AMP deamination delays muscle acidification during heavy exercise and hypoxia

In silico studies carried out by using a computer model of oxidative phosphorylation and anaerobic glycolysis in skeletal muscle demonstrated that deamination of AMP to IMP during heavy short term exercise and/or hypoxia lessens the acidification of myocytes. The concerted action of adenylate kinase and AMP deaminase, leading to a decrease in the total adenine nucleotide pool, constitutes an additional process consuming ADP and producing ATP. It diminishes the amount of ADP that must be converted to ATP by other processes in order to meet the rate of ADP production by ATPases (because the adenylate kinase + AMP deaminase system produces only 1 ATP per 2 ADPs used, ATP consumption is not matched by ATP production, and the reduction of the total adenine nucleotide pool occurs mostly at the cost of [ATP]). As a result, the rate of ADP consumption by other processes may be lowered. This effect concerns mostly ADP consumption by anaerobic glycolysis that is inhibited by AMP deamination-induced decrease in [ADP] and [AMP], and not oxidative phosphorylation, because during heavy exercise and/or hypoxia [ADP] is significantly greater than the Km value of this process for ADP. The resultant reduction of proton production by anaerobic glycolysis enables us to delay the termination of exercise because of fatigue and/or to diminish cell damage.     

Adenylate kinase: Kinetic behavior in intact cells indicates it is integral to multiple cellular processes

Monitoring the kinetic behavior of adenylate kinase (AK) and creatine kinase (CK) in intact cells by ¹⁸O-phosphoryl oxygen exchange analysis has provided new perspectives from which to more fully define the involvement of these phosphotransferases in cellular bioenergetics. A primary function attributable to both AK and CK is their apparent capability to couple ATP utilization with its generation by glycolytic and/or oxidative processes depending on cell metabolic status. This is evidenced by the observation that the sum of the net AK- plus CK-catalyzed phosphoryl transfer is equivalent to about 95% of the total ATP metabolic flux in non-contracting rat diaphragm; under basal conditions almost every newly generated ATP molecule appears to be processed by one or the other of these phosphotransferases prior to its utilization. Although CK accounts for the transfer of a majority of the ATP molecules generated/consumed in the basal state there is a progressive, apparently compensatory, shift in phosphotransfer catalysis from the CK to the AK system with increasing muscle contraction or graded chemical inhibition of CK activity. AK and CK appear therefore to provide similar and interrelated functions. Evidence that high energy phosphoryl transfer in some cell types or metabolic states can also be provided by specific nucleoside mono- and diphosphate kinases and by the phosphotransfer capability inherent to the glycolytic system has been obtained. Measurements by ¹⁸O-exchange analyses of net AK- and CK-catalyzed phosphoryl transfer in conjunction with 31P NMR analyses of total unidirectional phosphoryl flux show that each new energy-bearing molecule CK or AK generates subsequently undergoes about 50 or more unidirectional CK-or AK-catalyzed phosphotransfers en route to an ATP consumption site in intact muscle. This evidence of multiple enzyme catalyzed exchanges coincides with the mechanism of vectorial ligand conduction suggested for accomplishing intracellular high energy phosphoryl transfer by the AK and CK systems. AK-catalyzed phosphotransfer also appears to be integral to the transduction of metabolic signals influencing the operation of ion channels regulated by adenine nucleotides such as ATP-inhibitable K⁺ channels in insulin secreting cells; transition from the ATP to ADP liganded states closely coincides with the rate AK-catalyzes phosphotransfer transforming ATP (+AMP) to (2) ADP.     

