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Substrate Hydrolysis (substrate + hydrolysis)

Distribution by Scientific Domains
Life Sciences40%

Selected Abstracts

Kinetics of inhibition of acetylcholinesterase in the presence of acetonitrile

FEBS JOURNAL, Issue 8 2009
Markus Pietsch
The hydrolysis of acetylthiocholine by acetylcholinesterase from Electrophorus electricus was investigated in the presence of the inhibitors tacrine, gallamine and compound 1. The interaction of the enzyme with the substrate and the inhibitors was characterized by the parameters KI, ,,, b or ,, Km and Vmax, which were determined directly and simultaneously from nonlinear Michaelis,Menten plots. Tacrine was shown to act as a mixed-type inhibitor with a strong noncompetitive component (,, , 1) and to completely block deacylation of the acyl-enzyme. In contrast, acetylcholinesterase inhibition by gallamine followed the ,steric blockade hypothesis', i.e. only substrate association to as well as substrate/product dissociation from the active site were reduced in the presence of the inhibitor. The relative efficiency of the acetylcholinesterase,gallamine complex for the catalysis of substrate conversion was determined to be 1.7,25% of that of the free enzyme. Substrate hydrolysis and the inhibition of acetylcholinesterase were also investigated in the presence of 6% acetonitrile, and a competitive pseudo-inhibition was observed for acetonitrile (KI = 0.25 m). The interaction of acetylcholinesterase with acetonitrile and tacrine or gallamine resulted in a seven- to 10-fold increase in the KI values, whereas the principal mode of inhibition was not affected by the organic solvent. The determination of the inhibitory parameters of compound 1 in the presence of acetonitrile revealed that the substance acts as a hyperbolic mixed-type inhibitor of acetylcholinesterase. The complex formed by the enzyme and the inhibitor still catalysed product formation with 8.7,9.6% relative efficiency. [source]

Intraclonal variability in Daphnia acetylcholinesterase activity: The implications for its applicability as a biomarker

ENVIRONMENTAL TOXICOLOGY & CHEMISTRY, Issue 9 2003
Liane Biehl Printes
Abstract The relationship between individual growth and acetylcholinesterase (AChE) activity was evaluated for Daphnia magna. Analysis on the influence of two different culture media on baseline AChE activity was performed with Daphnia similis. The results indicated an inverse relationship between D. magna body length and AChE activity. An increase in total protein, which was not proportional to an increase in the rate of the substrate hydrolysis (, absorbance/min), seems to be the reason for this inverse size versus AChE activity relationship. Therefore, toxicants such as phenobarbital, which affect protein and size but not AChE activity directly, have an overall affect on AChE activity. In contrast, the AChE inhibitor parathion altered AChE activity but not protein. Culture medium also had a significant affect on AChE activity in D. similis. Changes in total protein seem to be the main reason for the variations in baseline AChE activity in Daphnia observed in the different evaluations performed in this work. Therefore, AChE activity in Daphnia must be interpreted carefully, and variations related to changes in total protein must be taken into account when applying this enzyme as a biomarker in biological monitoring. [source]

Hydrolysis of acetylthiocoline, o -nitroacetanilide and o- nitrotrifluoroacetanilide by fetal bovine serum acetylcholinesterase

