Coronaridine

Last updated
Coronaridine
Coronaridine.svg
Coronaridine molecule ball.png
Clinical data
ATC code
  • none
Identifiers
  • Methyl (1S,15R,17S,18S)-17-ethyl-3,13-diazapentacyclo[13.3.1.02,10.04,9.013,18]nonadeca-2(10),4,6,8-tetraene-1-carboxylate
CAS Number
PubChem CID
ChemSpider
ChEBI
CompTox Dashboard (EPA)
ECHA InfoCard 100.006.727 OOjs UI icon edit-ltr-progressive.svg
Chemical and physical data
Formula C21H26N2O2
Molar mass 338.451 g·mol−1
3D model (JSmol)
  • CCC1CC2CC3(C1N(C2)CCC4=C3NC5=CC=CC=C45)C(=O)OC
  • InChI=1S/C21H26N2O2/c1-3-14-10-13-11-21(20(24)25-2)18-16(8-9-23(12-13)19(14)21)15-6-4-5-7-17(15)22-18/h4-7,13-14,19,22H,3,8-12H2,1-2H3/t13-,14+,19+,21-/m1/s1
  • Key:NVVDQMVGALBDGE-PZXGUROGSA-N

Coronaridine, also known as 18-carbomethoxyibogamine, is an alkaloid found in Tabernanthe iboga and related species, including Tabernaemontana divaricata for which (under the now obsolete synonym Ervatamia coronaria) it was named. [1]

Contents

Like ibogaine, (R)-coronaridine and (S)-coronaridine can decrease intake of cocaine and morphine in animals [2] and it may have muscle relaxant and hypotensive activity. [3]

Chemistry

Congeners

Coronaridine congers are important in drug discovery and development due to multiple actions on different targets. They have ability to inhibit Cav2.2 channel, [4] modulate and inhibit subunits of nAChr selectively such as α9α10, [4] α3β4 [5] [6] and potentiate GABAA activity. [7]

Pharmacology

Coronaridine has been reported to bind to an assortment of molecular sites, including: μ-opioid (Ki = 2.0 μM), δ-opioid (Ki = 8.1 μM), and κ-opioid receptors (Ki = 4.3 μM), NMDA receptor (Ki = 6.24 μM) (as an antagonist), [8] and nAChRs (as an antagonist). [9] It has also been found to inhibit the enzyme acetylcholinesterase, act as a voltage-gated sodium channel blocker, [10] and displays estrogenic activity in rodents. [8] [9] In contrast to ibogaine and other iboga alkaloids, coronaridine does not bind to either the σ1 or σ2 receptor. [10]

Sources

Plant sources
FamilyPlants
Apocynaceae T. catharinensis, T. ternifolia, T. pandacaqui, T. heyneana, T. litoralis, T. divaricata, T. penduliflora. [11]

See also

Related Research Articles

<span class="mw-page-title-main">Ibogaine</span> Psychoactive substance found in plants in the family Apocynaceae

Ibogaine is a naturally occurring psychoactive substance found in plants in the family Apocynaceae such as Tabernanthe iboga, Voacanga africana, and Tabernaemontana undulata. It is a psychedelic with dissociative properties.

<span class="mw-page-title-main">18-Methoxycoronaridine</span> Chemical compound

18-Methoxycoronaridine, also known as zolunicant, is a derivative of ibogaine invented in 1996 by the research team around the pharmacologist Stanley D. Glick from the Albany Medical College and the chemists Upul K. Bandarage and Martin E. Kuehne from the University of Vermont. In animal studies it has proved to be effective at reducing self-administration of morphine, cocaine, methamphetamine, nicotine and sucrose. It has also been shown to produce anorectic effects in obese rats, most likely due to the same actions on the reward system which underlie its anti-addictive effects against drug addiction.

