Gene:

ADRB2

adrenergic, beta-2-, receptor, surface

Overview

Details

Introduction

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The beta-2-adrenergic receptor (beta2-AR) is a member of the G-protein-coupled adrenergic receptor family with seven transmembrane segments. Similar to other members of this receptor family, beta2-AR specifically binds and is activated by the endogenous class of ligands known as catecholamines, and epinephrine in particular. The gene encoding this receptor, ADRB2, was cloned by Kobilka et al in 1987 and is localized to chromosome 5q31-q32, a region that has been linked with asthma and asthma related phenotypes [PMID: 3025863,7666875]. ADRB2 consists of a single exon of 2015 nucleotides which encodes a 413 amino acid protein. This review highlights the genetic polymorphisms in ADRB2 and the pivotal role of beta2-AR in the regulation of the cardiac, pulmonary, vascular, endocrine and central nervous systems.

ADRB2 is abundantly expressed in bronchial smooth muscle cells and activation of the resulting receptor leads to bronchodilation. In addition, this gene is expressed in cardiac myocytes and vascular smooth muscle cells. Activation of beta2-AR in these cells causes an increase in the rate and force of heart contractions. Intracellular signaling upon beta2-AR activation is largely affected through a trimer of G proteins coupled to adenylate cyclase, to produce cyclic adenosine monophosphate (cAMP). This, in turn, activates protein kinase A, leading to the phosphorylation and downregulation of proteins including beta2-AR itself (please refer to PharmGKB Beta-agonist and Beta-blocker Pathway for further details.

Beta2-AR is the target of clinically important drugs for asthma and cardiovascular conditions including hypertension and congestive heart failure (CHF). Beta-receptor agonists (e.g. albuterol, salmeterol) and antagonists (e.g. such as carvedilol and propranolol) are among the mostly commonly prescribed medications in the treatment of asthma and cardiovascular disease, respectively. While some beta-blockers are "selective" for the beta1-AR (e.g. metoprolol and atenolol), these also antagonize the beta2-AR at higher concentrations. A number of genetic polymorphisms in the ADRB2 gene have been described that affect gene expression, the function of the resulting receptor, and response to beta2-agonists.

ADRB2 variants:
The ADRB2 gene has been resequenced in multiple populations and more than 80 polymorphisms has been identified, of which 45 single nucleotide polymorphisms (SNPs) and 2 insertion/deletion polymorphisms have been validated in more than one study [PMID: 16931635]. Two of these non-synonomous SNPs code for amino acid changes at positions 16 (arginine to glycine (Arg16Gly); rs1042713) and 27 (glutamic acid to glutamine (Glu27Gln); rs1042714), are common with minor allele frequencies (MAF) between 40-50% and have been well characterized in asthma pharmacogenetics [PMID: 8383511]. In vitro studies demonstrated that the Gly16 isoform enhanced the agonist-stimulated downregulation of beta2-AR, while the Glu27 variant did not regulate the expression of this receptor [PMID: 7915137,7598936]. In addition to these common polymorphisms, other less common, non-synonymous coding variants have also been reported in the ADRB2 gene. For example, the SNP rs1800888 encodes a Threonine to Isoleucine substitution at amino acid position 164 (Thr164Ile) and occurs with a MAF of 1-3%. The Ile164 isoform is three-to-four times less responsive to agonist induced stimulation than carriers of the wildtype Thr164 [PMID: 7901205,19422376]. Another rare, nonsynonymous variant resulting in a Valine to Methionine change at amino acid position 34 (Val34Met) in beta2-AR has a MAF <1% [PMID: 16142389].

In vivo studies of the genetic variants in ADRB2 suggest that these are not likely to be disease causing variants but possibly serve as predictive markers for responsiveness to both agonists and antagonists. Moreover, three meta-analyses of the two common non-synonymous SNPs in ADRB2 have concluded that these polymorphisms are not associated with the diagnosis of asthma [PMID: 15153795,15867853,15987731]. However, homozygotes of Arg16 treated with regular short acting beta-agonist (SABA) therapy tend to experience more adverse effects [PMID: 18303970]. Furthermore, among the patients prescribed beta-blocker therapy after an acute coronary syndrome, those homozygous for both Arg16 and Gln27 were at higher risk for death in 3 years (3-year mortality rate of 20%) compared to the other diplotypes (3-year mortality rate of 6-11%) [PMID: 16189366]. Congestive heart failure patients with the Ile164 variant were at higher risk for death or heart transplantation in 1 year (event rate 76%) compared to those homozygous for Thr164 while others did not observe this finding [PMID: 9788966,18068431].

