Acetylcholine receptors named for their selective binding of nicotine
Nicotinic acetylcholine receptors, or nAChRs, are receptorpolypeptides that respond to the neurotransmitter acetylcholine. Nicotinic receptors also respond to drugs such as the agonist nicotine. They are found in the central and peripheral nervous system, muscle, and many other tissues of many organisms. At the neuromuscular junction they are the primary receptor in muscle for motor nerve-muscle communication that controls muscle contraction. In the peripheral nervous system: (1) they transmit outgoing signals from the presynaptic to the postsynaptic cells within the sympathetic and parasympathetic nervous system, and (2) they are the receptors found on skeletal muscle that receive acetylcholine released to signal for muscular contraction. In the immune system, nAChRs regulate inflammatory processes and signal through distinct intracellular pathways.[1] In insects, the cholinergic system is limited to the central nervous system.[2]
The nicotinic receptors are considered cholinergic receptors, since they respond to acetylcholine. Nicotinic receptors get their name from nicotine which does not stimulate the muscarinic acetylcholine receptors but selectively binds to the nicotinic receptors instead.[3][4][5] The muscarinic acetylcholine receptor likewise gets its name from a chemical that selectively attaches to that receptor—muscarine.[6] Acetylcholine itself binds to both muscarinic and nicotinic acetylcholine receptors.[7]
As ionotropic receptors, nAChRs are directly linked to ion channels. Some evidence suggests that these receptors can also use second messengers (as metabotropic receptors do) in some cases.[8] Nicotinic acetylcholine receptors are the best-studied of the ionotropic receptors.[3]
Since nicotinic receptors help transmit outgoing signals for the sympathetic and parasympathetic systems, nicotinic receptor antagonists such as hexamethonium interfere with the transmission of these signals. Thus, for example, nicotinic receptor antagonists interfere with the baroreflex[9] that normally corrects changes in blood pressure by sympathetic and parasympathetic stimulation of the heart.
Structure
Nicotinic receptors, with a molecular mass of 290 kDa,[10] are made up of five subunits, arranged symmetrically around a central pore.[3] Each subunit comprises four transmembrane domains with both the N- and C-terminus located extracellularly. They possess similarities with GABAA receptors, glycine receptors, and the type 3 serotonin receptors (which are all ionotropic receptors), or the signature Cys-loop proteins.[11]
In vertebrates, nicotinic receptors are broadly classified into two subtypes based on their primary sites of expression: muscle-type nicotinic receptors and neuronal-type nicotinic receptors. In the muscle-type receptors, found at the neuromuscular junction, receptors are either the embryonic form, composed of α1, β1, γ, and δ subunits in a 2:1:1:1 ratio ((α1)2β1γδ), or the adult form composed of α1, β1, δ, and ε subunits in a 2:1:1:1 ratio ((α1)2β1δε).[3][4][5][12] The neuronal subtypes are various homomeric (all one type of subunit) or heteromeric (at least one α and one β) combinations of twelve different nicotinic receptor subunits: α2−α10 and β2−β4. Examples of the neuronal subtypes include: (α4)3(β2)2, (α4)2(β2)3, (α3)2(β4)3, α4α6β3(β2)2, (α7)5, and many others. In both muscle-type and neuronal-type receptors, the subunits are very similar to one another, especially in the hydrophobic regions.[13]
A number of electron microscopy and x-ray crystallography studies have provided very high resolution structural information for muscle and neuronal nAChRs and their binding domains.[10][14][15][16]
As with all ligand-gated ion channels, opening of the nAChR channel pore requires the binding of a chemical messenger. Several different terms are used to refer to the molecules that bind receptors, such as ligand, agonist, or transmitter. As well as the endogenous agonist acetylcholine, agonists of the nAChR include nicotine, epibatidine, and choline. Nicotinic antagonists that block the receptor include mecamylamine, dihydro-β-erythroidine, and hexamethonium.[13]
In muscle-type nAChRs, the acetylcholine binding sites are located at the α and either ε or δ subunits interface. In neuronal nAChRs, the binding site is located at the interface of an α and a β subunit or between two α subunits in the case of α7 receptors. The binding site is located in the extracellular domain near the N terminus.[4][17] When an agonist binds to the site, all present subunits undergo a conformational change and the channel is opened[18] and a pore with a diameter of about 0.65 nm opens.[4]
Channel opening
Nicotinic AChRs may exist in different interconvertible conformational states. Binding of an agonist stabilizes the open and desensitized states. In normal physiological conditions, the receptor needs exactly two molecules of ACh to open.[19] Opening of the channel allows positively charged ions to move across it; in particular, sodium enters the cell and potassium exits. The net flow of positively charged ions is inward.
