Stimulation of glycogenolysis by adenine nucleotides in the perfused rat liver.

Infusion of adenine nucleotides and adenosine into perfused rat livers resulted in stimulation of hepatic glycogenolysis, transient increases in the effluent perfusate [3-hydroxybutyrate]/[acetoacetate] ratio, and increased portal vein pressure. In livers perfused with buffer containing 50 microM-Ca2+, transient efflux of Ca2+ was seen on stimulation of the liver with adenine nucleotides or adenosine. ADP was the most potent of the nucleotides, stimulating glucose output at concentrations as low as 0.15 microM, with half-maximal stimulation at approx. 1 microM, and ATP was slightly less potent, half-maximal stimulation requiring 4 microM-ATP. AMP and adenosine were much less effective, doses giving half-maximal stimulation being 40 and 20 microM respectively. Non-hydrolysed ATP analogues were much less effective than ATP in promoting changes in hepatic metabolism. ITP, GTP and GDP caused similar changes in hepatic metabolism to ATP, but were 10-20 times less potent than ATP. In livers perfused at low (7 microM) Ca2+, infusion of phenylephrine before ATP desensitized hepatic responses to ATP. Repeated infusions of ATP in such low-Ca2+-perfused livers caused homologous desensitization of ATP responses, and also desensitized subsequent Ca2+-dependent responses to phenylephrine. A short infusion of Ca2+ (1.25 mM) after phenylephrine infusion restored subsequent responses to ATP, indicating that, during perfusion with buffer containing 7 microM-Ca2+, ATP and phenylephrine deplete the same pool of intracellular Ca2+, which can be rapidly replenished in the presence of extracellular Ca2+. Measurement of cyclic AMP in freeze-clamped liver tissue demonstrated that adenosine (150 microM) significantly increased hepatic cyclic AMP, whereas ATP (15 microM) was without effect. It is concluded that ATP and ADP stimulate hepatic glycogenolysis via P2-purinergic receptors, through a Ca2+-dependent mechanism similar to that in alpha-adrenergic stimulation of hepatic tissue. However, adenosine stimulates glycogenolysis via P1-purinoreceptors and/or uptake into the cell, at least partially through a mechanism involving increase in cyclic AMP. Further, the hepatic response to adenine nucleotides may be significant in regulating hepatic glucose output in physiological and pathophysiological states.     

The deposition of calcium pyrophosphate by NTP pyrophosphohydrolase of matrix vesicles from fetal bovine epiphyseal cartilage

About 5 mumol CaPPi/mg protein was deposited within 3 h in the presence of the reaction mixtures containing 1 mM ATP, 2 mM Ca2+, 1 mM Pi, and 17 micrograms of purified NTP pyrophosphohydrolase. At 1 mM ATP, 50% of the deposition was inhibited by 0.5-1 mM of various substrate and product analogues including AMP, ADP, and ethylene hydroxyl diphosphonate. The magnitude of inhibition on NTP pyrophosphohydrolase activity was in the order of AMP = CMP = ADP greater than adenosine greater than adenine greater than NAD = NADP. AMP, CMP, ADP, and adenosine are competitive inhibitors. The modes of inhibition by adenine, NAD, and NADP differ from the competitive inhibition. Ribose, 3'-AMP, 2'-AMP, and cAMP did not inhibit the enzyme activity.     

Growth inhibition of transformed mouse fibroblasts by adenine nucleotides occurs via generation of extracellular adenosine