Common ADRB2 haplotypes were not associated with adverse clinical outcome (all cause mortality, non-fatal MI and non-fatal stroke) in patients with coronary artery diseases who were treated with either beta-blocker-based or calcium channel blocker-based strategy [PMID: 18615004].None of the major ADRB2 genotypes or haplotypes was associated with the increased risk of MI or ischemic stroke in patients with pharmacologically treated hypertension. In addition, none of the genetic variants interacted with beta blocker use [PMID: 18219297]. None of the major ADRB2 genotypes (Arg16Gly and Glu27Gln) or haplotypes (Gly16Glu27, Arg16Gln27 and Gly16Gln27) was associated with the increased risk of sudden cardiac death and ventricular arrhythmias in patients with coronary artery disease [PMID: 18534365]. After receiving percutaneous coronary intervention, patients carrying Ile164 variant were 3.7 times more like to have cardiac death and 4.1 times more likely to have a major cardiac adverse event (cardiac death, acute MI, new PCI, CABG, and CHF) than those homozygous for Thr164 [PMID: 18940527].

Studies have produced conflicting results as to the association of the Arg16Gln27 haplotype with the risk of death or cardiac transplantation in heart failure patients. While one study reported patients carrying two copies of the haplotype had a 91% increased risk of the adverse outcomes compared with those who did not carry the haplotype, others did not observe the association [PMID: 17223428, 18702968]. The differences may be explained in part by the percent of patients treated with beta-blockers.

Conclusion:
Variants in the ADRB2 gene encoding beta2-AR have been correlated with variable response to drugs for asthma and cardiovascular medications as well as disease risks such as type 2 diabetes, obesity and hypertension. However, the directions of these correlations differ across studies and remain to be replicated in larger studies. A meta-analysis by Contopoulos-Ioannidis et al. reported that most associations between the two common polymorphisms in ADRB2 and asthma drug response and other asthma related phenotypes are statistically insignificant due to small sample sizes and less than 2% of the associations were replicated by two or more groups [PMID: 17001289]. In addition, correlations between these variants and beta2-agonists may be specific to short-acting beta2-agonists, and not affect response to long-acting drugs. Pharmacogenetic correlations may also be affected by the interval of drug treatment (regular use or use as needed) and interactions with other medications. Furthermore, these associations may also be specific to certain ethnicities and subject to gender effects. Cagliani et al described ethnicity-specific and sex-based haplotype distributions of the ADRB2 variants [PMID: 19576569]. Similar finding were reported in a meta-analysis by Jalba et al, which resulted in differences in association across populations [PMID: 19186333]. Moreover, the relative fitness associated with these haplotypes varies under the influence of epistasis and imprinting. Experiment techniques that can directly access the functional importance of beta-adrenoceptor polymorphisms on ligand-induced conformation changes (eg. Fluorescence resonance energy transfer (FRET)) will also help clarify the discrepancies with respect to the role of these polymorphisms in disease susceptibilities and therapeutic responses [PMID: 19272658].

In-Depth Annotations ()

1. rs1042713 at chr5:148186633 in ADRB2
   This variant has been studied in terms of asthma and its drug response and in terms of heart disease and vascular phenotypes and their drug responses.

   Variant Name:

   ADRB2:16Arg>Gly

   Related Diseases:

   Asthma, Heart Diseases

   Evidence:

   http://www.pharmgkb.org/.../variant.jsp
   

2. rs1042714 at chr5:148186666 in ADRB2
   This variant has been studied in terms of asthma and its drug response and in terms of heart disease and vascular phenotypes and their drug responses.

   Variant Name:

   ADRB2:27Glu>Gln

   Related Diseases:

   Asthma, Heart Diseases

   Evidence:

   http://www.pharmgkb.org/.../variant.jsp
   

3. rs1800888 at chr5:148187078 in ADRB2
   Congestive heart failure patients with Ile164 variant were at higher risk for death or heart transplantation in 1 year (event rate 76%) compared to those homozygous for Thr164 while others did not observe this finding. After receiving percutaneous coronary intervention, patients carrying Ile164 variant were 3.7 times more like to have cardiac death and 4.1 times more likely to have a major cardiac adverse event (cardiac death, acute MI, new PCI, CABG, and CHF) than those homozygous for Thr164.

   Variant Name:

   ADRB2: 164Thr>Ile; Thr164Ile; 491T>C; Ile164

   Related Diseases:

   Cardiomyopathies, Death, Heart Failure, Myocardial Infarction

   Evidence:

   http://www.pharmgkb.org/.../variant.jsp#ImportantVariantInformationforADRB2-164
   

Curated Annotations ()

1. rs1042711 at chr5:148186541 in ADRB2
   This variant is a noncoding SNP within 5' UTR of ADRB2, in amino acid residue 19 of the 19 amino acid beta upstream peptide (BUP) affecting ADRB2 expression at the translational level. Arg-19 allele was associated with lower receptor expression.

