Acetylation Acetylcholine

However, in sharp contrast to the acetylated acetylcholine esterase, which is unstable and hydrolysed very rapidly (the half-life is about 0.1 ms) the phosphorylated enzyme is much more stable by a factor of at least 10. ... 

Mode of Action. All of the insecticidal carbamates are cholinergic, and poisoned insects and mammals exhibit violent convulsions and other neuromuscular disturbances. The insecticides are strong carbamylating inhibitors of acetylcholinesterase and may also have a direct action on the acetylcholine receptors because of their pronounced stmctural resemblance to acetylcholine. The overall mechanism for carbamate interaction with acetylcholinesterase is analogous to the normal three-step hydrolysis of acetylcholine however, is much slower than with the acetylated enzyme. 

The use of mutant 34486 of Neurospora crassa for the microbiological assay of ch oline has been described (8). A physiological method has also been used in which the ch oline is extracted after hydrolysis from a sample of biological material and acetylated. The acetylcholine is then assayed by a kymographic procedure, in which its effect in causing contraction of a piece of isolated rabbit intestine is measured (33). 

Important derivatives of choline are acetylcholine, acetyl-P-methylcholine, and carbamylcholine. Many other choline derivatives have been synthesized and studied, but have not been found satisfactory for clinical use. 

Acetylcholine is the product of the reaction between choline and acetyl coenzyme A in the presence of choline acetylase (41). 

An enzymatic assay can also be used for detecting anatoxin-a(s). " This toxin inhibits acetylcholinesterase, which can be measured by a colorimetric reaction, i.e. reaction of the acetyl group, liberated enzymatically from acetylcholine, with dithiobisnitrobenzoic acid. The assay is performed in microtitre plates, and the presence of toxin detected by a reduction in absorbance at 410 nm when read in a plate reader in kinetic mode over a 5 minute period. The assay is not specific for anatoxin-a(s) since it responds to other acetylcholinesterase inhibitors, e.g. organophosphoriis pesticides, and would need to be followed by confirmatory tests for the cyanobacterial toxin. 

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... 

Figure 6.1 Synthesis and metabolism of acetylcholine. Choline is acetylated by reacting with acetyl-CoA in the presence of choline acetyltransferase to form acetylcholine (1). The acetylcholine binds to the anionic site of cholinesterase and reacts with the hydroxy group of serine on the esteratic site of the enzyme (2). The cholinesterase thus becomes acetylated and choline splits off to be taken back into the nerve terminal for further ACh synthesis (3). The acetylated enzyme is then rapidly hydrolised back to its active state with the formation of acetic acid (4)...

Potential oscillation was measured in the presence of cholinergic agents (acetylcholine chloride, carbamylcholine chloride, carbamyl- d-methylcholine chloride, and acetyl-/6-methylcholine chloride) and anticholinergic agents (tetramethylammonium chloride, tetra-ethylammonium chloride, succinylcholine chloride, hexamethonium chloride, scopolamine hydrobromide, atropine sulfate, homatropine hydrochloride, and tubocurarine chloride)... 

FIG. 18 Chemical structures of (a) acetylcholine chloride, (b) carbamylcholine chloride, (c) carba-myl-y8-methylcholine chloride, (d) acetyl-/i-methylcholine chloride, (e) tetramethylammonium chloride, (f) tetraethylamonium chloride, (g) succinylcholine chloride, (h) hexamethonium chloride, (i) scopolamine hydrobromide, 0 atropine sulfate, (k) homatropine hydrochloride, and (1) tubocurar-ine chloride. 

A number of substituted p-aminoacetates inhibit the enzyme cholinesterase. The main function of this enzyme is to hydrolyze acetyl choline and thereby terminate the action of that substrate as a neurotransmitter. Such inhibition is functionally equivalent to the administration of exogenous acetylcholine. Direct administration of the neurotransmitter substance itself is not a useful therapeutic procedure due to rapid drug destruction and unacceptable side... 

Acetylcholine is formed from acetyl CoA (produced as a byproduct of the citric acid and glycolytic pathways) and choline (component of membrane lipids) by the enzyme choline acetyltransferase (ChAT). Following release it is degraded in the extracellular space by the enzyme acetylcholinesterase (AChE) to acetate and choline. The formation of acetylcholine is limited by the intracellular concentration of choline, which is determined by the (re)uptake of choline into the nerve ending (Taylor Brown, 1994). 

