Indole alkaloid

and one of the founders of alkaloid chemistry The uses of some indole alkaloids has been known for ages: The Aztecs have used psilocybin mushrooms in religious rituals for thousands of years. Extracts of the flowering plant Rauvolfia serpentina which contain reserpine were a common medicine in India around 1000 BC. Various African tribes used the ibogaine-rich roots of the perennial rainforest shrub Iboga as a traditional medicine. An infusion of Calabar bean seed pods was given to people accused of crime in Nigeria: vomiting was regarded as a sign of innocence, otherwise, the person was killed via the action of physostigmine, which is present in the plant and causes full body paralysis. Consumption of rye and related cereals contaminated with the fungus Claviceps purpurea causes ergotism in humans and other mammals. The relationship between ergot and ergotism was established only in 1717, and the alkaloid ergotamine, one of the main active ingredients of ergot, was isolated in 1918. The first indole alkaloid, strychnine, was isolated by Pierre Joseph Pelletier and Joseph Bienaimé Caventou in 1818 from the plants of the genus Strychnos. The correct structural formula of strychnine was determined only in 1947, although the presence of the indole nucleus in the structure of strychnine was established somewhat earlier. Indole itself was first obtained by Adolf von Baeyer in 1866 while decomposing Indigo. ==Classification==

Indole alkaloids are distinguished depending on their biosynthesis. The two types of indole alkaloids are isoprenoids and non-isoprenoids. The latter include terpenoid structural elements, synthesized by living organisms from dimethylallyl pyrophosphate (DMAPP) and/or isopentenyl pyrophosphate (IPP): • Non-isoprenoid: • Simple derivatives of indole • Simple derivatives of β-carboline • Pyrroloindole alkaloids • Indole-3-carbinol • Indole-3-acetic acid • Tryptamines • Carbazoles • Isoprenoid: • hemiterpenoids: ergot alkaloids • monoterpenoids. • Strictosidine • Catharanthine • Yohimbine • Vinca • Strychnine • Ellipticine There are also purely structural classifications based on the presence of carbazole, β-carboline or other units in the carbon skeleton of the alkaloid molecule. Some 200 dimeric indole alkaloids are known with two indole groups. ==Non-isoprenoid indole alkaloids==

The number of known non-isoprenoid indole alkaloids is small compared to the number of indole alkaloids. Although their assignment to the alkaloid is not universally accepted, they are both found in plants and animals. The tryptamine skeleton is part of the vast majority of indole alkaloids. For example, N,N-dimethyltryptamine (DMT), psilocin and its phosphorylated psilocybin are the simplest derivatives of tryptamine. Camalexin is a simple indole alkaloid produced by the plant Arabidopsis thaliana, often used as a model for plant biology. Simple derivatives of β-carboline The prevalence of β-carboline alkaloids is associated with the ease of forming the β-carboline core from tryptamine in the intramolecular Mannich reaction. Simple (non-isoprenoid) β-carboline derivatives include harmine, harmaline, harmane and a slightly more complex structure of canthinone. Harmaline was first isolated in 1838 by Göbel and harmine in 1848 by Fritzche. Pyrolo-indole alkaloids Pyrolo-indole alkaloids form a relatively small group of tryptamine derivatives. They are produced by methylation of indole nucleus at position 3 and the subsequent nucleophilic addition at the carbon atom in positions 2 with the closure of the ethylamino group into a ring. A typical representative of this group is physostigmine, which was isolated by Jobst and Hesse in 1864. ==Isoprenoid indole alkaloids==

– the tryptophan fragment is colored in yellow and the isoprenoid part from DMAPP is blue Isoprenoid indole alkaloids include residues of tryptophan or tryptamine and isoprenoid building blocks derived from the dimethylallyl pyrophosphate and isopentenyl pyrophosphate. • Water-soluble aminoalcohol derivatives, such as ergometrine and its isomer ergometrinine • Water-insoluble polypeptide derivatives: • Ergotamine group, including ergotamine, ergosine and their isomers • Ergoxine groups, including ergostine, ergoptine, ergoline and their isomers • Ergotoxine group, including ergocristine, α-ergocryptine, β-ergocryptine, ergocornine and their isomers. Ergotinine, discovered in 1875, and ergotoxine (1906) were subsequently proven to be a mixture of several alkaloids. In pure form, the first ergot alkaloids, ergotamine and its isomer ergotaminine were isolated by Arthur Stoll in 1918. Some representative monoterpenoid indole alkaloids: There is also a small group of alkaloids present in the plant Aristotelia – about 30 compounds, the most important of which is peduncularine – which contain a monoterpenoid C10 part originating not from secologanin. Bisindole alkaloids Dimers of strictosidine derivatives, loosely called bisindoles but more complicated than that. More than 200 of dimeric indole alkaloids are known. They are produced in living organisms through dimerization of monomeric indole bases, in the following reactions: • Mannich reaction (voacamine) • Michael reaction (villalstonine) • Condensation of aldehydes with amines (toxiferine, calebassine) • Oxidative coupling of tryptamines (calicantine); • Splitting of the functional group of one of the monomers (vinblastine, vincristine). Apart from bisindole alkaloids, dimeric alkaloids exist which are formed via dimerization of the indole monomer with another type of alkaloid. An example is tubulosine consisting of indole and isoquinoline fragments. File:Voacamine chemical structure.png|Voacamine File:Villalstonine.svg|Villalstonine File:Toxiferine I.png|Toxiferine File:Vinblastine.svg|Vinblastine ==Distribution in nature==

