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Iridoid

Iridoids are a class of monoterpenoids characterized by a bicyclic cyclopentanopyran , typically occurring as glycosides derived from the of iridodial, a key biosynthetic precursor. These compounds are secondary metabolites widely distributed in the plant kingdom and some , particularly in dicotyledonous families such as , , , and , where they serve ecological roles like defense against herbivores and pathogens. Approximately 1,000 iridoids have been identified as of 2025, with many exhibiting diverse pharmacological activities, including , , neuroprotective, hepatoprotective, hypoglycemic, and antitumor effects, making them valuable in traditional and modern medicine. Structurally, iridoids feature a cis-fused five-membered carbocyclic and a six-membered , often with a at C-1 linked to a glucose moiety, though variations include secoiridoids (with an opened ) and non-glycosidic forms. Their biosynthesis begins with the cyclization of or related precursors via pathways, leading to subtypes like iridoid glycosides (e.g., aucubin and catalpol) and bis-iridoids. Notable plant sources include (geniposide), officinalis (valepotriates), and (loganin and morroniside), where they contribute to the therapeutic efficacy of herbal remedies used for conditions such as , , and liver disorders. In terms of biological significance, iridoids modulate key signaling pathways, such as and MAPK, to exert their effects; for instance, catalpol has shown promise in by enhancing , while geniposide demonstrates hypoglycemic activity through insulin sensitization. Their low toxicity and multifaceted bioactivities have spurred research into , revealing moderate oral and via in the liver. Despite their potential, challenges remain in for clinical use, with ongoing studies focusing on structure-activity relationships to optimize therapeutic applications.

Chemical Properties

Structure

Iridoids are characterized by the iridane skeleton, a bicyclic -fused - ring system derived from a 10-carbon monoterpenoid framework. This core consists of a five-membered ring fused to a six-membered ring, with the fusion occurring in a . The numbering begins at the anomeric carbon of the in the ring, following standard monoterpenoid conventions. A defining feature of the iridane is the functionality at C-1, which imparts reactivity and often leads to equilibrium with the open-chain form. Additionally, a is typically present between C-3 and C-4 in the ring, contributing to the and influencing spectral properties. These elements form the foundational architecture observed across iridoid variants. In nature, iridoids predominantly occur as glycosidic forms, where the aglycone is bound to a β-D-glucose moiety at the C-1 hydroxyl group via a glycosidic linkage. This glycosylation enhances solubility and stability, with the glucose often attached in a β-configuration. Representative examples include aucubin, which features a simple iridane skeleton with a methyl group at C-11 and hydroxyls at C-6 and C-10, and catalpol, which features an epoxide bridge between C-5 and C-10, a hydroxyl at C-6, and the standard double bond between C-3 and C-4. The stereochemical configuration of iridoids is highly specific, with the cis fusion at the C-5/C-9 ensuring a compact bicyclic . Key chiral centers at C-5 and C-9 exhibit defined absolute configurations, typically (5R,9S) in the standard iridane system, influencing the overall three-dimensional shape and biological interactions. Iridoids can be differentiated from their ring-opened counterparts, secoiridoids, which arise from cleavage of the C-7–C-8 bond in the ring, resulting in an acyclic or lactone-containing structure while retaining the monoterpenoid origin. This modification expands the structural diversity but maintains traceability to the parent iridane skeleton.

Classification

Iridoids are classified primarily into two major categories based on the integrity of their core cyclopentanopyran skeleton: iridoid glycosides, which retain the intact bicyclic , and secoiridoid glycosides, which feature of the C-7/C-8 , resulting in an open ring. This structural distinction serves as the foundational criterion for categorization, with iridoid glycosides exemplified by aucubin-type compounds that maintain the fused and rings, often linked via a β-D-glucose moiety at the C-1 position. In contrast, secoiridoid glycosides, such as oleuropein-type structures, exhibit an aldehydic or functionality due to the ring opening, enhancing their reactivity and diversity. Further subtypes arise from variations in glycosylation patterns, the presence of additional functional groups, and intermolecular linkages. Valepotriates represent a subgroup of non-glycosidic iridoids, characterized by esterification at multiple hydroxyl positions on the intact iridoid , as seen in valtrate, which lacks the typical attachment but includes and isovalerate esters. Bis-iridoids, or dimeric forms, involve two iridoid units connected through C-C bonds or glycosidic linkages, such as in sylvestroside I, where the dimerization contributes to increased molecular complexity and stability. Iridoid alkaloids constitute another subtype, formed by the fusion of the iridoid moiety—often a secoiridoid derivative—with nitrogen-containing systems like , as in strictosidine, a key precursor in monoterpenoid featuring a tryptamine-iridoid linkage. Classification criteria emphasize not only ring integrity but also the degree of glycosylation (predominantly β-D-glycosides versus aglycones) and appended groups, such as lactones in many iridoid glycosides or dialdehydes in certain secoiridoids like amarogentin, a bitter secoiridoid glycoside with an opened and aromatic substitutions that amplify its pharmacological profile. These features highlight the structural diversity within iridoids, which often serve as precursors for more complex molecules, including alkaloids. The structural variations in iridoids hold significant evolutionary implications, functioning as chemotaxonomic markers that illuminate phylogenetic relationships among plant families. For instance, the prevalence of intact iridoid glycosides in orders like contrasts with the dominance of secoiridoids in , suggesting biosynthetic divergences that align with angiosperm and aid in resolving taxonomic ambiguities. This diversity, encompassing over 1,000 known compounds as of 2025, underscores iridoids' role in tracing adaptive radiations and monophyletic groupings in dicotyledons.

