Bacterial Synthesis of Nucleotides

The synthesis of inosinic acid from inosine and p-nitrophenylphosphate by the partially purified enzyme, nucleoside phosphotransferase, prepared from Escherichia coli (B-25) is described.

The results presented in this paper represent that the nucleotide, inosinic acid, synthesized by the nucleoside phosphotransferase of E. coli, used as an example of bacterial enzymes, is not always 5′-isomer and that most of inosinic acid synthesized are 3′(& 2′)-isomer, together with a small amount of 5′-isomer. It was pointed out that cupric ion accelerated both the synthesis of inosinic acid and the liberation of p-nitrophenol, and that the nucleoside phosphotransferase and the phosphatase may be different from each other.     

Bacterial Synthesis of Nucleotides

5′-Phosphoribosyl 5-amino-4-imidazole carboxamide was prepared by incubating 5-amino-4-imidazole carboxamide riboside and a phosphate compound with the bacteria characterized to phosphorylate at C_5′ via the phosphoryl transfer reaction. Aromatic phosphate compounds and 5′-nucleotides were able to act as the phosphate donor. This material was isolated chromatographically and its properties were studied. The other bacteria characterized to phosphorylate at C_{3′ (or 2′)} also phosphorylated a little probably at C_{3′ (or 2′)} of 5-amino-4-imidazole carboxamide riboside.

The phosphoryl interconversion between nucleotides and nucleosides was studied to be carried out via the phosphoryl transfer reaction observed in bacteria. The phosphotransferase activity of Ps. trifolii mediated reversibly the phosphoryl transfer between 5′-nucleotides and nucleosides, and its optimal pH was at around 8.5, whereas that of Prot. mirabilis did transfer the phosphoryl radical from 2′- and 3′-nucleotide to nucleoside at its optimal pH, around 5.0.

These donor- and product-isomer specificities of both bacteria were evident to be invariable, regardless of reaction pH and cultural conditions. These reactions, especially using the bacteria characterized to phosphorylate at C_5′ of nucleoside, were demonstrated to catalyze the phosphoryl interconversion between 5′-purine nucleotides and pyrimidine nucleosides or vice versa.     

Bacterial Synthesis of Nucleotides

Inosine-5′, 2′(or 3′)-diphosphate was prepared by incubating 5′-IMP and p-nitrophenyl-phosphate with the bacteria characterized to phosphorylate at C_{3′ (&2′)}, or, on the contrary, by incubating 2′-IMP and a donor with the others capable of synthesizing 5′-nucleotide, via their phosphoryl transfer reactions.

Formation of the 5′, 2′(or 3′)-diphosphates of guanosine, cytidine, and uridine was also demonstrated to be carried out under the same relationship between nucleotide isomer as an acceptor and specificities of bacterial phosphotransferases, as observed in the phosphorylation of adenylic acid isomers, while 5′-dTMP was phosphorylated by both groups of bacteria.     

Acceptor Specificity Observed with Crude Preparation of Nucleoside Phosphotransferases

The acceptor specificities of bacterial nucleoside phosphotransferase were further investigated by phosphorylating various kinds of nucleoside analogues. The bacteria belonging to A group(5′-nucleotide former) specifically phosphorylated the primary alcohol at 5′-position of nucleosides and their analogues, such as adenine xyloside, psicofuranine and pseudouridine, while the others belonging to B group (3′(2′)-nucleotide former) the secondary alcohol at 3′(2′)-position. The phosphorylation at 5′-primary alcohol with the bacteria belonging to A group, however, was prohibited mainly by phosphoryl-or amino-radical at 3′-position, as observed in the case of 3′-nucleotide or amino-nucleoside (or puromycin), depending on the steric conformation around the 3′-position of acceptor. Besides, both types of nucleoside phosphotransferases were also able to phosphorylate nucleoside having a C-C-linkage between base and sugar moieties.     

