Daniele Cusi

Association of the α-Adducin Locus With Essential Hypertension

Abstract Previous studies on genetic rat hypertension have shown that polymorphism within the α-adducin gene may regulate blood pressure. Adducin is a cytoskeletal protein that may be involved in cellular signal transduction and interacts with other membrane-skeleton proteins that affect ion transport across the cell membrane. There is a high homology between rat and human adducin and pathophysiological similarities between the Milan hypertensive rat strain and a subgroup of patients with essential hypertension. Thus, we designed a case-control study to test the possible association between the α-adducin locus and hypertension. One hundred ninety primary hypertensive patients were compared with 126 control subjects. All subjects were white and unrelated. Four multiallelic markers surrounding the α-adducin locus located in 4p16.3 were selected: D4S125 and D4S95 mapping at 680 and 20 kb centromeric, and D4S43 and D4S228/E24 mapping at 660 and 2500 kb telomeric. Alleles for each marker were pooled into groups. Comparisons between control subjects and hypertensive patients were carried out by testing the allele-disease association relative to the marker genotype. The maximal association occurred for D4S95 (χ12 13.33), which maps closest to α-adducin. These data suggest that a polymorphism within the α-adducin gene may affect blood pressure in humans.

Left Ventricular Mass, Stroke Volume, and Ouabain-Like Factor in Essential Hypertension

Many patients with essential hypertension (EH) exhibit increased left ventricular mass. Similarly, elevated circulating levels of an endogenous ouabainlike factor (OLF) have been described in some but not all patients with EH. Moreover, ouabain has a hypertrophic influence on isolated cardiac myocytes. Accordingly, we investigated relationships among plasma OLF, left ventricular mass, and cardiac function in patients with EH. Plasma OLF was determined in 110 normotensive subjects and 128 patients with EH. Echocardiographic parameters and humoral determinants were measured in EH. Plasma OLF levels were increased (P<0.0001) in patients with EH (377+/-19 pmol/L) versus normotensive (253+/-53 pmol/L) subjects. The distribution of plasma OLF was unimodal in normotensives, whereas it was bimodal in EH. Twenty-four-hour diastolic ambulatory blood pressure was slighter higher in EH with high OLF compared with EH with normal OLF (93.2+/-1.14 versus 89.4+/-1.33 mm Hg, P=0.03). Left ventricular mass index and stroke volume in EH with high OLF were greater than in EH with normal OLF (101.9+/-3.3 versus 86.1+/-2.5 g/m(2), P=0.0003, and 57.10+/-1.48 versus 52.30+/-1.14 mL/m(2), P=0. 02, respectively), although heart rate was slower (74.2+/-1.3 versus 80.5+/-1.3 bpm, P=0.005). Multiple regression analysis that tested the influence of body mass index, age, gender, 24-hour blood pressure, and OLF on left ventricular mass revealed independent contributions of systolic (13.2%) and diastolic (12.4%) blood pressure and plasma OLF (11.6%) to left ventricular mass. We conclude that approximately 50% of patients with uncomplicated EH have elevated-high circulating OLF levels, higher diastolic blood pressure, greater left ventricular mass and stroke volume, and reduced heart rate. We propose that the OLF affects cardiovascular function and structure and should be considered as a factor that contributes to the risk of morbid events.

Discovery of new risk loci for IgA nephropathy implicates genes involved in immunity against intestinal pathogens

We performed a genome-wide association study (GWAS) of IgA nephropathy (IgAN), the most common form of glomerulonephritis, with discovery and follow-up in 20,612 individuals of European and East Asian ancestry. We identified six new genome-wide significant associations, four in ITGAM-ITGAX, VAV3 and CARD9 and two new independent signals at HLA-DQB1 and DEFA. We replicated the nine previously reported signals, including known SNPs in the HLA-DQB1 and DEFA loci. The cumulative burden of risk alleles is strongly associated with age at disease onset. Most loci are either directly associated with risk of inflammatory bowel disease (IBD) or maintenance of the intestinal epithelial barrier and response to mucosal pathogens. The geospatial distribution of risk alleles is highly suggestive of multi-locus adaptation, and genetic risk correlates strongly with variation in local pathogens, particularly helminth diversity, suggesting a possible role for host–intestinal pathogen interactions in shaping the genetic landscape of IgAN.

