5-HT1B receptor
The 5-HT1B receptor, also known as HTR1B, is a G protein-coupled receptor (GPCR) subtype within the serotonin (5-HT) receptor family that binds the neurotransmitter serotonin to mediate inhibitory signaling in the brain and periphery.[1] Encoded by an intronless gene on human chromosome 6q14.1, it couples primarily to Gi/o proteins, inhibiting adenylyl cyclase activity and thereby reducing intracellular cyclic AMP (cAMP) levels to modulate neuronal excitability and presynaptic neurotransmitter release.[1][2] As both an autoreceptor on serotonergic neurons and a heteroreceptor on neurons releasing other transmitters, the 5-HT1B receptor exerts autoinhibitory control over serotonin release while also suppressing the release of dopamine, acetylcholine, glutamate, and GABA, influencing a range of physiological processes including mood regulation, aggression, anxiety, satiety, sleep, and vascular tone.[2] High expression is observed in the substantia nigra and globus pallidus; intermediate levels in the striatum, dorsal raphe nucleus, and cortex; with lower levels in the hippocampus, amygdala, and cerebellum. It is also present in cerebral arteries where it contributes to vasoconstriction.[2][3] Dysregulation of the 5-HT1B receptor has been implicated in neuropsychiatric disorders, including major depressive disorder (MDD), where positron emission tomography (PET) studies reveal reduced binding potential in limbic areas like the anterior cingulate cortex[2] and ventral striatum[4] of affected individuals, potentially linking to impaired serotonin signaling. It also plays roles in anxiety, obsessive-compulsive disorder, substance abuse, and aggression, with genetic variations associated with altered risk for these conditions, and emerging evidence implicates it in Alzheimer's disease with reduced receptor density in cortical regions.[2][5] Therapeutically, 5-HT1B receptor agonists such as triptans (e.g., sumatriptan) are established treatments for acute migraine by inducing cranial vasoconstriction and inhibiting trigeminal nerve activation, while emerging evidence supports its potential as an antidepressant target, with agonists and partial agonists like vortioxetine demonstrating efficacy in preclinical and clinical models by enhancing serotonergic transmission.[6][2] The receptor's structure, resolved by X-ray crystallography in complex with ergotamine, reveals a binding pocket that facilitates selective ligand design for improved therapies.[7]Molecular Biology
Gene and Expression
The HTR1B gene, which encodes the 5-HT1B receptor, is located on the long arm of human chromosome 6 at cytogenetic band 6q14.1, with genomic coordinates spanning 77,460,924 to 77,463,491 (GRCh38.p14 assembly), encompassing approximately 2.6 kb of DNA.[1] This intronless gene structure consists of a single exon, a feature common among some G-protein-coupled receptor genes, which simplifies its transcription but limits variability at the pre-mRNA level.[1][8] Transcription of HTR1B is regulated by its 5' upstream regulatory region, extending from approximately -1587 to +711 bp relative to the transcription start site (TSS at +1). Functional analyses have identified critical promoter segments, including -1587 to -1371 bp, -1149 to -894 bp, -603 to -316 bp, -39 to +130 bp, +130 to +341 bp, and notably +341 to +505 bp, the latter being essential for basal transcriptional activity in reporter assays.[9] Common polymorphisms within this region, such as rs4140535 (T allele enhancing expression) and rs1778258 (A allele reducing it), form haplotypes that modulate promoter strength, potentially influencing susceptibility to neuropsychiatric conditions through altered gene dosage.[9] Predicted binding sites for transcription factors like TBX2, E2F6, TFAP2C, and KLF3 in the promoter suggest combinatorial regulation, though tissue-specific enhancers remain to be fully characterized.