Enzymic Phosphorylation of Some 5-Aminoimidazole Nucleosides to the 5′-Phosphates

Abstract

Phosphotransferases from wheat shoots and a suitable phosphate donor have been used for the specific conversion of unprotected pyrimidine and purine nucleosides and some analogues into nucleoside 5'-phosphates. We have been interested to investigate the application of this technique to the phosphorylation of 5-aminoimidazole nucleosides to afford corresponding 5'-phosphates related to intermediates in purine nucleotide de novo biosynthesis. Several D-ribofuranosyl, D-xylofuranosyl and D-arabinofuranosyl 5-aminoimidazoles have been successfully phosphorylated (TABLE) to 5'-phosphates using a phosphotransferase from wheat shoots and p-nitrophenylphosphate as a phosphate donor.     

Metabolism of Pyridine Coenzymes in Microorganisms

NADP was enzymatically synthesized from NAD and p-nitrophenyl phosphate or nucleoside monophosphate with the enzyme preparation of Proteus mirabilis (IFO 3849). In this phosphotransferring reaction, ATP did not serve as phosphoryl donor.

In addition to NADP, an unidentified substance (Compound I) showing fluorescence with methyl ethyl ketone and having no coenzyme activity to glutamic dehydrogenase was synthesized. The yield of NADP was usually below 30 per cent of Compound I.

NADP was isolated from the reaction mixture and its coenzyme activity to some dehydrogenases was demonstrated.

A new derivative of NAD (Compound I) synthesized from NAD and p-nitrophenyl phosphate by the enzyme preparation of Proteus mirabilis (IFO 3849), was isolated from the reaction mixture.

After degradation of this compound with snake venom nucleotide pyrophosphatase, Compound III was obtained. 5′-NMN was phosphorylated to Compound IV by the same enzyme preparation of P. mirabilis. By the determination of chemical constituents and the degradation with phosphomonoesterases, Compounds III and IV were identified as nicotinamide riboside 2′(3′),5′-diphosphate, and Compound I was identified as NADP analog which was formed by phosphorylation at the 2′ or 3′ position of the nicotinamide ribose moiety, not at the 2′ position of adenosine moiety of NAD.     

Distribution and Properties of NAD Phosphorylating Reaction

Distribution of NAD phosphorylating reactions, phosphorylation through NAD kinase and phosphotransferase, was investigated. NAD kinase activity was distributed rather widely in bacteria, whereas phosphotransferase activity with p-NPP and NAD was limited to a few genera. Proteus mirabilis showed strong activity of phosphotransferase besides NAD kinase activity.

Partial purification of the phosphotransferase was attempted. The enzyme preparation possessed phosphatase activity as well as phosphotransferase activity. Phosphorylation of NAD proceeded maximally under the conditions below pH 4.0. Cu²⁺ showed stimulating effect on the activity. Besides p-NPP and phenylphosphate, various nucleotides, especially 2′ (or 3′) isomers, served as excellent phosphoryl donors, and various kinds of nucleosides and nucleotides were phosphorylated to form nucleoside monophosphates and nucleoside diphosphates.     

Studies on Vitamin B6 Metabolism in Microorganisms

A large number of bacteria were searched for the activity of the synthesis of pyridoxine 5′-phosphate by the transphosphorylation between pyridoxine and p-nitrophenyl phosphate. Several properties of the transphosphorylation by the partially purified enzyme prepared from one of the isolated bacteria, Escherichia freundii K–1, were investigated accompanying with phosphatase activity. The behavior of the phosphotransferase and phosphatase activities in various reaction conditions were almost parallel. It was pointed out that the transphosphorylation might be catalyzed by the function of acid phosphatase. The phosphoryl donor specificity for the enzyme system was found to be broad.

The enzyme which catalyzed the transphosphorylation of pyridoxine accompanying with the hydrolyzation of phosphoryl donor substrates was purified and crystallized from the cell free extract of Escherichia freundii K–1. The purification procedures involved heat treatment, ammonium sulfate fractionation and DEAE-cellulose, hydroxylapatite, and CM-sephadex column chromatographies. The crystalline enzyme showed the sedimentation coefficient of 7.5 S and the diffusion coefficient of 6.15 × 10^?7 cm²/sec. The molecular weight was calculated to be 120,000. Several properties of the purified enzyme were also investigated. It was recognized that the transphosphorylation of pyridoxine might be catalyzed by the action of acid phosphatase.     

A novel human phosphotransferase highly specific for adenosine.

