Phosphate, inorganic reactions producing

The latter reaction (producing the labile acyl phosphate) is less favored at increasing chain-lengths, and attack occurs along the hydrocarbon chain, with formation of an organic peroxide. In the absence of oxygen, no acyl phosphate or peroxide is formed, but inorganic phosphate is liberated. 

Fig. 8 Malachite green assay for phosphate detection. The enzymatic reaction produces inorganic phosphate P. A secondary reaction is used to form a phosphomolybdate-malachite green complex, which has a strong absorbance at 660 nm.

Efforts have also been made to produce MDF-like materials in which the role of the organic polymer is taken over by an inorganic polymer, specifically sodium polyphosphate (Ma and Brown, 1992). In this way flexural strengths of up to about 30 MPa were achieved in combination with calcium aluminate cement. The resulting phosphate-containing reaction products were found to be amorphous. 

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 11.3 Regulation of GAD during the synthesis of GABA. Active GAD (GAD-PLP) combines with glutamate (1) to form a complex (GAD-PLP-GLU). After decarboxylation (2) this yields GABA and GAD-PLP (3). The intermediate product (GAD-INT) can undergo an alternative reaction (4) to produce succinic semialdehyde (SSA) and pyridoxamine-5 -phosphate (PMP). PMP dissociates from GAD (5) leaving inactive enz5mie, which requires additional PLP to be reactivated (6), a process that is affected by ATP and inorganic phosphate...

A mechanism proposed 87) for the alkaline hydrolysis of tetraethyl pyrophosphate, which is markedly accelerated by HPO e ions, has been substantiated by isotopic labeling 88). The nucleophilic attack by HPOJp on the symmetrical pyrophosphate 131 is considered to lead initially to the unsymmetrical P P1-diethyl pyrophosphate dianion 132 which decomposes spontaneously under the conditions of reaction to give the diethyl phosphate anion and POf 102. The latter reacts with water to form inorganic phosphate and with alcohols suclj as methanol and ethylene glycol to produce alkyl phosphates. 

Many methods have been developed in which a product of the reaction is chemically modified to produce a substance with a particular spectral property. The inorganic phosphate released by the hydrolysis of phosphate esters may be measured by simple chemical methods (Fiske and Subbarow) after the enzyme reaction has been stopped. Such techniques are often convenient but do not lend themselves to the measurement of initial velocity. 

CMP-NeuAc synthetase (EC 2.7.7.43) to produce CMP-NeuAc. The by-product pyrophosphate (PPi) is hydrolyzed to phosphate (Pi) by inorganic pyrophosphatase (PPase). Sialyla-tion is accomplished with a2,3-sialyltransferase (< 2,3NeuAcT) or a2,6-sialyltransferase (a2,3NeuAcT), respectively. The released CMP is again converted to CDP, to CTP, and finally to CMP-NeuAc. The UDP-Gal and CMP-NeuAc regeneration schemes have been combined in a one-pot reaction and applied to the synthesis of sialyl Lewis X. 

Many addition and elimination reactions, e.g., the hydration of aldehydes and ketones, and reactions catalyzed by lyases such as fumarate hydratase are strictly reversible. However, biosynthetic sequences are often nearly irreversible because of the elimination of inorganic phosphate or pyrophosphate ions. Both of these ions occur in low concentrations within cells so that the reverse reaction does not tend to take place. In decarboxylative eliminations, carbon dioxide is produced and reversal becomes unlikely because of the high stability of C02. Further irreversibility is introduced when the major product is an aromatic ring, as in the formation of phenylpyruvate. 

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