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Alpha-2 adrenergic receptor

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(Redirected from Alpha2-adrenergic agonist)

The alpha-2 (α2) adrenergic receptor (or adrenoceptor) is a G protein-coupled receptor (GPCR) associated with the Gi heterotrimeric G-protein. It consists of three highly homologous subtypes, including α2A-, α2B-, and α2C-adrenergic. Some species other than humans express a fourth α2D-adrenergic receptor as well.[1] Catecholamines like norepinephrine (noradrenaline) and epinephrine (adrenaline) signal through the α2-adrenergic receptor in the central and peripheral nervous systems.

Cellular localization

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The α2A adrenergic receptor is localised in the following central nervous system (CNS) structures:[2]

Whereas the α2B adrenergic receptor is localised in the following CNS structures:[2]

  • Thalamus
  • Pyramidal layer of the hippocampus
  • Cerebellar Purkinje layer

and the α2C adrenergic receptor is localised in the CNS structures:[2]

Effects

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The α2-adrenergic receptor is classically located on vascular prejunctional terminals where it inhibits the release of norepinephrine (noradrenaline) in a form of negative feedback.[3] It is also located on the vascular smooth muscle cells of certain blood vessels, such as those found in skin arterioles or on veins, where it sits alongside the more plentiful α1-adrenergic receptor.[3] The α2-adrenergic receptor binds both norepinephrine released by sympathetic postganglionic fibers and epinephrine (adrenaline) released by the adrenal medulla, binding norepinephrine with slightly higher affinity.[4] It has several general functions in common with the α1-adrenergic receptor, but also has specific effects of its own. Agonists (activators) of the α2-adrenergic receptor are frequently used in anaesthesia where they affect sedation, muscle relaxation and analgesia through effects on the central nervous system (CNS).[5]

In the brain, α2-adrenergic receptors can be localized either pre- or post-synaptically, and the majority of receptors appear to be post-synaptic.[6] For example, the α2A adrenergic receptor subtype is post-synaptic in the prefrontal cortex and these receptors strengthen cognitive and executive functions by inhibiting cAMP opening of potassium channels, thus enhancing prefrontal connections and neuronal firing.[7] The α2A-adrenergic agonist, guanfacine, is now used to treat prefrontal cortical cognitive disorders such as attention deficit hyperactivity disorder (ADHD).[8]

General

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Common effects include:

Individual

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Individual actions of the α2 receptor include:

Signaling cascade

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The α subunit of an inhibitory G protein - Gi dissociates from the G protein,[19] and associates with adenylyl cyclase. This causes the inactivation of adenylyl cyclase, resulting in a decrease of cAMP produced from ATP, which leads to a decrease of intracellular cAMP. PKA is not able to be activated by cAMP, so proteins such as phosphorylase kinase cannot be phosphorylated by PKA. In particular, phosphorylase kinase is responsible for the phosphorylation and activation of glycogen phosphorylase, an enzyme necessary for glycogen breakdown. Thus in this pathway, the downstream effect of adenylyl cyclase inactivation is decreased breakdown of glycogen.

The relaxation of gastrointestinal tract motility is by presynaptic inhibition,[16] where transmitters inhibit further release by homotropic effects.

Agonists
Partial agonists
Inverse agonist
Antagonists
Binding affinity (Ki in nM) and clinical data on a number of alpha-2 ligands[24][25][26][27]
Drug α1A α1B α1D α2A α2B α2C Indication(s) Route of Administration Bioavailability Elimination half-life Metabolising enzymes Protein binding
Agonists
Clonidine 316.23 316.23 125.89 42.92 106.31 233.1 Hypertension, ADHD, analgesia, sedation Oral, epidural, transdermal 75–85% (IR), 89% (XR) 12–16 h CYP2D6 20–40%
Dexmedetomidine 199.53 316.23 79.23 6.13 18.46 37.72 Procedural and ICU sedation IV 100% 6 minutes 94%
Guanfacine ? ? ? 71.81 1200.2 2505.2 Hypertension, ADHD Oral 80–100% (IR), 58% (XR) 17 h (IR), 18 h (XR) CYP3A4 70%
Xylazine ? ? ? 5754.4 3467.4 >10000 Veterinary sedation ? ? ? ? ?
Xylometazoline ? ? ? 15.14 1047.13 128.8 Nasal congestion Intranasal ? ? ? ?
Antagonists
Asenapine 1.2 ? ? 1.2 0.32 1.2 Schizophrenia, bipolar disorder Sublingual 35% 24 h CYP1A2 & UGT1A4 95%
Clozapine 1.62 7 ? 37 25 6 Treatment-resistant schizophrenia Oral 50–60% 12 h CYP1A2, CYP3A4, CYP2D6 97%
Mianserin 74 ? ? 4.8 27 3.8 Depression Oral 20% 21–61 h CYP3A4 95%
Mirtazapine 500 ? ? 20 ? 18 Depression Oral 50% 20–40 h CYP1A2, CYP2D6, CYP3A4 85%

Agonists

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Norepinephrine has higher affinity for the α2 receptor than epinephrine does, and therefore relates less to the latter's functions.[16] Nonselective α2 agonists include the antihypertensive drug clonidine,[16] which can be used to lower blood pressure and to reduce hot flashes associated with menopause. Clonidine has also been successfully used in indications that exceed what would be expected from a simple blood-pressure lowering drug: it has shown positive results in children with ADHD who have tics resulting from the treatment with a CNS stimulant drug, such as Adderall XR or methylphenidate;[28] clonidine also helps alleviate symptoms of opioid withdrawal.[29] The hypotensive effect of clonidine was initially attributed through its agonist action on presynaptic α2 receptors, which act as a down-regulator on the amount of norepinephrine released in the synaptic cleft, an example of autoreceptor. However, it is now known that clonidine binds to imidazoline receptors with a much greater affinity than α2 receptors, which would account for its applications outside the field of hypertension alone. Imidazoline receptors occur in the nucleus tractus solitarii and also the centrolateral medulla. Clonidine is now thought to decrease blood pressure via this central mechanism. Other nonselective agonists include dexmedetomidine, lofexidine (another antihypertensive), TDIQ (partial agonist), tizanidine (in spasms, cramping) and xylazine. Xylazine has veterinary use.

