Defective fasciculata zone function as the mechanism of glucocorticoid-remediable aldosteronism

Primary aldosteronism diagnostics: KCNJ5 mutations and hybrid steroid synthesis in aldosterone-producing adenomas

Primary aldosteronism (PA) is characterized by autonomous aldosterone production by renin-independent mechanisms and is most commonly sporadic. While 60-70% of sporadic PA can be attributed to bilateral hyperaldosteronism, the remaining 30-40% is caused by a unilateral aldosterone-producing adenoma (APA). Somatic mutations in or near the selectivity filter the KCNJ5 gene (encoding the potassium channel GIRK4) have been implicated in the pathogenesis of both sporadic and familial PA. Several studies using tumor tissue, peripheral and adrenal vein samples from PA patients have demonstrated that along with aldosterone, the hybrid steroids 18-hydroxycortisol (18OHF) and 18-oxocortisol (18oxoF) are a hallmark of APA harboring KCNJ5 mutations. Herein, we review the recent advances with respect to the molecular mechanisms underlying the pathogenesis of PA and the steroidogenic fingerprints of KCNJ5 mutations. In addition, we present an outlook toward the future of PA subtyping and diagnostic work-up utilizing steroid profiling.

Old and new genes in primary aldosteronism

Primary aldosteronism (PA) is the most common form of secondary hypertension affecting 5%-10% of patients with arterial hypertension. In PA, high blood pressure is associated with high aldosterone and low renin levels, and often hypokalemia. In a majority of cases, autonomous aldosterone production by the adrenal gland is caused by an aldosterone producing adenoma (APA) or bilateral adrenal hyperplasia (BAH). During the last ten years, a better knowledge of the pathophysiology of PA came from the discovery of somatic and germline mutations in different genes in both sporadic and familial forms of the disease. Those genes code for ion channels and pumps, as well as proteins involved in adrenal cortex development and function. Targeted next generation sequencing following immunohistochemistry guided detection of aldosterone synthase expression allows detection of somatic mutations in up to 90% of APA, while whole exome sequencing has discovered the genetic causes of four different familial forms of PA. The identification, in BAH, of somatic mutations in aldosterone producing cell clusters open new perspectives in our understanding of the bilateral form of the disease and the development of new therapeutic approaches.

DIAGNOSIS OF ENDOCRINE DISEASE: 18-Oxocortisol and 18-hydroxycortisol: is there clinical utility of these steroids?

Since the early 1980s 18-hydroxycortisol and 18-oxocortisol have attracted attention when it was shown that the urinary excretion of these hybrid steroids was increased in primary aldosteronism. The development and more widespread use of specific assays has improved the understanding of their role in the (patho)physiology of adrenal disorders. The adrenal site of synthesis is not fully understood although it is clear that for the synthesis of 18-hydroxycortisol and 18-oxocortisol the action of both aldosterone synthase (zona glomerulosa) and 17α-hydroxylase (zona fasciculata) is required with cortisol as main substrate. The major physiological regulator is ACTH and the biological activity of both steroids is very low and therefore only very high concentrations might be effective in vivo In healthy subjects, the secretion of both steroids is low with 18-hydroxycortisol being substantially higher than that of 18-oxocortisol. The highest secretion of both steroids has been found in familial hyperaldosteronism type 1 (glucocorticoid-remediable aldosteronism) and in familial hyperaldosteronism type 3. Lower but yet substantially increased secretion is found in patients with aldosterone-producing adenomas in contrast to bilateral hyperplasia in whom the levels are similar to patients with hypertension. Several studies have attempted to show that these steroids, in particular, peripheral venous plasma 18-oxocortisol, might be a useful discriminatory biomarker for subtyping PA patients. The current available limited evidence precludes the use of these steroids for subtyping. We review the biosynthesis, regulation and function of 18-hydroxycortisol and 18-oxocortisol and their potential utility for the diagnosis and differential diagnosis of patients with primary aldosteronism.

Pathophysiology, diagnosis, and treatment of mineralocorticoid disorders

The renin-angiotensin-aldosterone system (RAAS) is a major regulator of blood pressure control, fluid, and electrolyte balance in humans. Chronic activation of mineralocorticoid production leads to dysregulation of the cardiovascular system and to hypertension. The key mineralocorticoid is aldosterone. Hyperaldosteronism causes sodium and fluid retention in the kidney. Combined with the actions of angiotensin II, chronic elevation in aldosterone leads to detrimental effects in the vasculature, heart, and brain. The adverse effects of excess aldosterone are heavily dependent on increased dietary salt intake as has been demonstrated in animal models and in humans. Hypertension develops due to complex genetic influences combined with environmental factors. In the last two decades, primary aldosteronism has been found to occur in 5% to 13% of subjects with hypertension. In addition, patients with hyperaldosteronism have more end organ manifestations such as left ventricular hypertrophy and have significant cardiovascular complications including higher rates of heart failure and atrial fibrillation compared to similarly matched patients with essential hypertension. The pathophysiology, diagnosis, and treatment of primary aldosteronism will be extensively reviewed. There are many pitfalls in the diagnosis and confirmation of the disorder that will be discussed. Other rare forms of hyper- and hypo-aldosteronism and unusual disorders of hypertension will also be reviewed in this article.

Glucocorticoid-remediable aldosteronism

Glucocorticoid-remediable aldosteronism (GRA) is a hereditary form of primary hyperaldosteronism and the most common monogenic cause of hypertension. A chimeric gene duplication leads to ectopic aldosterone synthase activity in the cortisol-producing zona fasciculata of the adrenal cortex, under the regulation of adrenocorticotropin (ACTH). Hypertension typically develops in childhood, and may be refractory to standard therapies. Hypokalemia is uncommon in the absence of treatment with diuretics. The discovery of the genetic basis of the disorder has permitted the development of accurate diagnostic testing. Glucocorticoid suppression of ACTH is the mainstay of treatment; alternative treatments include mineralocorticoid receptor antagonists.

