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Aryl hydrocarbon receptor

The aryl hydrocarbon receptor (AhR) is a ligand-activated of the basic helix-loop-helix/Per-Arnt-Sim (bHLH/PAS) family that functions as an environmental sensor, detecting and responding to a wide array of exogenous, endogenous, and microbial signals to regulate and maintain physiological . Encoded by a on chromosome 7, AhR resides in the in an inactive state, bound to chaperone proteins such as and XAP2, until binding induces a conformational change, nuclear translocation, and dimerization with the aryl hydrocarbon receptor nuclear translocator (ARNT) to drive transcription of target genes via aryl hydrocarbon response elements (AHREs). AhR's ligand repertoire is diverse and includes environmental toxins like 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) and polycyclic aromatic hydrocarbons (PAHs), endogenous metabolites such as tryptophan-derived compounds (e.g., 6-formylindolo[3,2-b]carbazole [FICZ] and ), and microbial products like derivatives from gut . This versatility enables AhR to mediate detoxification, cellular metabolism, and adaptive responses to environmental stressors, while also influencing developmental processes and organ formation during embryogenesis. In non-toxic contexts, AhR activation promotes immune cell differentiation, including regulatory T cells (Tregs) and Th17 cells, thereby balancing and tolerance in barrier tissues like the gut and . Dysregulation of AhR signaling contributes to a of pathologies, exhibiting a : protective in suppressing and , yet potentially detrimental in promoting tumor progression and . For instance, AhR activation by microbial ligands supports intestinal barrier integrity and modulates the gut-brain axis, linking it to neurological disorders, while chronic exposure to agonists like TCDD is associated with and developmental . Recent advances, including cryo-electron microscopy structures and targeted agonists like , highlight AhR's therapeutic potential in treating inflammatory skin diseases, autoimmune conditions, and cancers, with ongoing clinical trials exploring selective modulators to harness its benefits while minimizing .

Overview

Definition and General Function

The aryl hydrocarbon receptor (AhR) is a ligand-activated that serves as a key regulator of cellular responses to environmental cues. It belongs to the basic helix-loop-helix/Per-Arnt-Sim (bHLH/PAS) family of transcription factors, characterized by its ability to form heterodimers with aryl hydrocarbon receptor nuclear translocator (ARNT) proteins to bind DNA and modulate . As a pioneer member of this family, AhR exemplifies the structural motifs that enable sensing of diverse signals, including both exogenous toxins and endogenous metabolites. AhR's primary function involves detecting environmental signals and orchestrating adaptive programs. Upon binding, it translocates to the , where it activates transcription of target genes, particularly those encoding enzymes (such as and ) that facilitate metabolism and . Beyond , AhR plays essential roles in developmental processes, including vascular and organ development, and in maintaining by influencing T-cell differentiation and production (e.g., and IL-10). These functions highlight AhR's integration of environmental sensing with physiological adaptation across multiple systems. The AhR exhibits remarkable evolutionary , with orthologs identified across , including mammals, , and even jawless species like lampreys, tracing back over 450 million years. In mammals, a single AhR predominates, while some non-mammalian possess duplicated forms (e.g., AHR1 and AHR2 in ), underscoring its fundamental role in adaptive responses conserved through evolution. This conservation extends to shared bHLH and domains that preserve core signaling mechanisms.

Historical Discovery

The discovery of the aryl hydrocarbon receptor (AhR) originated in the early through investigations into the mechanisms of toxicity and enzyme induction by environmental pollutants, particularly polycyclic aromatic hydrocarbons (PAHs) and their derivatives. Researchers Alan Poland and Ellen Glover identified a specific, high-affinity binding protein in mouse liver that interacted with 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), a potent known for inducing aryl hydrocarbon hydroxylase (AHH) activity. Their studies demonstrated that TCDD was extraordinarily potent—up to 30,000 times more effective than PAHs like 3-methylcholanthrene—in eliciting this response, suggesting the involvement of a dedicated receptor mediating these effects. This binding was stereospecific and saturable, providing the first evidence for a receptor protein, initially termed the "dioxin receptor," that linked xenobiotic exposure to altered gene expression in hepatic tissues. In the 1980s, further characterization solidified the AhR's role as a central mediator of TCDD toxicity and xenobiotic metabolism. Binding assays using radiolabeled [³H]TCDD confirmed the receptor's presence across species and tissues, with genetic studies in mice revealing allelic variants (e.g., Ah^b and Ah^d) that influenced sensitivity to dioxin-induced effects like thymic atrophy and tumor promotion. These findings established the AhR as a key player in toxicological responses, including the induction of cytochrome P450 enzymes such as CYP1A1, which metabolize PAHs but can also generate reactive intermediates leading to mutagenesis and carcinogenesis. The receptor was characterized biochemically as a soluble, ligand-activated protein complexed with heat shock protein 90 (HSP90), highlighting its role in sensing and responding to environmental toxins. The molecular era began in 1993 with the cloning of the human AhR cDNA by Dolwick, Schmidt, Carver, Swanson, and Bradfield, revealing it as a member of the basic helix-loop-helix (bHLH) superfamily of transcription factors. This work demonstrated that the AhR contains a PAS domain for protein-protein interactions and ligand binding, enabling it to translocate to the nucleus upon activation and regulate target genes via xenobiotic response elements (XREs). In 1992, Reyes, Reisz-Porszasz, and Hankinson identified the aryl hydrocarbon receptor nuclear translocator (ARNT) as the essential heterodimerization partner for the AhR, confirming that the AhR-ARNT complex binds DNA and drives transcriptional activation. These milestones shifted the focus from purely toxicological mechanisms toward broader physiological implications, as emerging evidence suggested endogenous roles in development, immune regulation, and circadian rhythm, expanding the AhR's significance beyond xenobiotic sensing.

