|acetylcholinesterase (Yt blood group)|
Diagram of Pacific electric ray acetylcholinesterase. From .
|Locus||Chr. 7 q22|
Cartoon diagram of human butyrylcholinesterase. From .
|Alt. symbols||CHE1, CHE2, E1|
|Locus||Chr. 3 q26.1-26.2|
In biochemistry, a cholinesterase or choline esterase is an esterase that lyses choline-based esters, several of which serve as neurotransmitters. Thus, it is either of two enzymes that catalyze the hydrolysis of these cholinergic neurotransmitters, such as breaking acetylcholine into choline and acetic acid. These reactions are necessary to allow a cholinergic neuron to return to its resting state after activation. For example, in muscle contraction, acetylcholine at a neuromuscular junction triggers a contraction; but for the muscle to relax afterward, rather than remaining locked in a tense state, the acetylcholine must be broken down by a choline esterase. The main type for that purpose is acetylcholinesterase (also called choline esterase I or erythrocyte cholinesterase); it is found mainly in chemical synapses and red blood cell membranes. The other type is butyrylcholinesterase (also called choline esterase II or plasma cholinesterase); it is found mainly in the blood plasma.
- Types and nomenclature 1
- Discovery 2
- Clinical significance 3
- Inhibitors 4
- Pop culture 5
- Additional images 6
- References 7
- External links 8
Types and nomenclature
The two types of cholinesterase are acetylcholinesterase (ACHE) and butyrylcholinesterase (BCHE). The difference between the two types has to do with their respective preferences for substrates: the former hydrolyses acetylcholine more quickly; the latter hydrolyses butyrylcholine more quickly.
The term cholinesterase is sometimes used to refer specifically to butyrylcholinesterase, but this usage produces the oddity that cholinesterase and false cholinesterase (pseudocholinesterase) under that scheme mean the same thing (confusingly), and acetylcholinesterase is then called true cholinesterase in contrast, producing the second oddity that cholinesterase and true cholinesterase then do not mean the same thing. But such usage is now outdated; the current, unambiguous HGNC names and symbols are acetylcholinesterase (ACHE) and butyrylcholinesterase (BCHE).
Acetylcholinesterase (EC 126.96.36.199) (ACHE), also known as AChE, RBC cholinesterase or erythrocyte cholinesterase, or (most formally) acetylcholine acetylhydrolase, is found primarily in the blood on red blood cell membranes, in neuromuscular junctions, and in other neural synapses. Acetylcholinesterase exists in multiple molecular forms. In the mammalian brain the majority of AChE occurs as a tetrameric, G4 form (10) with much smaller amounts of a monomeric G1 (4S) form.
Butyrylcholinesterase (EC 188.8.131.52) (BCHE), also known as BChE, BuChE, pseudocholinesterase, plasma cholinesterase, butylcholinesterase, or (most formally) acylcholine acylhydrolase, is produced in the liver and found primarily in blood plasma. The butyl and butyryl syllables both refer to butane with one of its terminal methyl groups substituted.
The half-life of BCHE is approximately 8 to 16 hours. BCHE levels may be reduced in patients with advanced liver disease. The decrease must be greater than 75% before significant prolongation of neuromuscular blockade occurs with succinylcholine.
In 1968, Walo Leuzinger et al. successfully purified and crystallized acetylcholinesterase from electric eels at Columbia University, NY.
Clinically useful quantities of butyrylcholinesterase were synthesized in 2007 by PharmAthene, through the use of genetically modified goats.
An absence or mutation of the BCHE enzyme leads to a medical condition known as pseudocholinesterase deficiency. This is a silent condition that manifests itself only when people that have the deficiency receive the muscle relaxants succinylcholine or mivacurium during a surgery.
Pseudocholinesterase deficiency may also affect local anaesthetic selection in dental procedures. The enzyme plays an important role in the metabolism of ester-based local anaesthetics, a deficiency lowers the margin of safety and increases the risk of systemic effects with this type of anaesthetic. The selection of an amide-based solution is recommended in such patients.
Elevation of plasma BCHE levels was observed in 90.5% cases of acute myocardial infarction.
The presence of ACHE in the amniotic fluid may be tested in early pregnancy. A sample of amniotic fluid is removed by amniocentesis, and presence of ACHE can confirm several common types of birth defect, including abdominal wall defects and neural tube defects.
BCHE can be used as a
- ATSDR Case Studies in Environmental Medicine: Cholinesterase Inhibitors, Including Insecticides and Chemical Warfare Nerve Agents U.S. Department of Health and Human Services
- Movies at weizmann.ac.il showing the structure of acetylcholinesterase and interactions with various inhibitors.
- Proteopedia Acetylcholinesterase
- PDB Molecule of the Month pdb54_1
- Acetylcholinesterase at the US National Library of Medicine Medical Subject Headings (MeSH)
- Pseudocholinesterase at the US National Library of Medicine Medical Subject Headings (MeSH)
- Wang R, Tang XC (2005). "Neuroprotective effects of huperzine A. A natural cholinesterase inhibitor for the treatment of Alzheimer's disease". Neuro-Signals 14 (1-2): 71–82.
