ABSTRACT
Background: Familial hyperaldosteronism type I is caused by the generation of a chimeric aldosterone synthase enzyme (ASCE) which is regulated by ACTH instead of angiotensin II. We have reported that in vitro, the wild-type (ASWT) and chimeric aldosterone synthase (ASCE) enzymes are inhibited by progesterone and estradiol does not affect their activity. Aim: To explore the direct action of testosterone on ASWT and ASCE enzymes. Material and Methods: HEK-293 cells were transiently transfected with vectors containing the full ASWT or ASCE cDNAs. The effect of testosterone on AS enzyme activities was evaluated incubating HEK-cells transfected with enzyme vectors and adding deoxycorticosterone (DOC) alone or DOC plus increasing doses of testosterone. Aldosterone production was measured by HPLC-MS/MS. Docking of testosterone within the active sites of both enzymes was performed by modelling in silico. Results: In this system, testosterone inhibited ASWT (90% inhibition at five pM, 50% inhibitory concentration (IC50) =1.690 pM) with higher efficacy andpotency than ASCE (80% inhibition at five pM, IC50=3.176 pM). Molecular modelling studies showed different orientation of testosterone in ASWT and ASCE crystal structures. Conclusions: The inhibitory effect of testosterone on ASWT or ASCE enzymes is a novel non-genomic testosterone action, suggesting that further clinical studies are needed to assess the role of testosterone in the screening and diagnosis of primary aldosteronism.
ABSTRACT
Background: Type I familial hyperaldosteronism is caused by the presence of a chimaetic gene CYPl 1B1/CYP11BZ which encodes an enzyme with aldosterone synthetase activityregulated by adrenocorticotrophic hormone (ACTH). Therefore, in patients with FH I is possible to normalize the aldosterone levels with glucocorticoid treatment. Recently it has been shown that aldosterone plays a role in the production of endothelial oxidative stress and subclinical inflammation. Aim: To evaluate subclinical endothelial inflammation markers, Me Metalloproteinase 9 (MMP-9) and ultrasensitive C reactive protein (usPCR), before and after glucocorticoid treatment in family members with FH-I caused by a de novo mutation. Patients and methods: We report three subjects with FH-I in a single family (proband, father and sister). We confirmed the presence of a chimaeric CYPl 1B1/CYP11B2 gene by ¡ong-PCR in all of them. Paternal grandparents were unaffected by the mutation. The proband was a 13year-old boy with hypertension stage 2 (in agree to The JointNational Committee VII, JNC-vIl), with an aldosterone/plasma rennin activity ratio equal to 161. A DNA paternity test confirmed the parental relationship between the grandparents and father with the index case. MMP-9 and usPCR levels were determined by gelatin zymography and nephelometry, respectively. Results: All affected subjects had approximately a 50 percent increase in MMP-9 levels. Only the father had an elevated usPCR. The endothelial inflammation markers returned to normal range after glucocorticoid treatment. Conclusions: We report a family canying a FH-I caused by a de novo mutation. The elevation of endothelial inflammation markers in these patients and its normalization after glucocorticoid treatment provides new insight about the possible deleterious effect of aldosterone on the endothelium.
Subject(s)
Adolescent , Female , Humans , Male , C-Reactive Protein/analysis , Endothelium, Vascular , Hyperaldosteronism/genetics , Matrix Metalloproteinase 9/blood , Mutation/genetics , Vasculitis/blood , Cytochrome P-450 CYP11B2/genetics , Aldosterone/blood , Biomarkers/blood , Hyperaldosteronism/blood , Oxidative Stress/physiology , Paternity , Polymerase Chain Reaction/methods , /genetics , Vasculitis/geneticsABSTRACT
Primary aldosteronism (PA) is a known cause of hypertension. In the kidney, aldosterone promotes sodium and water reabsorption, increasing the intravascular volume and blood pressure (BP). In the cardiovascular system, aldosterone modifies endothelial and smooth muscle cell response, increasing cardiovascular risk in a blood pressure-independent way. Recently a high prevalence of PA (near to 10 percent) in hypertensive population, has been detected measuring plasma aldosterone/renin activity ratio (ARR) as screening test. This ratio increases along with the severity of the hypertensive disease. The diagnostic work up of PA should confirm the autonomy of aldosterone secretion from the renin-angiotensin system and should differentiate the clinical subtypes of the disease. These are idiopathic aldosteronism (IA) and aldosterone-producing adenoma (APA). Other causes are familial hyperaldosteronism (FH) type I (glucocorticoid-remediable aldosteronism), FH-II (non glucocorticoid-remediable aldosteronism), primary adrenal hyperplasia and adrenal carcinoma. This article reviews the prevalence, diagnosis and treatment of PA and also the clinical, biochemical and genetic characteristics ofits different subtypes.