Inherited forms of mineralocorticoid hypertension

PURPOSE OF REVIEW

Inherited forms of mineralocorticoid hypertension are a group of monogenic disorders that, although rare, have enlightened our understanding of normal physiology, and subsequent processes implicated in the pathogenesis of 'essential' hypertension. They often present in early life and can be a cause of major morbidity and mortality that can be effectively treated with simple but targeted pharmacological therapy. Interestingly, all the conditions centre on the regulation of sodium transport through its epithelial channel, either directly or through mediators that act via the mineralocorticoid receptor.

RECENT FINDINGS

In recent years, molecular mechanisms of these conditions and their functional consequences have been elucidated. Diagnosis has been facilitated by plasma and urinary biomarkers.

SUMMARY

We provide an overview and diagnostic approach to apparent mineralocorticoid excess, glucocorticoid remediable aldosteronism, familial hyperaldosteronism type 2, Liddle's syndrome, Gordon's syndrome, activating mutations of the mineralocorticoid receptor, generalized glucocorticoid resistance and hypertensive forms of congenital adrenal hyperplasia.

A novel form of human mendelian hypertension featuring nonglucocorticoid-remediable aldosteronism

CONTEXT

Primary aldosteronism is a leading cause of secondary hypertension (HTN), but the mechanisms underlying the characteristic renin-independent secretion of aldosterone remain unknown in most patients.

OBJECTIVES

We report a new familial form of aldosteronism in a father and two daughters. All were diagnosed with severe HTN refractory to medical treatment by age 7 yr. We performed a variety of clinical, biochemical, and genetic studies to attempt to clarify the underlying molecular defect.

RESULTS

Biochemical studies revealed hyporeninemia, hyperaldosteronism, and very high levels of 18-oxocortisol and 18-hydroxycortisol, steroids that reflect oxidation by both steroid 17-alpha hydroxylase and aldosterone synthase. These enzymes are normally compartmentalized in the adrenal fasciculata and glomerulosa, respectively. Administration of dexamethasone failed to suppress either aldosterone or cortisol secretion; these findings distinguish this clinical syndrome from glucocorticoid-remediable aldosteronism, another autosomal dominant form of HTN, and suggest a global defect in the regulation of adrenal steroid production. Genetic studies excluded mutation at the aldosterone synthase locus, further distinguishing this disorder from glucocorticoid-remediable aldosteronism. Because of unrelenting HTN, all three subjects underwent bilateral adrenalectomy, which in each case corrected the HTN. Adrenal glands showed dramatic enlargement, with paired adrenal weights as high as 82 g. Histology revealed massive hyperplasia and cellular hypertrophy of a single cortical compartment that had features of adrenal fasciculata or a transitional zone, with an atrophic glomerulosa.

CONCLUSION

These findings define a new inherited form of aldosteronism and suggest that identification of the underlying defect will provide insight into normal mechanisms regulating adrenal steroid biosynthesis.

The molecular basis of pediatric hypertension

Blood pressure, the product of cardiac output and peripheral vascular resistance, follows a circadian rhythm and is altered by a host of circulating and local substances and by many physiologic events. The number of genes, signaling pathways, and systems involved in blood pressure regulation is enormous, and dissecting those factors that are most important in hypertension has proven challenging. This article discusses molecular mechanisms of hypertension in several conditions in which mutations in a single gene give rise to hypertension and then considers the contribution of these and other genes to essential hypertension.

Monogenic mineralocorticoid hypertension

Monogenic mutations leading to excessive activation of the mineralocorticoid pathway result, almost always, in suppressed renin and hypertension in adult life and sometimes in hypokalaemia and alkalosis, which can be severe. In most of these syndromes, precise molecular changes in specific steroidogenic or effector genes have been identified, permitting appreciation of (1) pathophysiology, (2) great diversity of phenotype and (3) possibility of genetic methods of diagnosis. Yet to be achieved elucidation of the genetic basis of familial hyperaldosteronism type II, the most common and clinically significant of them, will enhance detection of primary aldosteronism, currently the commonest specifically treatable and potentially curable form of hypertension. While classic, complete-phenotype presentations of monogenic forms of mineralocorticoid hypertension are rarely recognised, more subtle genetic expression causing less florid manifestations could represent a significant proportion of so-called 'essential hypertension.'

A time-resolved fluoroimmunoassay for 18-oxocortisol and 18-hydroxycortisol. Development of a monoclonal antibody to 18-oxocortisol

Patients with primary aldosteronism and with glucocorticoid-suppressible aldosteronism excrete in the urine excessive amounts of the hybrid steroids 18-hydroxycortisol and 18-oxocortisol. The measurement of these steroids aids in the differential diagnosis of various adrenal disorders. We have produced mouse monoclonal antibodies against 18-oxocortisol and polyclonal antibodies against 18-hydroxycortisol and describe a time-resolved fluoroimmunoassay (TR-FIA) technique for the measurement of these steroids in the urine. We have also compared this assay with an ELISA technique for these compounds. We also describe the preparation of in-house Eu(III)-labeled avidin and an enhancement solution and compared to a commercially available Eu(III)-labeled streptavidin and enhancement solutions. The monoclonal antibodies against 18-oxocortisol are sensitive and have a high level of specificity. The TR-FIA technique using in-house prepared reagents or commercial ones were indistinguishable from each other, but at a significant saving. The TR-FIA technique was more sensitive and had a greater precision than the ELISA technique for both steroids.

Urinary steroid profile analysis

BACKGROUND

A detailed analysis (profile) of the steroid metabolites in urine is useful for diagnosis of adrenal problems. Hospitals from many of UK health regions and around the world use the specialist assay and advisory service at UCLH. According to the total workload, samples are from patients with precocious puberty/premature adrenarche (21%), ambiguous genitalia (17%), Cushing's syndrome (13%), tumors (11%), polycystic ovaries (9%), hypertension (6%), problems of growth and development (5%), salt-loss (3%) and male pseudohermaphroditism (3%). Sixty percent of samples are from children and comprehensive reference data for steroid excretion rates in childhood unique to this laboratory were essential for interpretation of the results.

