Total syntheses of racemic albifloranine and its anti-addictive congeners, including 18-methoxycoronaridine

Modular assembly of indole alkaloids enabled by multicomponent reaction

Indole alkaloids are one of the largest alkaloid classes, proving valuable structural moiety in pharmaceuticals. Although methods for the synthesis of indole alkaloids are constantly explored, the direct single-step synthesis of these chemical entities with broad structural diversity remains a formidable challenge. Herein, we report a modular assembly of tetrahydrocarboline type of indole alkaloids from simple building blocks in a single step while showing broad compatibility with medicinally relevant functionality. In this protocol, the 2-alkylated or 3-alkylated indoles, formaldehyde, and amine hydrochlorides could undergo a one-pot reaction to deliver γ-tetrahydrocarbolines or β-tetrahydrocarbolines directly. A wide scope of these readily available starting materials is applicable in this process, and numerous structural divergent tetrahydrocarbolines could be achieved rapidly. The control reaction and deuterium-labelling reaction are conducted to probe the mechanism. And mechanistically, this multicomponent reaction relies on a multiple alkylamination cascade wherein an unusual C(sp3)-C(sp3) connection was involved in this process. This method could render rapid access to pharmaceutically interesting compounds, greatly enlarge the indole alkaloid library and accelerate the lead compound optimization thus facilitating drug discovery.

What We Have Gained from Ibogaine: α3β4 Nicotinic Acetylcholine Receptor Inhibitors as Treatments for Substance Use Disorders

For decades, ibogaine─the main psychoactive alkaloid found in Tabernanthe iboga─has been investigated as a possible treatment for substance use disorders (SUDs) due to its purported ability to interrupt the addictive properties of multiple drugs of abuse. Of the numerous pharmacological actions of ibogaine and its derivatives, the inhibition of α3β4 nicotinic acetylcholine receptors (nAChRs), represents a probable mechanism of action for their apparent anti-addictive activity. In this Perspective, we examine several classes of compounds that have been discovered and developed to target α3β4 nAChRs. Specifically, by focusing on compounds that have proven efficacious in pre-clinical models of drug abuse and have been evaluated clinically, we highlight the promising potential of the α3β4 nAChRs as viable targets to treat a wide array of SUDs. Additionally, we discuss the challenges faced by the existing classes of α3β4 nAChR ligands that must be overcome to develop them into therapeutic treatments.

The iboga enigma: the chemistry and neuropharmacology of iboga alkaloids and related analogs

Covering: 2000 up to 2020 Few classes of natural products have inspired as many chemists and biologists as have the iboga alkaloids. This family of monoterpenoid indole alkaloids includes the anti-addictive compound ibogaine as well as catharanthine, a precursor to the chemotherapeutic vinblastine. Despite being known for over 120 years, these small molecules continue to challenge our assumptions about biosynthetic pathways, catalyze our creativity for constructing complex architectures, and embolden new approaches for treating mental illness. This review will cover recent advances in both the biosynthesis and chemical synthesis of iboga alkaloids as well as their use as next-generation neurotherapeutics. Whenever appropriate, we provide historical context for the discoveries of the past decade and indicate areas that have yet to be resolved. While significant progress regarding their chemistry and pharmacology has been made since the 1960s, it is clear that the iboga alkaloids will continue to stoke scientific innovation for years to come.

A non-hallucinogenic psychedelic analogue with therapeutic potential

The psychedelic alkaloid ibogaine has anti-addictive properties in both humans and animals.¹ Unlike most substance use disorder (SUD) medications, anecdotal reports suggest that ibogaine possesses the potential to treat patients addicted to a variety of substances including opiates, alcohol, and psychostimulants. Like other psychedelic compounds, its therapeutic effects are long-lasting,² which has been attributed to its ability to modify addiction-related neural circuitry through activation of neurotrophic factor signaling.^3,4 However, several safety concerns have hindered the clinical development of ibogaine including its toxicity, hallucinogenic potential, and proclivity for inducing cardiac arrhythmias. Here, we apply the principles of function-oriented synthesis (FOS) to identify the key structural elements of its potential therapeutic pharmacophore, enabling us to engineer tabernanthalog (TBG)—a water soluble, non-hallucinogenic, non-toxic analog of ibogaine that can be prepared in a single step. TBG promoted structural neural plasticity, reduced alcohol- and heroin-seeking behavior, and produced antidepressant-like effects in rodents. This work demonstrates that through careful chemical design, it is possible to modify a psychedelic compound to produce a safer, non-hallucinogenic variant with therapeutic potential.

DARK Classics in Chemical Neuroscience: Ibogaine

The West African iboga plant has been used for centuries by the Bwiti and Mbiri tribes to induce hallucinations during religious ceremonies. Ibogaine, the principal alkaloid responsible for iboga's psychedelic properties, was isolated and sold as an antidepressant in France for decades before its adverse effects precipitated its removal from the market. An ibogaine resurgence in the 1960s was driven by U.S. heroin addicts who claimed that ibogaine cured their opiate addictions. Behavioral pharmacologic studies in animal models provided evidence that ibogaine could blunt self-administration of not only opiates but cocaine, amphetamines, and nicotine. Ibogaine displays moderate-to-weak affinities for a wide spectrum of receptor and transporter proteins; recent work suggests that its actions at nicotinic acetylcholine receptor subtypes may underlie its reputed antiopiate effects. At micromolar levels, ibogaine is neurotoxic and cardiotoxic and has been linked to several deaths by cardiac arrest. Structure-activity studies led to the isolation of the ibogaine analog 18-methoxycoronaridine (18-MC), an α3β4 nicotinic receptor modulator that retains ibogaine's anticraving properties with few or no adverse effects. Clinical trials of 18-MC treatment of nicotine addiction are pending. Ibogaine analogs may also hold promise for treating anxiety and depression via the "psychedelic-assisted therapy" approach that employs hallucinogens including psilocybin and methylenedioxymethamphetamine ("ecstasy").

