The adenosine triphosphate-pyrophosphate isotopic exchange reaction: a tool for determination of tryptophan

Quantitative determination of tryptophan at the picomole level is described, using the ATP-[32P]PPi isotopic exchange reaction catalyzed by tryptophanyl-tRNA synthetase. Sensitivity limits of 500 fmol were obtained. The presence of other amino acids at a 1000-fold excess over tryptophan did not interfere significantly with the quantitative determination of tryptophan. The specificity of the reaction was checked using five tryptophan analogs. These analogs did not prevent the determination of tryptophan when present in the same concentration range as tryptophan. When sensitive determination of a single amino acid is needed, the ATP-[32P]PPi exchange reaction catalyzed by aminoacyl-tRNA synthetases is suggested as a general method and as an alternative to HPLC procedures.     

ATP-dependent and NAD-dependent modification of glutamine synthetase from Rhodospirillum rubrum in vitro

Glutamine synthetase from the photosynthetic bacterium Rhodospirillum rubrum is the target of both ATP- and NAD-dependent modification. Incubation of R. rubrum cell supernatant with [alpha-32P]NAD results in the labeling of glutamine synthetase and two other unidentified proteins. Dinitrogenase reductase ADP-ribosyltransferase does not appear to be responsible for the modification of glutamine synthetase or the unidentified proteins. The [alpha-32P]ATP- and [alpha-32P] NAD-dependent modifications of R. rubrum glutamine synthetase appear to be exclusive and the two forms of modified glutamine synthetase are separable on two-dimensional gels. Loss of enzymatic activity by glutamine synthetase did not correlate with [alpha-32P]NAD labeling. This is in contrast to inactivation by nonphysiological ADP-ribosylation of other glutamine synthetases by an NAD:arginine ADP-ribosyltransferase from turkey erythrocytes (Moss, J., Watkins, P.A., Stanley, S.J., Purnell, M.R., and Kidwell, W.R. (1984) J. Biol. Chem. 259, 5100-5104). A 32P-labeled protein spot comigrates with the NAD-treated glutamine synthetase spot when glutamine synthetase purified from H3 32PO4-grown cells is analyzed on two-dimensional gels. The adenylylation site of R. rubrum glutamine synthetase has been determined to be Leu-(Asp)-Tyr-Leu-Pro-Pro-Glu-Glu-Leu-Met; the tyrosine residue is the site of modification.     

The ATP synthetase of Escherichia coli K12: purification of the enzyme and reconstitution of energy-transducing activities.

The ATP synthetase of Escherichia coli K12 was purified by a simple procedure. The dicyclohexylcarbodiimide-sensitive ATPase activity was enriched 21-fold. The ATP synthetase preparation contained the eight polypeptides (alpha, beta, gamma, a,delta, b,espilon, c) of the enzyme and a residual contamination (4% of the total protein) as shown by dodecylsulfate/polyacrylamide electrophoresis. The polypeptide c was specifically labelled with [14C]dicyclohexylcarbodiimide. Energy-transducing activities were reconstituted from soybean phospholipids and the purified enzyme. The proteoliposomes exhibited a significantly higher ATP-32Pi exchange activity and a higher proton-translocating activity as compared to the untreated membranes.     

Chemical modification of lysine residues in tyrosyl-tRNA-synthetase from cattle liver using pyridoxal-5'-phosphate]

Chemical modification of lysine residues of eukaryotic tyrosyl-tRNA synthetase was studied. It was shown that only four out of 22 lysine residues per enzyme dimer could be modified with pyridoxal-5'-phosphate. This modification led to the inactivation of tRNATyr aminoacylation by more than 90% but did not practically affect the rate of ATP-[32P]pyrophosphate exchange. Low molecular weight substrates (ATP, ATP-tyrosine) weakly protected the enzyme from inactivation, whereas tRNATyr afforded a much more effective protection. It was supposed that lysine residues of tyrosyl-tRNA synthetase can be involved in the interaction with tRNATyr.     