Biosynthesis

Metabolic Pathway

The biosynthesis of iridoids begins with geranyl diphosphate (GPP), a precursor derived from the mevalonate or methylerythritol phosphate pathways. GPP is first converted to by (GES), which undergoes sequential oxidations: first to 10-hydroxygeraniol, and then to 8-oxogeranial, a citral-like dialdehyde that serves as the key . These steps establish the linear carbon skeleton necessary for cyclization, with the pathway conserved across iridoid-producing organisms but adapted for specific end products. A pivotal reaction involves the NADPH-dependent reduction of 8-oxogeranial by , yielding an open-chain intermediate. This is rapidly followed by enzyme-assisted cyclization via iridoid cyclase to form nepetalactol, which equilibrates with iridodial, resulting in the characteristic bicyclic cyclopentanopyran skeleton. Further modifications include at C-1 to produce 7-deoxyloganic acid as an early glycosylated intermediate, which is then hydroxylated at C-7 and the carboxylic group is methylated to loganin. Loganin undergoes ring opening via oxidative cleavage to form secologanin, a crucial branch point leading to secoiridoids. The pathway can be visualized as a linear sequence from GPP to secologanin, with arrows denoting transformations: GPP → → 10-hydroxygeraniol → 8-oxogeranial → 8-oxocitronellyl → nepetalactol → iridodial → 7-deoxyloganic acid → loganic acid → loganin → secologanin, where secologanin is formed from loganin via oxidative cleavage of the C-7/C-8 bond. Variations occur across organisms; in , the pathway often includes elongations or dimerizations to form bis-iridoids, such as in certain where additional prenylations extend the scaffold. Secologanin serves as a precursor for monoterpenoid alkaloids in some species.

Key Enzymes

Iridoid synthase (ISY), a proline-rich member of the short-chain /reductase (SDR) family, catalyzes the pivotal reduction of 8-oxogeranial to the 8-oxocitronellyl , utilizing NADPH as a cofactor to perform a 1,4-reduction that generates an prone to cyclization. This enzyme's activity establishes the core iridoid bicyclic scaffold, with structural features including a conserved Rossmann fold for binding and a proline-rich potentially aiding orientation, though its precise role remains unclear. Subsequent enzymatic steps involve iridoid cyclase (ICYC), an α/β hydrolase-fold enzyme that promotes the cyclization of the 8-oxocitronellyl enol intermediate from ISY via protonation at the enol's γ-position, yielding nepetalactol (also known as 8-epi-iridodial in its form) with determined by the (Ser-Asp-His). Further progression involves of iridodial by 7-deoxyloganic acid glucosyltransferase (7DLGT) to 7-deoxyloganic acid, followed by at C-7 by 7-deoxyloganic acid hydroxylase (7DLH), a enzyme requiring NADPH and O₂, to form loganic acid; methylation by loganic acid O-methyltransferase (LAMT) using S-adenosylmethionine () then yields loganin. The formation of secologanin, a key intermediate linking iridoids to synthesis, involves secologanin synthase (), another that performs oxidative cleavage of the C-7/C-8 bond in 7-hydroxy-loganin. These enzymes belong to broader gene families, including the progesterone 5β-reductase/iridoid (P5βR/ISY) for reductive steps and the CYP72A subfamily of P450s for oxidative modifications, with iridoid-specific variants identified in such as CYP72A orthologs tailored for secoiridoid formation. Mechanistically, cyclization by ICYC involves histidine-mediated proton donation to facilitate enol-to-aldehyde tautomerization and ring closure, while cofactor dependencies across the pathway—NADPH for reductions and O₂ for hydroxylations—highlight balance as critical for efficiency. Post-2012 discoveries have advanced applications, notably through engineering of iridoid pathways in , where co-expression of ISY, ICYC, and downstream enzymes like 7DLGT, 7DLH, and LAMT enabled of loganic acid and secologanin at yields up to 100 mg/L, bypassing plant-specific limitations. Such reconstructions, often using codon-optimized genes from , have illuminated enzyme promiscuity and facilitated stereoselective iridoid variants for pharmaceutical precursor synthesis.

