Fabiana Filigheddu

Effect of the HMG-CoA Reductase Inhibitors on Blood Pressure in Patients With Essential Hypertension and Primary Hypercholesterolemia

Certain hydroxymethylglutaryl coenzyme A reductase inhibitors, ie, statins, may cause vasodilation by restoring the endothelial dysfunction that frequently accompanies hypertension and hypercholesterolemia. Several studies have found that a blood pressure reduction is associated with the use of statins, but conclusive evidence from controlled trials is lacking. After an 8-week placebo and diet run-in period, 30 persons with moderate hypercholesterolemia and untreated hypertension (total cholesterol 6.29+/-0.52 mmol/L, systolic and diastolic blood pressure 149+/-6 and 97+/-2 mm Hg) were randomized in a double-blind manner to placebo or pravastatin (20 to 40 mg/d) in a crossover design. In 25 participants who completed the 32-week trial, pravastatin decreased total and LDL cholesterol (both -1.09 mmol/L, P=0.001), systolic and diastolic blood pressure (-8 and -5 mm Hg, both P=0.001), and pulse pressure (-3 mm Hg, P=0.011) and blunted the blood pressure increase caused by the cold pressor test (-4 mm Hg, P=0.005) compared with placebo. It also reduced the level of circulating endothelin-1 (P=0.001). The blood pressure results were virtually unchanged in stratified analyses according to gender and age and in intention-to-treat analyses that included the 5 patients who dropped out of the study. When the participants were taking either placebo or pravastatin, blood pressure was not significantly correlated with total or LDL cholesterol or with circulating endothelin-1. Pravastatin decreases systolic, diastolic, and pulse pressures in persons with moderate hypercholesterolemia and hypertension. This antihypertensive effect may contribute to the documented health benefits of certain statins.

Genetic polymorphism of the renin-angiotensin-aldosterone system and arterial hypertension in the Italian population: The GENIPER Project

Objective To detect the association of single polymorphisms of the renin–angiotensin–aldosterone system (RAAS), or different combinations thereof, with hypertension. Design and methods The GENIPER database is the result of a collaborative effort of 13 Italian research centres to collect genomic DNA in subjects well characterized in terms of blood pressure status. A total of 2461 subjects (normotensive = 611; hypertensive = 1850) were selected and genotyped for the angiotensin-converting enzyme insertion/deletion (ACE I/D), angiotensinogen (AGT) T/C704, angiotensin receptor type 1 (AT1) A/C1166 and aldosterone synthase (ALDO) T/C−344 genetic variants. Results Allele frequencies were homogeneous over the Italian territory, with the relevant exception of the ACE I/D, the D allele being significantly less frequent in the northern region (61%) than in the rest of the country (67%; P < 0.0001). When comparing allele and genotype distributions in normotensives and hypertensives, the latter presented a small but statistically significant increase of the C allele of AGT T/C704, the A allele of AT1 A/C1166 and the T allele of ALDO T/C−344 polymorphisms (P = 0.018, P = 0.037 and P = 0.015, respectively), with similar trends all over the country. A step-wise logistic regression analysis confirmed these findings, by entering in the model as independent predictors of blood pressure status of AGT T/C704 (P = 0.013), ALDO T/C−344 (P = 0.032) and AT1 A/C1166 polymorphisms (P = 0.075), but not ACE I/D (P = 0.996). We also found some evidence of an additive effect of individual genetic variants of the RAAS, modulating at different levels the same functional pathway, on the risk of developing hypertension, but no synergistic interaction was observed. Conclusions Our results suggest that some allelic variants of RAAS genes carry a small but identifiable risk of developing arterial hypertension.

Interaction of α1-Na,K-ATPase and Na,K,2Cl-Cotransporter Genes in Human Essential Hypertension

