A simple procedure for the synthesis of [32P]phosphoenolpyruvate via the pyruvate kinase exchange reaction at equilibrium

A one step procedure is presented for the preparation of [³²P]phosphoenolpyruvate from [γ-³²P]ATP using pyruvate kinase. The reaction is carried out at chemical equilibrium and involves only an exchange of isotope between ATP and phosphoenolpyruvate. The initial phosphoenolpyruvate/ATP ratio in the reaction mixture determines the degree of ³²P incorporation into phosphoenolpyruvate when isotopic equilibrium is achieved.     

An easy and rapid method for the measurement of [γ-32P]ATP specific radioactivity in tissue extracts obtained from in vitro rat heart preparations labeled with 32Pi

A rapid method for the measurement of [γ-³²P]ATP specific radioactivity in tissue extracts containing other ³²P-labeled compounds is described. The neutralized acid extract is incubated with cyclic AMP-dependent protein kinase, cyclic AMP and casein. The incorporation of ³²P into casein from [γ-³²P]ATP is measured by perchloric acid precipitation of the protein on filter paper. ³²P-Casein formation is linearly related to the specific radioactivity of the [γ-³²P]ATP. Separation of ATP from other ³²P-labeled compounds is not required for the assay. Application of this method in the evaluation of [γ-³²P]ATP specific radioactivity in two rat cardiac muscle preparations exposed to ³²P_i is demonstrated.     

Regulation of hepatic acetyl coenzyme A carboxylase by phosphorylation and dephosphorylation

Acetyl CoA carboxylase, in a partially purified preparation, was inactivated by ATP in a time- and temperature-dependent reaction. Adenosine 3′,5′-monophosphate did not affect the inactivation. Further purification separated the carboxylase from a protein fraction which could greatly enhance the inactivation of the enzyme.Inactivation of the enzyme with [γ-³²P]ATP resulted in the incorporation of ³²P which copurified with the enzyme. No label was incorporated when [U-¹⁴C]ATP was used. When carboxylase inactivated by exposure to [γ-³²P]ATP was precipitated with antibody, isotope incorporation into the precipitate paralleled enzyme inactivation. The phosphate was bound to serine and threonine residues by an ester linkage.Sodium fluoride completely inhibited the activation of partially purified enzyme by magnesium ions. Activation by magnesium, accompanied by the release of protein-bound ³²P, was antagonistic to inactivation of the enzyme by ATP.The data presented in this communication are consistent with a mechanism for controlling acetyl CoA carboxylase activity by interconversion between phosphorylated and dephosphorylated forms. Phosphorylation of the enzyme by a portein kinase decreases enzyme activity, whereas dephosphorylation by a protein phosphatase reactivates the enzyme.     

An enzymatic method for [32P]phosphoenolpyruvate synthesis

A convenient method for the enzymatic synthesis of [³²P]phosphoenolpyruvate from [γ-³²P]ATP using partially pufified phosphoenolpyruvate carboxykinase from Escherichia coli is described. The synthesis was shown to convert essentially all the [γ-³²P]ATP to [³²P]phosphoenolpyruvate, which was subsequently separated from residual [γ-³²P]ATP and $\text{[}{}^{32}\text{P}\text{]P}{}_{\mathrm{<mtext>i</mtext>}}$ by chromatography on AG-1-X8-bicarbonate resin.     

A new and improved method for 3′-end labelling DNA using [α-32P]ddATP

We have synthesised dideoxyadenosine-5′-[α-³²P]triphosphate ([α-³²P]ddATP) at a specific activity of 3000 Ci/mmol and directly compared it with cordycepin-5′-[α-³²P]triphosphate ([α-³²P]KTP) as a means to 3′-end label DNA. The [α-³²P]ddATP was found to be three to five times more efficient than [α-³²P]KTP. Blunt and 3′-protruding ends were labelled more efficiently with [α-³²P]ddATP using terminal transferase than were the 5′-ends with [γ-³²P]ATP using polynucleotide kinase by standard methods. This improvement in efficiency of labelling DNA and the simplicity of the method allows 3′-end labelling of DNA to become a realistic alternative to 5′-end labelling. We have also compared [α-³²P]ddATP- and [α-³²P]KTP-labelled DNA in Maxam and Gilbert sequencing procedures and find that both give equally good results.     