The growth of transformed mouse fibroblasts (3T6 cells) in medium containing 5% fetal bovine serum was inhibited after treatment with concentrations greater than 50 microM ATP, ADP, or AMP. Adenosine, the common catabolite of the nucleotides, had no effect on cell growth at concentrations below 1 mM. However, the following results indicate that the toxicity of ATP, ADP, and AMP is mediated by serum- and cell-associated hydrolysis of the nucleotides to adenosine. 1) ADP and AMP, but not ATP, were toxic to 3T6 cells grown in serum-free medium or medium in which phosphohydrolase activity of serum was inactivated. Under these conditions, the cells exhibited cell-associated ADPase and 5'-nucleotidase activity, but little ecto-ATPase activity. 2) Inhibition of adenosine transport in 3T6 cells by dipyridamole or S-(p-nitrobenzyl)-6-thioinosine prevented the toxicity of ATP in serum-containing medium and of ADP and AMP in serum-free medium. 3) A 16-24-h exposure to 125 microM AMP or ATP was needed to inhibit cell growth under conditions where serum- and cell-associated hydrolysis of the nucleotides generated adenosine in the medium continuously over the same time period. In contrast, 125 microM adenosine was completely degraded to inosine and hypoxanthine within 8-10 h. Furthermore, multiple doses of adenosine added to the cells at regular intervals over a 16-h period were significantly more toxic than an equivalent amount of adenosine added in one dose. Treatment of 3T6 cells with AMP elevated intracellular ATP and ADP levels and reduced intracellular UTP levels, effects which were inhibited by extracellular uridine. Uridine also prevented growth inhibition by ATP, ADP, and AMP. These and other results indicate that serum- and cell-associated hydrolysis of adenine nucleotides to adenosine suppresses growth by adenosine-dependent pyrimidine starvation.     

Inhibition by adenine compounds of the induced formation of photosynthetic pigments in Rhodopseudomonas spheroides cells under dark-semiaerobic conditions

Effects of adenine, adenosine, AMP, ADP and ATP on the inducedformation of bacteriochlorophyll and carotenoids in cell suspensionsof dark-aerobically grown Rhodopseudomonas spheroides were examinedunder dark-semiaerobic conditions where no significant cellgrowth occurred. Pigment formation was strongly inhibited by3 mM adenine, adenosine, AMP or ATP, but less strongly by ADP.Inhibition by either adenosine or ATP was completely reversible.Addition of 3 mM adenosine resulted in complete inhibition ofpigment formation, while inhibition by more than 10 min ATPdid not exceed 80%. No accumulation of any precursor-like pigmentsof either bacteriochlorophyll or carotenoids was observed incells incubated in the presence of adenine compounds. Amountsof exogenously-added adenine, adenosine, or AMP decreased significantlyduring incubation, whereas the amount of exogeneously-addedATP or ADP did not appreciably decrease. Addition of 3 mM ATPor adenosine also significantly suppressed ³H-leucine incorporationinto bacterial proteins. Nucleosides other than adenosine wereineffective in inhibiting the induced formation of photosyntheticpigments, indicating that the inhibitory action is specificto adenine compounds. It was assumed that both adenosine andATP inhibit chromatophore formation rather than a particularstep(s) in the biosynthetic pathways of the photosynthetic pigment,and that ATP exerts its effect from outside the cells, whereasadenosine does so after being taken up by the cells. (Received July 24, 1972; )     

In vitro effect of homocysteine on nucleotide hydrolysis by blood serum from adult rats

During the past few years, elevated blood levels of homocysteine (Hcy) have been linked to increased risk of premature coronary artery disease, stroke and thromboembolism. These processes can be also related to the ratio adenine nucleotide/adenosine, since extracellularly these nucleotides are associated with modulation of processes such as platelet aggregation, vasodilatation and coronary flow. Furthermore, there are some studies that suggest a relationship between Hcy and plasma adenosine concentrations. The sequential hydrolysis of ATP to adenosine by soluble nucleotidases constitutes one of the systems for rapid inactivation of circulating adenine nucleotides. Thus, the main objective of this study was to evaluate if Hcy can participate in the modulation of the extracellular adenine nucleotide hydrolysis by rat blood serum. Our results showed that Hcy, at final concentrations of 5.0 mM, inhibits in vitro ATP, ADP and AMP hydrolysis by 26, 21 and 16%, respectively. Also Hcy, at final concentrations of 8.0mM, inhibited the in vitro hydrolysis of ATP, ADP and AMP by 46, 44 and 44%, respectively. Kinetic analysis showed that the inhibitions of the three adenine nucleotide hydrolyses in the presence of Hcy, by serum of adult rats, is of the uncompetitive type. The IC50 calculated from the results obtained were 6.52+/-1.75 mM (n = 4), 5.18 +/- 0.64 mM (n = 3) and 5.16 +/- 1.22 mM (n = 3) for ATP, ADP and AMP hydrolysis, respectively.     

