Adenine nucleotide salvage synthesis in the rat heart; pathways of adnosine salvage

Enzymatic deamination of the epigenetic nucleoside N6-methyladenosine regulates gene expression

N⁶-methyladenosine (m⁶A) modification is the most extensively studied epigenetic modification due to its crucial role in regulating an array of biological processes. Herein, Bsu06560, formerly annotated as an adenine deaminase derived from Bacillus subtilis 168, was recognized as the first enzyme capable of metabolizing the epigenetic nucleoside N⁶-methyladenosine. A model of Bsu06560 was constructed, and several critical residues were putatively identified via mutational screening. Two mutants, F91L and Q150W, provided a superiorly enhanced conversion ratio of adenosine and N⁶-methyladenosine. The CRISPR-Cas9 system generated Bsu06560-knockout, F91L, and Q150W mutations from the B. subtilis 168 genome. Transcriptional profiling revealed a higher global gene expression level in BS-F91L and BS-Q150W strains with enhanced N⁶-methyladenosine deaminase activity. The differentially expressed genes were categorized using GO, COG, KEGG and verified through RT-qPCR. This study assessed the crucial roles of Bsu06560 in regulating adenosine and N⁶-methyladenosine metabolism, which influence a myriad of biological processes. This is the first systematic research to identify and functionally annotate an enzyme capable of metabolizing N⁶-methyladenosine and highlight its significant roles in regulation of bacterial metabolism. Besides, this study provides a novel method for controlling gene expression through the mutations of critical residues.

ATPe Dynamics in Protozoan Parasites. Adapt or Perish

In most animals, transient increases of extracellular ATP (ATPe) are used for physiological signaling or as a danger signal in pathological conditions. ATPe dynamics are controlled by ATP release from viable cells and cell lysis, ATPe degradation and interconversion by ecto-nucleotidases, and interaction of ATPe and byproducts with cell surface purinergic receptors and purine salvage mechanisms. Infection by protozoan parasites may alter at least one of the mechanisms controlling ATPe concentration. Protozoan parasites display their own set of proteins directly altering ATPe dynamics, or control the activity of host proteins. Parasite dependent activation of ATPe conduits of the host may promote infection and systemic responses that are beneficial or detrimental to the parasite. For instance, activation of organic solute permeability at the host membrane can support the elevated metabolism of the parasite. On the other hand ecto-nucleotidases of protozoan parasites, by promoting ATPe degradation and purine/pyrimidine salvage, may be involved in parasite growth, infectivity, and virulence. In this review, we will describe the complex dynamics of ATPe regulation in the context of protozoan parasite⁻host interactions. Particular focus will be given to features of parasite membrane proteins strongly controlling ATPe dynamics. This includes evolutionary, genetic and cellular mechanisms, as well as structural-functional relationships.

Using fructose-1,6-diphosphate during hypothermic rabbit-heart preservation: a high-energy phosphate study

BACKGROUND

In this study, we evaluated the effects of fructose-1,6-diphosphate (FDP) on high-energy phosphate metabolism during 18-hour hypothermic rabbit-heart preservation.

METHODS

Under general anesthesia and artificial ventilation, hearts from 42 adult New Zealand white rabbits were harvested, flushed, and preserved in St. Thomas solution at 4(o)C for 18 hours. In the study group (n = 15), FDP (5 mmol/liter) was added to the St. Thomas solution, whereas in the control group (n = 17), fructose (5 mmol/liter) was added. Another 10 hearts did not undergo hypothermic storage, but were used as the normal group for high-energy phosphate concentration comparison.

RESULTS

After 18 hours of hypothermic preservation, myocardial high-energy phosphate content decreased in both preservation groups. In the study group, left ventricular adenosine triphosphate (ATP) content was 33% of that in the normal hearts, but in the control group, ATP decreased to 14% of normal. Adenosine diphosphate (ADP) content, energy charge, and ATP-to-ADP ratio showed similar decreases. The high-energy phosphate profile (content in the atria and ventricles and the ratio of ATP to ADP to AMP) was maintained in the study group but not in the control group. High-energy phosphate metabolites such as inosine monophosphate (IMP), inosine, and hypoxanthine increased in both preservation groups, but the increase was more prominent in the control group.

CONCLUSION

Adding FDP to St. Thomas solution attenuated the depletion of high-energy phosphate concentration in the preserved hearts. This difference was especially prominent in the left and right ventricles. The protective effect of FDP during hypothermic heart preservation deserves further study.

