Polymorphism in the &bgr;1-Adrenergic Receptor Gene and Hypertension

Background—The Arg389 variant of the &bgr;1-adrenergic receptor gene mediates a higher isoproterenol-stimulated adenylate cyclase activity than the Gly389 variant in vitro. We investigated whether the Arg389Gly or the Ser49Gly polymorphism is associated with hypertension in Scandinavians. Methods and Results—A total of 292 unrelated, nondiabetic, hypertensive patients and 265 unrelated healthy control subjects were included in a case-control association study. From 118 families, 102 nondiabetic sibling pairs without antihypertensive medication who were discordant for the Arg389Gly polymorphism were selected for a sibling study. Allele and genotype frequencies of the Arg389Gly and Ser49Gly polymorphisms were compared between hypertensive patients and normotensive control subjects. Blood pressure and heart rate were compared between carriers of the different genotypes. In the case-control study, the age- and body mass index-adjusted odds ratio for hypertension in subjects homozygous for the Arg389 allele was 1.9 (95% confidence interval, 1.3 to 2.7;P =0.0005) when compared with carriers of 1 or 2 copies of the Gly389 allele. The genotype-discordant sibling pair analysis revealed that siblings homozygous for the Arg389 allele had significantly higher diastolic blood pressures (79.4±9.9 versus 76.0±10.1 mm Hg;P =0.003) and higher heart rates (68.3±11.0 versus 65.1±9.4 bpm;P =0.02) than siblings carrying 1 or 2 copies of the Gly389 allele. The Ser49Gly polymorphism was not associated with hypertension. Conclusion—Our data suggest that individuals homozygous for the Arg389 allele of the &bgr;1-adrenergic receptor gene are at increased risk to develop hypertension.

[1]  L. Groop,et al.  Polymorphism in the angiotensin converting enzyme but not in the angiotensinogen gene is associated with hypertension and type 2 diabetes: the Skaraborg Hypertension and diabetes project. , 1999, Journal of hypertension.

[2]  L. Groop,et al.  A paired-sibling analysis of the XbaI polymorphism in the muscle glycogen synthase gene , 1999, Diabetologia.

[3]  D. A. Mason,et al.  A Gain-of-function Polymorphism in a G-protein Coupling Domain of the Human β1-Adrenergic Receptor* , 1999, The Journal of Biological Chemistry.

[4]  S. Ball,et al.  Common polymorphisms of β1-adrenoceptor: identification and rapid screening assay , 1999, The Lancet.

[5]  J. Ranstam,et al.  Risk factor clustering in patients with hypertension and non‐insulin‐dependent diabetes mellitus. The Skaraborg Hypertension Project , 1998, Journal of internal medicine.

[6]  L. Groop,et al.  Metabolic Consequences of a Family History of NIDDM (The Botnia Study): Evidence for Sex-Specific Parental Effects , 1996, Diabetes.

[7]  B. Brenner,et al.  Hypertension: Pathophysiology, Diagnosis, and Management , 1994 .

[8]  M. Caron,et al.  Cloning of the cDNA for the human beta 1-adrenergic receptor. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[9]  C. Mathew,et al.  Blot hybridisation analysis of genomic DNA. , 1984, Journal of medical genetics.

[10]  D. A. Mason,et al.  Racial differences in the frequencies of cardiac β1‐adrenergic receptor polymorphisms: Analysis of c145A>G and c1165G>C , 1999, Human mutation.

[11]  J. Swales Textbook of hypertension , 1994 .

[12]  R. Lifton,et al.  Finding genes that cause human hypertension. , 1993, Journal of hypertension.

[13]  R. Ward Familial aggregation and genetic epidemiology of blood pressure , 1990 .