pq229912790p


Steroid disorders in children: Congenital adrenal
hyperplasia and apparent mineralocorticoid excess
Maria I. New* and Robert C. Wilson

Pediatric Endocrinology, New York Presbyterian Hospital and the Weill Medical College of Cornell University, 525 East 68th Street, New York, NY 10021

This contribution is part of the special series of Inaugural Articles by members of the National Academy of Sciences elected on April 30, 1996.

Contributed by Maria Iandolo New, July 7, 1999

Our research team and laboratories have concentrated on two inher-
ited endocrine disorders, congenital adrenal hyperplasia (CAH) and
apparent mineralocorticoid excess, in thier investigations of the
pathophysiology of adrenal steroid hormone disorders in children.
CAH refers to a family of inherited disorders in which defects occur in
one of the enzymatic steps required to synthesize cortisol from
cholesterol in the adrenal gland. Because of the impaired cortisol
secretion, adrenocorticotropic hormone levels rise due to impairment
of a negative feedback system, which results in hyperplasia of the
adrenal cortex. The majority of cases is due to 21-hydroxylase defi-
ciency (21-OHD). Owing to the blocked enzymatic step, cortisol
precursors accumulate in excess and are converted to potent andro-
gens, which are secreted and cause in utero virilization of the affected
female fetus genitalia in the classical form of CAH. A mild form of the
21-OHD, termed nonclassical 21-OHD, is the most common autosomal
recessive disorder in humans, and occurs in 1y27 Ashkenazic Jews.
Mutations in the CYP21 gene have been identified that cause both
classical and nonclassical CAH. Apparent mineralocorticoid excess is a
potentially fatal genetic disorder causing severe juvenile hyperten-
sion, pre- and postnatal growth failure, and low to undetectable
levels of potassium, renin, and aldosterone. It is caused by autosomal
recessive mutations in the HSD11B2 gene, which result in a deficiency
of 11b-hydroxysteroid dehydrogenase type 2. In 1998, we reported a
mild form of this disease, which may represent an important cause of
low-renin hypertension.

Our laboratory has dedicated itself to two severe disorders ofchildhood— congenital adrenal hyperplasia (CAH) and
apparent mineralocorticoid excess (AME)—which can be seen
as paradigms of the process of identification, characterization,
and treatment of an autosomal recessive disease. For both of
these steroid disorders, we have used a combination of clinical
observation and investigation, hormonal assays, epidemiological
and population studies, and molecular genetics analyses.

CAH Caused by 21-Hydroxylase Deficiency (21-OHD). CAH refers to a
family of inherited disorders in which defects occur in one of the
enzymatic steps required to synthesize cortisol from cholesterol in
the adrenal gland. Because of the impaired cortisol secretion,
adrenocorticotropic hormone (ACTH) levels rise via a negative
feedback system, which results in hyperplasia of the adrenal cortex.
In 21-OHD, responsible for 90 –95% of CAH cases, there is an
accumulation of the precursors immediately proximal to the 21-
hydroxylation step in the pathway of cortisol synthesis. These excess
precursors are converted to potent androgens, which cause in utero
virilization of the external genitalia of the female fetus in the
classical form of CAH. Newborn males have normal genitalia
although, as with females, they may develop other signs of androgen
excess in childhood.

The earliest documented description of CAH was in 1865 by
a Neapolitan anatomist named Luigi De Crecchio (1), in which
he described a cadaver as having a penis with urethral openings
on its underside and undescended testes. To the surprise of De
Crecchio, the post mortem dissection also revealed a vagina, a
uterus, fallopian tubes, and ovaries, as well as markedly enlarged
adrenal glands. The patient had had a sex reassignment, having

been declared a female at birth and a male 4 years later. As an
adult, he conducted himself as a male socially and sexually. The
patient died in his 40s after the last of several episodes of
vomiting, diarrhea, and prostration. This was certainly a case of
a genetic female with masculinization of the external genitalia,
caused by excess adrenal androgens, who had symptoms consis-
tent with adrenal insufficiency (2). This remarkable description,
written almost 135 years ago, could apply to present-day cases.

Biochemical Features. Adrenal steroidogenesis and fetal develop-
ment. The adrenal cortex produces the glucocorticoid, cortisol,
and the mineralocorticoid, aldosterone, under the control of
regulatory systems that largely function independently. The
cortex is divided into three distinct zones—the outer zona
glomerulosa, the middle zona fasciculata, and the inner zona
reticularis— defined by different cellular arrangements. These
zones are functionally distinct: i.e., mineralocorticoids are syn-
thesized in the zona glomerulosa, glucocorticoids are produced
by the zona fasciculatayreticularis, and androgens are synthe-
sized in the zona reticularis.

The steroidogenic acute regulatory protein shuttles choles-
terol to the inner mitochondrial membrane (3). The production
of cortisol in the zona fasciculata occurs in five steps: cleavage
of the cholesterol side chain by the cholesterol desmolase
enzyme, cytochrome CYP11A1 (P450scc), to yield preg-
nenolone; conversion of pregnenolone to progesterone by 3b-
hydrox ysteroid dehydrogenase w ith ac c ompanying D5,4-
isomerization; and successive hydroxylations at the 17a, 21, and
11b positions, each mediated by a distinct cytochrome P450,
resulting in cortisol (Fig. 1) (4). Cortisol is synthesized under the
trophic control of ACTH and in turn regulates ACTH synthesis
via a negative feedback loop.

Male genital differentiation in embryonic and fetal life de-
pends on two functions of the testes (5): (i) the secretion of
testosterone by the Leydig cells directs the formation of the
internal male urogenital tract (i.e., the epididymides, vasa def-
erentia, seminal vesicles, and ejaculatory ducts) from the Wolf-
fian (mesonephric) ducts, and testosterone, which is reduced to
dihydrotestosterone by 5a-reductase, virilizes the external gen-
italia; and (ii) the secretion of the anti-Mullerian hormone
(AMH) from the Sertoli cells suppresses development of the
Mullerian ducts, thus preventing formation of the female inter-
nal structures (i.e., the fallopian tubes, uterus, cervix, and upper
vagina). AMH is not secreted by the fetal ovary. Thus, even
females with extreme external virilization from androgen excess
will have normal development of the uterus and fallopian tubes,
making later childbearing possible with proper treatment.

In females with CAH, the degree of virilization of external
genitalia toward the male type in genetic females has been classified

Abbreviations: CAH, congenital adrenal hyperplasia; AME, apparent mineralocorticoid
excess; ACTH, adrenocorticotropic hormone; 11b-HSD2, 11b-hydroxysteroid dehydroge-
nase type 2; 21-OHD, 21-hydroxylase deficiency; 17-OHP, 17a-hydroxyprogesterone; MR,
mineralocorticoid receptor; THF, tetrahydrocortisol; THE, tetrahydrocortisone.