CONCLUSION

The recognition and high excretion rates of certain steroids not easily measured in blood or urine by any other assays was particularly in cases of hypertension and tumors. The assay is cost effective by comparison with the combined costs of several individual hormone measurements but that cost may delay early referral to a specialist centre and that is not in the best interests of the families involved.

Genetic study of patients with dexamethasone-suppressible aldosteronism without the chimeric CYP11B1/CYP11B2 gene

Glucocorticoid-remediable aldosteronism is an inherited disorder caused by a chimeric gene duplication between the CYP11B1 (11beta-hydroxylase) and CYP11B2 (aldosterone synthase) genes. The disorder is characterized by hyperaldosteronism and high levels of 18-hydroxycortisol and 18-oxocortisol, which are under ACTH control. The diagnosis of glucocorticoid-remediable aldosteronism had been traditionally made using the dexamethasone suppression test; however, recent studies have shown that several patients with primary aldosteronism and a positive dexamethasone suppression test do not have the chimeric CYP11B1/CYP11B2 gene. The aim of this work was to evaluate whether other genetic alterations exist in CYP11B genes (gene conversion in the coding region of CYP11B1 or in the promoter of CYP11B2) that could explain a positive dexamethasone suppression test and to determine another genetic cause of glucocorticoid-remediable aldosteronism. We also evaluated the role of 18-hydroxycortisol as a specific biochemical marker of glucocorticoid-remediable aldosteronism. We studied eight patients with idiopathic hyperaldosteronism, a positive dexamethasone suppression test, and a negative genetic test for the chimeric gene. In all patients we amplified the CYP11B1 gene by PCR and sequenced exons 3-9 of CYP11B1 and a specific region (-138 to -284) of CYP11B2 promoter. We also measured the levels of 18-hydroxycortisol, and we compared the results with those found in four subjects with the chimeric gene. None of eight cases showed abnormalities in exons 3-9 of CYP11B1, disproving a gene conversion phenomenon. In all patients a fragment of 393 bp corresponding to a specific region of the promoter of CYP11B2 gene was amplified. The sequence of the fragment did not differ from that of the wild-type promoter of the CYP11B2 gene. The 18-hydroxycortisol levels in the eight idiopathic hyperaldosteronism patients and four controls with chimeric gene were 3.9 +/- 2.3 and 21.9 +/- 3.5 nmol/liter, respectively (P < 0.01). In summary, we did not find other genetic alterations or high levels of 18-hydroxycortisol that could explain a positive dexamethasone suppression test in idiopathic hyperaldosteronism. We suggest that the dexamethasone suppression test could lead to an incorrect diagnosis of glucocorticoid-remediable aldosteronism.

Familial hyperaldosteronism

Primary aldosteronism (PAL) may be as much as ten times more common than has been traditionally thought, with most patients normokalemic. The study of familial varieties has facilitated a fuller appreciation of the nature and diversity of its clinical, biochemical, morphological and molecular aspects. In familial hyperaldosteronism type I (FH-I), glucocorticoid-remediable PAL is caused by inheritance of an ACTH-regulated, hybrid CYP11B1/CYP11B2 gene. Genetic testing has greatly facilitated diagnosis. Hypertension severity varies widely, demonstrating relationships with gender, affected parent's gender, urinary kallikrein level, degree of biochemical disturbance and hybrid gene crossover point position. Analyses of aldosterone/PRA/cortisol 'day-curves' have revealed that (1) the hybrid gene dominates over wild type CYP11B2 in terms of aldosterone regulation and (2) correction of hypertension in FH-I requires only partial suppression of ACTH, and much smaller glucocorticoid doses than those previously recommended. Familial hyperaldosteronism type II is not glucocorticoid-remediable, and is clinically, biochemically and morphologically indistinguishable from apparently sporadic PAL. In one informative family available for linkage analysis, FH-II does not segregate with either the CYP11B2, AT1 or MEN1 genes, but a genome-wide search has revealed linkage with a locus in chromosome 7. As has already occurred in FH-I, elucidation of causative mutations is likely to facilitate earlier detection of PAL and other curable or specifically treatable forms of hypertension.

Treatment of familial hyperaldosteronism type I: only partial suppression of adrenocorticotropin required to correct hypertension

In familial hyperaldosteronism type I, inheritance of a hybrid 11beta-hydroxylase/aldosterone synthase gene leads to ACTH-regulated overproduction of aldosterone (causing hypertension) and of "hybrid" steroids, 18-hydroxy- and 18-oxo-cortisol. To determine whether complete suppression of the hybrid gene is necessary to normalize blood pressure, we sought evidence of persisting expression in eight patients who were rendered normotensive for 1.3-4.5 yr by glucocorticoid treatment. At the time of the study, six patients were receiving dexamethasone (0.125-0.25 mg/day) and two patients were taking prednisolone (2.5 or 5 mg/day). Urinary 18-oxo-cortisol levels during treatment demonstrated close correlation with mean "day curve" (blood collected every 2 h for 24 h) cortisol (r = 0.74), consistent with regulation by ACTH. Although urinary 18-oxo-cortisol levels were lower during than before treatment (mean 12.6 +/- 2.4 SEM vs. 35.0 +/- 5.6 nmol/mmol creatinine; P < 0.01), they remained above normal (0.8-5.2 nmol/mmol creatinine) in all eight patients. Although mean upright plasma potassium levels during treatment were higher, aldosterone levels lower, PRA levels higher, and aldosterone to PRA ratios lower than before treatment, PRA levels were uncorrected (< 13 pmol/L x min) and aldosterone to PRA ratios were uncorrected (>65) during treatment in four patients. For each of the eight patients, day curve aldosterone levels during treatment correlated more tightly with cortisol (mean r for the eight patients, 0.87 +/- 0.05 SEM) than with PRA (mean r = 0.36 +/- 0.10 SEM). Hence, control of hypertension by glucocorticoid treatment was associated, in all patients, with only partial suppression of ACTH-regulated hybrid steroid and aldosterone production. Normalization of urinary hybrid steroid levels and abolition of ACTH-regulated aldosterone production is not a requisite for hypertension control and, if used as a treatment goal, may unnecessarily increase the risk of Cushingoid side effects.