Adenylate kinase activity in ejaculated bovine sperm flagella

Adenylate kinase (ATP:AMP phosphotransferase, EC 2.7.4.3) activity was detected in the flagella of ejaculated bovine spermatozoa. This activity provided sufficient ATP to produce normal motility in cells permeabilized with digitonin and treated with 0.5 mM MgADP. In the presence of ADP, adenylate kinase activity was inhibited by P1,P5-di(adenosine 5')-pentaphosphate (Ap5A), an adenylate kinase-specific inhibitor, and motility was stopped. ATP-supported motility was not affected by Ap5A. Mitochondrial adenylate kinase activity allowed AMP to stimulate respiration in permeabilized sperm. Adenylate kinase activity in tail fragments was most active in a pH range from 7.6 to 8.4, and a similar pH sensitivity was observed for this enzyme activity in a hypotonic extract of whole sperm. The apparent km of adenylate kinase activity in permeabilized tail fragments was about 1.0 mM ADP in the direction of ATP synthesis. The fluctuation of nucleotide concentrations in normal and metabolically stimulated sperm suggested that adenylate kinase was most active when the cell was highly motile, although adenylate kinase activity did not appear to be coupled strictly with motility.     

An intrinsic adenylate kinase activity regulates gating of the ABC transporter CFTR

Cystic fibrosis transmembrane conductance regulator (CFTR) is an anion channel in the ATP binding cassette (ABC) transporter family. Like other ABC transporters, it can hydrolyze ATP. Yet while ATP hydrolysis influences channel gating, it has long seemed puzzling that CFTR would require this reaction because anions flow passively through CFTR. Moreover, no other ion channel is known to require the large energy of ATP hydrolysis to gate. We found that CFTR also has adenylate kinase activity (ATP + AMP <=> ADP + ADP) that regulates gating. When functioning as an adenylate kinase, CFTR showed positive cooperativity for ATP suggesting its two nucleotide binding domains may dimerize. Thus, channel activity could be regulated by two different enzymatic reactions, ATPase and adenylate kinase, that share a common ATP binding site in the second nucleotide binding domain. At physiologic nucleotide concentrations, adenylate kinase activity, rather than ATPase activity may control gating, and therefore involve little energy consumption.     

Demonstration of Phosphoryl Group Transfer Indicates That the ATP-binding Cassette (ABC) Transporter Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) Exhibits Adenylate Kinase Activity

Cystic fibrosis transmembrane conductance regulator (CFTR) is a membrane-spanning adenosine 5′-triphosphate (ATP)-binding cassette (ABC) transporter. ABC transporters and other nuclear and cytoplasmic ABC proteins have ATPase activity that is coupled to their biological function. Recent studies with CFTR and two nonmembrane-bound ABC proteins, the DNA repair enzyme Rad50 and a structural maintenance of chromosome (SMC) protein, challenge the model that the function of all ABC proteins depends solely on their associated ATPase activity. Patch clamp studies indicated that in the presence of physiologically relevant concentrations of adenosine 5′-monophosphate (AMP), CFTR Cl⁻ channel function is coupled to adenylate kinase activity (ATP+AMP ⇆ 2 ADP). Work with Rad50 and SMC showed that these enzymes catalyze both ATPase and adenylate kinase reactions. However, despite the supportive electrophysiological results with CFTR, there are no biochemical data demonstrating intrinsic adenylate kinase activity of a membrane-bound ABC transporter. We developed a biochemical assay for adenylate kinase activity, in which the radioactive γ-phosphate of a nucleotide triphosphate could transfer to a photoactivatable AMP analog. UV irradiation could then trap the ³²P on the adenylate kinase. With this assay, we discovered phosphoryl group transfer that labeled CFTR, thereby demonstrating its adenylate kinase activity. Our results also suggested that the interaction of nucleotide triphosphate with CFTR at ATP-binding site 2 is required for adenylate kinase activity. These biochemical data complement earlier biophysical studies of CFTR and indicate that the ABC transporter CFTR can function as an adenylate kinase.     

Synthesis of bound adenosine triphosphate from bound adenosine diphosphate by the purified coupling factor 1 of chloroplasts. Evidence for direct involvement of the coupling factor in this "adenylate kinase-like" reaction.

