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Keywords: acetylcholine catabolic process in synaptic cleft, synaptic cleft, neurotransmitter, neurotransmitter catabolic process, synapse, sarin, snake toxin


Every time you move a muscle and every time you think a thought, your nerve cells are hard at work. They are processing information: receiving signals, deciding what to do with them, and dispatching new messages off to their neighbors. Some nerve cells communicate directly with muscle cells, sending them the signal to contract. Other nerve cells are involved solely in the bureaucracy of information, spending their lives communicating only with other nerve cells. But unlike our human bureaucracies, this processing of information must be fast in order to keep up with the ever-changing demands of life.


Nerves communicate with one another and with muscle cells by using neurotransmitters. These are small molecules that are released from the nerve cell and rapidly diffuse to neighboring cells, stimulating a response once they arrive. Many different neurotransmitters are used for different jobs: glutamate excites nerves into action; GABA inhibits the passing of information; dopamine and serotonin are involved in the subtle messages of thought and cognition. The main job of the neurotransmitter acetylcholine is to carry the signal from nerve cells to muscle cells. When a motor nerve cell gets the proper signal from the nervous system, it releases acetylcholine into its synapses with muscle cells. There, acetylcholine opens receptors on the muscle cells, triggering the process of contraction. Of course, once the message is passed, the neurotransmitter must be destroyed, otherwise later signals would get mixed up in a jumble of obsolete neurotransmitter molecules. The cleanup of old acetylcholine is the job of acetylcholinesterase.

Acetylcholinesterase in Action

Acetylcholinesterase is found in the synapse between nerve cells and muscle cells. It waits patiently and springs into action soon after a signal is passed, breaking down the acetylcholine into its two component parts, acetic acid and choline. This effectively stops the signal, allowing the pieces to be recycled and rebuilt into new neurotransmitters for the next message. Acetylcholinesterase has one of the fastest reaction rates of any of our enzymes, breaking up each molecule in about 80 microseconds.

Electric Fish

Acetylcholinesterase was first studied by using the form found in electric fish, such as the torpedo ray. These fish have massive arrays of nerve-like structures in the organs that generate electricity, so acetylcholinesterase is particularly abundant. The form shown here, from PDB entry 1acj, forms a dimer in the crystal structure. It normally has lipids attached to the protein chains, which anchor the enzyme to the cell membrane. The lipids were removed in the crystal structure, however, to allow crystallization. The active site is found in a deep pocket, just big enough for the acetylcholine to slip down inside. At the base of the pocket is a triad of three amino acids--serine-histidine-glutamate--that is almost identical to the triad used in the serine proteases like trypsin and chymotrypsin.


Attacking Acetylcholinesterase

Since acetylcholinesterase has an essential function, it is a potential weak point in our nervous system. Poisons and toxins that attack the enzyme cause acetylcholine to accumulate in the nerve synapse, paralyzing the muscle. Over the years, acetylcholinesterase has been attacked in many ways by natural enemies. For instance, some snake toxins attack acetylcholinesterase. The picture at the top shows a view straight down the active site tunnel, from PDB entry 1b41, showing the active site serine in red. The middle picture shows how a lethal toxin from the eastern green mamba blocks the active site and poisons the action of the enzyme. For more information on snake toxins, take a look at the Protein of the Month at the European Bioinformatics Institute.

Doctors are now willfully poisoning acetylcholinesterase in an attempt to reverse the symptoms of Alzheimer's disease. People with Alzheimer's disease lose many nerve cells as the disease progresses. By taking a drug that partially blocks acetylcholinesterase, the levels of the neurotransmitter can be raised, strengthening the nerve signals that remain. One drug being used in the way is shown at the bottom, from PDB entry 1eve. It inserts into the active site pocket and temporarily blocks entry of acetylcholine. Other poisons, as shown on the next page, take a more permanent approach.



Exploring the Structure

The nerve toxin sarin and insecticides such as malathion directly attack the active site machinery of acetylcholinesterase. The structure shown here, from PDB entry 1cfj, shows the active site triad of acetylcholinesterase after being poisoned by sarin. In the normal reaction, the serine amino acid forms a bond to the acetyl group of acetylcholine, breaking the molecule. Then, in a matter of microseconds, a water molecule breaks the new bond, releasing acetic acid and restoring the serine to its original form. Sarin, however, transfers a nasty methylphosphonate group (MeP in the picture) to the serine. The phosphonate is far more stable and will disable the enzyme for hours or days.

This picture was created with RasMol. You can create similar pictures by clicking on the accession codes and picking one of the options under View Structure.


Further reading on acetylcholinesterase

P. Taylor (1991) The Cholinesterases. Journal of Biological Chemistry 266, 4025-4028.
P. Taylor and Z. Radic (1994) The Cholinesterases: From genes to Proteins. Annual Review of Pharmacology and Toxicology 34, 281-320.
K. L. Davis (2002) Current and Experimental Therapeutics of Alzheimer Disease. In Neuropsychopharmacology, K.L. Davis, D. Charney, J.T. Coyle, C. Nemeroff editors. Lippincott, Williams and Wilkins, publishers.
J. L. Sussman, M. Harel, F. Frolow, C. Oefner, A. Goldman, L. Toker and I. Silman (1991) Atomic structure of acetylcholinesterase from Torpedo californica: a prototypic acetylcholine-binding protein. Science 253, 872-879.

Discussed Structures

Discussed Structures

© 2014 David Goodsell & RCSB Protein Data Bank