Pyrophosphate esters formation

The enzyme catalyzed reactions that lead to geraniol and farnesol (as their pyrophosphate esters) are mechanistically related to the acid catalyzed dimerization of alkenes discussed m Section 6 21 The reaction of an allylic pyrophosphate or a carbo cation with a source of rr electrons is a recurring theme m terpene biosynthesis and is invoked to explain the origin of more complicated structural types Consider for exam pie the formation of cyclic monoterpenes Neryl pyrophosphate formed by an enzyme catalyzed isomerization of the E double bond m geranyl pyrophosphate has the proper geometry to form a six membered ring via intramolecular attack of the double bond on the allylic pyrophosphate unit... 

Acid dye method for the analysis of thiamin, 18A, 73 electrophoretic separation and fluorometric determination of thiamin and its phosphate esters, 18A, 91 catalytic polarography in the study of the reactions of thiamin and thiamin derivatives, 18A, 93 preparation of thiamin derivatives and analogs, 18A, 141 preparation of the mono- and pyrophosphate esters of 2-methyl-4-amino-5-hydroxymethylpyrimidine for thiamin biosynthesis, 18A, 162 formation of the pyrophosphate ester of 2-methyl-4-amino-5-hydroxymethylpyrimidine by enzymes from brewers yeast in thiamin biosynthesis, 18A, 203 resolution, reconstitution, and other methods for the study of binding of thiamin pyrophos-... 

Lewin, L.M. Brown, G.M. The Biosynthesis of thiamine. III. Mechanism of enzymatic formation of the pyrophosphate ester of 2-methyl-4-ammo-5-hy-droxymethylpyrimidine. J. Biol. Chem., 236, 2768-2771 (1961)... 

Figure 1 Thiamine, vitamin B1, is the cofactor, as its pyrophosphate ester, for many important biologic reactions. These reactions involve the formation of an anion 2 that is stabilized by resonance with a carbene form 3. The related species 4 and derivatives have been developed as important ligands for metal ions in chemical synthesis.

Samples of (IK, 2R, 3R) and (IS, 25, 35) prephytoene alcohols have been chemically synthesized and only the (IK, 2K, 3K) enantiomer (91), as the pyrophosphate ester, is biologically active The absolute configuration of prephytoene pyrophosphate (89) is thus identical to that found for presqualene pyrophosphate (77) and the detailed stereochemistry of the formation of these compounds is probably identical. 

Closely related to the alkyl exchange reaction is the well-known formation of pyrophosphate esters from the interaction of pentavalent phosphorus esters with phosphoryl halides (296). 

Analysis of PPA demonstrates that it is composed mainly of phosphoric acid tetramers (from hydrolysis of P4O10), as illustrated in Scheme 18.11. During the initial stage of quinacridone synthesis, reaction with a terephthalic acid 17 results in the formation of phosphate esters. A bis-diphosphate (bis-pyrophosphate) ester species 23 is displayed in the reaction scheme although a variety of combinations of mono- to triphosphate esters could and probably do form and probably equilibrate with each other also, in the hot acid. However, due to the symmetry of the tetrameric phosphoric acid and the known nucleofugic propensity of a diphosphate moiety, bis-diphosphate esters such as 23 probably form preferentially as reactive intermediates and by analogy, diphosphate esters would be expected to significantly facilitate the cycUzation process. 

Besides being a very useful protecting group the alkylthio moiety can also serve as an activating group. Treatment with iodine in the presence of a nucleophile, e.g., phosphate ion or an alcohol, leads to the formation of pyrophosphate esters or alkyl esters, respectively [17] (Fig. 6.6). 

Alcohols react with ATP in enzyme-catalyzed reactions to produce phosphate and pyrophosphate esters. The reaction occurs by nucleophilic attack of the alcohol hydroxyl group on phosphorus. The net enzyme-catalyzed reaction for formation of a pyrophosphoryl group is shown below. 

In keeping with its biogenetic origin m three molecules of acetic acid mevalonic acid has six carbon atoms The conversion of mevalonate to isopentenyl pyrophosphate involves loss of the extra carbon as carbon dioxide First the alcohol hydroxyl groups of mevalonate are converted to phosphate ester functions—they are enzymatically phosphorylated with introduction of a simple phosphate at the tertiary site and a pyrophosphate at the primary site Decarboxylation m concert with loss of the terti ary phosphate introduces a carbon-carbon double bond and gives isopentenyl pyrophos phate the fundamental building block for formation of isoprenoid natural products... 