[9] Basal mRNA expression of HTR1B exhibits tissue-specific patterns, as quantified in the GTEx database (v8 release) using median transcripts per million (TPM) across 54 non-diseased tissues from nearly 1,000 donors. Highest expression occurs in the testis (median TPM ≈ 12.5), followed by brain regions including the substantia nigra (≈ 8.2 TPM), putamen (basal ganglia; ≈ 6.9 TPM), caudate (basal ganglia; ≈ 5.4 TPM), and nucleus accumbens (basal ganglia; ≈ 4.1 TPM), reflecting its role in serotonergic signaling. Moderate levels are observed in arterial tissues such as tibial artery (≈ 3.2 TPM) and coronary artery (≈ 2.8 TPM), while expression is low or undetectable in whole blood (≈ 0.1 TPM) and most peripheral organs like liver and lung (< 1 TPM). These patterns indicate preferential neural and vascular expression, consistent with the receptor's autoinhibitory functions.[10] Given its single-exon architecture, HTR1B lacks confirmed alternative splicing variants, producing one primary transcript (ENST00000369947.5) that encodes the full-length 390-amino-acid protein. No significant post-transcriptional modifications, such as isoform-specific RNA editing or microRNA-mediated regulation unique to HTR1B, have been widely reported in human tissues, though general mRNA stability mechanisms may apply.[11][1]Protein Structure
The 5-HT1B receptor is a G-protein-coupled receptor (GPCR) belonging to the rhodopsin-like family (class A), comprising 390 amino acids in humans and encoded by the HTR1B gene.[12] Like other class A GPCRs, it exhibits a characteristic topology with seven α-helical transmembrane domains (TM1–TM7) spanning the plasma membrane, connected by three extracellular loops (ECL1–ECL3) and three intracellular loops (ICL1–ICL3). The protein also includes a relatively short N-terminal extracellular domain involved in ligand accessibility and a C-terminal intracellular tail that facilitates interactions with intracellular effectors.[13] This architecture positions the receptor to detect extracellular signals, such as serotonin, and transduce them across the membrane.[14] Key structural motifs conserved among class A GPCRs are prominent in the 5-HT1B receptor, including the Asp-Arg-Tyr (DRY) sequence at the C-terminus of TM3 extending into ICL2, which is essential for stabilizing the inactive state and enabling G-protein coupling upon activation. Additionally, a conserved disulfide bond between Cys3.25 in TM3 and a cysteine residue in ECL2 provides structural rigidity to the extracellular vestibule, preserving the integrity of the ligand-binding site. These features underscore the receptor's evolutionary adaptation for precise signal transduction.[13] High-resolution structures of the 5-HT1B receptor, obtained via X-ray crystallography and cryo-electron microscopy, have elucidated its atomic details. For instance, the crystal structure bound to the agonist ergotamine (PDB: 4IAR) reveals a compact helical bundle with the orthosteric binding pocket buried approximately 10 Å below the extracellular surface, where serotonin is predicted to form hydrogen bonds with Asp3.32 (Asp129) in TM3 and hydrophobic interactions with Phe6.51 and Phe6.52 in TM6, facilitating receptor activation. A cryo-EM structure with the agonist donitriptan and Go protein (PDB: 6G79) further highlights conformational changes, such as outward movement of TM6 by ~14 Å, upon G-protein engagement. These structures confirm the receptor's inactive and active conformations, aiding in understanding ligand-induced dynamics.[15] The 5-HT1B receptor exhibits a propensity for oligomerization, forming homodimers when expressed alone, as evidenced by co-immunoprecipitation and bioluminescence resonance energy transfer studies in heterologous systems. It also engages in heterodimerization with the closely related 5-HT1D receptor, potentially modulating ligand binding and trafficking, though the functional implications in native tissues remain under investigation. Such oligomeric states are common among GPCRs and may influence receptor maturation and signaling efficiency.[16][17]Tissue Distribution
Central Nervous System
