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Acetogenin

Acetogenins are a class of secondary metabolites derived from the polyketide pathway, primarily found in plants of the Annonaceae family, such as species of Annona (e.g., custard apple, soursop).^[1] These waxy, lipophilic compounds typically consist of a linear C35 or C37 carbon chain featuring one to three tetrahydrofuran (THF) rings, multiple hydroxyl groups, and a terminal α,β-unsaturated γ-lactone ring, which contributes to their distinctive structure and bioactivity.^[2] First isolated in 1982 from Uvaria accuminata as uvaricin,^[3] over 500 acetogenins have since been identified, mainly from the roots, bark, leaves, seeds, and fruits of Annonaceous plants native to tropical regions of South America, Africa, and Southeast Asia.^[2] The most notable aspect of acetogenins is their potent cytotoxic and antitumor properties, making them promising candidates for anticancer therapy.^[4] They exert their effects primarily by inhibiting mitochondrial complex I (NADH:ubiquinone oxidoreductase) in the electron transport chain, disrupting ATP production and inducing energy depletion in cancer cells.^[4] This mechanism leads to apoptosis, cell cycle arrest (often in the G1 phase), and autophagy, with demonstrated activity against various cancer cell lines, including multidrug-resistant ones like MCF-7 (breast) and A-549 (lung), while showing potential selectivity over normal cells.^[4]^[2] Beyond anticancer effects, acetogenins exhibit a range of other biological activities, including anti-inflammatory, antimicrobial, antimalarial, pesticidal, and immunosuppressant properties, attributed to their ability to interfere with cellular energy metabolism and other pathways like glucose uptake inhibition.^[2] Despite their low natural yields (often 0.00019%–0.003% of plant dry weight), ongoing research explores synthetic derivatives and delivery systems, such as nanosuspensions, to enhance bioavailability and therapeutic potential.^[2] Traditional uses in folk medicine for treating inflammation and parasites underscore their historical significance in regions where Annonaceae plants are abundant.^[4]

Overview and Sources

Definition and History

Acetogenins, also known as annonaceous acetogenins, are a class of polyketide-derived natural products isolated exclusively from plants in the Annonaceae family. They are characterized by a linear backbone typically comprising 35 or 37 carbon atoms, derived from C32 or C34 long-chain fatty acids, with a terminal α,β-unsaturated γ-lactone ring and one to three embedded tetrahydrofuran (THF) rings, often flanked by hydroxyl groups.^[5] These compounds are waxy substances that exhibit potent bioactivity, particularly as inhibitors of mitochondrial complex I, which has driven extensive phytochemical research.^[2] The discovery of acetogenins traces back to 1982, when the first member of this class, uvaricin, was isolated from the roots of Uvaria accuminata (Annonaceae) by Jolad and colleagues at the University of Arizona. This isolation marked the beginning of systematic studies on these metabolites, spurred by uvaricin's demonstrated antitumor activity against P-388 leukemia cells in vivo.^[3] Early research was led by pioneering groups including those of J.L. McLaughlin at Purdue University (USA), A. Cavé at CNRS (France), and Y. Fujimoto at Tokyo University of Pharmacy and Life Sciences (Japan), who expanded isolations from various Annonaceae species. Key milestones included the identification of annonacin, the first mono-THF acetogenin, from the bark of Annona densicoma in 1987 by McCloud et al.,^[6] and bullatacin, a highly potent cytotoxic bis-THF acetogenin, from Annona bullata in 1989 by Hui et al., which exhibited exceptional activity against human solid tumor cell lines.^[7] Initial scientific interest in acetogenins was amplified by the long-standing traditional medicinal uses of Annonaceae plants in folk remedies across tropical regions, particularly in Africa, Asia, and Latin America. These plants, such as Annona muricata and Annona squamosa, have been employed by indigenous communities to treat parasitic infections, fever, pain, inflammation, and symptoms resembling cancer, including tumors and skin lesions, often through decoctions of leaves, bark, or fruit.^[8] This ethnopharmacological context provided the impetus for bioactivity-guided isolations in the 1980s, transforming anecdotal uses into a foundation for modern pharmacological investigations.