Gene and Expression

Gene Structure and Location

The human AHR gene is located on the short arm of chromosome 7 at band p21.1, with genomic coordinates spanning from 17,298,652 to 17,346,147 on reference sequence NC_000007.14. This positioning places it in a region associated with various regulatory influences, though the gene itself exhibits a conserved structure across mammals. The gene encompasses approximately 47 kb of genomic DNA and is organized into 11 exons, which encode the full-length 848-amino-acid protein. The exon-intron boundaries follow a pattern typical of basic helix-loop-helix (bHLH) transcription factor genes, with exon 1 containing the non-coding 5' untranslated region and the initial coding sequence for the bHLH domain. The promoter region of the AHR gene, located upstream of exon 1, features multiple regulatory elements that facilitate both basal and inducible transcription. Notably, it includes xenobiotic-responsive elements (XREs), also known as dioxin-responsive elements (DREs), with the core 5'-T(A/G)GCGTG-3', which can bind the AHR-ARNT heterodimer to enable auto-regulatory feedback in response to ligands like 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD). Additional elements, such as GC-rich Sp1 binding sites, contribute to constitutive expression, while integration with nearby (AREs) allows crosstalk with pathways like NRF2 signaling for coordinated stress responses. Several single nucleotide polymorphisms (SNPs) have been identified in the AHR gene, with some influencing receptor function. A prominent example is the rs2066853 variant (c.1661G>A; p.Arg554Lys) in exon 10, which lies within the and is associated with reduced transcriptional activity and altered sensitivity to ligands, potentially affecting metabolism and disease susceptibility. These variants can subtly modulate AHR expression levels across tissues, though primary regulation occurs through environmental and epigenetic factors.

Tissue Expression and Regulation

The aryl hydrocarbon receptor (AhR) exhibits ubiquitous expression across tissues, but with notable variations in levels. High mRNA and protein expression is observed in the liver, , , and , where it supports roles in and . In contrast, expression is relatively lower in the and , though detectable in specific neural regions such as the and . These patterns are derived from transcriptomic datasets, including analyses from the Genotype-Tissue Expression (GTEx) project, indicating normalized transcript per million (nTPM) values that are substantially elevated in the aforementioned high-expression tissues compared to others. AhR expression is tightly regulated at the transcriptional level by interactions with key factors, including , which modulates AhR promoter activity through pathway crosstalk and can suppress or enhance expression depending on cellular context. Epigenetic mechanisms further control AhR levels, particularly at CpG islands within the promoter region; hypermethylation silences expression, as seen in conditions like , while demethylation agents restore it. modifications and targeting also contribute to this epigenetic landscape, influencing accessibility and AhR transcription. Recent studies have identified alterations in AhR expression associated with diseases; for example, decreased expression correlates with susceptibility to (COPD). Environmental influences, such as exposure to pollutants like dioxins and polycyclic aromatic hydrocarbons, can upregulate AhR mRNA levels via ligand-induced feedback mechanisms, amplifying receptor availability in responsive tissues like the liver and .

Protein Structure

Functional Domains

The aryl hydrocarbon receptor (AhR) protein in humans comprises 848 amino acids, forming a modular structure with distinct functional domains that are highly conserved across vertebrate species, reflecting its evolutionary role in environmental sensing and transcriptional regulation. This conservation is evident in the core motifs, such as the basic helix-loop-helix (bHLH) and Per-Arnt-Sim (PAS) domains, which share significant sequence similarity among mammals, birds, and fish, enabling analogous functions in ligand response and gene expression control. The N-terminal bHLH domain, spanning approximately the first 200 amino acids, is responsible for DNA binding and heterodimerization with the aryl hydrocarbon receptor nuclear translocator (ARNT). This domain features a basic region that recognizes the xenobiotic response element (XRE) consensus sequence (5'-TTGCGTG-3') on target DNA via two α-helices connected by a flexible loop, while the helix-loop-helix motif mediates protein-protein interactions essential for dimer formation. Deletion studies have confirmed that the bHLH domain is indispensable for AhR's transcriptional activity, as its absence abolishes DNA binding and ARNT association. In the central region, the PAS-A and PAS-B s facilitate binding and protein-protein interactions. The PAS-A regulates the specificity and of heterodimerization with ARNT, acting as a for conformational adjustments during complex formation. Adjacent to it, the PAS-B , which encompasses residues roughly 230–421 in the ortholog and is similarly positioned in humans, serves as the primary site for accommodation and interactions with chaperone proteins like , contributing to the receptor's cytosolic prior to . structures of the PAS-B highlight its β-sheet-rich fold, which undergoes subtle shifts to accommodate diverse signals while maintaining structural integrity across species. Recent cryo-electron (cryo-EM) structures have provided insights into the full-length human AhR in complex with chaperones , XAP2, and p23, resolving the cytosolic complex at near-atomic resolution (e.g., 3.0 ) and revealing how the PAS-B is stabilized within the multiprotein assembly before -induced . The C-terminal glutamine-rich (Q-rich) transactivation domain recruits transcriptional co-activators and the basal transcription machinery to initiate . This domain, rich in residues, interacts with components such as the and mediator complex, potentiating the recruitment of to XRE-bound promoters. Functional analyses indicate that the Q-rich region is critical for full potential, with mutations reducing transcriptional efficacy by impairing co-activator binding. Ligand binding induces conformational changes across these domains that enhance their interactions, promoting nuclear translocation and pathway activation.