Electrophoretically homogeneous coupling factor 1 from spinach chloroplasts binds ADP and converts the bound ADP to bound ATP and AMP. That this transphosphorylation of enzyme-bound ADP is catalyzed by the coupling factor itself, and not be a conventional adenylate kinase which might possibly contaminate preparations of the coupling factor, is supported by the following evidence. 1. The procedure for isolatio of the coupling factor is designed to separate this large (approximately 13 S) enzyme from the smaller (4.2 S) conventional adenylate kinase of spinach chloroplasts. The conventional adenylate kinase cannot be detected in purified preparations of the coupling factor by biochemical assay or by polyacrylamide gel electrophoresis. 2. The activity of spinach adenylate kinase is completely dependent upon magnesium ions. However, the production of bound ATP and AMP from bound ADP by the coupling factor can be assayed in the total absence of added magnesium ions or even in the presence of added EDTA. 3. Comparative studies with inhibitors show that the coupling factor can produce bound ATP from ADP under conditions where the activity of adenylate kinase is strongly inhibited. Conversely, the coupling factor is prevented from synthesizing bound ATP from ADP under other conditions where the conventional adenylate kinase has high levels of activity. 4. AMP, when added in solution to the coupling factor, does not bind to this enzyme, even in the presence of APT. Thus, it is unlikely that the appearance of AMP bound to the coupling factor after its incubation with ADP is due to the production of free AMP by contaminating adenylate kinase. These results demonstrate that the isolated, homogeneous coupling factor from spinach chloroplasts has the intrinsic capacity to perform a phosphoryl group transfer between two bound ADP molecules and thus to synthesize ATP. This reaction may have an important role in the photosynthetic production of ATP by the chloroplast, as is discussed in this communication.     

Extracellular ATP formation on vascular endothelial cells is mediated by ecto-nucleotide kinase activities via phosphotransfer reactions.

Cell surface ecto-nucleotidases are considered the major effector system for inactivation of extracellular adenine nucleotides, whereas the alternative possibility of ATP synthesis has received little attention. Using a TLC assay, we investigated the main exchange activities of 3H-labeled adenine nucleotides on the cultured human umbilical vein endothelial cells. Stepwise nucleotide degradation to adenosine occurred when a particular nucleotide was present alone, whereas combined cell treatment with ATP and either [3H]AMP or [3H]ADP caused unexpected phosphorylation of 3H-nucleotides via the backward reactions AMP --> ADP --> ATP. The following two groups of nucleotide-converting ecto-enzymes were identified based on inhibition and substrate specificity studies: 1) ecto-nucleotidases, ATP-diphosphohydrolase, and 5'-nucleotidase; 2) ecto-nucleotide kinases, adenylate kinase, and nucleoside diphosphate kinase. Ecto-nucleoside diphosphate kinase possessed the highest activity, as revealed by comparative kinetic analysis, and was capable of using both adenine and nonadenine nucleotides as phosphate donors and acceptors. The transphosphorylation mechanism was confirmed by direct transfer of the gamma-phosphate from [gamma-32P]ATP to AMP or nucleoside diphosphates and by measurement of extracellular ATP synthesis using luciferin-luciferase luminometry. The data demonstrate the coexistence of opposite, ATP-consuming and ATP-generating, pathways on the cell surface and provide a novel mechanism for regulating the duration and magnitude of purinergic signaling in the vasculature.     