The nAChR is a non-selective cation channel, meaning that several different positively charged ions can cross through.[3] It is permeable to Na+ and K+, with some subunit combinations that are also permeable to Ca2+.[4][20][21] The amount of sodium and potassium the channels allow through their pores (their conductance) varies from 50 to 110 pS, with the conductance depending on the specific subunit composition as well as the permeant ion.[22]
Many neuronal nAChRs can affect the release of other neurotransmitters.[5] The channel usually opens rapidly and tends to remain open until the agonistdiffuses away, which usually takes about 1 millisecond.[4] AChRs can spontaneously open with no ligands bound or can spontaneously close with ligands bound, and mutations in the channel can shift the likelihood of either event.[23][18] Therefore, ACh binding changes the probability of pore opening, which increases as more ACh binds.
The nAChR is unable to bind ACh when bound to any of the snake venomα-neurotoxins. These α-neurotoxins antagonistically bind tightly and noncovalently to nAChRs of skeletal muscles and in neurons, thereby blocking the action of ACh at the postsynaptic membrane, inhibiting ion flow and leading to paralysis and death. The nAChR contains two binding sites for snake venom neurotoxins. Progress in discovering the dynamics of binding action of these sites has proved difficult, although recent studies using normal mode dynamics[24] have aided in predicting the nature of both the binding mechanisms of snake toxins and of ACh to nAChRs. These studies have shown that a twist-like motion caused by ACh binding is likely responsible for pore opening, and that one or two molecules of α-bungarotoxin (or other long-chain α-neurotoxin) suffice to halt this motion. The toxins seem to lock together neighboring receptor subunits, inhibiting the twist and therefore, the opening motion.[25]
Ligand-bound desensitization of receptors was first characterized by Katz and Thesleff in the nicotinic acetylcholine receptor.[26]
Prolonged or repeated exposure to a stimulus often results in decreased responsiveness of that receptor toward a stimulus, termed desensitization. nAChR function can be modulated by phosphorylation[27] by the activation of second messenger-dependent protein kinases. PKA[26] and PKC,[28] as well as tyrosine kinases,[29] have been shown to phosphorylate the nAChR resulting in its desensitization. It has been reported that, after prolonged receptor exposure to the agonist, the agonist itself causes an agonist-induced conformational change in the receptor, resulting in receptor desensitization.[30]
Desensitized receptors can revert to a prolonged open state when an agonist is bound in the presence of a positive allosteric modulator, for example PNU-120,596.[31] Also, there is evidence that indicates specific chaperone molecules have regulatory effects on these receptors.[32]
Roles
The subunits of the nicotinic receptors belong to a multigene family (16 members in humans) and the assembly of combinations of subunits results in a large number of different receptors (for more information see the Ligand-Gated Ion Channel database). These receptors, with highly variable kinetic, electrophysiological and pharmacological properties, respond to nicotine differently, at very different effective concentrations. This functional diversity allows them to take part in two major types of neurotransmission. Classical synaptic transmission (wiring transmission) involves the release of high concentrations of neurotransmitter, acting on immediately neighboring receptors. In contrast, paracrine transmission (volume transmission) involves neurotransmitters released by axon terminals, which then diffuse through the extra-cellular medium until they reach their receptors, which may be distant.[33] Nicotinic receptors can also be found in different synaptic locations; for example the muscle nicotinic receptor always functions post-synaptically. The neuronal forms of the receptor can be found both post-synaptically (involved in classical neurotransmission) and pre-synaptically[34] where they can influence the release of multiple neurotransmitters.