Ion-exchange column chromatographic method for assaying purine metabolic pathway enzymes

High energy phosphate levels fall rapidly during cardiac ischemia and recover slowly (more than one week) during reperfusion. The slow recovery of ATP may reflect a lack of purine metabolic precursors and/or increased activity of purine catabolic enzymes such as 5'-nucleotidase (5'-NT, EC 3.1.3.5) and adenosine deaminase (ADA, EC 3.5.4.4). The activity of enzymes involved in both the catabolism of ATP precursors (5-NT and ADA) and the restoration of ATP from slow synthetic pathways [adenosine kinase (AK, EC 2.7.1.20), adenine phosphoribosyl transferase (APRT, EC 2.4.2.7) and hypoxanthine phosphoribosyl transferase (HPRT, EC 2.4.2.8)] may directly affect the rate of ATP recovery. Strategies to enhance recovery will depend on the relative activity of these enzymes following ischemia. Their activity in different species and their response to ischemia are not well characterized. Hence, rapid assay methods for these enzymes would facilitate detailed time course studies of their activities in postischemic myocardium. We modified a single ion-exchange column chromatographic method using DEAE-Sephadex to determine the products of incubation of 5'-NT, AK, APRT and HPRT with their respective substrates. The uniformity of the final product measurement procedure for all assays permits the activities of the four enzymes to be rapidly determined in a single tissue sample and facilitates the study of a large number of samples. This technique should also be useful for enzymes of the pyrimidine metabolic pathway.

Age-related changes of AMP breakdown in chicken heart

The activity of adenylate deaminase, adenylate phosphatase and adenosine deaminase, as well as the endogenous content of adenine nucleotides, was examined in the heart of ageing chickens. In new-born (1-day-old) and young (20-day-old) chickens, AMP degradation in the heart seems to proceed preferentially through deamination, while in adult (1-year-old) through dephosphorylation. Compared with the adult heart, a 2-year-old one exhibits a decline of AMP catabolism. The total adenine nucleotide content and the concentration of ATP are higher in adult and aged chicken hearts, than in new-born and young ones. Adaptive mechanisms might occur in the heart of ageing chickens to ensure an adequate availability of adenine nucleotides.

Superior myocardial preservation with modified UW solution after prolonged ischemia in the rat heart

Cardiac transplantation remains constrained by poor graft tolerance of prolonged cold ischemia. University of Wisconsin solution has remarkably extended ischemic preservation in pancreas, kidney, and liver transplantation. To assess its efficacy in cardiac preservation, modified University of Wisconsin solution flush and storage were tested against St. Thomas' cardioplegia flush and normal saline solution storage after six hours of ischemia at 0 degrees C in 46 isolated rat hearts. After ischemia, groups were compared before and after reperfusion. After ischemia but before reperfusion, University of Wisconsin solution hearts had significantly less tissue water (3.8%), superior tissue sodium, potassium, calcium, and magnesium profiles, and elevated adenosine and inosine levels, and tended toward better histological preservation. After reperfusion, University of Wisconsin solution more effectively preserved left ventricular compliance (75% versus 35% of baseline), developed pressure (71% versus 45% of baseline), histological integrity, and tissue potassium and calcium profiles than St. Thomas' solution. The University of Wisconsin solution provided superior preservation of systolic and diastolic ventricular function, tissue histology, tissue water, and tissue electrolytes than did St. Thomas' cardioplegia and normal saline solution storage in this experimental model, and might result in improved graft tolerance of ischemia in clinical cardiac transplantation.

Effects of adenosine perfusion on the metabolism and contractile activity of Rana ridibunda heart

The effects of adenosine were examined on the isolated perfused heart of the frog Rana ridibunda. Adenosine produced negative chronotropic and inotropic effects on frog ventricle in a concentration-dependent manner. The effects of adenosine on cardiac metabolism were also investigated by measuring the tissue content of adenine nucleotides, lactate, pyruvate, adenosine and inorganic phosphate, during adenosine perfusion. Adenosine had no effect on the tissue content of metabolites. No net synthesis of adenine nucleotides was observed during perfusion with increasing concentrations of adenosine. Lactate output from the heart decreased significantly with adenosine perfusion. Correlation of adenosine effects on cardiac muscle with the effects of hypoxia are discussed.

Alterations of purine salvage pathways during differentiation of rat heart myoblasts towards myocytes

Enzyme activities of purine catabolism and salvage, the concentrations of high-energy phosphates and the reutilisation of purine bases and purine nucleosides were studied in rat heart myoblasts and myocytes. Rat heart myoblasts H9c2(2-1) were grown in Dulbecco's modified Eagle's minimum essential medium supplemented with 10% fetal calf serum. Reduction of fetal calf serum to 2% for 1 week resulted in a differentiation into myocytes with respect to their morphological features and their enzyme pattern. In differentiated myocytes, activity of 5'-nucleotidase was increased more than 2-fold, and AMP deaminase and creatine kinase activities were more than 10-fold elevated. The concentration of creatine phosphate in differentiated myocytes was doubled compared to that in myoblasts. The uptake into myoblasts and myocytes and the incorporation into adenine nucleotides was highest using adenosine, inosine and adenine uptake rates were intermediate, and hypoxanthine was utilised least. Differentiation of myoblasts into myocytes resulted in a slightly lower overall uptake of adenosine and adenine, whereas about 40% more inosine and hypoxanthine were utilised by myocytes. Increasing the phosphate concentration in the incubation medium up to 50 mmol/l resulted in a stimulation of uptake of all purine compounds tested. This stimulation was more pronounced in myoblasts.