Determination of phosphorylase kinase activity in crude homogenates by affinity chromatography on 5′-AMP Sepharose

A sensitive method for measuring phosphorylase kinase activity by the incorporation of ³²P from [γ-³²]ATP into phosphorylase in the presence of other phosphorylation reactions is described. The kinase reaction is carried out in a crude homogenate. After stopping the reaction, a portion of the reaction mixture is withdrawn for assay of phosphorylase conversion and the rest is applied on a 5′-AMP Sepharose column. Phosphorylase in both forms is retained on the column while other phosphorylated proteins and [γ-³²P]ATP are washed out. The phosphorylase is then eluted by 10 mm AMP and the radioactivity incorporated is counted.     

Preparation of (beta-32P)ribonucleoside-5'-triposphates using permeable cells of Escherichia coli

A rapid method for the preparation of [β-³²P]ribonucleoside-5′-triphosphates is described. The method involves the incubation of a ribonucleoside triphosphate with ³²P_i and E. coli cells made permeable to nucleotides. The labeled triphosphates can be isolated by preparative thin layer chromatography on poly(ethylene)imine cellulose plates. Labeled GTP, CTP, and UTP obtained by this method are more than 99% pure [β-³²P]compounds. Labeled ATP contains about equal amounts of label in the β- and γ-phosphate position. Pure [β-³²P]ATP can be obtained from this preparation by exchanging the γ-³²P against unlabeled P_i and reisolating the labeled ATP by charcoal adsorption and elution.     

32P-base analysis of DNA

A ³²P-labeling method for the base composition analysis of nonradioactive DNA was developed consisting of the digestion of DNA to deoxynucleoside 3′-monophosphates by incubation with a mixture of micrococcal nuclease and spleen phosphodiesterase, transfer of ³²P-label from [γ-³²P]ATP to the 5′-hydroxyl groups of the mononucleotides by T4 polynucleotide kinase, two-dimensional anion-exchange thin-layer chromatography on PEI-cellulose of the resultant [5′-³²P]deoxynucleoside 3′,5′-bisphosphates, autoradiography, and scintillation counting. The method was standardized to afford quantitative digestion of DNA to mononucleotides as well as to give quantitative incorporation of ³²P-label into the nucleotides in the DNA hydrolysate so as to make the method an accurate means for determining the base composition of eucaryotic DNA containing adenine, guanine, thymine, cytosine, and 5-methylcytosine.     

Erratum

RNA polynucleotide kinase has been shown to transfer [γ³²P] from ATP to 5-OH termini of endogenous nuclear RNA. The products of this reaction have been isolated in RNA larger than 125 after in vitro incubation of mouse L cell nuclei. About 20%–30% of these 5′-OH kinase products are polyadenylated. A sizeable fraction of the [γ³²P] label from ATP is also found in internal phosphodiester bonds after 30-minute nuclear incubation in vitro. The possibility of substantial [³²P] recycling via the α position of nucleoside triphosphate was ruled out because: (1) 2mM nucleoside triphosphates in the incubation medium, (2) limited nearestneighbor distribution 3′ and 5′ to the phosphodiester bond compared with that from [α³²P] UTP, (3) different nearest-neighbor distribution for RNA molecules > 12S and 12-3S, (4) relative insensitivity of the [γ³²P] incorporation to α-amanitin as compared with total RNA synthesis, (5) internal [³²P] appearance in RNA > 12S in less than five minutes of incubation, and (6) < 0.03% to 0.6% of the total [³²P] in the α position of nucleoside triphosphates after 30 minutes of incubation. The [γ³²P] incorporation was dependent on high ATP concentration and was insensitive to competition by inorganic phosphate. These results are consistent with the levels of 5′ RNA polynucleotide kinase activity in L cell nuclei and suggest the presence of an RNA ligase that can utilize the termini generated by the 5′-OH RNA kinase in a ligation reaction.     