Ligand Binding and Conformational Changes

The PAS-B of the aryl hydrocarbon receptor (AhR) serves as the primary -binding pocket, accommodating a diverse array of planar aromatic through a conserved hydrophobic cavity. This pocket is lined by key residues such as Phe293, Leu351, Phe295, Phe351, and Tyr322, which facilitate π-π stacking and van der Waals interactions essential for stabilizing accommodation. The bipartite nature of the pocket, comprising a primary site for specificity and a secondary site for enhanced promiscuity, allows binding of up to approximately 600 in size. Upon binding, the AhR undergoes significant conformational changes that initiate its . These include a rearrangement of the Dα-Eα loop and a 90° rotation of residues like Met331 and Ile332 in the βG-βF region, which expose the N-terminal localization signal (NLS) and disrupt inhibitory interactions with chaperone proteins such as and XAP2. Additionally, the C-terminal loop (residues 401–413) shifts, further alleviating sequestration in the and promoting translocation. Cryo-EM structures of -bound human AhR complexes (e.g., with indirubin) have elucidated these dynamics at the full-complex level, showing how engagement displaces chaperones and enables ARNT heterodimerization. These local changes propagate allosteric effects to distant domains, particularly enhancing the dimerization potential of the bHLH domain. -induced alterations in the DE-loop and C-terminal loop, involving residues like Asp327, Val348, Phe349, and Arg396, transmit signals that reposition the bHLH region for efficient interaction with ARNT. This structural communication underscores the PAS-B domain's role in coupling recognition to downstream functional competence.

Ligands

Endogenous Ligands

The aryl hydrocarbon receptor (AhR) is activated by several endogenous ligands, primarily metabolites derived from dietary or physiological pathways, which play roles in maintaining cellular and modulating immune responses. These ligands, often present at low physiological concentrations, bind to AhR with varying affinities and contribute to non-toxic, regulatory functions distinct from responses. Among the most potent endogenous AhR activators are metabolites generated via the or photochemical reactions. 6-Formylindolo[3,2-b]carbazole (FICZ), a photoproduct formed by UV oxidation of , exhibits high binding affinity with an EC50 of approximately 34 pM and a KD of 0.07 nM, enabling at trace physiological levels detected in human tissues. FICZ promotes AhR-dependent immune , including the differentiation of T helper 17 (Th17) cells and induction of cytochrome P450 1A1 (CYP1A1) for response, thereby supporting intestinal barrier function and . Another derivative, kynurenine, produced by indoleamine 2,3-dioxygenase 1 (IDO1) or tryptophan 2,3-dioxygenase 2 (TDO2), acts as a weaker agonist with an EC50 of approximately 10–13 μM, though its physiological concentrations (1–2 μM in normal serum, elevated to 10–50 μM during inflammation) allow for relevant . facilitates (Treg) generation and immune suppression, contributing to tolerance in contexts like tumor microenvironments and chronic inflammation. Microbiota-derived tryptophan metabolites also serve as important endogenous AhR ligands, produced by gut bacteria such as Lactobacillus species. Examples include indole-3-aldehyde (I3A) and indole-3-propionic acid (IPA), which activate AhR to promote interleukin-22 (IL-22) production, enhance barrier integrity, and balance mucosal immunity. These ligands are particularly relevant in the gut, where they support host-microbe homeostasis and protect against inflammation. Additional endogenous ligands include heme-derived and lipid-derived metabolites with anti-inflammatory properties. , a breakdown product of , activates AhR at an EC50 of about 30 µM, with physiological blood levels typically below this threshold but elevated in conditions like Crigler-Najjar syndrome (400–800 µM), where it enhances detoxification and antioxidant defenses. Similarly, lipoxin A4, an arachidonic acid derivative involved in resolution, binds AhR with an EC50 of 100 nM and promotes immune homeostasis by dampening pro-inflammatory responses. These ligands underscore AhR's role in physiological balance, with FICZ exemplifying rapid, high-potency regulation in immune contexts.