Adenine nucleotide metabolism in Azotobacter vinelandii. Two metabolic pathways of AMP degradation

AMP-degrading pathways in Azotobacter vinelandii cells were investigated. AMP nucleosidase (EC 3.2.2.4) was rapidly synthesized and reached a maximum at 24 h, while the activity of 5-nucleotidase (EC 3.1.3.5) specific for AMP, which was negligible during the logarithmic phase of the growth, first appeared in 24 h-cultures, and reached a maximum after complete exhaustion of sucrose from the growth medium (70 h).Cell-free extracts of A. vinelandii of 48 h-cultures hydrolyzed AMP to ribose 5-phosphate and adenine in the presence of ATP, and adenine was deaminated to hypoxanthine. When ATP was excluded, AMP was dephosphorylated to adenosine, which was further metabolized to inosine, and finally to hypoxanthine. Hypoxanthine thus formed was reutilized for the salvage synthesis of IMP under the conditions where 5-phosphoribosyl 1-pyrophosphate was able to be supplied. These results suggest that the levels of ATP can determine the rate of AMP degradation by the AMP nucleosidase- and 5-nucleotidase-pathways. The role of ATP in the AMP degradation was discussed in relation to the regulatory properties of AMP nucleosidase, inosine nucleosidase (EC 3.2.2.2) and adenosine deaminase (EC 3.5.4.4).     

The rate of the AMP/adenosine substrate cycle in concanavalin-A-stimulated rat lymphocytes.

The effect of adenosine on the metabolism of prelabelled adenine nucleotides was investigated in concanavalin-A-stimulated rat lymphocytes. Adenosine in the presence of the adenosine deaminase inhibitor, deoxycoformycin, caused a 2-fold increase in the ATP concentration. This effect was, in part, countereacted by an increased rate of adenine nucleotide catabolism, which could be explained by a stimulation of AMP deaminase (EC 3.5.4.6). At the same time a continuous rate of labelled adenosine production was found, which was not affected by the increased ATP concentration and which could only be detected by the trapping effect of a high concentration of added unlabelled adenosine. It is concluded that the rate of the substrate cycle between AMP and adenosine is low (1.9 +/- 0.2 nmol/h per 10(7) cells) in comparison to the rate of AMP deamination.     

Accelerated degradation of adenine nucleotide in erythrocytes of patients with chronic renal failure