The detection of micromolar pericellular ATP pool on lymphocyte surface by using lymphoid ecto-adenylate kinase as intrinsic ATP sensor

Current models of extracellular ATP turnover include transient release of nanomolar ATP concentrations, triggering of signaling events, and subsequent ectoenzymatic inactivation. Given the high substrate specificity for adenylate kinase for reversible reaction (ATP + AMP <--> 2ADP), we exploited lymphoid ecto-adenylate kinase as an intrinsic probe for accurate sensing pericellular ATP. Incubation of leukemic T- and B-lymphocytes with [3H]AMP or [alpha-32P]AMP induces partial nucleotide conversion into high-energy phosphoryls. This "intrinsic" AMP phosphorylation occurs in time- and concentration-dependent fashions via nonlytic supply of endogenous gamma-phosphate-donating ATP, remains relatively resistant to bulk extracellular ATP scavenging by apyrase, and is diminished after lymphocyte pretreatment with membrane-modifying agents. This enzyme-coupled approach, together with confocal imaging of quinacrine-labeled ATP stores, suggests that, along with predominant ATP accumulation within cytoplasmic granules, micromolar ATP concentrations are constitutively retained on lymphoid surface without convection into bulk milieu. High basal levels of inositol phosphates in the cells transfected with ATP-selective human P2Y2-receptor further demonstrate that lymphocyte-surrounding ATP is sufficient for triggering purinergic responses both in autocrine and paracrine fashions. The ability of nonstimulated lymphocytes to maintain micromolar ATP halo might represent a novel route initiating signaling cascades within immunological synapses and facilitating leukocyte trafficking between the blood and tissues.     

Mutating the Conserved Q-loop Glutamine 1291 Selectively Disrupts Adenylate Kinase-dependent Channel Gating of the ATP-binding Cassette (ABC) Adenylate Kinase Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) and Reduces Channel Function in Primary Human Airway Epithelia

The ATP-binding cassette (ABC) transporter cystic fibrosis transmembrane conductance regulator (CFTR) and two other non-membrane-bound ABC proteins, Rad50 and a structural maintenance of chromosome (SMC) protein, exhibit adenylate kinase activity in the presence of physiologic concentrations of ATP and AMP or ADP (ATP + AMP ⇆ 2 ADP). The crystal structure of the nucleotide-binding domain of an SMC protein in complex with the adenylate kinase bisubstrate inhibitor P¹,P⁵-di(adenosine-5′) pentaphosphate (Ap₅A) suggests that AMP binds to the conserved Q-loop glutamine during the adenylate kinase reaction. Therefore, we hypothesized that mutating the corresponding residue in CFTR, Gln-1291, selectively disrupts adenylate kinase-dependent channel gating at physiologic nucleotide concentrations. We found that substituting Gln-1291 with bulky side-chain amino acids abolished the effects of Ap₅A, AMP, and adenosine 5′-monophosphoramidate on CFTR channel function. 8-Azidoadenosine 5′-monophosphate photolabeling of the AMP-binding site and adenylate kinase activity were disrupted in Q1291F CFTR. The Gln-1291 mutations did not alter the potency of ATP at stimulating current or ATP-dependent gating when ATP was the only nucleotide present. However, when physiologic concentrations of ADP and AMP were added, adenylate kinase-deficient Q1291F channels opened significantly less than wild type. Consistent with this result, we found that Q1291F CFTR displayed significantly reduced Cl⁻ channel function in well differentiated primary human airway epithelia. These results indicate that a highly conserved residue of an ABC transporter plays an important role in adenylate kinase-dependent CFTR gating. Furthermore, the results suggest that adenylate kinase activity is important for normal CFTR channel function in airway epithelia.     

Analysis of adenine nucleotides at the picomole level with 32P-phosphoenolpyruvate and pyruvate kinase.

A new sensitive method for adenine nucleotide analysis is described. The key reaction is the phosphorylation of ADP by [³²P]PEP in a reaction catalyzed by pyruvate kinase, with the extent of transfer of ³²P to ADP being determined by adsorbing the nucleotides onto charcoal. The nonadenine nucleoside diphosphates which also react in the pyruvate kinase reaction are corrected for by determining the ³²P retained in the nucleotide fraction after a second incubation with hexokinase and excess glucose. ATP is determined as ADP, after it is quantitatively converted by hexokinase in the presence of excess glucose. Similarly, AMP is analyzed by its conversion to ADP in an incubation with excess ATP and adenylate kinase. The sensitivity of the method for ADP and ATP is 0.05–0.5 pmoles while for AMP it is 5 pmoles.     