Genome-Wide Scan Identifies TNIP1, PSORS1C1, and RHOB as Novel Risk Loci for Systemic Sclerosis

Systemic sclerosis (SSc) is an orphan, complex, inflammatory disease affecting the immune system and connective tissue. SSc stands out as a severely incapacitating and life-threatening inflammatory rheumatic disease, with a largely unknown pathogenesis. We have designed a two-stage genome-wide association study of SSc using case-control samples from France, Italy, Germany, and Northern Europe. The initial genome-wide scan was conducted in a French post quality-control sample of 564 cases and 1,776 controls, using almost 500 K SNPs. Two SNPs from the MHC region, together with the 6 loci outside MHC having at least one SNP with a P<10−5 were selected for follow-up analysis. These markers were genotyped in a post-QC replication sample of 1,682 SSc cases and 3,926 controls. The three top SNPs are in strong linkage disequilibrium and located on 6p21, in the HLA-DQB1 gene: rs9275224, P = 9.18×10−8, OR = 0.69, 95% CI [0.60–0.79]; rs6457617, P = 1.14×10−7 and rs9275245, P = 1.39×10−7. Within the MHC region, the next most associated SNP (rs3130573, P = 1.86×10−5, OR = 1.36 [1.18–1.56]) is located in the PSORS1C1 gene. Outside the MHC region, our GWAS analysis revealed 7 top SNPs (P<10−5) that spanned 6 independent genomic regions. Follow-up of the 17 top SNPs in an independent sample of 1,682 SSc and 3,926 controls showed associations at PSORS1C1 (overall P = 5.70×10−10, OR:1.25), TNIP1 (P = 4.68×10−9, OR:1.31), and RHOB loci (P = 3.17×10−6, OR:1.21). Because of its biological relevance, and previous reports of genetic association at this locus with connective tissue disorders, we investigated TNIP1 expression. A markedly reduced expression of the TNIP1 gene and also its protein product were observed both in lesional skin tissue and in cultured dermal fibroblasts from SSc patients. Furthermore, TNIP1 showed in vitro inhibitory effects on inflammatory cytokine-induced collagen production. The genetic signal of association with TNIP1 variants, together with tissular and cellular investigations, suggests that this pathway has a critical role in regulating autoimmunity and SSc pathogenesis.

ACE and α-Adducin Polymorphism as Markers of Individual Response to Diuretic Therapy

Abstract—Renin-angiotensin system reactivity and the constitutive capacity of the renal tubule to reabsorb sodium play a role in the individual response to diuretic therapy; therefore we evaluated the blood pressure (BP) response to hydrochlorothiazide in 87 never-treated individuals with mild essential hypertension, according to ACE gene I/D and &agr;-adducin Gly460Trp polymorphism. These genotypes where chosen because previous data showed their interaction in determining the BP response to salt probably was the result of their involvement in the activation of the renin-angiotensin system (ACE) and in the constitutive capacity of the kidney to reabsorb sodium (&agr;-adducin) (treatment for 2 months). BP was measured after 3 run-in visits and after the first and second months of treatment by means of a standardized procedure. Data were analyzed by ANOVA, t test, and multivariate ANOVA for repeated measures (covarying for gender, age, and body mass index). Although basal mean BP (MBP) was similar in the different ACE and &agr;-adducin genotypes, patients carrying at least one I allele of ACE and one 460Trp allele of &agr;-adducin had the largest MBP decrease with treatment (12.7±1.9 mm Hg), the effect of the combination of genotypes being additive but not epistatic. These patients had an odds ratio of 15.75 of being a responder to hydrochlorothiazide compared with patients with Gly460Gly+DD, with the least MBP decrease (3.4±1.7 mm Hg). &agr;-Adducin and ACE I/D polymorphism may be useful to predict the interindividual degree of response to hydrochlorothiazide; the analysis of the combination of the 2 genotypes increases the accuracy of the prediction of response to the drug.