Natural Distribution

Plant Sources

Iridoids occur in over 50 plant families, predominantly within the clade of angiosperms, where they serve as key secondary metabolites. Among these, the most prominent families include , exemplified by which contains geniposide as a major iridoid ; , such as species producing strictosidine, a precursor to monoterpenoid alkaloids; , represented by genera with aucubin as a characteristic compound; and , where species accumulate swertiamarin. These families highlight the widespread yet patterned distribution of iridoids, often as glycosides, across dicotyledonous plants. Iridoids typically exhibit the highest concentrations in leaves, roots, and fruits, with levels varying by species and environmental factors; for instance, in , total iridoid content can reach 2.5–7.3% of dry weight in some Siberian species. Extraction methods commonly involve solvent-based techniques like or ultrasonication, often optimized for recovery, yielding up to 63 mg/g in optimized processes from species. Chemotaxonomically, iridoids function as reliable markers for orders such as Cornales and , aiding in delineating evolutionary relationships within due to their conserved biosynthetic pathways and discrete distribution. Recent investigations up to 2025 have uncovered new iridoids in Patrinia species of Valerianaceae, including six novel compounds from P. villosa with potential insulin-sensitizing properties, and iridoids in genera like , expanding understanding of structural diversity in these taxa.

Animal Sources

Iridoids are predominantly associated with plants but occur in certain animals, particularly , where they function primarily as chemical defenses or pheromones. Unlike the widespread de novo production in plants, animal iridoids often result from either endogenous or sequestration from dietary sources, highlighting adaptive strategies for survival in herbivorous or predatory contexts. In of the genus Iridomyrmex, such as the (Linepithema humile, formerly classified under Iridomyrmex), iridoids are synthesized de novo and stored in the pygidial glands as key components. Iridomyrmecin, a cyclopentanoid , constitutes the major iridoid in these glands, reaching up to 2% of the ant's body weight and serving as a potent defensive against predators and competitors. This occurs via the , which is the primary route for production in , converting isopentenyl diphosphate (IPP) and dimethylallyl diphosphate (DMAPP) into geranyl diphosphate (GPP) precursors. Butterflies in the Euphydryas, such as E. anicia and E. phaeton, exemplify sequestration of plant-derived iridoids rather than . Larvae and adults accumulate aucubin, an iridoid , from host like those in the family, incorporating it into their tissues for defense against predators; levels vary seasonally and by population, with higher concentrations in caterpillars correlating to host plant chemistry. This process involves selective uptake and of plant precursors, adapting the mevalonate-derived iridoid scaffold for insect-specific modifications without full endogenous pathway activation. Iridoids are rare outside of and lepidopterans, appearing in trace amounts in some and primarily as pheromones or repellents. In leaf beetles of the Chrysomelina subtribe, such as Phaedon cochleariae, de novo biosynthesis produces deterrent iridoids like chrysomelidial via cytochrome P450-mediated hydroxylation of intermediates, enabling rapid deployment against herbivores. exhibit minimal iridoid presence, limited to sporadic defensive roles in species interactions, underscoring the compounds' niche specialization in insect chemical . Insect pathways show evolutionary convergence with iridoid , sharing core cyclization steps from 8-oxogeranial but diverging in precursor sourcing and enzymatic efficiency. Recent genomic studies in the have revealed iridoid synthase homologs in lepidopteran transcriptomes, supporting potential latent biosynthetic capacity alongside ; for instance, analyses of genomes (closely related hemipterans) confirm mevalonate-dependent iridoid production with orthologs akin to synthases, suggesting broader adaptability.