Myocardial protection

Early studies of myocardial protection were designed to minimize ischemic injury. The next class and generation of investigations will most likely be designed to accelerate recovery following known myocardial injury. Such techniques will play an important role in allowing operations on acutely injured and ischemic myocardium and will be important in the treatment of postischemic injury when such injury occurs during the course of complex cardiac operations. Surgical aspects of myocardial metabolism are still rudimentary and many empiric observations require further exploration into the mechanisms by which such applications work.

Metabolism and salvage of adenine and hypoxanthine by myocytes isolated from mature rat heart

Adenine and hypoxanthine can be utilised by cardiac muscle cells as substrates for the synthesis of ATP. A possible therapeutic advantage of these compounds as high-energy precursors is their lack of vasoactive properties. Myocytes isolated from mature rat heart have been used to establish in kinetic detail the capacity of the heart to incorporate adenine, hypoxanthine and ribose into cellular nucleotides. Maximum rates of catalysis by enzymes on the salvage pathways have been established. Whilst the rate of incorporation of adenine into the ATP pool appears to depend upon intracellular concentrations of adenine and phosphoribosylpyrophosphate, for hypoxanthine the pattern is more complex. Hypoxanthine is salvaged at a slow rate compared with adenine, and is incorporated into GTP and IMP as well as into adenine nucleotides. The rate of incorporation of hypoxanthine into both IMP and ATP is accelerated in myocytes incubated with ribose. However, the rate-limiting reaction appears to be that catalysed by adenylosuccinate synthetase, for the rate of ATP synthesis is not accelerated when hypoxanthine concentration is increased from 10 to 50 microM, while the rate of IMP synthesis is more than doubled. Adenine and hypoxanthine phosphoribosyl transferases are present in equal catalytic amounts, but rat cardiac myocytes have very little adenylosuccinate synthetase activity. Exogenous ribose is incorporated into adenine nucleotides in amounts equimolar with adenine or hypoxanthine.

Accumulation and salvage of adenosine and inosine by isolated mature cardiac myocytes

Reoxygenation of ischaemic, energy-depleted heart does not result in sufficiently rapid regeneration of normal adenine nucleotide concentrations for preservation of cardiac function and structure. Salvage of nucleoside as a mechanism for restoration of ATP in the post-ischaemic myocardium is limited by efflux of adenosine during ischaemia. Isolated cardiac myocytes have been used to establish the kinetics of uptake and salvage of adenosine and inosine, measuring the distribution of radioactive nucleoside incorporated into ATP, ADP and AMP. Maximum rates of catalysis of reactions on the salvage pathway, and of enzymes competing for substrates on the pathway, have been established in myocyte extracts. Myocytes have little capacity to salvage or catabolise inosine. Enzyme measurements indicate that salvage of adenosine should proceed at 7-8-times the rate exhibited by intact myocytes dependent upon extracellular adenosine as substrate. The data indicate that the rate of transport of adenosine is not determined by its metabolic utilization, but is the rate-limiting step in the salvage of adenosine.

Influence of ribose, adenosine, and "AICAR" on the rate of myocardial adenosine triphosphate synthesis during reperfusion after coronary artery occlusion in the dog