Exogenous Ligands

Exogenous ligands of the aryl hydrocarbon receptor (AhR) encompass a diverse array of environmental and dietary compounds that bind to the receptor with varying affinities and potencies, often originating from sources or natural products. These ligands can activate AhR signaling, influencing , immune responses, and pathways, with some exhibiting beneficial effects at low doses while others pose significant risks due to their persistence and . Polycyclic aromatic hydrocarbons (PAHs), such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), represent among the most potent exogenous AhR ligands, primarily arising from incomplete combustion processes in industrial activities, vehicle exhaust, and wildfires. TCDD, the prototypical dioxin, binds AhR with high affinity, characterized by a dissociation constant (Kd) of approximately 1 nM, enabling persistent activation that disrupts normal physiological functions. Other PAHs, like benzopyrene, exhibit similar but generally lower binding potencies, contributing to AhR-mediated responses in exposed organisms. Dietary exogenous ligands include phytochemicals from plant sources, such as (I3C) derived from like and , which undergoes acid-catalyzed conversion in the to form high-affinity AhR agonists like (DIM). I3C and its derivatives activate AhR at concentrations relevant to human dietary intake, promoting anti-inflammatory and immunomodulatory effects without the toxicity associated with synthetic ligands. , exemplified by found in onions, apples, and tea, also bind AhR directly, inducing expression and downstream signaling, though with lower potency compared to TCDD, as evidenced by their inability to fully displace high-affinity ligands in competitive binding assays. Industrial pollutants, particularly polychlorinated biphenyls (PCBs), serve as persistent organic exogenous AhR ligands, with dioxin-like congeners such as PCB-126 demonstrating significant activation potency through structural mimicry of TCDD. PCBs vary widely in their AhR-binding efficacy, with coplanar isomers like PCB-77 and PCB-126 exhibiting relative potencies up to 0.01-0.1 times that of TCDD, leading to in fatty tissues and long-term environmental exposure risks. Non-coplanar PCBs generally show reduced potency, highlighting the role of planarity in ligand-receptor interactions.

Signaling Pathway

Cytosolic Complex and Sequestration

In its inactive state, the aryl hydrocarbon receptor (AhR) resides in the cytoplasm as a multiprotein complex that ensures its stability and prevents premature activation. This cytosolic complex primarily consists of the AhR bound to a dimer of heat shock protein 90 (Hsp90), the co-chaperone p23, and the immunophilin-like protein XAP2 (also known as AIP or ARA9). Hsp90 plays a central role by associating with the AhR's bHLH and PAS domains, thereby maintaining the receptor's proper folding, ligand-binding competency, and overall structural integrity while shielding it from proteasomal degradation. The association with this chaperone machinery also masks the AhR's nuclear localization signal (NLS), located in the bHLH domain, thereby retaining the receptor in the latent cytosolic form and inhibiting spontaneous nuclear translocation or heterodimerization with ARNT. p23 stabilizes the ATP-bound conformation of , enhancing the complex's assembly and further contributing to AhR retention in the . XAP2 binds independently to both AhR and via its TPR , augmenting cytosolic retention, protecting against ubiquitination-mediated degradation, and increasing steady-state AhR levels by up to several fold in various cell types. Protein phosphatase 2A (PP2A) has been implicated in regulating the complex through of AhR, which influences receptor stability and activity, though its structural integration remains less defined. The cytosolic complex operates in a dynamic , with chaperone components exhibiting exchange and turnover that balance AhR availability. For instance, and p23 associate transiently, while XAP2 modulates the complex's by slowing AhR proteasomal turnover, extending it from minutes in unbound states to hours within the assembled form. This maintains the receptor in a poised, inactive state, poised for ligand-induced .

Activation and Nuclear Translocation

Upon binding of a to the aryl hydrocarbon receptor (AhR) in the , a conformational change occurs that leads to the dissociation of the chaperone complex, including , p23, and XAP2, from the receptor. This dissociation unmasks the bipartite nuclear localization signal (NLS) located within the basic helix-loop-helix (bHLH) domain of AhR, which was previously sequestered by the chaperones in the inactive state. The exposed NLS is essential for initiating the receptor's movement toward the , marking the transition from the cytosolic, ligand-free form to the activated state capable of nuclear entry. The unmasked NLS is recognized by proteins, specifically importin β1 or the importin α/β1 heterodimer, which facilitate the transport of AhR through the nuclear pore complex into the . This importin-mediated process relies on the positively charged residues in the NLS, and inhibition of importin α/β function significantly reduces AhR nuclear accumulation. As noted in studies of the cytosolic chaperone complex, the release from Hsp90-based sequestration is a prerequisite for this efficient import, ensuring that only ligand-activated AhR proceeds to the . Nuclear accumulation of AhR following ligand exposure, such as with indirubin or β-naphthoflavone, occurs rapidly, typically within 15 minutes in cellular models. Phosphorylation events can modulate translocation efficiency; for instance, ligand-induced activation has been associated with that influences the receptor's nuclear dynamics, although specific kinases like are more prominently linked to downstream signaling rather than direct enhancement of import. This swift translocation underscores the sensitivity of the AhR pathway to environmental cues, enabling prompt transcriptional responses.