Natural Occurrence

Acetogenins, also known as annonaceous acetogenins, are exclusively found in plants of the Annonaceae family, a diverse group comprising approximately 110 genera and 2,500 species.^[9] These compounds have been isolated primarily from genera such as Annona, Rollinia, and Xylopia, with notable examples including Annona muricata (commonly known as graviola or soursop) and various Rollinia species.^[10] To date, more than 500 distinct acetogenins have been identified from over 50 species within this family, highlighting the chemical richness of these plants.^[11] Within Annonaceae plants, acetogenins are concentrated in various tissues, including leaves, seeds, bark, roots, and fruit, where they contribute to the plant's secondary metabolism.^[2] For instance, in Annona muricata, over 100 acetogenins have been documented across these parts, with particularly high yields from seeds and leaves.^[10] Geographically, Annonaceae species—and thus acetogenins—are most abundant in tropical and subtropical regions, with highest diversity in Central and South America (such as the inter-Andean valleys of Peru and Ecuador), Africa, and Southeast Asia.^[11] These plants thrive in lowland rainforests and similar habitats, reflecting the family's pantropical distribution.^[2] Ecologically, acetogenins are believed to serve as defense mechanisms in their host plants, deterring herbivores and pathogens through potent bioactivities.^[10] Their insecticidal and antimicrobial properties, such as the larvicidal action of compounds like bullatacin against mosquito larvae (with LC50 values as low as 0.1 mg/L), suggest a role in protecting Annonaceae species from pests and infections in their native environments.^[2] This defensive function aligns with the compounds' presence in exposed tissues like leaves and bark, aiding plant survival in biodiverse tropical ecosystems.^[11]

Chemical Characteristics

Molecular Structure

Annonaceous acetogenins are C35 or C37 natural products characterized by a linear aliphatic chain derived from C32 or C34 long-chain fatty acids combined with a propan-2-ol unit. At the terminus, they possess an α,β-unsaturated γ-lactone ring, which is often methylated and responsible for the compounds' stability and lipophilicity. The central region features one or more tetrahydrofuran (THF) rings, usually flanked by one or two hydroxyl groups that contribute to the molecule's polarity. The opposite end of the chain includes additional oxygenated substituents, such as hydroxyl, acetoxy, or ketone groups, which vary in position and number across different acetogenins.^[2]^[12]^[13] These compounds are classified based on the number and spatial arrangement of the THF rings in the core structure. Non-THF acetogenins lack rings and are linear, while mono-THF types contain a single THF ring. Bis-THF acetogenins are subdivided into adjacent (contiguous rings) and non-adjacent (separated by methylene groups) variants, and tri-THF acetogenins feature three THF rings. Some acetogenins incorporate tetrahydropyran (THP) rings or epoxide moieties instead of or alongside THF rings, adding to structural diversity. The stereochemistry at the THF ring junctions and chiral centers is highly specific; for instance, adjacent bis-THF acetogenins commonly exhibit a threo/trans/threo configuration across the rings, with additional erythro or threo assignments at flanking hydroxyl-bearing carbons. Side chain variations often include free hydroxyl groups at positions like C4, C15, or C24, acetoxy groups for esterification, or ketones that alter the chain's flexibility and hydrogen-bonding potential.^[2]^[14]^[12] Representative examples illustrate these structural motifs. Annonin, a mono-THF acetogenin, features a C35 chain with the THF ring spanning C15 to C20 in a threo-trans-threo stereochemistry (15R,16S,19S,20S configuration), hydroxyl groups at C4, C19, and C23, and the standard terminal γ-lactone at C1-C4. Bullatacin exemplifies an adjacent bis-THF acetogenin with a C37 chain, where the THF rings occupy C15-C24 in a threo-trans-threo-trans-threo arrangement (15R,16S,19S,20R,23R,24S), accompanied by hydroxyls at C4, C15, and C24. Rolliniastatin-1, another adjacent bis-THF acetogenin on a C37 framework, mirrors bullatacin's core with THF rings at C15-C24 and the same threo-trans-threo-trans-threo stereochemistry, including hydroxyl groups at C4, C15, and C24, highlighting the conserved architecture within this subclass.^[13]^[2]

Biosynthesis

Acetogenins are biosynthesized in plants of the Annonaceae family through a polyketide pathway that resembles fatty acid synthesis but incorporates specialized modifications. The process initiates with the condensation of multiple acetate units, derived from acetyl-CoA and malonyl-CoA, to assemble a long-chain polyketide backbone typically comprising 32–34 carbon atoms from fatty acid precursors, extended by a three-carbon unit to yield C35 or C37 structures. This chain undergoes subsequent cyclization events, including epoxidation of isolated double bonds followed by intramolecular ring opening, to form one or more tetrahydrofuran (THF) rings, and terminates with the creation of an α,β-unsaturated γ-lactone moiety via Claisen-type condensation.^[15]00917-5) Key enzymatic steps in this pathway involve polyketide synthase (PKS) complexes, which facilitate chain elongation by iteratively adding malonyl-CoA extender units to the growing polyketide chain. Post-elongation, reductions and dehydrations introduce sites of unsaturation, while stereospecific hydroxylations at specific positions contribute to the molecule's chirality and bioactivity. In Annonaceae species, these processes are mediated by fatty acid synthase-like PKS enzymes, with evidence from precursor isolation—such as diene and triene intermediates like muridienins—supporting the sequential formation of unsaturated units prior to ring closure. The THF rings and associated epoxides likely arise from hydroperoxide or epoxide intermediates, highlighting the role of oxidative enzymes in the biosynthetic cascade.^[15]00908-4) Genetic studies on acetogenin biosynthesis remain limited, with few characterized enzymes due to the complexity of the pathway. However, post-2020 genomic analyses of Annona species have provided insights into potential biosynthetic gene clusters. For instance, in Annona cherimola, a 97 kb cluster spanning nine genes (Ach20829–Ach20837) has been identified, encoding proteins with domains of 3-ketoacyl-CoA synthase and chalcone synthase-like type III PKS activities, which are implicated in very long-chain fatty acid synthesis and lactone ring formation essential for acetogenins. Similar clusters are suggested in other Annona genomes, such as A. muricata, underscoring the genetic basis for polyketide production in this family, though functional validation through gene expression or knockout studies is still emerging.^[16]^[17]