Reaction mechanism of gramicidin S synthetase 1, phenylalanine racemase, of Bacillus brevis

We have demonstrated that gramicidin S synthetase 1 (GS 1), phenylalanine racemase [EC 5.1.1.11], of Bacillus brevis catalyzes the exchange between a proton in the medium and alpha-hydrogen of phenylalanine in the course of the racemase reaction by using tritiated water or L-phenyl[2,3-3H]alanine. GS 1 from some gramicidin S non-producing mutants of B. brevis lacking phenylalanine racemase activity did not catalyze the tritium exchange reaction. The proton exchange between phenylalanine bound as thioester on the GS 1-phenylalanine complex and water in the medium was detected, but 5,5'-dithiobis(2-nitrobenzoic acid)-modified complex lacked both the proton exchange and phenylalanine racemase activity. It is suggested that a base group, probably a sulfhydryl group, on the enzyme functions as proton donor and acceptor during the phenylalanine racemase reaction.     

Effect of diadenosine oligophosphates (Ap4A and Ap3A) and their phosphonate analogs on catalytic properties of phenylalanyl-tRNA synthetase from E. coli

The influence of P1,P3-bis(5'-adenosyl)triphosphate (Ap3A), P1,P4-bis(5'-adenosyl)tetraphosphate (Ap4A) and its analogues, containing a residue of methylenediphosphonic acid in various positions of the oligophosphate chain, on the reactions catalysed by phenylalanyl-tRNA synthetase from E. coli MRE-600 has been studied. The compounds do not affect significantly the rate of ATP-[32P]PPi-exchange nor maintain this reaction in the absence of ATP. The diadenosineoligophosphates are shown to be noncompetitive inhibitors of ATP in the tRNA aminoacylation by phenylalanine (for Ap4A Ki = 1,45.10(-3) M). The phosphonate analogues of Ap4A inhibit the synthesis of Ap3A depending on their structure. The conclusion is thus drawn that the E. coli MRE-600 phenylalanyl-tRNA synthetase does not interact property with Ap4A and its phosphonate analogues.     

A stereochemical and positional isotope-exchange study of the mechanism of activation of methionine by methionyl-tRNA synthetase from Escherichia coli

Methionyl-tRNA synthetase from Escherichia coli catalyses the activation of [18O2]methionine by adenosine 5'-[(R)-alpha 17O]triphosphate with inversion of configuration at P alpha. Furthermore methionyl-tRNA synthetase does not catalyse positional isotope exchange in adenosine 5'-[beta-18O2]triphosphate in the absence of methionine or in the presence of the competitive inhibitor, methioninol, which eliminates the possibility of either adenylyl-enzyme or adenosine metaphosphate intermediates being involved. These observations require that methionyl-tRNA synthetase catalyses the activation of methionine by an associative 'in-line' nucleotidyl transfer mechanism. A kinetic study of positional isotope exchange in adenosine 5'-[beta-18O2]triphosphate in the presence of methionine, Mg2+ and methionyl-tRNA synthetase showed that torsional equilibration (18O exchange into the P alpha--O--P beta bridge) occurs faster than tumbling (18O exchange into P gamma by rotation about the C2 axis of Mg[18O2]PPi), demonstratings that the positional isotope exchange occurs at least in part in the E X Met-AMP X Mg[18O2]PPi complex.     

CMP activates reversal of phosphatidylinositol synthase and base exchange by distinct mechanisms in rat pituitary GH3 cells.

CMP is known to activate phosphatidylinositol (PtdIns)/inositol (Ins) base exchange and has been reported to activate reversal of PtdIns synthase also. Because it is possible that PtdIns synthase acting in the reverse direction, followed by re-incorporation of ambient Ins, could be responsible for base-exchange activity, we characterized these processes in rat pituitary GH3 cells. In permeabilized GH3 cells prelabelled with [3H]Ins and incubated in buffer with LiCl but without added Ins, CMP stimulated rapid accumulation of [3H]Ins and decreases in [3H]PtdIns; the Km for CMP was 1.7 mM. CDP and CTP were less effective, whereas 2'-CMP, 3'-CMP, other nucleoside monophosphates and cytidine did not influence this process. In permeabilized cells prelabelled to isotopic equilibrium with [3H]Ins and [32P]Pi, CMP stimulated decreases in both the 32P and 3H labelling of PtdIns, but did not increase that of [32P]phosphatidic acid. These findings demonstrate that in the absence of added Ins the effect of CMP is not via activation of base exchange nor via a phospholipase D, but by reversal of PtdIns synthase. In permeabilized cells prelabelled with [3H]Ins and [32P]Pi, unlabelled Ins inhibited loss of 32P labelling of PtdIns caused by CMP while markedly stimulating loss of 3H labelling of PtdIns and release of [3H]Ins. These data demonstrate that Ins inhibits reversal of PtdIns synthase, but stimulates base exchange. We conclude that in GH3 cells reversal of PtdIns synthase and PtdIns/Ins base exchange are both stimulated by CMP, but are distinct processes.     