Recovery of adenosine triphosphate after myocardial ischemia is limited by the slow adenine nucleotide de novo synthesis and the availability of precursors of the nucleotide salvage pathways. We determined the adenine nucleotide de novo synthesis in the dog by infusion of [14C]glycine and the acceleration of adenine nucleotide built up by intracoronary infusion of ribose together with [14C]glycine or radiolabeled 5-amino-4-imidazolcarboxamide riboside or adenosine in the same animal model and with the same dosage of substrates (9 mmol) in postischemic and nonischemic myocardial tissue. After 45 minutes of occlusion of a side branch of the left coronary artery, the ischemic area was reperfused for 3 hours, and needle biopsies were taken for biochemical analysis. Adenine nucleotide de novo synthesis was found to be very slow (1.5 nmol/g wet weight per hour). The rate was doubled after ischemia. Adenine nucleotide synthesis was accelerated 5-fold by ribose, the basic substrate of the adenine nucleotide de novo synthesis, 9-fold by 5-amino-4-imidazolcarboxamide riboside, an intermediate of the adenine nucleotide de novo synthesis and 90-fold by adenosine, a substrate of the nucleotide salvage pathway. Therefore, only adenosine infusion resulted in a measurable increase of adenosine triphosphate levels after 3 hours of reperfusion, but over a longer time period, ribose or 5-amino-4-imidazol-carboxamide riboside also can be expected to replenish reduced myocardial adenosine triphosphate faster than adenine nucleotide de novo synthesis. Studies with radiolabeled 5-amino-4-imidazol-carboxamide riboside showed significant incorporation of radioactivity into 5-amino-4-imidazol-carboxamide ribose triphosphate which had also risen measurably during 5-amino-4-imidazol-carboxamide ribose infusion, and which is not normally found in heart muscle.

Interrelation between salvage of purine nucleotides and protein synthesis in rat heart cells

The effect of transition from a respiring to a respiration-inhibited state on the rate of protein synthesis was investigated in glycolyzing, cultured rat heart cells. The rate was found to be significantly lower after blocking respiration, and it was further decreased by L-lactate. In contrast, pyruvate or phenazine methosulfate prevented the drop in the rate caused by lack of respiration. The changes in the respiratory state also affected the steady-state concentration of ATP, which varied in the same sense as the rate of protein synthesis. Pyruvate or phenazine methosulfate induced an increment in the concentration of ATP of respiration-inhibited cells. This increment could not be accounted for by more extensive phosphorylation of the available purine nucleotides, but required repletion of the pool by synthesis of purine nucleotides through the salvage pathway. Pyruvate and phenazine methosulfate were found to stimulate incorporation of labeled hypoxanthine into the purine nucleotide fraction in general, and into the nucleotide triphosphates in particular. Under similar incubation conditions an increase in the ATP/ADP ratio was also noted. The stimulatory effect of pyruvate on protein synthesis and on the cellular level of ATP was also observed in respiration-inhibited 3T6 cells and in human fibroblasts, but not in human fibroblasts deficient in the salvage enzyme, hypoxanthine-guanine-phosphoribosyltransferase. Based on the demonstrated influence of L-lactate, pyruvate, and phenazine methosulfate on the salvage synthesis of purine nucleotides [K. Ravid, P. Diamant, and Y. Avi-Dor, (1984) Arch. Biochem. Biophys. 229, 632-639] and on the present findings, the connection between protein synthesis and the salvage activity is discussed.

[Synthesis of adenine nucleotides from exogenous adenosine in the perfused rat heart under normoxic conditions and after ischemia]

The rate of synthesis of myocardial adenine nucleotides from exogenous adenosine was studied in the isolated rat heart perfused under normoxic conditions and following ischaemia. The rate of incorporation of adenosine depended on the extracellular concentration of the precursor, following Michaelis-Menten kinetics with a apparent Km of 51.3 microM and a maximal rate of incorporation of about 1 100 nmol g-1 (wet wt.) 30 min-1. The adenosine uptake induced an increase in ATP concentration (+ 20%) when the exogenous concentration of precursor exceeded 10 microM. Following low-flow ischaemia (0.5 ml/min, 30 min), the rate of incorporation of 5 microM adenosine was diminished (-23%), but adenine nucleotide level restoration was favoured by the nucleoside administration. After total ischaemia (24 min), the extent of the decrease in adenosine incorporation was the same as in the case of moderate ischaemia but adenine nucleotide content was not restored.

Metabolic intervention to affect myocardial recovery following ischemia

Myocardial recovery during reperfusion following ischemia is critical to patient survival in a broad spectrum of clinical settings. Myocardial functional recovery following ischemia correlates well with recovery of myocardial adenosine triphosphate (ATP). Adenosine triphosphate recovery is uniformly incomplete during reperfusion following moderate ischemic injury and is therefore subject to manipulation by metabolic intervention. By definition ATP recovery is limited either by (1) energy availability and application in the phosphorylation of adenosine monophosphate (AMP) to ATP or (2) availability of AMP for this conversion. Experimental data suggest that substrate energy and the mechanisms required for its application in the creation of high energy phosphate bonds (AMP conversion to ATP) are more than adequate during reperfusion following moderate ischemic injury. Adenosine monophosphate availability, however, is inadequate following ischemia due to loss of diffusable adenine nucleotide purine metabolites. These purine precursors are necessary to fuel adenine nucleotide salvage pathways. Metabolic interventions that enhance AMP recovery rather than those that improve substrate energy availability during reperfusion are therefore recommended. The mechanisms of various metabolic interventions are discussed in this framework along with the rationale for or against their clinical application.