Isolation and Synthesis

Extraction and Isolation

Acetogenins are primarily extracted from the bark, leaves, seeds, and fruits of plants in the Annonaceae family, such as Annona muricata and Annona squamosa, using solvent-based methods that target their lipophilic nature. Conventional extraction techniques include maceration and Soxhlet extraction, where plant material is treated with organic solvents like ethanol, methanol, or chloroform at temperatures below 60°C to prevent degradation of these thermolabile compounds. Maceration with 95% ethanol has been used to isolate specific acetogenins like squamostanin-A and squamostanin-B from A. squamosa seeds.^[18] Greener alternatives have gained prominence to reduce solvent use and environmental impact, including ultrasound-assisted extraction (UAE), microwave-assisted extraction (MAE), and supercritical fluid extraction (SFE) with CO₂. Recent innovations like thermosonication-assisted extraction (TSAE), combining ultrasound and controlled heating, optimize conditions at 50°C, 100% amplitude, and 50 minutes to yield 3.6% total acetogenin content (35.89 mg/g) from A. muricata seeds—2.17-fold higher than conventional UAE.^[19] Isolation of pure acetogenins from crude extracts involves chromatographic techniques, often guided by bioassays to target bioactive fractions. Initial fractionation uses silica gel column chromatography, eluting with gradients of dichloromethane:ethanol or hexane:ethyl acetate to separate acetogenin-rich fractions based on polarity. Further purification employs high-performance liquid chromatography (HPLC) on reversed-phase C18 columns, enabling simultaneous isolation of multiple acetogenins, as in the separation of eight compounds from A. squamosa seeds.^[18] Liquid chromatography-mass spectrometry (LC-MS) integrates identification during isolation, confirming structures via mass spectra and improving efficiency in post-extraction analysis. Bioassay-guided fractionation, monitoring cytotoxicity or antimicrobial activity, directs the process to active compounds like pseudoannonacin.^[19] Challenges in extraction and isolation include low yields—typically less than 1% of plant dry weight due to acetogenins' low natural abundance—and co-elution from structural similarities among analogs. Thermal instability above 60°C further complicates heating-based methods, while scalability and solvent residue removal add practical hurdles. Recent efforts in optimization, such as the development of acetogenin-enriched nanosystems using aqueous extracts from Annona cherimola, have shown potential for improved recovery and application as of 2024.^[20]

Synthetic Approaches

The total synthesis of acetogenins has been a significant challenge in organic chemistry due to their complex structures featuring multiple tetrahydrofuran (THF) rings and stereocenters. The first reported total syntheses of naturally occurring acetogenins were achieved in 1993 for the mono-THF compounds solamin and reticulatacin, employing stereoselective olefin metathesis and aldol reactions to construct the core framework.^[21] Subsequent milestones included the 1997 synthesis of asimicin, a bis-THF acetogenin, using a bidirectional approach with Sharpless asymmetric epoxidation for THF ring formation.^[22] In 2000, the first total synthesis of annonacin, the prototypical mono-THF acetogenin, was completed via Sharpless asymmetric dihydroxylation followed by coupling of fragments with BF₃·Et₂O.^[22] Key synthetic routes have relied on stereoselective methods for THF ring construction. The Sharpless asymmetric epoxidation has been widely adopted to generate epoxy alcohols that cyclize into THF rings with high enantioselectivity, as demonstrated in the syntheses of tonkinecin (1999) and goniocin (1998), where it enabled control over adjacent stereocenters.^[22] Similarly, the Evans aldol reaction using chlorotitanium enolates has provided access to the bis-THF core, notably in the 2004 total synthesis of gigantecin, achieving the required threo/trans/threo configuration through diastereoselective additions.^[23] These methods have been pivotal in establishing the absolute configurations of natural acetogenins, often correcting prior misassignments through comparative NMR analysis.^[22] Modern strategies emphasize convergent syntheses to improve efficiency for bis-THF acetogenins. For instance, the 2006 synthesis of asimicin utilized an outside-in approach with cross-metathesis using Grubbs catalysts to couple THF fragments, yielding the C19-epimer in 12 steps with 5% overall yield. Progress on bullatacin analogs, such as cis-solamin (2006), incorporated olefin cross-metathesis for side-chain attachment, facilitating the preparation of libraries with varied substituents.^[24] Semi-synthetic modifications starting from muricatacin—a readily accessible mono-THF precursor—have enabled the elaboration of higher acetogenins like 4-deoxygigantecin (2007) through regioselective chain extensions and lactone adjustments, enhancing solubility and stability for biological evaluation. Challenges in acetogenin synthesis primarily stem from establishing the correct stereochemistry across 10–15 chiral centers while maintaining scalability. Early routes often suffered from low yields due to lengthy linear sequences, but recent innovations (2020–2025) focus on modular assemblies, such as the 2020 use of muricatacin in convergent cross-metathesis for non-adjacent bis-THF analogs, reducing steps to under 20 with improved stereocontrol via chiral auxiliaries. In 2023, the total syntheses of chatenaytrienins-1, -3, and -4 employed seven-step enantioselective routes featuring dihydroxylation and ring-closing metathesis, prioritizing scalability for potential drug development candidates. These advances address stability issues by incorporating bioisosteric modifications, such as fluorinated side chains, to mitigate hydrolysis of the labile γ-lactone.