Essential hypertension is a common disease the genetic determinants of which have been difficult to unravel because of its clinical heterogeneity and complex, multifactorial, polygenic etiology. Based on our observations that α1-Na,K-ATPase ( ATP1A1 ) and renal-specific, bumetanide-sensitive Na,K,2Cl-cotransporter ( NKCC2 ) genes interactively increase susceptibility to hypertension in the Dahl salt-sensitive hypertensive (Dahl S) rat model, we investigated whether parallel molecular genetic mechanisms might exist in human essential hypertension in a relatively genetic homogeneous cohort in northern Sardinia. Putative ATP1A1-NKCC2 gene interaction was tested by comparing hypertensive patients (blood pressure [BP] >165/95 mm Hg) with normotensive controls age >60 years with BP <140/85 mm Hg. Genotype analysis with microsatellite markers revealed conformation to Hardy-Weinberg proportions for 6 alleles of both ATP1A1 ( D1S453 ) and NKCC2 ( NKCGT7 ) markers, respectively. Two-by-six χ2 analysis of alleles identified overrepresentation of ATP1A1 No. 4 and NKCC2 No. 4 alleles, respectively, in hypertensives compared with controls. With a qualitative trait framework, single-gene analysis detected association of both the ATP1A1 No. 4 allele ( P =0.004, χ2=8.094, df =1) and the NKCC2 No. 4 allele ( P =0.0002, χ2=14.279, df =1) with moderate to severe hypertension. Digenic analysis revealed that ATP1A1 No. 4– NKCC2 No. 4 allele interaction increases susceptibility to hypertension ( P <0.0001, χ2=22.3, df =1) beyond levels obtained in single-gene analysis. Analysis was also performed in a quantitative trait framework with BP as the continuous trait parameter. Digenic analysis of ATP1A1 No. 4– NKCC2 No. 4 allele interaction revealed significant association with systolic (1-way ANOVA, P =0.000076) and diastolic ( P =0.00099) BP. Interaction was corroborated by 2×2 factorial ANOVA for interaction (systolic BP interaction term, P <0.05, diastolic BP interaction term, P =0.035). The data are compelling that ATP1A1 and NKCC2 genes are candidate interacting hypertension-susceptibility loci in human essential hypertension and affirm gene interaction as an important genetic mechanism underlying hypertension susceptibility. Although corroboration in other cohorts and identification of functionally significant mutations are imperative next steps, the data provide a genotype-stratification scheme, with 4-fold predictive value (odds ratio, 4.28; 95% confidence interval, 2.29 to 8.0), which could help decipher the complex genetics of essential hypertension.

Association of ATP1A1 and Dear Single-Nucleotide Polymorphism Haplotypes With Essential Hypertension Sex-Specific and Haplotype-Specific Effects

Essential hypertension remains a major risk factor for cardiovascular and cerebrovascular diseases. As a complex multifactorial disease, elucidation of susceptibility loci remains elusive. ATP1A1 and Dear are candidate genes for 2 closely linked rat chromosome-2 blood pressure quantitative trait loci. Because corresponding human syntenic regions are on different chromosomes, investigation of ATP1A1 (chromosome [chr]-1p21) and Dear (chr-4q31.3) facilitates genetic analyses of each blood pressure quantitative trait locus in human hypertension. Here we report the association of human ATP1A1 (P<0.000005) and Dear (P<0.03) with hypertension in a relatively isolated, case/control hypertension cohort from northern Sardinia by single-nucleotide polymorphism haplotype analysis. Sex-specific haplotype analyses detected stronger association of both loci with hypertension in males than in females. Haplotype trend-regression analyses support ATP1A1 and Dear as independent susceptibility loci and reveal haplotype-specific association with hypertension and normotension, thus delineating haplotype-specific subsets of hypertension. Although investigation in other cohorts needs to be performed to determine genetic effects in other populations, haplotype subtyping already allows systematic stratification of susceptibility and, hence, clinical heterogeneity, a prerequisite for unraveling the polygenic etiology and polygene–environment interactions in essential hypertension. As hypertension susceptibility genes, coexpression of ATP1A1 and Dear in both renal tubular cells and vascular endothelium suggest a cellular pathogenic scaffold for polygenic mechanisms of hypertension, as well as the hypothesis that ATP1A1 and/or Dear could contribute to the known renal and vascular endothelial dysfunction associated with essential (polygenic) hypertension.

