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Title: N-Arachidonylglycine  
Author: World Heritage Encyclopedia
Language: English
Subject: Stearoylethanolamide, Docosatetraenoylethanolamide, Arachidonoyl serotonin, Hypotaurine, Oleoylethanolamide
Publisher: World Heritage Encyclopedia


CAS number  N
ChemSpider  YesY
Jmol-3D images Image 1
Image 2
Molecular formula C22H35NO3
Molar mass 361.52 g mol−1
Except where noted otherwise, data are given for materials in their standard state (at 25 °C (77 °F), 100 kPa)
 N   YesY/N?)

N-Arachidonylglycine (NAGly) is a carboxylic analog of the endocannabinoid anandamide.[1] Since it was first synthesized in 1996,[2] NAGly has been a primary focus of the relatively contemporary field of lipidomics due to its wide range of signaling targets in the brain, the immune system and throughout various other bodily systems. In combination with 2‐arachidonoyl glycerol (2‐AG), NAGly has enabled the identification of a family of lipids often referred to as endocannabinoids.[3] Recently, NAGly has been found to bind to G-protein coupled receptor 18 (GPR18), the putative abnormal cannabidiol receptor.[4][5] NaGly is found throughout the body and research on its explicit functions is on going.


The exact biosynthesis of NaGly is not completely understood, but there are two proposed pathways found in vitro for its biosynthesis: 1) enzymatically regulated conjugation of arachidonic acid and glycine and 2) the oxidative metabolism of the endogenous cannabinoid anandamide.[6][7] In the first pathway, Cytochrome c catalyzes the in vitro synthesis of NaGly from arachidonoyl coenzyme A and glycine in the presence of hydrogen peroxide.[8] In the second pathway, alcohol dehydrogenase catalyzes the oxidation of anandamide into N-arachidonoyl glycine.[9]


Effects on the nervous system

NAGly has been hypothesized to have a neurophysiological function of pain suppression, supported by evidence that it suppresses formalin-induced pain behavior in rats.[10] In particular, peripherally administered NAGly inhibited phase 2 pain behavior, suggesting either a direct suppression of nociceptive afferents on the nerve or an indirect modulation of the afferents' interstitial environment.[10] In either case, these findings hold promise for NAGly as a means of mitigating postoperative or chronic pain. NAGly is also effective in acute pain models, reducing mechanical allodynia and thermal hyperalgesia induced by intraplantar injection of Fruend's complete adjuvant.[11] Similar mechanical allydonia induced by partial ligation of the sciatic nerve was also reduced by NaGly.[12] Other arachidonic acid-amino acid conjugates did not have the same effects and the actions of NaGly were not affected by cannabinoid receptor agonists in either study, suggesting a novel non-cannabinoid receptor mediated approach to alleviate inflammatory pain.[11][12]

NaGly was shown to be endogenous ligand for the G-protein couple receptor GPR92 along with farnesyl pyrophosphate.[13] In the dorsal root ganglia (DRG), where GPR92 was found to be localized NaGly increased intracellular calcium levels in DRG neurons, indicating a role of NaGly in the sensory nervous system through the activation of GPR92.[13]

Effects on the immune system

NAGly has been the focus of research on the immune system because of its antinociceptive effects and inhibitory action on components of the immune system. Specifically, it significantly inhibited TNFα and IFNγ production, and it shows potential as a therapeutic treatment for chronic inflammation.[14] Moreover, NAGly has been shown to act as a substrate for cyclooxygenase-2 (COX-2), the enzyme primarily known for producing prostaglandins associated with increases in inflammation and hyperalgesia. In many mammalian tissues that express COX-2, significant levels of NAGly are naturally present, and in these tissues COX-2 selectively metabolizes NAGly prostaglandin (PG) H2 glycine and HETE-Gly.[15]

Cell migration

NAGly has been hypothesized to induce cell migration in BV-2 microglia cells.[4] The same research suggests that this migration occurs through GPR18. This was verified using GPR18 transfected HEK-293 cells. The same migration wasn't witnessed using non-transfected and GPR55 transfected HEK-293.[4] Additionally, tetrahydrocannabinol and NaGly are full agonists at the GPR18 receptors and induce migration in human endometrial HEC-1B cells.[16] Understanding functions of NaGly in such structures provides a promising future in helping treat diseases such as endometriosis.