The 5-HT1B receptor exhibits a distinct distribution within the central nervous system, with highest densities observed in the substantia nigra and globus pallidus, as demonstrated by autoradiographic studies in human postmortem tissue.[2] High mRNA expression is also noted in the dorsal raphe nucleus.[18] Intermediate levels are present in the striatum, particularly the caudate-putamen and higher in ventral regions, and the frontal cortex, while moderate expression occurs in the hippocampus and hypothalamus.[19][2] Lower levels are observed in the amygdala and cerebellum.[2] In vivo positron emission tomography (PET) imaging using radioligands such as [11C]AZ10419369 confirms this pattern, revealing high binding potential in the basal ganglia structures like the substantia nigra and globus pallidus, with lower but detectable binding in cortical regions, hippocampus, and hypothalamus.[20] These receptors are expressed both pre- and postsynaptically, functioning primarily as inhibitory G-protein-coupled receptors. Presynaptically, 5-HT1B receptors act as autoreceptors on serotonergic neuron terminals, where activation by serotonin inhibits further 5-HT release, thereby providing negative feedback control over serotonergic transmission.[2] As heteroreceptors, they are localized on terminals of non-serotonergic neurons, including dopaminergic terminals in the nucleus accumbens and striatum, where they suppress dopamine release, and glutamatergic terminals in regions such as the raphe nuclei and basal ganglia, reducing glutamate-mediated excitatory transmission.[21][22] In the basal ganglia, 5-HT1B receptors modulate key circuits involved in motor control by inhibiting GABA release from striatonigral terminals in the substantia nigra pars reticulata and regulating excitatory inputs from the subthalamic nucleus, which helps gate burst firing and facilitate smooth movement initiation.[23] Within the hippocampus, 5-HT1B activation influences mood regulation through bidirectional effects on emotional memory consolidation, with agonists impairing fear memory in wild-type mice but enhancing it in models with altered receptor signaling, potentially via interactions with adaptor proteins like p11.[24] Additionally, these receptors contribute to synaptic plasticity by modulating glutamate release in the dentate gyrus and CA1 regions, promoting phosphorylation of AMPA receptor subunits and supporting long-term potentiation underlying learning and mood stabilization.[24]Peripheral Tissues
The 5-HT1B receptor is prominently expressed in the smooth muscle of peripheral blood vessels, including coronary arteries and meningeal blood vessels, where it plays a key role in vascular tone regulation. In human coronary arteries, the receptor is localized to smooth muscle cells and mediates serotonin-induced vasoconstriction, as demonstrated by functional studies showing potent contractile responses to 5-HT1B agonists like sumatriptan.[25] This expression pattern contributes to the receptor's involvement in peripheral vascular reactivity, with mRNA and protein detection confirming its presence in arterial tissues. Similarly, in meningeal blood vessels such as the middle meningeal artery, 5-HT1B receptors drive vasoconstriction in response to serotonin and triptan agonists, exerting effects on cranial extracerebral vasculature that support antimigraine mechanisms through vessel constriction.[26] In the gastrointestinal tract, 5-HT1B receptors are expressed in smooth muscle layers and associated vasculature, influencing motility patterns. Activation of these receptors by 5-HT1B/1D agonists promotes prokinetic activity, enhancing contractile responses and transit in intestinal smooth muscle, which modulates gut motility as part of serotonin's broader regulatory role in the enteric system.[27] This function highlights the receptor's contribution to peripheral serotonin signaling in coordinating peristalsis and segmentation without overlapping central neural modulation. The 5-HT1B receptor exhibits moderate expression levels in several other peripheral tissues, including the spleen, lung, and bladder, contrasting with its more pronounced vascular localization. In the spleen, mRNA expression has been detected in rodent models, suggesting a role in immune-vascular interactions, though human data indicate lower abundance. Within the lung, the receptor is present on pulmonary arterial smooth muscle cells, where it facilitates vasoconstriction and cell proliferation in conditions like pulmonary hypertension, linking serotonin signaling to respiratory vascular homeostasis.