Studies on the metabolism of ATP by isolated bacterial membranes: solubilization and phosphorylation of a protein component of the diglyceride kinase system

A soluble fraction, obtained by extracting E. coli cytoplasmic membrane vesicles with water, transfers radioactivity from [γ-³²P]ATP to a protein present in this soluble fraction. The formation of the [³²P]phosphoprotein appears to be reversible. Thus the protein can transfer its ³²P to ADP to form [³²P]ATP, and the phosphate on the protein can exchange with the phosphate of ATP. Preliminary evidence indicates that the phosphate moiety is linked to a histidine residue of the protein. The Mn²⁺ and ATP dependencies of [³²P]phosphoprotein formation are almost identical to the diglyceride kinase reaction previously reported in intact membrane vesicles. Although indirect evidence supports the involvement of the phosphoprotein in the diglyceride kinase reaction, the soluble fraction catalyzes only a slow formation of [³²P]phosphatidie acid from [γ-³²P]ATP and α,β-diglyceride.     

Assay of adenosine 3', 5' cyclic monophosphate by stimulation of protein kinase: a method not involving radioactivity

In order to meet a need for a cAMP assay which is not subject to interference by compounds in plant extracts, and which is suitable for use on occasions separated by many ³²P half-lives, an assay based on cAMP-dependent protein kinase has been developed which does not require the use of [γ-³²P]ATP. Instead of measuring the cAMP-stimulated increase in the rate of transfer of [γ-³²P] phosphate from [γ-³²P]ATP to protein, the rate of loss of ATP from the reaction mixture is determined. The ATP remaining after the protein kinase reaction is assayed by ATP-dependent chemiluminescence of the firefly luciferin-luciferase system. Under conditions of the protein kinase reaction in which a readily measurable decrease in ATP concentration occurs, the logarithm of the concentration of ATP decreases in proportion to the cAMP concentration, i.e., the reaction can be described by the equation: [ATP] = [ATP]₀ e^?[cAMP]kt. The assay based on this relationship can detect less than 1 pmol of cAMP. The levels of cAMP found with this assay after partial purification of the cAMP from rat tissue, algal cells, and the media in which the cells were grown agreed with measurements made by the cAMP binding-competition assay of Gilman, and the protein kinase stimulation assay based on transfer of [³²P] phosphate from [γ-³²P]ATP to protein. All of the enzymes and chemicals required for the assay of cAMP by protein kinase catalyzed loss of ATP can be stored frozen for months, making the assay suitable for occasional use.     

A radiotracer enzyme assay for phosphofructokinase using ( , , -32P) adenosine triphosphate

A radiotracer enzyme assay for phosphofructokinase using adenosine 5′-triphosphate[α,β,γ-³²P] is described in this paper. Here the rates of appearance of both [1-³²P]d-fructose 1,6-diphosphate and [α,β-³²P] adenosine 5′-diphosphate were followed to establish enzyme activity. The unique advantages of multiple rate determinations in a single reaction sequence which accrue from the use of a readily available multiply labeled cosubstrate are discussed. By an extension of this approach other labeled(¹) nucleotides of the type, N(¹P)_n, and enzymes in the Enzyme Commision categories, EC 2.7(phosphotransferases) and EC 6.1–6.4(ligases) are equally amenable to radionuclide assay.     

Convenient methods to determine the specific radioactivity of (gamma-32P)ATP of high specific activity.

