Relation between AT1R Gene Polymorphism and Long-Term Outcome in Patients with Heart Failure

Renal impairment is associated with increased mortality in heart failure (HF). Recently, reports suggest that worsening renal function (WRF) is another predictor of clinical outcome in HF. The present study was designed to establish the proportion of patients with HF that exhibits (WRF) and the associated risk for mortality and hospitalization by conducting a systematic review and meta-analysis. A systematic search of MEDLINE revealed 8 studies on the relationship between WRF and mortality in 18,634 patients with HF. The mortality risk associated with WRF was estimated using random-effects meta-analysis. WRF was defined as an increase in serum creatinine > or = 0.2 mg/dL or a corresponding decrease in estimated glomerular filtration rate > or = 5 mL x min x 1.73 m2. Subgroup analysis included differentiation between in- and out-hospital patients, degree of WRF and time until end point occurrence. WRF developed in 4,734 (25%) patients and was associated with a higher risk for mortality (odds ratio [OR] = 1.62; 95% confidence interval [CI] 1.45-1.82, P < .001) and hospitalization (OR = 1.30, 95% CI 1.04-1.62, P = .022). The severity of WRF was also associated with greater mortality. Patients with impaired renal function at baseline were more prone to progressive renal function loss. WRF predicts substantially higher rates of mortality and hospitalization in patients with HF.

Animal microRNAs (miRNAs) regulate gene expression through base pairing to their targets within the 3' untranslated region (UTR) of protein-coding genes. Single-nucleotide polymorphisms (SNPs) located within such target sites can affect miRNA regulation. We mapped annotated SNPs onto a collection of experimentally supported human miRNA targets. Of the 143 experimentally supported human target sites, 9 contain 12 SNPs. We further experimentally investigated one of these target sites for hsa-miR-155, within the 3' UTR of the human AGTR1 gene that contains SNP rs5186. Using reporter silencing assays, we show that hsa-miR-155 down-regulates the expression of only the 1166A, and not the 1166C, allele of rs5186. Remarkably, the 1166C allele has been associated with hypertension in many studies. Thus, the 1166C allele may be functionally associated with hypertension by abrogating regulation by hsa-miR-155, thereby elevating AGTR1 levels. Since hsa-miR-155 is on chromosome 21, we hypothesize that the observed lower blood pressure in trisomy 21 is partially caused by the overexpression of hsa-miR-155 leading to allele-specific underexpression of AGTR1. Indeed, we have shown in fibroblasts from monozygotic twins discordant for trisomy 21 that levels of AGTR1 protein are lower in trisomy 21.

The process of heart failure appears to be a common and coordinated response to cardiac injury and dysfunction. The contemporary mechanistic viewpoint that predictable, shared, highly regulated events underlie the complex heart failure process implies that an improved understanding of these mechanisms is fundamental to the advancement of cardiovascular biology and the subsequent development of targeted, effective treatment strategies for patients with congestive heart failure (CHF). Cardiac remodeling (CR) is the restructuring and reshaping of the heart that underlies heart failure progression. CR is a major determinant of the clinical course of CHF, irrespective of its etiology. The traditional concepts of cellular remodeling in the failing heart are based on well-established data indicating characteristic alterations in cell size, shape, and the ability to perform contractile work. The role of programmed cell death and the exciting possibility of cardiomyocyte regeneration are areas of intense investigation. Notably, the accumulating data in both animal and human hearts suggesting cardiomyocyte regeneration and renewal indicate that cellular remodeling is a complex and dynamic process that is not completely understood. For the development of new treatments to regenerate and restore failing myocardium, the possibilities offered by controlling cell death and enhancing cell renewal as a therapeutic target are unprecedented. Based on a critical review of the available literature, the traditional concepts and mechanisms describing the regulation of remodeling are largely inadequate. The neurohormonal (RAAS and adrenergic systems) and innovative cytokine hypothesis (TNF-alpha and others) of remodeling and failure do not account for all the cellular and molecular changes that result in the progression of CHF. Given that these contemporary concepts serve as the basis for the majority of our current heart failure treatments, it is not surprising that CHF is an emerging epidemic in our society. To define new therapeutic targets and to control the process of remodeling, novel biomolecules and mechanisms for the coordinated control of CR must be further defined.