[28] Moderate presence in the bladder smooth muscle implies involvement in serotonergic modulation of detrusor contractility, though specific functional studies remain limited. In contrast, expression is low in the liver and kidney, with minimal mRNA or protein detectable in these organs, limiting the receptor's direct influence on hepatic or renal serotonin-mediated processes.[29] Overall, these peripheral distributions enable the 5-HT1B receptor to participate in serotonin regulation beyond the central nervous system, such as fine-tuning vascular responses and enteric motility, while its sparse presence in metabolic organs like the liver and kidney underscores tissue-specific roles in peripheral physiology.Signaling Pathways and Function
Signal Transduction Mechanisms
The 5-HT1B receptor, a member of the G protein-coupled receptor superfamily, primarily couples to pertussis toxin-sensitive Gi/o proteins upon activation by serotonin or agonists.[30] This coupling inhibits adenylyl cyclase activity, resulting in decreased intracellular cyclic AMP (cAMP) levels and subsequent reduction in protein kinase A (PKA) signaling.[30] Unlike Gq-coupled receptors such as 5-HT2 subtypes, 5-HT1B activation does not elevate inositol trisphosphate (IP3) or diacylglycerol (DAG) levels, thereby avoiding phospholipase C-mediated pathways.[31] Activation of Gi/o proteins releases Gβγ subunits, which mediate several downstream effects. These subunits directly open G protein-gated inwardly rectifying potassium (GIRK) channels, promoting potassium efflux and membrane hyperpolarization.[32] Additionally, Gβγ inhibits voltage-gated calcium (Ca2+) channels, particularly N-type channels, reducing Ca2+ influx and neuronal excitability.[33] The receptor also stimulates mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase (ERK) pathways, with ERK1/2 phosphorylation requiring both Gαi/o signaling and β-arrestin recruitment; key phosphorylation sites include serines 256, 277, 279, and 291 in the receptor's third intracellular loop.[34] Desensitization of the 5-HT1B receptor occurs through phosphorylation by G protein-coupled receptor kinases (GRKs), followed by β-arrestin binding, which uncouples the receptor from G proteins and facilitates clathrin-independent, caveolin-1-dependent internalization.[35] The receptor interacts with the adaptor protein p11 (S100A10), which enhances its trafficking to the cell surface and increases functional responsiveness; reduced p11 expression diminishes surface receptor density and impairs antidepressant-like effects in models of depression.[36] Overall, these mechanisms allow the 5-HT1B receptor to modulate ion channels and second messengers in a manner that fine-tunes cellular responses without engaging IP3/DAG pathways.[30]Physiological Roles
The 5-HT1B receptor plays a critical role in regulating neurotransmitter release within the basal ganglia, particularly by acting as a presynaptic autoreceptor to inhibit serotonin release and as a heteroreceptor to modulate dopamine efflux. In the substantia nigra pars reticulata, activation of 5-HT1B receptors by serotonin released in response to dopamine signaling reduces GABA release from D1-medium spiny neuron terminals by approximately 75% at low frequencies (2 Hz), thereby filtering striatonigral synaptic activity to favor high-frequency transmission essential for motor control.[37] This modulation influences locomotion by enhancing action selection and reward processing, as disruptions in 5-HT1B-mediated dopamine-serotonin interactions in the nucleus accumbens shell amplify cocaine's rewarding effects and locomotor sensitization.[38] For instance, elevated 5-HT1B expression in accumbens neurons projecting to the ventral tegmental area potentiates stimulant-induced dopamine release, linking the receptor to reward-driven behaviors.