Clinical applications of gas chromatography and gas chromatography-mass spectrometry of steroids

This review article underlines the importance of gas chromatography-mass spectrometry (GC-MS) for determination of steroids in man. The use of steroids labelled with stable isotopes as internal standard and subsequent analysis by GC-MS yields up to now the only reliable measurement of steroids in serum. Isotope dilution GC-MS is the reference method for evaluation of routine analysis of serum steroid hormones. GC-MS is an important tool for detection of steroid hormone doping and combined with a combustion furnace and an isotope ratio mass spectrometer the misuse of testosterone by athletes can be discovered. Finally the so called urinary steroid profile by GC and GC-MS is the method of choice for detection of steroid metabolites in health and disease.

Hypertension: genes and environment

Hypertension can be classified as either Mendelian hypertension or essential hypertension, on the basis of the mode of inheritance. The Mendelian forms of hypertension develop as a result of a single gene defect, and as such are inherited in a simple Mendelian manner. In contrast, essential hypertension occurs as a consequence of a complex interplay of a number of genetic alterations and environmental factors, and therefore does not follow a clear pattern of inheritance, but exhibits familial aggregation of cases. In this review, we discuss recent advances in understanding the pathogenesis of both types of hypertension. We review the causal gene defects identified in several monogenic forms of hypertension, and we discuss their possible relevance to the development of essential hypertension. We describe the current approaches to identifying the genetic determinants of human essential hypertension and rat genetic models of hypertension, and summarise the results obtained to date using these methods. Finally, we discuss the significance of environmental factors, such as stress and diet, in the pathogenesis of hypertension, and we describe their interactions with specific hypertension susceptibility genes.

Brachydactyly-short stature-hypertension (Bilginturan) syndrome: report on two families

We report on two families with autosomal dominant brachydactyly of hands and feet and hypertension. All affected members of the first family had proportionate short stature. However, the propositus and the affected relatives in the second family were only short compared to unaffected relatives. The hypertension was medically responsive in all cases. The propositus in the second family had poor compliance and a striking generalized vasculopathy. All patients were of normal intelligence and had a normal facial appearance. The brachydactyly-short stature-hypertension syndrome was first reported by Bilginturan et al. [1973] in a Turkish family and the families reported by us are Caucasian and Hispanic. The gene causing this condition in the original Turkish family was recently mapped to 12p. Our report expands our existing knowledge and the ethnic diversity of this syndrome.

Evaluation of the dexamethasone suppression test for the diagnosis of glucocorticoid-remediable aldosteronism

Glucocorticoid-remediable aldosteronism (GRA) is a rare form of inherited hypertension caused by a characteristic gene duplication. With the advent of definitive genetic testing for GRA, the performance of the traditional screening test for GRA, the dexamethasone suppression test (DST), can be evaluated. We compared the DST to direct genetic testing in 24 patients referred for genetic screening for GRA (12 GRA positive and 12 GRA negative) based on clinical and biochemical findings, DST, and family history. Plasma aldosterone was measured before and after oral dexamethasone administration to determine the extent to which aldosterone was suppressed by glucocorticoids in each patient group. The results of the DST in these subjects were also compared to those in 19 historical patients with primary aldosteronism [4 bilateral hyperplasia and 15 aldosterone-producing adenoma (APA)] reported previously. The DST differentiated GRA-positive from GRA-negative patients with 92% sensitivity and 100% specificity. Cutoffs based on the post-DST plasma aldosterone level (< 4 ng/dL) or percent suppression compared to baseline (> 80%) were equally effective in correctly diagnosing GRA (only one GRA-positive patient would have been incorrectly diagnosed). However, DST in 15 APA patients revealed that 33% had greater than 80% suppression of aldosterone, and 1 had aldosterone levels below 4 ng/dL. We conclued that a post-DST aldosterone level below 4 ng/dL will correctly diagnose GRA patients with high sensitivity and specificity. Suppression compared to baseline can be misleading, as evidenced by the results in APA patients and referred subjects who genetically screened negative.

The amino acid substitutions Ser288Gly and Val320Ala convert the cortisol producing enzyme, CYP11B1, into an aldosterone producing enzyme

Transfection studies with cDNAs encoding hybrids between the highly similar cytochrome P450 enzymes, CYP11B1 (steroid 11 beta-hydroxylase) and CYP11B2 (aldosterone synthase) have identified which amino acids determine the different activities of the enzymes.

Inherited forms of mineralocorticoid hypertension

Aldosterone, the most important mineralocorticoid, regulates electrolyte excretion and intravascular volume mainly through its effects on renal distal convoluted tubules and cortical collecting ducts. Excess secretion of aldosterone or other mineralocorticoids or abnormal sensitivity to mineralocorticoids may result in hypertension, suppressed plasma renin activity, and hypokalemia. Such conditions often have a genetic basis, and studies of these conditions have provided valuable insights into the normal and abnormal physiology of mineralocorticoid action. Deficiencies of steroid 11 beta-hydroxylase or 17 alpha-hydroxylase are types of congenital adrenal hyperplasia, the autosomal recessive inability to synthesize cortisol. These two defects often cause hypertension because of overproduction of cortisol precursors that are, or are metabolized to, mineralocorticoid agonists. These disorders result from mutations in the CYP11B1 and CYP17 genes encoding the corresponding enzymes. Glucocorticoid-suppressible hyperaldosteronism is an autosomal dominant form of hypertension in which aldosterone secretion is abnormally regulated by corticotropin. It is caused by recombinations between linked genes encoding closely related isozymes, 11 beta-hydroxylase (CYP11B1) and aldosterone synthase (CYP11B2), generating a dysregulated chimeric gene with aldosterone synthase activity. Apparent mineralocorticoid excess is a loss of functional ligand specificity of the mineralocorticoid receptor caused by a deficiency of the kidney isozyme of 11 beta-hydroxysteroid dehydrogenase, an enzyme that normally metabolizes cortisol to cortisone to prevent cortisol from occupying the receptor. This autosomal recessive form of severe hypertension results from mutations in the HSD11K (HSD11B2) gene.