<span class="mw-page-title-main">Voacangine</span> Chemical compound

Voacangine is an alkaloid found predominantly in the root bark of the Voacanga africana tree, as well as in other plants such as Tabernanthe iboga, Tabernaemontana africana, Trachelospermum jasminoides, Tabernaemontana divaricata and Ervatamia yunnanensis. It is an iboga alkaloid which commonly serves as a precursor for the semi-synthesis of ibogaine. It has been demonstrated in animals to have similar anti-addictive properties to ibogaine itself. It also potentiates the effects of barbiturates. Under UV-A and UV-B light its crystals fluoresce blue-green, and it is soluble in ethanol.

<span class="mw-page-title-main">Indole alkaloid</span> Class of alkaloids

Indole alkaloids are a class of alkaloids containing a structural moiety of indole; many indole alkaloids also include isoprene groups and are thus called terpene indole or secologanin tryptamine alkaloids. Containing more than 4100 known different compounds, it is one of the largest classes of alkaloids. Many of them possess significant physiological activity and some of them are used in medicine. The amino acid tryptophan is the biochemical precursor of indole alkaloids.

<span class="mw-page-title-main">Desformylflustrabromine</span> Chemical compound

Desformylflustrabromine (dFBr) is a monomethyltryptamine derivative which was first isolated as a secondary metabolite of the marine bryozoan Flustra foliacea.

<span class="mw-page-title-main">Noribogaine</span> Principal psychoactive metabolite of the oneirogen ibogaine

Noribogaine, or 12-hydroxyibogamine, is the principal psychoactive metabolite of the oneirogen ibogaine. It is thought to be involved in the antiaddictive effects of ibogaine-containing plant extracts, such as Tabernanthe iboga.

The alpha-3 beta-4 nicotinic receptor, also known as the α3β4 receptor and the ganglion-type nicotinic receptor, is a type of nicotinic acetylcholine receptor, consisting of α3 and β4 subunits. It is located in the autonomic ganglia and adrenal medulla, where activation yields post- and/or presynaptic excitation, mainly by increased Na+ and K+ permeability.

<span class="mw-page-title-main">Ibogamine</span> Anti-convulsant, anti-addictive CNS stimulant alkaloid

Ibogamine is an anti-convulsant, anti-addictive, CNS stimulant alkaloid found in Tabernanthe iboga and Crepe Jasmine. Basic research related to how addiction affects the brain has used this chemical.

<span class="mw-page-title-main">Tabernanthine</span> Chemical compound

Tabernanthine is an alkaloid found in Tabernanthe iboga.

<span class="mw-page-title-main">2-Methoxyethyl-18-methoxycoronaridinate</span> Chemical compound

(–)-2-Methoxyethyl-18-methoxycoronaridinate (ME-18-MC) is a second generation synthetic derivative of ibogaine developed by the research team led by the pharmacologist Stanley D. Glick from the Albany Medical College and the chemist Martin E. Kuehne from the University of Vermont. In animal studies it has shown similar efficacy to the related compound 18-methoxycoronaridine (18-MC) at reducing self-administration of morphine and methamphetamine but with higher potency by weight, showing anti-addictive effects at the equivalent of half the minimum effective dose of 18-MC. Similarly to 18-MC itself, ME-18-MC acts primarily as a selective α3β4 nicotinic acetylcholine antagonist, although it has a slightly stronger effect than 18-MC as an NMDA antagonist, and its effects on opioid receptors are weaker than those of 18-MC at all except the kappa opioid receptor, at which it has slightly higher affinity than 18-MC.

<span class="mw-page-title-main">18-Methylaminocoronaridine</span> Chemical compound

(–)-18-Methylaminocoronaridine (18-MAC) is a second generation synthetic derivative of ibogaine developed by the research team led by the pharmacologist Stanley D. Glick from the Albany Medical College and the chemist Martin E. Kuehne from the University of Vermont.

<span class="mw-page-title-main">Voacamine</span> Chemical compound

Voacamine, also known under the older names voacanginine and vocamine, is a naturally occurring dimeric indole alkaloid of the secologanin type, found in a number of plants, including Voacanga africana and Tabernaemontana divaricata. It is approved for use as an antimalarial drug in several African countries. Voacamine exhibits cannabinoid CB1 receptor antagonistic activity.

