Monoanions metaphosphate, formation

As for the acetyl phosphate monoanion, a metaphosphate mechanism has also been proposed 78) for the carbamoyl phosphate monoanion 119. Once again, an intramolecular proton transfer to the carbonyl group is feasible. The dianion likewise decomposes in a unimolecular reaction but not with spontaneous formation of POf as does the acetyl phosphate dianion, but to HPOj and cyanic acid. Support for this mechanism comes from isotopic labeling proof of C—O bond cleavage and from the formation of carbamoyl azide in the presence of azide ions. 

In 1955 Westheimer, Bunton, Vernon and their coworkers suggested that the hydrolysis of the monoanions of phosphate monoesters proceeds through the formation of an intermediate monomeric metaphosphate monoanion, which reacts rapidly with water to give inorganic phosphate (equation 1)(7,2). 

As implied above, a dissociative or Sul mechanism for phosphoryl transfer is more difficult to establish than an Su2 mechanism. An SnI mechanism may be operative in the reaction catalyzed by creatine kinase as suggested by the observation that planar trigonal monoanions such as nitrate and formate (54) which are analogs of metaphosphate, (Fig. 5)... 

Structure of the substrate and the reaction conditions determine the transition state for reaction with a particular nucleophile 104, 105). The extreme cases are generally described as the dissociative and associative substitution mechanisms. The fully dissociative mechanism entails the formation of monomeric metaphosphate monoanion as a discrete intermediate and was first formulated by F. H. Westheimer, who pioneered the physical organic chemistry of the hydrolysis of phosphate esters 106, 107). This mechanism is depicted in Eq. (40) and is possible only for phosphomonoesters with good leaving groups, examples of which are shown. 

Very little is known about the transition states for enzymic nucleotidyl and phospho transfer reactions. Inasmuch as the mechanisms of the nonenzymic sol-volyses of phosphate esters establish the possibilities for comparable enzymic reactions, either associative or dissociative mechanisms can be considered. However, the dissociative mechanism is thought to be possible only for phospho transfer reactions and not for nucleotidyl transfers, because metaphosphate cannot be formed from diesters. A dissociative mechanism for a diester would entail the formation of a monomeric metaphosphate monoester, a species that can exist but which has not been observed in solvolysis reactions. The difficulty with the dissociative mechanism for phosphodiesters may be that a monoanion cannot provide enough driving force to expel a leaving group under solvolytic conditions. 

Uncatalyzed Reactions of Phosphate Monoesters. Phosphate monoesters in physiologically relevant pH ranges exist as either the monoanion or dianion. A large body of evidence indicates that uncatalyzed phosphoryl transfer reactions of both ionic forms takes place by loose transition states that are characterized by extensive bond cleavage to the leaving group and a small degree of bond formation to the nucleophile (for reviews of the evidence, see References (3,4)). Despite loose transition states, these reactions are concerted, and free metaphosphate is not formed in protic solvents (5). 

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