Acute oral 18-methoxycoronaridine (18-MC) decreases both alcohol intake and IV nicotine self-administration in rats

The ibogaine derivative 18-methoxycoronaridine (18-MC) has been found to decrease self-administration of morphine, nicotine and alcohol in rats after systemic injection. However oral dosing is the preferred route clinically. The current study evaluated the effect of oral 18-MC dosing in rats on alcohol and nicotine self-administration. For the nicotine study, young adult female Sprague-Dawley rats were fitted with IV jugular infusion catheters and trained for nicotine self-administration in 45min. sessions. At weekly intervals they were administered by oral gavage doses of 18-MC (0, 10, 20 and 40mg/kg) following a repeated measures counterbalanced design twice. Acute oral 18-MC, at the 40mg/kg dosage, significantly reduced nicotine self-administration. There was a differential effect of 18-MC with rats above or below the median level of nicotine self-administration during the pretreatment baseline performance. Rats with lower baseline performance showed a significant reduction in nicotine self-administration with the 40mg/kg dosage, while those in the higher baseline group did not show a significant effect of 18-MC. In alcohol studies, the effects of the same doses of 18-MC were tested in both male and female alcohol preferring (P) rats that had free access to water and alcohol (10% v/v) 6h/day. The results show that 18-MC dose-dependently reduced alcohol intake in both male and female rats. All doses caused significant reductions in alcohol self-administration. These data reinforce previous findings that 18-MC is significantly effective in reducing alcohol intake and nicotine self-administration. The finding that 18-MC is also effective orally makes it advantageous for further development as a possible new therapy for treating alcoholism as well as smoking addiction.

Synthesis and some reactions of functionalized 11,12-dihydro-5H-dibenzo[b,g]azonines

Dihydro-5H-dibenzo[b,g]azonine-6,13-dione (2) has been used as a precursor in the synthesis of the indolo[2,3-e]dibenzo[b,g]azonine and tribenzo[b,g,j][1,6]diazacyclododecine ring systems 6 and 7 respectively via a Fischer indolization/periodate oxidation sequence. Fischer indolization of the (1,4-phenylenedihydrazono) derivative 8 gave the polycyclic system 9. The Schmidt reaction of 2 led to the formation of the benzimidazo[1,2-b] [2]benzazepine ring system 11. The Mannich reaction of 2 led to the spirocyclic system 15. The reactions of 2 with aldimines and aromatic aldehydes were also investigated.

rac-18-Methoxycoronaridine hydrochloride

In the crystal structure of the racemic title compound, C₂₂H₂₉N₂O₃⁺·Cl⁻, both NH groups form N—H⋯Cl hydrogen bonds with the chloride counter-ion, forming translational chains along the a axis.

Collective synthesis of natural products by means of organocascade catalysis

Organic chemists are now able to synthesize small quantities of almost any known natural product, given sufficient time, resources and effort. However, translation of the academic successes in total synthesis to the large-scale construction of complex natural products and the development of large collections of biologically relevant molecules present significant challenges to synthetic chemists. Here we show that the application of two nature-inspired techniques, namely organocascade catalysis and collective natural product synthesis, can facilitate the preparation of useful quantities of a range of structurally diverse natural products from a common molecular scaffold. The power of this concept has been demonstrated through the expedient, asymmetric total syntheses of six well-known alkaloid natural products: strychnine, aspidospermidine, vincadifformine, akuammicine, kopsanone and kopsinine.

Synthesis and biological evaluation of 18-methoxycoronaridine congeners. Potential antiaddiction agents

Variation of the methoxycarbonyl and C-18 substituents of the antiaddictive compound 18-methoxycoronaridine, and contraction of its isoquinuclidine ring segment, provided 15 congeners for SAR evaluation at opioid and alpha3beta4 nicotinic acetylcholine receptors. The opioid activities were relatively low, and the alpha3beta4 nicotinic acetylcholine receptor activities were found to correlate with in vivo antiaddictive activities.

In vitro activities of iboga alkaloid congeners coronaridine and 18-methoxycoronaridine against Leishmania amazonensis

In previous studies, we demonstrated the leishmanicide effect of coronaridine, a natural indole alkaloid isolated from stem bark of Peschiera australis (Delorenzi et al., Antimicrob. Agents Chemother. 45:1349-1354, 2001). In this study we show the leishmanicidal effect of the synthetic coronaridine and its racemic 18-methoxylated analog, 18-methoxycoronaridine. Both alkaloids revealed a potent leishmanicide effect against Leishmania amazonensis, a causative agent of cutaneous and diffuse cutaneous leishmaniasis in the New World. Despite their potent leishmanicide effect, both alkaloids were neither toxic to murine macrophages nor did they modulate their oxidative or cytokine production responses.

Synthesis of enantiomerically pure (+)- and (-)-18-methoxycoronaridine hydrochloride and their preliminary assessment as anti-addictive agents

Chemical resolution of racemic 18-methoxycoronaridine (18-MC) was achieved by the formation of its diastereomeric sulfonamides with either (R)-(-)- or (S)-(+)-camphorsulfonyl chloride. Preliminary assessment of (+)-, (-)-, and (+/-)-18-MC x HCl showed similar effects on morphine self-administration in a rat model, and similar affinities at the kappa opioid receptors.