Sachiko Suematsu

Human renal mesangial cells produce aldosterone in response to low-density lipoprotein (LDL)

Systemic aldosterone plays an important role in the development of the microvascular disease and glomerular damage of the kidney in patients with diabetes mellitus and hyperlipidemia. Here, we investigated the possibility of local production of aldosterone in the kidney, using human primary glomerular mesangial cells. These cells produced both pregnenolone and aldosterone measured by specific radioimmunoassay and/or gas chromatography/mass spectrometry (GC/MS) methods. The production of both steroids was significantly stimulated by treatment with LDL, while angiotensin II had a synergistic effect. Adrenocorticotropic hormone (ACTH) and (Bu)2cAMP, on the other hand, failed to stimulate aldosterone production by these cells, suggesting that the local production of this steroid by mesangial cells is regulated differently from that of adrenal zona glomerulosa cells. Mesangial cells expressed the mRNA of the LDL receptor and steroidogenic enzymes, such as P450scc, 3beta-hydroxysteroid dehydrogenase (3beta-HSD), 21-hydroxylase and CYP11B2. Mesangial cells also expressed mRNA of the mineralocorticoid receptor (MR), and LDL stimulated its abundance by three-fold, while spironolactone, a completive antagonist of aldosterone, completely abolished this LDL effect. Since MR is a known mineralocorticoid-responsive gene as well as an intracellular receptor molecule for this steroid, these results suggest that locally produced aldosterone is biologically active, stimulating the transcription rates of the mineralocorticoid-responsive genes by activating the MR in mesangial cells. These pieces of evidence indicate that human mesangial cells are an aldosterone-producing tissue in which LDL plays a major regulatory role. Therefore, human renal mesangial endocrine system may contribute to local aldosterone concentrations and effects in the renal glomerulus independently of the systemic renin--angiotensin--aldosterone system and may participate in the development and progression of glomerular damage in several pathologic conditions.

Comparison of Cardiovascular Complications in Patients with and without KCNJ5 Gene Mutations Harboring Aldosterone-producing Adenomas

AIM Our objective was to evaluate the incidence of cardiovascular complications before and after unilateral adrenalectomy in patients with and without KCNJ5 gene mutations harboring aldosterone-producing adenoma (APA). METHODS A total of 108 APA patients were evaluated in the present study. We compared the clinical characteristics and laboratory findings according to the cardiovascular complications in the patients with or without KCNJ5 gene mutations harboring APA after excluding five APA patients with ATPase or CACNA1D gene mutations. RESULTS There were 75 and 28 APA patients with somatic mutations of KCNJ5 (p.G151R, p.L168R, p.E145Q, p.T158A or 157del) and no mutations, respectively. There were no double mutations in any of the subjects. The KCNJ5-mutated and wild type groups demonstrated similar advances in left ventricular hypertrophy prior to surgery, although the mutated group was significantly younger, with higher plasma and urine aldosterone levels, than the wild type group (48.2 vs. 55.8 (years old); p＜0.001, 436.0 vs. 247 (pg/mL); p＜0.001, 22.2 vs. 12.6 (μg/day); p=0.008). Both groups displayed postoperative improvements in hyperaldosteronism and hypertension. Moreover, the LV mass index (LVMI) significantly improved after surgery in the mutated group (p＜0.001), but not in the wild type group (p=0.256). A multiple linear regression analysis showed that an improvement in the LVMI was independently associated with KCNJ5 mutations and the plasma aldosterone level in that order (p=0.034, 0.050, respectively). CONCLUSION The present findings clearly demonstrated that KCNJ5 mutations are common among Japanese APA patients (frequency: 69.4%). In this study, the KCNJ5-mutated group demonstrated significant postoperative improvements in LVMI, possibly due to strong autonomous aldosterone production. Hence, it is necessary to precisely diagnose younger APA patients possessing a strong capacity for aldosterone production due to KCNJ5 gene mutations, as such cases may be easily complicated by cardiovascular events.

Clinical and Steroidogenic Characteristics of Aldosterone-Producing Adenomas With ATPase or CACNA1D Gene Mutations

OBJECT This comparative study clarified the clinical characteristics and in vitro steroidogenic activities of aldosterone-producing adenomas (APAs) harboring ATPase or CACNA1D gene mutations. DESIGN AND PATIENTS Genetic testing was performed on 159 unilateral APAs. Somatic ATPase and CACNA1D gene mutations were analyzed in 42 APA tissues without KCNJ5 gene mutations. RESULTS ATP1A1, ATP2B3, and CACNA1D mutations were detected in one, four, and four patients, respectively. Compared with patients without KCNJ5, ATPase, or CACNA1D mutations (wild type), ATPase mutations tended to have more severe hyperaldosteronism and smaller tumors; those with CACNA1D mutations had clinical characteristics and tumor sizes similar to those with wild-type genes. APAs with ATPase mutations were composed mainly of compact eosinophilic tumor cells, whereas CACNA1D mutations resulted in predominantly clear tumor cells. Aldosterone production in APA cells with ATP2B3 mutations were more responsive to dibutyryl cAMP, whereas those with CACNA1D mutations were more responsive to adrenocorticotropic hormone than the wild-type cells. CONCLUSION APAs with ATPase mutations demonstrated a potentially severe primary aldosteronism phenotype, whereas those with CACNA1D mutations displayed characteristics similar to wild-type APAs. The status of stimulated aldosterone production was also different according to the cell types, suggesting that the regulatory effects of adrenocorticotropic hormone on aldosterone synthesis could possibly vary according to the intracellular signaling involved in hormone production.

