A method for the enzymatic synthesis and purification of [alpha-32P] nucleoside triphosphates.

A simplified method is described for the enzymatic synthesis and purification of [alpha-32P]ribo- and deoxyribonucleoside triphosphates. The products are obtained at greater than 97% radiochemical purity with yields of 50--70% (relative to 32Pi) by a two-step elution from DEAE-Sephadex. All reactions are done in one vessel as there is no need for intermediate product purifications. This method is therefore suitable for the synthesis of these radioactive compounds on a relatively large scale. The sequential steps of the method involve first the synthesis of [gamma-32P]ATP and the subsequent phosphorylation of nucleoside 3' monophosphate with T4 polynucleotide kinase to yield nucleoside 3', [5'-32P]diphosphate. Hexokinase is used after the T4 reaction to remove any remaining [gamma-32P]ATP. Nucleoside 3',[5'-32P]diphosphate is treated with nuclease P-1 to produce the nucleoside [5'-32P]monophosphate which is phosphorylated to the [alpha-32P]nucleoside triphosphate with pyruvate kinase and nucleoside monophosphate kinase. Adenosine triphosphate used as the phosphate donor for [alpha-32P]deoxynucleoside triphosphate syntheses is readily removed in a second purification step involving affinity chromatography on boronate-polyacrylamide. [alpha-32P]Ribonucleoside triphosphates can be similarly purified when deoxyadenosine triphosphate is used as the phosphate donor.     

Evidence of histidine phosphorylation in isocitrate lyase from Escherichia coli

Escherichia coli isocitrate lyase (EC 4.1.3.1.) can be phosphorylated in vitro by an ATP-dependent reaction. The enzyme becomes phosphorylated by an endogenous kinase when partially purified sonic extracts are incubated with [gamma-32P]ATP. Treatment of isocitrate lyase with diethyl pyrocarbonate, a histidine-modifying reagent, blocked incorporation of [32P]phosphate from [gamma-32P]ATP. The isoelectric point of the enzyme was altered by treatment with phosphoramidate, a histidine phosphorylating agent, which suggests that isocitrate lyase can be phosphorylated at a histidine residue(s). Immunoprecipitated 32P-labeled isocitrate lyase was subjected to alkaline hydrolysis, mixed with chemically synthesized phosphohistidine standards, and analyzed by anion exchange chromatography. Characterization of the phosphoamino acid was based on the demonstration that the 32P-labeled product from alkali-hydrolyzed isocitrate lyase comigrated with synthetic 1-phosphohistidine. In addition, loss of catalytic activity after treatment with potato acid phosphatase indicates that catalytically active isocitrate lyase is the phosphorylated form of the enzyme.     

The enzymatic preparation of [alpha-(32)P]nucleoside triphosphates, cyclic [32P] AMP, and cyclic [32P] GMP.

A method has been developed for the enzymatic preparation of alpha-(32)P-labeled ribo- and deoxyribonucleoside triphosphates, cyclic [(32)P]AMP, and cyclic [(32)P]GMP of high specific radioactivity and in high yield from (32)Pi. The method also enables the preparation of [gamma-(32)P]ATP, [gamma-(32)P]GTP, [gamma-(32)P]ITP, and [gamma-(32)P]-dATP of very high specific activity and in high yield. The preparation of the various [alpha-(32)P]nucleoside triphosphates relies on the phosphorylation of the respective 3'-nucleoside monophosphates with [gamma-(32)P]ATP by polynucleotide kinase and a subsequent nuclease reaction to form [5'-(32)P]nucleoside monophosphates. The [5'-(32)P]nucleoside monophosphates are then converted enzymatically to the respective triphosphates. All of the reactions leading to the formation of [alpha-(32)P]nucleoside triphosphates are carried out in the same reaction vessel, without intermediate purification steps, by the use of sequential reactions with the respective enzymes. Cyclic [(32)P]AMP and cyclic [(32)P]GMP are also prepared enzymatically from [alpha-(32)P]ATP or [alpha-(32)P]GTP by partially purified preparations of adenylate or guanylate cyclases. With the exception of the cyclases, all enzymes used are commerically available. The specific activity of (32)P-labeled ATP made by this method ranged from 200 to 1000 Ci/mmol for [alpha-(32)P]ATP and from 5800 to 6500 Ci/mmol for [gamma-(32)P]ATP. Minor modifications of the method should permit higher specific activities, especially for the [alpha-(32)P]nucleoside triphosphates. Methods for the use of the [alpha-(32)P]nucleoside phosphates are described for the study of adenylate and guanylate cyclases, cyclic AMP- and cyclic GMP phosphodiesterase, cyclic nucleotide binding proteins, and as precursors for the synthesis of other (32)P-labeled compounds of biological interest. Moreover, the [alpha-(32)P]nucleoside triphosphates prepared by this method should be very useful in studies on nucleic acid structure and metabolism and the [gamma-(32)P]nucleoside triphosphates should be useful in the study of phosphate transfer systems.     