   Variant Name:

   ADRB2: Arg-19Cys; T-47C

   Evidence:

   PMID:9835617
   

2. rs1042713 at chr5:148186633 in ADRB2
   None of the ADRB2 haplotypes tested that contained this SNP were associated with differential primary outcome (i.e., the first incidence of death, nonfatal myocardial infarction, or nonfatal stroke) in hypertensive patients with coronary artery disease.

   Variant Name:

   ADRB2:Gly16Arg (46G>A)

   Related Drugs:

   atenolol, verapamil

   Related Diseases:

   Death

   Evidence:

   PMID:18615004
   

3. rs1042713 at chr5:148186633 in ADRB2
   The ADRB2:Arg16Gly variant was not associated with asthma exacerbation in patients treated with inhaled corticosteroids plus longacting beta agonists.

   Variant Name:

   ADRB2:Arg16Gly

   Related Drugs:

   budesonide, fluticasone propionate, formoterol, salmeterol

   Related Diseases:

   Asthma

   Evidence:

   PMID:18156033
   

4. rs1042713 at chr5:148186633 in ADRB2
   Relative to ADRB2:16Gly/Gly patients with asthma, ADRB2:16Arg/Arg patients with asthma may have an impaired therapeutic response to salmeterol in either the absence or presence of concurrent inhaled corticosteroid use.

   Variant Name:

   ADRB2:Arg16Gly

   Related Drugs:

   salmeterol

   Related Diseases:

   Asthma

   Evidence:

   PMID:16322642
   

5. rs1042713 at chr5:148186633 in ADRB2
   Subjects who are homozygous for Arg16 and who are on regular albuterol treatment reported to have lower morning peak flows compared with those who were not on regular albuterol treatment, suggesting that regular albuterol therapy may not be approporiate for Arg16 homozygous sugjects

   Variant Name:

   ADRB2: Gly16Arg; 46G>A; Arg16

   Related Drugs:

   salbutamol

   Related Diseases:

   Asthma

   Evidence:

   PMID:15500895
   

6. rs1042713 at chr5:148186633 in ADRB2
   Gly16 receptor had an enhanced agonist-promoted downregulation relative to Arg16 in in vitro studies using chinese hamster fibroblasts with expressed ADRB2.

   Variant Name:

   ADRB2: Gly16Arg; 46G>A

   Evidence:

   PMID:7915137
   

7. rs1042713 at chr5:148186633 in ADRB2
   In healthy subjects, the Arg16 variant was associated with enhanced isoproterenol-mediated desensitization of the vasculature and enhanced isoproterenol induced-venodilation, suggesting that it maybe important determinant of the vascular response to stress.

   Variant Name:

   ADRB2: Gly16Arg; 46G>A

   Evidence:

   PMID:11586955
   

8. rs1042714 at chr5:148186666 in ADRB2
   None of the ADRB2 haplotypes tested that contained this SNP were associated with differential primary outcome (i.e., the first incidence of death, nonfatal myocardial infarction, or nonfatal stroke) in hypertensive patients with coronary artery disease.

   Variant Name:

   ADRB2:Gln27Glu; ADRB2:79C>G

   Related Drugs:

   atenolol, verapamil

   Related Diseases:

   Death, Myocardial Infarction, Stroke

   Evidence:

   PMID:18615004
   

9. rs1042714 at chr5:148186666 in ADRB2
   Three recent meta-analyses have shown that the Gln27Glu and Gly16Arg polymorphisms are not associated with asthma.

   Variant Name:

   ADRB2: Gln27Glu; 318C>G

   Related Diseases:

   Asthma

   Evidence:

   PMID:15153795
   PMID:15867853
   PMID:15987731
   

10. rs1042714 at chr5:148186666 in ADRB2
    Heart failure patients homozygous for Gln27 were less likely to have improved left ventricular ejection fraction after carvedilol treatment compared to Glu27 carriers. However, in another study of heart failure patients, Gln27Glu polymorphism was not associated with the improvement of left ventricular ejection fraction or decrease in heart rate to a beta blocker in stable congestive heart failure.