Properties of ATP tightly bound to catalytic sites of chloroplast ATP synthase

Under steady state photophosphorylating conditions, each ATP synthase complex from spinach thylakoids contains, at a catalytic site, about one tightly bound ATP molecule that is rapidly labeled from medium 32Pi. The level of this bound [32P]ATP is markedly reduced upon de-energization of the spinach thylakoids. The reduction is biphasic, a rapid phase in which the [32P] ATP/synthase complex drops about 2-fold within 10 s, followed by a slow phase, kobs = 0.01/min. A decrease in the concentration of medium 32Pi to well below its apparent Km for photophosphorylation is required to decrease the amount of tightly bound ATP/synthase found just after de-energization and before the rapid phase of bound ATP disappearance. The [32P]ATP that remains bound after the rapid phase appears to be mostly at a catalytic site as demonstrated by a continued exchange of the oxygens of the bound ATP with water oxygens. This bound [32P]ATP does not exchange with medium Pi and is not removed by the presence of unlabeled ATP. The levels of tightly bound ADP and ATP arising from medium ADP were measured by a novel method based on use of [beta-32P]ADP. After photophosphorylation and within minutes after the rapid phase of bound ATP loss, the measured ratio of bound ADP to ATP was about 1.4 and the sum of bound ADP plus ATP was about 1/synthase. This ratio is smaller than that found about 1 h after de-energization. Hence, while ATP bound at catalytic sites disappears, bound ADP appears. The results suggest that during and after de-energization the bound ATP disappears from the catalytic site by hydrolysis to bound ADP and Pi with subsequent preferential release of Pi. These and related observations can be accommodated by the binding change mechanism for ATP synthase with participation of alternating catalytic sites and are consistent with a deactivated state arising from occupancy of one catalytic site on the synthase complex by an inhibitory ADP without presence of Pi.     

Isotope exchange as a probe of the kinetic mechanism of pyrophosphate-dependent phosphofructokinase

Data obtained from isotope exchange at equilibrium, exchange of inorganic phosphate against forward reaction flux, and positional isotope exchange of 18O from the bridge position of pyrophosphate to a nonbridge position all indicate that the pyrophosphate-dependent phosphofructokinase from Propionibacterium freudenreichii has a rapid equilibrium random kinetic mechanism. The maximum rates of isotope exchange at equilibrium for the [14C]fructose 1,6-bisphosphate in equilibrium fructose 6-phosphate, [32P]Pi in equilibrium MgPPi, and Mg[32P]PPi in equilibrium fructose 1,6-bisphosphate exchange reactions increasing all four possible substrate-product pairs in constant ratio are identical, consistent with a rapid equilibrium mechanism. All exchange reactions are strongly inhibited at high concentrations of the fructose 6-phosphate (F6P)/Pi and MgPPi/Pi substrate-product pairs and weakly inhibited at high concentrations of the MgPPi/fructose 1,6-bisphosphate (FBP) pair suggesting three dead-end complexes, E:F6P:Pi, E:MgPPi:Pi, and E:FBP:MgPPi, in agreement with initial velocity studies [Bertagnolli, B.L., & Cook, P.F. (1984) Biochemistry 23, 4101]. Neither back-exchange by [32P]Pi nor positional isotope exchange of 18O-bridge-labeled pyrophosphate was observed under any conditions, suggesting that either the chemical interconversion step or a step prior to it limits the overall rate of the reaction.     

Monoclonal antibodies against tryptophanyl-tRNA-synthetase

Monoclonal antibodies designated as Am1 and Am2 were prepared against purified beef pancreas tryptophanyl-tRNA synthetase (EC 6.1.1.2). Both antibodies were able to bind the native enzyme in a solid-phase assay and to precipitate enzyme activity in immune complexes. Am2 inhibited the tryptophanyl-tRNA synthetase activity in ATP-[32P]pyrophosphate exchange and in tRNATrp aminoacylation reactions; Am1 had no influence on both the enzyme activity and the inhibiting action of Am2. Only Am2, not Am1, bound elastase-modified form of the enzyme which consists of two subunits shortened by 20 000 daltons from the N-end of the molecule. These results were interpreted as an evidence for non-overlapping of Am1 and Am2 antigenic determinants along the polypeptide chains of the enzyme.     