Regulation of the salvage pathway of purine nucleotide synthesis by the oxidation state of NAD+ in rat heart cells

The rate of salvage of purine nucleotides from hypoxanthine in glycolyzing, cultured rat heart cells was found to be decreased when respiration was suppressed. Pyruvate or phenazine methosulfate, acting as hydrogen acceptors, reversed the effect of the respiratory block. The inhibition and the reversal could not be attributed to the limitation of energy supply or of 5-phosphoribosyl-1-pyrophosphate. A causal connection was, however, shown to exist between this inhibition and the concomitant shift in the redox state of NAD+ in favor of NADH. NADH also inhibited the key enzyme of the salvage pathway, hypoxanthine-guanine-phosphoribosyltransferase, in cell-free extracts. Regulation of purine nucleotide synthesis by the redox state of NAD+ in heart cells might gain significance during transition from respiring to hypoxic state and vice versa.

Myocardial xanthine oxidase/dehydrogenase

High-energy phosphates in heart muscle deprived of oxygen are rapidly broken down to purine nucleosides and oxypurines. We studied the role of xanthine oxidase/dehydrogenase (EC 1.2.3.2/EC 1.2.1.37) in this process with novel high-pressure liquid chromatographic techniques. Under various conditions, including ischemia and anoxia, the isolated perfused rat heart released adenosine, inosine and hypoxanthine, and also substantial amounts of xanthine and urate. Allopurinol, an inhibitor of xanthine oxidase, greatly enhanced the release of hypoxanthine. From the purine release we calculated that the rat heart contained about 18 mU xanthine oxidase per g wet weight. Subsequently, we measured a xanthine oxidase activity of 9 mU/g wet wt. in rat-heart homogenate. When endogenous low molecular weight inhibitors were removed by gel-filtration, the activity increased to 31 mU/g wet wt. Rat myocardial xanthine oxidase seems to be present mainly in the dehydrogenase form, which upon storage at -20 degrees C is converted to the oxidase form.

Prevention of ATP catabolism during myocardial ischemia: a preliminary report

The enhancement of ATP regeneration following global myocardial ischemia in dogs by both ATP catabolic enzyme blockade and precursor infusion was investigated. The breakdown of AMP to adenosine is catalyzed by 5'-nucleotidase and this enzyme was inhibited during the ischemic period with either concanavalin A (Con A, 3 mg/kg) or alpha, beta-methyleneadenosine 5'-diphosphate (AMP-CP, 250 microM). To provide additional ATP precursors, adenine (30 mg/kg) and ribose (25 mg/kg) (A/R) were also infused into the coronary vasculature during ischemia and recovery on cardiopulmonary bypass. Left ventricular myocardial ATP levels in control animals decreased to 52% of preischemic values during aortic cross clamping, but ATP levels in dogs treated with AMP-CP + A/R fell to only 67% of preischemic values (P less than 0.05). During reperfusion, ATP levels in Con A + A/R (3.43 +/- 0.26 mumol/g wet wt) and AMP-CP + A/R (3.77 +/- 0.42) treated animals were higher than values found in control dogs (2.73 +/- 0.16, P less than 0.05). Infusions of A/R alone without enzyme inhibition did not increase ATP regeneration. The adenine nucleotide energy charge ratio was also increased by enzyme blockade with either inhibitor when combined with precursor infusion. On bypass, left ventricular myocardial blood flow (measured by the microsphere technique) was increased by 140% (P less than 0.01) over control values in all groups receiving A/R; therefore, enhanced ATP levels were not merely the result of increased flow. Renal blood flow was not adversely affected by this combination of drugs as has been previously found with adenosine infusion and inhibition of adenosine catabolism.

Release of purine nucleosides and oxypurines from the isolated perfused rat heart

In the ischemic heart, high-energy phosphates are rapidly broken down. We studied the release of AMP catabolites from the isolated perfused rat heart which was temporarily made ischemic or anoxic. We measured the concentration of purine nucleosides and oxypurines with a novel high-pressure liquid chromatographic technique. The postischemic working heart released adenosine, inosine, hypoxanthine, and also substantial amounts of xanthine. The latter could indicate that xanthine oxidase is present in rat heart. Further evidence for the myocardial occurrence of this enzyme was obtained from experiments with hearts perfused retrogradely with allopurinol, an inhibitor of xanthine oxidase. This drug greatly enhanced the release of hypoxanthine, both during normoxic and anoxic perfusions. We conclude that xanthine oxidase could play an essential role in the myocardial breakdown of AMP catabolites.