The plants that are rich in non-isoprenoid indole alkaloids include Syrian rue (Peganum harmala), which contains harmane, harmine and harmaline, and Calabar bean (Physostigma venenosum) containing physostigmine. Some members of the family Convolvulaceae, in particular Ipomoea violacea and Turbina corymbosa, contain ergolines and lysergamides. Despite the considerable structural diversity, most of monoterpenoid indole alkaloids is localized in three families of dicotyledon plants: Apocynaceae (genera Alstonia, Aspidosperma, Rauvolfia and Catharanthus), Rubiaceae (Corynanthe) and Loganiaceae (Strychnos). Indole alkaloids are also present in fungi. For example, Psilocybe stuntzii contains derivatives of tryptamine and Claviceps purpurea contains derivatives of lysergic acid. Serotonin, which is an important neurotransmitter in mammals, can also be attributed to simple indole alkaloids. File:Peganum harmala1.jpg|Peganum harmala contains monoamine oxidase-inhibiting β-carboline alkaloids File:Physostigma venenosum - Köhler–s Medizinal-Pflanzen-237.jpg|Physostigma venenosum "Calabar bean", source of physostigmine (coloured plate from Köhler's Medicinal Plants) File:Urbana Illinois park 20070929 img 2141.jpg|Ipomoea violacea contains lysergic acid. File:Strychnos toxifera - Köhler–s Medizinal-Pflanzen-267.jpg|Strychnos toxifera, source of the neurotoxic alkaloid toxiferine (coloured plate from Köhler's Medicinal Plants) File:Strychnos nux-vomica - Köhler–s Medizinal-Pflanzen-266.jpg|Strychnos nux-vomica, principal source of the convulsant alkaloid strychnine (coloured plate from Köhler's Medicinal Plants) File:Tabernanthe iboga MS 4098.jpg|Tabernanthe iboga, principal source of the entheogen Ibogaine File:Rauwolfia serpentina(Flower).jpg|Rauvolfia serpentina contains reserpine. File:Starr 061223-2741 Catharanthus roseus.jpg|Catharanthus roseus contains monoterpenoid indole alkaloids such as vincristine File:Crape Jasmine.jpg|Tabernaemontana divaricata contains indole alkaloids including catharanthine, conophylline, ibogamine, tabersonine and voacristine File:Pcubmazatapec.jpg |Psilocybe cubensis contains psilocybin and psilocin File:Claviceps purpurea.JPG|Ergot contains ergotamine. File:2009-03-13Bufo alvarius071.jpg|The Colorado River toad (Bufo alvarius) secretes bufotenin and 5-MeO-DMT from specialized parotoid glands. ==Biosynthesis==

Biogenetic precursor of all indole alkaloids is the amino acid tryptophan. For most of them, the first synthesis step is decarboxylation of tryptophan to form tryptamine. Dimethyltryptamine (DMT) is formed from tryptamine by methylation with the participation of coenzyme of S-adenosyl methionine (SAM). Psilocin is produced by spontaneous dephosphorylation of psilocybin. In the biosynthesis of serotonin, the intermediate product is not tryptamine but 5-hydroxytryptophan, which is in turn decarboxylated to form 5-hydroxytryptamine (serotonin). Biosynthesis of ergot alkaloids begins with the alkylation of tryptophan by dimethylallyl pyrophosphate (DMAPP), where the carbon atom C(4) in the indole nucleus plays the role of the nucleophile. The resulting 4-dimethylallyl-L-tryptophan undergoes N-methylation. Further products of biosynthesis are chanoclavine-I and agroclavine – the latter is hydroxylated to elymoclavine, which in turn oxidizes into paspalic acid. In the process of allyl rearrangement, paspalic acid is converted to lysergic acid. Biosynthesis of monoterpenoid indole alkaloids begins with the Mannich reaction of tryptamine and secologanin; it yields strictosidine which is converted to 4,21-dehydrogeissoschizine. Then, the biosynthesis of most alkaloids containing the unperturbed monoterpenoid part (Corynanthe type) proceeds through cyclization with the formation of cathenamine and subsequent reduction to ajmalicine in the presence of nicotinamide adenine dinucleotide phosphate (NADPH). In the biosynthesis of other alkaloids, 4,21-dehydrogeissoschizine first converts into preakuammicine (an alkaloid of subtype strychnos, type Corynanthe) which gives rise to other alkaloids of subtype strychnos and of the types Iboga and Aspidosperma. Bisindole alkaloids vinblastine and vincristine are produced in the reaction involving catharanthine (alkaloid of type Iboga) and vindolin (type Aspidosperma). ==Physiological activity==