*To whom reprint requests should be addressed. E-mail: minew@mail.med.cornell.edu

12790 –12797 u PNAS u October 26, 1999 u vol. 96 u no. 22

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in five stages by Prader (6), where on a scale of 1 to 5 (I–V) the
genitalia can be scored from slightly virilized (e.g., mildly enlarged
clitoris) to indistinguishable from a male. Most classical cases of
21-OHD are born with Prader IV genitalia.

Abnormalities in steroid production.The hormonal imbalances
in CAH result from the combination of impaired enzymatic
activity and subsequent impaired cortisol synthesis. Clinical
syndromes ref lect the resultant increased levels of steroids
proximal to the nonfunctioning enzymatic step and hyperstimu-
lation of the adrenal gland by ACTH. In 21-OHD, the conver-
sion of 17a-hydroxyprogesterone (17-OHP), the main substrate
of the 21-hydroxylase enzyme, to 11-deoxycortisol in the path-
way of cortisol synthesis is impaired (Fig. 1). The enzyme defect
also impairs the conversion of progesterone to 11-deoxycorti-
costerone in the pathway of aldosterone synthesis. When cortisol
production is decreased, pituitary secretion of ACTH increases
via the negative feedback system. Thus, the unblocked precur-
sors 17-OHP, pregnenolone, 17-hydroxypregnenolone, and pro-
gesterone accumulate. These steroid precursors can serve as
substrates for androgen biosynthesis and are diverted in the
adrenals to androgen pathways, resulting in excess secretion of
the androgens dehydroepiandrosterone, D4-androstenedione,
and testosterone. In classic 21-OHD, the production of these
androgens early in gestation virilizes the external genitalia in the
genetic female fetus.

Clinical Features. There are three forms of 21-OHD: (i) classic simple
virilizing; (ii) classic salt wasting; and (iii) nonclassical, a mild form
of the disease (Fig. 2).

Classic simple virilizing. The prominent features of classic simple
virilizing 21-OHD are progressive virilism with accelerated growth
and advanced bone ages but no evidence of mineralocorticoid
deficiency. Females with this type of CAH have ambiguity of the
external genitalia (including clitoromegaly and fusion and scrotal-
ization of the labial folds with a urogenital sinus).

Diagnosis at the birth of a female with virilizing CAH is usually
made immediately because of the apparent genital ambiguity. For
newborn males, however, differentiation of the external genitalia is
not affected. Diagnosis in the newborn male depends on screening.
Postnatally, genitalia may continue to virilize because of an excess
of adrenal androgens, and pseudoprecocious puberty can occur.
Signs of hyperandrogenism include facial, axillary, and pubic hair;
adult body odor; temporal balding; and severe acne. Poor control
of the disease in boys with classic CAH has been associated with

small testes and infertility with reduced sperm counts. This occurs
because the excess androgens are aromatized peripherally to es-
trogens, which suppress pituitary gonadotropins and impair the
growth and function of the testes.

The high levels of androgens can also accelerate growth in
early childhood, producing an unusually tall and muscular child.
However, this early growth spurt is followed by premature
epiphyseal maturation and closure, resulting in a final height that
is below that expected from parental heights (7). Thus, the
patients are tall children but short adults.

Classic salt wasting. Blocks in the activity of 21-hydroxylase
result in genital ambiguity in the simple virilizing form and
additionally in salt wasting in three-fourths of cases (4). With the
use of double isotope-dilution techniques, our team demon-
strated that aldosterone synthesis is impaired in some patients
with 21-OHD CAH, which is associated with electrolyte abnor-
malities, but is normal in those with no electrolyte abnormalities
(8, 9), thus biochemically distinguishing a salt-wasting form from
the simple virilizing form.

Because of a deficiency of aldosterone, a salt-retaining hormone,
renal salt wasting causes low serum concentrations of sodium
(hyponatremia), high serum potassium levels (hyperkalemia), high
plasma renin levels, and f luid volume depletion. This hormonal
milieu may be manifested by a life-threatening shock-like hypoten-
sion and hyperkalemia. We and others have shown that salt losing
in infancy from an aldosterone biosynthetic defect may improve
with age in some cases (10 –13).

Nonclassical. An attenuated late-onset form of adrenal hyper-
plasia, which we have called ‘‘nonclassical CAH,’’ was first
suspected during the 1950s by gynecologists in clinical practice
who treated women with glucocorticoids for physical signs of
hyperandrogenism, including infertility. The first biochemical
documentation of a late-appearing 21-OHD was by Decourt and
colleagues in 1957 (14). It was determined by the studies of our
group and others that this form was in fact an allelic variant at
the genetic locus of the 21-hydroxylase enzyme (15–21).

In nonclassical 21-OHD, partial deficiencies of 21-hydroxylation
cause postnatal androgen excess and milder symptoms. Females do
not have genital ambiguity at birth, though both males and females
may manifest signs of androgen excess at any phase of postnatal
development, such as precocious pubic hair. In pubertal-age girls,
menarche may be delayed, and in adolescent and young adult
women, secondary amenorrhea is common. In women, hirsutism,

Fig. 1. Pathways of steroid biosynthesis.

Fig. 2. Clinical spectrum of steroid 21-OHD. There is a wide spectrum of
clinical presentations ranging from prenatal virilization with labial fusion to
precocious adrenarche to pubertal or postpubertal virilization. [Reproduced
with permission from ref. 113 (copyright 1983, McGraw–Hill)].

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male-pattern baldness, oligomenorrhea or amenorrhea, andyor
polycystic ovary disease may occur. In males, oligospermia has been
found in some cases. For men and women, short adult stature,
insulin resistance, severe cystic acne, and reduced fertility can also
be seen in untreated groups.

Epidemiology. Newborn screening worldwide of almost 6.5 mil-
lion babies has demonstrated an overall incidence of 1:15,000 live
births for the classic form of 21-OHD (22–24). The incidence of
classic CAH in either homogeneous or heterogeneous general
populations is as high as 1 in 7,500 live births (Brazil) (25).

In 1985, we demonstrated that the overall frequency of
nonclassic 21-OHD is surprisingly high in the population at large
and even higher in certain ethnic groups (25). It is in fact the
most common human autosomal recessive disorder in humans.
The disease frequency in the general heterogeneous population
of New York City was 1y100. The highest ethnic-specific disease
frequency was found among Ashkenazic Jews at 1y27. Other
ethnic groups with high disease frequency included Hispanics
(1y40), Slavs (1y50), and Italians (1y300) (25). These results
have been confirmed by others (26, 27).