    Variant Name:

    ADRB2: Gln27Glu; 318C>G ; Gln27

    Related Drugs:

    carvedilol

    Related Diseases:

    Heart Failure

    Evidence:

    PMID:12835612
    PMID:15861037
    

11. rs1800888 at chr5:148187078 in ADRB2
    Receptors containing Ile164 variant showed a substantial decrease in basal and epinephrine-stimulated adenylyl cyclase activities due to defective coupling of the receptor to the stimulatory G protein Gs, and impaired agonist-promoted sequestration. Ile164 also displayed a lower binding affinity for epinephrine as compared with the wild-type ADRB2.

    Variant Name:

    ADRB2: 164Thr>Ile; Thr164Ile; 491T>C; Ile164

    Evidence:

    PMID:7901205
    

12. rs1800888 at chr5:148187078 in ADRB2
    In vivo studies found that ADRB2 mediated increase in heart rate and contractibility is blunted in subject carrying one allele of Ile164.

    Variant Name:

    ADRB2: 164Thr>Ile; Thr164Ile; 491T>C; Ile164

    Evidence:

    PMID:11222464
    

13. rs1042718 at chr5:148187110 in ADRB2
    None of the ADRB2 haplotypes tested that contained this SNP were associated with differential primary outcome (i.e., the first incidence of death, nonfatal myocardial infarction, or nonfatal stroke) in hypertensive patients with coronary artery disease.

    Variant Name:

    ADRB2:Arg175Arg (523C>A)

    Related Drugs:

    atenolol, verapamil

    Related Diseases:

    Death

    Evidence:

    PMID:18615004
    

Non-Curated Information

A list of non-curated publications that mention this gene along with other genes is available.

PharmGKB Curated Pathways

• Antiarrhythmic Drug Pathways

BioCarta Pathways†

• corticosteroids and cardioprotection - (BioCarta via Pathway Interaction Database)
• cystic fibrosis transmembrane conductance regulator (cftr) and beta 2 adrenergic receptor (b2ar) pathway - (BioCarta via Pathway Interaction Database)
• phospholipase c-epsilon pathway - (BioCarta via Pathway Interaction Database)

PID Pathways†

• Arf6 signaling events - (Pathway Interaction Database NCI-Nature Curated)
• Arf6 signaling events - (Pathway Interaction Database NCI-Nature Curated)
• Arf6 trafficking events - (Pathway Interaction Database NCI-Nature Curated)

Curated Information

The following drugs are in curated knowledge about this gene.

	Drug Class	Relationship	Evidence
	antiarrhythmics, class i and iii	PD	Pathways
	Beta Blocking Agents	CO PD    FA GN	Publications
	Beta blocking agents, selective	CO          GN	Publications
	glucocorticoids	GN	Publications
	selective beta-2-adrenoreceptor agonists	CO PD       GN	Publications
	Selective beta-2-adrenoreceptor agonists	CO          GN	Publications
	xenobiotics	GN	Publications

	Drug	Relationship	Evidence
	amiodarone	PD	Pathways
	arsenic trioxide	PD	Pathways
	atenolol	CO PD    FA GN	Publications, Variants
	budesonide	CO          GN	Publications, Variants
	carvedilol	CO PD       GN	Publications, Variants
	cisapride	PD	Pathways
	disopyramide	PD	Pathways
	dobutamine	CO PD       GN	Publications
	dofetilide	PD	Pathways
	droperidol	PD	Pathways
	enalapril	CO PD    FA GN	Publications
	flecainide	PD	Pathways
	fluticasone propionate	CO          GN	Publications, Variants
	formoterol	CO       FA GN	Publications, Variants
	halofantrine	PD	Pathways
	haloperidol	PD	Pathways
	hexoprenaline	CO          GN	Publications
	ibutilide	PD	Pathways
	isoproterenol	PD    FA GN	Publications
	lidocaine	PD	Pathways
	mesoridazine	PD	Pathways
	methadone	PD	Pathways
	mexiletine	PD	Pathways
	morphine	FA GN	Publications
	orciprenaline	FA GN	Publications
	pentamidine	PD	Pathways
	pimozide	PD	Pathways
	procainamide	PD	Pathways
	propafenone	PD	Pathways
	propranolol	GN	Publications
	quinidine	PD	Pathways
	ritodrine	GN	Publications
	salbutamol	CO PD PK FA GN	Publications, Variants
	salmeterol	CO PD    FA GN	Publications, Variants
	sotalol	PD	Pathways
	sparfloxacin	PD	Pathways
	terbutaline	PD    FA GN	Publications
	thioridazine	PD	Pathways
	tocainide	PD	Pathways
	verapamil	CO          GN	Publications, Variants
	warfarin	CO          GN	Publications

Non-Curated Information

A list of non-curated publications that mention this gene along with other drugs is available.

Curated Information

The following diseases are in curated knowledge about this gene.