Subunits
17 vertebrate nAChR subunits have been identified, which are divided into muscle-type and neuronal-type subunits. Although an α8 subunit/gene is present in avian species such as the chicken, it is not present in human or mammalian species.[35]
The nAChR subunits have been divided into four subfamilies (I–IV) based on similarities in protein sequence.[36] In addition, subfamily III has been further divided into three types.
Neuronal nAChRs are transmembrane proteins that form pentameric structures assembled from a family of subunits composed of α2–α10 and β2–β4.[37] These subunits were discovered from the mid-1980s through the early 1990s, when cDNAs for multiple nAChR subunits were cloned from rat and chicken brains, leading to the identification of eleven different genes (twelve in chickens) that code for neuronal nAChR subunits; The subunit genes identified were named α2–α10 (α8 only found in chickens) and β2–β4.[38] It has also been discovered that various subunit combinations could form functional nAChRs that could be activated by acetylcholine and nicotine, and the different combinations of subunits generate subtypes of nAChRs with diverse functional and pharmacological properties.[39] When expressed alone, α7, α8, α9, and α10 are able to form functional receptors, but other α subunits require the presence of β subunits to form functional receptors.[37] In mammals, nAchR subunits have been found to be encoded by 17 genes, and of these, nine genes encoding α-subunits and three encoding β-subunits are expressed in the brain. β2 subunit-containing nAChRs (β2nAChRs) and α7nAChRs are widely expressed in the brain, whereas other nAChR subunits have more restricted expression.[40] The pentameric assembly of nAChRs is subjected to the subunits that are produced in various cell types such as in the human lung where epithelial and muscular pentamers largely differ.[41]
CHRNA5/A3/B4
An important nAchR gene cluster (CHRNA5/A3/B4) contains the genes encoding for the α5, α3 and β4 subunits. Genetic studies have identified single nucleotide polymorphisms (SNPs) in the chromosomal locus encoding these three nAChR genes as risk factors for nicotine dependence, lung cancer, chronic obstructive pulmonary disease, alcoholism, and peripheral arterial disease.[37][42] The CHRNA5/A3/B4 nAChR subunit genes are found in a tight cluster in chromosomal region 15q24–25. The nAChR subunits encoded by this locus form the predominant nicotinic receptor subtypes expressed in the peripheral nervous system (PNS) and other key central nervous system (CNS) sites, such as the medial habenula, a structure between the limbic forebrain and midbrain involved in major cholinergic circuitry pathways.[37] Further research of the CHRNA5/A3/B4 genes have revealed that "neuronal" nAChR genes are also expressed in non-neuronal cells where they are involved in various fundamental processes, such as inflammation.[43] The CHRNA5/A3/B4 genes are co-expressed in many cell types and the transcriptional activities of the promoter regions of the three genes are regulated by many of the same transcription factors, demonstrating that their clustering may reflect control of gene expression.[37]
CHRNA6/CHRNB3
CHRNB3 and CHRNA6 are also grouped in a gene cluster, located on 8p11.[42] Multiple studies have shown that SNPS in the CHRNB3–CHRNA6 have been linked to nicotine dependence and smoking behavior, such as two SNPs in CHRNB3, rs6474413 and rs10958726.[42] Genetic variation in this region also displays influence susceptibility to use drugs of abuse, including cocaine and alcohol consumption.[44] Nicotinic receptors containing α6 or β3 subunits expressed in brain regions, especially in the ventral tegmental area and substantia nigra, are important for drug behaviors due to their role in dopamine release.[45] Genetic variation in these genes can alter sensitivity to drugs of abuse in numerous ways, including changing the amino acid structure of the protein or cause alterations in transcriptional and translational regulation.[44]