Diagnosis. In classical 21-OHD, progesterone, 17-OHP, andro-
stenedione, and testosterone are secreted in excess. Diagnosis
can be made by measuring the urinary excretion of the metab-
olites of C19 steroids, which are increased (28, 29). However,
hormonal diagnosis of all types of 21-OHD is best achieved by
an ACTH stimulation test, in which the serum 17-OHP concen-
tration is measured before and 60 min after intravenous admin-
istration of synthetic ACTH (Cortrosyn). In 1983, we set the
hormonal standards for a diagnostic ACTH-stimulation test:
plots on a logarithmic scale of baseline vs. ACTH-stimulated
17-OHP concentrations result in a regression line with three
distinguishable groups (30, 31) (Fig. 3). These nomograms
clearly distinguish the patient with (i) classical 21-OH deficiency
from (ii) those with the milder symptomatic and asymptomatic
nonclassical forms of 21-OH deficiency, as well as (iii) heterozy-
gotes for all of the forms and those subjects predicted by
genotyping to be unaffected. The nomograms can also identify
individuals heterozygous for 21-OH deficiency in the general
population who have a characteristic heterozygote response.
These nomograms provide a powerful tool by which to assign the
21-OH deficiency genotype.

Genetics. CYP21 mutations. The gene encoding 21-hydroxylase (a
microsomal cytochrome P450 termed CYP21 [previously
P450c21]) is located on the short arm of chromosome 6 in the
human lymphocyte antigen complex (32), and the gene for the
21-OH enzyme is termed CYP21 (33). Our group advanced the
understanding of the CYP21 gene, adding to its characterization
in terms of location, duplication in tandem with complement C4
isotypes, structure, and the sequencing of the gene and its
pseudogene and their arrangement on the chromosome (34 –38).
CYP21 and its homologue, the pseudogene CYP21P, alternate
with two genes called C4B and C4A (37, 39) that encode the two
isoforms of the fourth component (C4) of serum complement
(40). CYP21 and CYP21P, which each contain 10 exons, share
98% sequence homology in exons and approximately 96%
sequence homology in introns (38, 41).

Approximately 40 mutations in the CYP21 gene causing
21-OHD have been identified thus far (42). Of those, we
demonstrated deletional mutations of the 21-OHD genes and
characterized specific point mutations in many patients at our
center (38, 43– 48). The most common mutations appear to be
the result of either of two types of meiotic recombination
between CYP21 and CYP21P: (i) misalignment and unequal
crossing over, resulting in large-scale DNA deletions, and (ii)
apparent gene conversion events that result in the transfer to

CYP21 of smaller-scale deleterious mutations present in the
CYP21P pseudogene.

Correlationynoncorrelation of genotype to phenotype. In gen-
eral, the genotype of CYP21 correlates with the phenotype of
21-OHD. In 1995, we compared the genotypes and phenotypes
in approximately 200 patients and divided them into mutation-
identical groups (49). This study demonstrated that the 10 most
common mutations observed in CYP21 cause variable phenotype
effects and are not always concordant with genotype. We have
subsequently genotyped over 600 patients and identified 85
mutational groups, 23 groups of which had more than one
phenotype. DNA sequencing analysis could enable us to rule out
rare undetected mutations on the same allele.

The noncorrelation of genotype to phenotype may present a
difficulty for the clinician in directing prenatal treatment. How-
ever, in general, prenatal treatment for CAH is safe and is
warranted even when the doubt exists.

Prenatal Diagnosis and Treatment. Prenatal diagnosis is appropriate in
families where a previous family member has been affected. Pre-
natal treatment with dexamethasone suppresses the formation of
androgens by the fetal adrenal gland and can prevent or minimize
the ambiguity of the female genitalia, thus precluding an incorrect
sex assignment, and the ensuing psychiatric problem of gender
confusion in affected females. Prenatal diagnosis has now been
utilized for over a decade in the prenatal treatment of 21-OHD
(approximately 780 at-risk pregnancies were referred to our hos-
pital). Dexamethasone was chosen because it crosses the placenta,
crossing from the maternal to the fetal circulation. It enters the fetus
to suppress ACTH because it is not bound to high-affinity transport
proteins in the blood and because it cannot be metabolized by the
placental 11b-hydroxysteroid dehydrogenase.

Our group developed an algorithm for the prenatal diagnosis
of 21-OHD using direct molecular analysis of the CYP21 gene

Fig. 3. 17-OHP nomogram for the diagnosis of steroid 21-OHD (60-min
cortrosyn stimulation test). The data for this nomogram was collected be-
tween 1982 and 1991 at the Department of Pediatrics. The New York Hospital–
Cornell Medical Center, New York, NY 10021.

12792 u www.pnas.org New and Wilson

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and for treatment of the disorder with dexamethasone (Fig. 4)
(50). Dexamethasone (20 mgykgyday in three divided doses) is
administered to the pregnant mother beginning before 10 weeks
gestation, blind to whether the fetus is female or is affected, to
suppress excess adrenal androgen secretion and to prevent
virilization should the fetus be an affected female (Fig. 4). From
the timetable of sexual differentiation, it is evident that the
urogenital sinus has already begun to be formed by the ninth
week of gestation, and thus treatment must begin before this to
prevent virilization of the genitalia (Fig. 5). Diagnosis by DNA
analysis can be made after chorionic villus sampling in the eighth
to tenth week gestation or by sampling amniotic f luid cells
(amniocentesis) in the second trimester. The fetal DNA is
analyzed by PCR (51) and Southern blotting (52). Treatment is
discontinued if the fetus is shown to be an unaffected female on
DNA analysis or a male on karyotype analysis.

Since 1986, prenatal diagnosis and treatment for CAH caused by
21-OHD has been carried out in over 400 pregnancies at The New
York Hospital–Cornell Medical Center. Of those pregnancies
evaluated, approximately 85 fetuses were found to be affected with
classical 21-OHD; of those, approximately 50 were female, and of
those 35 were treated prenatally with dexamethasone until term.
Dexamethasone administered at or before the ninth week of
gestation was effective in reducing virilization in the genetic female
so that genitoplasty was not needed (Fig. 6). As reported in previous
studies (53–55), prenatally treated newborns did not differ signif-
icantly in birth weight from untreated newborns in our study. Mean
birth weight was 3.4 kg for dexamethasone-treated fetuses and 3.5
kg (P 5 0.26) for controls. Fetal wastage was slightly less for
dexamethasone-treated than untreated pregnancies. Followup
studies are in progress to evaluate cognition, gender, temperament,
and handedness (an indicator of prenatal androgen effect) in
children and adults to evaluate the long-term consequences of
prenatal dexamethasone treatment.

In initial studies, we have not identified significant or enduring
differences in side effects in the mothers who were treated with
dexamethasone from the mothers who were not. However, by

report, mothers who were not treated with dexamethasone gained
an average of 28.6 lb, whereas treated mothers gained an average
of 36.8 lbs. (P , 0.005). There were no significant differences in
regard to the presence of striae (P 5 0.14), edema (P 5 0.56),
hypertension (P 5 0.60), or gestational diabetes (P 5 0.42) by
report, either. Further, when we surveyed 100 treated mothers at

Fig. 4. Algorithm depicting prenatal management of pregnancy in families
at risk for a fetus with 21-OHD. hCG, human chorionic gonadotropin [Repro-
duced with permission from ref. 115 (Copyright 1995, the Endocrine Society)].

