin, H(2)O(2), adenosine and nicotinic acid. Stimulation of the apparent rate of glucose transport by insulin was dependent on adipocyte concentration, the hormone being most effective at relatively high cell concentrations. Adenosine and nicotinic acid further enhanced the maximum stimulation of glucose transport by insulin. Potentiation of insulin action by adenosine was more pronounced at lower cell concentrations. At relatively high cell concentrations the stimulatory action of insulin was markedly decreased by adenosine deaminase. Stimulation of apparent rates of glucose transport by the compounds noted above were antagonized by agents that increased intracellular cyclic AMP concentrations (theophylline and isoprenaline) and by dibutyryl cyclic AMP. Intracellular concentrations of cyclic AMP were significantly lowered when adipocytes were incubated with insulin, H(2)O(2), adenosine or nicotinic acid. These effects were observed under basal conditions or when intracellular cyclic AMP concentrations were elevated by theophylline or isoprenaline. On the basis of the above data, we suggest that insulin, H(2)O(2), adenosine and nicotinic acid may all stimulate glucose transport in rat adipocytes by lowering the intracellular cyclic AMP concentration. These data therefore support the hypothesis that cyclic AMP inhibits glucose transport in rat adipocytes.     

A reappraisal of the effects of adenosine 3′:5′-cyclic monophosphate on the function and morphology of the rat prostate gland

1. A comparison was made of the binding of 5alpha-dihydrotestosterone (17beta-hydroxy-5alpha-androstan-3-one) and cyclic AMP in the rat prostate gland. Distinct binding mechanisms exist for these compounds, and cyclic AMP cannot serve as a competitor for the 5alpha-dihydrotestosterone-binding sites and vice versa. In contrast with the results obtained with 5alpha-dihydrotestosterone, very small amounts of cyclic AMP are retained in nuclear chromatin and the overall binding of this cyclic nucleotide is not markedly affected by castration. 2. Androgenic stimulation does not lead to major increases in the adenylate cyclase activities associated with any subcellular fraction of the prostate gland. Accordingly, changes in the concentration of cyclic AMP in the prostate gland after hormonal treatment are likely to be small, but these were not measured directly. 3. When administered to whole animals in vivo, small amounts of non-degraded cyclic AMP are found in the prostate gland but sufficient to promote an activation of certain carbohydrate-metabolizing enzymes in the cell supernatant fraction. The stimulatory effects of cyclic AMP were not evident with cytoplasmic enzymes engaged in polyamine synthesis or nuclear RNA polymerases. These latter enzymes were stimulated solely by the administration of testosterone. 4. By making use of antiandrogens, a distinction can be drawn between the biochemical responses attributable to the binding of 5alpha-dihydrotestosterone but not of cyclic AMP. Evidence is presented to suggest that the stimulation of RNA polymerase, ornithine decarboxylase and S-adenosyl-l-methionine decarboxylase is a consequence of the selective binding of 5alpha-dihydrotestosterone. Only the stimulation of glucose 6-phosphate dehydrogenase can be attributed to cyclic AMP or other metabolites of testosterone. 5. Overall, this study indicates that the formation of cyclic AMP is not a major feature of the androgenic response and affects only a restricted number of biochemical processes. Certainly, cyclic AMP cannot be considered as interchangeable with testosterone and its metabolites in the control of the function of the prostate gland. This difference is additionally emphasized by the failure of cyclic AMP to restore the morphology of the prostate gland in castrated animals; morphological restoration only follows the administration of androgens.