Abstract

An anticipated outcome of the genetic revolution is more individualized treatment and prevention strategies. For the past decade supported by a SCOR in Hypertension (HTN) we have developed a large cohort who has been carefully characterized phenotypically and genotyped for several key candidate genes. We have strong evidence that a number of these genes identify homogeneous subgroups that theoretically should respond to specific therapies. The logical next step is to test these expectations. Our focus has been on the genetic underpinnings of hormonal factors leading to HTN and its associated cardiovascular (CV) risks. From these studies, we have identified several specific intermediate phenotypes of the hypertensive population. Two are the focus of this proposal. Common characteristics are: 1) an abnormality in the regulation of aldosterone (ALDO) secretion when sodium diet is modified and 2) salt sensitive blood pressure (BP). The first intermediate phenotype, comprising 25-30% of hypertensives, is termed non-modulation. Their defect is dysregulation of tissue ANGII production when Na intake is modified in the adrenal and the vasculature. They have abnormalities in renal function but normal renin level. Non-modulators are associated with polymorphic variants of angiotensinogen (ACT) that increases angiotensinogen production-a gain in function mutation- and adipocyte derived leucine aminopeptidase (ALAP) that reduces ANGII degradation- a loss of function mutation. Thereby in two ways non-modulators can increase tissue levels of ANGII. The pathophysiologic features of non-modulation are corrected by administrating an ACE inhibitor. The second intermediate phenotype, only recently identified by our group, is part of the more traditional salt sensitive sub-group: low renin HTN. These individuals have disproportionately increased ALDO levels in contrast to the reduced ALDO levels observed in non-modulators, and are associated with polymorphisms in the ?-2 adrenergic receptor gene. This intermediate phenotype may comprise a third or more of low renin hypertensives. The overall goal of the present proposal is to expand on these preliminary findings in three ways. First, in non-modulators we will determine the relationship of the two major gene variants to the presence of the metabolic syndrome/insulin resistance-a major feature of non-modulation. Second, for both phenotypes, we will determine the likely mechanism(s) underlying the increased risk of HTN using in vivo and in vitro techniques. Third, for the non-modulators, we will determine the likelihood that therapy directed at these mechanism(s) will be more effective in reducing BP, than will non-specific therapy- pharmacogenetics. Thus, the ultimate outcome of this project is to develop tools for individualized therapy in a substantial fraction of the hypertensive population using mechanistically and genetically driven approaches. ? ? ?

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL086907-02
Application #
7496515
Study Section
Special Emphasis Panel (ZRG1-CVS-F (03))
Program Officer
Reid, Diane M
Project Start
2007-09-15
Project End
2012-06-30
Budget Start
2008-07-01
Budget End
2009-06-30
Support Year
2
Fiscal Year
2008
Total Cost
$698,101
Indirect Cost

  Institution

Name
Brigham and Women's Hospital
Department
Type
DUNS #
030811269
City
Boston
State
MA
Country
United States
Zip Code
02115

  Publications

Manosroi, Worapaka; Tan, Jia Wei; Rariy, Chevon M et al. (2017) The Association of Estrogen Receptor-? Gene Variation With Salt-Sensitive Blood Pressure. J Clin Endocrinol Metab 102:4124-4135
Gupta, Tina; Connors, Molly; Tan, Jia Wei et al. (2017) Striatin Gene Polymorphic Variants Are Associated With Salt Sensitive Blood Pressure in Normotensives and Hypertensives. Am J Hypertens 31:124-131
Tan, Jia W; Gupta, Tina; Manosroi, Worapaka et al. (2017) Dysregulated aldosterone secretion in persons of African descent with endothelin-1 gene variants. JCI Insight 2:
Baudrand, Rene; Pojoga, Luminita H; Vaidya, Anand et al. (2015) Statin Use and Adrenal Aldosterone Production in Hypertensive and Diabetic Subjects. Circulation 132:1825-33
Garza, Amanda E; Rariy, Chevon M; Sun, Bei et al. (2015) Variants in striatin gene are associated with salt-sensitive blood pressure in mice and humans. Hypertension 65:211-217
Baudrand, Rene; Pojoga, Luminita H; Romero, Jose R et al. (2014) Aldosterone's mechanism of action: roles of lysine-specific demethylase 1, caveolin and striatin. Curr Opin Nephrol Hypertens 23:32-7
Underwood, Patricia C; Chamarthi, Bindu; Williams, Jonathan S et al. (2012) Replication and meta-analysis of the gene-environment interaction between body mass index and the interleukin-6 promoter polymorphism with higher insulin resistance. Metabolism 61:667-71
Underwood, Patricia C; Sun, Bei; Williams, Jonathan S et al. (2011) The association of the angiotensinogen gene with insulin sensitivity in humans: a tagging single nucleotide polymorphism and haplotype approach. Metabolism 60:1150-7
Bafford, Richard; Sui, Xin Xin; Park, Min et al. (2011) Mineralocorticoid receptor expression in human venous smooth muscle cells: a potential role for aldosterone signaling in vein graft arterialization. Am J Physiol Heart Circ Physiol 301:H41-7
Watkins, W Scott; Hunt, Steven C; Williams, Gordon H et al. (2010) Genotype-phenotype analysis of angiotensinogen polymorphisms and essential hypertension: the importance of haplotypes. J Hypertens 28:65-75

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