A satisfactory method for the determination of the specific activity of highly labeled [γ-³²P]ATP has not been reported previously. Yields of high specific activity ³²P labeled material usually are too small to be detected by ultraviolet spectrophotometry or phosphate analysis. Recent reports describing the assay of ATP by enzyme catalyzed phosphate transfer to ³H labeled glucose (1) or galactose (2) are not suitable for use with highly labeled ³²P material since the crossover into the ³H channel will greatly exceed the radioactivity of the ³H labeled phosphate acceptor. Recently Schendel and Wells reported the preparation of essentially carrier free [γ-³²P]ATP. They indicated, however, that the specific activity of the labeled product could not be determined by conventional methods (3). We have developed and now routinely use an expedient method for the determination of the specific activity of picomole quantities of highly labeled [γ-³²P]ATP. This procedure measures the phosphate transfer from [γ-³²P]ATP to oligothymidylic acid [dT(pT)₁₀] catalyzed by bacteriophage T4 induced polynucleotide kinase. The specific activity is determined by measuring the radioactivity present in d-³²pT(pT)₁₀, and can be verified by an isotope dilution method employing the same assay. Specific activities as high as 240 Ci/mmole have been determined.     

Anomalies in 5'-end [32P] labelling of transfer RNA and partial sequence of a tRNAGlu from Scenedesmus obliquus

A chloroplast tRNA_m^Met species from $\text{Scenedesmus}\text{obliquus}$ is very poorly 5′-end [${}^{32}\text{P}$] labelled using [γ-³²P]ATP and T4 polynucleotide kinase. In sequencing the tRNA using standard 5′-labelled methods a very minor contaminating tRNA is preferentially labelled. The partial tRNA sequence determined by this method has an anticodon (CUC) for tRNA^Glu.     

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.     

A novel method for measurement of the specific radioactivity of gamma-32P ATP.

The specific radioactivity of the γ-phosphorus of ATP has been determined by an indirect method. Galactokinase is employed to transfer the terminal phosphate group of [γ-³²P] ATP to [1-³H] galactose. The doubly labeled galactose-1-phosphate is purified by ion exchange chromatography on QAE Sephadex. The specific radioactivity of the phosphorus is calculated from the ${}^{32}\text{P}{}^3\text{H}$ ratio. The method is extremely sensitive, requiring only 0.005 μmoles of ATP with a specific radioactivity of 1 μCi/μmole, and the chromatographic isolation of galactose-1-phosphate is simple and reproducible. The method is directly applicable to the determination of the specific radioactivity of [γ-³²P] ATP in biological samples.     

Nuclear protein phosphorylation in isolated nuclei from HeLa cells. Evidence that 32P incorporation from [γ-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 [γ-³²P]GTP, low levels of [γ-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.     

Properties of the 5'-terminus of tRNAHis: kinetics of polynucleotide kinase catalyzed exchange and effect of dephosphorylation on the aminoacylation reaction.

Bacteriophage T₄ induced polynucleotide kinase was found to be ineffective in transferring ³²P from [γ-³²P]ATP to the 5′-terminus of 5′-phosphorylated $\text{E. coli}$ tRNA^His using the ADP mediated exchange reaction. However, prior dephosphorylation with alkaline phosphatase allowed polynucleotide kinase catalyzed phosphorylation of tRNA^His. Contrary to reports for other tRNA species, alkaline phosphatase catalyzed 5′-terminus dephosphorylation destroys the amino acid accepting ability of tRNA^His. Aminoacylation competency of the tRNA^His is restored after phosphorylation with polynucleotide kinase.     

A simple modification to an enzymic method for the preparation of[γ-32P]ATP free of salt and buffer

An existing enzymic method for preparing [γ-³²P]ATP from 32P_i has been modified toyield [γ-³²P]ATP free of salt and buffer. ³²P is incorporated into the γ-position of ATP by isotopic exchange in the presence of glyceraldehyde 3-phosphate dehydrogenase and 3-phosphoglycerate kinase. Unreacted ³²P_i is separated from [γ-³²P]ATP by column chromatography on Dowex 1 bicarbonate. [γ-³²P]ATP is eluted with 2 m triethylammonium bicarbonate, which is then completely removed by freeze-drying.     

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.