Nifedipine reduces adenine nucleotide breakdown in ischemic rat heart

An ATP-sparing effect has been demonstrated for a number of calcium antagonists. Nifedipine probably has a similar action, but data supporting this view are limited. Therefore we decided to study the effect of nifedipine on high-energy phosphate (and carbohydrate) metabolism in the ischemic rat heart. Langendorff preparations were made ischemic for less than 15 min. The reduction in coronary flow was 60 or 70%. Apex displacement during ischemia, a measure of contractility, was comparable for nifedipine-treated and untreated hearts. Ischemia caused a considerable release of the AMP catabolites adenosine, inosine and (hypo)xanthine, and of lactate. Nifedipine (10-100 micrograms/l) prevented this in a dose-dependent way. The highest dose reduced the release of purines and lactate by 90% (P less than 0.01) and 60% (P less than 0.001), respectively. The drug acted in a similar way during reperfusion. Due to ischemia, the adenylate energy charge (ATP + 0.5 ADP)/(ATP + ADP + AMP), decreased 15% (P less than 0.001); nifedipine at a concentration of 100 micrograms/l prevented this decrease (P less than 0.05). We conclude that nifedipine exerts a beneficial effect on myocardial adenine nucleotide metabolism during ischemia and reperfusion.

Prolonged derangements of canine myocardial purine metabolism after a brief coronary artery occlusion not associated with anatomic evidence of necrosis

Changes in myocardial purine metabolism were studied after temporary coronary artery occlusion and subsequent reperfusion in the dog. Sequential myocardial biopsies were performed to allow for measurements of ATP, adenine nucleotide, nucleoside, and base concentrations after 15 min of ischemia, and after 90 min and 72 hr of reperfusion following this period of ischemia. Control, nonischemic sites were also sampled. After 15 min of coronary occlusion, subendocardial ATP concentrations (reported in nmol/mg of protein; mean +/- SEM) were depressed in the ischemic zone at 19.9 +/- 3.5 compared to 38.1 +/- 2.8 in the nonischemic zone (P < 0.001). Subepicardial ATP concentrations also were depressed at 27.0 +/- 2.2 in ischemic sites compared to subepicardial nonischemic sites (40.0 +/- 4.0, P < 0.005). After 90 min of reperfusion ATP concentrations remained depressed in the previously ischemic subendocardium 26.8 +/- 4.2 (P < 0.025 vs. nonischemic sites). After 72 hr of reperfusion, ATP was still depressed in the previously ischemic subendocardium at 29.2 +/- 2.5 (P < 0.025 vs. nonischemic) and subepicardium (27.9 +/- 3.3, P < 0.05 vs. nonischemic). Total purines were determined as the sum of ATP, ADP, AMP, adenosine, inosine, and hypoxanthine. After 15 min of occlusion, the total purine pool in the ischemic subendocardium tended towards being lower than in the nonischemic zone (42.0 +/- 5.9 vs. 53.8 +/- 5.2, not significant) but in the ischemic subepicardium the total purine pool was similar to that in the nonischemic zone. After 90 min of reperfusion the previously ischemic subendocardial purine pool was reduced compared to the nonischemic zone (39.0 +/- 4.8, P < 0.025). Total purines were also depleted in both the subendocardium and subepicardium of previously ischemic zones after 72 hr of reperfusion (44.5 +/- 2.9 and 40.0 +/- 4.4, respectively, P < 0.05). Histologic analysis of the previously ischemic tissue revealed no evidence of necrosis. Therefore, brief temporary coronary artery occlusions not associated with anatomic evidence of necrosis may result in prolonged abnormalities of ATP concentration and significant depletion of the total purine pool.

Aspects of purine metabolism in the gill epithelium of rainbow trout, Salmo gairdneri Richardson

1. Enzymes interconnecting the adenylate pool were present in high concentration. 2. AMP and adenosine were easily deaminated by the corresponding enzymes whose high levels were detected. 3. Adenylate was hydrolyzed either by deamination to yield IMP which was further dephosphorylated to inosine or by dephosphorylation to adenosine followed by deamination to inosine. 4. Incubation of gill extract with [-14C]-AMP in the presence and absence of ATP but with adenosine deaminase inhibitors allowed demonstration that ATP controlled the balance between these pathways. 5. Some biochemical properties of 5'-nucleotidase. AMP deaminase and adenosine deaminase were defined. 6. Purine salvage enzymes were also estimated.