Dimerization, DNA Binding, and Transcription

Upon nuclear translocation, the ligand-bound aryl hydrocarbon receptor (AhR) undergoes heterodimerization with the aryl hydrocarbon receptor nuclear translocator (ARNT) primarily through their respective basic helix-loop-helix (bHLH) domains, forming the functional AhR-ARNT complex essential for transcriptional activation. This dimerization is mediated by specific interactions between the bHLH motifs of both proteins, which stabilize the complex and enable DNA recognition, as revealed by crystallographic studies of the bHLH-PAS-A domains. The bHLH domain of AhR contributes the basic region for DNA contact and the helix-loop-helix for ARNT dimerization, while the adjacent Per-ARNT-Sim (PAS) domains further support heterodimer formation without homodimerization. The AhR-ARNT heterodimer binds to xenobiotic response elements (XREs), also known as dioxin response elements (DREs), located in the promoter or enhancer regions of target genes. The consensus XRE sequence is 5'-TNGCGTG-3', where N represents any , and this (particularly the invariant GCGTG) is recognized by the basic regions of the bHLH domains in a sequence-specific manner. Multiple XREs often cluster to enhance binding affinity and transcriptional synergy, facilitating the of the transcriptional machinery to genes involved in metabolism. Binding of the AhR-ARNT complex to XREs induces chromatin remodeling and recruits RNA polymerase II (Pol II) along with coactivators such as steroid receptor coactivator 1 (SRC1) and the positive transcription elongation factor b (P-TEFb), which phosphorylates Pol II to promote transcriptional elongation.82745-5/fulltext) This recruitment leads to the upregulation of target genes, exemplified by cytochrome P450 1A1 (CYP1A1), where AhR-ARNT occupancy correlates with increased Pol II loading and histone acetylation at the promoter. The cyclical association of these factors ensures robust and ligand-dependent gene induction without persistent activation.82745-5/fulltext)

Crosstalk with Other Pathways

The aryl hydrocarbon receptor (AhR) engages in bidirectional crosstalk with multiple signaling pathways, modulating cellular responses in processes such as inflammation, fibrosis, and proliferation. This integration allows AhR to fine-tune non-canonical signals, often exerting inhibitory or synergistic effects depending on the context and ligand activation. Key interactions occur with the transforming growth factor-β (TGF-β)/Smad pathway, nuclear factor-κB (NF-κB) pathway, estrogen receptor (ER) signaling, and Wnt/β-catenin pathway, influencing outcomes in immunity, hormone regulation, and tissue homeostasis. AhR inhibits TGF-β/Smad signaling primarily through direct interaction with Smad3, disrupting its association with β-catenin and thereby attenuating fibrogenic responses. In hepatic stellate cells, AhR activation sequesters Smad3 away from β-catenin, preventing TGF-β-induced production and differentiation, which is critical for suppressing liver . Similarly, AhR agonists like 2-(1′H-indole-3′-carbonyl)-thiazole-4-carboxylic acid methyl ester (ITE) block TGF-β1-stimulated synthesis and α-smooth muscle expression in fibroblasts, reducing in models of and while preserving immune regulatory functions. This Smad3-mediated inhibition also extends to immune , where AhR limits TGF-β-driven T-cell and fibrotic remodeling in autoimmune contexts. In cross-regulation with during , activated AhR suppresses pro-inflammatory production, including tumor necrosis factor-α (TNF-α), by interfering with DNA binding and transcriptional activity. AhR agonists such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) and β-naphthoflavone inhibit responses triggered by TNF-α or lipopolysaccharide (LPS), reducing expression like interleukin-8 in bronchial epithelial cells and macrophages. This suppression involves AhR binding to consensus sites and competition for coactivators, shifting the balance toward anti-inflammatory outcomes, as seen in models of silica-induced where AhR exacerbates -driven storms. Conversely, subunits like can upregulate AhR expression, creating a feedback loop that modulates chronic inflammatory states, including those involving indoxyl sulfate-induced TNF-α in renal disease. AhR interacts with the (ER) pathway to influence hormone responses, often repressing ER-mediated transcription through direct protein-protein associations and indirect effects on estrogen metabolism. Ligand-activated AhR binds ERα, inhibiting its recruitment to estrogen response elements and downregulating genes involved in breast cell proliferation and hormone-dependent cancers. Additionally, AhR induces enzymes that hydroxylate estrogens, promoting their degradation and attenuating ER signaling in reproductive tissues, which contributes to altered estrogenic responses in environmental exposures. This crosstalk is evident in pituitary and mammary models, where AhR activation antagonizes ER-driven , potentially linking exposure to endocrine disruption. AhR modulates the Wnt/β-catenin pathway, impacting and by altering β-catenin stability and transcriptional output. AhR enhances Wnt signaling through targets like scinderin, an actin-severing protein that facilitates β-catenin nuclear translocation and upregulates genes in intestinal and hepatic cells. However, in other contexts, AhR inhibits canonical Wnt by competing for β-catenin binding, reducing its interaction with T-cell factor/lymphoid enhancer factor (TCF/LEF) and suppressing proliferative responses in colon cancer models. This bidirectional interplay positions AhR as a regulator of Wnt-driven tissue regeneration and oncogenesis, with disruptions observed in development and where AhR ligands alter β-catenin-dependent .