CHRNA4/CHRNB2
Other well studied nAChR genes include the CHRNA4 and CHRNB2, which have been associated as Autosomal Dominant Nocturnal Frontal Lobe Epilepsy (ADNFLE) genes.[42][46] Both of these nAChR subunits are present in the brain and the occurrence of mutations in these two subunits cause a focal type of epilepsy. Examples include the CHRNA4 insertion mutation 776ins3 that is associated with nocturnal seizures and psychiatric disorders, and the CHRNB2 mutation I312M that seems to cause not only epilepsy but also very specific cognitive deficits, such as deficits in learning and memory.[46][47] There is naturally occurring genetic variation between these two genes and analysis of single nucleotide polymorphisms (SNPs) and other gene modifications show a higher variation in the CHRNA4 gene than in the CHRNB2 gene, implying that nAChR β2, the protein encoded by CHRNB2, associates with more subunits than α4. CHRNA2 has also been reported as a third candidate for nocturnal frontal lobe seizures.[42][46]
CHRNA7
Several studies have reported an association between CHRNA7 and endophenotypes of psychiatric disorders and nicotine dependence, contributing to the significant clinical relevance of α7 and research being done on it.[46] CHRNA7 was one of the first genes that had been considered to be involved with schizophrenia. Studies identified several CHRNA7 promoter polymorphisms that reduce the genes transcriptional activity to be associated with schizophrenia, which is consistent with the finding of reduced levels of a7 nAChRs in the brain of schizophrenic patients.[46] Both nAChRs subtypes, α4β2 and α7, have been found to be significantly reduced in post-mortem studies of individuals with schizophrenia.[48] Additionally, smoking rates are significantly higher in those with schizophrenia, implying that smoking nicotine may be a form of self-medicating.[49]
Notable variations
Nicotinic receptors are pentamers of these subunits; i.e., each receptor contains five subunits. Thus, there is immense potential of variation of these subunits, some of which are more commonly found than others. The most broadly expressed subtypes include (α1)2β1δε (adult muscle-type), (α3)2(β4)3 (ganglion-type), (α4)2(β2)3 (CNS-type) and (α7)5 (another CNS-type).[50] A comparison follows:
Post- and presynaptic excitation,[50] mainly by increased Na+, K+ and Ca2+ permeability. Major subtype involved in some of the cognitive effects of nicotine.[55] Moreover, activation of (α7)5 could improve neurovascular coupling response in neurodegenerative disease[56] and neurogenesis in ischemic stroke.[57] Also involved in the pro-angiogenic effects of nicotine and accelerate the progression of chronic kidney disease in smokers.[58][59][60]
^Ishii M, Kurachi Y (1 October 2006). "Muscarinic acetylcholine receptors". Current Pharmaceutical Design. 12 (28): 3573–81. doi:10.2174/138161206778522056. PMID17073660.
^Lott EL, Jones EB (2020). "Cholinergic Toxicity". StatPearls. StatPearls Publishing. PMID30969605.
^Kabbani N, Nordman JC, Corgiat BA, Veltri DP, Shehu A, Seymour VA, Adams DJ (December 2013). "Are nicotinic acetylcholine receptors coupled to G proteins?". BioEssays. 35 (12): 1025–34. doi:10.1002/bies.201300082. PMID24185813. S2CID9441100.
^ abUnwin N (March 2005). "Refined structure of the nicotinic acetylcholine receptor at 4A resolution". Journal of Molecular Biology. 346 (4): 967–89. doi:10.1016/j.jmb.2004.12.031. PMID15701510.