	Disease	Relationship	Evidence
	Acquired Long QT Syndrome (aLQTS)	GN	Publications
	Angina Pectoris	PD       GN	Publications
	Arrhythmias, Cardiac	CO          GN	Publications
	Asthma	CO PD PK FA GN	Publications, Variants
	Atrial Fibrillation	CO          GN	Publications
	Brugada syndrome	CO          GN	Publications
	Cardiomyopathies		Variants
	Cardiomyopathy, Dilated	CO PD       GN	Publications
	Cardiomyopathy, Hypertrophic	CO          GN	Publications
	Cardiovascular Diseases	PD       GN	Publications
	Coronary Artery Disease	CO          GN	Publications
	Coronary Disease	CO PD       GN	Publications
	Cystic Fibrosis	PD	Publications
	Death		Variants
	Death, Sudden, Cardiac	CO          GN	Publications
	Diabetes Mellitus, Type 1	PD       GN	Publications
	Essential hypertension	PD       GN	Publications
	Heart Diseases	CO          GN	Publications, Variants
	Heart Failure	CO       FA GN	Publications, Variants
	Hyperalgesia	FA GN	Publications
	Hypertension	CO PD    FA GN	Publications
	Long QT Syndrome	CO          GN	Publications
	Lung Neoplasms	CO          GN	Publications
	Myocardial Infarction	CO          GN	Publications, Variants
	Obesity	GN	Publications
	Premature Birth	CO          GN	Publications
	Stroke		Variants
	Sudden Infant Death	CO          GN	Publications
	Thromboembolism	CO          GN	Publications
	Torsades de Pointes	CO          GN	Publications
	Ventricular Fibrillation	CO          GN	Publications

Non-Curated Information

A list of non-curated publications that mention this gene along with other diseases is available.

Curated Phenotype Datasets

These datasets are sorted alphabetically by title.

1. ADRB2 association with cardiovascular disease

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   Submitted by Daniel T. O'Connor, MD involving ADRB2, and Cardiovascular Diseases
2. Blood pressure measurements

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   • PD

   Submitted by Daniel T. O'Connor, MD involving ADRB2, acetylcholine, isoproterenol, NG-monomethyl-l-arginine, phenylephrine, and Cardiovascular Diseases
3. Blood pressure measurements, group 2

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   Submitted by Daniel T. O'Connor, MD involving ADRB2, and Cardiovascular Diseases
4. Bronchodilator response to beta agonist in asthmatics

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   • PD

   Submitted by Richard Judson, PhD involving ADRB2, salbutamol, and Asthma
5. Cold Pressor Test (CPT) measurements of twins

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   Submitted by Daniel T. O'Connor, MD involving ADRB1, ADRB2 and ADRB3
6. Drug-Induced Long QT Intervals

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   • PD

   Submitted by Dan Roden, MD involving ADRB1, ADRB2, KCNE1, KCNE2, KCNH2, KCNQ1, SCN5A, almokalant, amiodarone, amitriptyline, bretylium, bupivacaine, cisapride, disopyramide, dofetilide, encainide, fluconazole, haloperidol, hydroquinidine, isoflurane, itraconazole, ketoconazole, lithium, loratadine, metoclopramide, nortriptyline, procainamide, quinidine, sematilide, sotalol, sulfamethoxazole, thioridazine, trimethoprim, , Long QT Syndrome, Proarrhythmia and Torsades de Pointes
7. Genetic Epidemiology of Responses to Antihypertensives (GERA)

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   • PD

   Submitted by Stephen T. Turner, MD involving ACE, ADD1, ADRB1, ADRB2, AGT, AGTR1, CYP11B2, GNB3, LPL, NOS3, REN, hydrochlorothiazide, and Essential hypertension
8. Survival of patients on beta-blockers after ACS, and ADRB1, ADRB2

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   • CO
   • PD

   Submitted by Howard McLeod, PharmD involving ADRB1, ADRB2, Beta Blocking Agents, , Angina, Unstable and Myocardial Infarction

Additional Datasets

These datasets are minimally curated and are sorted alphabetically by title.

1. A chemogenomic approach to drug discovery: focus on cardiovascular diseases
2. Genetic Associations in Drug-induced QT Prolongation and Torsades
3. International Multi-Center ADHD Genetics Project (IMAGE)
4. Pharmacogenetics of Minimal Residual Disease Response in Children with B-Precursor Acute Lymphoblastic Leukemia (ALL): A Report from the Children's Oncology Group

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LinkOuts

Common Searches

• Comparative Genomics at UCSC
• Search BioCarta and KEGG Pathways at CGAP
• Search Reactome

Non-Curated Publications

A list of non-curated publications that mention this gene is available.