Phosphorylation of some thiamine analogs by yeast thiamine pyrophosphokinase]

A rapid efficient method of separation of the thiamine pyrophosphokinase reaction products (ATP: thiamine pyrophosphotransferase) on the column packed with DEAE-Sephadex A-25 and their subsequent identification by direct spectrophotometry is suggested. Phosphorylation of some thiamine analogs substituted at the second position of the pyrimidine ring was studied. It was shown that in addition to thiamine, the enzyme transfers the pyrophosphate group to some of its derivatives. The vitamin analogs devoid of quaternary nitrogen in the thiazole cycle, do not form pyrophosphate ethers (thus being unable to act as substrates), whereas 2'-phenoxythiamine, 2'-methoxythiamine and especially 2'-phenylthiamine are phosphorylated at a greater rate than does the "true" substrate, thiamine, under similar conditions.     

Identification of the functional groups of yeast thiamine pyrophosphokinase]

The content of free sulfhydril groups in yeast thiamine pyrophosphokinase (EC 2.7.6.2) was studied. Their blocking was found not to affect considerably the enzyme activity. N-bromsuccinimide developes the inhibitory effect only if taken in excessive concentrations, which indicates that tryptophane has no key position for the enzyme-substrate complex formation. On account of high speed of photoinactivation with Rose bengale and methilene blue, sigmoid dependence of activity loss on pH under irradiation, characteristic narrowing of the modified enzyme absorption spectrum, it is suggested that imidazole residue of the histidine is one of the functional groups of thiamine pyrophosphokinase.     

Kinetic characteristics of thiamine diphosphate biosynthesis by thiamine pyrophosphokinase from rat liver]

The kinetic analysis of bisubstrate enzymatic reaction catalysed by electrophoretically homogenous thiamine pyrophosphokinase (EC 2.7.6.2), isolated from rat liver has been carried out. Kinetic studies of the initial rates in the absence of the products and inhibition by the reaction products as well as the data from the equilibrium dialysis suggest that the reaction proceeds through the formation of a ternary enzyme-substrate complex. The combination with substrates and release of the products appears to be highly ordered. A possible scheme of the reaction mechanism is discussed.     

Interaction centres of purine nucleotides: adenosine-5'-diphosphate and adenosine-5'-triphosphate in their reactions with tetramines and Cu(II) ions

The interactions between the nucleotides: adenosine-5'-diphosphate (ADP) and adenosine-5'-triphosphate (ATP) with spermine (Spm) and 1,11-diamine-4,8-diazaundecane (3,3,3-tet), as well as Cu(II) ions are studied. In the metal-free systems nucleotide-polyamine molecular complexes have been found to form, in which the interaction centres are the nitrogen atoms of the purine ring N(1) and N(7), oxygen atoms of the phosphate group of the nucleotide (for 3,3,3-tet) and protonated nitrogen atoms of the polyamine. Significant differences in the mode of metallation between the systems with Spm and 3,3,3-tet have been established. In the systems with Spm, the main products are protonated species with [N(7),O] chromophore and the nitrogen N(1) is involved in the intramolecular interaction additionally stabilising the complex. In the systems with 3,3,3-tet the formation of metal-ligand-ligand (MLL) species has been observed, in which the oxygen atoms from the phosphate group and the nitrogen atoms from the polyamine are involved in the metallation, while the N(1) and N(7) atoms from the purine ring of the nucleotide remain outside the inner coordination sphere of the copper ion. The main centre of metallation in the nucleotide, both with Spm and 3,3,3-tet, is the phosphate group of the nucleotide.     

Nucleotide specificity of rat liver thiamine pyrophosphokinase]

The nucleotide specificity of thiamine pyrophosphokinase from rat liver was studied. The enzyme was found to possess a sufficiently wide substrate specificity. Any of the nucleotides can be a donor of the pyrophosphate groups for TDP biosynthesis at two pH optima of the enzyme in the T-kinase reaction under the Mg2++/NTP optimal ratio. The minimal requirement for the substrate structure allowing to predict the position of the split nucleotide phosphoester bond was postulated.     

Quaternary structure and allosteric properties of thiamine pyrophosphokinase from rat liver]

Using electrophoresis in polyacrylamide gel in the presence of sodium dodecyl sulfate thiamine pyrophosphokinase (EC 2.7.6.2) was found to possess quaternary structure and consist of two polypeptide chains. It was shown that besides active centres, the oligomer has allosteric centres for binding of Mg2+ ions, since treatment by HgCl2 and heating of the enzyme lead to complete "desensibilisation". This results in a disappearance of the S-shaped curve of the dependence of reaction rate on Mg2+ concentration, the Hill coefficient coming down to 1. It is assumed that thiamine pyrophosphokinase belongs to the class dissociating regulatory enzymes.     