[39] Recent studies as of 2025 have identified additional roles for the 5-HT1B receptor in the central nervous system. Serotonin and psychedelics like psilocybin activate 5-HT1B receptors on inputs from the anterior cingulate cortex to suppress activity in the claustrum, a brain region implicated in perception and consciousness. Furthermore, Htr1b is necessary for normal retinal function, as knockout mice exhibit impairments in visual processing.[40][41] In the peripheral vasculature, the 5-HT1B receptor mediates vasoconstriction triggered by serotonin release from activated platelets or during stress responses. Upon platelet activation by stimuli such as thrombin or shear stress, serotonin binds to 5-HT1B receptors on vascular smooth muscle cells, activating NADPH oxidase 1 (Nox1) via Src kinase to generate reactive oxygen species (ROS), which promote contraction and proliferation in pulmonary arteries.[42] This mechanism contributes to vascular remodeling, as evidenced by increased 5-HT1B expression in pulmonary arteries of patients with pulmonary arterial hypertension, where antagonists like SB216641 attenuate ROS production and hypertension in serotonin transporter-overexpressing mouse models.[42] Stress-induced serotonin elevation similarly engages 5-HT1B receptors to induce cranial and carotid vasoconstriction in humans and animal models, underscoring its role in maintaining vascular homeostasis. Additionally, in endothelial cells, 5-HT1B regulates amyloid beta-induced dysfunction of endothelial nitric oxide synthase (eNOS), suggesting a role in vascular aspects of Alzheimer's disease pathology.[43][44] The 5-HT1B receptor is integral to the modulation of aggression, anxiety, and social behavior, with knockout mouse models revealing distinct phenotypes that highlight its inhibitory functions. 5-HT1B receptor knockout mice exhibit heightened aggression, with nearly all pairs (6/6) displaying attacks compared to controls (1/6), an effect mediated by developmental forebrain heteroreceptors rather than adult expression.[45] These mice also show reduced anxiety-like behaviors in elevated plus-maze tests and increased impulsivity, responding with 80% more bursts in differential reinforcement of low-rate responding tasks, indicating impaired impulse control without altering non-aggressive social interactions.[45] Such phenotypes suggest 5-HT1B receptors normally dampen reactive emotional states, as agonists like CP 94,253 reduce offensive aggression in wild-type rodents while knockouts display enhanced reactivity to social instigation.[46] Through hypothalamic and mesolimbic pathways, the 5-HT1B receptor modulates feeding behavior and alcohol preference by integrating serotonin signaling with reward circuits. Activation of hypothalamic 5-HT1B receptors by agonists such as CP-94,253 suppresses food intake and promotes satiety without disrupting meal patterns, reflecting its role in appetite regulation.[47] In the mesolimbic system, 5-HT1B receptors in the nucleus accumbens core inhibit glutamate release onto dopaminergic neurons, reducing ethanol self-administration; for example, local infusion of agonist CGS12066B decreases alcohol intake by 40-50% in rats.[47] Conversely, overexpression in the accumbens shell elevates voluntary alcohol consumption, while knockout mice paradoxically show increased ethanol preference due to compensatory changes in dopamine sensitivity, linking the receptor to both inhibitory and facilitatory effects on reward-driven intake.[47] The 5-HT1B receptor contributes to neuroplasticity in the hippocampus, particularly by influencing long-term depression (LTD) and emotional memory consolidation, with implications for mood disorders. In hippocampal circuits, 5-HT1B activation via agonists like CP94253 modulates presynaptic glutamate release in the dentate gyrus and CA1 regions, altering AMPA receptor phosphorylation (e.g., GluR1 at Ser831/Ser845) to bidirectionally regulate LTD and memory retention; this effect reverses in p11-deficient models, where agonism enhances plasticity and corrects depression-like impairments.[24] Reduced 5-HT1B binding and p11 expression in postmortem hippocampal tissue from depressed individuals and suicide victims correlate with synaptic deficits, suggesting the receptor's role in maintaining plasticity for mood stability.[24] Overexpression of p11 in the hippocampus normalizes these responses, highlighting 5-HT1B-p11 interactions as a key mechanism in neuroplastic adaptations linked to affective regulation.[24]Pharmacology