Somatic KCNJ5 mutation occurring early in adrenal development may cause a novel form of juvenile primary aldosteronism.

We report a case of non-familial juvenile primary aldosteronism (PA). Super-selective adrenal venous sampling identified less aldosterone production in the right inferior adrenal segment than others. Bilateral adrenalectomy sparing the segment normalized blood pressure and improved PA. Both adrenals had similar histologies, consisting of a normal adrenal cortex and aldosterone synthase-positive hyperplasia/adenoma. An aldosterone-driving KCNJ5 mutation was detected in the lesions, but not in the histologically normal cortex. After taking into account that the two adrenal glands displayed a similar histological profile, as well as the fact that hyperplastic lesions in both glands exhibited a common KCNJ5 mutation, we conclude that the specific mutation may have occurred at an adrenal precursor mesodermal cell, at an early stage of development; its daughter cells were mixed with non-mutant cells and dispersed into both adrenal glands, resulting into a form of the condition known as genetic mosaicism.

Effect of atorvastatin on aldosterone production induced by glucose, LDL or angiotensin II in human renal mesangial cells

Nephropathy is a major complication of diabetes mellitus, thus development of rational therapeutic means is critical for improving public health. It was previously reported that human mesangial cells locally produced aldosterone, a steroid hormone that plays an important role in the development of diabetic nephropathy. The present experiments clarified the effect of glucose, LDL and angiotensin II, the molecules frequently elevated in patients with diabetic nephropathy, on aldosterone production in human primary mesangial cells. These cells expressed the CYP11B2 mRNA, a rate-limiting enzyme in the aldosterone biosynthesis. LDL and angiotensin II stimulated CYP11B2 mRNA expression in these cells, while a high concentration of glucose, angiotensin II and/or LDL increased aldosterone production. Importantly, atorvastatin (CAS 134523-03-8), an HMG-CoA (3-hydroxy-3-methylglutaryl-coenzyme A) reductase inhibitor, strongly suppressed their effects on aldosterone production. Atorvastatin also suppressed positive effects of these compounds on the mRNA expression of the angiotensin II receptor type 1, thus atorvastatin exerted its negative effect in part through changing expression of this receptor. Since elevated levels of glucose and LDL, and increased action of the renin-angiotensin-aldosterone system is known to participate in the progression of diabetic nephropathy, it is speculated that the mesangial endocrine system that produces aldosterone locally is a promising therapeutic target for diabetic nephropathy where HMG-CoA reductase inhibitors provide a beneficial effect.

Vascular Aldosterone Production at the Pre-Diabetic Stage of Young Otsuka Long-Evans Tokushima Fatty (OLETF) Rats, Compared with Long-Evans Tokushima Otsuka (LETO) Rats

We examined the ability of aortic smooth muscle cells (AoSMC) prepared from spontaneously diabetic rats to produce aldosterone (Aldo) and the regulatory mechanism that controls their Aldo production. AoSMC of 6 week-old Long-Evans Tokushima Otsuka (LETO: the control group) and 6 week-old Otsuka Long-Evans Tokushima Fatty (OLETF: the type 2 diabetes group) rats were used in the present experiments. CYP11B2 (Aldo synthetase) mRNA expression was detected in both the LETO and OLETF AoSMC. Basal Aldo production was significantly greater (4–5 fold higher) in the OLETF AoSMC culture medium than in the LETO AoSMC culture medium. When AoSMC were co-incubated with high-density lipoproteins (HDL), supplying cholesterol as a substrate for steroidogenesis in rats, angiotensin II (AII) significantly increased greater Aldo production in the OLETF AoSMC than in the LETO AoSMC. The present data suggested that future onset of diabetic vascular dysfunction is partly caused by excess Aldo production by AoSMC in young OLETF rats. Concomitant stimulation by HDL and AII resulted in elevated Aldo production in the OLETF and the LETO AoSMC, and also demonstrated that AII-induced Aldo production is greatly enhanced by HDL in OLETF, rather than in LETO. In conclusion, our data clearly demonstrated that Aldo production in the OLETF AoSMC was significantly higher than in the LETO AoSMC, suggesting possible future onset of vascular dysfunction in diabetes, induced by local Aldo production in the AoSMC.