Recently, we have shown that erythrocytes obtained from patients with chronic renal failure (CRF) exhibited an increased rate of ATP formation from adenine as a substrate. Thus, we concluded that this process was in part responsible for the increase of adenine nucleotide concentration in uremic erythrocytes. There cannot be excluded however, that a decreased rate of adenylate degradation is an additional mechanism responsible for the elevated ATP concentration. To test this hypothesis, in this paper we compared the rate of adenine nucleotide breakdown in the erythrocytes obtained from patients with CRF and from healthy subjects.Using HPLC technique, we evaluated: (1) hypoxanthine production by uremic RBC incubated in incubation medium: (a) pH 7.4 containing 1.2 mM phosphate (which mimics physiological conditions) and (b) pH 7.1 containing 2.4 mM phosphate (which mimics uremic conditions); (2) adenine nucleotide degradation (IMP, inosine, adenosine, hypoxanthine production) by uremic RBC incubated in the presence of iodoacetate (glycolysis inhibitor) and EHNA (adenosine deaminase inhibitor). The erythrocytes of healthy volunteers served as control.The obtained results indicate that adenine nucleotide catabolism measured as a hypoxanthine formation was much faster in erythrocytes of patients with CRF than in the cells of healthy subjects. This phenomenon was observed both in the erythrocytes incubated at pH 7.4 in the medium containing 1.2 mM inorganic phosphate and in the medium which mimics hyperphosphatemia (2.4 mM) and metabolic acidosis (pH 7.1). The experiments with EHNA indicated that adenine nucleotide degradation proceeded via AMP-IMP-Inosine-Hypoxanthine pathway in erythrocytes of both patients with CRF and healthy subjects. Iodoacetate caused a several fold stimulation of adenylate breakdown. Under these conditions: (a) the rate of AMP catabolites (IMP + inosine + adenosine + hypoxanthine) formation was substantially higher in the erythrocytes from patients with CRF; (b) in erythrocytes of healthy subjects degradation of AMP proceeded via IMP and via adenosine essentially at the same rate; (c) in erythrocytes of patients with CRF the rate of AMP degradation via IMP was about 2 fold greater than via adenosine.The results presented in this paper suggest that adenine nucleotide degradation is markedly accelerated in erythrocytes of patients with CRF.     

Adenylate kinase of plants. Properties of adenylate kinase of pea leaves]

The properties of adenylate kinase in 2 ADP in equilibrium ATP + AMP reaction have been studied. The dependence of the enzyme activity on medium pH, protein concentration, substrates, Mg++ ions, AMP, adenine and adenosine has been also investigated. pH optimum is found to be 8.5 for forward reaction and 8-9--for the reverse one. The Michaelis constants are as follows: for ADP--1.17-10(-4) M, for ATP--3.33-10(-4) M at 24 degrees C, in 50 mM tris-HCl pH 7.6. The optimal ratio, Mg++ ions/substrates (ADP, ATP + AMP), is 1:2. The chelates of adenine nucleotides with Mg++ ions are proved to be "true" reaction substrates. Unlike adenine and adenosine, the product of AMP reaction inhibits adenylate kinase activity. It is concluded that the properties of adenylate kinase in plants are similar to those of animals and humans (moikinase).     

Relation of tegumentary phosphohydrolase to purine and pyrimidine transport in Schistosoma mansoni.

Inhibition of the saturable influx of 0.05 mM 14C-labeled adenine or adenosine by AMP in adult Schistosoma mansoni in vitro suggested hydrolysis of this nucleotide at the tegumental surface of the parasite. Adenosine liberated as a result of AMP hydrolysis was the inhibitor of uptake of labeled adenine or adenosine. Inhibition of adenosine uptake by AMP or ATP was relieved by paranitrophenyl phosphate or ammonium molybdate supporting the hypothesis of nucleotide hydrolysis at the tengumental surface. Addition of glucose-1-phosphate, glucose-6-phosphate, NaF, or cysteine did not relieve AMP inhibition of adenosine uptake indicating substrate and inhibitor specificity for the surface enzyme(s). AMP, ATP, UMP, and p-nitrophenyl are hydrolyzed, at least in part, by the same enzyme(s). Apparent absorption of labeled AMP was preceded by hydrolysis, with labeled adenosine as the actual compound absorbed, although there was a small diffusion component for absorption of intact AMP. The site of nucleotide hydrolysis in close proximity to absorption sites provides a kinetic advantage for uptake of products of adenine nucleotide hydrolysis but not for products of uracil nucleotide hydrolysis.     