Fig. 5. Timetable of prenatal sexual differentiation.

Fig. 6. Genitalia of prenatally untreated ( A) and treated (B) sisters with
salt-wasting 21-OHD. The untreated newborn girl exhibits ambiguous geni-
talia with an enlarged clitoris and scrotalization of the labia majora (Prader
IV). The sib treated prenatally with dexamethasone was born with normal
genitalia, and surgical recession will not be necessary.

New and Wilson PNAS u October 26, 1999 u vol. 96 u no. 22 u 12793

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random, 14 of them had had CAH-affected girls, and all 14 were
satisfied with the outcome of prenatal dexamethasone treatment.

Based on our experience and other large human studies
(53–55), proper prenatal diagnosis and treatment of 21-OHD is
safe and is effective in significantly reducing or eliminating
virilization in the affected female.

Now that a mouse model for steroid 21-OHD has been found,
we have begun a project to develop gene therapy for CAH.

Apparent Mineralocorticoid Excess (AME). AME is a genetic disor-
der that typically causes severe hypertension in children, pre- and
postnatal growth failure, low to undetectable levels of potas-
sium, renin, and aldosterone levels, and is caused by a deficiency
of 11b-hydroxysteroid dehydrogenase type 2 (11b-HSD2). This
potentially fatal disease is caused by autosomal recessive muta-
tions in the HSD11B2 gene. The exploration and elucidation of
this disease at our center and others has opened up a new area
in receptor biology as a result of the demonstration that the
specificity of the mineralocorticoid receptor (MR) function
depends on a metabolic enzyme rather than the receptor itself.

Historical Background. Although Werder et al. described a patient
with similar clinical features in 1974, the first biochemical
description of this disease was made by us in a 3-year-old Native
American child from the Zuni tribe (56, 57). Detailed clinical
and endocrine evaluations of this child established the presence
of features that could not be explained by any known syndrome.

Aldosterone regulates electrolyte excretion and intravascular
volume by stimulating increased resorption of sodium from the
urine. It is the most potent mineralocorticoid synthesized, yet,
despite strong evidence of mineralocorticoid excess and hyper-
aldosteronism, aldosterone was undetectable in the prismatic
case and in similar cases that were subsequently identified. Thus
it was initially thought that the condition was caused by an
unknown mineralocorticoid (57, 58). However, our attempts to
identify one were unsuccessful. Using tritiated cortisol, we then
observed that the metabolism of cortisol to biologically inactive
cortisone was decreased and serum cortisol half-life was pro-
longed, whereas the conversion of cortisone to cortisol was
normal (59). This implied that 11b-hydroxysteroid dehydroge-
nase, the enzyme that converts cortisol to cortisone, may be
deficient.

We and others postulated that the mineralocorticoid speci-
ficity of the MR was lost in these patients, allowing cortisol to
bind to the MR and act as a mineralocorticoid (59 – 61). It was
demonstrated that the MR has equal affinity for aldosterone and
cortisol in vitro (62– 65). However, circulating levels of cortisol
are 100- to 1,000-fold higher than those of aldosterone, hence it
appeared that endogenous exposure of the MR to cortisol could
preempt the ability of aldosterone to be its ligand. In 1982, we
proposed that cortisol was the mineralocorticoid inducing hy-
pertension. (66).

The role 11b-HSD plays in mineralocorticoid action was con-
firmed from studies of the effects of the drug carbenoxolone and of
extracts from the root of the licorice plant, Glycyrrhiza glabra.
Licorice ingestion in large amounts can cause sodium retention,
elevated blood pressure, and potassium wasting, resulting in a
hypertensive state resembling AME (67). Glycyrrhetinic acid, the
hydrolytic derivative of the active steroid in licorice extracts, is a
competitive inhibitor of 11b-HSD (68, 69). Carbenoxolone is a
semisynthetic analog of glycyrrhetinic acid and can also induce
AME-like side effects, including sodium retention, hypokalemic
alkalosis, low levels of plasma renin, and hypertension. However,
unlike glycyrrhetinic acid, which inhibits only the dehydrogenase
function of 11b-HSD, carbenoxolone inhibits both the dehydroge-
nase and the oxoreductase (i.e., converting cortisone to cortisol)
function of the enzyme in the liver (68, 70).

Although defective 11b-HSD appeared to be a likely candi-

date for the cause of AME, the only form of the enzyme, the
gene for which had been cloned at that time, was shown to be
normal (71). The mRNA was found to be expressed predomi-
nantly in the liver (71). Because aldosterone acts primarily
through its effects on the renal distal convoluted tubules and
cortical collecting ducts, it was predicted that the MRs should
exist in these locations. However, this 11b-HSD, which was
NADP dependent, was shown to be expressed only in the
proximal tubules (72–74), suggesting the presence of another
isoform of 11b-HSD in the distal tubules. Further, no mutations
were detected in the gene for ‘‘HSD11 ’’ (later described as type
1) in patients with AME (75).

A separate NAD-dependent isoform (type 2) that colocalized
with the MR in the distal nephron was subsequently discovered by
Naray-Fejes-Toth (76 –79).† It possessed all of the properties nec-
essary for protecting the MR: a very high affinity for endogenous
glucocorticoids, a high abundance in target cells, and irreversible
dehydrogenase activity. These data suggested that a defect in a type
2 isoform was responsible for AME (77, 79 – 81).

In 1995, cDNA encoding rabbit-collecting duct 11b-HSD type
2 was isolated, sequenced, and characterized by Naray-Fejes-
Toth (82). The human cDNA for the type 2 isoform (11b-HSD2)
was cloned, sequenced (83), and localized to chromosome 16q22
by Krozowski et al. (84) and by Agarwal et al. (85) by 1995 as well.
The 11b-HSD2 enzyme is NAD-dependent and appears to have
dehydrogenase activity only (80, 83). The Km of 11b-HSD2 for
cortisol is 1–100 nM (78, 80, 83, 86), indicating that 11b-HSD2
has a 20- to 2,000-fold higher affinity for cortisol than does
11b-HSD1. In humans, 11b-HSD2 mRNA was expressed in
kidney cortex and medulla, sigmoid and rectal colon, and
salivary gland (87), and in the pancreas, prostate, ovary, small
intestine, placenta, spleen, and testes (83).

In 1995, we discovered the first mutation in the HSD11B2 gene
in a consanguineous Iranian family with three sibs suffering from
AME (a C to T transition resulting in a R337C mutation) (88). We
and others have subsequently identified 17 mutations in the
HSD11B2 gene in patients affected with AME (Fig. 7) (refs. 88 –94;
P. M. Stewart, personal communication). We have also shown, by
in vitro expression studies, that the mutations impair the conversion
of cortisol to cortisone (95, 96).