The hydrogen chloride is removed either by reduced pressure or by salt formation with pyridine or sodium bicarbonate the latter procedure gave high yields of the pure ester. Toy (47) also measured the hydrolysis rates and compared the toxicities of a series of tetraalkyl pyrophosphates. Of these tested, the tetraethyl ester was the most toxic to white mice. 

The reaction of 151 with methanol to give dimethyl phosphate (154) or with N-methylaniline to form the phosphoramidate 155 and (presumably) the pyrophosphate 156 complies with expectations. The formation of dimethyl phosphate does not constitute, however, reliable evidence for the formation of intermediate 151 since methanol can also react with polymeric metaphosphates to give dimethyl phosphate. On the other hand, reaction of polyphosphates with N-methylaniline to give 156 can be ruled out (control experiments). The formation of 156 might encourage speculations whether the reaction with N,N-diethylaniline might involve initial preferential reaction of monomeric methyl metaphosphate via interaction with the nitrogen lone pair to form a phosphoric ester amide which is cleaved to phosphates or pyrophosphates on subsequent work-up (water, methanol). Such a reaction route would at least explain the low extent of electrophilic aromatic substitution by methyl metaphosphate. 

The first suggestion of a practical form of antidotal therapy came in 1949 from Hestrin, who found that acetylcholinesterase (AChE) catalyzed the formation of acetohydroxamlc acid when incubated with sodium acetate and hydroxylamine. Critical in vitro studies in the next decade led to the development of a practical approach to therapy. The crucial concept in these studies was the recognition that the compound formed when AChE reacted with a phosphorus ester was a covalent phosphoryl-enzyme Intermediate similar to that formed in the hydrolysis of acetylcholine. 3 Wilson and colleagues, beginning in 1951, demonstrated that AChE inhibited by alkyl phosphate esters (tetraethyl pyrophosphate, TEPP) could be reactivated by water, but that free enzyme formed much more rapidly in the presence of hydroxylamine. 0 21 Similar results... 

The derivative (9) of 3,6-dideoxy-a-D-xyIo-hexopyranose (abequose) was isolated from a strain of Salmonella typhimurium,16 that (10) of 3,6-dideoxy-a-D-nfco-hexopyranose (paratose) from Salmonella paratyphi,54 and a mixture of 10 and the ester (11) of 3,6-dideoxy-a-D-arabino-hexopyranose (tyvelose) from Salmonella enteritidis.,6 It was shown that these derivatives are formed from cytidine 5 -(a-D-glu-copyranosyl pyrophosphate) by treatment with nicotinamide adenine dinucleotide (NAD+) and reduced nicotinamide adenine dinucleotide phosphate (NADPH) in the presence of cell extracts of the respective bacterial strain. For example, formation of 9 is characteristic of preparations from Salmonella, group B,55,56 or Pasteurella pseudotuberculosis, type II.56 The derivative 10 was obtained with extracts of Salmonella, group A,56 and Pasteurella pseudotuberculosis, type I and III,56 and a mixture of 10 and 11 with those of Salmonella, group D,55-60 or Pasteurella pseudotuberculosis, type IV 56.59,60 Under similar conditions, the ester (12) of cytidine 5 -pyro-... 

Nucleoside 5 -phosphorothioates have also been employed as activated nucleotide derivatives for synthesis of pyrophosphates.321 The interaction of tributylammonium 2, 3 -di-0-benzoyluridine 5 -phosphorothioate (73) with silver a-D-glucopyranosyl and a-D-galac-topyranosyl phosphates in pyridine solution, with subsequent de-benzoylation, gave the corresponding glycosyl esters in 60-70% yield. This procedure can probably be classified as a variant of the mixed-anhydride method, the driving force of the reaction being the formation of insoluble silver sulfide. 

The reactivity of acidified chlorite solutions is reduced for bleaching some textiles by adding compounds like polyamines, pyrophosphates, and hydrogen peroxide that suppress the formation of chlorine dioxide (57). Another method is to buffer the solution at pH 5—6 to reduce the rate of chlorine dioxide formation. Hydrolysis of anhydrides and esters or oxidation of alcohols can be used to slowly generate acids to promote chlorine dioxide formation (58). Aldehydes also promote chlorine dioxide generation from neutral chlorite solutions, but the effect is greater than simply lowering the pH as they... 

---