Biological Activities

Cytotoxic and Anticancer Effects

Acetogenins exhibit potent cytotoxic effects against various cancer cell lines in vitro, often surpassing the potency of conventional chemotherapeutic agents. For instance, bullatacin demonstrates an IC50 value below 0.01 μg/mL in multidrug-resistant human mammary adenocarcinoma (MCF-7/Adr) cells, showing linear dose-response cytotoxicity down to 10^{-4} μg/mL, while exerting primarily cytostatic effects on sensitive MCF-7 cells at similar concentrations.^[25] Other acetogenins, such as squamocin-IV, achieve IC50 values as low as 0.049 μg/mL against human lung carcinoma (H460) cells.^[25] These compounds induce apoptosis in cancer cells through activation of caspases, including caspase-3, as observed with annonacin and squamocin in leukemia and hepatoma cell lines. In vivo studies further support the antitumor potential of acetogenins, demonstrating significant tumor growth inhibition in animal models. Bullatacin, a bis-tetrahydrofuran (bis-THF) acetogenin, reduced tumor growth by 65.8% in S180 sarcoma-bearing mice and 63.4% in HepS hepatoma models at doses of 15 μg/kg. Similarly, laherradurin achieved 64% inhibition in HeLa xenograft models in nude mice at 7.5 mg/kg/day. Acetogenins display selectivity for malignant cells over normal ones, attributed to the elevated mitochondrial activity in cancer cells, which enhances their uptake and efficacy, as evidenced in xenotransplant assays with reductions ranging from 50% to 80%.^[25] Clinical relevance of acetogenins stems from evaluations of Annona muricata (graviola) extracts, which are rich in these compounds. Over 100 acetogenins have been tested for anticancer activity, with bis-THF types, such as bullatacin and asiminocin, identified as the most potent subtypes. Early-phase clinical investigations in the 2010s and beyond include a completed study on graviola leaf effects in colorectal cancer patients (NCT02439580) and an initiated trial for advanced pancreatic and other adenocarcinomas using guanábana (graviola) leaves (NCT04773769), reflecting ongoing interest despite limited published efficacy data.^[26]^[27]

Antimicrobial and Other Activities

Acetogenins from Annonaceae plants demonstrate notable antimicrobial activity against both Gram-positive and Gram-negative bacteria, as well as fungi. For instance, extracts rich in acetogenins from Annona muricata leaves show minimum inhibitory concentrations (MICs) of 0.0313–0.0625 μg/mL against Staphylococcus aureus, while purified acetogenins exhibit MICs in the range of 3.12–6.25 μg/mL against various Gram-positive species, including methicillin-resistant strains.^[28]^[29] This activity is attributed to the disruption of microbial cell membranes, leading to increased permeability, leakage of cellular contents such as nucleotides, and subsequent cell death.^[28] Antifungal effects have been observed against species like Candida albicans, with inhibition zones up to 15.5 mm at concentrations of 0.8 mg/mL for isolated acetogenins from seeds.^[28] Beyond antimicrobial properties, acetogenins display antiparasitic effects against protozoan parasites such as Trypanosoma and Leishmania species. Purified acetogenins from Porcelia macrocarpa seeds exhibit IC₅₀ values of 0.4–3.6 μM against Trypanosoma cruzi trypomastigotes and amastigotes, outperforming some standard drugs in preliminary assays.^[30] Similarly, acetogenins from Annona senegalensis demonstrate activity against Leishmania donovani and Leishmania major, with extracts inhibiting parasite growth through mechanisms involving mitochondrial disruption.^[31] Insecticidal properties contribute to their role in plant defense, where acetogenins like asimicin from Asimina triloba inhibit insect respiration at complex I of the electron transport chain, showing potent toxicity against agricultural pests such as German cockroaches at low concentrations.^[32]^[33] Additionally, acetogenins possess potential anti-inflammatory effects. Recent research in the 2020s has highlighted further biological activities, including antiviral potential. In silico molecular docking studies of Annona muricata acetogenins, such as cis-annonacin, against the SARS-CoV-2 spike protein revealed strong binding affinities of up to -7.7 kcal/mol, suggesting interference with viral entry and surpassing reference inhibitors like dexamethasone.^[34] Preliminary models also indicate a duality in neuroprotective effects, where acetogenins exhibit antioxidant-mediated protection against cerebral ischemia in rat models by scavenging free radicals, yet display neurotoxicity through tau protein dysfunction and mitochondrial inhibition at higher exposures.^[35]^[36]