Evidence from 18O exchange measurements for steps involving a weak acid and a slow chemical transformation in the mechanism of phosphorylation of the gastric H+, K+-ATPase by inorganic phosphate

Phosphorylation of the gastric H,K-ATPase by Pi has been studied by measuring the P18Oj16O4-j distribution as a function of time at different H+, K+, and [18O]Pi concentrations. The advantage of isotope exchange measurements is that the P18Oj16O4-j distribution depends on the relative rates of HOH loss to form the phosphoenzyme intermediate and Pi dissociation from the enzyme. Therefore, 18O exchange is a sensitive probe of mechanism. K+ increases the exchange rate (v(ex] but does not affect the partition coefficient (Pc) that determines the P18Oj16O4-j distribution. Conversely, H+ inhibits exchange. A single Pc describes the data at every pH, but the value increases from 0.04 at pH 8 to 0.64 at pH 5.5. Vex depends hyperbolically on [Pi]0. Km for Pi does not depend on pH, and Pc does not depend on [Pi]0. Individual rate constants in the phosphorylation mechanism are estimated. Formation of the E.Pi complex that looses HOH is 1-2 orders of magnitude slower at pH 5.5 than at pH 8 and is not diffusion controlled. The observed change in Pc with pH is compatible with catalysis occurring by a different mechanism when a group with pKa = 7.2 is protonated. Slower than diffusion-controlled formation of the E.Pi complex that splits out HOH is evidence for a relatively slow, unimolecular chemical transformation involving an additional intermediate in the phosphorylation mechanism, such as a protein conformational change.     

Source of rapidly labeled ATP tightly to non-catalytic sites on the chloroplast ATP synthetase

Bound [32P]ATP is found on deenergized, washed chloroplast thylakoids which were illuminated in the presence of ADP and [32P]Pi. Tight binding of [32P]ATP occurred both during and after energization. Different classes of bound [32P]ATP were distinguished on the basis of their rates of formation, susceptibility to hexokinase and displacement by unlabeled ATP. 1. The rates of formation and discharge of the rapidly labeled tightly bound ATP class were much lower than that of ATP formation. The level of this bound ATP saturates at lower concentrations of substrates than does the rate of phosphorylation. Unlabeled ATP, present in the reaction medium, displaces the rapidly labeled tightly bound ATP without affecting the rate of phosphorylation. 2. We therefore conclude that the rapidly labeled bound ATP class does not fulfill the requirements expected for a catalytic intermediate and that the nucleotide tight binding site(s) on the ATP synthetase differ from the catalytic site(s) for ATP formation. 3. Since the rapidly labeled tightly bound [32P]ATP is not abolished by high concentrations of hexokinase, but is nevertheless displaced by exogenous ATP, we propose that tight binding of ATP to non-catalytic sites occurs via a free species of newly synthesized ATP which diffuses slowly to the medium from a space accessible to ATP but not to hexokinase.     

Bound adenosine 5'-triphosphate formation, bound adenosine 5'-diphosphate and inorganic phosphate retention, and inorganic phosphate oxygen exchange by chloroplast adenosinetriphosphatase in the presence of Ca2+ or Mg2+

When the heat-activated chloroplast F1 ATPase hydrolyzes [3H, gamma-32P]ATP, followed by the removal of medium ATP, ADP, and Pi, the enzyme has labeled ATP, ADP, and Pi bound to it in about equal amounts. The total of the bound [3H]ADP and [3H]ATP approaches 1 mol/mol of enzyme. Over a 30-min period, most of the bound [32P]Pi falls off, and the bound [3H]ATP is converted to bound [3H]ADP. Enzyme with such remaining tightly bound ADP will form bound ATP from relatively high concentrations of medium Pi with either Mg2+ or Ca2+ present. The tightly bound ADP is thus at a site that retains a catalytic capacity for slow single-site ATP hydrolysis (or synthesis) and is likely the site that participates in cooperative rapid net ATP hydrolysis. During hydrolysis of 50 microM [3H]ATP in the presence of either Mg2+ or Ca2+, the enzyme has a steady-state level of about one bound [3H]ADP per mole of enzyme. Because bound [3H]ATP is also present, the [3H]ADP is regarded as being present on two cooperating catalytic sites. The formation and levels of bound ATP, ADP, and Pi show that reversal of bound ATP hydrolysis can occur with either Ca2+ or Mg2+ present. They do not reveal why no phosphate oxygen exchange accompanies cleavage of low ATP concentrations with Ca2+ in contrast to Mg2+ with the heat-activated enzyme. Phosphate oxygen exchange does occur with either Mg2+ or Ca2+ present when low ATP concentrations are hydrolyzed with the octyl glucoside activated ATPase. Ligand binding properties of Ca2+ at the catalytic site rather than lack of reversible cleavage of bound ATP may underlie lack of oxygen exchange under some conditions.     