<i>Tabernaemontana divaricata</i> Species of plant

Tabernaemontana divaricata, commonly called pinwheel flower, crape jasmine, East India rosebay, and Nero's crown, is an evergreen shrub or small tree native to South Asia, Southeast Asia and China. In zones where it is not hardy it is grown as a house/glasshouse plant for its attractive flowers and foliage. The stem exudes a milky latex when broken, whence comes the name milk flower

<span class="mw-page-title-main">Catharanthine</span> Chemical compound

Catharanthine is a terpene indole alkaloid produced by the medicinal plant Catharanthus roseus and Tabernaemontana divaricata. Catharanthine is derived from strictosidine, but the exact mechanism by which this happens is currently unknown. Catharanthine is one of the two precursors that form vinblastine, the other being vindoline.

<span class="mw-page-title-main">Stemmadenine</span> Chemical compound

Stemmadenine is a terpene indole alkaloid. Stemmadenine is believed to be formed from preakuammicine by a carbon-carbon bond cleavage. Cleavage of a second carbon-carbon bond is thought to form dehydrosecodine. The enzymes forming stemmadenine and using it as a substrate remain unknown to date. It is thought to be intermediate compound in many different biosynthetic pathways such as in Aspidosperma species. Many alkaloids are proposed to be produced through intermediate stemmadenine. Some of them are:

<span class="mw-page-title-main">Dehydronorketamine</span> Chemical compound

Dehydronorketamine (DHNK), or 5,6-dehydronorketamine, is a minor metabolite of ketamine which is formed by dehydrogenation of its metabolite norketamine. Though originally considered to be inactive, DHNK has been found to act as a potent and selective negative allosteric modulator of the α7-nicotinic acetylcholine receptor (IC50 = 55 nM). For this reason, similarly to hydroxynorketamine (HNK), it has been hypothesized that DHNK may have the capacity to produce rapid antidepressant effects. However, unlike ketamine, norketamine, and HNK, DHNK has been found to be inactive in the forced swim test (FST) in mice at doses up to 50 mg/kg. DHNK is inactive at the α3β4-nicotinic acetylcholine receptor (IC50 > 100 μM) and is only very weakly active at the NMDA receptor (Ki = 38.95 μM for (S)-(+)-DHNK). It can be detected 7–10 days after a modest dose of ketamine, and because of this, is useful in drug detection assays.

Iboga-type alkaloids are a set of monoterpene indole alkaloids comprising naturally occurring compounds found in Tabernanthe and Tabernaemontana, as well as synthetic structural analogs. Naturally occurring iboga-type alkaloids include ibogamine, ibogaine, tabernanthine, and other substituted ibogamines (see below). Many iboga-type alkaloids display biological activities such as cardiac toxicity and psychoactive effects, and some have been studied as potential treatments for drug addiction.

Peripherally selective drugs have their primary mechanism of action outside of the central nervous system (CNS), usually because they are excluded from the CNS by the blood–brain barrier. By being excluded from the CNS, drugs may act on the rest of the body without producing side-effects related to their effects on the brain or spinal cord. For example, most opioids cause sedation when given at a sufficiently high dose, but peripherally selective opioids can act on the rest of the body without entering the brain and are less likely to cause sedation. These peripherally selective opioids can be used as antidiarrheals, for instance loperamide (Imodium).

<span class="mw-page-title-main">Ibogaline</span> Alkaloid found in Tabernanthe iboga

Ibogaline is an alkaloid found in Tabernanthe iboga along with the related chemical compounds ibogaine, ibogamine, and other minor alkaloids. It is a relatively smaller component of Tabernanthe iboga root bark total alkaloids (TA) content. It is also present in Tabernaemontana species such as Tabernaemontana australis which shares similar ibogan-biosynthetic pathways. The percentage of ibogaline in T. iboga root bark is up to 15% TA with ibogaine constituting 80% of the alkaloids and ibogamine up to 5%.