Phosphorylation of ATP citrate lyase in response to glucagon.

Incubation of hepatocytes with [32P]orthophosphate resulted in the incorporation of 32P into material that is precipitated by reaction with antibodies to ATP citrate lyase. The amount of radioactivity precipitated was decreased when unlabeled, purified ATP citrate lyase was added to extracts of hepatocytes that had been incubated with [32P]orthophosphate. Addition of glucagon to hepatocytes that had been preincubated with [32P]orthophosphate resulted in a 56% increase in acid-stable 32P in the trichloroacetic acid-insoluble portion of immunoprecipitates. Catalytic phosphate bound to ATP citrate lyase reaction with ATP and Mg2+ is acid-labile; thus, glucagon-dependent phosphorylation is distinguished from the catalytic phosphate. When hepatocytes were incubated in the absence of [32P]orthophosphate and extracted in a medium containing [gamma-32P]ATP, no acid-stable 32P was present in immunoprecipitates. This indicates that the incorporation into ATP citrate lyase of acid-stable phosphate occurs prior to extraction of the enzyme. Preliminary studies, using a procedure that allows for measurement of enzyme activity starting 1 min after beginning the extraction of lyase from hepatocytes, have shown no difference in lyase activity when hepatocytes are treated with or without glucagon.     

Phosphorylation of isocitrate lyase in Escherichia coli

Isocitrate lyase from Escherichia coli becomes phosphorylated in vitro by an endogenous kinase when partially purified extracts are incubated with [gamma-32P]ATP. Treatment of isocitrate lyase with histidine modifying reagents, and alkaline hydrolysis of in vitro phosphorylated enzyme indicated the presence of a phosphohistidine residue. Phosphorylation of isocitrate lyase can also occur in vivo, which indicates a possible regulatory significance of this modification. In addition to phosphorylation, isocitrate lyase is capable of incorporating label from both [alpha-32P]ATP and [14C]ATP suggesting that more than one type of covalent modification occurs on this enzyme. This report reviews the studies which have demonstrated the phosphorylation and modification of isocitrate lyase from Escherichia coli.     

Enzymatic synthesis of [beta-32P]ADP using adenylate kinase and [gamma-32P]ATP

An enzymatic method for the synthesis of [beta-32P]ADP from [gamma-32P]ATP is described. This substrate is required for the assay of ADPase and is not commercially available. The method described results in a preparation of [beta-32P]ADP of high purity with a yield of approximately 40% the theoretical obtainable.     

Purification of a serine and histidine phosphorylated mitochondrial nucleoside diphosphate kinase from Pisum sativum.

For the first time, to our knowledge, a nucleoside diphosphate kinase (NDPK) has been purified from plant mitochondria (Pisum sativum L.). In intact pea leaf mitochondria, a 17.4-kDa soluble protein was phosphorylated in the presence of EDTA when [gamma-32P]ATP was used as the phosphate donor. Cell fractionation demonstrated that the 17.4-kDa protein is a true mitochondrial protein, and the lack of accessibility to EDTA of the matrix compartment in intact mitochondria suggested it may have an intermembrane space localization. The 17.4-kDa protein was purified from mitochondrial soluble proteins using ATP-agarose and anion exchange chromatography. Amino-acid sequencing of two peptides, resulting from a trypsin digestion, revealed high similarity with the conserved catalytic phosphohistidine site and with the C-terminal of NDPKs. Acid and alkali treatments of [32P]-labelled pea mitochondrial NDPK indicated the presence of acid-stable as well as alkali-stable phosphogroups. Thin-layer chromatography experiments revealed serine as the acid-stable phosphogroup. The alkali-stable labelling probably reflects phosphorylation of the conserved catalytic histidine residue. In phosphorylation experiments, the purified pea mitochondrial NDPK was labelled more heavily on serine than histidine residues. Furthermore, kinetic studies showed a faster phosphorylation rate for serine compared to histidine. Both ATP and GTP could be used as phosphate donor for histidine as well as serine labelling of the pea mitochondrial NDPK.     