Adenine nucleotide translocation in plant mitochondria

The rapid translocation of external ADP-[^14C]by corn mitochondria is inhibited by high concentrations of atractyloside with enhanced inhibition occurring in the presence of Mg²⁺. This translocation is also inhibited by AMP or ATP but CDP, GDP, IDP or UDP have little effect. Backward exchange of internal ADP-[¹⁴C] occurs in the presence of AMP, ADP or ATP but is not promoted by other nucleoside diphosphates. It is suggested that the adenine nucleotide (AdN) carrier is specific for ADP and ATP and that apparent translocation of AMP is a result of adenylate kinase activity. The translocated ADP can be separated into 3 components: (1) atractyloside-insensitive binding; (2) carrier-bound ADP saturated at ca 30 μM external ADP; and (3) exchanged ADP saturated as ca 5 μM external ADP. It is suggested that the adenine nucleotide carrier of plant mitochondria possesses similar properties to the classical carrier of vertebrate mitochondria.     

Kinetics and compartmentation of energy metabolism in intact skeletal muscle determined from 18O labeling of metabolite phosphoryls

Analyses of isolated intact diaphragm muscle show that at rest only about 30% of the total cellular Pi is metabolically reactive as indicated by 18O incorporation from [18O]water, whereas up to 90% becomes metabolically active incrementally with contractile frequency. Kinetics of [gamma-18O]ATP appearance show that about 90% of the cellular ATP is metabolically active and suggest slowly and rapidly metabolizing compartments of ATP in resting muscle and only rapidly metabolizing compartments in contracting muscle. Rates of [18O]creatine phosphate [( 18O]CrP) appearance are consistent with creatine kinase-catalyzed phosphoryl exchange functioning in an obligatory phosphoryl shuttle system. In noncontracting muscle, ATP turnover rate was 83 nmol.mg protein-1.min-1, and the P/O ratio was determined to be 3.2. ATP utilization increases in direct proportion to contractile frequency with each contracture consuming the equivalent of 0.96 nmol of ATP.mg protein-1 or 2.5-3.5 molecules of ATP/myosin active site. Basal concentrations of nucleotide polyphosphates are not altered when ATP utilization rates increase during contraction. At high contractile frequencies, decreases in CrP concentration occur, but this accounts for less than 4% of total high energy phosphoryls consumed. If metabolic intermediates are free in the aqueous cellular cytosol, each twitch contracture would result in a decrease in ATP concentration of no more than 2% and increases in ADP and AMP concentrations of less than 20 and 7%, respectively. Thus, changes in metabolite concentration must be highly localized or metabolic regulation can be accomplished by a nonallosteric mechanism.     

Purification and properties of squid mantle adenylate kinase. Role of NADH in control of the enzyme.

Adenylate kinase (ATP:AMP phosphotransferase, EC 2.7.4.3) from the mantle muscle of the squid, Loligo pealeii, was purified over 170-fold to homogeneity as judged by polyacrylamide and starch gel electrophoresis. The tissue contains a single isozyme of adenylate kinase, the enzyme from cytoplasmic and mitochondrial compartments (90 and 10% of total activity, respectively) being identical in physical and kinetic properties. Molecular weight was found to be 27,000 +/- 400. The enzyme shows a pH optimum of 8.2 in the forward (APD utilizing) and 7.4 in the reverse direction. Michaelis constants for ADP, ATP, and AMP are 0.70, 0.13, and 0.15 mM, respectively, with optimal Mg2+:adenylate ratios being 1:2 for ADP and 1:1 for ATP. A comparison of mass action ratios with the equilibrium constant indicated that squid adenylate kinase is held out of equilibrium in resting, but not active, muscle. A search for metabolic modulators of adenylate kinase revealed that NADH (Ki of 0.1 mM) was the only modulator which exerted a significant effect within its in vivo concentration range. The data presented indicate that NADH inhibition is the factor maintaining adenylate kinase in a nonequilibrium state in resting muscle and that release of this inhibition can serve to integrate adenylate kinase into the known scheme of intermediary metabolism in this tissue. A sharp drop in NADH levels at the onset on muscular work co-ordinates that activation of aerobic metabolism in this tissue and allows adenylate kinase to return to equilibrium function. At equilibrium, the enzyme can function to ampligy the concentration of AMP, a potent activator and deinhibitor of key glycolytic and Krebs cycle enzymes. The effect of modulators of adenylate kinase in preventing denaturation by heat or proteolysis revealed that NADH and substrates induced conformational changes in the enzyme which rendered it less susceptible to denaturation. The conformation state induced by NADH differed from that induced by substrate.     