Nucleotide coronary vasodilation in guinea pig hearts

The role of P1 receptors and P2Y1 receptors in coronary vasodilator responses to adenine nucleotides was examined in the isolated guinea pig heart. Bolus arterial injections of nucleotides were made in hearts perfused at constant pressure. Peak increase in flow was measured before and after addition of purinoceptor antagonists. Both the P1 receptor antagonist 8-(p-sulfophenyl)theophylline and adenosine deaminase inhibited adenosine vasodilation. AMP-induced vasodilation was inhibited by P1 receptor blockade but not by adenosine deaminase or by the selective P2Y1 antagonist N6-methyl-2'-deoxyadenosine 3',5'-bisphosphate (MRS 2179). ADP-induced vasodilation was moderately inhibited by P1 receptor blockade and greatly inhibited by combined P1 and P2Y1 blockade. ATP-induced vasodilation was antagonized by P1 blockade but not by adenosine deaminase. Addition of P2Y1 blockade to P1 blockade shifted the ATP dose-response curve further rightward. It is concluded that in this preparation ATP-induced vasodilation results primarily from AMP stimulation of P1 receptors, with a smaller component from ATP or ADP acting on P2Y1 receptors. ADP-induced vasodilation is largely due to P2Y1 receptors, with a smaller contribution by AMP or adenosine acting via P1 receptors. AMP responses are mediated solely by P1 receptors. Adenosine contributes very little to vasodilation resulting from bolus intracoronary injections of ATP, ADP, or AMP.     

Adenosine Receptor Activation and the Regulation of Tyrosine Hydroxylase Activity in PC 12 and PC 18 Cells

We compared the response of rat PC12 cells and a derivative PC18 cell line to the effects of adenosine receptor agonists, antagonists, and adenine nucleotide metabolizing enzymes. We found that theophylline (an adenosine receptor antagonist), adenosine deaminase, and AMP deaminase all decreased basal cyclic AMP content and tyrosine hydroxylase activity in the PC12 cells, but not in PC18 cells. Both cell lines responded to the addition of 2-chloroadenosine and 5'-N-ethylcarboxamidoadenosine, adenosine receptor agonists, by exhibiting an increase in tyrosine hydroxylase activity and cyclic AMP content. The latter finding indicates that both cell lines contained an adenosine receptor linked to adenylate cyclase. We found that the addition of dipyridamole, an inhibitor of adenosine uptake, produced an elevation of cyclic AMP and tyrosine hydroxylase activity in both cell lines. Deoxycoformycin, an inhibitor of adenosine deaminase, failed to alter the levels of cyclic AMP or tyrosine hydroxylase activity. This suggests that uptake was the primary inactivating mechanism of adenosine action in these cells. We conclude that both cell types generated adenine nucleotides which activate the adenosine receptor in an autocrine or paracrine fashion. We found that PC12 cells released ATP in a calcium-dependent process in response to activation of the nicotinic receptor. We also measured the rates of degradation of exogenous ATP, ADP, and AMP by PC12 cells. We found that the rates of metabolism of the former two were at least an order of magnitude greater than that of AMP. Any released ATP would be rapidly metabolized to AMP and then more slowly degraded to adenosine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of deoxyadenosine and nucleoside analog phosphorylation by human placental adenosine kinase