Evidence that chlorpromazine and prostaglandin E1 but not neomycin interfere with the inositol phospholipid metabolism in intact human platelets

Human platelets that had been prelabelled with [32P]Pi were stimulated with trombin in the presence or absence of neomycin, prostaglandin E1 (PGE1) or chlorpromazine. The content of [32P]Pi in phosphatidylinositol 4-phosphate, phosphatidylinositol 4,5-bisphosphate and phosphatidic acid (PA) were determined. The data demonstrate that PGE1 and chlorpromazine but not neomycin interfere with the tight metabolic relationship that exists between the inositol phospholipids and PA in thrombin-stimulated platelets [(1989) Biochem. J. 263, 621-624]. Our results therefore indicate that neomycin does not inhibit signal transduction in intact platelets at the level of the inositol phospholipid metabolism.     

Biosynthesis of the Escherichia coli siderophore enterobactin: sequence of the entF gene, expression and purification of EntF, and analysis of covalent phosphopantetheine.

The sequence of the entF gene which codes for the serine activating enzyme in enterobactin biosynthesis is reported. The gene encodes a protein with a calculated molecular weight of 142,006 and shares homologies with the small subunits of gramicidin S synthetase and tyrocidine synthetase. We have subcloned and overexpressed entF in a multicopy plasmid and attempted to demonstrate L-serine-dependent ATP-[32P]PPi exchange activity and its participation in enterobactin biosynthesis, but the overexpressed enzyme appears to be essentially inactive in crude extract. A partial purification of active EntF from wild-type Escherichia coli, however, has confirmed the expected activities of EntF. In a search for possible causes for the low level of activity of the overexpressed enzyme, we have discovered that EntF contains a covalently bound phosphopantetheine cofactor.     

Phosphatidylinositol metabolism in rat hepatocytes stimulated by vasopressin.

In isolated rat hepatocytes, vasopressin evoked a large increase in the incorporation of [32P]Pi into phosphatidylinositol, accompanied by smaller increases in the incorporation of [1-14C]oleate and [U-14C]glycerol. Incorporation of these precursors into the other major phospholipids was unchanged during vasopressin treatment. Vasopressin also promoted phosphatidylinositol breakdown in hepatocytes. Half-maximum effects on phosphatidylinositol breakdown and on phosphatidylinositol labelling occurred at about 5 nM-vasopressin, a concentration at which approximately half of the hepatic vasopressin receptors are occupied but which is much greater than is needed to produce half-maximal activation of glycogen phosphorylase. Insulin did not change the incorporation of [32P]Pi into the phospholipids of hepatocytes and it had no effect on the response to vasopressin. Although the incorporation of [32P]Pi into hepatocyte lipids was decreased when cells were incubated in a Ca2+-free medium, vasopressin still provoked a substantial stimulation of phosphatidylinositol labelling under these conditions. Studies with the antagonist [1-(beta-mercapto-beta, beta-cyclopentamethylenepropionic acid),8-arginine]vasopressin indicated that the hepatic vasopressin receptors that control phosphatidylinositol metabolism are similar to those that mediate the vasopressor response in vivo. When prelabelled hepatocytes were stimulated for 5 min and then subjected to subcellular fractionation. The decrease in [3H]phosphatidylinositol content in each cell fraction with approximately in proportion to its original phosphatidylinositol content. This may be a consequence of phosphatidylinositol breakdown at a single site, followed by rapid phosphatidylinositol exchange between membranes leading to re-establishment of an equilibrium distribution.     

Special features of Pi transport in pig heart and rat liver mitochondria as revealed by 6,6'-dithiodinicotinic acid (CPDS).