Mechanisms of rat liver thiamine pyrophosphokinase activation by magnesium ions]

The role of Mg2+ in the activation of thiamine pyrophosphokinase from rat liver was studied. The dependence of the thiamine pyrophosphokinase reaction rate on total and free ATP concentrations suggests that the role of the metal comes down to optimization of conditions of the active enzyme-substrate complex formation due to incorporation of the reactions of Mg2+ and ATP-4 consecutive acception, the affinity of the latter for the enzyme being higher than that of Mg-ATP-2. The kinetic parameters of the reaction were determined. In the absence of ATP-4 free Mg2+ ions were shown to compete with the Mg-ATP-2 complex (Ki = 18 . 10(-3) M). Thiamine pyrophosphokinase is also inhibited by free ATP-4 with Ki = 3 . 10(-3) M.     

Evidence for existence and a tentative identification of coenzyme in yeast thiamine pyrophosphokinase.

Thiamine pyrophosphokinase (E.C. 2.7.6.2.) from $\text{Saccharomyces cerevisiae}$ was found to require the presence of a non-protein, non-metal compound for its activity. $\text{myo}$-Inositol was found capable of stimulating the kinase activity in the presumably resolved but otherwise crude sample of the enzyme. The hexytol was also found capable of inducing the enzyme in growing yeast cells. The cultured yeast cells, in which the kinase had been induced, were used as source of the enzyme for its purification. The compound that had been left adsorbed to the final column of DEAE-Sephadex was proved to have a coenzyme activity towards the enzyme and tentatively identified with $\text{myo}$-inositol 1-pyrophosphate. A sample of synthetic $\text{myo}$-inositol 1-pyrophosphate was made and its coenzyme activity was observed.     

A catalytic site of protein disulfide isomerase probed with adenosine-5'-triphosphate analogs

Anthraniloyl adenosine-5'-triphosphate (Ant-ATP) and etheno-adenosine-5'-triphosphate (epsilon-ATP) complexed to Mg(2+) ions are substrates of protein disulfide isomerase (PDI). epsilon-ATP, coordinated to Tb(3+) ions, was used as a probe of the ATPase binding site. Sensitized luminescence arising from resonance energy transfer from epsilon-adenine to Tb(3+) is quenched by PDI. The luminescence results are discussed in reference to a model in which the distance of separation between epsilon-adenine (donor) and Tb(3+) (acceptor) is increased upon binding of PDI. The interaction of a small peptide of 14 amino acid residues with the b/b' domain of the protein does not influence the ATPase activity. The phosphorescence, fluorescence and fluorescence anisotropy of bound epsilon-ATP are not perturbed by the binding of the small molecular weight peptide to PDI. It is suggested that the peptide and ATP do not share a common binding site on the b/b' domain.     

Partial purification and properties of thiamine pyrophosphokinase from pig brain.

Pig brain thiamine pyrophosphokinase (ATP: thiamine pyrophosphotransferase, EC 2.7.6.2) was purified 260-fold over extracts of brain acetone powder. A direct, radiometric assay was used to follow the purification. By isoelectric focusing, the purified enzyme appeared to have an isoionic point of approx. pH 4.2, but these preparations were still not homogeneous by disc-gel electrophoresis nor by analytical ultracentrifugation. The purified enzyme has a broad pH optimum extending from pH 8.3 to 9.3 in 0.028 M phosphate/glycylglycine buffers. For optimal enzymatic activity, the ratio of magnesium to ATP must be fixed at 0.6, which suggests that for this ATP-pyrophosphoryl transfer reaction, the enzymatically preferred reactant may be Mg(ATP)6-/2. A preliminary study of the kinetics of the reaction reveals that the enzyme may function via a partial "ping-pong" mechanism; on this basis, dissociation constants for ATPt and for thiamine were evaluated. Pyrithiamine, butylthiamine, ethylthiamine, and oxythiamine appeared to be competitive inhibitors with respect to thiamine as the variable substrate, and their inhibitor dissociation constants were calculated. The relatively poor affinity of oxythiamine to the enzyme emphasizes the 4-amino group in the pyrimidine ring as one of the specificity requirements for thiamine pyrophosphokinase. Preliminary values for the apparent equilibrium coefficient of the thiamine pyrophosphokinase-catalyzed reaction, in terms of total species, has been approximated at several initial concentrations of reactants: e.g. K'eq,app = (see article) 9.66 - 10(-3) M; and [Th]initial - 1 - 10(-6) and 2 - 10(-6) M, respectively, where TDP, Th, t and eq represent thiamine diphosphate, thiamine, total concentration and equilibrium concentration, respectively.     