A novel nucleoside phosphotransferase, referred to as adenosine phosphotransferase (Ado Ptase), was partially purified 1230-fold from human placenta. This enzyme differed from other known nucleoside phosphotransferases in its substrate specificity. Using AMP as the phosphate donor, it readily phosphorylated Ado. Changes in the sugar moiety were tolerated. dAdo and ddAdo were phosphate acceptors and dAMP was a donor. No other nucleotide or nucleoside common in nature displayed appreciable activity as donor or acceptor substrate, respectively. In the absence of nucleoside, the enzyme catalyzed the hydrolysis of AMP, typical of other nucleoside phosphotransferases. However, in the presence of Ado, little, if any, hydrolysis occurred. Ado Ptase had an absolute requirement for a metal cation, with Mg2+ and, to a lesser extent, Mn2+ fulfilling this requisite. The apparent Km for Ado was 0.2 mM. However, the donor AMP displayed cooperativity in both transfer and hydrolytic reactions. This cooperativity was eliminated by nucleotides, 2,3-diphosphoglycerate, and inorganic phosphate. ADP and 2,3-diphosphoglycerate were especially potent. In the presence of these effectors, the apparent Km for AMP was 3.0 mM in the transfer reaction and 4.0 mM in the hydrolytic reaction. Kinetic data suggest that there are two nucleotide binding sites on Ado Ptase, one for the donor, the other for an effector. AMP appeared to bind to both sites. Although this novel enzyme might play a role in the anabolism of nucleoside analogues, the normal physiological role of this nucleoside phosphotransferase is not understood.     

A comparison of enzymatic phosphorylation and phosphatidylation of β-l- and β-d-nucleosides

Enzymatic 5′-monophosphorylation and 5′-phosphatidylation of a number of β-l- and β-d-nucleosides was investigated. The first reaction, catalyzed by nucleoside phosphotransferase (NPT) from Erwinia herbicola, consisted of the transfer of the phosphate residue from p-nitrophenylphosphate (p-NPP) to the 5′-hydroxyl group of nucleoside; the second was the phospholipase d (PLD)-catalyzed transphosphatidylation of l-α-lecithin with a series of β-l- and β-d-nucleosides as the phosphatidyl acceptor resulted in the formation of the respective phospholipid-nucleoside conjugates. Some β-l-nucleosides displayed similar or even higher substrate activity compared to the β-d-enantiomers.     

Phosphorylation of Some 5-Aminoimidazole Nucleosides to the 5’ -Phosphates Using a Phosphotransferase from Wheat

Abstract

Several D-ribofuranosyl, D-xylofuranosyl and D-arabinofuranosyl 5-aminoimidazoles have been successfully phosphorylated to 5’ -phosphates using a phosphotransferase from wheat shoots and p-nitrophenylphosphate as a phosphate donor.     

Studies on Vitamin B6 Metabolism in Microorganisms

A new phosphotransferring reaction which phosphorylated pyridoxine through the phosphoryl group transfer from p-nitrophenylphosphate was found, and the distribution of the reaction in several microorganisms was investigated. The transferring activity was widely distributed in various kinds of microorganisms, especially in fungi belonging to genus such as Aspergillus. The phosphorylated product was isolated from the reaction mixture with the dried cells of Aspergillus flavus and identified as pyridoxine 5′-phosphate.     

Membrane-bound 5′-nucleotidase/nucleoside phosphotransferase from Bacillus cereus

• 1.1. A search for nucleoside phosphotransferase activity in Bacillus cereus led to the following results: (i) The phosphotransferase activity was associated with a membrane bound 5′-nucleotidase. (ii) The enzyme phosphorylates both purine and pyrimidine nucleosides as well as 2′,3′-dideoxyinosine. (iii) The enzyme was inhibited by adenylic nucleotide di- and triphosphates, and its nucleotidase activity was increased in the presence of inosine as phosphate acceptor.
• 2.2. Bacterial and vertebrate 5′-nucleotidases with phosphotransferase activity diner for several characteristics, such as cellular location, substrate specificity, magnesium requirement and regulation.