Molecular genetics of human blood pressure variation

Hypertension is a common multifactorial vascular disorder of largely unknown cause. Recognition that hypertension is in part genetically determined has motivated studies to identify mutations that confer susceptibility. Thus far, mutations in at least 10 genes have been shown to alter blood pressure; most of these are rare mutations imparting large quantitative effects that either raise or lower blood pressure. These mutations alter blood pressure through a common pathway, changing salt and water reabsorption in the kidney. These findings demonstrate the utility of molecular genetic approaches to the understanding of blood pressure variation and may provide insight into the physiologic mechanisms underlying common forms of hypertension.

Severe autosomal dominant hypertension and brachydactyly in a unique Turkish kindred maps to human chromosome 12

Finding genes that cause human hypertension is not straightforward, since the determinants of blood pressure in primary hypertension are multifactorial. One approach to identifying relevant genes is to elucidate rare forms of monogenic hypertension. A relevant mutation may provide a rational starting point from which to analyse the pathophysiology of a condition affecting 20% of the world's population. In 1973 a family with autosomal dominantly inherited brachydactyly and severe hypertension, where the two traits cosegregated completely, was described. We have now re-examined this kindred, and localized the hypertension and brachydactyly locus to chromosome 12p in a region defined by markers D12S364 and D12S87. As the renin-angiotensin-system and sympathetic nervous system respond normally in this form of hypertension, the condition resembles essential hypertension. This feature distinguishes this form of hypertension from glucocorticoid remediable aldosteronism and Liddle's syndrome, which are salt-sensitive forms of monogenic hypertension with very low plasma renin activity. We suggest that identification of the gene involved in hypertension and brachydactyly and its mutation will be of great relevance in elucidating new mechanisms leading to blood pressure elevation.

Glucocorticoid-suppressible hyperaldosteronism and adrenal tumors occurring in a single French pedigree

Glucocorticoid-suppressible hyperaldosteronism is a dominantly inherited form of hypertension believed to be caused by the presence of a hybrid CYP11B1/CYP11B2 gene which has arisen from an unequal crossing over between the two CYP11B genes in a previous meiosis. We have studied a French pedigree with seven affected individuals in which two affected individuals also have adrenal tumors and two others have micronodular adrenal hyperplasia. One of the adrenal tumors and the surrounding adrenal tissue has been removed, giving a rare opportunity to study the regulation and action of the hybrid gene causing the disease. The hybrid CYP11B gene was demonstrated to be expressed at higher levels than either CYP11B1 or CYP11B2 in the cortex of the adrenal by RT-PCR and Northern blot analysis. In situ hybridization showed that both CYP11B1 and the hybrid gene were expressed in all three zones of the cortex. In cell culture experiments hybrid gene expression was stimulated by ACTH leading to increased production of aldosterone and the hybrid steroids characteristic of glucocorticoid-suppressible hyperaldosteronism. The genetic basis of the adrenal pathologies in this family is not known but may be related to the duplication causing the hyperaldosteronism.

Genetic determinants of human hypertension

Hypertension is a common trait of multifactorial determination imparting an increased risk of myocardial infarction, stroke, and end-stage renal disease. The primary determinants of hypertension, as well as the factors which determine specific morbid sequelae, remain unknown in the vast majority of subjects. Knowledge that a large fraction of the interindividual variation in this trait is genetically determined motivates the application of genetic approaches to the identification of these primary determinants. Success in this effort will afford insights into pathophysiology, permit preclinical identification of subjects with specific inherited susceptibility, and provide opportunities to tailor therapy to specific underlying abnormalities. To date, mutations in three genes have been implicated in the pathogenesis of human hypertension: mutations resulting in ectopic expression of aldosterone synthase enzymatic activity cause a mendelian form of hypertension known as glucocorticoid-remediable aldosteronism; mutations in the beta subunit of the amiloride-sensitive epithelial sodium channel cause constitutive activation of this channel and the mendelian form of hypertension known as Liddle syndrome; finally, common variants at the angiotensinogen locus have been implicated in the pathogenesis of essential hypertension in Caucasian subjects, although the nature of the functional variants and their mechanism of action remain uncertain. These early findings demonstrate the feasibility and utility of the application of genetic analysis to dissection of this trait.

Inborn errors of aldosterone biosynthesis in humans

Corticosterone methyl oxidase (CMO) type I and type II deficiencies are inborn errors at the penultimate and ultimate steps in the biosynthesis of aldosterone in humans. Recently, steroid 18-hydroxylase (P450C18), or aldosterone synthase (P450aldo), was shown to be a multifunctional enzyme catalyzing these two steps of aldosterone biosynthesis, i.e., the conversion of corticosterone to 18-hydroxycorticosterone and the subsequent conversion of 18-hydroxycorticosterone to aldosterone. This observation suggests that CMO I and CMO II deficiencies are derived from two different mutations in the P450C18 gene (CYP11B2). To elucidate whether or not this is the case, we performed molecular genetic studies on CYP11B2 of both types of patients. Nucleotide sequence analysis has indicated that the gene of CMO I deficient patients is completely inactivated by a frameshift to form a stop codon due to a 5-bp nucleotide deletion in exon 1. Sequence analysis of CYP11B2 of CMO II deficient patients has revealed two point mutations, CGG-->TGG (Arg181-->Trp) in exon 3 and GTG-->GCG (Val386-->Ala) in exon 7. CYP11B1, the gene for steroid 11 beta-hydroxylase (P45011 beta) which was previously postulated to be the target for CMO II deficiency, is not impaired in these two types of patients. Expression studies using the corresponding mutant cDNAs have shown that CMO I deficient patients are null mutants with a complete lack of P450C18 whereas CMO II deficient patients are leaky mutants with an altered P450C18 activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Genetic recombination as a cause of inherited disorders of aldosterone and cortisol biosynthesis and a contributor to genetic variation in blood pressure