Biological Significance

Ecological Roles

Iridoids play crucial roles in plant defense mechanisms within ecosystems, primarily by deterring herbivores through their bitter taste and toxicity. In species like Plantago lanceolata, the iridoid glycoside aucubin acts as a feeding deterrent against generalist mammalian and insect herbivores, reducing consumption rates by making foliage unpalatable. Similarly, these compounds exhibit antimicrobial properties, inhibiting the growth of soil pathogens such as the specialist fungus Diaporthe adunca while sparing generalist fungi, thereby protecting plant roots from infection. This dual functionality enhances plant survival in microbe-rich environments. In insect-plant interactions, iridoids are often sequestered by specialist herbivores for their own defense. Larvae of butterflies in the genus Euphydryas, such as E. phaeton, incorporate iridoid glycosides like aucubin from host plants (Aureolaria flava) into their tissues, rendering them emetic to predators like and increasing rejection rates during attacks. In ants, particularly dolichoderine species like the Argentine ant (Linepithema humile), iridoids such as dolichodial serve as alarm pheromones and defensive secretions, signaling threats and deterring intruders through volatility and irritancy. Iridoids also function as allelochemicals, suppressing the growth of neighboring plants to reduce competition. Extracts containing iridoid glucosides from Verbascum thapsus roots, such as hastatoside, inhibit seed germination and root elongation in bioassays at concentrations around 3 mM, creating bare zones around parent plants. From an evolutionary perspective, iridoids exemplify co-evolution between plants and herbivores, where glycosidic forms are activated into toxic aglycones within the herbivore's gut via enzymatic hydrolysis by β-glucosidases. This process generates reactive compounds that cross-link proteins, deterring feeding and driving adaptations in specialist insects that tolerate or sequester them. Field studies underscore these roles; for instance, elevated catalpol levels in Veronica species correlate with reduced herbivory by generalist insects, with plants showing up to 50% lower damage rates compared to low-iridoid individuals in natural populations.

Pharmacological Effects

Iridoids, a class of monoterpenoid glycosides, demonstrate diverse pharmacological effects through mechanisms involving antioxidant activity, enzyme inhibition, and modulation of signaling pathways. These compounds, often derived from plants like Gardenia jasminoides and Olea europaea, have been investigated for their potential in treating inflammatory, oxidative stress-related, and infectious diseases. Recent reviews highlight their low toxicity profiles, with oral LD50 values exceeding 2 g/kg in rodent models, supporting further therapeutic exploration. Anti-inflammatory effects of iridoids are mediated primarily through inhibition of the signaling pathway, which reduces the expression of pro-inflammatory cytokines such as TNF-α and IL-6. Geniposide, an iridoid glycoside from , has exhibited significant suppression of joint inflammation and cartilage degradation in collagen-induced mouse models, comparable to dexamethasone at doses of 50-100 mg/kg. Similarly, catalpol from attenuates in by downregulating activation and iNOS expression. These effects position iridoids as candidates for managing chronic inflammatory conditions like . Iridoids also display potent antioxidant and anticancer activities by scavenging (ROS) and inducing in malignant cells. Oleuropein, a secoiridoid from leaves, inhibits colon proliferation via ROS-mediated mitochondrial dysfunction in HT-29 cell lines. Catalpol further contributes to anticancer effects by promoting caspase-3 activation and downregulation in and models, enhancing the efficacy of chemotherapeutic agents like . These properties underscore iridoids' role in mitigation and tumor suppression. In antimicrobial and antiviral applications, iridoids disrupt microbial cell membranes and inhibit viral replication. Aucubin from Plantago major exhibits bactericidal activity against Staphylococcus aureus by compromising formation and efflux pumps, with minimum inhibitory concentrations () ranging from 64-128 μg/mL. Swertiamarin, isolated from Swertia chirayita, demonstrates antiviral effects against (HSV-1) by interfering with viral attachment and penetration, reducing plaque formation by up to 70% in assays. These findings support iridoids' utility in combating antibiotic-resistant infections and viral outbreaks. Additional pharmacological effects include hepatoprotective and actions. Catalpol protects against carbon tetrachloride-induced by enhancing enzymes like and GSH-Px, while reducing and levels in rat models. Valerian-derived iridoids, such as valepotriates, alleviate anxiety and provide via GABA_A receptor modulation and reduction of β-amyloid aggregation in models. Pharmacokinetically, iridoids like geniposide suffer from poor oral (around 10-20%) due to extensive first-pass by , though nanoformulations have improved absorption in preclinical studies. As of 2025, iridoid research remains predominantly preclinical, with ongoing studies emphasizing structure-activity relationships, mechanisms, and optimized delivery systems to enhance therapeutic applications.

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    Jul 31, 2025 · A review study analyzed the antidepressant activity of the main iridoids found in the literature, noting that GP has several beneficial effects ...Missing: 2020-2025 | Show results with:2020-2025