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Beta-3 adrenergic receptor

The β₃-adrenergic receptor (β₃-AR), encoded by the ADRB3 on human chromosome 8p11.23, is a (GPCR) consisting of 408 with seven transmembrane helices that mediate catecholamine signaling. Primarily activated by norepinephrine and epinephrine, it couples to Gs proteins to stimulate adenylate cyclase, elevating intracellular cyclic AMP () levels and activating (PKA), while also engaging Gi pathways to produce in certain tissues. Unlike β₁- and β₂-AR subtypes, β₃-AR lacks key sites, conferring resistance to rapid desensitization and allowing sustained signaling. Expressed predominantly in white and , urinary bladder, gallbladder, and to a lesser extent in the heart, , and , it regulates , , smooth muscle relaxation, and metabolic . Polymorphisms such as Trp64Arg in ADRB3 are associated with , , and cardiovascular risks, highlighting its role in energy balance and disease susceptibility. Structurally, β₃-AR features an extracellular N-terminal domain with glycosylation sites, three intracellular loops (including a distinctive ICL2), and a short C-terminal tail that facilitates interactions without typical desensitization motifs. Cryo-electron microscopy studies reveal a narrow orthosteric binding pocket and an exosite that enhance selectivity for agonists like , distinguishing it from β₁- and β₂-ARs through key residues such as Asp¹¹⁷ and Asn³³². Upon activation, downstream effects include PKA-mediated phosphorylation of targets that promote release in adipocytes and relaxation of in the , contributing to its anti-obesogenic and urinary functions. Physiologically, β₃-AR drives thermogenesis and white adipose lipolysis to increase energy expenditure, countering , while in the it induces relaxation to facilitate storage. In the cardiovascular system, it modulates inotropic effects in the myocardium and in certain vessels, potentially protecting against . Emerging roles include regulation of renal water reabsorption, uterine relaxation during , and even neuroprotection in the , underscoring its broad metabolic and organ-specific impacts. Clinically, selective β₃-AR agonists like are approved for treatment, offering efficacy with fewer side effects than antimuscarinics by promoting detrusor relaxation. Investigational applications target and through enhanced and insulin sensitivity, though challenges like species-specific ligand differences have slowed development. Additionally, β₃-AR overexpression in tumors such as and suggests antagonistic potential for anticancer therapies, with preclinical studies exploring immune modulation and inhibition.

Genetics and structure

Gene

The ADRB3 gene, which encodes the beta-3 adrenergic receptor, is located on the short arm of human chromosome 8 at position 8p11.23. It spans approximately 3.6 kb of genomic DNA and consists of two exons, with the coding sequence primarily in the second exon. The gene produces a mature mRNA that translates into a 408-amino acid protein, characteristic of the G protein-coupled receptor (GPCR) superfamily. A common single nucleotide polymorphism (SNP) in ADRB3 is the Trp64Arg variant (rs4994), resulting from a C-to-T transition at codon 64 in the first . This polymorphism has been associated with increased risk of , , and , particularly in homozygous carriers who exhibit greater and earlier disease onset. The minor Arg64 varies by population, reaching 0.16-0.18 in and groups but only about 0.06 in Caucasians. Functionally, the Arg64 substitution reduces the receptor's constitutive activity and enhances agonist-induced desensitization relative to the wild-type Trp64 form, potentially impairing lipolytic responses in . The ADRB3 gene demonstrates strong evolutionary conservation across mammals, reflecting its conserved role in metabolic regulation. For instance, the human ADRB3 protein shares approximately 81% amino acid sequence identity with its mouse ortholog (Adrb3), and similar high similarity with the rat counterpart.