CYP11B1 (11 beta-hydroxylase) and CYP11B2 (aldosterone synthase) are steroidogenic enzymes which mediate the final step (11 beta-hydroxylation) in cortisol synthesis and the final three steps (11 beta-hydroxylation, 18-hydroxylation, and 18-oxidation) in aldosterone synthesis, respectively. The enzymes share 93% identity in amino acid sequence and are encoded by two structurally similar genes which are located in tandem on chromosome 8q22, approximately 40 kb apart. Expression of the aldosterone synthase gene (CYP11B2) is limited to the zona glomerulosa of the adrenal cortex, thereby limiting the synthesis of aldosterone to that zone, where it is principally regulated by plasma levels of angiotensin II and potassium. The 11 beta-hydroxylase gene (CYP11B1) is expressed in the zona fasciculata, the zone which also expresses a 17-hydroxylase activity, where it mediates cortisol synthesis under the control of ACTH. Genetic recombination involving a mispairing of the two CYP11B genes can lead to duplications and deletions of the genes, creation of hybrid genes of several forms, or transfer of coding and regulatory sequences from one gene to the other. Since the two genes have related but different activities, are normally expressed in different zones, and respond to different physiological signals, such recombination has the potential to generate a variety of inherited disorders of steroid production. In this paper we review the range of mutations which can occur and the resulting disorders of steroid biosynthesis, and suggest some novel mutations which might be sought in variants of these endocrinological syndromes.

Genetic diseases of steroid metabolism

All major classes of biologically active steroid hormones (progestins, mineralocorticoids, glucocorticoids, and sex steroids) are synthesized from cholesterol through 11 different bioconversions. With the exception of 5 alpha-reductase, all the enzymes mediating these reactions fall into two classes, cytochromes P450 and short-chain dehydrogenases. Cytochromes P450 are heme-containing membrane-bound proteins with molecular weights of approximately 50,000 that utilize molecular oxygen and electrons from NADPH-dependent accessory proteins to hydroxylate substrates. Short-chain dehydrogenases have molecular weights of 30,000-40,000, have tyrosine and lysine residues at the active site, and remove a hydride from the substrate, transferring the electrons of the hydride to NAD+ or NADP+. In most cases, this reaction is reversible so that the dehydrogenase can also function as a reductase under appropriate conditions. Inherited disorders in enzymes required for steroid biosynthesis have varying effects. Defects that prevent cortisol from being synthesized are referred to collectively as congenital adrenal hyperplasia. Because the enzymes required for cortisol biosynthesis in the adrenal cortex are in many cases required for the synthesis of mineralocorticoids and/or sex steroids, these classes of steroids may also not be synthesized normally. Thus, cholesterol desmolase and 3 beta-hydroxysteroid dehydrogenase deficiencies affect synthesis of all classes of steroids in both the adrenals and gonads. Steroid 21-hydroxylase deficiency, the most common cause (> 90% of cases) of congenital adrenal hyperplasia, can affect both mineralocorticoid and glucocorticoid synthesis, but androgen secretion is usually abnormally high due to shunting of accumulated precursors into this pathway. Excessive secretion of androgens and mineralocorticoids occurs in 11 beta-hydroxylase deficiency (the second most frequent form of congenital adrenal hyperplasia). Mineralocorticoid excess is also seen in 17 alpha-hydroxylase deficiency, but in this disorder sex steroid synthesis is defective. All defects that affect estrogen synthesis (deficiencies of cholesterol desmolase, 3 beta-hydroxysteroid dehydrogenase, 17 alpha-hydroxylase, aromatase, and 17 beta-hydroxysteroid dehydrogenase) are very rare, suggesting that the inability to synthesize placental estrogens may adversely affect fetal survival. A number of enzymes are expressed at sites of steroid action and regulate the amount of active steroid available to steroid receptors. Steroid 5 alpha-reductase converts testosterone to the more active dihydrotestosterone. Deficiency of this activity leads to incomplete development of male genitalia; 17 beta-hydroxysteroid dehydrogenase deficiency has similar phenotypic effects.(ABSTRACT TRUNCATED AT 400 WORDS)

A direct enzyme immunoassay for 18-hydroxycortisol in urine: a new tool for screening primary aldosteronism

A microplate enzyme immunoassay has been developed for the measurement of 18-hydroxycortisol in urine. An antiserum was produced by immunization of rabbits with a 3-O-(carboxymethyl)oximino-18-hydroxycortisol-bovine serum albumin conjugate. IgG was isolated from the antiserum and was biotinylated. Newly synthesized p-nitrophenyl ester of the oxime was used for the preparation of steroid-horseradish peroxidase conjugate. After an incubation of diluted urine samples (or standards) and the steroid-enzyme conjugate with the biotinylated antibody, the resulting antigen-antibody complex was separated by adding a portion of the reaction mixture into the avidin-coated microtiter plate. Peroxidase bound to solid phase was measured colorimetrically. The standard curve was linear from 0.25 to 10 ng/well. Intra- and interassay coefficients of variation were 5.5-8.8 and 7.8-8.2%, respectively. The assay was specific except for 18-hydroxycortisone with minor cross reaction. Urinary 18-hydroxycortisol excretion ranged 836-7460 and 26-696 nmol/24 h, respectively, in patients with primary aldosteronism (n = 8) and in control subjects (n = 40). This simple and rapid (< 4 h) assay is suitable for screening patients with primary aldosteronism.