Mechanism of endogenous phosphorylation of microtubule proteins during GTP-induced microtubule assembly and implications for stability of the assembled structures

Cycle-purified microtubule protein from mammalian brain incorporated [32P]Pi upon incubation with [gamma-32P]GTP under the conditions used to promote assembly. This phosphorylation also occurred in the same proteins when phosphorylated with [gamma-32P]ATP and was only slightly stimulated by cAMP. GTP was a much less effective substrate than ATP. The transfer of phosphoryl groups from [gamma-32P]GTP to endogenous proteins followed a linear time-course and was stimulated by low concentrations of ATP and, more efficiently, by ADP. These data are in agreement with the predictions derived from a mechanism of phosphorylation by which [gamma-32P]GTP does not act as a phosphoryl donor for the protein kinase activity but, instead, only as a repository of high group transfer potential phosphoryl groups used to make [gamma-32P]ATP, from contaminating ADP, by means of the nucleoside diphosphate kinase activity. Using 100 mM fluoride, which suppressed protein phosphorylation without inhibiting the nucleoside diphosphate kinase activity, formation of [gamma-32P]ATP was detected. Fluoride was also able to protect microtubules from a slow depolymerization which was found to occur during long-term incubation of microtubules. This indicates that the phosphorylation observed in the presence of GTP is sufficient to destabilize microtubules.     

Synthesis and affinity purification of beta-32P-labeled [gamma-S]GTP

A method for the synthesis and purification of guanosine 5'-[gamma-S]triphosphate labeled with 32P in the beta-position is described. The first step in the synthesis involves the quantitative transfer of 32Pi from [gamma-32P]dATP to 5'-GMP catalyzed by GMP kinase. Further incubation of the beta-32P]GDP product with [gamma-S]GTP and nucleoside diphosphate kinase results in the synthesis of [beta-32P][gamma-S]GTP with a yield of 10 to 18%. The 32P-labeled [gamma-S]nucleotide is purified by binding to mercury-agarose and eluting with buffer containing beta-mercaptoethanol. Specific incorporation of 32P into the beta-position was demonstrated by treating [beta-32P][gamma-S]GTP with 7% formic acid to remove the gamma-thiophosphate and digesting the remaining [beta-32P]GDP with nucleotide pyro-phosphatase. Although 5'-GMP was released after pyrophosphatase digestion, the only 32P radioactivity detected was as inorganic phosphate.     

A 3-aminobenzamide-resistant labeled protein in [32P]NAD+-labeled cells

A series of proteins are covalently labeled when human lymphocytes are incubated with [32P]NAD+. The majority of this labeling is effectively inhibited when the lymphocytes are coincubated with 3-aminobenzamide, a potent inhibitor of poly(ADP-ribose) polymerase. However, labeling of a 72 000 molecular weight protein was resistant to the inhibitory effect of 3-aminobenzamide. Labeling of this protein from [32P]NAD+ was shown to be Mg2+-dependent. The 72 000 molecular weight protein could also be labeled on incubation with [alpha-32P]ATP, [gamma-32P]ATP and [32P]orthophosphate, but not from [3H]NAD+ or [14C]NAD+. In the present study, we show that the 72 000 molecular weight protein is not ADP-ribosylated but rather, phosphorylated on incubation with [32P]NAD+. This phosphorylation appears to occur via an Mg2+-dependent conversion of NAD+ to AMP with the eventual utilization of the alpha-phosphate for phosphorylation of the 72 000 molecular weight protein.     

Bovine brain Na+, K+-stimulated ATP phosphohydrolase studied by a rapid-mixing technique. Detection of a transient [32P]phosphoenzyme formed in the presence of potassium ions.