Systematic variations in the content of the purine nucleotides in the steady-state perfused rat heart. Evidence for the existence of controlled storage and release of adenine nucleotides

1. The contents of the major purine nucleotides in the isolated non-working perfused rat heart varied systematically during 80min of perfusion. In particular the amounts of ATP, ADP, GTP, cyclic AMP and cyclic GMP in the well-oxygenated myocardium showed changes ranging from 25 to 60% of the mean concentrations. The apparent periodicity was about 30min for some and about 60min for other nucleotides. 2. These data are in contrast with measurements of parameters reflecting heart performance, which remained constant over this period of perfusion. 3. The ATP/ADP ratio, the cyclic AMP content, the GTP content and the GTP/GDP ratio in the tissue bore a constant relationship to one another, and all showed the same temporal variation. 4. Increasing the energy demand on the heart by administration of bovine somatotropin (1mug/ml) tended to damp the variations, and generally lower the content of all the nucleotides. 5. The total extractable adenine nucleotide pool also showed systematic temporal variations of as much as 1.3mumol/g wet wt. of tissue within 10min. 6. These variations could not be accounted for as inter-conversion with adenosine, other purine nucleotides, nucleosides or purine-degradation products either in the tissue or in the perfusion medium. No evidence was found in this preparation of the purine nucleotide oscillations described by Lowenstein and his co-workers [see Tornheim & Lowenstein (1975) J. Biol. Chem.250, 6304-6314]. 7. Further, the pool size increases cannot be satisfactorily explained by either synthesis de novo or the breakdown of any purine macromolecular species in the cell. Thus it is suggested that an unsuspected substantial storage form of purine nucleotide may exist in heart.

Hereditary hemolytic anemia with increased red cell adenosine deaminase (45- to 70-fold) and decreased adenosine triphosphate

Hereditary hemolytic anemia, a dominantly transmitted disorder, has affected 12 family members spanning three generations. The concentration of adenosine triphosphate in the red cells was about half that of comparably reticulocyte-rich blood. Since adenosine deaminase and adenosine kinase compete for a common substrate, the greatly increased activity of the former may interfere with nucleotide salvage via the latter.

Transport and metabolism of adenosine in human blood platelets

The uptake and metabolism of [14C]- or E[3H] adenosine have been studied in suspensions of washed platelets and in platelet rich plasma. The appearance of radioactivity in the platelets and the formation of radioactive adenosine metabolites have been used to determine the uptake. Adenosine is transported into human blood platelets by two different systems: a low Km system (9.8 muM) which is competitively inhibited by papaverine, and a high Km system (9.4 mM) which is competitively inhibited by adenine. Adenosine transported via the low Km system is probably directly incorporated into adenine nucleotides, while adenosine transported through the high Km system arrives unchanged inside the platelet and is then converted into inosine and hypoxanthine or incorporated into adenine nucleotides.

Effect of adenosine on the adenine nucleotide content and metabolism of hepatocytes

ADENOSINE (0.5 MM) added to hepatocyte suspensions increased the intracellular concentration of ATP and total adenine nucleotides within 60 min up to three-fold. 2. Adenosine at 0.5 mM inhibited gluconeogenesis from lactate by about 50%. At higher adenosine concentrations the inhibition was less. There was no strict parallelism between the time-course of the increase of the adenine nucleotide content and the time-course of the inhibition of gluconeogenesis from lactate. 3. Adenosine abolished the accelerating effects of oleate and dibutyryl cyclic AMP on gluconeogenesis from lactate. 4. Gluconeogenesis was no significant effect of adenosine with fructose, dihydroxyacetone or glycerol. With asparagine, adenosine caused anacceleration of glucose formation. 5. Adenosine incorporation into adenine nucleotides accounted for about 20% of the adenosine removal. 6. Inosine, hypoxanthine or adenine compared with adenosine gave relatively slight increases of adenine nucleotides. 7. Urea synthesis from NH4Cl under optimum conditions i.e. in the presence of ornithine, lactate and oleate, was also inhibited by adenosine. The inhibition increased with the adenosine concentration and was 65% at 4 mM-adenosine. Again there was no correlation between the degree of inhibition of urea synthesis and the increase in the adenine nucleotide content. 8. The basal O2 consumption, the increased O2 consumption on the addition of oleate and the rate of formation of ketone bodies were not affected by the addition of adenosine. The [beta-hydroxybutyrate]/[acetoacetate] ratio was increased by adenosine, provided that lactate was present. 9. The increase of the adenine nucleotide content of the hepatocytes on the addition of adenosine may be explained on the assumption that adenosine kinase is not regulated by feedback but by substrate supply.

