Acetylcholinesterase AChE true

It is well established that acetylcholine can be catabolized by both acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) these are also known as "true" and "pseudo" cholinesterase, respectively. Such enzymes may be differentiated by their specificity for different choline esters and by their susceptibility to different antagonists. They also differ in their anatomical distribution, with AChE being associated with nervous tissue while BChE is largely found in non-nervous tissue. In the brain there does not seem to be a good correlation between the distribution of cholinergic terminals and the presence of AChE, choline acetyltransferase having been found to be a better marker of such terminals. An assessment of cholinesterase activity can be made by examining red blood cells, which contain only AChE, and plasma. 

The ligand binding or catalytic sites are the most relevant parts of a protein domain for the development of small molecules as modulators of protein function. There is evidence that proteins with conserved folds often also have their functional sites on the same topological location. In some cases a remarkable conservatism in functional sites can be observed. This is true for the example described later in this review on similarity of Cdc25A phosphatase, acetylcholinesterase (AChE) and 1 Ifl-hydroxysteroid dehydrogenases (1 l HSD) (Fig. 9). Nevertheless, it should be stressed that the correlation patterns of amino acid sequence, protein fold and protein function remain a matter of debate. Moreover, a vast number of specific functions can be carried out by the limited number of protein domains due to the high amino acid diversity of proteins with similar folds. " ... 

There are two major types of cholinesterases acetylcholinesterase (AChE) and pseudocholinesterase (pseudo-ChE). AChE (also known as true, specific, or erythrocyte cholinesterase) is found at a number of sites in the body, the most important being the cholinergic neuroeffector junction. Here it is localized to the prejunctional and postjunctional membranes, where it rapidly terminates the action of synaptically released ACh. It is essential to recognize that the action of ACh is ter-... 

Neurotransmitters are removed by translocation into vesicles or destroyed in enzyme-catalysed reactions. Acetylcholine must be removed from the synaptic cleft to permit repolarization and relaxation. A high affinity acetylcholinesterase (AChE) (the true or specific AChE) catalyses the hydrolysis of acetylcholine to acetate and choline. A plasma AChE (pseudo-AChE or non-specific AChE) also hydrolyses acetylcholine. A variety of plant-derived substances inhibit AChE and there is considerable interest in AChE inhibitors as potential therapies for cognition enhancement and for Alzheimer s disease. Organophosphorous compounds alkylate an active site serine on AChE and the AChE inhibition by this mechanism is the basis for the use of such compounds as insecticides (and unfortunately also as chemical warfare agents). Other synthetics with insecticidal and medical applications carbamoylate and thus inactivate AChE (Table 6.4). 

Acetylcholinesterase (AChE) (also termed true cholinesterase ) is found in the synaptic cleft of cholinergic synapses, and is of undoubted importance in regulation of neurotransmission by rapid hydrolysis of released endogenous acetylcholine (ACh). AChE is also found in erythrocytes and in the CSF, and can be present in soluble form in cholinergic nerve terminals, but its function at these sites is not clear, AChE is specific for substrates that include acetylcholine and the agents methacholine and acetylthiocholine. but it has little activity with other esters. It has a maximum turnover rate at very low concentrations of AChE (and is inhibited by high concentrations). 

There are two main enzymes of interest. Acetylcholinesterase (AChE EC 3.1.1.7) has an affinity for the substrate acetylcholine and it is found in the erythrocytes and nervous tissue. The enzyme is sometimes referred to as true cholinesterase, and it exists in differing polymorphic forms (Skau 1985). Butyrylcholinesterase (BuChE, acylcholine acylhydrolase, EC 3.1.1.8)—also known as pseudocholinesterase or nonspecific cholinesterase— has affinities for the substrates butyrylcholine and/or pro-pionylcholine, which are dependent on the animal species (Myers 1953 Ecobichon and Comeau 1973 Scarsella et al. 1979 Unakami et al. 1987 Evans 1990 Matthew and Chapin 1990 Woodard et al. 1994). 

All what applies to CW agents is basically also true for toxic industrial compounds (TIC) like pesticides, etc. Organophosphorus pesticides are used extensively to control agricultural pests. Similary to nerve agents, they inhibit the enzyme acetylcholinesterase (AChE) [8]. Expositions mainly might occur in pesticide production plants and dnring their application in forestry, agriculture, and horticulture. Chemically similar compounds are used as flexibilizers or additives in lubrication solvents. 

According to inpatient records from St. Luke s Hospital, the most common laboratory finding related to sarin toxicity was a decrease in plasma cholinesterase (ChE) levels in 74% of patients. In patients with more severe toxicity, plasma ChE levels tended to be lower, but a more accurate indication of ChE inhibition is the measurement of erythrocyte ChE, as erythrocyte acetylcholinesterase (AChE) is considered "true ChE" and plasma ChE is "pseudo-ChE." However, erythrocyte ChE is not routinely measured, whereas plasma ChE is included in many clinical chemistry panels thus, it can be used as a simple index for ChE activity. In both the Matsumoto and Tokyo subway sarin attacks, plasma ChE served as a useful index of sarin exposure. In 92% of hospitalized patients, plasma ChE levels returned to normal on the following day. In addition, inpatient records from St. Luke s Hospital showed an elevated creatine phosphokinase and leukocytosis in 11% and 60% of patients, respectively. In severe cases such as the Matsumoto attack, hyperglycemia, ketonuria, and low serum triglycerides due to tire toxic effects of sarin on the adrenal medulla were observed (Yanagisawa et al, 2006). 

Acetylcholinesterase (EC 3.1.1.7) (AChE) Acetylcholine acetylhydrolase True ChE ChE I ChE Acet-ylthiocholinesterase Acetylcholine hydrolase Acetyl (3-methylcholinesterase Erythrocyte ChE Butyrylcholinesterase (EC 3.1.1.8) (BChE or BuChE) ChE Pseudocholinesterase Plasma ChE Acylcholine acylhydrolase Non-specific ChE ChEII Benzoylcholinesterase Propionylcholinesterase... 

Released ACh is broken down by membrane-bound acetylcholinesterase, often called the true or specific cholinesterase to distinguish it from butyrylcholinesterase, a pseudo-or non-specific plasma cholinesterase. It is an extremely efficient enzyme with one molecule capable of dealing with something like 10000 molecules of ACh each second, which means a short life and rapid turnover (100 ps) for each molecule of ACh. It seems that about 50% of the choline freed by the hydrolysis of ACh is taken back into the nerve. There is a wide range of anticholinesterases which can be used to prolong and potentiate the action of ACh. Some of these, such as physostigmine, which can cross the blood-brain barrier to produce central effects and neostigmine, which does not readily... 

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