Acetylcholine synthesis and neurotransmission requires normal functioning of two active transport mechanisms. Choline acetyltransferase (ChAT) is the enzyme responsible for ACh synthesis from the precursor molecules acetyl coenzyme A and choline. ChAT is the neurochemical phenotype used to define cholinergic neurons although ChAT is present in cell bodies, it is concentrated in cholinergic terminals. The ability of ChAT to produce ACh is critically dependent on an adequate level of choline. Cholinergic neurons possess a high-affinity choline uptake mechanism referred to as the choline transporter (ChT in Fig. 5.1). The choline transporter can be blocked by the molecule hemicholinium-3. Blockade of the choline transporter by hemicholinium-3 decreases ACh release,... 

The acetyl choline receptor is a ligand-gated ion channel that allows cations to flow out of the neuron to initiate an action potential during neurotransmission (Fig. 9-6). When the receptor binds acetylcholine, a conformational change of the receptor opens a membrane channel that conducts ions. 

Figure 8 Chromatograms of diluted urine (I) and diluted urine spiked with 2.1 pM choline and 2.3 pM acetylcholine (II). Elution order Hydrogen peroxide (0.7 min), choline (1.6 min), and acetyl choline (2.9 min). See Ref. 50 for further details.

The answers are 333-c, 334-a, 335-d. (Katzung, pp 77-80. Hardman, pp 116, 132, 147—148.) Acetylcholine is synthesized from acetyl-CoA and choline. Choline is taken up into the neurons by an active transport system. Ilemicholinium blocks this uptake, depleting cellular choline, so that synthesis of ACh no longer occurs. 

Acetyl coenzyme A formed from glucose is the precursor for acetylcholine 543... 

The effect of Li+ upon the synthesis and release of acetylcholine in the brain is equivocal Li+ is reported to both inhibit and stimulate the synthesis of acetylcholine (reviewed by Wood et al. [162]). Li+ appears to have no effect on acetyl cholinesterase, the enzyme which catalyzes the hydrolysis of acetylcholine [163]. It has also been observed that the number of acetylcholine receptors in skeletal muscle is decreased by Li+ [164]. In the erythrocytes of patients on Li+, the concentration of choline is at least 10-fold higher than normal and the transport of choline is reduced [165] the effect of Li+ on choline transport in other cells is not known. A Li+-induced inhibition of either choline transport and/or the synthesis of acetylcholine could be responsible for the observed accumulation of choline in erythrocytes. This choline is probably derived from membrane phosphatidylcholine which is reportedly decreased in patients on Li+ [166],... 

A variety of enzymes (such as acetylcholine esterase, Porcine pancreatic lipase, Pseudomonas cepacia lipase, and Candida antarcita lipase) have been found useful in the preparation of enantiomerically pure cyclopentenol (+)-2 from 1. The enantiomeric (—)-2 has been prepared from diol 4 by enzymatic acetylation catalyzed by VP-345 with isopropenyl acetate in an organic medium. The key intermediate cyclopentanones (+)-6, (—)-6, 7, and 8, which are useful in the preparation of many bioactive molecules, can be obtained from 3 and 5 via routine chemical transformations.7... 

True and pseudo-cholinesterase. The above serum preparations contained both the true and pseudo- cholinesterases of Mendel and Rudney.1 The effect of di-isopropyl phosphorofluoridate on these components was examined separately by means of the specific substrates described by Mendel, Mundel and Rudney,2 using the titration method described above. Phosphorofluoridate (5 x 10 8m) gave an inhibition of 57 per cent of the activity towards 00045m acetylcholine, 30 per cent of the activity towards 0-0005 m acetyl-/ methyl-choline, and 40 per cent of that towards 0-005 m benzoylcholine, after incubating the enzyme with the poison for 5 min. Thus in these experiments there appeared to be no appreciable difference in sensitivity of the true and pseudo-cholinesterases of horse serum to phosphorofluoridates. 

Synthesis of noradrenaline (norepinephrine) is shown in Figure 4.7. This follows the same route as synthesis of adrenaline (epinephrine) but terminates at noradrenaline (norepinephrine) because parasympathetic neurones lack the phenylethanolamine-N-methyl transferase required to form adrenaline (epinephrine). Acetylcholine is synthesized from acetyl-Co A and choline by the enzyme choline acetyltransferase (CAT). Choline is made available for this reaction by uptake, via specific high-affinity transporters, within the axonal membrane. Following their synthesis, noradrenaline (norepinephrine) or acetylcholine are stored within vesicles. Release from the vesicle occurs when the incoming nerve impulse causes an influx of calcium ions resulting in exocytosis of the neurotransmitter. 

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