Epidemiology. AME is rare, having been identified in only
approximately 40 patients worldwide in the past 20 years. Owing

†Provencher, P. H., Mercer, W. R., Funder, J. W. & Krozowski, Z. S., Endocrine Society 74th
Annual Meeting, June 24 –27, 1992, San Antonio, TX, Vol. 305, p. 128 (abstr).

Fig. 7. Mutations in the gene for 11b-hydroxysteroid dehydrogenase type 2
in patients with AME who were investigated by our group. The HSD11B2 gene
has five exons, is 6.2 kb long, and has been mapped to chromosome 16q22. All
mutations found in affected patients are homozygous except for one patient,
who is a compound heterozygote (D244NyL250R).

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to our primary role in the discovery and characterization of
AME, we have been referred a large number of these patients
and have been able to analyze the phenotype and genotype of
these cases (90).

To date, most patients with AME who have had molecular
genetic analysis have been homozygotes for one of the different
mutations. Rare autosomal recessive mutations are classically ex-
plained by consanguinity, endogamy (a high coefficient of inbreed-
ing), or by a founder effect. In our study in 1995 of eight families
with members affected by AME, seven of the families appeared to
fit one of these three explanations (89). Four families came from
ancestry where consanguinity and tribal inbreeding were the cus-
tom, and three came from a Zoroastrian population that originated
in Iran and was driven out by Muslims in the seventh century. In the
remaining family, African-Americans from North Carolina, con-
sanguinity was not proven. Few compound heterozygotes have been
identified.

Clinical and Biochemical Features. Classic AME. We are one of the few
centers in which a comprehensive AME study population was
examined clinically, biochemically, and genetically.

AME usually presents early in life. Clinical features include
severe hypertension, failure to thrive, and persistent polydipsia
and polyuria. Biochemical profiles demonstrate metabolic alka-
losis and severe hypokalemia. Plasma renin activity is low,
suggesting a volume-expansion hypertension, which responds to
dietary sodium restriction. All steroid levels, including aldoste-
rone, are very low.

Biochemical diagnosis of AME can be made by measuring the
ratio of cortisol to cortisone by the ratios of their urinary
metabolites. In our report in 1998 of 14 AME patients studied
at our center, urinary metabolites of cortisol demonstrated an
abnormal ratio of tetrahydrocortisoneytetrahydrocortisone
(THFyTHE) with a predominance of THF (90). The ratio of
THF15aTHF to THE was 6.7 to 33, whereas the normal ratio
is 1.0. The optimal diagnostic test is to measure the generation
of tritiated water in plasma samples when 11-tritiated cortisol is

injected, as described by Hellman et al. (97). Infusion of [11-
3H]cortisol in our patients revealed the conversion of cortisol to
cortisone to be 0 – 6% in typical AME patients, whereas the
normal conversion is 90 –95% (Table 1).

In our report (90), all 14 patients studied had characteristic
signs of a severe 11b-HSD2 defect, which were consistent with
patients reported worldwide (56, 57, 59, 75, 88 –91, 98 –111):
birth weights were lower than in their unaffected sibs, and the
patients were short, underweight, and hypertensive for age.
Damage of one or more organs (kidneys, retina, heart, and
central nervous system) because of hypertension was found in all
of the patients except one. In addition, most of these patients also
had nephrocalcinosis and left ventricular hypertrophy. The
followup studies of end-organ damage in six patients who had
had 2 to 13 years of treatment revealed significant improvement
in all patients, demonstrating the importance of early diagnosis
and treatment. In our review of AME and suspected AME
patients worldwide, 5 of 42 died of AME-related illnesses, and
2 diagnosed genetically were stillborn (112).

Mild form of AME. All of the AME patients reported until 1998
had the characteristic signs of a severe 11b-HSD2 defect. We
have recently reported the first patient with a mild form of AME.

Asymptomatic hypertension was diagnosed in an American
girl at age 12.5 years during a sports physical in 1995. She had
normal serum electrolytes, undetectable plasma renin, serum
aldosterone of ,1.2 ngydl, normal urinalysis, normal urine
culture, normal intravenous pyelography, normal arteriogram of
the kidney, normal renal scan, and normal heart size on chest
x-ray. Birth weight was 7 lb 1 oz. The parents are consanguineous
Mennonites of Prussian descent (Alexanderwohl Church) (Fig.
8). The only family member with hypertension is the maternal
grandmother. Although the patient lacked hypokalemia and low
birth weight and had only mild hypertension, we established a
diagnosis of AME genetically. She exhibited only a moderately
abnor mal ratio of c ortisol to c ortisone met abolites
[THF15aTHFyTHE was 3.0] and metabolism of cortisol to
cortisone as determined by the measurement of tritiated water

Table 1. Review of AME patients studied at the New York Hospital–Cornell Medical Center: Signs and biochemical features at
presentation and subsequent biochemical and genetic evaluation

Patient Kindred Ethnicity
Age,

yr Sex

Birth
weight,

kg
BP,

mmHg

BP (90th
centile for

age)

Serum
K1,

mmol/l

THF1
5aTHFy

THE
F secretion
rate, mg/d

%
Conversion

F 3 E HSD11B2 mutation

1* 1 American Indian 1.0 F 1.8 180y140 105y69 2.2 32.1 0.08 0 E356 2 1 frameshift
2 2 Zoroastrian 9.0 M 2.0 250y180 110y71 3.5 9.1† 0.47 0 R337H, DY338
3 3 Italian-

Moroccan
4.0 M 2.3 160y110 104y67 3.1 33.0 0.72 ND L250RyD244N

4 4 African-
American

9.3 F 2.1 130y90 109y71 2.7 8.9 0.12 2 R186C

5 4 African-
American

4.3 F 2.6 142y98 98y70 2.8 14.9 0.15 4.2 R186C

6 5 East Indian 0.8 M 2.0 150y100 105y67 2.4 20.1 0.05 6 R337H, DY338
7 6 East Indian 2.1 M 2.3 150y100 91y68 1.79 12.5 0.83 2 R337H, DY338
8 7 Middle Eastern 10.9 M 2.1 170y110 115y73 1.7 27.9 0.36 ND R208C
9 7 Middle Eastern 9.3 M 2.4 160y118 110y71 2.9 27.3 0.24 ND R208C

10 8 American Indian 3.3 M 2.0 205y130 99y60 0.9 26.8 0.51 1.5 L250P, L251S
11 9 Persian 14.0 F 2.2 220y160 116y79 2.8 8.91 ND ND R337C
12 9 Persian 11.6 M 2.1 170y110 110y72 2 6.85 ND ND R337C
13 9 Persian 4.0 F 2.4 160y100 98y70 3.1 6.7 ND ND R337C
14 10 Turkish 0.1 M 2.5 155y115 99y60 3.0 13.8 ND 4.5 N286 2 1

frameshift
15 11 Mennonite 12.6 F 3.6 160y90 110y72 5.0 3.0 0.55 58.4 P227L

Normal values .2.5 3.2–5.2 1.0 11.5 90–95%

ND, not done; BP, blood pressure; F, cortisol; B, cortisone.
*, Patient 1 died; †, THFyTHE.