Haplotypes of the adrenergic system predict the blood pressure response to β-blockers in women with essential hypertension

AIMS To analyze the association of haplotypes of the adrenergic system with essential hypertension and with the blood pressure response to beta-blockers. MATERIALS & METHODS In 1112 never-treated essential hypertension patients and 203 normotensive controls, tightly linked SNPs of beta-adrenergic receptors (ADRB1 - Ser49Gly and Arg389Gly; ADRB2 - Cys19Arg, Gly16Arg and Gln27Glu) and the G-protein beta3-subunit (GNB3 - A3882C, G5249A and C825T) were genotyped. Association of haplotypes with essential hypertension and with the blood pressure response to atenolol 50 mg twice daily in a subgroup of essential hypertension patients (n = 340) was evaluated (Haploview 3.2). RESULTS No SNPs or haplotypes were associated with essential hypertension. In females only, GNB3 SNPs and haplotypes were associated with the blood pressure response (p < 0.05). CONCLUSION Our study confirmed the sex-specific association of GNB3 with the blood pressure response to atenolol with no substantial advantage of the analysis of haplotypes over SNPs.

Clinical variables, not RAAS polymorphisms, predict blood pressure response to ACE inhibitors in Sardinians

AIM No definite factors predict blood pressure response to angiotensin-converting enzyme-inhibitors. The aim of this study was to test the association of gene polymorphisms of the renin-angiotensin-aldosterone system with essential hypertension and anthropometric variables, intermediate phenotypes and gene polymorphisms with blood pressure after fosinopril in a genetically homogeneous cohort. METHODS A total of 630 essential hypertension patients, not previously treated or out of antihypertensive treatment for at least 6 months versus 219 normotensives (genotype frequencies, chi(2)). A total of 191 patients were randomly assigned to fosinopril 20 mg/day. Samples for plasma renin activity and aldosterone, 24-h urinary sodium (flame photometry) were collected. Gene polymorphisms--angiotensin-converting enzyme (insertion/deletion), angiotensin II type 1-receptor (A1166C), aldosterone synthase (-344C/T) and angiotensinogen (-6A/G)--were analyzed by standard techniques. The association of anthropometric variables, intermediate phenotypes and gene polymorphisms with blood pressure after 4 weeks therapy was tested by univariate analysis and analysis of covariance model (Intercooled Stata SE 9.2). RESULTS No genetic polymorphisms were associated with essential hypertension, blood pressure response and intermediate phenotypes (p > 0.05). Systolic blood pressure after therapy was associated with baseline systolic blood pressure, age and sex. CONCLUSIONS Our results confirm the difficulty in dissecting both essential hypertension and pharmacogenomics when analyzing the effect of single genes in complex multifactorial traits.

Urinary adrenomedullin is related to ET-1 and salt intake in patients with mild essential hypertension

Adrenomedullin (ADM) infusion increases salt excretion in the rat. However, there is no evidence that this substance is related to changes in salt intake in humans. In this study we sought whether the urinary excretion rate of this autacoid is related to salt intake and by the expected changes in arterial pressure in patients with mild essential hypertension. The influence of salt intake on the renal excretion of ADM was investigated in 55 hypertensive patients in a double blind, randomized and crossover study comparing a 2-week 50 mmol/day salt intake period with a 150 mmol/day salt intake period. Twenty-four-hour ADM and endothelin-1 (ET-1) excretion rate were measured by radioimmunoassay on preextracted urinary samples (intraassay confidence variable <8%). The antibodies used in these assays had minimal ADM-ET-1 cross-reactivity (<1%). Twenty-four-hour microalbuminuria was measured by nephelometry. On univariate analysis changes in urinary ADM were significantly related to those in salt excretion (r = 0.33, P = .01) as well as to changes in urinary ET-1 (r = 0.56, P = .0001). Furthermore, changes in urinary albumin excretion were related to those in urinary ET-1 (r = 0.26, P = .05), but were independent of those in urinary ADM (P = .19). In a multiple regression model including age, sex, body mass index, and changes in systolic pressure, plasma renin activity and plasma aldosterone and urine volume, salt excretion resulted as the stronger independent predictor of urinary ADM (r = 0.33, P = .01). However, changes in urinary salt lost prediction power (P = .11) for urinary ADM when urinary ET-1 was introduced into the model. In this model (multiple r = 0.31) urinary ET-1 resulted to be the only independent predictor of urinary ADM (beta = 0.56, P = .0001). This study is the first to show that the renal excretion of ADM is related to changes in salt intake and that it is tightly linked to that of ET-1. The data support the notion that these autacoids play a role in the regulation of sodium metabolism in patients with mild hypertension. The intercorrelations between ET-1, ADM, and microalbuminuria are compatible with the hypothesis that ET-1 is involved in a salt-induced increase in glomerular pressure and suggest that ADM may act as a counterregulatory factor in this situation.

