Adenosine 59-phosphate, 0- synthesis

Fig.2. Adenosine phosphates. Synthesis of cyclic adenosine 3, 5 - monophosphate (cAMP), and the structure of cyclic A. O -dibutyryladenosine y.B -monophosphate.

The synthesis of ATP is catalyzed by the enzyme ATP synthase (or FiFq-ATP synthase) the Fj portion of this enzyme was first isolated by Racker and coworkers in 1960 [4]. ATP synthase is present in abundance in the membranes of animal mitochondria, plant chloroplasts, bacteria and other organisms. ATP synthesized by our ATP synthase is transported out of mitochondria and used for the function of muscle, brain, nerve, liver and other tissues, for active transport, and for synthesizing myriad compounds needed by the cell. Since the pool of adenosine phosphates in the body is limited, the use of ATP must be continually compensated by its synthesis, and an active person synthesizes his own body weight of ATP every day. The synthesis of ATP is the most prevalent chemical reaction in the body [5]. This is indeed a very important reaction. How exactly does it occur ... 

Nucleoside Pyrophosphates. - The synthesis of 8-aryl-3-P-o-ribofuranosylimiazo[2,l-i]purine 5 -phosphates (122) from AMP or ATP has been described. To access these fluorescent nucleotide derivatives, a combination of Kornblum oxidation reaction and imidazole formation was employed. For this conversion, the appropriate adenosine phosphate, present in its free acid form, was treated with p-nitro-acetophenone in DMSO in the presence of DBU. Treatment of a 5-(chloroethyl)-4-(triazole-l-yl)pyrimidine-nucleoside with benzylhydrazine offered the 6,6-bicyclic pyrimido-pyradazin-7-one, the precursor to (123). This triphosphate was used as a substrate for DNA polymerases. ... 

Adenylic Acid. Muscle adenylic acid ergaden -ylic acid t -adenylic acid adenosine S -monophosphate adenosine phosphate adenosine-5 -phosphoric add edeno-sine-5. monophosphoric acid A5MP AMP NSC-20264 Addiyl Cardiomone (Na salt) Lycedan My -B-Den My-oston Phosaden. C,0HhNjO7P mol wt 347.23, C 34.59%, H 4.06%, N 20.17%, O 32,25%, P 8,92%. Nucleotide widely distributed in nature. Prepn from tissues Embden, Zimmerman, Z. Physrot Chem. 167, 137 (1927) Embden, Schmidt, ibid. 181, 130 (1929) cf. Kalckar, J. B.ol Chem. 167, 445 (1947). Prepn by hydrolysis of ATP with barium hydroxide Kerr, 3. Biot Chem. 139, 13l (1941). Synthesis Baddiley, Todd. 3. Chem. Soc. 1947, 648. Commercial prepn by enzymatic phosphorylation of adenosine. Monograph on synthesis of nucleotides G. R. Pettit. Synthetic Nucleotides vol, 1 (Van Nostrand-Reinhold. New York, 1972) 252 pp. Crystal structure Kraut, lensen, Acta Cryst 16, 79 (1963). Reviews see Adenosine Nucleic Acids. 

FIGURE 19.2 2-Deoxyribose 5-phosphate synthesis from glucose and acetaldehyde hy baker s yeast and a deoxyriboaldolase-expressing E. coli. ADP, adenosine diphosphate. 

The use of the phosphoenol pyruvate (PEP)/pyruvate kinase system is probably the most useful method for the regeneration of nucleoside triphosphates [523]. PEP is not only very stable towards spontaneous hydrolysis but it is also a stronger phosphorylating agent than ATP. Furthermore, nucleosides other than adenosine phosphates are also accepted by pyruvate kinase. The drawbacks of this system are the more complex synthesis of PEP [524, 525] and the fact that pyruvate kinase is inhibited by pyruvate at higher concentrations. 

Structure of Coemyme A. The elucidation of the structure of CoA depended heavily on d radation by specific enzymes. The phosphate on carbon 3 of the adenosine was shown to be a monoester phosphate by hydrolysis with prostate phosphomonoesterase. The localization of the monoester at the 3 position was established by its sensitivity to a b nucleotidase that attacks only nucleoside 3 -pbosphates, not 2 - or 5 -phosphates. The original CoA molecule or the phosphatase product, depbospho CoA, can be split by nucleotide pyrophosphatases from potato or snake venom. These reactions permitted the identification of the adenosine phosphate portion of the molecule. The position of the phosphate on pantothenic acid cannot be determined enzymatically, but was established by studies on the synthesis of CoA from synthetic phos-phorylated pantetheines. Pantetheine is split to thiolethanolamine and pantothenic acid by an enzyme found in liver and kidney. This enzyme also attacks larger molecules, including CoA. 

