Stabilization phosphatase

In 1984, Magnuson et al. (Entry 1) investigated the influence of ethylammoni-um/water mixtures on enzyme activity and stability [29]. At low [H3NEt][N03] concentrations, an increased activity of alkaline phosphatase was found. The same ionic liquid was used by Flowers and co-workers, who found improved protein refolding after denaturation (Entry 2) [30]. 

Phosphonate analogs to phosphate esters, in which the P—0 bond is formally replaced by a P—C bond, have attracted attention due to their stability toward the hydrolytic action of phosphatases, which renders them potential inhibitors or regulators of metabolic processes. Two alternative pathways, in fact, may achieve introduction of the phosphonate moiety by enzyme catalysis. The first employs the bioisosteric methylene phosphonate analog (39), which yields products related to sugar 1-phosphates such as (71)/(72) (Figure 10.28) [102,107]. This strategy is rather effective because of the inherent stability of (39) as a replacement for (25), but depends on the individual tolerance of the aldolase for structural modification close... 

Enzyme Reference Serums. Several companies sell lyophilized or stabilized reference serums for the calibration of instruments and for quality control. The label values given for the enzymatic activity of these serums should never be taken at face value, as at times they may be quite erroneous (19,33). Also, these values should only be used for the assay with which they were standardized, as interconversion of activity from one method to another for the same enzyme may often lead to marked errors. For instance, it is not recommended that alkaline phosphatase expressed in Bodansky units be multiplied by a factor to convert it to the units of the Ring-Armstrong method, or any other method for that matter. 

Sample Collection and Enzyme Stability. Serum samples are collected with chemically clean, sterile glassware. Blood is allowed to clot at room temperature, the clot is gently separated from the test tube with an applicator stick, and the blood is centrifuged for 10 minutes at 1,000 g. If the red cells are known to contain the enzymes whose activity is being measured, as in the case of LD, even slightly hemolyzed serums must be discarded. When acid phosphatase is to be measured, the serum should be placed immediately in ice and processed as soon as possible, or it should be acidified by the addition of a small amount of sodium citrate. Anticoagulants such as EDTA, fluoride and oxalate inhibit some serum enzymes. However, heparin activates serum lipoprotein lipase. 

Tricalcium phosphate was also used as an enzyme embedding matrix. Das and coworkers [229] demonstrated that acid phosphatase and amylase immobilized on Ca3(P04)2 retained their activities with increased thermal stability. 

Several enzymes have been immobilized in sol-gel matrices effectively and employed in diverse applications. Urease, catalase, and adenylic acid deaminase were first encapsulated in sol-gel matrices [72], The encapsulated urease and catalase retained partial activity but adenylic acid deaminase completely lost its activity. After three decades considerable attention has been paid again towards the bioencapsulation using sol-gel glasses. Braun et al. [73] successfully encapsulated alkaline phosphatase in silica gel, which retained its activity up to 2 months (30% of initial) with improved thermal stability. Further Shtelzer et al. [58] sequestered trypsin within a binary sol-gel-derived composite using TEOS and PEG. Ellerby et al. [74] entrapped other proteins such as cytochrome c and Mb in TEOS sol-gel. Later several proteins such as Mb [8], hemoglobin (Hb) [56], cyt c [55, 75], bacteriorhodopsin (bR) [76], lactate oxidase [77], alkaline phosphatase (AP) [78], GOD [51], HRP [79], urease [80], superoxide dismutase [8], tyrosinase [81], acetylcholinesterase [82], etc. have been immobilized into different sol-gel matrices. Hitherto some reports have described the various aspects of sol-gel entrapped biomolecules such as conformation [50, 60], dynamics [12, 83], accessibility [46], reaction kinetics [50, 54], activity [7, 84], and stability [1, 80],... 

Fructose 1,6-diphosphatase hydrolyzes D-fructose 1,6-diphosphate to give D-fructose 6-phosphate and PO . It is a key enzyme in the gluconeo-genesis pathway. Two divalent metal ions (Mg2+, Mn2+, Zn2+, and Co2+) are involved in catalysis. In the enzyme isolated from pork kidney the metal-metal distance accounts to 3.7 A [12]. A reaction mechanism similar to that of protein phosphatase 1 was proposed, but leaving group stabilization by metal coordination of the ester oxygen atom appears to be absent (Figure 6) [12]. 