Evaluation of Cortisol Production in Aldosterone-Producing Adenoma

Aldosterone-producing adenoma (APA) is sometimes accompanied with subclinical hypercortisolism. We investigated the ability of cortisol production in APA, both clinically and pathologically. A retrospective cohort study was conducted at Yokohama Rosai Hospital from 2009 to 2016. Thirty patients with APA and serum cortisol levels during the 1 mg dexamethasone suppression test (F-DST)<3.0 μg/dl were included. We evaluated the 1) difference between pre-adrenalectomy F-DST (pre-F-DST) and post-adrenalectomy F-DST (ΔF-DST), 2) correlation between ∆F-DST and pre-F-DST, tumour size determined by CT, and type of adrenalectomy (total or partial), and 3) relationship between the ratio of F-DST divided by tumour size (ΔF-DST/pre-F-DST/mm) and immunoreactivity of CYP17A1, CYP11B1, and CYP11B2. The median [interquartile range] age was 48 [38-58] years. We found a significant decrease in F-DST after adrenalectomy [before: 1.4 (1.1-1.8); after: 0.9 (0.6-1.2); p<0.001]. Additionally, a significant correlation was found for ΔF-DST and both pre-F-DST (Spearman, ρ=-0.68, p<0.001) and tumour size (ρ=-0.51, p 0.005). No significant difference was found in ΔF-DST between total and partial adrenalectomy. CYP17A1 and CYP11B1 were positive in 21 (100%) and 17 (81%) adenomas, respectively. CYP17A1 immunoreactivity in the tumour was significantly related with ΔF-DST/pre-F-DST/mm (p 0.049). F-DST significantly decreased after adrenalectomy, and most of the adenomas were immunohistochemically positive for CYP17A1 and CYP11B1 as well as CYP11B2. We should consider the possibility of autonomous cortisol production as well as hyperaldosteronism in the evaluation and treatment of APA patients.

Guanosine triphosphate can directly regulate cortisol production by activating Ca 2+ -messenger systems in bovine adrenal fasciculata cells

Adenosine triphosphate (ATP) is known to stimulate cortisol production in vitro, however, the effect of guanosine triphosphate (GTP) on cortisol production is not known. We studied the effect of GTP on cortisol production and investigated the regulation of intracellular signal transduction systems, including the cyclic AMP-dependent and Ca(2+)-messenger systems, in bovine adrenal fasciculata cells. GTP clearly induced cortisol biosynthesis but only to a level less than half the adrenocorticotropic hormone (ACTH)-induced maximum. The binding site for [γ-(35)S]-GTPγS was shown to differ completely from that for ATP and also from those for Gs and Gi, as indicated by the fact that binding was not influenced by pretreatment with cholera toxin and pertussis toxin. GTP significantly increased cytosolic calcium ([Ca(2+)]i) and inositol 1, 4, 5-triphosphate without affecting cyclic AMP formation. GTP-induced cortisol production was suppressed by H-9 and Calphostin C (specific protein kinase C inhibitors) but not by H-8 and KT5720 (specific inhibitors of cyclic AMP-dependent protein kinase), suggesting that GTP activates cortisol biosynthesis possibly via a protein kinase C-dependent pathway. Extracellular calcium may be essential for GTP activity since GTP-induced cortisol production was almost completely suppressed in its absence. In conclusion, it can be postulated that GTP-induced steroid secretion in bovine adrenal fasciculata cells is under paracrine or autocrine control.

Steroidogenic Activity of Aldosterone-Producing Adenoma with and without KCNJ5 Gene Mutations, Comparing with that in Each Adherent Normal Tissue

Introduction: The steroidogenic activity in a KCNJ5-gene mutated aldosterone-producing adenoma (APA) was reported to be much stronger than that in an APA of the wild type, while it is still controversial. Objectives: We examined whether the normal adrenal tissue attached to APA also possesses KCNJ5 gene mutations, and also investigated steroidogenic activity of mutated and non-mutated APA tissue cells with that of each normal tissue cell attached to APA in order to clarify the nature of steroidogenic activity. Methods: We selected 12 patients with and without KCNJ5 gene mutation-harboring APA in whom normal adrenal tissue adhered to the APA. We analyzed the presence of KCNJ5 gene mutations by using those tissues. Results: APA tissues of 6 patients possessed KCNJ5 gene mutations, whereas those mutations were not detected in any of the adjacent normal tissue samples as well as another 6 cases of APA. In two APA tissues with or without KCNJ5 gene mutation, we also compared the steroidogenic activity of isolated cells from each APA tissue with that from the normal adherent tissues. The cortisol production of the mutated APA cells was markedly decreased compared with that of the normal cells, suggesting that the aldosterone production pathway becomes dominant and the cortisol production pathway is downregulated in that APA tissue. Furthermore, the ratio of aldosterone to cortisol in the normal adherent tissue was about 1/4th of that of the wild-type APA tissue, while it was about 1/10th in the mutated APA. Conclusion: KCNJ5 gene mutations in the normal tissue adhering to KCNJ5 gene mutation-harboring APA was not observed, suggesting that somatic mutations of the KCNJ5 gene only occur in APA tissue. It is also suggested that KCNJ5 gene mutations dominantly induce the aldosterone production pathway as well as concomitant decline in cortisol production, resulting in highly autonomous aldosterone production.