Differential diagnosis in primary aldosteronism

The diagnosis of primary aldosteronism (PA) is based on the finding of the combination of elevated urinary and/or plasma aldosterone and suppressed renin activity in patients with hypertension and hypokalemia. However, PA consists of a number of subsets, and diagnostic criteria for a correct identification of surgically remediable forms are of great interest. The methods and the results concerning our series of 113 patients with PA are presented in this review. Aldosterone producing adenoma (APA) and idiopathic hyperaldosteronism (IHA) were the most frequent forms, 51 and 44%, respectively. They had similar blood pressure levels, but hypokalemia was most frequently found in APA. Urinary and upright plasma aldosterone were similar, but supine plasma aldosterone was lower in IHA. Plasma aldosterone response to upright posture and angiotensin II infusion was absent in most cases of APA and present in IHA, but occasionally renin-responsive adenoma were found. Captopril failed to decrease plasma aldosterone in most patients with APA, and in a subgroup of patients with IHA. Patients with adenoma also had higher values of the aldosterone precursor 18-hydroxy-corticosterone, and of atrial natriuretic peptide, probably as a consequence of a greater degree of volume expansion. Among morphological studies, CT scan and adrenal radiocholesterol scintiscan provided similar results (85% accuracy): adrenal veins catheterization clarified almost all the remaining cases. Among the subsets of PA, 3 familiar cases of dexamethasone-suppressible hyperaldosteronism were recognized, with characteristically high levels of aldosterone, 18-hydroxy-corticosterone, 18-hydroxy-cortisol and 18-oxo-cortisol, due to the genetic abnormalities of the 11-18 hydroxylase system. Isolated cases of primary adrenal hyperplasia (with all functional tests resulting compatible with APA, but no tumour at surgery) and aldosterone producing carcinoma (1 case) have also been reported in the present study.

The molecular basis of a hereditary form of hypertension, glucocorticoid-remediable aldosteronism

Glucocorticoid-remediable aldosteronism (GRA) is a hereditary cause of human hypertension in which aldosterone secretion is regulated by ACTH. Recent studies demonstrate that this disorder is caused by fusion of regulatory sequences of the steroid 11beta-hydroxylase gene to coding sequences of the aldosterone synthase gene. These mutations occur by unequal crossing over between these two genes and result in ectopic expression of aldosterone synthase in adrenal fasciculata. These features explain the physiology and genetics of GRA and provide the basis for a simple direct genetic test for this disorder.

In vitro glucocorticosteroid and mineralocorticosteroid biosynthesis in Conn's adenoma tissues

The in vitro metabolism of [1,2-3H] deoxycorticosterone (DOC), [1,2-3H] 18-hydroxy-11-deoxycorticosterone (18-OHDOC) and [1,2-3H] 11-deoxycortisol (S) was studied in adrenal adenoma homogenates from patients with primary hyperaldosteronism. Tumor tissues actively converted deoxycorticosterone and 18-hydroxy-11-deoxycorticosterone to 18-hydroxycorticosterone and aldosterone. Yields of cortisol and cortisone were also large showing that the tissues did not lack the zona fasciculata-like 11 beta-hydroxylation ability.

Genetics of essential hypertension

Blood pressure is a complex quantitative trait that is determined by multiple environmental and genetic factors. Although some simple Mendelian forms of high blood pressure have been described, essential hypertension is characterized by a complex mode of inheritance. Based on recent advances in molecular biology and statistical genetics, it has become feasible to search for chromosome regions that may contain genes contributing to the pathogenesis of hypertension in humans. For example, recent linkage and association studies have raised the possibility that a blood pressure regulatory locus may exist in or near the angiotensinogen gene on chromosome 1. Detailed genetic experiments in animal models of hypertension may help to guide further clinical studies and lead to an improved understanding of gene action in the pathogenesis of essential hypertension.

Glucocorticoid-suppressible hyperaldosteronism results from hybrid genes created by unequal crossovers between CYP11B1 and CYP11B2

Glucocorticoid-suppressible hyperaldosteronism (GSH) is an autosomal dominant form of familial hypertension. The biochemical abnormalities seen in this disorder may be remedied by administration of dexamethasone, implying that aldosterone synthesis is being abnormally regulated by corticotropin. The final three steps of aldosterone synthesis, 11 beta- and 18-hydroxylation and 18-oxidation, are mediated by a cytochrome P450 in the zona glomerulosa of the adrenal cortex termed CYP11B2. A related isozyme in the zona fasciculata, CYP11B1, is required for cortisol synthesis; this isozyme, which is normally expressed at much higher levels than CYP11B2, only has 11 beta-hydroxylase activity. These isozymes are encoded by genes on human chromosome 8q22. We have now studied four unrelated patients with GSH. We found that each patient has one chromosome that carries three CYP11B genes instead of two. This has presumably been generated by unequal meiotic crossing-over. The extra gene is a hybrid with 5' regulatory and coding regions corresponding to CYP11B1 and 3' coding regions from CYP11B2. The breakpoint is in intron 2 in two cases, intron 3 in one, and exon 4 in one. Cells transfected with hybrid cDNAs containing up to the first three exons of CYP11B1 synthesized aldosterone at levels near that of cells carrying normal CYP11B2, but cells transfected with hybrids containing the first five or more exons of CYP11B1 could not synthesize detectable amounts of aldosterone. These data demonstrate that GSH is caused by expression of a gene that is regulated like CYP11B1 but that encodes a protein able to synthesize aldosterone.

Hereditary hypertension caused by chimaeric gene duplications and ectopic expression of aldosterone synthase

Patients with glucocorticoid-remediable aldosteronism (GRA) from 12 kindreds possess chimaeric gene duplications arising from unequal crossing-over, fusing regulatory sequences of steroid 11 beta-hydroxylase to coding sequences of aldosterone synthase. These chimaeric genes are specific for GRA and explain the biochemistry, physiology and genetics of this form of hypertension. Sites of crossing over range from intron 2 to intron 4. Most mutations have arisen independently from either sister or non-sister chromatid exchange between these genes, which are only 45 kilobases apart. The possibility of a susceptibility allele for GRA of Irish origin is suggested. These findings indicate the utility of a direct genetic test for this disorder.