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release after [11-3H]cortisol infusion (58%) (typical patients are
,6%) (Table 1). The patient clearly had AME based on
biochemical evidence and later was proven to be homozygous for
the P227L mutation in the HSD11B2 gene.

Kinetic analysis, performed by our collaborator Z. Krozowski,
showed an intermediary Km in this patient as compared with a
severe AME patient (112). In whole cells, the P227L construct
gave a Km for cortisol of 300 nM as compared with a Km 62 nM
for the wild-type construct; in cell homogenates, the P227L
construct gave a Km for cortisol of 350 nM and a Km of 54 nM
for the wild-type construct. Another study of a severe AME
patient demonstrated a Km of 1,010 nM as compared with the
normal control of 110 nM (95, 96). The Km of 300 nM in this
patient suggests a less severe defect than in other patients,
resulting in her mild phenotype.

We believe that this mild form of A ME may be prevalent in
the inbred Mennonite population to which our patient belongs.
We are in the process of studying this population of 2,000
members (i) to determine whether there are other cases of this
mild form of A ME and (ii) to establish the heterozygote
frequency of the mutation found in the HSD11B2 gene of our
patient in the Mennonites to ascertain the frequency of this
disease in the European counterpart. So far, approximately
500 blood samples have been sent to us for DNA analysis from
the Mennonite population in Goessel, KS, from which our
patient comes. In our preliminar y findings of 369 samples
tested thus far, we identified nine carriers of the P227L
mutation. This results in a heterozygote frequency of 2.4%.§
Considering there are only approximately 40 patients known
worldwide with A ME, this heterozygote frequency is ver y
high.

Essential hypertension (the second highest cause of death) has
been estimated to occur in 15 million residents in the United States,
and approximately 40% are associated with low renin. If patients
unrelated to the Mennonite community have similar mild muta-
tions in the HSD11B2 gene, we may find that this disorder is an
unrecognized cause of low-renin hypertension.

§Ugrasbul-Eksinar, F., New, M. I. & Wilson, R. C., Endocrine Society 81st Annual Meeting,
June 12–15, 1999, San Diego, CA.

Significant sections of the work on which the data are reported herein
were supported by U.S. Public Health Service Grant HD00072 and
General Clinical Research Center Grant RR 06020. We express our
appreciation to Laurie Vandermolen for her editorial assistance in the
preparation of this manuscript.

1. De Crecchio, L. (1865) Morgagni 7, 154 –188.
2. New, M. I., Dupont, B., Grumbach, K. & Levine, L. S. (1982) in The Metabolic

Basis of Inherited Disease, eds. Stanbury, J. B., Wyngaarden, J. B., Fredrickson,
D. S., Goldstein, J. L. & Brown, M. D. (McGraw–Hill, New York), pp.
973–1000.

3. Lin, D., Sugawara, T., Strauss, J. F., 3rd, Clark, B. J., Stocco, D. M., Saenger,
P., Rogol, A. & Miller, W. L. (1995) Science 267, 1821–1831.

4. New, M. I. & White, P. C. (1995) in Genetic and Molecular Biological Aspects
of Endocrine Disease., ed. Thakker, R. V. (Bailliere Tindall, London), pp.
525–554.

5. Jost, A. (1971) in Hermaphroditism, Genital Anomalies and Related Endocrine
Disorders, eds. Jones, H. W. & Scott, W. W. (Williams & Wilkins, Baltimore),
pp. 16.

6. Prader, A. (1958) Helv. Paediatr. Acta 13, 2313.
7. New, M. I., Gertner, J. M., Speiser, P. W. & Del Balzo, P. (1989) J. Endocrinol.

Invest. 12, 91–95.
8. New, M. I., Miller, B. & Peterson, R. E. (1966) J. Clin. Invest. 45, 412– 428.
9. New, M. I. & Seaman, M. P. (1970) J. Clin. Endocrinol. Metab. 30, 361–371.

10. Luetscher, J. A. (1956) Recent Prog. Horm. Res. 12, 175.
11. Rosler, A., Levine, L. S., Schneider, B., Novogroder, M. & New, M. I. (1977)

J. Clin. Endocrinol. Metab. 45, 500 –512.
12. Stoner, E., Dimartino-Nardi, J., Kuhnle, U., Levine, L. S., Oberfield, S. E. &

New, M. I. (1986) Clin. Endocrinol. (Oxford) 24, 9 –20.
13. Speiser, P. W., Agdere, L., Ueshiba, H., White, P. C. & New, M. I. (1991)

N. Engl. J. Med. 324, 145–149.
14. Decourt, M. J., Jayle, M. F. & Baulieu, E. (1957) Ann. Endocrinol. (Paris) 18,

416.
15. New, M. I., Lorenzen, F., Pang, S., Gunczler, P., Dupont, B. & Levine, L. S.

(1979) J. Clin. Endocrinol. Metab. 48, 356 –359.
16. Rosenwaks, Z., Lee, P. A., Jones, G. S., Migeon, C. J. & Wentz, A. C. (1979)

J. Clin. Endocrinol. Metab. 49, 335.
17. Levine, L. S., Dupont, B., Lorenzen, F., Pang, S., Pollack, M., Oberfield, S.,

Kohn, B., Lerner, A., Cacciari, E., Mantero, F., et al. (1980) J. Clin.
Endocrinol. Metab. 51, 1316 –1324.

18. Laron, Z., Pollack, M. S., Zamir, R., Roitman, A., Dickerman, Z., Levine,
L. S., Lorenzen, F., O’Neill, G. J., Pang, S., New, M. I. , et al. (1980) Hum.
Immunol. 1, 55– 66.

19. Pollack, M. S., Levine, L. S., O’Neill, G. J., Pang, S., Lorenzen, F., Kohn, B.,
Rondanini, G. F., Chiumello, G., New, M. I. & Dupont, B. (1981) Am. J. Hum.
Genet. 33, 540 –550.

20. Levine, L. S., Dupont, B., Lorenzen, F., Pang, S., Pollack, M., Oberfield, S. E.,

Kohn, B., Lerner, A., Cacciari, E., Mantero, F., et al. (1981) J. Clin.
Endocrinol. Metab. 53, 1193–1198.