Mechanism of Action

Molecular Targets

Acetogenins exert their primary inhibitory effects on the NADH-ubiquinone oxidoreductase, known as Complex I, within the mitochondrial electron transport chain. This inhibition occurs through binding that blocks electron transfer from NADH to ubiquinone, disrupting ATP production in targeted cells.^[37] Specifically, photoaffinity analogues of acetogenins, such as asimicin, have been shown to crosslink to the ND2 subunit of Complex I, indicating this as a key binding site for the inhibitors.^[38] Cryo-electron microscopy structures (as of 2022) have revealed that acetogenins bind along the ubiquinone channel, confirming interactions with specific residues in ND1 and NDUFS2 subunits.^[37] The binding mechanism involves hydrophobic interactions primarily mediated by the tetrahydrofuran (THF) rings and the γ-lactone moiety of acetogenins, which anchor within the ubiquinone-binding channel at the interface of the enzyme's hydrophilic and transmembrane domains. For representative acetogenins like bullatacin and related compounds, this results in potent inhibition with IC₅₀ values typically ranging from 1 to 5 nM against Complex I activity.^[37]^[39] Beyond Complex I, acetogenins demonstrate potential inhibition of NADH oxidase enzymes located in the plasma membranes of certain tumor cells, such as those from HeLa and HL-60 lines, without affecting normal liver plasma membranes; this selective action correlates with their antitumor selectivity.^[40] Studies have shown evidence for acetogenins interfering with topoisomerase IIα in cancer cells, including downregulation of its expression in drug-resistant hepatocellular carcinoma lines, contributing to enhanced cytotoxicity.^[41]

Cellular and Physiological Impacts

Acetogenins exert profound effects at the cellular level primarily through disruption of mitochondrial function, leading to ATP depletion and an ensuing energy crisis in treated cells. By inhibiting NADH:ubiquinone oxidoreductase (Complex I) in the electron transport chain, these compounds reduce ATP synthesis, which impairs cellular energy homeostasis and triggers compensatory stress responses.^[25] This energy deficit is particularly detrimental in rapidly dividing cells, where metabolic demands are high, resulting in halted proliferation and metabolic collapse.^[42] At the cellular level, acetogenins induce programmed cell death pathways, including apoptosis, autophagy, and cell cycle arrest. Apoptosis is mediated by mitochondrial outer membrane permeabilization, which facilitates cytochrome c release into the cytosol, activating caspases 3 and 9 and downregulating anti-apoptotic proteins like Bcl-2 while upregulating pro-apoptotic Bax.^[43] Autophagy is also promoted, as seen with mimics like AA005, which activate AMP-activated protein kinase (AMPK) and inhibit mTOR complex 1, leading to autophagosome formation as a survival mechanism under energy stress before tipping toward cell death.^[25] Additionally, acetogenins cause cell cycle arrest predominantly at the G1/S phase transition, achieved through upregulation of cyclin-dependent kinase inhibitors like p21/WAF1 and downregulation of cyclin D1, preventing DNA replication in affected cells.^[1] Physiologically, acetogenins demonstrate antitumor effects in vivo, including reduced tumor vascularization through suppression of the hypoxia-inducible factor-1 (HIF-1)/vascular endothelial growth factor (VEGF) pathway, which limits nutrient supply to growing tumors. Acetogenins suppress the hypoxia-inducible factor-1 (HIF-1)/vascular endothelial growth factor (VEGF) pathway in vitro, potentially reducing tumor vascularization and limiting nutrient supply to growing tumors.^[44] Their toxicity profile shows selectivity for high-energy-demand cells, such as cancer cells and neurons, due to reliance on mitochondrial ATP production; for instance, annonacin exhibits potent cytotoxicity against multidrug-resistant tumor lines while inducing neuronal apoptosis in models of high metabolic activity.^[25] This selectivity arises from the compounds' targeted interference with mitochondrial respiration in cells with elevated Complex I activity.^[45] Dose-response relationships for acetogenins often exhibit biphasic patterns, where low concentrations (e.g., 0.1–1 μM) exert cytostatic effects via cell cycle arrest and autophagy induction, while higher doses (e.g., >5 μM) shift to overt cytotoxicity through apoptosis and necrosis.^[12] Sensitivity varies across species, with rodents showing higher tolerance (LD50 ~1.67 g/kg for Annona muricata extracts) compared to humans or certain invertebrates, attributed to differences in mitochondrial enzyme expression and metabolic rates.^[25]