A chimaeric 11 beta-hydroxylase/aldosterone synthase gene causes glucocorticoid-remediable aldosteronism and human hypertension

Glucocorticoid-remediable aldosteronism (GRA), an autosomal dominant disorder, is characterized by hypertension with variable hyperaldosteronism and by high levels of the abnormal adrenal steroids 18-oxocortisol and 18-hydroxycortisol, which are all under control of adrenocorticotropic hormone and suppressible by glucocorticoids. These abnormalities could result from ectopic expression of aldosterone synthase, which is normally expressed only in adrenal glomerulosa, in the adrenal fasciculata. Genes encoding aldosterone synthase and steroid 11 beta-hydroxylase (expressed in both adrenal fasciculata and glomerulosa), which are 95% identical and lie on chromosome 8q (refs 7, 10), are therefore candidate genes for GRA. Here we demonstrate complete linkage of GRA in a large kindred to a gene duplication arising from unequal crossing over, fusing the 5' regulatory region of 11 beta-hydroxylase to the coding sequences of aldosterone synthase (maximum lod score 5.23 for complete linkage, odds ratio of 170,000:1). This mutation can account for all the physiological abnormalities of GRA. Our result represents the demonstration of a mutation causing hypertension in otherwise phenotypically normal animals or humans.

Bovine adrenal cytochrome P-450(11 beta)-mediated conversion of 11-deoxycortisol to 18- and 19-hydroxy derivatives; structural analysis by 1H-NMR

Incubation of 11-deoxycortisol with a cytochrome P-450(11 beta)-reconstituted system yielded, in addition to cortisol, several new steroid products. In this study, structures of the three steroid products were elucidated. Retention time of the first product (Peak 2 substance) coincided with that of authentic 18-hydroxycortisol on reverse phase HPLC. To further confirm the chemical identity of this product, the purified sample was subjected to 1H-NMR analysis. The spectrum was essentially identical to that of 18-hydroxycortisol. The retention time of the second product (Peak 3 substance) did not coincide with those of commonly occurring steroids. The one- and two-dimension 1H-NMR spectra provided strong evidence for its structure of 19-hydroxy-11-deoxycortisol. The retention time of the third product (Peak 4 substance) did not coincide with those of commonly occurring steroids. The 1H-NMR spectrum showed the presence of signals of 19-CH3 and 18-CH2 protons. There was also evidence that this product is not hydroxylated at the 11-position. Further analysis of the COSY spectra identified its structure as 18-hydroxy-11-deoxycortisol. From these results, we conclude that bovine P-450(11 beta) can catalyze the hydroxylation of 11-deoxycortisol at 11 beta-, 18- and 19-positions and produce cortisol, 18-hydroxy-11-deoxycortisol, 18-hydroxycortisol and 19-hydroxy-11-deoxycortisol.

Measurement of 4 urinary C-18 oxygenated corticosteroids by stable isotope dilution mass fragmentography

The cortisol C-18 oxidation pathway leading to the production of 18-hydroxy- and 18-oxocortisol is expressed in adenomatous primary aldosteronism and glucocorticoid remediable aldosteronism. In order to better define the significance of the pathway and its usefulness in differential diagnosis, we have developed a stable isotope dilution mass fragmentographic method for the determination of the tetrahydro metabolites of aldosterone, 18-hydroxycorticosterone and 18-oxocortisol and of unmetabolized 18-hydroxycortisol in urine. Stereochemically correct tetrahydro steroids containing 3 deuterium atoms were synthesized from the available 3-keto-4-pregnenes in 2 steps and 1,2-deuterium-labeled 18-hydroxycortisol was prepared by selective deuteration of the 1,2-double bond of a dienone precursor. Simultaneous measurement of the 4 steroids permitted a comparison of the abnormal products of the C-18 oxidation of cortisol with the normal C-18 oxidation products of corticosterone, 18-hydroxycorticosterone and aldosterone. Application of the method to the definition of the normal range is described.

Steroids and hypertension

Primary aldosteronism is the principal disorder of zona glomerulosa and a number of subsets have been identified: unilateral adenoma; bilateral micro- or macro-nodular hyperplasia (idiopathic aldosteronism); primary hyperplasia and aldosterone-producing carcinoma either adrenal or ectopic. The diagnostic criteria for a correct differential diagnosis of these subsets are now quite reliable and our experience is presented in detail. Unfortunately the pathogenesis of most of these forms is still poorly recognized and requires further investigation. An extreme sensitivity to angiotensin II is present in patients with idiopathic aldosteronism, and a role for adrenal renin is now being advocated. A peculiar form of hyperaldosteronism is the glucocorticoid-remediable subtype. An unusual sensitivity of aldosterone to ACTH is present in this form. A qualitative biochemical abnormality in this disorder consists of marked over-production of products of the cortisol C18-oxidation pathway, 18-hydroxycortisol and 18-oxocortisol, which are more abundant than aldosterone and 18-hydroxycorticosterone. A family with three affected sibs has been studied by our group. In other clinical situations, classical zona fasciculata mineralocorticoids [deoxycorticosterone (DOC), corticosterone and their 18-hydroxy compounds] are secreted in excess. The hypertensive diseases of this zone are rare DOC-secreting tumors and two forms of congenital adrenal hyperplasia (CAH), the 11 beta-hydroxylase (11-OHDS) and the 17 alpha-hydroxylase deficiency syndromes (17-OHDS), which are identified by the presence of hypokalemia and suppressed renin activity. DOC is the only mineralocorticoid hormone (MCH) oversecreted in the 11-OHDS, while all ACTH-dependent MCH are very high in the 17-OHDS. The molecular basis of gene abnormalities of this disorder are currently under investigation, and preliminary data obtained in some of our patients are presented. Finally a syndrome of apparent mineralocorticoid excess, which is not a primary disorder of the adrenal cortex, describes the association of an unexplained hypermineralocorticoid state with a decreased rate of peripheral 11 beta-hydroxy dehydrogenation of cortisol to cortisone. Studies on this syndrome have led to the hypothesis that peripheral cortisol inactivation is the normal mechanism permitting specific mineralocorticoid recognition. The syndrome exists in two forms both characterized by a decreased turnover of a normal level of plasma cortisol, but in the type I variant an elevated cortisol/cortisone metabolite ratio is found, whereas in the type II variant this ratio is normal. Three patients of the latter form have recently been described by us and are shortly illustrated.(ABSTRACT TRUNCATED AT 400 WORDS)