Physiological Functions

Role in Development and Differentiation

The aryl hydrocarbon receptor (AhR) plays a critical role in vascular development, particularly through regulation of (VEGF) expression. In AhR-deficient mice, impaired has been observed due to downregulation of VEGF, leading to abnormal vascular structures in multiple organs, including the liver and heart. These vascular defects arise from altered hypoxia-inducible factor-1α (HIF-1α) stabilization, which fails to adequately induce VEGF under physiological conditions, highlighting AhR's necessity for proper endothelial and vessel formation during embryogenesis. AhR also contributes to liver zonation and hematopoiesis, processes essential for organ maturation and blood cell production. In the liver, AhR promotes polyploidization of s and influences zonal patterns, with centrilobular predominance of AhR activity supporting metabolic along the porto-central axis. AhR mice exhibit reduced liver size, disrupted , and delayed zonation, underscoring its role in establishing functional hepatic architecture. In hematopoiesis, AhR modulates (HSC) quiescence and ; AhR activation promotes HSC into myeloid lineages while suppressing self-renewal. Species-specific effects of AhR deficiency manifest in developmental anomalies, such as persistent fetal vascular structures in mice. AhR-null mice display portosystemic shunting due to failure of ductus venosus closure and abnormal renal vascularization, contrasting with phenotypes in other species like zebrafish, where AhR activation disrupts similar processes. Additionally, ocular defects including persistent hyaloid artery occur in AhR-deficient mice on certain genetic backgrounds, reflecting AhR's conserved yet context-dependent influence on tissue differentiation.

Immune and Metabolic Responses

The aryl hydrocarbon receptor (AhR) plays a pivotal role in modulating T-cell , particularly in promoting the development of regulatory T cells (Tregs) and T helper 17 (Th17) cells through interactions with endogenous ligands like . In tumor microenvironments, (IDO) catabolizes to , which binds AhR and drives Treg expansion while suppressing effector T cells, thereby fostering that supports tumor progression. Seminal studies have shown that AhR activation by skews naive CD4+ T cells toward FoxP3+ Tregs rather than Th17 cells, highlighting -specific effects on immune balance. Depending on the context, AhR can also promote Th17 , as demonstrated in early research where synthetic AhR agonists influenced the Treg/Th17 axis in autoimmune models. AhR further contributes to immune homeostasis by regulating barrier functions in the gut and skin, primarily through induction of interleukin-22 (IL-22), which enhances production of antimicrobial peptides. In the intestinal mucosa, microbiota-derived tryptophan metabolites activate AhR in innate lymphoid cells, leading to IL-22 secretion that promotes epithelial integrity and expression of peptides like regenerating islet-derived IIIγ (RegIIIγ), thereby defending against pathogens and maintaining barrier permeability. AhR signaling in the gut also modulates the gut-brain axis via microbial ligands, influencing neurological homeostasis and potentially linking to disorders like depression. Similarly, in the skin, AhR signaling supports epidermal barrier robustness by modulating keratinocyte differentiation and immune responses, with agonists like tapinarof reducing inflammation and bolstering antimicrobial defenses via IL-22 pathways. This IL-22-dependent mechanism underscores AhR's role in preventing dysbiosis and barrier disruption at mucosal sites. In metabolic , AhR governs and the expression of enzymes, such as the (CYP) family. AhR activation induces and related enzymes, facilitating the phase I metabolism of and endogenous substrates to maintain cellular balance and prevent toxicity. Regarding , AhR ligands repress genes involved in and biosynthesis, such as , thereby controlling formation and preventing in high-fat diets. These functions integrate AhR into broader metabolic regulation, linking environmental sensing to without direct overlap with inflammatory pathways like .

Toxicological Implications

Mechanism of Xenobiotic Toxicity

The aryl hydrocarbon receptor (AhR) mediates toxicity primarily through persistent activation by environmental pollutants such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), a potent exogenous that binds with high and resists metabolic degradation. This binding dissociates AhR from its cytosolic chaperones, enabling nuclear translocation and dimerization with ARNT to drive transcription via response elements (XREs) in target gene promoters. Unlike transient activation by endogenous or rapidly metabolized ligands, TCDD induces prolonged AhR occupancy on XREs, resulting in sustained overexpression of phase I and II detoxification enzymes like CYP1A1. This persistent transcriptional activity shifts cellular redox balance toward oxidative stress, as CYP1A1 uncoupling generates reactive oxygen species (ROS), including superoxide and hydroxyl radicals, which damage lipids, proteins, and DNA. AhR also upregulates NADPH oxidase, amplifying ROS production and overwhelming antioxidant defenses such as glutathione. In scenarios of chronic low-level exposure, this mechanism initially supports adaptive detoxification, but sustained activation exhausts cellular resources, promoting prooxidant effects that contribute to broader toxic outcomes. Dysregulation of AhR target genes under persistent activation disrupts normal cellular processes, notably inducing in developing tissues through ROS-mediated mitochondrial dysfunction and activation. For instance, in embryonic models, TCDD exposure elevates Bax/ ratios and release, leading to that impairs . In adult skin, this dysregulation manifests as , where AhR-driven ROS and production (e.g., IL-6, TNF-α) alter and hyperkeratinization. Toxicity exhibits a dose-dependent biphasic response: at low doses, AhR activation enhances metabolism via inducible CYPs, facilitating adaptive without significant harm. However, high doses overwhelm this system, as TCDD's persistence prevents ligand clearance, leading to unchecked XRE transcription and ROS accumulation. This switch is exacerbated by failure of the AhR repressor (AhRR), an XRE-inducible regulator that competes for ARNT ; under toxic overwhelm, AhRR lags or is insufficient, allowing prolonged AhR signaling and amplification of deleterious effects.