<span class="mw-page-title-main">Threohydrobupropion</span> Type of substituted amphetamine derivative

Threohydrobupropion is a substituted amphetamine derivative—specifically a β-hydroxyamphetamine—and a major active metabolite of the antidepressant drug bupropion (Wellbutrin). Bupropion is a norepinephrine–dopamine reuptake inhibitor and nicotinic acetylcholine receptor negative allosteric modulator, with its metabolites contributing substantially to its activities. Threohydrobupropion exists as two isomers, (1R,2R)-threohydrobupropion and (1S,2S)-threohydrobupropion. Other metabolites of bupropion include hydroxybupropion and erythrohydrobupropion.

References

  1. Delorenzi JC, Freire-de-Lima L, Gattass CR, de Andrade Costa D, He L, Kuehne ME, Saraiva EM (July 2002). "In vitro activities of iboga alkaloid congeners coronaridine and 18-methoxycoronaridine against Leishmania amazonensis". Antimicrobial Agents and Chemotherapy. 46 (7): 2111–2115. doi:10.1128/aac.46.7.2111-2115.2002. PMC   127312 . PMID   12069962.
  2. Spinella M (2001). The Psychopharmacology of Herbal Medicine: Plant Drugs that Alter Mind, Brain, and Behavior. The MIT Press; Illustrated edition. ISBN   978-0262692656.
  3. Perera P, Kanjanapothy D, Sandberg F, Verpoorte R (May 1985). "Muscle relaxant activity and hypotensive activity of some Tabernaemontana alkaloids". Journal of Ethnopharmacology. 13 (2): 165–173. doi:10.1016/0378-8741(85)90004-2. PMID   4021514.
  4. 1 2 Arias HR, Tae HS, Micheli L, Yousuf A, Ghelardini C, Adams DJ, Di Cesare Mannelli L (September 2020). "Coronaridine congeners decrease neuropathic pain in mice and inhibit α9α10 nicotinic acetylcholine receptors and CaV2.2 channels". Neuropharmacology . 175: 108194. doi:10.1016/j.neuropharm.2020.108194. hdl: 2158/1213504 . PMID   32540451. S2CID   219705597.
  5. Arias HR, Targowska-Duda KM, Feuerbach D, Jozwiak K (August 2015). "Coronaridine congeners inhibit human α3β4 nicotinic acetylcholine receptors by interacting with luminal and non-luminal sites". The International Journal of Biochemistry & Cell Biology . 65: 81–90. doi: 10.1016/j.biocel.2015.05.015 . PMID   26022277.
  6. Arias HR, Lykhmus O, Uspenska K, Skok M (March 2018). "Coronaridine congeners modulate mitochondrial α3β4* nicotinic acetylcholine receptors with different potency and through distinct intra-mitochondrial pathways". Neurochemistry International . 114: 26–32. doi:10.1016/j.neuint.2017.12.008. PMID   29277577. S2CID   3675707.
  7. Arias HR, Do Rego JL, Do Rego JC, Chen Z, Anouar Y, Scholze P, Gonzales EB, Huang R, Chagraoui A (July 2020). "Coronaridine congeners potentiate GABAA receptors and induce sedative activity in mice in a benzodiazepine-insensitive manner" (PDF). Progress in Neuro-psychopharmacology & Biological Psychiatry . 101: 109930. doi:10.1016/j.pnpbp.2020.109930. PMID   32194202. S2CID   212734631.
  8. 1 2 Wiart C (16 December 2013). Lead Compounds from Medicinal Plants for the Treatment of Neurodegenerative Diseases. Academic Press. pp. 67–69, 73. ISBN   978-0-12-398383-1.
  9. 1 2 Polya G (15 May 2003). Biochemical Targets of Plant Bioactive Compounds: A Pharmacological Reference Guide to Sites of Action and Biological Effects. CRC Press. pp. 203–. ISBN   978-0-203-01371-7.
  10. 1 2 Popik P, Skolnick P (1999). "Pharmacology of Ibogaine and Ibogaine-Related Alkaloids". In Cordell GA (ed.). The Alkaloids. Chemistry and Biology. Vol. 52. San Diego: Academic Press. pp. 197–232 (222). ISBN   978-0-08-086576-8.
  11. "(−)-Coronaridine". ChEBI. European Bioinformatics Institute. CHEBI:3887.
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