FEBS JOURNAL, Issue 7 2009
Marķa F. Montenegro
Besides esterase activity, acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) hydrolyze o -nitroacetanilides through aryl acylamidase activity. We have reported that BuChE tetramers and monomers of human blood plasma differ in o -nitroacetanilide (ONA) hydrolysis. The homology in quaternary structure and folding of subunits in the prevalent BuChE species () of human plasma and AChE forms of fetal bovine serum prompted us to study the esterase and amidase activities of fetal bovine serum AChE. The kcat/Km values for acetylthiocholine (ATCh), ONA and its trifluoro derivative N -(2-nitrophenyl)-trifluoroacetamide (F-ONA) were 398 × 106 m,1·min,1, 0.8 × 106 m,1·min,1, and 17.5 × 106 m,1·min,1, respectively. The lack of inhibition of amidase activity at high F-ONA concentrations makes it unlikely that there is a role for the peripheral anionic site (PAS) in F-ONA degradation, but the inhibition of ATCh, ONA and F-ONA hydrolysis by the PAS ligand fasciculin-2 points to the transit of o -nitroacetalinides near the PAS on their way to the active site. Sedimentation analysis confirmed substrate hydrolysis by tetrameric 10.9S AChE. As compared with esterase activity, amidase activity was less sensitive to guanidine hydrochloride. This reagent led to the formation of 9.3S tetramers with partially unfolded subunits. Their capacity to hydrolyze ATCh and F-ONA revealed that, despite the conformational change, the active site architecture and functionality of AChE were partially retained. [source]

Comparative study of PSMA expression in the prostate of mouse, dog, monkey, and human,

THE PROSTATE, Issue 9 2006
Saurabh Aggarwal
Abstract BACKGROUND Intraprostatic PSMA targeted prodrugs/protoxins are under development in our laboratory. Future toxicologic studies of these therapies require identification of animal models that express PSMA within the prostate. METHOD PSMA enzymatic activity and protein expression was determined. PSMA expression in the prostates of mouse, dog, and monkey were compared to humans by real-time PCR analysis. RESULTS No substrate hydrolysis was observed in dog or monkey prostate homogenates. Monkey prostate was negative for PSMA protein expression. No significant PSMA mRNA levels were detected by real time PCR in mouse, dog, or monkey prostate tissue compared to PSMA negative tissues. CONCLUSIONS PSMA is not expressed in any significant amount in the prostates of mouse, beagle dog, or macaque monkeys in this study but is expressed in high levels by human prostate. These non-human species, therefore, are not suitable toxicologic models to assess prostate damage from PSMA-activated intraprostatic prodrug/protoxin therapies. Prostate 66: 903,910, 2006. © 2006 Wiley-Liss, Inc. [source]

Detection of human neutrophil elastase with peptide-bound cross-linked ethoxylate acrylate resin analogs

CHEMICAL BIOLOGY & DRUG DESIGN, Issue 4 2005
J.V. Edwards
Abstract:, An assessment of elastase-substrate kinetics and adsorption at the solid,liquid interface of peptide-bound resin was made in an approach to the solid-phase detection of human neutrophil elastase (HNE), which is found in high concentration in chronic wound fluid. N-succinyl-alanine-alanine-proline-valine- p -nitroanilide (suc-Ala-Ala-Pro-Val- pNA), a chromogenic HNE substrate, was attached to glycine-cross-linked ethoxylate acrylate resins (Gly-CLEAR) by a carbodiimide reaction. To assess the enzyme-substrate reaction in a two-phase system, the kinetic profile of resin-bound peptide substrate hydrolysis by HNE was obtained. A glycine and di-glycine spacer was placed between the resin polymer and substrate to assess the steric and spatial requirements of resin to substrate with enzyme hydrolysis. The enzymatic activities of suc-Ala-Ala-Pro-Val- pNA and suc-Ala-Ala-Pro-Ala- pNA on the solid-phase resin were compared with similar analogs in solution. An increase in visible wavelength absorbance was observed with increasing amounts of substrate-resin and enzyme concentration. Enzyme hydrolysis of the resin-bound substrate was also demonstrated on a polypropylene surface, which was employed for visible absorbance of released chromophore. A soluble active substrate analog was released from the resin through saponification of the ethoxylate ester linkages in the resin polymer. The resin-released conjugate of the HNE substrate demonstrated an increased dose response with increasing enzyme concentration. The synthesis and assay of elastase substrates bound to CLEAR resin gives an understanding of substrate-elastase adsorption and activity at the resin's solid,liquid interface for HNE detection with a solid-phase peptide. [source]