Endogenous and Synthetic Ligands
The endogenous ligand for the 5-HT1B receptor is serotonin (5-hydroxytryptamine, 5-HT), which acts as a full agonist with high binding affinity, typically in the low nanomolar range (pKi 7.4–9.0, equivalent to Ki ≈ 1–40 nM for the human receptor).[13] Among synthetic agonists, selective compounds such as sumatriptan exhibit potent affinity for the 5-HT1B receptor (pKi 6.5–8.1, Ki ≈ 8–800 nM), functioning as partial agonists and demonstrating selectivity over other serotonin receptor subtypes.[13] Similarly, zolmitriptan binds with comparable potency (pKi ≈ 7.7, Ki ≈ 20 nM) and also acts as a partial agonist.[13] Non-selective agonists like ergotamine show even higher affinity (pKi 8.0–9.2, Ki ≈ 0.6–10 nM) across multiple 5-HT receptor subtypes, including 5-HT1B, and serve as full agonists.[13] Full agonists such as CP-94253 (a close analog of CP-94269) display strong binding (pKi 8.7, Ki ≈ 2 nM) and are used in research to probe receptor function.[13] Antagonists targeting the 5-HT1B receptor include selective compounds like SB-216641, which binds with high potency (pKi 9.0, Ki ≈ 1 nM) and acts as a partial agonist at higher concentrations, aiding in dissecting receptor signaling.[13] Non-selective antagonists such as methiothepin exhibit moderate to high affinity (pKi 7.1–8.5, Ki ≈ 3–80 nM) and function as inverse agonists, reducing constitutive receptor activity.[13] GR-127935 serves as a potent antagonist (pKi 9.2, Ki ≈ 0.6 nM) with inverse agonist properties in certain assays (pKi 9.0–9.8).[13] Allosteric modulators of the 5-HT1B receptor are less well-characterized, but 5-HT-moduline acts as a negative allosteric modulator with high potency (pIC50 11.9), selectively inhibiting serotonin binding without competing at the orthosteric site.[13] The orthosteric binding pocket of the 5-HT1B receptor is located within the transmembrane helices, primarily involving residues from TM3, TM5, and TM6, as revealed by crystal structures with agonists like ergotamine (PDB: 4IAR).[13] A key interaction is the ionic bond between the receptor's Asp3.32 (Asp129 in TM3) and the positively charged amine group of serotonin or synthetic ligands, which anchors the tryptamine core common to many agonists.[48] Additional hydrophobic contacts with residues in TM5 and TM6 stabilize the ligand, contributing to selectivity.[49] Structure-activity relationship (SAR) studies for triptans, such as sumatriptan and zolmitriptan, highlight that their tryptamine-like scaffold with N,N-dimethyl substitutions on the ethylamine side chain and sulfonamide or oxazolidinone groups at the 5-position of the indole ring enhance affinity and selectivity for 5-HT1B over other subtypes like 5-HT2B.[50] Modifications at the 5-position, including alkyl or polar substituents, increase agonism potency by improving interactions within the extended binding pocket, as seen in crystal structures.[51] These insights inform future drug design, emphasizing rigid conformations and targeted substitutions to optimize therapeutic profiles while minimizing off-target effects at cardiovascular 5-HT1B sites.[52]| Ligand Type | Example | Binding Affinity (Human 5-HT1B, Ki approx.) | Activity |
|---|---|---|---|
| Endogenous | Serotonin | ~4–40 nM | Full agonist |
| Selective Agonist | Sumatriptan | ~10 nM | Partial agonist |
| Selective Agonist | Zolmitriptan | ~20 nM | Partial agonist |
| Non-selective Agonist | Ergotamine | ~1–10 nM | Full agonist |
| Partial Agonist | CP-94253 | ~2 nM | Full agonist |
| Selective Antagonist | SB-216641 | ~1 nM | Partial agonist/antagonist |
| Non-selective Antagonist | Methiothepin | ~10–30 nM | Inverse agonist |
| Antagonist/Inverse | GR-127935 | ~0.6 nM | Antagonist/inverse agonist |
| Allosteric Modulator | 5-HT-moduline | pIC50 11.9 | Negative modulator |