The enzymes responsible for the phosphorylation of deoxyadenosine and nucleoside analogs are important in the pathogenesis of adenosine deaminase deficiency and in the activation of specific anticancer and antiviral drugs. We examined the role of adenosine kinase in catalyzing these reactions using an enzyme purified 4000-fold (2.1 mumol/min/mg) from human placenta. The Km values of deoxyadenosine and ATP are 135 and 4 microM, respectively. Potassium and magnesium are absolute requirements for deoxyadenosine phosphorylation, and 150 mM potassium and 5 mM MgCl2 are critical for linear kinetics. With only 0.4 mM MgCl2 in excess of ATP levels, the Km for deoxyadenosine is increased 10-fold. ADP is a competitive inhibitor with a Ki of 13 microM with variable MgATP2-, while it is a mixed inhibitor with a Ki and Ki' of 600 and 92 microM, respectively, when deoxyadenosine is variable. AMP is a mixed inhibitor with Ki and Ki' of 177 and 15 microM, respectively, with variable deoxyadenosine; it is a non-competitive inhibitor with a Ki of 17 microM and Ki' of 27 microM with variable ATP. Adenosine kinase phosphorylates adenine arabinoside with an apparent Km of 1 mM using deoxyadenosine kinase assay conditions. The Km values for 6-methylmercaptopurine riboside and 5-iodotubercidin, substrates for adenosine kinase, are estimated to be 4.5 microM and 2.6 nM, respectively. Other nucleoside analogs are potent inhibitors of deoxyadenosine phosphorylation, but their status as substrates remains unknown. These data indicate that deoxyadenosine phosphorylation by adenosine kinase is primarily regulated by its Km and the concentrations of Mg2+, ADP, and AMP. The high Km values for phosphorylation of deoxyadenosine and adenine arabinoside suggest that adenosine kinase may be less likely to phosphorylate these nucleosides in vivo than other enzymes with lower Km values. Adenosine kinase appears to be important for adenosine analog phosphorylation where the Michaelis constant is in the low micromolar range.     

Circadian rhythms in Neurospora crassa: oscillation in the level of an adenine nucleotide.

In a mutant strain (bd) of Neurospora, the biological clock is visibly expressed at the growing front of a mycelial mat by sequential periods of conidiating (spore-forming) and non-conidiating growth. The edges (8 mm) of the mycelium at different ages were sampled during a 31 h period, and the adenine nucleotide levels were enzymatically assayed. In the edge region, the total adenosine 5'-monophosphate (AMP) level showed an oscillation, with a minimum of 0.5 mumol/g (residual dry weight) and a maximum of 6.0 mumol/g. The total adenosine 5'-triphosphate level and the total adenosine 5'-diphosphate level showed no obvious oscillation. The oscillation in AMP content had many of the properties of a circadian rhythm. Its period was about 22 h long, it was phase-shifted by light, and it was damped out by continuous illumination. The oscillation in AMP level led to an oscillation in the overall cellular energy charge from 0.65 to 0.93. However, the energy charge calculation does not take into account any possible compartmentalization of AMP, and therefore must be interpretated cautiously. It is suggested that the underlying cause of the oscillation in AMP level could be a rhythmic, partial uncoupling of mitochondrial oxidative phosphorylation.     

A cell wall-bound adenosine nucleosidase is involved in the salvage of extracellular ATP in Solanum tuberosum

Extracellular ATP (eATP) has recently been demonstrated to play a crucial role in plant development and growth. To investigate the fate of eATP within the apoplast, we used intact potato (Solanum tuberosum) tuber slices as an experimental system enabling access to the apoplast without interference of cytosolic contamination. (i) Incubation of intact tuber slices with ATP led to the formation of ADP, AMP, adenosine, adenine and ribose, indicating operation of apyrase, 5'-nucleotidase and nucleosidase. (ii) Measurement of apyrase, 5'-nucleotidase and nucleosidase activities in fractionated tuber tissue confirmed the apoplastic localization for apyrase and phosphatase in potato and led to the identification of a novel cell wall-bound adenosine nucleosidase activity. (iii) When intact tuber slices were incubated with saturating concentrations of adenosine, the conversion of adenosine into adenine was much higher than adenosine import into the cell, suggesting a potential bypass of adenosine import. Consistent with this, import of radiolabeled adenine into tuber slices was inhibited when ATP, ADP or AMP were added to the slices. (iv) In wild-type plants, apyrase and adenosine nucleosidase activities were found to be co-regulated, indicating functional linkage of these enzymes in a shared pathway. (v) Moreover, adenosine nucleosidase activity was reduced in transgenic lines with strongly reduced apoplastic apyrase activity. When taken together, these results suggest that a complete ATP salvage pathway is present in the apoplast of plant cells.     

Transport of AMP by Rickettsia prowazekii.