1. Conditions for binding of [gamma-32P]ATP to bovine brain Na+,K+-stimulated ATPase were investigated by the indirect technique of measuring the initial rate of 32P-labelling of the active site of the enzyme. 2. At 100 muM [gamma-32P]ATP in the presence of 3 mM MgCl2, approximately the same very high rate of formation of [32P]phosphoenzyme was obtained irrespective of whether [gamma-32P]ATP was added to the enzyme simultaneously with, or 70 ms in advance of the addition of NaCl. A comparatively slow rate of phosphorylation was obtained at 5 muM[gamma-32P]ATP without preincubation. However, on preincubation of the enzyme with 5 muM[gamma-32P]ATP a rate of formation of [32P]phosphoenzyme almost as rapid as at 100 muM[gamma-32P]ATP was observed. 3. A transient [32P]phosphoenzyme was discovered. It appeared in the presence of K+, under conditions which allowed extensive binding of [gamma-32P]-ATP. The amount of [gamma-32P]ATP that could be bound to the enzyme seemed to equal the amount of [32P] phosphorylatable sites. 4. The formation of the transient [32P] phosphoenzyme was inhibited by ADP. The transient [32P] phosphoenzyme was concluded mainly to represent the K+-insensitive and ADP-sensitive E1-32P. 5. When KCl was present in the enzyme solution before the addition of NaCl only a comparatively slow rate of phosphorylation was observed. On preincubation of the enzyme with [gamma-32]ATP an increase in the rate of formation of [32P] phosphoenzyme was obtained, but there was no transient [32P]-phosphoenzyme. The transient [32P]phosphoenzyme was, however, detected when the enzyme solution contained NaCl in addition to KCl and the phosphorylation was started by the addition of [gamma-32P]ATP.     

Studies on the specific activity of [gamma-32P]ATP in adipose and other tissue preparations incubated with medium containing [32P]phosphate

The specific activity of the gamma-32P position of ATP was measured in various tissue preparations by two methods. One employed HPLC and the enzymatic conversion of ATP to glucose 6-phosphate and ADP. The other was based on the phosphorylation of histone by catalytic subunit of cAMP-dependent protein kinase (Hawkins, P.T., Michell, R.H. and Kirk, C.J. (1983) Biochem. J. 210, 717-720). The HPLC method also allowed the incorporation of 32P into the (alpha + beta)-positions of ATP to be determined. In rat epididymal fat-pad pieces and fat-cell preparations the specific activity of [gamma-32P]ATP attained a steady-state value after 1-2 h incubation in medium containing 0.2 mM [32P]phosphate. Addition of insulin or the beta-agonist isoprenaline increased this value by 5-10% within 15 min. Under these conditions the steady-state specific activity of [gamma-32P]ATP was 30-40% of the initial specific activity of the medium [32P]phosphate. However, if allowance was made for the change in medium phosphate specific activity during incubations the equilibration of the gamma-phosphate position of ATP with medium phosphate was greater than 80% in both preparations. The change in medium phosphate specific activity was a combination of the expected equilibration of [32P]phosphate with exchangeable intracellular phosphate pools plus the net release of substantial amounts of tissue phosphate. At external phosphate concentrations of less than 0.6 mM the loss of tissue phosphate to the medium was the major factor in the change in medium phosphate specific activity. It is concluded that little advantage is gained in employing external phosphate concentrations of less than 0.6 mM in experiments concerned with the incorporation of phosphate into proteins and other intracellular constituents. Indeed, a low external phosphate concentration may cause depletion of important intracellular phosphorus-containing components.     

Nuclear protein phosphorylation in isolated nuclei from HeLa cells. Evidence that 32P incorporation from [gamma-32P]GTP is catalyzed by nuclear kinase II

A nuclear system for studying nuclear protein phosphorylation is characterized, using as phosphate donor either low levels of [gamma-32P]GTP, low levels of [gamma-32P]ATP, or low levels of labeled ATP plus excess unlabeled GTP. Since nuclear casein kinase II is the only described nuclear protein kinase to use GTP with high affinity, low levels of GTP should specifically assay this enzyme. ATP should measure all kinases, and ATP plus unlabeled GTP should measure all kinases except nuclear casein kinase II (ATP-specific kinases). The results are consistent with these predictions. In contrast with the ATP-specific activity, endogenous phosphorylation with GTP was enhanced by 100 mM NaCl, inhibited by heparin and quercetin, stimulated by polyamines, and did not use exogenous histone as substrate. The GTP- and ATP-specific kinases phosphorylated different subsets of about 20 endogenous polypeptides each. Addition of purified casein kinase II enhanced the GTP-supported phosphorylation of the identical proteins that were phosphorylated by endogenous kinase. These results support the hypothesis that activity measured with GTP is catalyzed by nuclear casein kinase II, though other minor kinases which can use GTP are not ruled out. Preliminary observations with this system suggest that the major nuclear kinases exist in an inhibited state in nuclei, and that the effects of polyamines on nuclear casein kinase II activity are substrate specific. This nuclear system is used to determine if the C-proteins of hnRNP particles, previously shown to be substrates for nuclear casein kinase II in isolated particles, is phosphorylated by GTP in intact nuclei. The results demonstrate that the C-proteins are effectively phosphorylated by GTP, but in addition they are phosphorylated by ATP-specific kinase activity.     