^Brejc K, van Dijk WJ, Klaassen RV, Schuurmans M, van Der Oost J, Smit AB, Sixma TK (May 2001). "Crystal structure of an ACh-binding protein reveals the ligand-binding domain of nicotinic receptors". Nature. 411 (6835): 269–76. Bibcode:2001Natur.411..269B. doi:10.1038/35077011. PMID11357122. S2CID4415937.
^Zouridakis M, Giastas P, Zarkadas E, Chroni-Tzartou D, Bregestovski P, Tzartos SJ (November 2014). "Crystal structures of free and antagonist-bound states of human α9 nicotinic receptor extracellular domain". Nature Structural & Molecular Biology. 21 (11): 976–80. doi:10.1038/nsmb.2900. PMID25282151. S2CID30096256.
^Beker F, Weber M, Fink RH, Adams DJ (September 2003). "Muscarinic and nicotinic ACh receptor activation differentially mobilize Ca2+ in rat intracardiac ganglion neurons". Journal of Neurophysiology. 90 (3): 1956–64. doi:10.1152/jn.01079.2002. PMID12761283. S2CID8684707.
^Barrantes FJ (September 1978). "Agonist-mediated changes of the acetylcholine receptor in its membrane environment". Journal of Molecular Biology. 124 (1): 1–26. doi:10.1016/0022-2836(78)90144-4. PMID712829.
^Sadigh-Eteghad S, Majdi A, Talebi M, Mahmoudi J, Babri S (May 2015). "Regulation of nicotinic acetylcholine receptors in Alzheimer׳s disease: a possible role of chaperones". European Journal of Pharmacology. 755: 34–41. doi:10.1016/j.ejphar.2015.02.047. PMID25771456. S2CID31929001.
^Graham A, Court JA, Martin-Ruiz CM, Jaros E, Perry R, Volsen SG, et al. (2002). "Immunohistochemical localization of nicotinic acetylcholine receptor subunits in human cerebellum". Neuroscience. 113 (3): 493–507. doi:10.1016/S0306-4522(02)00223-3. PMID12150770. S2CID39839166.
^Le Novère N, Changeux JP (February 1995). "Molecular evolution of the nicotinic acetylcholine receptor: an example of multigene family in excitable cells". Journal of Molecular Evolution. 40 (2): 155–72. Bibcode:1995JMolE..40..155L. doi:10.1007/BF00167110. PMID7699721. S2CID2040912.
^Graham A, Court JA, Martin-Ruiz CM, Jaros E, Perry R, Volsen SG, et al. (September 2002). "Immunohistochemical localization of nicotinic acetylcholine receptor subunits in human cerebellum". Neuroscience. 113 (3): 493–507. doi:10.1016/S0306-4522(02)00223-3. PMID12150770. S2CID39839166.
^Wu J, Gao M, Shen JX, Shi WX, Oster AM, Gutkin BS (October 2013). "Cortical control of VTA function and influence on nicotine reward". Biochemical Pharmacology. 86 (8): 1173–80. doi:10.1016/j.bcp.2013.07.013. PMID23933294.
^"Nicotine: Biological activity". IUPHAR/BPS Guide to Pharmacology. International Union of Basic and Clinical Pharmacology. Retrieved 7 February 2016. Kis as follows; α2β4=9900nM [5], α3β2=14nM [1], α3β4=187nM [1], α4β2=1nM [4,6]. Due to the heterogeneity of nACh channels we have not tagged a primary drug target for nicotine, although the α4β2 is reported to be the predominant high affinity subtype in the brain which mediates nicotine addiction [2-3].
^Mihalak KB, Carroll FI, Luetje CW (September 2006). "Varenicline is a partial agonist at alpha4beta2 and a full agonist at alpha7 neuronal nicotinic receptors". Molecular Pharmacology. 70 (3): 801–5. doi:10.1124/mol.106.025130. PMID16766716. S2CID14562170.