Subject(s)
Humans , Aldosterone/metabolism , Hyperaldosteronism/diagnosis , Hypertension/etiology , Aldosterone , Hyperaldosteronism/complications , Hyperaldosteronism/therapy , Hypertension/blood , Mass Screening , Renin-Angiotensin System , Renin/bloodABSTRACT
Background: Cortisol has been implicated in hypertension and lately reported to be regulated at the pre-receptor level by the 11ßHSD1 enzyme, which converts cortisone (E) to cortisol (F). Over expression ofthis enzyme in adipose tissue could determine an increase in available cortisol that interacts with the mineralocorticoid receptor (MR) in renal, brain and heart tissue, leading to similar hypertensive effects as in 11ßHSD2 impaired patients. Severa! polymorphisms have been reported in HSDl IB 1 gene (CAI5, CAI9 and InsA83557), which could modify HSDl IB 1 gene expression or activity. Aun: To determine the distribution and prevalence of CAI5, CAI9 and InsA83557 in the HSDl IBl gene, and to correlate these results with biochemical parameters in cortisol/ ACTH (HPA) and renin-angiotensin-aldosterone (RAA) axis in patients with essential hypertension (EH). Patients and Methods: We studied 113 EHpatients (76 non-obese and 37 obese, with a body mass índex >30 kg/m²) and 30 normotensive adults (NT). In each patient, we measured serum levéis of E E, serum aldosterone (SA), plasma renin activity (PRA), adrenocorticotrophic hormone (ACTH), the urinary free cortisol/creatinine (UFF/Cr), F/ACTH and SA/PRA ratios. Each polymorphism was studied by PCR and 8 percent polyacrylamide gel electrophoresis. Statistical associations were evaluated by Pearson correlations and the genetic equilibñum by the Hardy-Weinberg (H-W) equation. Results: We found all three polymorphisms in the EH and the NT group, both in genetic equilibñum. In obese essential hypertensives, the CAI5polymorphism showed association with SA/PRA ratio (r =0.189, p =0.012) and F/ACTH (r =0.301, p 0.048); CA19 also showed correlation with F/ACTH in obese EH (r = 0.220, p 0.009). The InsA83557polymorphism correlated with UFF/Cr in both EH (r =0.206; p =0.03), and in obese EH (r =0.354; p =0.05). Conclusions: The CAI5 and CAI9 polymorphism correlated with changes in biochemical parameters...
Subject(s)
Adult , Female , Humans , Male , Young Adult , Hypertension/genetics , Polymorphism, Genetic , /genetics , /metabolism , Adrenocorticotropic Hormone/blood , Aldosterone/blood , Case-Control Studies , Chronic Disease , Cortisone/biosynthesis , Gene Frequency , Hydrocortisone/blood , Hypertension/enzymology , Microsatellite Repeats , Obesity/enzymology , Obesity/genetics , Polymerase Chain Reaction , Renin/blood , Young AdultABSTRACT
Type I familial hyperaldosteronism (HAF-I) is caused by the presence of a chimeric gene CYP11B1/CYP11B2 which encodes an enzyme with aldosterone synthetase activity regulated by ACTH. HAF-I patients present with severe hypertension at young ages and a greater risk of stroke. AIM: To characterize clinical and biochemical presentation of family members with HAF-I. To evaluate endothelial oxidative stress markers before and after glucocorticoid treatment. PATIENTS AND METHODS: We evaluated three family members with HAF-I confirmed with a genetic test (XL-PCR) for chimeric gene CYP11B1/CYP11B2. The index case was a 13 years old boy with stage 2 hypertension (Joint National Committee VIIth report), plasma aldosterone/ plasma renin activity (AP/ARP) ratio of161 and normal plasma potassium. His father had primary hyperaldosteronism diagnosed at 25 years of age with hypertension and hypokalemia. His sister was 15 years old, with a normal blood pressure and an AP/ARP ratio of 37.6. RESULTS: All subjects had plasma xanthine-oxidase levels in the upperlimit of normal. Malondialdehyde was above normal in the index case and his father. These markers returned to normal with glucocorticoid treatment. CONCLUSIONS: We report a HAF-I carrying family with a wide phenotypical variability between affected members. Elevation of endothelial oxidativestress markers and its normalization after glucocorticoid treatment, may indicate that aldosterone produces endothelial damage and increases cardiovascular risk.
Subject(s)
Humans , Male , Adolescent , Middle Aged , Oxidative Stress , Glucocorticoids/therapeutic use , Hyperaldosteronism/genetics , Hyperaldosteronism/drug therapy , Cytochrome P-450 CYP11B2/genetics , Endothelial Cells , /genetics , Phenotype , Hyperaldosteronism/physiopathology , BiomarkersABSTRACT
Background: Hypertensive states could result from constitutive activation of mineralorticoid receptor (MR) that generates salt retention and blood pressure elevation. Moreover, microsatellite regions can be associated to the regulation of the gene expression, producing subtle pathologies. Aim: To determine the influence of microsatellite marker AGAT of the mineralocorticoid receptor gene in the plasma renin activity (PRA) and serum aldosterone (SA) levels of essential hypertensives (HT). Patients and Methods: We studied 292 HT patients and 57 normotensive (NT) controls. Blood samples were collected for PRA, SA and DNA isolation. Subjects were genotyped according to the length of the tetranucleotide AGAT repeat using polymerase chain reaction and polyacrylamide gel electrophoresis. Based on the normal distribution, we considered 13 to 15 repeats as a habitual (H) length and less than 13 or more than 15 repeats, as non-habitual (non-H). Results: We detected 8 different lengths in the AGAT repeat (allele) in both groups, ranging from 9-17 repeats, where the allele 11 was not detected in either hypertensive or normotensive groups. The allelic distribution was different in both groups (c2=37.57, 4GL, p <0.001). In hypertensive patients, the H group showed higher PRA levels (median (Q1-Q3)) than the non-H group: 1.3 (0-7-3.5) vs 1.0 (0.5-2.3) ng/mL*h, p <0.05. The SA levels did not show differences between both groups, but the SA*PRA product was higher in the H group than the no-H group: 9.3 (3.0-24.6) vs 6.5 (2.5-14.6) p <0.05. In normotensive patients, no differences were observed in PRA, SA and SA*PRA between both groups. Conclusion: These results show association between the length of the AGAT repeat with the PRA in HT, suggesting a plausible role in the control of the MR gene expression, and secondarily in the regulation of blood pressure .