Enzymes have different degrees of stability after their collection. Alkaline phosphatase demonstrates up to 10% increased activity after a few hours at room temperature (B15). Most enzymes are not stable at room temperature, but can be preserved in the refrigerator for short periods or in the deep freeze for relatively long times. In Table 4 are tabulated the reported stabilities of many serum enzymes. It must be realized that the problem of enzyme stability is complicated by the fact that the isoenzymes of a particular enzyme may have different stabilities and that specimens with high activities may react differently than those with normal activities (KIO). Although it is indicated in Table 4 that serum... 

There are stability problems in urines stored for analysis. Fifty percent of delta-aminolevulinic acid was lost in specimens stored without preservative and exposed to light for 24 hours (V3). The loss increased to 80% in 48 hours, 85% in 72 hours, and 95% in 2 weeks. However, the same specimens acidified with tartaric acid and stored in the dark lost 2% of the aminolevulinic acid in 72 hours and 6% in 2 weeks (V3). The destruction of catecholamines collected in nonacidified urine specimens is well documented (Cll). Urinary acid phosphatase was destroyed on freezing (S15). The effect was related to increasing salt concentration during freezing and was prevented by the addition of albumin (S15). 

Dla. Davidson, M. M., Stability of acid phosphatase in frozen serum. Amer. J. Clin. Pathol. 23, 411 (1953). 

The substitution of nickel for other essential elements may also contribute to the adverse effects of nickel. Nickel can replace magnesium in certain steps in the activation of complement (McCoy and Kenney 1992). For example, nickel greatly increased the half-life and stability of the C3b, Bb enzyme which amplifies activation of the complement pathway. Nickel has also been shown to activate calcineurin, a phosphatase that binds zinc and iron, and which is usually activated by manganese (Kenney and McCoy 1992). 

Differential effects of the three major mood stabilizers on phosphatase activity have been reported lithium blocks activity, carbamazepine increases activity, and valproate has no effect (Vadnal and Parthasarathy... 

Alkaline phosphatase [H,NEt][N03] Enzyme activity and stability assayed by hydrolysis of 29... 

Fig. 7.14. Regulation of CaM kinase II. Scheme of regulation of CaM kinase II by Ca Vcalmodu-lin and by autophosphorylation. CaM kinase II is inactive in the unphosphorylated form and in the absence of Ca calmodulin. Binding of Ca Vcalmodulin activates the kinase for phosphorylation of protein substrates. In the process, autophosphorylation takes place at a conserved Thr residue that stabilizes the active state of the enzyme. In this state, significant residual activity is still present after dissociation of Ca Vcalmodulin and the enzyme remains in an active state for a longer time after the Ca signal has died away. The active state is only terminated when the activating phosphate residue is cleaved off by a protein phosphatase.

Fig. 8.17. Mechanism of hydrolysis of phosphotyrosine residues by tyrosine phosphatases. Cleavage of phosphate from phosphotyrosine residues takes place by an in-line attack of a nucleophilic cysteine thiolate of the tyrosine phosphatase at the phosphate of the phosphotyrosine residue. The negative charge on the thiolate is stabilized by the positive charge of a conserved Arg residue. In the course of the reaction, an enzyme-Cys-phosphate intermediate is formed, which is hydrolytically cleaved to phosphate and enzyme-Cys-SH. The figure shows selected interactions. Other interactions in the active center involved in substrate binding and catalysis are not shown. According to Tainer and Russel, (1994). R substrate protein.

The frequent occurrence of sialylated enzymes, or even of multiple forms, which are sometimes tissue-dependent, with a varying number of sialyl residues as, for example, in y-glutamyltranspeptida.se (EC 2.3.2.2),456,457 is not yet fully understood. Although the activity of most of these enzymes is not influenced by removal of sialic acid,454 the activity of monoamine oxidase A (EC 1.4.3.4) of outer mitochondrial membranes of rat liver has been shown to be destroyed by treatment with sialidase438 the substrate specificity of acetylcholinesterase (EC 3.1.1.7) is altered,459 the kinetic properties of human acid and alkaline phosphatases (EC 3.1.3.1 and 3.1.3.2) are changed, and the stability of a-D-galactosidase (EC 3.2.1.22) is drastically lowered.415 In these cases, an influence of sialyl residues on the conformation of the enzyme is assumed, but awaits firm evidence. 

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