Adducin- and Ouabain-Related Gene Variants Predict the Antihypertensive Activity of Rostafuroxin, Part 2: Clinical Studies

Five genetic variants that affect Na,K-ATPase interactions predict the blood pressure response to rostafuroxin but not to losartan and hydrochlorothiazide. Help for Hypertension As if changing its mind about how best to detoxify the body, the kidney first secretes a filtrate that contains almost everything in the blood but then recaptures much of it by pumping essential water, salts, and other molecules back in. The Na+, K+-ATPase, or sodium pump, recaptures sodium salts, and because Na+ is the prime determinant of extracellular fluid volume in the body, regulation of this pump controls blood pressure. Now a pair of papers describes how an antihypertension drug can correct abnormal sodium pumping and how this understanding of the drug’s mechanism points to a genetic signature that can predict whether a patient will respond to the drug. One cause of hypertension is a particular variant(s) of the protein adducin, a modulator of protein exposure on the cell surface that stimulates the sodium pump; a second is high concentrations of endogenous ouabain, an activating ligand for the pump. Both factors abnormally enhance the pump function through the triggering of the Src signaling pathway. Rostafuroxin, a derivative of digitoxigenin, acts as an antihypertensive agent by interfering with both of these ways to activate the sodium pump, preventing an increase in renal tubular Na+ transport and the resulting hypertension. In the first of the companion papers (Ferrandi et al.), the authors explore how rostafuroxin accomplishes its pressure-lowering feat. They show that the drug inhibits the Na+, K+ ATPase-Src-EGFR-ERK signaling activated by mutant adducin or ouabain, normalizing renal cell sodium transport, in two different rodent models of hypertension and in human cells. Upon closer examination of rostafurotoxin’s effects on Src-related phosphorylation in vitro, it became clear that the drug disrupts the ability of the variant adducin and the oubain-bound sodium pump to bind and activate Src at its SH2 domain. In the second of the companion papers (Lanzani et al.), the authors apply these results to patients by examining genetic variants that control the mechanisms of hypertension explored in the first paper. Lanzani et al. inspected genetic alterations in genes that encode enzymes that control ouabain synthesis and transport as well as two variants of adducin. They then tested the ability of these genetic variants to predict the response to rostafuroxin in a group of never-before treated patients with hypertension. Individuals who carried certain combinations of these genetic variants responded well to rostofuroxin, displaying a mean drop in the placebo-corrected blood pressure of about 14 mmHg, a clinically meaningful value. The same genetic signature did not predict the blood pressure response to other antihypertensive drugs with different mechanisms of action. The authors suggest that this genetic signature may exist in about a quarter of hypertensive patients. Finally, rostfuroxin may do more than lower blood pressure. Organ damage is known to be a downstream effect of an overactive Src signaling pathway—one of the byproducts of the hypertension mechanisms studied in this pair of papers. Because rostafuroxin interferes with Src signaling, the drug may curb the secondary damage to the heart, kidney, and brain caused by high blood pressure. Thus the kidney’s seemingly schizophrenic filtering actually represents a multilevel, fine-tuned control of the sodium pump as a means of managing blood pressure. Rostafuroxin can selectively correct hypertension in patients whose pumping mechanism is out of kilter, an advance toward personalized treatment of high blood pressure. Twenty years of genetic studies have not contributed to improvement in the clinical management of primary arterial hypertension. Genetic heterogeneity, epistatic-environmental-biological interactions, and the pathophysiological complexity of hypertension have hampered the clinical application of genetic findings. In the companion article, we furnished data from rodents and human cells demonstrating two hypertension-triggering mechanisms—variants of adducin and elevated concentrations of endogenous ouabain (within a particular range)—and their selective inhibition by the drug rostafuroxin. Here, we have investigated the relationship between variants of genes encoding enzymes for ouabain synthesis [LSS (lanosterol synthase) and HSD3B1 (hydroxy-δ-5-steroid dehydrogenase, 3β- and steroid δ-isomerase 1)], ouabain transport {MDR1/ABCB1 [ATP-binding cassette, sub-family B (MDR/TAP), member 1]}, and adducin activity [ADD1 (adducin 1) and ADD3], and the responses to antihypertensive medications. We determined the presence of these variants in newly recruited, never-treated patients. The genetic profile defined by these variants predicted the antihypertensive effect of rostafuroxin (a mean placebo-corrected systolic blood pressure fall of 14 millimeters of mercury) but not that of losartan or hydrochlorothiazide. The magnitude of the rostafuroxin antihypertensive effect was twice that of antihypertensive drugs recently tested in phase 2 clinical trials. One-quarter of patients with primary hypertension display these variants of adducin or concentrations of endogenous ouabain and would be expected to respond to therapy with rostafuroxin. Because the mechanisms that are inhibited by rostafuroxin also underlie hypertension-related organ damage, this drug may also reduce the cardiovascular risk in these patients beyond that expected by the reduction in systolic blood pressure alone.