Research and Toxicology

Historical and Recent Developments

The discovery of annonaceous acetogenins began in the early 1980s with the isolation of uvaricin, the first cytotoxic compound identified from the plant family Annonaceae in 1982, sparking intensive research into their potential as antitumor agents.^[46] Through the 1980s and 1990s, efforts focused primarily on isolation and structural elucidation, driven by their potent bioactivities; by 1999, a comprehensive review documented over 350 such compounds, with more than half isolated from species like Annona muricata.^[15] The 2000s saw continued emphasis on extraction from leaves, seeds, and roots, expanding the known library to hundreds of variants while highlighting their polyketide-derived structures.^[47] Breakthroughs in synthesis emerged around 2005, with reviews summarizing advances in total synthesis of complex acetogenins like bullatacin and squamocin, enabling the production of analogs for structure-activity studies and overcoming supply limitations from natural sources.^[48] These synthetic routes, often involving stereoselective tetrahydrofuran ring formation, laid the groundwork for modifying key moieties to enhance stability and activity.^[13] From 2010 to 2025, research has accelerated with the isolation of over 500 acetogenins total, including novel structures reported in recent years, such as three new cytotoxic annonaceous acetogenins from Annona squamosa seeds in 2024.^[49] Analog design has prioritized selectivity, exemplified by the 2015 development of AA005, a mimic that targets mitochondrial complex I in cancer cells while sparing normal tissues at low doses.^[50] Clinical exploration of graviola (Annona muricata) extracts, rich in acetogenins, includes a 2024 Phase I open-label trial assessing safety and tolerability in cancer patients, building on preclinical antitumor data but revealing sparse Phase II progress.^[51] Persistent research gaps include the scarcity of human trials, hampered by toxicity concerns like neurotoxicity observed in preclinical models, which has limited advancement beyond in vitro and animal studies.^[25] Ongoing genomic investigations, such as the 2024 sequencing of the cherimoya genome, have identified potential gene clusters for acetogenin biosynthesis, offering pathways to engineer safer variants through metabolic elucidation.^[52]

Toxicity and Safety Concerns

Acetogenins, particularly annonacin found in Annona muricata (graviola), have been implicated in neurotoxicity, especially through chronic consumption leading to atypical parkinsonism. Epidemiological studies in Guadeloupe during the 2000s and 2010s linked high intake of Annonaceae fruits to a high prevalence of atypical parkinsonian syndromes, with annonacin concentrations in these fruits correlating to environmental exposure levels that could induce neurodegeneration.^[53]^[54] In animal models, annonacin acts as a lipophilic inhibitor of mitochondrial complex I, causing selective degeneration of dopaminergic neurons in the substantia nigra and striatum, mimicking Parkinson's disease pathology.^[55]^[56] This mechanism results in impaired energy metabolism and ATP depletion, contributing to neuronal death observed in rat studies at doses as low as 0.3-3.6 mg/kg administered intracerebroventricularly over weeks.^[55] Beyond neurotoxicity, acetogenins pose risks of hepatotoxicity and genotoxicity at elevated doses. Bullatacin, another prominent acetogenin, has demonstrated liver and kidney toxicity in rodent models of hepatic cancer, with repeated intraperitoneal doses of 25-50 μg/kg leading to increased reactive oxygen species, elevated calcium levels, and histopathological changes in hepatic tissue.^[57] In vitro assays with acetogenins from Annona cherimolia seeds showed genotoxic effects, including DNA damage in human lymphocytes and bacterial mutagenicity, raising concerns for chromosomal aberrations with prolonged exposure.^[58] Acute toxicity data indicate that purified acetogenins exhibit low LD50 values in rodents, typically below 20 mg/kg via non-oral routes, highlighting their potent cytotoxicity that limits safe dosing in whole-organism contexts.^[59] Regulatory considerations for acetogenins emphasize caution due to their toxicity profile, particularly in supplements derived from Annonaceae species. The U.S. Food and Drug Administration (FDA) has issued warnings to manufacturers marketing graviola-based products with unapproved therapeutic claims, such as cancer treatment, and has not approved acetogenin-containing supplements for any medical use, citing insufficient safety data and potential neurotoxic risks.^[60] The European Food Safety Authority (EFSA) has assessed Annona muricata preparations and concluded substantial uncertainties exist regarding safe consumption levels, recommending avoidance of long-term use due to neurotoxic potential from annonacin accumulation.^[61] In veterinary contexts, acetogenins lack approved formulations, with their pesticidal properties noted but restricted by mammalian toxicity, precluding routine use in animal health products.^[59] Current guidelines, including those from health authorities in 2020-2024, stress monitored clinical evaluation for any investigational applications, prioritizing risk assessment over unsupervised supplementation.^[61]