Protein structure

The β3-adrenergic receptor (β3AR), encoded by the ADRB3 gene on chromosome 8, is a 408-amino-acid glycoprotein classified as a class A (rhodopsin-like) G-protein-coupled receptor (GPCR). Like other GPCRs in this family, it adopts a serpentine architecture embedded in the plasma membrane, featuring seven α-helical transmembrane domains (TM1–TM7), three extracellular loops (ECL1–ECL3), three intracellular loops (ICL1–ICL3), a glycosylated extracellular N-terminal domain, and an intracellular C-terminal tail. The N-terminus includes potential N-glycosylation sites that influence receptor trafficking and stability, while the C-terminus is subject to palmitoylation at sites such as Cys358 to anchor the receptor to the membrane. Central to its function are conserved structural motifs typical of class A GPCRs, including the DRY sequence (Asp^{3.49}Arg^{3.50}Tyr^{3.51}) at the cytoplasmic end of TM3, which facilitates G-protein coupling and receptor activation by stabilizing the outward movement of TM6. The NPxxY motif (Asn^{7.49}Pro^{7.50}xxTyr^{7.53}) in TM7 contributes to conformational changes during activation. The orthosteric ligand-binding pocket, which accommodates catecholamines such as norepinephrine and epinephrine, is formed primarily by residues in TM3–TM6 and ECL2, with key interactions involving the conserved ^{3.32} in TM3 for hydrogen bonding with the ligand's group. A conserved bridge between Cys^{3.25} in TM3 and Cys189 in ECL2 rigidifies the extracellular vestibule, essential for maintaining the binding site's integrity. High-resolution structural insights have been gained through (cryo-EM). The 3.2 Å structure of the agonist-bound active-state β3AR in complex with Gs and the selective ligand , reported in 2021, illustrates an elongated pose where extends perpendicularly into the pocket, forming hydrogen bonds with Asp117^{3.32}, Asn332^{7.39}, and Tyr326^{7.33}, while its tail occupies a subtype-specific exosite. This conformation reveals an inward tilt of TM5 and outward displacement of TM6, hallmarks of GPCR . Subsequent cryo-EM studies, such as those with solabegron, confirm similar active features but highlight variations in the extended that enhance selectivity over β1AR and β2AR. Inactive-state models derived from these works show a more constricted pocket with helical rearrangements that prevent access. Distinct from β1AR and β2AR, the β3AR possesses a shorter C-terminal (approximately residues) lacking multiple phosphorylation sites targeted by () and GPCR kinases, which reduces agonist-induced desensitization and . The third intracellular loop is also shorter and lacks analogous motifs, altering G-protein interaction dynamics. Ligand-binding differences arise from unique residues, such as Pro93^{2.60} in TM2 and the positioning of Trp333^{7.40} in TM7, which narrow the exosite and confer higher affinity for β3-selective agonists like compared to the broader pockets in β1AR and β2AR. These features underscore the β3AR's specialized role in tissues like adipose and .

Tissue distribution and expression

Primary tissues

The β3-adrenergic receptor (β3-AR) exhibits predominant expression in several key tissues, including white and , the , the of the , and the colon. In humans, β3-AR mRNA is notably abundant in the , with substantially lower levels observed in the colon, independent of expression. Protein expression has been confirmed in adipose depots, particularly deep subcutaneous and omental , as well as in the , where it constitutes approximately 97% of total β-adrenergic receptor mRNA. Transcriptomic data also indicate expression in reproductive tissues such as and . These sites highlight the receptor's primary roles in metabolic and regulation. Lower levels of β3-AR expression are detected in cardiovascular tissues such as the atria and ventricles, , liver, and immune cells including macrophages. , mRNA and protein are present at modest levels in human myocardium, while hepatic expression supports modulation. shows minimal to undetectable levels, and macrophages express functional β3-AR that influences inflammatory responses. These distributions were established through targeted analyses avoiding higher-expression sites. Species differences in β3-AR expression are pronounced, with displaying higher levels in both white and brown adipose tissue compared to s, where expression is more restricted to and prominent in the . In mice and rats, β3-AR is the dominant β-adrenergic subtype in adipocytes, facilitating robust thermogenic responses, whereas human adipose expression is comparatively subdued, emphasizing bladder predominance for therapeutic targeting. Detection of β3-AR expression typically involves mRNA quantification via (RT-PCR) for tissue-specific transcripts and protein assessment through or Western blotting for cellular localization and abundance. These methods have been instrumental in mapping baseline distributions across species and confirming low-level expressions in non-primary tissues.