A reaction similar in type to that described above has been demonstrated in liver extracts by Wajzer and Baron for inosine-3 -phosphate synthesis from hypoxanthine and ribose-3-phosphate. The formation of the mononucleotide, adenylic acid, by the phosphorylation of adenosine by adenosinetriphosphate has also been described. The significance and integration of these different reactions remains a major problem for future effort. 

CycHc adenosine monophosphate (cAMP), produced from ATP, is involved in a large number of ceUular reactions including glycogenolysis, Hpolysis, active transport of amino acids, and synthesis of protein (40). Inorganic phosphate ions are involved in controlling the pH of blood (41). The principal anion of interceUular fluid is HP (Pig. 3) (41). 

Figure 29.1 An overview of catabolic pathways for the degradation of food and the production of biochemical energy. The ultimate products of food catabolism are C02 and H2O, with the energy released in the citric acid cycle used to drive the endergonic synthesis of adenosine triphosphate (ATP) from adenosine diphosphate (ADP) plus phosphate ion, HOPO32-.

When AMP is heated under reflux in DMF, the 2, 3 -cyclic phosphate is formed, and cyclic phosphates can also be obtained from nucleosides and ortho-, pyro-, or poly-phosphoric acids under the same conditions. Promotion of phosphorylation by DMF is well known and the reaction with AMP is probably intermolecular as no 3, 5 -cyclic AMP can be detected. Minor products in the latter reaction are the 2, 3 -cyclic 5 -diphosphate and the 2 (30,5 -diphosphate. The synthesis of adenosine 2 (3 )-phosphate 5 -pyrophosphate has been achieved by the phosphoromorpholidate method used in a synthesis of Co A. ... 

A remarkable feature of the bioenergetic oxidation reactions of nutrients in cells is the fact that they are always coupled to another reaction, that of synthesis of the energy-rich chemical substance adenosine triphosphate (ATP) from adenosine diphosphate (ADP) and phosphate (oxidative phosphorylation Engelgardt and Ljubimova, 1939) ... 

ECF. Note that phosphorus is the major anion within the cells. Given this distribution, serum phosphate concentration does not accurately reflect total body phosphorus stores. Phosphorus is expressed in milligrams (mg) or millimoles (mmol), not as milliequivalents (mEq). Because phosphorus is the source of phosphate for adenosine triphosphate (ATP) and phospholipid synthesis, manifestations of phosphorus imbalance are variable. 

Figure 14.1. Outline of the relationship between glucose metabolism, acetylcholine synthesis and energy production. TCA = tricarboxylic acid ADP = adenosine diphosphate P = inorganic phosphate.

O-isopropylideneuridine (XIII), followed by removal of the protecting groups, gave adenosine-5 uridine-5 (hydrogen phosphate) (XIV). This particular route to the synthesis of dinucleotides is capable of being applied only to the synthesis of compounds in which at least one uridine residue is... 

Phosphoribosylpyrophosphate (PRPP) synthetase is one of the very few enzymes which transfer a pyrophosphoryl group from ATP in one step. When the synthesis is carried out in lsO-enriched water, lsO is incorporated into the PRPP, but not into AMP.91 The lsO in the PRPP arises from a pre-exchange between the H2180 and the ribose phosphate, and hence the results confirm that fission of the /5-P—O bond takes place. PRPP and ATP are starting materials in the biosynthesis of histidine, and Ai-(5 -phospho-D-ribosyl)adenosine triphosphate (29) is an intermediate. The... 

J. Leppanen, J. Huuskonen, J. Savolainen, T. Nevalainen, H. Taipale, J. Vepsalainen, J. Gynther, T. Jarvinen, Synthesis of a Water-Soluble Prodrug of Entacapone , Bioorg. Med. Chem. Lett. 2000, 10, 1967-1969 R. Sauer, J. Maurinsh, U. Reith, F. Ftille, K. N. Klotz, C. E. Muller, Water-Soluble Phosphate Prodrugs of l-Propargyl-8-styryl-xanthine Derivatives, A2A-Selective Adenosine Receptor Antagonists , J. Med. Chem. 2000, 43, 440-448. 

The first step of this sequence, which is not unique to de novo purine nucleotide biosynthesis, is the synthesis of 5-phosphoribosylpyrophosphate (PRPP) from ribose-5-phosphate and adenosine triphosphate. Phosphoribosyl-pyrophosphate synthetase, the enzyme that catalyses this reaction [278], is under feedback control by adenosine triphosphate [279]. Cordycepin interferes with thede novo pathway [229, 280, 281), and cordycepin triphosphate inhibits the synthesis of PRPP in extracts from Ehrlich ascites tumour cells [282]. Formycin [283], probably as the triphosphate, 9-0-D-xylofuranosyladenine [157] triphosphate, and decoyinine (LXXlll) [284-286] (p. 89) also inhibit the synthesis of PRPP in tumour cells, and this is held to be the blockade most important to their cytotoxic action. It has been suggested but not established that tubercidin (triphosphate) may also be an inhibitor of this reaction [193]. 

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