In the European Union, dexmedetomidine received a marketing authorization from the European Medicines Agency (EMA) on August 10, 2012, under the brand name of Dexdor.[30] It is indicated for sedation in the ICU for patients needing mechanical ventilation.

In non-human species this is an immobilizing and anesthetic drug, presumptively also mediated by α2 adrenergic receptors because it is reversed by yohimbine, an α2 antagonist.

α2A selective agonists include guanfacine (an antihypertensive) and brimonidine (UK 14,304).

(R)-3-nitrobiphenyline is an α2C selective agonist as well as being a weak antagonist at the α2A and α2B subtypes.[31][32]

Antagonists

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Nonselective α blockers include, A-80426, atipamezole, phenoxybenzamine, efaroxan, idazoxan[16] (experimental),[33] and SB-269,970.

Yohimbine[16] is a relatively selective α2 blocker that has been investigated as a treatment for erectile dysfunction.

Tetracyclic antidepressants mirtazapine and mianserin are also potent α antagonists with mirtazapine being more selective for α2 subtype (~30-fold selective over α1) than mianserin (~17-fold).

α2A selective blockers include BRL-44408 and RX-821,002.

α2B selective blockers include ARC-239 and imiloxan.

α2C selective blockers include JP-1302 and spiroxatrine, the latter also being a serotonin 5-HT1A antagonist.

See also

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References

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  1. ^ Ruuskanen JO, Xhaard H, Marjamäki A, Salaneck E, Salminen T, Yan YL, Postlethwait JH, Johnson MS, Larhammar D, Scheinin M (January 2004). "Identification of duplicated fourth alpha2-adrenergic receptor subtype by cloning and mapping of five receptor genes in zebrafish". Molecular Biology and Evolution. 21 (1): 14–28. doi:10.1093/molbev/msg224. PMID 12949138.
  2. ^ a b c d Saunders, C; Limbird, LE (November 1999). "Localization and trafficking of alpha2-adrenergic receptor subtypes in cells and tissues". Pharmacology & Therapeutics. 84 (2): 193–205. doi:10.1016/S0163-7258(99)00032-7. PMID 10596906.
  3. ^ a b c Cardiovascular Physiology, 3rd Edition, Arnold Publishers, Levick, J.R., Chapter 14.1, Sympathetic vasoconstrictor nerves
  4. ^ Boron, Walter F. (2012). Medical Physiology: A Cellular and Molecular Approach. p. 360.
  5. ^ a b c Khan, ZP; Ferguson, CN; Jones, RM (February 1999). "alpha-2 and imidazoline receptor agonists. Their pharmacology and therapeutic role". Anaesthesia. 54 (2): 146–65. doi:10.1046/j.1365-2044.1999.00659.x. PMID 10215710.
  6. ^ Multiple apparent alpha-noradrenergic receptor binding sites in rat brain: effect of 6-hydroxydopamine. Mol Pharmacol. 16: 47-60, 1979.
  7. ^ Alpha2A-adrenoceptors strengthen working memory networks by inhibiting cAMP-HCN channel signaling in prefrontal cortex. Cell 129: 397–410, 2007.
  8. ^ Guanfacine's mechanism of action in treating prefrontal cortical disorders: Successful translation across species. Neurobiol Learn Mem. 176: 107327, 2020.
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  17. ^ Wright EE, Simpson ER (1981). "Inhibition of the lipolytic action of beta-adrenergic agonists in human adipocytes by alpha-adrenergic agonists". J. Lipid Res. 22 (8): 1265–70. doi:10.1016/S0022-2275(20)37319-3. PMID 6119348.
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  20. ^ a b Haenisch, B.; Walstab, J.; Herberhold, S.; Bootz, F.; Tschaikin, M.; Ramseger, R.; Bönisch, H. (2009). "Alpha-adrenoceptor agonistic activity of oxymetazoline and xylometazoline". Fundamental & Clinical Pharmacology. 24 (6): 729–739. doi:10.1111/j.1472-8206.2009.00805.x. PMID 20030735. S2CID 25064699.
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  32. ^ Del Bello, Fabio; Mattioli, Laura; Ghelfi, Francesca; Giannella, Mario; Piergentili, Alessandro; Quaglia, Wilma; Cardinaletti, Claudia; Perfumi, Marina; Thomas, Russell J.; Zanelli, Ugo; Marchioro, Carla; Dal Cin, Michele; Pigini, Maria (11 November 2010). "Fruitful Adrenergic α2C-Agonism/α2A-Antagonism Combination to Prevent and Contrast Morphine Tolerance and Dependence". Journal of Medicinal Chemistry. 53 (21): 7825–7835. doi:10.1021/jm100977d. PMID 20925410.
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[edit]
  • "Adrenoceptors". IUPHAR Database of Receptors and Ion Channels. International Union of Basic and Clinical Pharmacology.