5-Methyltryptamine decreases net accumulation of 32P into the polyphosphoinositides from [gamma-32P]ATP in a cell-free system from blowfly salivary glands. Activation of breakdown of the newly synthesized [32P]polyphosphoinositides

Incubation of blowfly salivary gland homogenates with 30 microM [gamma-32P]ATP resulted in a rapid, Mg2+-dependent, synthesis of [32P]polyphosphoinositides and [32P]phosphatidic acid. 5-Methyltryptamine, in the presence of 10 microM guanosine 5'-(3-O-thio)trisphosphate, reduced the net accumulation of 32P label into phosphatidylinositol-4,5-P2 and phosphatidylinositol-4-P by 35 and 20%, respectively. 5-Methyltryptamine did not affect synthesis of [32P]phosphatidic acid. Phosphorylation of polyphosphoinositides was not affected by 5-methyltryptamine. In membranes labeled in vitro with [gamma-32P]ATP, 5-methyltryptamine stimulated a rapid breakdown of the [32P]polyphosphoinositides. These results indicate that in blowfly salivary gland homogenates, hormone stimulates breakdown of the newly synthesized polyphosphoinositides. In the presence of hormone, the rate of polyphosphoinositide synthesis does not compensate for the rate of polyphosphoinositide degradation.     

Studies on insulin-stimulated phosphorylation of acetyl-CoA carboxylase, ATP citrate lyase and other proteins in rat epididymal adipose tissue. Evidence for activation of a cyclic AMP-independent protein kinase.

Protein kinase activity in high-speed supernatant fractions prepared from rat epididymal adipose tissue previously incubated in the absence or presence of insulin was investigated by following the incorporation of 32P from [gamma-32P]ATP into phosphoproteins separated by sodium dodecyl sulphate/polyacrylamide-gel electro-phoresis. Incorporation of 32P into several endogenous proteins in the supernatant fractions from insulin-treated tissue was significantly increased. These included acetyl-CoA carboxylase and ATP citrate lyase (which exhibit increased phosphorylation within fat-cells exposed to insulin), together with two unknown proteins of subunit Mr 78000 and 43000. The protein kinase activity increased by insulin was distinct from cyclic AMP-dependent protein kinase, was not dependent on Ca2+ and was not appreciably affected by dialysis or gel filtration. The rate of phosphorylation of added purified fat-cell acetyl-CoA carboxylase and ATP citrate lyase was also increased by 60-90% in high-speed-supernatant fractions prepared from insulin-treated tissue. No evidence for any persistent changes in phosphoprotein phosphatase activity was found. It is concluded that insulin action on acetyl-CoA carboxylase, ATP citrate lyase and other intracellular proteins exhibiting increased phosphorylation involves an increase in cyclic AMP-independent protein kinase activity in the cytoplasm. The possibility that the increase reflects translocation from the plasma membrane, perhaps after phosphorylation by the protein tyrosine kinase associated with insulin receptors, is discussed.     

Incorporation of [32P]- and [14C]-ATP intoEscherichia coli isocitrate lyase

InEscherichia coli, isocitrate lyase has been shown to be phosphorylated in vitro by [-³²P]-ATP on histidine residues. This phosphorylation is believed to be necessary for activity of this enzyme. Previous work has shown that treatment of isocitrate lyase with acid phosphatase leads to a decrease in activity as well as a loss of incorporated [³²P]-phosphate in a time-dependent manner. In addition to phosphorylation by [-³²P]ATP, isocitrate lyase has been found to incorporate radioactive label from [-³²P]ATP and from [¹⁴C]ATP. This finding may indicate that more than one type of covalent modification occurs on this enzyme. Isocitrate lyase activity, inE. coli, may be regulated by posttranslational modification in several ways.     

Direct photoaffinity labeling of Kir6.2 by [gamma-(32)P]ATP-[gamma]4-azidoanilide

ATP-sensitive potassium (K(ATP)) channels are under complex regulation by intracellular ATP and ADP. The potentiatory effect of MgADP is conferred by the sulfonylurea receptor subunit of the channel, SUR, whereas the inhibitory effect of ATP appears to be mediated via the pore-forming subunit, Kir6.2. We have previously reported that Kir6.2 can be directly labeled by 8-azido-[gamma-(32)P]ATP. However, the binding affinity of 8-azido-ATP to Kir6.2 was low probably due to modification at 8' position of adenine. Here we demonstrate that Kir6.2 can be directly photoaffinity labeled with higher affinity by [gamma-(32)P]ATP-[gamma]4-azidoanilide ([gamma-(32)P]ATP-AA), containing an unmodified adenine ring. Photoaffinity labeling of Kir6.2 by [gamma-(32)P]ATP-AA is not affected by the presence of Mg(2+), consistent with Mg(2+)-independent ATP inhibition of K(ATP) channels. Interestingly, SUR1, which can be strongly and specifically photoaffinity labeled by 8-azido-ATP, was not photoaffinity labeled by ATP-AA. These results identify key differences in the structure of the nucleotide binding sites on SUR1 and Kir6.2.     