Other targets

Insulin secretion

NaGly was identified as a novel insulin secretagogue and was shown to increase intracellular calcium concentration through stimulation of voltage dependent calcium channels.[17] Additionally, this action was dependent on extracellular glucose level.[17]

Additional biochemical interactions

NaGly has been shown to inhibit the glycine transporter GLYT2a in a non-competitive fashion with arachidonic acids and secondary messenger systems of GLYT2a, suggesting a novel recognition site for the N-arachodnoyl amino acids, especially because other conjugated amino acids had similar effects.[18]


  1. ^ Burstein, Sumner; Huang, S.M.; Petros, T.J.; Rossetti, R.G.; Walker, J.M.; Zurier, R.B. (30 April 2002). "Regulation of anandamide tissue levels by N-arachidonylglycine". Biochemical Pharmacology 64 (7): 1147–1150.  
  2. ^ Sheskin, Tzviel; Hanus, L.; Slager, J.; Vogel, Z.; Mechoulam, R. (1997). "Structural Requirements for Binding of Anandamide-Type Compounds to the Brain Cannabinoid Receptor". Journal of Medicinal Chemistry 40 (5): 659–667.  
  3. ^ Bradshaw, Heather; Rimmerman, N.; Hu, S.J.; Burstein, S.; Walker, J.M. (2009). "Novel Endogenous N-Acyl Glycines: Identification and Characterization". Vitamins and Hormones. Vitamins & Hormones 81: 191–205.  
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  7. ^ Aneetha, Halikhedkar; O’Dell, David K.; Tan, Bo; Walker, J. Michael; Hurley, Thomas D. (1 January 2009). "Alcohol dehydrogenase-catalyzed in vitro oxidation of anandamide to N-arachidonoyl glycine, a lipid mediator: Synthesis of N-acyl glycinals". Bioorganic & Medicinal Chemistry Letters 19 (1): 237–241.  
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  13. ^ a b Oh, D. Y.; Yoon, J. M.; Moon, M. J.; Hwang, J.-I.; Choe, H.; Lee, J. Y.; Kim, J. I.; Kim, S.; Rhim, H.; O'Dell, D. K.; Walker, J. M.; Na, H. S.; Lee, M. G.; Kwon, H. B.; Kim, K.; Seong, J. Y. (22 May 2008). "Identification of Farnesyl Pyrophosphate and N-Arachidonylglycine as Endogenous Ligands for GPR92". Journal of Biological Chemistry 283 (30): 21054–21064.  
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  15. ^ Prusakiewicz, J; Kingsley P; Kozak K; Marnett L (2002). "Selective oxygenation of N-arachidonylglycine by cyclooxygenase-2". Biochemical and Biophysical Research Communications 296: 612–617.  
  16. ^ McHugh, Douglas; Page, Jeremy; Dunn, Emily; Bradshaw, Heather B (1 April 2012). "Δ9-Tetrahydrocannabinol and N-arachidonyl glycine are full agonists at GPR18 receptors and induce migration in human endometrial HEC-1B cells". British Journal of Pharmacology 165 (8): 2414–2424.  
  17. ^ a b Ikeda, Yukio; Iguchi, Haruhisa; Nakata, Masanori; Ioka, Ryoichi X.; Tanaka, Toshiya; Iwasaki, Satoshi; Magoori, Kenta; Takayasu, Shinobu; Yamamoto, Tokuo T.; Kodama, Tatsuhiko; Yada, Toshihiko; Sakurai, Takeshi; Yanagisawa, Masashi; Sakai, Juro (1 August 2005). "Identification of N-arachidonylglycine, U18666A, and 4-androstene-3,17-dione as novel insulin Secretagogues". Biochemical and Biophysical Research Communications 333 (3): 778–786.  
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