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Jul 18, 2019 · Their most prominent biologic activity is inhibition of the mitochondrial Complex I due to their bis-THF structure. Indeed, it was previously ...
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Study Details | NCT02439580 | Effect of Annona Muricata Leaves on Colorectal Cancer Patients and Colorectal Cancer Cells | ClinicalTrials.gov
- **Phase**: Not specified in the content.
[26]
Study of Guanábana Leaves for The Treatment of Patients With ...
The main compounds in Graviola are the annonaceous acetogenins. These acetogenins have been shown to be selective and toxic against various types of cancer ...Study Overview · Study Plan · Publications
[27]
Acetogenins from Annona muricata as Antimicrobial Agents
However, has it been demonstrated that acetogenins are antimicrobial. This chapter aims to show the scientific evidence of the antimicrobial effect of crude ...
[28]
The Antimicrobial Activity of Annona emarginata (Schltdl.) H. Rainer ...
Compound 1 showed strong antimicrobial activity against all Gram (+) species tested (MICs = 3.12–6.25 µg/mL). In addition, the synthesis and antibacterial ...
[29]
Antitrypanosomal Activity of Acetogenins Isolated from the Seeds of ...
May 2, 2019 · The new compounds 1 and 2 displayed activity against the trypomastigote (IC50 = 0.4 and 3.6 μM) and amastigote (IC50 = 23.0 and 27.7 μM) forms.
[30]
Cytotoxic and antiparasitic activity from Annona senegalensis seeds
Several extracts of Annona senegalensis (Annonaceae) seeds were tested for antiparasitic activity against Leishmania major, Leishmania donovani, Trypanosoma ...
[31]
Inhibition of Respiration at Site I by Asimicin, an Insecticidal ...
The insecticidal mode of action of the acetogenin asimicin and a standardized acetogenin extract, FO20, isolated from Asimina triloba Dunal was investigated ...
[32]
Acetogenins from Annona muricata as potential inhibitors of ... - NIH
Apr 13, 2016 · Annona muricata is a tropical plant that belongs to the Annonaceae family and is well known for its anticancer properties. In this study, ...Missing: definition history
[33]
Evaluation of Annona muricata Acetogenins as Potential Anti-SARS ...
Jan 27, 2021 · Chemically, Acetogenins are the metabolic derivatives of long-chain fatty acids derived via the polyketide pathway (Prasad et al., 2019). Over ...
[34]
Abstract - WJPR
The results obtained here study suggested that the neuroprotective effect of acetogenin was mediated through the antioxidant, free radical scavenging activity ...<|control11|><|separator|>
[35]
Acetogenins from Annonaceae plants: potent antitumor and ...
The evidenced neurotoxic mechanisms were via the inhibition of neuronal mitochondrial complex I and dysfunctions of the tau protein. Acetogenins demonstrated ...Missing: duality | Show results with:duality
[36]
Cryo-electron microscopy reveals how acetogenins inhibit ...
Here, we report the structure (determined by cryo-EM) of mouse complex I with a tight-binding natural product acetogenin inhibitor.
[37]
The ND2 Subunit Was Labeled by a Photoaffinity Analogue of ...
NADH-ubiquinone oxidoreductase (complex I) is the entry enzyme of the respiratory chain in both mitochondria and bacteria. Complex I is the most elaborate iron- ...
[38]
Binding of Natural Inhibitors to Respiratory Complex I - MDPI
Aug 31, 2022 · Rotenone, piericidin A, and annonaceous acetogenins are representatives of complex I inhibitors from biological sources.Missing: ND2 | Show results with:ND2
[39]
inhibition of NADH oxidase activity of HeLa and HL-60, but not liver ...
In this report, we show activity of bullatacin in inhibition of NADH oxidase activity of plasma membrane vesicles isolated from HeLa cells and HL-60 cells but ...
[40]
Identification of an Annonaceous Acetogenin Mimetic, AA005, as an ...
Annonaceous acetogenins represent a class of naturally occurring polyketides isolated from various species of the plant genus Annonaceae [22]. These compounds ...
[41]
Annonaceous acetogenin mimic AA005 induces cancer cell death ...
Mar 18, 2015 · In response to apoptotic stimulus, permeabilized mitochondria release cytochrome c into the cytoplasm, where cytochrome c forms an apoptosome ...
[42]
The Alternative Medicine Pawpaw and Its Acetogenin Constituents ...