Associated Health Effects

Exposure to dioxins, such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), a potent aryl hydrocarbon receptor (AhR) , has been epidemiologically linked to increased cancer risk, including , in occupationally exposed cohorts. In a large industrial cohort with high TCDD exposure, incidence was elevated at the upper end of exposure levels, consistent with AhR-mediated carcinogenic mechanisms. Polymorphisms in the AhR modulate individual susceptibility to these effects, with certain variants associated with heightened sensitivity to dioxin-induced toxicity. AhR polymorphisms also contribute to from exposure, influencing outcomes such as and birthweight. For instance, genetic variations in the maternal AhR gene interact with TCDD exposure to affect fetal growth, as observed in the Seveso cohort where lower birthweights were linked to specific AhR alleles. These polymorphisms alter AhR signaling, leading to endocrine disruptions and reproductive abnormalities in exposed populations. Environmental epidemiology from the 1976 , involving a massive TCDD release, demonstrates long-term AhR-mediated immunotoxicity in exposed residents. Follow-up studies revealed persistent alterations in immune function, including suppressed humoral and cell-mediated responses attributable to AhR pathway dysregulation. These effects, observed decades post-exposure, underscore dioxin's role in chronic immunotoxic outcomes via sustained AhR activation.

Protein-Protein Interactions

Chaperone and Corepressor Interactions

The aryl hydrocarbon receptor (AhR) maintains its stability and proper folding in the through association with a multiprotein chaperone complex consisting of heat shock protein 90 (), the co-chaperone p23, and the immunophilin-like protein XAP2 (also known as Ara9 or AIP). This complex is essential for retaining the ligand-free AhR in the and preventing its premature degradation or aggregation. acts as the primary chaperone, binding to the AhR's ligand-binding domain to facilitate proper conformation, while p23 stabilizes the -AhR interaction and enhances chaperone activity. XAP2 further contributes by directly associating with and the AhR, promoting the assembly of this complex and inhibiting the receptor's ubiquitination, thereby protecting it from proteasomal degradation. Upon ligand binding, the chaperone complex dissociates, allowing AhR nuclear translocation, but post-activation, regulatory mechanisms ensure timely receptor turnover. The E3 ubiquitin ligase (C-terminus of Hsc70-interacting protein, also called STUB1) plays a critical role in this process by interacting with the -bound AhR and promoting its ation. CHIP remodels the mature AhR- complex, facilitating the attachment of chains to both the AhR and , which targets them for 26S proteasomal degradation. This ubiquitin-dependent degradation occurs rapidly after ligand-induced activation, typically within 1-2 hours, and is essential for terminating AhR signaling and preventing sustained transcriptional activity. In addition to stabilizing interactions, AhR engages corepressors to modulate its transcriptional output, particularly at canonical DNA binding sites. Corepressors such as (NCOR1, also known as N-CoR) and silencing mediator for retinoid and thyroid hormone receptors (SMRT, also known as NCOR2) interact with the AhR complex and recruit histone deacetylases (HDACs), including and HDAC3, to deacetylate s and condense . For instance, SMRT directly binds the liganded AhR/ARNT heterodimer, reducing its DNA-binding affinity and repressing in transactivation assays. Similarly, NCOR1 participates in these repressive complexes, enhancing HDAC activity. At non-canonical sites lacking xenobiotic response elements (XREs), such as promoter regions of (ER)-responsive genes, AhR tethers to other transcription factors like ER or to repress their mediated transcription, potentially involving HDAC recruitment. These interactions allow AhR to exert inhibitory effects on diverse pathways beyond direct XRE binding.

