Molecular biology has shown that the nicotinic and muscarinic receptors belong to distinct
protein superfamilies. Nicotinic receptors are of two types: Nm and Nn. Nm is located in the neuromuscular junction which causes the contraction of skeletal muscles by way of
end-plate potential (EPPs). Nn causes depolarization in autonomic ganglia resulting in post ganglionic impulse. Nicotinic receptors cause the release of catecholamine from the adrenal medulla, and also site specific excitation or inhibition in brain. Both Nm and Nn receptor types are non-selective cation channels, permeable to sodium and potassium ions, in addition to that, Nn type receptors allow for calcium ion flow.
nAChR The nAChRs are
ligand-gated ion channels, and, like other members of the "
cys-loop" ligand-gated ion channel superfamily, are composed of five
protein subunits symmetrically arranged like staves around a barrel. The subunit composition is highly variable across different tissues. Each subunit contains four regions which span the membrane and consist of approximately 20 amino acids. Region II which sits closest to the pore lumen, forms the pore lining. Binding of acetylcholine to the N termini of each of the two alpha subunits results in the 15° rotation of all M2 helices. The cytoplasm side of the nAChR receptor has rings of high negative charge that determine the specific cation specificity of the receptor and remove the hydration shell often formed by ions in aqueous solution. In the intermediate region of the receptor, within the pore lumen,
valine and
leucine residues (Val 255 and Leu 251) define a hydrophobic region through which the dehydrated ion must pass. The nAChR is found at the
edges of junctional folds at the
neuromuscular junction on the postsynaptic side; it is activated by
acetylcholine release across the synapse. The diffusion of Na+ and K+ across the receptor causes depolarization, the end-plate potential, that opens
voltage-gated sodium channels, which allows for firing of the
action potential and potentially muscular contraction.
mAChR In contrast, the
mAChRs are not ion channels, but belong instead to the superfamily of class A (rhodopsin-like)
G-protein-coupled receptors that activate a
second messenger cascade. Muscarinic acetylcholinre receptors have 7 transmembrane domains. In the CNS, they are primarily located in the
hippocampus, cortex, and
thalamus. They help transduce signals in the CNS,
autonomic ganglia,
smooth muscle, and parasympathetic organs. When the excitatory Gq receptors are activated, they make
phospholipase C and
protein kinase C. These go on to make
diacylglycerol (DAG) and inositol triphosphate (IP3) which then increase intracellular calcium levels which causes the excitatory reaction. Gi is the inhibitory receptor which decreases levels of
adenylyl cyclase, causing a decrease in protein kinase A and
cAMP which then causes inhibition. == Origin and evolution ==