Lipid phosphorylation in chloroplast envelopes. Evidence for galactolipid CTP-dependent kinase activities

Lipid phosphorylation takes place within the chloroplast envelope. In addition to phosphatidic acid, phosphatidylinositol phosphate, and their corresponding lyso-derivatives, we found that two novel lipids underwent phosphorylation in envelopes, particularly in the presence of carrier-free [gamma-(32)P]ATP. These two lipids incorporated radioactive phosphate in chloroplasts in the presence of [gamma-(32)P]ATP or [(32)P]P(i) and light. Interestingly, these two lipids were preferentially phosphorylated in envelope membranes in the presence [gamma-(32)P]CTP, as the phosphoryl donor, or [gamma-(32)P]ATP, when supplemented with CDP and nucleoside diphosphate kinase II. The lipid kinase activity involved in this reaction was specifically inhibited in the presence of cytosine 5'-O-(thiotriphosphate) (CTPgammaS) and sensitive to CTP chase, thereby showing that both lipids are phosphorylated by an envelope CTP-dependent lipid kinase. The lipids were identified as phosphorylated galactolipids by using an acid hydrolysis procedure that generated galactose 6-phosphate. CTPgammaS did not affect the import of the small ribulose-bisphosphate carboxylase/oxygenase subunit into chloroplasts, the possible physiological role of this novel CTP-dependent galactolipid kinase activity in the chloroplast envelope is discussed.     

Use of 8-azidoguanosine 5'-[gamma-32P]triphosphate as a probe of the guanosine 5'-triphosphate binding protein subunits in bovine rod outer segments

In an in vitro incubation, 8-azidoguanosine 5'-[gamma-32P]triphosphate ( [gamma-32P]-8-azido-GTP) labeled bleached rhodopsin independent of ultraviolet light. Characterization of this labeling indicated that rhodopsin was phosphorylated with [gamma-32P]-8-azido-GTP as a phosphate donor. At low concentrations, ATP increased this labeling activity 5-fold. In the same incubation, [gamma-32P]-8-azido-GTP also labeled G alpha (Mr 40 000). This labeling was ultraviolet light dependent. G beta (Mr 35 000) was also labeled dependent for the most part upon ultraviolet light, but a smaller component of labeling appeared to result from phosphorylation. Differential labeling of G alpha and G beta was found to vary intricately with experimental conditions, especially prebleaching of rhodopsin, tonicity of the medium, and the presence or absence of 2-mercaptoethanol. Affinity labeling of G alpha and G beta by [gamma-32P]-8-azido-GTP in competition with ATP or GTP was kinetically complex, consistent with possible multiple binding sites for GTP on both subunits. Independent evidence for two or more binding sites on G alpha has been offered by other laboratories, and recently, at least one binding site on G beta and its analogues among the N proteins of adenylate cyclases has been identified.     

Existence in animal tissues of adenosine triphosphate thiamin diphosphate phosphotransferase [EC 2.7.4.15]

An enzyme which catalyzes the synthesis of thiamin triphosphate from thiamin diphosphate (TDP), thiamindiphosphate kinase (ATP:thiamin diphosphate phosphotransferase) [EC 2.7.4.15], was detected in animal tissues. The enzyme was partially purified (150-fold) from the cytosol fraction of guinea pig brain. The enzyme reaction required free (not protein-bound) TDP, ATP, Mg2+, and a cofactor, which is a low molecular weight and heat-stable compound. The enzyme activity was optimal at pH 11 and at 25 degrees C. A stoichiometric transfer of 32P from [gamma-32P]ATP to TDP was demonstrated. Km values for TDP and ATP were calculated to be 1.1 mM and 10 microM, respectively, and Vmax was 868 nmol/mg of protein/hr. The enzyme was found solely in the cytosol fraction of guinea pig brain and was also detectable in the skeletal muscle and heart. These results provide strong evidence for the existence of TDP kinase in animal tissues.