21. Kohn, B., Levine, L. S., Pollack, M. S., Pang, S., Lorenzen, F., Levy, D.,
Lerner, A. J., Rondanini, G. F., Dupont, B. & New, M. I. (1982) J. Clin.
Endocrinol. Metab. 55, 817– 827.

22. Pang, S. Y., Wallace, M. A., Hofman, L., Thuline, H. C., Dorche, C., Lyon,
I. C., Dobbins, R. H., Kling, S., Fujieda, K. & Suwa, S. (1988) Pediatrics 81,
866 – 874.

23. Pang, S. & Clark, A. (1990) Trends Endocrinol. Metab. 1, 300 –307.
24. Pang, S. & Clark, A. (1993) Screening 2, 105–139.
25. Speiser, P. W., Dupont, B., Rubinstein, P., Piazza, A., Kastelan, A. & New,

I. M. (1985) Am. J. Hum. Genet. 37, 650 – 667.
26. Sherman, S. L., Aston, C. E., Morton, N. E., Speiser, P. W. & New, M. I. (1988)

Am. J. Hum. Genet. 42, 830 – 838.
27. Zerah, M., Ueshiba, H., Wood, E., Speiser, P. W., Crawford, C., McDonald,

T., Pareira, J., Gruen, D. & New, M. I. (1990) J. Clin. Endocrinol. Metab. 70,
1662–1667.

28. Bongiovanni, A. M., Eberlein, W. R. & Cara, J. (1954) J. Clin. Endocrinol.
Metab. 14, 409.

29. Butler, G. C. & Marrian, G. F. (1937) J. Biol. Chem. 119, 565.
30. New, M. I., Lorenzen, F., Lerner, A. J., Kohn, B., Oberfield, S. E., Pollack,

M. S., Dupont, B., Stoner, E., Levy, D. J., Pang, S., et al. (1983) J. Clin.
Endocrinol. Metab. 57, 320 –326.

31. White, P. C., New, M. I. & Dupont, B. (1987) N. Engl. J. Med. 316, 1519 –1524.
32. Dupont, B., Oberfield, S. E., Smithwick, E. M., Lee, T. D. & Levine, L. S.

(1977) Lancet 2, 1309 –1312.
33. Nebert, D. W., Nelson, D. R. & Coon, M. J. (1991) DNA Cell Biol. 10, 1–14.
34. White, P. C., New, M. I. & Dupont, B. (1984) Proc. Natl. Acad. Sci. USA 81,

1986 –1990.
35. White, P. C., New, M. I. & Dupont, B. (1984) Proc. Natl. Acad. Sci. USA 81,

7505–7509.
36. White, P. C., Chaplin, D. D., Weis, J. H., Dupont, B., New, M. I. & Seidman,

J. G. (1984) Nature (London) 312, 465– 467.
37. White, P. C., Grossberger, D., Onufer, B. J., Chaplin, D. D., New, M. I.,

Dupont, B. & Strominger, J. L. (1985) Proc. Natl. Acad. Sci. USA 82,
1089 –1093.

38. White, P. C., New, M. I. & Dupont, B. (1986) Proc. Natl. Acad. Sci. USA 83,
5111–5115.

39. Carroll, M. C., Campbell, R. D. & Porter, R. R. (1985) Proc. Natl. Acad. Sci.
USA 82, 521–525.

40. Belt, K. T., Carroll, M. C. & Porter, R. R. (1984) Cell 36, 907–914.

Fig. 8. Pedigree of Mennonite family showing consanguinity (114).

12796 u www.pnas.org New and Wilson

D
o
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a
d
e
d
 a

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e
llo

n
 U

n
iv

e
rs

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 o

n
 A

p
ri
l 5

, 
2
0
2
1
 



41. Higashi, Y., Yoshioka, H., Yamane, M., Gotoh, O. & Fujii-Kuriyama, Y.
(1986) Proc. Natl. Acad. Sci. USA 83, 2841–2845.

42. Krawczak, M. & Cooper, D. N. (1997) Trends Genet. 13, 121–122.
43. Werkmeister, J. W., New, M. I., Dupont, B. & White, P. C. (1986) Am. J. Hum.

Genet. 39, 461– 469.
44. Amor, M., Parker, K. L., Globerman, H., New, M. I. & White, P. C. (1988)

Proc. Natl. Acad. Sci. USA 85, 1600 –1604.
45. Globerman, H., Amor, M., Parker, K. L., New, M. I. & White, P. C. (1988)

J. Clin. Invest. 82, 139 –144.
46. White, P. C., Vitek, A., Dupont, B. & New, M. I. (1988) Proc. Natl. Acad. Sci.

USA 85, 4436 – 4440.
47. Speiser, P. W., New, M. I. & White, P. C. (1988) N. Engl. J. Med. 319, 19 –23.
48. Tusie-Luna, M., Speiser, P. W., Dumic, M., New, M. I. & White, P. C. (1991)

Mol. Endocrinol. 5, 685– 692.
49. Wilson, R. C., Mercado, A. B., Cheng, K. C. & New, M. I. (1995) J. Clin.

Endocrinol. Metab. 80, 2322–2329.
50. Speiser, P. W., Laforgia, N., Kato, K., Pareira, J., Khan, R., Yang, S. Y.,

Whorwood, C., White, P. C., Elias, S., Schriock, E., et al. (1990) J. Clin.
Endocrinol. Metab. 70, 838 – 848.

51. Wilson, R. C., Wei, J. Q., Cheng, K. C., Mercado, A. B. & New, M. I. (1995)
J. Clin. Endocrinol. Metab. 80, 1635–1640.

52. White, P. C., Vitek, A., Dupont, B. & New, I. (1988) Proc. Natl. Acad. Sci. USA
85, 4436 – 4440.

53. Forest, M. G., Betuel, H. & David, M. (1989) Endocr. Res. 15, 277–301.
54. Forest, M. G., David, M. & Morel, Y. (1993) J. Steroid Biochem. Mol. Biol. 45,

75– 82.
55. Mercado, A. B., Wilson, R. C., Cheng, K. C., Wei, J. Q. & New, M. I. (1995)

J. Clin. Endocrinol. Metab. 80, 2014 –2020.
56. Werder, E. A., Zachmann, M., Vollmin, J. A., Veyrat, R. & Prader, A. (1974)

Res. Steroids 6, 385–389.
57. New, M. I., Levine, L. S., Biglieri, E. G., Pareira, J. & Ulick, S. (1977) J. Clin.

Endocrinol. Metab. 44, 924 –933.
58. Ulick, S., Ramirez, L. C. & New, M. I. (1977) J. Clin. Endocrinol. Metab. 44,

799 – 802.
59. Ulick, S., Levine, L. S., Gunczler, P., Zanconato, G., Ramirez, L. C., Rauh,

W., Rosler, A., Bradlow, H. L. & New, M. I. (1979) J. Clin. Endocrinol. Metab.
49, 757–764.