Influence of Calcium-Sensing Receptor Gene on Urinary Calcium Excretion in Stone-Forming Patients

Calcium-sensing receptor (CaSR) is a plasma membrane protein that regulates tubular reabsorption of Ca. To establish its role in idiopathic hypercalciuria, the association of urinary Ca excretion with the polymorphisms of CASR gene has been studied in healthy subjects and in hypercalciuric and normocalciuric Ca stone formers. CASR exon 7 single nucleotide polymorphisms (SNP), G/T at codon 986, G/A at codon 990, and C/G at codon 1011, were evaluated by PCR amplification and direct sequencing in 97 normocalciuric stone formers, 134 hypercalciuric stone formers, and 101 normocalciuric healthy controls. Four haplotypes were defined on the basis of CASR gene SNP: haplotype 1 was characterized by the most frequent sequence; haplotypes 2, 3, or 4 by the presence of a single polymorphic variant at codon 986, 990, or 1011, respectively. The relative risk of hypercalciuria was calculated with multinomial logistic regression and was significantly increased only in individuals carrying haplotype 3 (Odds ratio, 13.0 [95% confidence interval, 1.7 to 99.4]). Accordingly, Ca excretion was higher in subjects bearing haplotype 3, whereas those bearing haplotype 2 showed a slight increase of plasma Ca concentration. Multiple regression analysis showed that haplotype 3 explained 4.1% of the total variance of Ca excretion and 12.6% of the variance explained by the variables considered in the study. In conclusion, CASR gene could be a component of the complex genetic background regulating Ca excretion. Arg990Gly polymorphism could facilitate activation of CaSR and increase Ca excretion and susceptibility to idiopathic hypercalciuria.

Genomewide association study using a high-density single nucleotide polymorphism array and case-control design identifies a novel essential hypertension susceptibility locus in the promoter region of endothelial NO synthase

Essential hypertension is a multifactorial disorder and is the main risk factor for renal and cardiovascular complications. The research on the genetics of hypertension has been frustrated by the small predictive value of the discovered genetic variants. The HYPERGENES Project investigated associations between genetic variants and essential hypertension pursuing a 2-stage study by recruiting cases and controls from extensively characterized cohorts recruited over many years in different European regions. The discovery phase consisted of 1865 cases and 1750 controls genotyped with 1M Illumina array. Best hits were followed up in a validation panel of 1385 cases and 1246 controls that were genotyped with a custom array of 14 055 markers. We identified a new hypertension susceptibility locus (rs3918226) in the promoter region of the endothelial NO synthase gene (odds ratio: 1.54 [95% CI: 1.37–1.73]; combined P=2.58 · 10−13). A meta-analysis, using other in silico/de novo genotyping data for a total of 21 714 subjects, resulted in an overall odds ratio of 1.34 (95% CI: 1.25–1.44; P=1.032 · 10−14). The quantitative analysis on a population-based sample revealed an effect size of 1.91 (95% CI: 0.16–3.66) for systolic and 1.40 (95% CI: 0.25–2.55) for diastolic blood pressure. We identified in silico a potential binding site for ETS transcription factors directly next to rs3918226, suggesting a potential modulation of endothelial NO synthase expression. Biological evidence links endothelial NO synthase with hypertension, because it is a critical mediator of cardiovascular homeostasis and blood pressure control via vascular tone regulation. This finding supports the hypothesis that there may be a causal genetic variation at this locus.