Rickettsia prowazekii possesses an exchange transport system for AMP. Chromatographic analysis of the rickettsiae demonstrated that transported AMP appeared intracellularly as AMP, ADP, and ATP, and no hydrolytic products appeared in either the intracellular or extracellular compartments. The phosphorylation of AMP to ADP and ATP was prevented by pretreatment of the cells with 1 mM N-ethylmaleimide without inhibiting the transport of AMP. Although no efflux was demonstrable in the absence of nucleotide in the medium, the intracellular adenine nucleotide pool could be exchanged with external unlabeled adenine nucleotides. Both ADP and ATP were as effective as AMP at inhibiting the uptake of [3H]AMP. Although this transport system was inhibited by low temperature (0 degrees C) and partially inhibited by the protonophore carbonyl cyanide-m-chlorophenyl hydrazone (1 mM), it was relatively insensitive to KCN (1 mM). The uptake of AMP at 34 degrees C had an apparent Kt for influx of 0.4 mM and a Vmax of 354 pmol min-1 per mg. At 0 degrees C there was a very rapid and unsaturable association of AMP with these organisms. Correction of the uptake data at 34 degrees C for the 0 degrees C component lowered the apparent Kt to 0.15 mM. Both magnesium and phosphate ions are required for optimal transport activity. Chemical measurements of the total intracellular nucleotide pools demonstrated that this system was not a net adenine nucleotide transport system, but that uptake of AMP was the result of an exchange with internal adenine nucleotides.     

Degradation and resynthesis of adenine nucleotides in adult rat heart myocytes

The degradation and short-term resynthesis of adenine nucleotides have been examined in a preparation of isolated rat heart myocytes. These myocyte preparations are essentially free of vascular and endothelial cells, contain levels of adenine nucleotides quite comparable to those of intact heart tissue, and retain these components remarkably well for up to 2 h of aerobic incubation in the presence of 1 mM Ca2+. When the cells are rapidly and synchronously de-energized by addition of uncoupler, an inhibitor of respiration and iodoacetate, cellular ATP is degraded almost quantitatively to AMP. The AMP is then converted to either intracellular adenosine, which accumulates to high concentrations before release to the cell exterior, or to IMP. The relative contribution of these two pathways depends on the metabolic state of the cells just prior to de-energization, with IMP production favored when respiring cells are de-energized and adenosine formation predominant when glycolyzing myocytes are subjected to this treatment. Cells de-energized by anaerobiosis in the absence of glucose lose ATP and adenine nucleotides with the production of IMP and adenosine. Upon reoxygenation, these cells restore a high adenylate energy charge and about 60% of control levels of GTP. There is a net resynthesis of 5-7 nmol of adenine nucleotides.mg-1 protein with a corresponding decline in IMP. Added [14C]adenosine labels the adenine nucleotide pool, but little net resynthesis of adenine nucleotides via adenosine kinase can be detected. It therefore appears that a rapid regeneration of adenine nucleotides can occur via the enzymes of the purine nucleotide cycle in heart myocytes and is limited by the size of the IMP pool retained.     