Studies on the coronary dilator actions of some adenosine analogues

1 The cardiovascular actions of 23 adenosine analogues have been examined in anaesthetized open thorax dogs; the analogues were substituted in the 2-position of the purine ring, or in the exocyclic amino group, or were modified in the imidazole or sugar rings.2 The effects of these compounds on coronary blood flow, peripheral blood pressure, and heart rate were compared with those of adenosine.3 9-beta-D-Arabinofuranosyladenine had no cardiovascular action; the other analogues on intra-atrial administration caused an immediate increase in coronary blood flow, the magnitude and duration of which varied with the structures of the analogues.4 2-Fluoro-, 2-bromo-, 2-isobutylthio-, 2-ethylamino-, and 5'-deoxy-5'-chloro- adenosines had coronary dilator potencies equal to or greater than that of adenosine. No relationship was found between the dilator potency of the adenosine analogues and their duration of coronary dilator action.5 The coronary dilator action of adenosine was potentiated by inosine, 9-beta-D-arabinofurano-syladenine, tubercidin, N(6)-methyladenosine and 2-trifluoromethyl-N(6)-methyladenosine.6 There was no correlation between the substrate specificities of the shorter-acting analogues for adenosine deaminase or adenosine kinase and their duration of coronary dilator action.7 It is proposed that in the anaesthetized dog, uptake into tissues is a more important mode of removal of adenosine and adenosine analogues from the vascular system than inactivation by adenosine deaminase, that the duration of coronary dilator action of the analogues is related primarily to their specificity for the carrier which mediates adenosine uptake, and that the adenosine carrier is not associated with kinase action.

Myocardial nucleotide synthesis from purine bases and nucleosides. Comparison of the rates of formation of purine nucleotides from various precursors and identification of the enzymatic routes for nucleotide formation in the isolated rat heart

14 C-Labeled adenosine, inosine, hypoxanthine, and adenine were extracted by the isolated rat heart in amounts proportional to their concentration in the perfusion medium between 0.05 and 5 µM. With each of the precursor materials, nearly all of the radioactivity retained by the heart was identified as acid-soluble nucleotide. Nucleotide formation from the four isotopic precursors occurred at similar rates when the concentration of the precursors was below 1 µM. Above this concentration, the heart appeared to utilize adenosine for nucleotide synthesis at rates three to five times those for the other purines. Several experimental approaches were employed to determine the predominant enzymatic routes in the rat heart for the conversion of the nucleosides adenosine and inosine to nucleotides. The results indicated that adenosine was directly phosphorylated to 5'-adenosine monophosphate by a nucleoside kinase. Inosine appeared to proceed to the nucleotide, at least partially, through an initial conversion to hypoxanthine.

De novo synthesis of myocardial adenine nucleotides in the rat. Acceleration during recovery from oxygen deficiency

De novo synthesis of adenine nucleotides was measured in rat hearts in situ and in isolated perfused rat hearts under normal conditions and during recovery from asphyxia or ischemia. Using l- 14 C-glycine as the precursor substrate, rates of de novo synthesis were determined from the total radioactivity of adenine nucleotides and from the mean specific activity of intracellular glycine. The rate of de novo synthesis of adenine nucleotides was 8.4±1.42 nmoles/g hour -1 in the heart in situ and 1.3±0.12 nmoles/g hour -1 in the isolated perfused heart. De novo synthesis of adenine nucleotides increased almost 100% in the heart in situ and about 580% in the isolated perfused heart during the first hour of recovery from asphyxia or ischemia. This acceleration is regarded as an adaptive process contributing to the postanoxic restoration of normal adenine nucleotide levels. Possible biochemical mechanisms that might be involved in the stimulation of the de novo pathway are a release of feedback inhibition of 5-phosphoribosyl-1-pyrophosphate amidotransferase, an enhanced synthesis of 5-phosphoribosyl-1-pyrophosphate, and an alternate way of 5-phosphoribosyl-amine formation.

Presence of adenosine in the human term placenta. Determination of adenosine content and pathways of adenosine metabolism

Adenosine, inosine, and hypoxanthine were isolated from human term placentas by paper chromatography of the dialyzates of aqueous placental homogenates and quantified by ultraviolet spectroscopy. Placentas obtained upon vaginal delivery contained 230 ± 18 nmoles adenosine/g tissue, 300 ± 29 nmoles inosine/g, and 250 ± 19 nmoles hypoxanthine/g. Three prelabor placentas obtained by cesarean section contained 44 ± 3 nmoles inosine/g and 277 ± 22 nmoles hypoxanthine/g, but adenosine was not detected in two of the placentas and was present only at 4 nmoles/g in the third. The activities of placental enzymes catabolizing ATP were determined in homogenates of term placentas. No adenylate deaminase or xanthine oxidase activity was found. Adenosinetriphosphatase, adenylate kinase, and 5'-nucleotidase were more active than were adenosine kinase, adenosine deaminase, and purine nucleoside phosphorylase. The results indicate that in the placenta both the formation of adenosine from adenosine monophosphate and the fate of adenosine, i.e., salvage or catabolism, are influenced by the level of adenosine triphosphate. Possibly, during labor, placental ischemia favors the enzymatic production of adenosine.