Regulation of expression

The expression of the beta-3 adrenergic receptor (encoded by ADRB3) is tightly controlled at transcriptional and post-transcriptional levels, ensuring appropriate responsiveness in tissues such as . In adipocytes, (PPARγ) indirectly contributes to this control via regulation of CEBPα, influencing ADRB3 levels during differentiation and metabolic adaptation. , particularly (T3), integrate with β3-adrenergic signaling to amplify production and thermogenic responses, though they primarily enhance downstream effects rather than directly altering ADRB3 transcription. Post-transcriptional regulation involves microRNAs that target ADRB3 mRNA for degradation or translational repression, thereby affecting stability and protein levels. For instance, members of the let-7 family (e.g., let-7a, let-7c) bind to ADRB3 transcripts, reducing expression in models of . Additionally, microRNA-18a directly targets ADRB3, suppressing its expression in cardiac models, highlighting a broader role in stress-responsive tissues. Receptor desensitization and further modulate surface expression, particularly after prolonged exposure. Unlike β1- and β2-adrenergic receptors, β3 undergoes minimal acute desensitization due to fewer phosphorylation sites for or G-protein-coupled receptor kinases; however, extended activation (hours to days) recruits β-arrestin, promoting and reduced membrane localization via pathways involving EPAC/RAP2A/PI-PLC. This leads to homologous desensitization, while heterologous downregulation occurs through inflammatory signals like TNF-α, decreasing ADRB3 mRNA and protein. Developmental and environmental factors dynamically alter ADRB3 levels to support physiological demands. Cold exposure upregulates ADRB3 expression in subcutaneous , promoting beige adipocyte formation and through enhanced mitochondrial activity and . In contrast, induces downregulation via elevated TNF-α and inflammatory cytokines, contributing to catecholamine resistance and impaired metabolic responses in .

Physiological functions

Metabolic roles

The β3-adrenergic receptor (β3-AR) plays a central role in by mediating in adipocytes. Upon activation by catecholamines, β3-AR stimulates the and activation of hormone-sensitive (HSL) through cAMP-dependent , leading to the of triglycerides into free fatty acids and , which are subsequently released into circulation for energy utilization. This process is particularly prominent in , where it contributes to the mobilization of stored during or stress conditions. In (), β3-AR activation is essential for non-shivering , primarily through upregulation of 1 (). This receptor couples to Gs proteins to increase intracellular , promoting UCP1 expression and activity in the mitochondrial inner membrane, which dissipates the proton gradient as heat rather than ATP synthesis, thereby enhancing energy expenditure. Studies in humans and demonstrate that β3-AR agonists can directly stimulate BAT , supporting its role in adaptive and potential metabolic benefits. β3-AR also influences insulin sensitivity and , particularly by modulating in and hepatic glucose production. stimulation of β3-AR has been shown to improve insulin-mediated glucose disposal in , potentially through enhanced lipolysis-derived signals that augment insulin signaling pathways. In the liver, β3-AR activation may suppress , contributing to better glycemic control and anti-obesity effects in insulin-resistant states. Clinical trials with β3-AR like have reported improvements in insulin sensitivity among obese individuals, underscoring its therapeutic potential. Evidence from β3-AR knockout mice highlights its importance in preventing metabolic dysregulation. These mice exhibit reduced lipolytic responses in , leading to diminished fat oxidation and increased susceptibility to diet-induced , with greater accumulation compared to wild-type controls. Additionally, they display impaired thermogenic capacity in BAT under cold exposure, further promoting energy imbalance and .