Elevation of the adenylate pool in rat cardiomyocytes by S-adenosyl-L-methionine

Rapid resynthesis of the adenylate pool in cardiac myocytes is important for recovery of contractility and normal function of regulatory mechanisms in the heart. Adenosine and adenine are thought to be the most effective substrates for nucleotide synthesis, but the possibility of using other compounds has been studied very little in cardiomyocytes. In the present study, the effect of S-adenosyl-L-methionine (SAM) on the adenylate pool of isolated cardiomyocytes was investigated and compared to the effect of adenine and adenosine. Adult rat cardiomyocytes were isolated using the collagenase perfusion technique. The cells were incubated in the presence of adenine derivatives for 90 min followed by nucleotide determination by HPLC. The concentrations of adenine nucleotides expressed in nmol/mg of cell protein were initially 22.1 +/- 1.4, 4.0 +/- 0.3 and 0.70 +/- 0.08 for ATP, ADP and AMP, respectively (n = 10, +/- S.E.M.), and the total adenylate pool was 26.8 +/- 1.6. In the presence of 1.25 mM SAM in the medium, the adenylate pool increased by 5.2 +/- 0.4 nmol/mg of cell protein, but only if 1 mM ribose was additionally present in the medium. No changes were observed with SAM alone. A similar increase (by 4.9 +/- 0.6 nmol/mg protein) was observed after incubation with 1.25 mM adenine plus 1 mM ribose, but no increase was observed if ribose was omitted. Adenosine at 0.1 or 1.25 mM concentrations also caused an increase in the adenylate pool (by 5.2 +/- 1.0 and 5.2 +/- 0.9 nmol/mg protein, respectively), which in contrast to the SAM or adenine was independent of the additional presence of ribose. Thus, S-adenosyl-L-methionine could be used as a precursor of the adenylate pool in cardiomyocytes, which is as efficient in increasing the adenylate pool after 90 min of incubation as adenosine or adenine. Nucleotide synthesis from SAM involves the formation of adenine as an intermediate with its subsequent incorporation by adenine phosphoribosyltransferase.     

Different relationships between cellular adenosine or 3′-phosphorylation and cellular adenine ribonucleotide catabolism may be obtained

Treatment of BALB/c-3T3 mouse fibroblasts with 3′-led to a rapid accumulation of 3′-phosphates and the kinetics of this process has been determined. Concomitant with accumulation of these compounds, the adenine ribonucleotide pool was reduced. The kinetics of the two processes suggested that they were tightly coupled. The inhibitory effect of relatively high concentrations of coformycin indicated that IMP was an intermediate in the catabolic pathway. Similar experiments with Ehrlich ascites tumor cells were performed in Ringer-Hepes solution at pH 6.5 or 7.5 and with varying concentrations of orthophosphate. The experiments were performed with cells where ATP was [³H]-. This allowed the determination of the catabolism of adenine ribonucleotides to labeled nucleosides under conditions where added adenosine was phosphorylated. The results showed that at low phosphate concentration (5.8 mM) at pH 6.5 adenosine may be phosphorylated at a rate that was completely balanced to the concomitant catabolism of adenine ribonucleotides; that is, there was apparently a tight kinetic coupling between anabolism of adenosine and catabolism of adenine ribonucleotides. With 3′-a corresponding effect was obtained although the apparent coupling between phosphorylation of 3′-and catabolism of adenine ribonucleotides was not complete. When experiments were performed at the same pH but at high concentration of phosphate (45 mM) there was in contrast no coupling between the two processes; that is, ATP was present in constant amounts while 3′-phosphates accumulated at a high rate. In experiments with adenosine under these conditions there was still some although a relatively limited degree of apparent coupling between phosphorylation of adenosine and catabolism of adenine ribonucleotides. In both lines of cells used and with both adenosine and 3′-, the main products of the catabolism of adenine ribonucleotides were inosine and hypoxanthine. With 3′-there was in addition (about 20%) formation of xanthosine, suggesting that IMP dehydrogenase had also been activated. These results lead to the suggestion that adenosine (or 3′-) may be phosphorylated in two ways. 1) Phosphorylation may depend on an adenosine kinase unrelated to catabolism of adenine ribonucleotides. 2) Phosphorylation may be tightly coupled to catabolism of adenine ribonucleotides. A nucleoside phosphotransferase may catalyze the transfer of a phosphoryl group from IMP to adenosine (or 3′-) to form AMP (or 3′-) and inosine, a process that may be tightly coupled to an AMP deaminase reaction. The IMP formed in the latter reaction may not be released but transferred to the phosphotransferase. In contrast, the AMP formed in the phosphotransferase reaction should be in equilibrium with soluble AMP. It is assumed that a physical complex may exist, possibly in a membrane bound form, between AMP deaminase and the nucleoside phosphotransferase. © 1993 Wiley-Liss, Inc.