Phosphates 4-nitrophenyl ester hydrolysis

The use of a lipophilic zinc(II) macrocycle complex, 1-hexadecyl-1,4,7,10-tetraazacyclododecane, to catalyze hydrolysis of lipophilic esters, both phosphate and carboxy (425), links this Section to the previous Section. Here, and in studies of the catalysis of hydrolysis of 4-nitrophenyl acetate by the Zn2+ and Co2+ complexes of tris(4,5-di-n-propyl-2 -imidazolyl)phosphine (426) and of a phosphate triester, a phos-phonate diester, and O-isopropyl methylfluorophosphonate (Sarin) by [Cu(A(A(A/,-trimethyl-A/,-tetradecylethylenediamine)l (427), various micellar effects have been brought into play. Catalysis of carboxylic ester hydrolysis is more effectively catalyzed by A"-methylimidazole-functionalized gold nanoparticles than by micellar catalysis (428). Other reports on mechanisms of metal-assisted carboxy ester hydrolyses deal with copper(II) (429), zinc(II) (430,431), and palladium(II) (432). 

N-oc-t-Boc-L-His Oleyl imidazole L-glutamic add dioleylester ribitol (stabilizer) DVB toluene Co(II)Cl2+water Using substrate analog surface imprinting by W/0 emulsion polymerization hydrolysis of N-a-Boc-L-Ala p-nitrophenyl ester in isooctane/phosphate buffer [1751... 

Sulfate ester hydrolysis (p-nitrophenyl sulfate, 1 x 10 ) Phosphomonoesters hydrolysis (p-nitrophenyl phosphate, 1.1)... 

It has to be pointed out that, with a few exceptions, the acceleration by polyelectrolytes was associated with decreases and Table IV gives the thermodynamic parameters for the aquation reactions of Co(NH3)5Br induced by Ag". Similar decreases in and AS were found for various reactions the Hg -induced aquation of Co(NH3)5Br , the SpjAr reaction of dinitrochlorobenzoic acid with OH [51], the hydrolysis of 2,4-dinitrophenyl phosphates [reaction (E)] [33], the outer-sphere electron-transfers between Co-complexes [Co(NH3)5N3, Co(NH3)5Br , Co(en)2Cl2 ] and Ru(NH3)6 or [8, 20] [en ethylenediamine], the polyvinyl-imidazole-accelerated solvolysis of p-nitrophenylacetate [52], the coupling reactions of dinitrofluorobenzene with aminoacids [53], dipeptides [53] and aniline [54], the lignin sulfonic acid-accelerated hydrolysis of methyl acetate [55], and the hydrolysis of nitrophenyl esters [37]. The opposite tendency (acceleration caused by increases... 

The nuclease requires Ca + ions for activity, with no other divalent metal ion being able to support catalysis. A large number of other phospodiester-ases have been found to be dependent on divalent metal ions for activity, including the restriction endonuclease icoRI (Barton et al, 1982). Thus elucidation of the mechanism of the reaction catalyzed by staphylococcal nuclease may provide important clues to the mechanisms of the other metal-dependent phosphodiesterases. Fortunately, staphylococcal nuclease will catalyze, albeit at a low rate, the hydrolysis of a number of mononucleotide esters (Cuatrecasas et al., 1969), including thymidine 5 -(4-nitro-phenyl phosphate) this ester is hydrolyzed to thymidine and 4-nitrophenyl phosphate. We have determined the stereochemical course of the hydrolysis of thymidine 5 -(4-nitrophenyl [ 0, 0]phosphate) and interpreted the result in terms of the structure of the active site of the enzyme. 

The highly electrophilic character of the POf ion would suggest a very unselective phosphorylation behavior. For example, the ratio of alkyl phosphate to inorganic phosphate obtained in hydrolyses of phosphoric esters in water/alcohol mixtures should reflect the molar ratio of water and alcohol. This is indeed found in numerous cases, e.g. in the hydrolysis of phenyl and 4-nitrophenyl phosphate monoanions 97) or of 4-nitrophenyl phosphate dianions 65) at 100 °C in methanol/ water mixtures of various compositions, as also in the solvolysis of the acetyl phosphate dianion at 37 °C 97) or of phosphoenol pyruvate monoanions 82). Calculations of the free energy of the addition reactions of water and ethanol to the POf ion support the energetic similarity of the two reactions 98) (Table 4). 

Fig. I. Hydrolysis rates for the monoanions of phosphate esters at IOO°C as a function of the pKa of the conjugate acid of the leaving group. D, p and mNP are di-.p- and m-nitrophenyl phosphates.

Although metal-promoted hydrolysis of phosphate esters is a topic of very current interest (Section 61.4.4), little work has been published dealing with the effects of metal ions on the hydrolysis of sulfate esters. The acid-catalyzed hydrolysis of aryl sulfates has been shown to occur by an A-l mechanism (Scheme 34).434 Nucleophilic catalysis by amines has been observed in the hydrolysis of p-nitrophenyl sulfate435 and intramolecular carboxyl group catalysis occurs with salicyl sulfate436 as with salicyl phosphate. 

Artificial enzymes with metal ions can also hydrolyze phosphate esters (alkaline phosphatase is such a natural zinc enzyme). We examined the hydrolysis of p-nitro-phenyfdiphenylphosphate (29) by zinc complex 30, and also saw that in a micelle the related complex 31 was an even more effective catalyst [118]. Again the most likely mechanism is the bifunctional Zn-OH acting as both a Lewis acid and a hydroxide nucleophile, as in many zinc enzymes. By attaching the zinc complex 30 to one or two cyclodextrins, we saw even better catalysis with these full enzyme mimics [119]. A catalyst based on 25 - in which a bound La3+ cooperates with H202, not water - accelerates the cleavage of bis-p-nitrophenyl phosphate by over 108-fold relative to uncatalyzed hydrolysis [120]. This is an enormous acceleration. 

Robinson, 1969a). It is probable that the hydrophobic nature of the phenyl groups of p-nitrophenyl diphenyl phosphate results in deep penetration of the neutral ester in the Stern layer, thus shielding the phosphoryl group from nucleophilic attack. Unlike other reactions between nucleophiles and neutral substrates catalyzed by cationic micelles (Bunton and Robinson, 1968, 1969a) and the hydrolysis of dinitrophenyl phosphate dianions in the presence of cationic micelles (Bunton et al., 1968), the catalysis of the hydrolysis of -nitrophenyl diphenyl phosphate by CTAB arises from an increase in the activation entropy rather than from a decrease in the enthalpy of activation. The Arrhenius parameters for the micelle-catalyzed and inhibited reactions are most probably manifestations of the extensive solubilization of this substrate. However, these parameters can be composites of those for the micellar and non-micellar reactions and the eifects of temperature on the micelles themselves are not known. Interpretation of the factors which affect these parameters must therefore be carried out with caution. In addition, the inhibition of the micelle-catalyzed reactions by added electrolytes has been observed (Bunton and Robinson, 1969a Bunton et al., 1969, 1970) and, as in the cases of other anion-molecule reactions and the heterolysis of dinitrophenyl phosphate dianions, can be reasonably attributed to the exclusion of the nucleophile by the anion of the added salt. 

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