Other physiological effects

The β3-adrenergic receptor (β3-AR) mediates relaxation of the detrusor in the urinary , thereby facilitating urine storage by increasing bladder capacity without significantly affecting voiding contractions. This effect is particularly prominent in human detrusor tissue, where β3-AR activation suppresses spontaneous contractile activity at low concentrations. In the cardiovascular system, β3-AR stimulation exerts cardioprotective effects, including negative inotropic responses that contribute to cardioprotection in models of and promotion of through pathways. These actions help modulate cardiac function during stress, reducing and oxidant stress in cardiomyocytes via . In the kidney, β3-AR activation promotes water reabsorption by enhancing accumulation in collecting duct principal cells, exerting an effect. In the , β3-AR mediates relaxation of myometrial , particularly during late , potentially contributing to the maintenance of uterine quiescence. In the , β3-AR activation provides neuroprotective effects, such as enhancing neurovascular coupling, reducing blood-brain barrier permeability, and mitigating , as demonstrated in aging models (as of 2025). β3-ARs expressed in the of the colon contribute to the of gastrointestinal by inhibiting cholinergically mediated contractions. activation prolongs gastrointestinal transit time, potentially through indirect signaling mechanisms that dampen activity. In immune cells, β3-ARs on macrophages play a potential immunomodulatory role by attenuating through effects and modulation of release, often dependent on (PPARγ) activation. This signaling influences inflammatory responses, promoting an in macrophages during immune challenges.

Signaling mechanism

G-protein coupling

The β3-adrenergic receptor (β3-AR) preferentially couples to the stimulatory G protein (Gs), facilitating the exchange of GDP for GTP on the Gαs subunit upon agonist activation, which initiates downstream signaling. This coupling is characteristic of the receptor's role in G-protein-coupled receptor (GPCR) family A, where the intracellular regions interact specifically with Gs heterotrimers. Agonist binding induces conformational changes in β3-AR, including an outward movement of transmembrane 6 (TM6), which opens the intracellular cavity to accommodate G-protein docking. Cryo-electron microscopy (cryo-EM) structures of the β3-AR-Gs complex reveal key interface residues, such as Arg135^{3.50} from the motif on the receptor's intracellular 2 forming a with Tyr391^{5.23} on Gαs, alongside hydrophobic interactions involving Gln234^{5.68} and Leu143 from intracellular 2 with Gαs pockets. These structural features stabilize the active conformation and promote efficient GDP-GTP exchange. In comparison to β1- and β2-adrenergic receptors, which exhibit stronger to inhibitory G proteins (/o) in various contexts, β3-AR demonstrates reduced /o overall but retains some -mediated interactions in specific tissues, such as adipocytes where it supports activation via pertussis toxin-sensitive pathways. also occurs in the myocardium, where it activates endothelial (eNOS) or neuronal (nNOS) to produce (NO), leading to cGMP elevation and G () activation for effects like and negative inotropy. This differential contributes to β3-AR's unique signaling profile, with Gs predominating in metabolic and contexts.

Downstream pathways

Upon activation of the β3-adrenergic receptor (β3-AR), the Gs protein stimulates adenylyl cyclase, leading to increased intracellular cyclic AMP (cAMP) levels, which in turn activates protein kinase A (PKA). PKA phosphorylates key targets such as hormone-sensitive lipase (HSL), promoting its translocation to lipid droplets and initiating lipolysis by hydrolyzing triglycerides into free fatty acids and glycerol in adipocytes. PKA also phosphorylates transcription factors like CREB (cAMP response element-binding protein), which drives gene expression, including upregulation of uncoupling protein 1 (UCP1) to enhance thermogenesis in brown adipose tissue. In addition to the canonical / pathway, β3-AR can engage β-arrestin-mediated signaling, which scaffolds and activates the MAPK/ERK cascade, contributing to non-canonical effects such as in certain tissues. with other adrenergic receptors modulates these pathways; for instance, α2-adrenergic receptor activation inhibits via Gαi/o proteins, thereby reducing cAMP accumulation and attenuating β3-AR-mediated responses.