- Barash PG, Cullen BF, Stoelting RK (2006). Handbook of Clinical Anesthesia (5th ed.). Philadelphia: Lippincott Williams & Wilkins. pp. 546–9.
- Miller RD (2005). Miller's Anesthesia (6th ed.). Philadelphia, Penns.: Elsevier/Churchill Livingstone. pp. 487–8.
- Leuzinger W, Baker AL (Feb 1967). "Acetylcholinesterase, I. Large-scale purification, homogeneity, and amino Acid analysis". Proceedings of the National Academy of Sciences of the United States of America 57 (2): 446–51.
- Leuzinger W, Baker AL, Cauvin E (Feb 1968). "Acetylcholinesterase. II. Crystallization, absorption spectra, isoionic point". Proceedings of the National Academy of Sciences of the United States of America 59 (2): 620–3.
- Sussman JL, Harel M, Frolow F, Oefner C, Goldman A, Toker L, Silman I (Aug 1991). "Atomic structure of acetylcholinesterase from Torpedo californica: a prototypic acetylcholine-binding protein". Science 253 (5022): 872–9.
- Huang YJ, Huang Y, Baldassarre H, Wang B, Lazaris A, Leduc M, Bilodeau AS, Bellemare A, Côté M, Herskovits P, Touati M, Turcotte C, Valeanu L, Lemée N, Wilgus H, Bégin I, Bhatia B, Rao K, Neveu N, Brochu E, Pierson J, Hockley DK, Cerasoli DM, Lenz DE, Karatzas CN, Langermann S (Aug 2007). "Recombinant human butyrylcholinesterase from milk of transgenic animals to protect against organophosphate poisoning". Proceedings of the National Academy of Sciences of the United States of America 104 (34): 13603–8.
- Shinde R, Chatterjea MN (2005). Textbook of Medical Biochemistry (6th ed.). New Delhi: Jaypee Brothers Medical Publications (P) Ltd. p. 565.
- FBR Resource Guide: Acetylcholinesterase-Amniotic Fluid. Foundation for Blood Research (September 7, 2007). Retrieved on 2007-11-21.
- Holmes JH, Kanfer I, Zwarenstein H (Aug 1978). "Effect of benzodiazepine derivatives on human blood cholinesterase in vitro". Research Communications in Chemical Pathology and Pharmacology 21 (2): 367–70.
- Ali N, Hoque MA, Haque A, Salam KA, Karim MR, Rahman A, Islam K, Saud ZA, Khalek MA, Akhand AA, Hossain M, Mandal A, Karim MR, Miyataka H, Himeno S, Hossain K. "Association between arsenic exposure and plasma cholinesterase activity: a population based study in Bangladesh". Environmental Health 9: 36.
- On organophosphates, where she is told her cholinesterase level is low.
- In the film The I Inside, Simon Cable is poisoned with cholinesterase inhibitors and he is given atropine and pralidoxime to help reverse the poison. The doctor is also shown dispensing a diazepam at the beginning of the movie.
- In the film The Rock, Dr. Goodspeed (Nicolas Cage) correctly describes the effects of the chemical weapon VX gas as a cholinesterase inhibitor to John Mason (Sean Connery) as they remove guidance chips from the rocket designed to deliver the gas into San Francisco from Alcatraz.
- Indie band Ruet Caelum have a song entitled 'Showing Signs of Cholinesterase Inhibition"
Outside of carbamate pesticides. In addition to acute poisoning as described above, a semi-acute poisoning characterized by strong mental disturbances can occur. Also, prolonged exposure can cause birth defects.
Cholinesterase levels can be used as an indirect marker of arsenic exposure.
Among the most common acetylcholinesterase inhibitors are phosphorus-based compounds, which are designed to bind to the active site of the enzyme. The structural requirements are a phosphorus atom bearing two lipophilic groups, a leaving group (such as a halide or thiocyanate), and a terminal oxygen. The entry on Lawesson's reagent has some details on one sub-class of the phosphorus-based compounds.
A cholinesterase inhibitor (or "anticholinesterase") suppresses the action of the enzyme. Because of its essential function, chemicals that interfere with the action of cholinesterase are potent neurotoxins, causing excessive salivation and eye-watering in low doses, followed by muscle spasms and ultimately death (examples are some snake venoms, and the nerve gases sarin and VX). One counteracting medication is pralidoxime. The so-called nerve gases and many substances used in insecticides have been shown to act by combining with a residue of serine in the active site of acetylcholine esterase, inhibiting the enzyme completely. The enzyme acetylcholine esterase breaks down the neurotransmitter acetylcholine, which is released at nerve and muscle junctions, in order to allow the muscle or organ to relax. The result of acetylcholine esterase inhibition is that acetylcholine builds up and continues to act so that any nerve impulses are continually transmitted and muscle contractions do not stop.