Coactivator and Dimerization Partners

The aryl hydrocarbon receptor (AhR) requires heterodimerization with the aryl hydrocarbon receptor nuclear translocator (ARNT) to bind DNA and initiate transcription of target genes, making ARNT an obligatory dimerization partner essential for AhR's canonical signaling pathway. Recent cryo-electron microscopy structures have revealed the atomic details of AhR-ARNT heterodimer formation and interfaces for coactivator binding. Upon ligand binding, the AhR translocates to the nucleus and forms this AhR-ARNT heterodimer, which recognizes xenobiotic response elements (XREs) in promoter regions to drive gene expression, such as cytochrome P450 1A1 (CYP1A1). Histone acetyltransferases like Tip60 and p300 serve as key coactivators that enhance AhR transcriptional activity by modifying structure. Tip60, acting through interactions with ARNT, facilitates events that support AhR/ARNT-mediated target , contributing to epigenetic regulation of responsive loci. Similarly, p300 acetylates ARNT and at AhR target promoters, promoting an open conformation that allows recruitment of the transcriptional machinery and boosts induction of genes like CYP1A1. SRC-1 (steroid receptor coactivator-1) and CBP/p300 further augment AhR function by enabling and enhancer . SRC-1 binds directly to the Q-rich of AhR, potentiating ligand-dependent transcription and facilitating histone modifications that decondense for efficient . CBP/p300, often in with SRC-1, acetylates H3 and H4 at enhancers, remodeling nucleosomes to enhance accessibility and sustain AhR-driven responses. AhR dimerization partners exhibit tissue-specific variations, reflecting context-dependent functions. In the liver, the canonical AhR-ARNT heterodimer predominates to mediate metabolism and . In contrast, immune cells such as Th17 lymphocytes and (ILCs) feature AhR-RORγt complexes, where signaling induces dimerization and nuclear translocation to promote IL-17A expression and inflammatory responses.

Therapeutic Potential

AhR Modulators and Drug Development

The development of pharmacological agents targeting the aryl hydrocarbon receptor (AhR) has focused on selective modulators to harness its therapeutic potential while minimizing off-target effects associated with full agonists like environmental toxins. Selective AhR modulators (SAhRMs) represent a key class of compounds that exhibit tissue- or cell-specific , allowing for nuanced regulation of AhR signaling pathways involved in and immunity. A prominent example of a SAhRM is , a topical AhR agonist approved by the FDA in May 2022 for the treatment of plaque in adults. acts as a , binding to AhR and promoting effects through downregulation of pro-inflammatory cytokines and enhancement of skin barrier function, without inducing the full spectrum of AhR activation seen with xenobiotics.31543-9/fulltext) This approval marks the first-in-class use of an AhR-targeted therapy for dermatological conditions, highlighting the feasibility of SAhRMs in clinical settings. In contrast, AhR antagonists are pursued to block pathological activation by toxic ligands. CH-223191, a synthetic ligand-selective antagonist, competitively inhibits the binding of halogenated aromatic hydrocarbons such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) to AhR, preventing nuclear translocation, DNA binding, and downstream toxic responses with IC50 values ranging from 0.2 μM (human) to 3.1 μM (rat). Natural compounds like sulforaphane, derived from cruciferous vegetables, serve as non-competitive antagonists, weakly agonizing AhR at low concentrations but potently inhibiting activation by agonists like benzopyrene, thereby reducing CYP1A1 induction and contributing to chemopreventive effects. Drug design strategies for AhR modulators increasingly rely on structure-based approaches, leveraging models and structures of the PAS-B —the primary ligand-binding pocket—to enhance specificity. The PAS-B pocket, characterized by a bipartite hydrophobic cavity (approximately 440–680 ų across species), accommodates diverse ligands through key interactions with residues like Tyr and Met/Ile, enabling rational optimization of modulators to avoid promiscuous binding while targeting therapeutic outcomes. Recent structural insights from and human AhR PAS-B domains have facilitated the design of compounds with improved selectivity, such as by mutating access paths to restrict access.

Clinical Applications and Research

Laquinimod, an aryl hydrocarbon receptor (AhR) , was investigated in a Phase II (NCT02284568) for primary progressive (PPMS), aiming to assess its efficacy in slowing disability progression through AhR-mediated immunomodulation. The trial, involving patients receiving 0.3 mg or 0.6 mg daily doses, demonstrated some effects via AhR activation in and reduced inflammation, but overall results were unsatisfactory, leading to discontinuation of development for MS in 2019. Despite the halt, findings from this and prior Phase III trials in relapsing-remitting MS validated AhR as a pathway for and immune regulation, informing subsequent drug designs targeting AhR for neurodegenerative and autoimmune conditions. In cancer immunotherapy, AhR modulation via the has emerged as a promising strategy, particularly through 1 (IDO1) inhibitors that reduce production and subsequent AhR activation, thereby alleviating tumor-induced . Preclinical and early clinical studies show that blocking the IDO1--AhR enhances T-cell responses and synergizes with checkpoint inhibitors like anti-PD-L1, improving outcomes in models of solid tumors such as and . Similarly, in (IBD), AhR agonists promote intestinal barrier integrity and regulatory T-cell differentiation, with several compounds derived from traditional medicines entering clinical trials for , demonstrating reduced inflammation and improved mucosal healing in Phase I/II studies. Post-2023 research has highlighted AhR's role in the microbiome-gut-brain axis, particularly in mitigating associated with conditions like and . A 2024 study elucidated how microbial-derived AhR ligands maintain gut and modulate systemic immune responses to prevent neuroinflammatory cascades, with age-related declines in these ligands exacerbating via . Phase III studies (ADORING 1 and 2) demonstrated significant efficacy of cream 1%, a non-steroidal AhR , achieving clear or almost clear skin (vIGA-AD success) in 36.4–45.4% of patients aged 2 years and older after 8 weeks, alongside improvements in pruritus and . These trials supported FDA approval of cream 1% on December 16, 2024, for in adults and children 2 years and older, confirming AhR agonism's safety and sustained response in pediatric and adult populations.

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