     

Kinetic properties of a nucleoside phosphotransferase of chick embryo

1. A nonspecific nucleoside phosphotransferase (nucleotide : 3'-deoxynucleotide 5'-phosphotransferase, EC 2.7.1.77), purified from chick embryos, catalyzes the transfer of phosphate ester from a nucleotide donor to a nucleoside acceptor. 2. The enzyme exhibits sigmoidal kinetics with respect to nucleoside monophosphate donors, but with respect to nucleoside di- or triphosphate donors and nucleoside acceptors hyperbolic kinetics were obtained. 3. The nucleoside phosphotransferase of chick embryo is unstable to heat and is protected from inactivation by a large number of nucleosides. 4. Nucleoside di- and triphosphates lower both the concentration of nucleoside monophosphates required for half-maximal velocity and the kinetic order of reaction measured with these phosphate donors. On the contrary, nucleoside di- or triphosphate do not modify the kinetic parameters evaluated for nucleoside acceptors. 5. We suggest that the nucleoside phosphotransferase contains both substrate and regulatory sites. It seems that the free apoenzyme is converted, by means of cooperative interactions between regulatory sites, into an enzyme-nucleotide complex, which is particularly stable at 37 degrees C.     

Purification and specificity of RNase A3 from Vicia faba root cells

Vicia faba root ribonucleases are bound to Cibacron blue F3GA. A Blue dextran-Sepharose column was used to purify RNase A₃, the more abundant enzyme from V. faba root. Using dinucleoside monophosphate as substrates, it appears that this enzyme behaves as a cyclizing phosphotransferase. With high enzyme/substrate ratios on prolonged digestion a partial release of a nucleoside 3′ phosphate occurs. The specificity is relatively high since only the purine-purine phosphodiester linkages out of 16 types of possible links are easily cleaved. When a pyrimidine is involved in the phosphodiester bond, a much slower rate of attack (Py in 5′) or no attack (Py in 3′) was detected.     

Reverse and forward reactions of carbamyl phosphokinase from Streptococcus faecalis R. Participation of nucleotides and reaction mechanisms

The participation of Mg complex of nucleoside diphosphates and nucleoside triphosphates in the reverse and forward reactions catalyzed by purified carbamyl phosphokinase (ATP : carbamate phosphotransferase, EC 2.7.2.2) of Streptococcus faecalis R, ATCC-8043 were studied. The results of initial velocity studies of approx. 1 mM free Mg2+ concentration have indicated that in the reverse reaction MgdADP was as effective a substrate as MgADP. The phosphoryl group transfer from carbamyl phosphate to MgGDP, MgCDP and MgUDP was also observed at relatively higher concentrations of the enzyme and respective magnesium nucleoside diphosphate. In the forward direction MgdATP was found to be as efficient a phosphate donor as MgATP. On the other hand, Mg complexes of GTP, CTP and UTP were ineffective even at higher concentrations of the enzyme and respective magnesium nucleoside triphosphate. Product inhibition studies carried out at non-inhibitory level of approx. 1 mM free Mg2+ concentration have revealed that the enzyme has two distinct sites, one for nucleoside diphosphate or nucleoside triphosphate and the other for carbamyl phosphate or carbamate, and its reaction with the substrates is of the random type. Further tests of numerical values for kinetic constants have indicated that they are partially consistent with the Haldane relationship which is characteristic of rapid equilibrium and random mechanism.     

Inhibition of the peptidyltransferase acceptor site by 2′(3′)-O-cycloleucyl- and α-aminoisobutyryl derivatives of cytidylyl-(3′–5′)adenosine