CPDS (6,6'-dithiodinicotinic acid), a non permeant thiol agent which affects several mitochondrial functions in a way different to that of mersalyl [18-19] revealed striking differences between the phosphate translocating systems of pig heart and rat liver mitochondria. Pi entry was measured either by swelling in 0.12 M ammonium phosphate or by rapid centrifugation in 32Pi medium. Pi efflux was measured after preloading of mitochondria with 32Pi, by exchange against Pi or malate; the "ATP-FCCP" system has been tested previously [19]. In pig heart mitochondria, Pi entry seems to proceed exclusively via the Pi/OH- carrier; CPDS completely inhibits this transport and the energy-linked functions. In contrast n-butyl-malonate does not affect the Pi-entry and the energy-linked functions. The Pi efflux is not affected either by CPDS or mersalyl, which do not produce a swelling in the "ATP-uncoupler system". In rat liver mitochondria, CPDS inhibits only the Pi/OH- carrier; both CPDS and n-butylmalonate are necessary to inhibit completely Pi entry. CPDS as well as mersalyl provokes a swelling in the presence of the "APT-uncoupler system". The results suggest two distinct functions of phosphate transport in both types of mitochondria.     

Regulation of the phosphate (Pi) concentration in UMR 106 osteoblast-like cells: Effect of Pi,Na+ and K+

Osteoblast-like cells possess Na-dependent transporters which accumulate orthophosphate (Pi) from the extracellular medium. This may be important in bone formation. Here we describe parallel measurements of Pi uptake and cellular [Pi] in such cells from the rat (UMR 106–01 and UMR 106–06) and human (OB), and in non-osteoblastic human fibroblasts (Detroit 532 (DET)). In UMR 106–01, cellular [Pi] was weakly dependent on extracellular [Pi] and higher than expected from passive transport alone. [³²Pi]-uptake was inhibited by Na deprivation, but paradoxically increased on K deprivation. With Na, 87 per cent of cellular ³²P was found in organic phosphorus pools after only 5 min. Na deprivation also decreased cellular [Pi], in both UMR 106–01 and DET, but the decrease was smaller than that in [³²Pi]-uptake. Ouabain decreased [³²Pi]-uptake and cellular [Pi] in DET, but not in UMR 106–01. Regulation of cellular [Pi] is therefore at least partly dependent on Na/Pi co-transport, but this does not seem to be an exclusive property of osteoblasts.     

Phosphatidic acid and phosphatidylinositol labelling in adipose tissue. The role of endogenously formed adenosine.

Incorporation of [32P]Pi into phosphatidic acid and phosphatidylinositol of hamster epididymal adipocytes was partially inhibited by 3-isobutyl-1-methylxanthine. This effect of 3-isobutyl-1-methylxanthine was antagonized by isopropyl-N6-phenyladenosine but not by 2',5'-dideoxyadenosine, prostaglandin E1 or clonidine. N6-Phenylisopropyladenosine did not affect incorporation of [32P]Pi into phosphatidic acid or phosphatidylinositol when 3-isobutyl-1-methylxanthine was not present. In contrast with 3-isobutyl-1-methylxanthine inhibition of [32P]Pi incorporation into phospholipids, which was blocked only by N6-phenylisopropyladenosine, accelerated lipolysis was blocked by prostaglandin E1, clonidine and 2',5'-dideoxyadenosine as well as by N6-phenylisopropyladenosine. Phospholipid labelling was also decreased in the presence of adenosine deaminase, but not in the presence of isoprenaline (isoproterenol). The stimulatory effect of N6-phenylisopropyladenosine on [32P]Pi incorporation into phospholipids in cells exposed to 3-isobutyl-1-methylxanthine was evident as soon as 3 min after addition of the adenosine analogue and maximum 10 min after its addition. As observed by others, [32P]Pi incorporation into phospholipids was increased by the alpha 1-selective agonist methoxamine. The stimulatory effect of methoxamine occurred with a time course similar to that of N6-phenylisopropyladenosine and was present at nearly equal magnitude in the absence or presence of 3-isobutyl-1-methylxanthine. The inhibitory effects of 3-isobutyl-1-methylxanthine and adenosine deaminase on phospholipid labelling are attributed to blockade of the action, or to the enzymic removal, of adenosine formed in and released from the fat-cells during their incubation. Supporting this view is the selective reversal of the actions of 3-isobutyl-1-methylxanthine and of adenosine deaminase by N6-phenylisopropyladenosine. These findings suggest an important role for endogenous adenosine in regulation of phospholipid turnover in adipocytes.