Ligands and pharmacology

Agonists

The endogenous agonists of the β3-adrenergic receptor (β3-AR) are norepinephrine and epinephrine, which bind with lower affinity compared to their interactions with β1- and β2-AR subtypes. For norepinephrine, the pKi values range from 4.7 to 6.3 in β3-AR (corresponding to Ki values of approximately 0.5–20 μM), while for epinephrine, pKi values range from 3.9 to 4.7 ( ≈ 20–126 μM). These catecholamines activate β3-AR primarily through Gs-protein , leading to increased levels, though their reduced potency at β3-AR limits their selectivity in physiological contexts. Selective synthetic agonists have been developed to target β3-AR with higher affinity and specificity, addressing limitations of endogenous ligands and non-selective agents. , approved by the FDA in 2012 for (OAB), is a potent β3-AR with an of approximately 22 for cAMP accumulation in human β3-AR-transfected CHO cells and greater than 440-fold selectivity over β1- and β2-AR. Its binding affinity is reported as a pKi of 7.7 (Ki ≈ 20 nM) at human β3-AR, enabling targeted relaxation of detrusor without significant cardiovascular effects from β1/β2 activation. , approved in 2020 for OAB, exhibits even higher potency with an of 2.13 at β3-AR and substantial selectivity (>400-fold over β1/β2-AR), supporting its role in enhancing . In December 2024, its approval was expanded by the FDA for use in men with OAB symptoms receiving pharmacological therapy for . Solabegron, which has advanced to phase II trials for OAB and , functions as a selective β3-AR with pEC50 values of 8.4–8.7 in human assays, promoting relaxation through cAMP-mediated pathways. Experimental agonists, often used in preclinical research, include CL-316,243, a highly selective compound primarily effective in rodents for studying β3-AR functions in metabolism and thermogenesis. It displays an EC50 of 3 nM at β3-AR with over 10,000-fold selectivity over β1- and β2-AR, though its potency is lower in human cells (pKi 5.2–5.9, Ki ≈ 1–6 μM). Ritobegron, another investigational agonist, shows high affinity for human β3-AR and has been explored for OAB, though development was discontinued due to hepatotoxicity concerns. These compounds highlight ongoing efforts to refine β3-AR selectivity for therapeutic applications in metabolic disorders and urinary conditions.

Antagonists and inverse agonists

Antagonists of the β3-adrenergic receptor (β3-AR) competitively bind to the receptor to prevent activation by endogenous ligands like norepinephrine, thereby inhibiting downstream signaling such as accumulation and . Non-selective β-blockers, such as and , primarily target β1- and β2-ARs with high affinity (Ki values of approximately 1-2 for both subtypes) but exhibit lower affinity for the β3-AR (Ki ≈ 0.06–0.6 μM), rendering them less effective as β3-AR antagonists in most experimental contexts. Selective β3-AR antagonists have been developed primarily as research tools, with notable examples including SR 59230A and L-748328. SR 59230A acts as a potent at β3-ARs (pA2 ≈ 8-9 in models), effectively blocking agonist-induced responses like in , but it displays species-specific variability, often functioning as a at β3-ARs due to its ability to stimulate in certain cell lines. In contrast, L-748328 is a highly selective for the β3-AR, with high (pKi ≈ 8.3) and demonstrating over 1,000-fold selectivity over β1- and β2-ARs, allowing it to competitively inhibit agonist-mediated activation in cell models without affecting other β-subtypes. Inverse agonists for the β3-AR go beyond simple blockade by stabilizing the inactive receptor conformation, thereby suppressing constitutive receptor activity and reducing basal cAMP levels even in the absence of agonists. Other compounds, like SP-1e and SP-1g, have been identified as potent β3-AR inverse agonists with high selectivity, further demonstrating the potential for these ligands to modulate receptor tone in tissues expressing constitutive β3-AR activity. These antagonists and inverse agonists are mainly employed in preclinical research to delineate β3-AR-specific contributions to , particularly in models where blocking β3-AR signaling helps isolate its roles in lipolysis and energy expenditure without confounding effects from other β-subtypes. For instance, SR 59230A has been used in studies to confirm β3-AR mediation of agonist-induced fat oxidation, while L-748328 aids in evaluating human-relevant pathways. Clinical applications remain limited, as no β3-AR antagonists have been approved for therapeutic use, with research emphasis instead on agonists for metabolic disorders due to the receptor's beneficial activation in and insulin sensitivity.