2′(3′)-O-(N-Benzyloxycarbonylcycloleucyl)adenosine (1a) was prepared by esterification of 5′-O-(4-methoxytrityl)adenosine with N-benzyloxycarbonylcycloleucine in the presence of dicyclohexylcarbodiimide and subsequent deprotection in acidic medium. The compound 1a was separated into pure 2′- and 3′-isomers using HPLC; these isomers were found to undergo an easy interconversion. Compound 1a was coupled with N-dimethylaminomethylene-2′,5′-di-O-tetrahydropyranylcytidine 3′-phosphate in the presence of dicyclohexylcarbodiimide to give, after subsequent deblocking, cytidylyl(3′→5′)2′(3′)-O-cycloleucyladenosine (1c). Compound 1c, as well as the related cytidylyl(3′→5′)2′(3′)-O-(α-aminoisobutyryl)adenosine (1d), inhibited the peptidyltransferase catalyzed transfer of an AcPhe residue to puromycin in the Ac[¹⁴C]Phe-tRNA·poly(U)·70 S E. coli ribosome system. A half of the maximum inhibition of AcPhe-puromycin formation (at 10^?5 M puromycin) was achieved at 9.5·10^?6 M of compound 1c and 9·10^?5 M of compound 1d, respectively. The inhibition of the puromycin reaction by compound 1d shows a mixed-type of inhibition kinetics. Further, none of the compounds 1c and 1d was an acceptor in the peptidyltransferase reaction. Both compounds 1c and 1d inhibited the binding of C-A-C-C-A[¹⁴C]Phe to the A site of peptidyltransferase in a system containing tRNA^Phe·poly(U)·70 S E. coli ribosomes, in which compound 1d was a much stronger inhibitor than 1c. These results indicate that the derivatives such as compounds 1c and 1d which contain an anomalous amino acid with a substituent in lieu of α-hydrogen can interfere with the peptidyltransferase A site; however, they are not acceptors in the peptidyltransferase reaction probably due to a misfit of the α-substituent.     

A novel non-radioactive method for detection of nucleoside analog phosphorylation by 5'-nucleotidase.

Cytosolic 5'-nucleotidase has been implicated in the phosphorylation of certain nucleosides of therapeutic interest. In vitro, IMP and GMP serve as the optimal phosphate donors for this nucleoside phosphotransferase reaction. Existing assays for nucleoside phosphorylation effected by 5'-nucleotidase require a radiolabeled nucleoside as the phosphate acceptor and separation of the substrate-nucleoside from product-nucleotide has been accomplished either by a filter binding method or HPLC. However, detection of the phosphorylation of unlabeled nucleoside by HPLC is difficult since the ultraviolet absorbance of the phosphate donor, IMP, frequently obscures the absorbance of newly formed nucleotide. The use of ribavirin 5'-phosphate (RMP, 1,2,4-triazole-3-carboxamide riboside 5-monophosphate) as the phosphate donor obviates this difficulty since this triazole heterocycle does not significantly absorb at the wavelengths used to detect most nucleoside analogs. Using this procedure, a 5'-nucleotidase activity from the 100,000 x g supernatant fraction of human T-lymphoblasts deficient in adenosine kinase, hypoxanthine-guanine phosphoribosyltransferase, and deoxycytidine kinase, was characterized with regard to structure-activity relationships for certain inosine and guanosine analogs.     

Large scale enzymatic synthesis of nucleoside-5'-monophosphates using a phosphotransferase from carrots

The enzymatic synthesis of nucleoside-5′-monophosphates from purineriboside, 6-mercapto-purine riboside, 6-methylmercapto-purine riboside, 6-chloro-purine riboside, tubercidin, 8-aza-adenosine, and 3′-deoxy-adenosine is described in gram scale. The synthesis is catalyzed by a phosphotransferase from carrots and uses phenylphosphate as phosphate donor. The reaction products are purified on QAE-Sephadex A25 columns. The large scale preparation of the enzyme is also reported.     

The elongation factor Tu·GTPase reaction: Effect of 2′(3′)-O-aminoacyl oligoribonucleotides

The activity of synthetic (2′(3′)-O-aminoacyl trinucleotides, C-C-A-Phe, C-C-U-Phe, C-U-A-Phe, U-C-A-Phe and C-A-A-Phe, in promoting the EF-Tu·70 S ribosome-catalyzed GTP hydrolysis was investigated. It was found that the activity decreases in the order C-C-A-Phe > C-U-A-Phe > U-C-A-Phe > C-A-A-Phe ⪢ C-C-U-Phe. Thus, the substitution in ‘natural’ C-C-A sequence with other nucleobases weakens binding of 2′(3′)-O-aminoacyl trinucleotides to EF-Tu, with the substitution at the 3′-position having the most profound effect. Since the 2′(3′)-O-aminoacyl oligonucleotides mimic the effect of the aa-tRNA 3′-terminus on EF-Tu·GTPase, it follows that EF-Tu probably directly recognizes structure of nucleobases in the aa-tRNA 3′-terminus, with the 3′-terminal adenine playing the most important role.