Both the extract and the purified acetogenins blocked the angiogenesis-stimulating activity of hypoxic T47D cells in vitro. Pawpaw extract and acetogenins ...
[43]
Laherradurin Inhibits Tumor Growth in an Azoxymethane/Dextran ...
Jan 29, 2024 · The neurotoxicity of acetogenins is reported in several works [64,65,66,67]. Some works demonstrated neural cell death and a change in the ...
[44]
Historic Perspectives on Annonaceous Acetogenins from the ...
Jun 24, 2010 · Studies on the Annonaceous acetogenins began after the first cytotoxic acetogenin, uvaricin, was isolated in 1982.
[45]
Annonaceous Acetogenins: Recent Progress - ACS Publications
The Annonaceous acetogenins are promising new antitumor and pesticidal agents that are found only in the plant family Annonaceae.
[46]
Acetogenins from Annonaceae: recent progress in isolation ...
The aim of the present review is to summarise the knowledge about newly isolated acetogenins (ACGs) in the last six years. It will also report the total ...Missing: breakthroughs | Show results with:breakthroughs
[47]
Annonaceous Acetogenins: The Unrevealed Area For Cytotoxic And ...
Aug 6, 2025 · They contain acetogenins which are known to have cytotoxic effect in tumor cells. Polyphenol activity from Annona muricata leaves has ...Missing: cytostatic | Show results with:cytostatic
[48]
Annonaceous acetogenins mimic AA005 targets mitochondrial ...
Oct 22, 2024 · Here we show AA005, an annonaceous acetogenin mimic, resists obesity induced by high-fat diets and leptin mutations at non-toxic doses.
[49]
The safety and tolerability of Annona muricata leaf product in people ...
The objective of this study was to design a clinical study protocol to investigate the safety and tolerability of Annona muricata, in people living with ...
[50]
The American Cherimoya Genome Reveals Insights into the Intra ...
Feb 26, 2024 · We have also identified a gene cluster that is potentially responsible for the biosynthesis of acetogenins, a class of natural products found ...
[51]
Quantification of acetogenins in Annona muricata linked to atypical ...
Oct 18, 2025 · An epidemiological study has reported that consumption of fruits of Annonaceae led to the prevalence of atypical parkinsonism in Guadeloupe due ...
[52]
Determination of Neurotoxic Acetogenins in Pawpaw (Asimina ...
The concentrations of the neurotoxins, annonacin and squamocin, were determined in a lyophilized sample of the fruit pulp of the North American pawpaw ...Missing: neuroprotective duality
[53]
Annonacin, a lipophilic inhibitor of mitochondrial complex I, induces ...
These data are compatible with the theory that annonaceous acetogenins, such as annonacin, might be implicated in the aetiology of Guadeloupean parkinsonism and ...
[54]
The mitochondrial complex I inhibitor annonacin is toxic to ... - PubMed
Our study demonstrates that annonacin promotes dopaminergic neuronal death by impairment of energy production.
[55]
Antitumor activity and toxicity relationship of annonaceous ...
Aug 7, 2025 · In fact, acetogenins with two adjacent tetrahydrofurans (THF) rings were reported to show higher antitumor activity and toxicity than those that ...Missing: vascularization | Show results with:vascularization
[56]
Genotoxic and cytotoxic effects produced by acetogenins obtained ...
In the present study we extracted three isomeric acetogenins (Ace) from the seeds of Annona cherimolia Mill. (Annonaceae) and determined their genotoxic and ...Missing: LD50 rodents
[57]
Annonaceous acetogenins as new pesticidal and antitumor agents
In purity certain acetogenins are toxic to mammals (LD 50 is < 20 mg kg −1 ), an impediment to regulatory approval, even though standardized extracts from ...
[58]
Amazing Sour Sop, Inc. - 512798 - 04/17/2017 - FDA
Apr 17, 2017 · “[O]ne chemical in Graviola was found to selectively kill colon cancer cells at 10,000 times the potency of (the commonly used chemotherapy drug) ...Missing: acetogenins | Show results with:acetogenins
[59]
Why Is Soursop Illegal? What Scientists and the FDA Say
Feb 10, 2025 · As a result, the FDA and Health Canada have not approved soursop supplements as a treatment for any disease. However, fresh soursop fruit ...
[60]
Risk assessment regarding the use of Annona muricata in food ...
Nov 26, 2020 · The assessment conducted within the present fellowship programme shows that substantial uncertainties exist regarding the safe use of A. muricata-based ...