Interaction of formycin A-5'-triphosphate with pyruvate carboxylase

Formycin triphosphate (FTP), a fluorescent analogue of ATP, is a competitive inhibitor of chicken liver pyruvate carboxylase with respect to ATP. The chicken liver enzyme is unable to utilise FTP as a substrate at a measureable rate, but FTP is a poor substrate for the sheep liver enzyme. When FTP binds to the enzyme, its fluorescence is enhanced and in this way the formation of enzyme-FTP complexes can be monitored. Using this property of FTP, the effect of Mg2+ and acetyl-CoA on the binding of nucleoside triphosphates to the chicken liver enzyme was examined. Mg2+ was found to enhance the binding of FTP whilst acetyl-CoA reduced the fluorescence intensity of a mixture of Mg2+, enzyme and FTP. Most probably, this was caused by a conformational change in the enzyme which changed the environment of the fluorophore.     

Isolation and characterization of a human thiamine pyrophosphokinase cDNA

A human thiamine pyrophosphokinase cDNA clone (hTPK1) was isolated and sequenced. When the intact hTPK1 open reading frame was expressed as a histidine-tag fusion protein in Escherichia coli, marked enzyme activity was detected in the bacterial cells. The hTPK1 mRNA was widely expressed in various human tissues at a very low level, and the mRNA content in cultured fibroblasts was unaffected by the thiamine concentration of the medium. The chromosome localization of the hTPK1 gene was assigned to 7q34.     

Primary structure of tRNA Thr 1a and b from brewer's yeast]

One of the two major species of brewer's yeast tRNA threonine (tRNA Thr 1) has been purified by countercurrent distribution followed by two chromatographic steps (respectively on a Sepharose 4B and a BD-cellulose column). Complete digestion with pancreatic and T1 RNases and a partial hydrolysis with T1 RNase followed by the isolation and determination of the nucleotide sequences of the resulting fragments permitted the derivation of its primary structure. tRNA Thr 1 is in fact a mixture of two subspecies differing only by a A49-U65 base pair in 50 per cent of the molecules which is replaced by a G49-C65 pair in the other 50 per cent. These two subspecies consist of 76 nucleotide residues including 14 minor nucleotides. They show a characteristic m3C at the 3'terminal end of the anticodon loop, an anticodon I-G-U followed by t6A and C48, uncompletely modified (50 per cent) to m5C within the 5 nucleotides long extra-arm. The minor nucleotides m2G m2 2G are located at positions in which they generally occur in the tRNA structures as does m1A within the T-psi-C loop.     

Activation by adenosine-5'-triphosphate of glutamic decarboxylase from a subcellular fraction of mouse brain.

Glutamate decarboxylase from a mouse brain P2 fraction undergoes a twofold activation in the presence of 0.5 mM ATP. No such stimulation by ATP occurs if the enzyme is assayed in the presence of excess pyridoxal phosphate as cofactor. The ATP-induced stimulation is almost completely eliminated if the enzyme is dialysed before its assay. [lambda-32P]ATP present during the enzyme measurement is converted to [32P]pyridoxal phosphate. These results demonstrate that the activation produced by ATP is the result of the generation of cofactor during the course of the assay. This phenomenon may be a reflection of a control mechanism of glutamate decarboxylase activity.     

Interaction of 8-substituted derivatives and adenosine-3',5'-cyclophosphate esters with protein kinase from pig brain]

A synthesis of previously unknown 8-substituted derivatives and alkyl esters of cyclic adenosine-3',5'-monophosphate, containing reactive groups, was carried out. The interaction of the compounds obtained with a homogeneous preparation of protein kinase from pig brain was studied. It was found that all compounds, with the exception of neutral esters of 3',5'-AMP, activate the enzyme and competitively inhibit 3H-labelled 3',5'-cAMP binding by the regulatory subunit of protein kinase. The activating effect and affinity of 8-(beta-aminoethylamino)-3',5'-cAMP for protein kinase was 10 times lower than that for 3',5'-cAMP and other 8-substituted derivatives of the cyclic nucleotide. It was found that 8-(N-chloroacetylaminoethylamino)-3',5'-cAMP interaction with the enzyme is of irreversible type, which suggest covalent blocking of the nucleophilic group of the 3',5'-cAMP binding site of protein kinase. The data obtained indicate that the 3',5'-cAMP molecule is bound to the regulatory site of protein kinase in the syn-conformation. The previously made assumption on the crucial importance of the negative charge in the 3',5'-cyclophosphate system for the interaction of cyclic AMP with the regulatory subunit of protein kinase has been thus confirmed.     