Indole alkaloids act on the central and peripheral nervous systems. Besides, bisindole alkaloids vinblastine and vincristine show antineoplastic effect. Because of structural similarities with serotonin, many tryptamines can interact with serotonin 5-HT receptors. The main effect of the serotonergic psychedelics such as LSD, DMT, and psilocybin is related to them being agonists of the 5-HT2A receptors. In contrast, gramine is an antagonist of the 5-HT2A receptor. Ergolines, such as lysergic acid, include structural elements of both tryptamine and phenylethylamine and thus act on the whole group of the 5-HT receptors, adrenoceptors (mostly of type α) and dopamine receptors (mostly type D2). So ergotamine is a partial agonist of α-adrenergic and 5-HT2 receptors, and thus narrows blood vessels and stimulates constriction of the uterus. Dihydroergotamine is more selective to α-adrenergic receptors and has a weaker effect on serotonin receptors. Ergometrine is an agonist of α-adrenergic, 5-HT2 and partly D2 receptors. Compared with other ergot alkaloids, ergometrine has a greater selectivity in stimulating the uterus. Some monoterpenoid indole alkaloids also interact with adrenoceptors. For example, ajmalicine is a selective antagonist of α1-adrenergic receptors and therefore has antihypertensive action. Yohimbine is more selective to α2 adrenoceptor; Some alkaloids affect the turnover of monoamines indirectly. So, harmine and harmaline are reversible selective inhibitors of monoamine oxidase-A. Reserpine reduces concentration of monoamines in presynaptic and synaptic neurons, thereby inducing antihypertensive and antipsychotic effects. and ibogaine – to NMDA-receptors. Physostigmine is a reversible acetylcholinesterase inhibitor. ==Applications==

Plants and fungi that contain indole alkaloids have a long history of use in traditional medicine. Rauvolfia serpentina, which contains reserpine as the active substance, was used for over 3000 years in India to treat snake bites and insanity. In medieval Europe, extracts of ergot were used in medical abortion. Later, the plants were joined by pure preparations of indole alkaloids. Reserpine was the second (after chlorpromazine) antipsychotic drug; however, it showed relatively weak action and strong side effects, and is not used for this purpose any longer. Instead, it is prescribed as an antihypertensive drug, often in combination with other substances. Other drugs that affect the cardiovascular system include ajmaline, which is a Class I antiarrhythmic agents, and ajmalicine, which is used in Europe as an antihypertensive drug. Ergot alkaloids ergometrine (ergobazin, ergonovine), ergotamine and their synthetic derivatives (methylergometrine) are applied against uterine bleeding, and bisindole alkaloids vinblastine and vincristine are antitumor agents. Animal studies have shown that ibogaine has a potential in treating heroin, cocaine, and alcohol addictions, which is associated with the ibogaine antagonism to NMDA-receptors. Medical use of ibogaine is hindered by its legal status, as it is banned in many countries as a powerful psychedelic drug with dangerous implications of overdose. However, illegal network in Europe and United States provide ibogaine for treating drug addiction. Since ancient times, plants containing indole alkaloids have been used as psychedelic drugs. The Aztecs used and the Mazatec people continue to use psilocybin mushrooms and the psychoactive seeds of morning glory species like Ipomoea tricolor. Amazonian tribes use the psychedelic infusion, ayahuasca, made from Psychotria viridis and Banisteriopsis caapi. Psychotria viridis contains the psychedelic drug DMT, while Banisteriopsis caapi contains harmala alkaloids, which act as monoamine oxidase inhibitors. It is believed that the main function of the harmala alkaloids in ayahuasca is to prevent the metabolization of DMT in the digestive tract and liver, so it can cross the blood–brain barrier, whereas the direct effect of harmala alkaloids on the central nervous system is minimal. The venom of the Colorado River toad, Bufo alvarius, may have used as a psychedelic drug, its active constituents being 5-MeO-DMT and bufotenin. One of the most common recreational psychedelic drugs, LSD, is a semi-synthetic ergoline (which contains the indole moiety). ==References==