Properties of adenylate kinase after modification of Arg-97 by phenylglyoxal.

Adenylate kinase (ATP:AMP phosphotransferase, EC 2.7.4.3) isolated from porcine skeletal and heart muscle and from rabbit muscle are inactivated when a single arginine residue is modified. In adenylate kinase from pig the modified residue was identified as Arg-97 by peptide-mapping. In native adenylate kinase Arg-97 is located at the bottom of the active site cleft. The protein fluorescence of modified adenylate kinase is reduced. Whereas the addition of AMP, ADP and MgATP quench the fluorescence of native adenylate kinase, the fluorescence of phenylglyoxal-modified adenylate kinase is only affected by ADP and MgATP. This finding is discussed in connection with the structural isomerization observed in native adenylate kinase by X-ray diffraction analysis.     

Intracellular localization of ATP:AMP phosphotransferase in Escherichia coli

ATP and AMP were immediately converted into ADP by intact cells of Escherichia coli in the presence of Mg2+, while ADP was also rapidly converted into ATP and AMP under the same conditions. Adenylate kinase was released when E. coli cells were converted to spheroplasts by treatment with lysozyme-EDTA or osmotic shock. Adenylate kinase activities detected in the cytoplasm, periplasm and membrane fractions were approximately 58%, 36% and 6% of the total cellular activity, respectively. These results indicate that adenylate kinase in E. coli occurs in the periplasm as well as the cytoplasm.     

Changes in intramitochondrial adenine nucleotides in blowfly flight-muscle mitochondria

1. With freshly isolated blowfly mitochondria 38% of the intramitochondrial adenine nucleotide was present as AMP. 2. On incubation with oxidizable substrates the AMP and ADP concentrations fell and that of ATP rose; with pyruvate together with proline the ATP concentration reached its maximum value at 6min; with glycerol phosphate the phosphorylation of endogenous nucleotide was more rapid. 3. Addition of the uncoupling agent carbonyl cyanide phenylhydrazone caused a rapid fall of ATP and a parallel rise in ADP, then ADP was converted into AMP. 4. This was in contrast with rat liver mitochondria endogenous AMP concentrations, which were always lower than those of blowfly mitochondria and changed little under different metabolic conditions. 5. Evidence is presented that adenylate kinase (EC 2.7.4.3) has a dual distribution in blowfly mitochondria, a part being located in the matrix space and a part in the space between the outer and inner mitochondrial membranes, as in liver and other mitochondria. 6. The possible regulatory role of changing AMP concentrations in the mitochondrial matrix was investigated. Partially purified pyruvate carboxylase (EC 6.4.1.1) and citrate synthase (EC 4.1.3.7) were inhibited 30% by 2mm-AMP, whereas pyruvate dehydrogenase (EC 1.2.4.1) was unaffected. 7. AMP activated the NAD(+)-linked isocitrate dehydrogenase (EC 1.1.1.41) activity of blowfly mitochondria in the absence of ADP, but in the presence of ADP, AMP caused inhibition. 8. It is suggested that AMP may exert a controlling effect on the oxidative activity of blowfly mitochondria.     