Plasma Ouabain-Like Factor During Acute and Chronic Changes in Sodium Balance in Essential Hypertension

Abstract—An ouabain-like factor has been implicated repeatedly in salt-sensitive hypertension as a natriuretic agent. However, the response of plasma ouabain-like factor to acute and chronic variation of body sodium is unclear. We studied 138 patients with essential hypertension who underwent an acute volume expansion/contraction maneuver (2 days) and 20 patients who entered a blind randomized crossover design involving chronically controlled sodium intake and depletion (170 to 70 mmol/d; 2 weeks each period). In both studies, plasma levels of ouabain-like factor were higher during sodium depletion (acute: 338.8±17.4 and 402.7±22.8 pmol/L for baseline and low sodium, respectively, P <0.01; chronic: 320.4±32.0 versus 481.0±48.1 pmol/L, P =0.01). No significant change in plasma ouabain-like factor was observed after a 2-hour saline infusion (333.4±23.9 pmol/L) or controlled sodium (402.1±34.9 pmol/L). When patients were divided into salt-sensitive or salt-resistant groups, no differences in plasma ouabain-like factor were observed in the 2 groups at baseline or in response to the 2 protocols: salt resistant (n=69, 340.1±25.9 pmol/L) versus salt sensitive (n=69, 337.4±23.6 pmol/L) and chronic salt resistant (n=11, 336.0±53.2) versus salt sensitive (n=9, 301.1±331.4 pmol/L). However, circulating ouabain-like factor was increased by sodium depletion in both groups. These results demonstrate that circulating ouabain-like factor is raised specifically by maneuvers that promote the loss of body sodium. Acute expansion of body fluids with isotonic saline is not a stimulus to plasma ouabain-like factor. Moreover, basal levels of plasma ouabain-like factor do not differ among patients with salt-sensitive or salt-resistant hypertension. Taken together, these new results suggest that ouabain-like factor is involved in the adaptation of humans to sodium depletion and argue against the hypothesis that ouabain-like factor is a natriuretic hormone.

Copy-Number Disorders Are a Common Cause of Congenital Kidney Malformations

We examined the burden of large, rare, copy-number variants (CNVs) in 192 individuals with renal hypodysplasia (RHD) and replicated findings in 330 RHD cases from two independent cohorts. CNV distribution was significantly skewed toward larger gene-disrupting events in RHD cases compared to 4,733 ethnicity-matched controls (p = 4.8 × 10(-11)). This excess was attributable to known and novel (i.e., not present in any database or in the literature) genomic disorders. All together, 55/522 (10.5%) RHD cases harbored 34 distinct known genomic disorders, which were detected in only 0.2% of 13,839 population controls (p = 1.2 × 10(-58)). Another 32 (6.1%) RHD cases harbored large gene-disrupting CNVs that were absent from or extremely rare in the 13,839 population controls, identifying 38 potential novel or rare genomic disorders for this trait. Deletions at the HNF1B locus and the DiGeorge/velocardiofacial locus were most frequent. However, the majority of disorders were detected in a single individual. Genomic disorders were detected in 22.5% of individuals with multiple malformations and 14.5% of individuals with isolated urinary-tract defects; 14 individuals harbored two or more diagnostic or rare CNVs. Strikingly, the majority of the known CNV disorders detected in the RHD cohort have previous associations with developmental delay or neuropsychiatric diseases. Up to 16.6% of individuals with kidney malformations had a molecular diagnosis attributable to a copy-number disorder, suggesting kidney malformations as a sentinel manifestation of pathogenic genomic imbalances. A search for pathogenic CNVs should be considered in this population for the diagnosis of their specific genomic disorders and for the evaluation of the potential for developmental delay.