A kinetic and structural characterization of adenosine-5'-triphosphate: ribonucleic acid adenylyltransferase from Pseudomonas putida.

A catalytic and structural study of ATP:RNA adenylyltransferase (EC 2.7.7.19) from the particulate fraction of Pseudomonas putida was made. During the large-scale purification of this enzyme, designated adenylyltransferase B, a previously undetected ATP-incorporating activity, designated adenylyltransferase A, was observed. Adenylyltransferases A and B were indistinguishable catalytically; however, they differed in their chromatographic and sedimentation properties. Adenylyltransferases A and B were resolved by phosphocellulose, by poly (U)-Sepharose and by Bio-Gel P-100 chromatographies. Adenylytransferase A was determined to have a sedimentation coefficient (S020,w) of 9.3 S and B of 4.3 S. The molecular weight of adenylyltransferase A was estimated to be 185000 and that of adenylyltransferase B to be 50000-60000. Apparently, adenylyltransferase A was generated from adenylyltransferase B during the purification. The AMP incorporation catalyzed by adenylyltransferases A and B was inhibited by two derivatives of the antibiotic rifamycin, AF/013 (50% at 5 mug/ml) and AF/DNFI (50% at 10 mug/ml). The 5'-triphosphate derivative (3'-dATP) of the drug cordycepin (3'-deoxyadenosine/ was a competitive inhibitor with ATP for both adenylyltransferases. The Ki for 3'-deoxyadenosine 5'-triphosphate was 6 - 10(-4)--10 - 10(-4) M, while the Km for ATP was 1 - 10(-4)--2 - 10(-4) M. Several other anaolgs of ATP, 2'-deoxyadenosine 5' triphosphate, 2'-O-methyl ATP, or the fluorescent 3-beta-D-ribofuranosylimidazo [2,1-i] purien 5'-triphosphate did not affect the activity of adenylyltransferase A or B. Poly(U) and poly(dT) were competitive inhibitors of the ribosomal RNA-primed polymerization reaction. The Ki for poly(U) or poly(dT), in terms of nucleotide phosphate, was 4 - 10-6)--10 - 10(-6) M for adenylyltransferases A and B, compared to 2 - 10(-4)--4 - 10(-4) M for the Km of ribosomal RNA. The inhibition was a result of the competition between the non-priming poly(U), or poly(dT), and ribosomal RNA for the primer binding site on the enzyme.     

Purification and properties of thiamine pyrophosphokinase in Paracoccus denitrificans

The existence of thiamine pyrophosphokinase [EC 2.7.6.2] in procaryotic cells was first demonstrated in Paracoccus denitrificans (J. Bacteriol, (1976) 126, 1030-1036). The enzyme was therefore purified from this organism to determine its molecular structure and properties. Thiamine pyrophosphokinase which was purified 620-fold from P. denitrificans showed a single band on both polyacrylamide and sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, and the molecular weight in the latter case was calculated to be 23,000. Gel filtration analysis using Sephadex G-150 gave a molecular weight of 44,000, indicating that this enzyme contains at least two identical subunits. Although sedimentation equilibrium analysis gave a molecular weight of 96,000, indirect evidence suggests that the form having this molecular weight is an aggregate of the functional dimer. The activity of the purified enzyme required thiamine, ATP, and Mg2+, and the enzyme catalyzed thepyrophosphorylation of thiamine by ATP. Km values for thiamine and ATP were 10 microM and 0.38 mM, respectively. The activity was competitively inhibited by pyrithiamine, giving a Ki value of 19 microM. Oxythiamine and chloroethylthiamine were very weak inhibitors of the enzyme. The activity was also inhibited by the product, TPP.     

Identification of the two missing bacterial genes involved in thiamine salvage: thiamine pyrophosphokinase and thiamine kinase

The genes encoding thiamine kinase in Escherichia coli (ycfN) and thiamine pyrophosphokinase in Bacillus subtilis (yloS) have been identified. This study completes the identification of the thiamine salvage enzymes in bacteria.