Photokinetic microassay of adenylate kinase using the firefly luciferase reaction.

A new rapid photokinetic method is described for determining the activity of adenylate kinase (ATP:AMP phosphotranspherase, EC 2.7.4.3) in 0.1--5.0 micrograms of freeze-dried tissue. This represents a weight range far below that obtainable by fine-needle biopsy. The reaction 2 ADP in equilibrium with AMP + ATP was employed and the ATP formed assayed with firefly luciferase as light yielder. The light emission was recorded on a multi-channel scaler. The adenylate kinase activities found in tissues of mice were in the same range as previously described in a study using fluorometric microassay.     

Distantly related sequences in the alpha- and beta-subunits of ATP synthase, myosin, kinases and other ATP-requiring enzymes and a common nucleotide binding fold.

The alpha- and beta-subunits of membrane-bound ATP synthase complex bind ATP and ADP: beta contributes to catalytic sites, and alpha may be involved in regulation of ATP synthase activity. The sequences of beta-subunits are highly conserved in Escherichia coli and bovine mitochondria. Also alpha and beta are weakly homologous to each other throughout most of their amino acid sequences, suggesting that they have common functions in catalysis. Related sequences in both alpha and beta and in other enzymes that bind ATP or ADP in catalysis, notably myosin, phosphofructokinase, and adenylate kinase, help to identify regions contributing to an adenine nucleotide binding fold in both ATP synthase subunits.     

Protein kinases in brown adipose tissue of developing rats. I. GTP as nucleotide substrate for histone phosphorylation.

100 000 times g soluble extracts from interscapular brown adipose tissue catalyzed the transfer of the terminal phosphoryl group from GTP to histone. Maximal velocity was achieved only with both cyclic AMP and ATP present. The cyclic AMP dose-response curve was the same as for the ATP-utilizing enzyme, with maximum stimulation at 0.5 muM. ATP (1--100muM) increased the rate of histone phosphorylation with GTP as the radioactive substrate. Higher concentrations had a dilution effect similar to that of GTP on the ATP-utilizing enzyme. Similar effects were observed with ADP and AMP. The apparent Km values for histone were the same with both GTP and ATP as nucleotide substrates. The effects of pH, purified beef muscle kinase inhibitor and of NaCl were also the same. Maximum velocities of histone phosphorylation from ATP and those from GTP were almost the same in brown fat of all age groups testes, Separated on histone-Sepharose, the GTP-utilizing activity was absolutely dependent on the re-addition of the ATP-utilizing enzyme (a linear relationship with a slope of approx. 0.95). An extremely active nucleotide phosphotransferase activity was found in the same subcellular fraction. The rate of equilibration of the gamma-32-P between GTP and ATP could account for all the histone phosphorylation with [gamma-32-P] GTP. It is concluded that, in spite of the presence of nucleotide phosphotransferase and ATP-protein kinase activities, a direct transfer from GTP to a protein substrate cannot be excluded. Also, histone may not be the natural protein acceptor for GTP-linked phosphorylation.     

Adenine nucleotides and the adenylate kinase equilibrium in livers of foetal and newborn rats

1. Measurements of ATP, ADP and AMP concentrations in livers of rats that had been delivered by Caesarian section indicate a rapid shift from a low to a high [ATP]/[AMP] ratio. This change is consistent with the cessation of glycolysis and the initiation of gluconeogenesis at birth. 2. When newborn animals are exposed to a 100% nitrogen atmosphere the hepatic ATP concentration falls and AMP increases. 3. Calculations of the [ATP][AMP]/[ADP](2) ratio give values that are close to the equilibrium constant of adenylate kinase except when the ATP concentration is high. 4. This difference cannot be accounted for by the preferential binding of available Mg(2+) to ATP(4-) rather than ADP(3-). It is concluded that the relative proportions of adenine nucleotides at any level of phosphorylation are only partly regulated by adenylate kinase.