Clinical significance

Therapeutic applications

The β3-adrenergic receptor mirabegron, approved at a dose of 50 mg once daily, treats (OAB) by selectively activating β3 receptors on detrusor , promoting relaxation during the bladder storage phase and increasing capacity. In randomized controlled trials (RCTs), mirabegron 50 mg reduced mean micturition frequency by approximately 1.5–2.0 episodes per 24 hours from baseline over 12 weeks, alongside decreases in urgency and incontinence episodes. Similarly, , approved at 75 mg once daily for OAB in adults and, as of December 2024, for OAB symptoms in adult males receiving pharmacological therapy for (BPH), exerts its effects through β3 receptor-mediated detrusor relaxation and has demonstrated significant reductions in daily micturitions, urgency episodes, and urge incontinence in phase 3 RCTs compared to . Investigational applications of β3 agonists for obesity have largely failed in human trials due to insufficient efficacy, though mirabegron is being explored for weight loss through brown adipose tissue activation as of 2024. For instance, the selective β3 agonist AJ-9677 (also known as TAK-677) showed no significant metabolic effects, such as energy expenditure increase or fat reduction, in obese individuals despite preclinical promise in animal models. In contrast, mirabegron is under investigation for heart failure, with phase 2 trials indicating potential benefits like improved cardiac index and reduced pulmonary vascular resistance after short-term use, and ongoing studies such as the 2024 SPHERE-HF trial exploring effects in HFpEF with pulmonary hypertension, though longer-term effects on left ventricular mass remain neutral. Combination therapies enhance OAB management for patients with inadequate response to monotherapy. 50 mg combined with antimuscarinics like 5 mg has shown superior reductions in micturition frequency, urgency, and incontinence episodes versus alone in RCTs, with additive improvements in voided volume. The safety profile of β3-selective agonists like and includes minimal cardiovascular risks, attributable to their high selectivity for β3 receptors over β1 and β2 subtypes, resulting in no significant changes in or in long-term studies. Common adverse events are mild, such as or urinary tract infections, occurring at rates comparable to .

Role in disease

The β3-adrenergic receptor (β3-AR) is implicated in several metabolic and physiological disorders through genetic variants and functional alterations that affect its signaling. In and , the Trp64Arg polymorphism (rs4994) in the ADRB3 gene encoding the β3-AR is associated with , , and earlier onset of non-insulin-dependent , potentially due to diminished receptor activity in . This variant reduces β3-AR-mediated and , impairing fat breakdown and contributing to and in susceptible individuals. In (OAB), the β3-AR modulates relaxation, and its altered expression correlates with disease symptoms, including detrusor overactivity during the storage phase. Studies indicate lower β3-AR protein levels in bladder biopsies from OAB patients compared to controls, suggesting that reduced receptor expression may impair relaxation mechanisms and exacerbate overactivity. Urinary β3-AR levels are also decreased in OAB, serving as a potential , with treatment using β3-AR agonists like increasing these levels and alleviating symptoms. Cardiovascular diseases involve both protective and risk-associated roles for the β3-AR. Activation of the β3-AR provides cardioprotection in by promoting production, which counters excessive β1- and β2-AR stimulation, reducing maladaptive remodeling and improving cardiac function through mild negative inotropic effects. However, polymorphisms such as Trp64Arg increase the risk of by altering adrenergic signaling and vascular reactivity, leading to elevated over time. The β3-AR also contributes to gallstone formation and colon disorders. The Arg64 variant of the β3-AR is linked to reduced motility, promoting bile stasis and cholesterol supersaturation that facilitate development. In colon disorders, particularly , β3-AR mRNA is upregulated in tumor tissues compared to normal colon, indicating a potential role in tumor progression through enhanced adrenergic signaling that supports and survival.