Prevalence and clinical features of heterozygous carriers of autosomal recessive hypercholesterolemia in Sardinia

OBJECTIVE Autosomal recessive hypercholesterolemia (ARH) is a lipid disorder caused by mutations in a specific adaptor protein for the LDL receptor. ARH is rare except in Sardinia where three alleles (ARH1, ARH2 and ARH3) explain most of cases. The prevalence of ARH heterozygotes in Sardinia is not well determined as well as inconclusive data are available on the effect of the ARH carrier status on LDL cholesterol (LDL-C) and coronary risk. METHODS 3410 Sardinians (986 blood donors, 1709 with hypertension and 715 with myocardial infarction (MI)) were screened for ARH alleles. For comparison purposes, lipid data of 60 ARH heterozygous carriers and 60 non-carriers identified within 24 ARH families were also considered. RESULTS In the whole study cohort, no ARH homozygotes were found, but 15 ARH1 (0.44%) and 9 ARH2 (0.26%) heterozygous carriers were identified. The frequency of ARH alleles in blood donors was 0.0030, not different from that in hypertensive subjects (0.0032). ARH alleles tended to be more common in MI patients (0.0049), but no association between ARH carrier status and MI risk was detected after controlling for conventional risk factors. ARH carriers and non-carriers showed similar LDL-C levels. This result was confirmed when ARH carriers and non-carriers identified throughout family-based and population-based screenings were combined and compared (141.0+/-41 mg/dl vs. 137.0+/-41 mg/dl, respectively; p=0.19). CONCLUSIONS These data indicate that the frequency of ARH heterozygotes in Sardinia is approximately 1:143 individuals, thus making this condition one of the most common in the Sardinian population. However, ARH carrier status does not influence LDL-C concentration and coronary risk, thus suggesting that ARH can be regarded as a truly recessive disorder.

Non-association of the thiazide-sensitive Na,Cl-cotransporter gene with polygenic hypertension in both rats and humans.

Objective Genes underlying renal regulation of sodium and water balances are a priori valid candidates for polygenic hypertension susceptibility genes. Having recently identified the association of α1 Na,K-ATPase (ATP1A1) and Na,K,2Cl-cotransporter (NKCC2) as interacting hypertension susceptibility loci in both a rat model and human hypertensives, we investigated whether the thiazide-sensitive Na,Cl-cotransporter (TSC) gene contributes to hypertension susceptibility in a rat F2 intercross and in a northern Sardinian human cohort for polygenic hypertension. Subjects and methods The rat TSC (rTSC) gene was analyzed directly for cosegregation with salt-sensitive hypertension in an F2 (Dahl S × Dahl R) rat population (n = 102) characterized for blood pressure by radiotelemetry. The human TSC (hTSC) gene was analyzed for association with hypertension in a human hypertensive cohort from northern Sardinia that consisted of 220 unrelated normotensives and 254 unrelated hypertensives. The TSC gene was subjected to single locus and digenic (in combination with ATP1A1 and NKCC2 genes) analyses in both rat and human cohorts. Results In both rat model and human cohorts, the rTSC and hTSC genes did not show linkage or association with high blood pressure, respectively. Furthermore, interaction with either ATP1A1 or NKCC2 was not detected in both the rat F2 intercross and human hypertension cohorts. Conclusions These data exclude a primary role of the TSC gene in hypertension pathogenesis in the hypertension cohorts studied.

Genetic Prediction of Heart Failure Incidence, Prognosis and Beta-blocker Response

Heart failure (HF) is a widespread syndrome due to left ventricular dysfunction with high mortality, morbidity and health-care costs. Beta-blockers, together with diuretics and ACE-inhibitors or angiotensin receptor blockers, are a cornerstone of HF therapy, as they reduce mortality and morbidity. Nevertheless, their efficacy varies among patients, and genetics is likely to be one of the modifying factors. In this article, literature on the role of candidate genes on the development of HF, its prognosis and pharmacogenomics of β-blockers in patients with HF is reviewed. The available findings do not support, at the present time, a role for genetic tests in the treatment of HF. More large-scale genome-wide studies with adequate methodology and statistical analysis are required before considering genetic tailoring of HF therapy in patients with systolic HF.