Protein interactions

Known interacting proteins

The β3-adrenergic receptor (β3-AR) primarily interacts with the stimulatory Gs, particularly its α subunit (Gsα), which facilitates canonical activation of and downstream production. This interaction has been structurally characterized in high-resolution cryo-electron microscopy studies of the agonist-bound β3-AR-Gs complex, confirming direct coupling in the active conformation. In specific cellular contexts, such as adipocytes, β3-AR also exhibits coupling to inhibitory G proteins of the Gi/o family, enabling alternative signaling pathways like activation, as demonstrated through pertussis toxin-sensitive functional assays. In adipocytes, β3-AR undergoes heterodimerization with other G protein-coupled receptors, including β1-AR, β2-AR, and α2A-AR, influencing lipolytic responses; these associations have been evidenced through co-immunoprecipitation and bioluminescence energy transfer (BRET) assays in co-expressing models. As an effector in the signaling cascade, β3-AR indirectly associates with isoforms AC5 and AC6 via Gsα, with proximity confirmed by fluorescence energy transfer () and co-immunoprecipitation in cardiac and s, highlighting tissue-specific compartmentalization.

Functional implications

The β3-adrenergic receptor (β3-AR) exhibits limited interaction with β-arrestins due to the absence of canonical sites for G protein-coupled receptor kinases (GRKs), resulting in negligible recruitment under stimulation. This lack of binding precludes β-arrestin-mediated receptor and trafficking to intracellular compartments, thereby conferring resistance to rapid desensitization and enabling sustained activation during prolonged exposure. In , this functional consequence supports continuous without attenuation, contrasting with the transient signaling of β1- and β2-ARs. Although β-arrestins scaffold ERK1/2 signaling in other β-AR subtypes, the β3-AR bypasses this by directly recruiting activated c-Src to its intracellular loops for ERK activation, which sustains MAPK pathways and modulates related to metabolic adaptation in chronic conditions. Interactions between the β3-AR and G proteins, primarily Gs heterotrimers, drive tissue-specific signaling biases through context-dependent downstream effectors. In adipocytes, Gs coupling activates to elevate , which in turn stimulates (PKA) to phosphorylate hormone-sensitive and perilipin, enhancing and release for energy expenditure. By contrast, in urinary detrusor , the same Gs- pathway promotes relaxation via PKA-mediated dephosphorylation of myosin light chain and potential cAMP-independent of large-conductance Ca²⁺-activated K⁺ channels, facilitating micturition . These differential outcomes underscore how G-protein engagement adapts β3-AR function to diverse physiological demands across tissues. Heterodimerization of the β3-AR with the β2-AR forms hetero-oligomers that modify affinity and signaling efficiency, creating a distinct β-adrenergic unit. In cells co-expressing both receptors, such as adipocytes, β2-β3 heterodimers display increased sensitivity to low-affinity agonists like norepinephrine and augmented Gs coupling, leading to amplified production and enhanced lipolytic responses compared to individual homodimers. This oligomerization mechanism optimizes adrenergic signaling in metabolically active tissues, potentially amplifying energy mobilization under physiological stress. Polymorphisms in the ADRB3 gene, notably the Trp64Arg variant, disrupt β3-AR protein interactions and contribute to disease susceptibility by impairing signaling fidelity. The Arg64 reduces G-protein coupling efficiency and lipolytic capacity in adipocytes, promoting fat accumulation and , with higher prevalence in certain populations correlating to elevated risks of and . Additionally, this polymorphism alters receptor desensitization dynamics, exacerbating symptoms through dysregulated detrusor relaxation. Such genetic variations highlight the pathophysiological impact of compromised interactions on metabolic and urological .

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