60. New, M. I., Oberfield, S. E., Carey, R. M., Greig, F., Ulick, S. & Levine, L. S.
(1982) in Endocrinology of Hypertension, Serono Symposia No. 50, eds.
Mantero, F., Biglieri, E. G. & Edwards, E. R. W. (Academic, New York), pp.
85–101.

61. Oberfield, S. E., Levine, L. S., Carey, R. M., Greig, F., Ulick, S. & New, M. I.
(1983) J. Clin. Endocrinol. Metab. 56, 332–339.

62. Funder, J. W., Pearce, P. T., Smith, R. & Smith, A. I. (1988) Science 242,
583–585.

63. Arriza, J. L., Weinberger, C., Cerelli, G., Glaser, T. M., Handelin, B. L.,
Housman, D. E. & Evans, R. M. (1987) Science 237, 268 –275.

64. Krozowski, Z. S. & Funder, J. W. (1983) Proc. Natl. Acad. Sci. USA 80,
6056 – 6060.

65. Marver, D., Stewart, J., Funder, J. W., Feldman, D. & Edelman, I. S. (1974)
Proc. Natl. Acad. Sci. USA 71, 1431–1435.

66. New, M. I., Oberfield, S. E., Carey, R. M., Greig, F., Ulick, S. & Levine, L.
S. (1982) Endocrinology of Hypertension, Serono Symposia No. 50 (Academic,
New York), pp. 85–101.

67. Stewart, P. M., Wallace, A. M., Valentino, R., Burt, D., Shackleton, C. H. &
Edwards, C. R. (1987) Lancet ii, 821– 824.

68. Stewart, P. M., Wallace, A. M., Atherden, S. M., Shearing, C. H. & Edwards,
C. R. (1990) Clin. Sci. 78, 49 –54.

69. Farese, R. V., Jr., Biglieri, E. G., Shackleton, C. H., Irony, I. & Gomez-Fontes,
R. (1991) N. Engl. J. Med. 325, 1223–1227.

70. Funder, J. W. (1989) Endocr. Res. 15, 227–238.
71. Tannin, G. M., Agarwal, A. K., Monder, C., New, M. I. & White, P. C. (1991)

J. Biol. Chem. 266, 16653–16658.
72. Edwards, C. R., Stewart, P. M., Burt, D., Brett, L., McIntyre, M. A., Sutanto,

W. S., de Kloet, E. R. & Monder, C. (1988) Lancet 2, 986 –989.
73. Castello, R., Schwarting, R., Muller, C. & Hierholzer, K. (1989) Renal Physiol.

Biochem. 12, 320 –327.
74. Rundle, S. E., Funder, J. W., Lakshmi, V. & Monder, C. (1989) Endocrinology

125, 1700 –1704.
75. Nikkila, H., Tannin, G. M., New, M. I., Taylor, N. F., Kalaitzoglou, G.,

Monder, C. & White, P. C. (1993) J. Clin. Endocrinol. Metab. 77, 687– 691.
76. Naray-Fejes-Toth, A., Watlington, C. O. & Fejes-Toth, G. (1991) Endocri-

nology 129, 17–21.
77. Mercer, W. R. & Krozowski, Z. S. (1992) Endocrinology 130, 540 –543.
78. Brown, R. W., Chapman, K. E., Edwards, C. R. & Seckl, J. R. (1993)

Endocrinology 132, 2614 –2621.
79. Naray-Fejes-Toth, A. & Fejes-Toth, G. (1994) Steroids 59, 105–110.

80. Rusvai, E. & Naray-Fejes-Toth, A. (1993) J. Biol. Chem. 268, 10717–10720.
81. Krozowski, Z., Ma Guire, J. A., Stein-Oakley, A. N., Dowling, J., Smith, R. E.

& Andrews, R. K. (1995) J. Clin. Endocrinol. Metab. 80, 2203–2209.
82. Naray-Fejes-Toth, A. & Fejes-Toth, G. (1995) Endocrinology 136, 2579 –2586.
83. Albiston, A. L., Obeyesekere, V. R., Smith, R. E. & Krozowski, Z. S. (1994)

Mol. Cell Endocrinol. 105, R11–R17.
84. Krozowski, Z. S., Baker, E., Obeyesekere, V. & Callen, D. F. (1995) Cytogenet.

Cell Genet. 71, 124 –125.
85. Agarwal, A. K., Rogerson, F. M., Mune, T. & White, P. C. (1995) Genomics

29, 195–199.
86. Agarwal, A. K., Mune, T., Monder, C. & White, P. C. (1994) J. Biol. Chem.

269, 25959 –25962.
87. Whorwood, C. B., Mason, J. I., Rickets, M. L., Howie, A. J. & Stewart, P. M.

(1995) Mol. Cell Endocrinol. 110, R7–R11.
88. Wilson, R. C., Krozowski, Z. S., Li, K., Obeyesekere, V. R., Razzaghy-Azar,

M., Harbison, M. D., Wei, J. Q., Shackleton, C. H. L., Funder, J. W. & New,
M. I. (1995) J. Clin. Endocrinol. Metab. 80, 2263–2266.

89. Wilson, R. C., Harbison, M. D., Krozowski, Z. S., Funder, J. W., Shackleton,
C. H. L., Hanauske-Able, H. M., Wei, J. Q., Hertecant, J., Moran, A.,
Neiberger, R. E., et al. (1995) J. Clin. Endocrinol. Metab. 80, 3145–3150.

90. Dave-Sharma, S., Wilson, R. C., Harbison, M. D., Newfield, R., Razzaghy-
Azar, M., Krozowski, Z., Funder, J. W., Shackleton, C. H. L., Bradlow, H. L.,
Wei, J., et al. (1998) J. Clin. Endo. Metab. 83, 2244 –2254.

91. Mune, T., Rogerson, F. M., Nikkila, H., Agarwal, A. K. & White, P. C. (1995)
Nat. Genet. 10, 394 –399.

92. Stewart, P. M., Krozowski, Z. S., Gupta, A., Milford, D. V., Howie, J. A. &
Sheppard, M. C. (1996) Lancet 347, 88 –91.

93. Kitanaka, S., Katsumata, N., Tanae, A., Hibi, I., Takeyama, K., Fuse, H., Kato,
S. & Tanaka, T. (1997) J. Clin. Endocrinol. Metab. 82, 4054 – 4058.

94. Li, A., Li, K. X. Z., Marui, S., Krozowski, Z. S., Batista, M. C., Whorwood,
C. B., Arnhold, I. J. P., Shackleton, C. H. L., Mendonca, B. B. & Stewart, P. M.
(1997) J. Hypertens. 15, 1397–1402.

95. Obeyesekere, V. R., Ferrari, P., Andrews, R. K., Wilson, R. C., New, M. I.,
Funder, J. W. & Krozowski, Z. S. (1995) J. Clin. Endocrinol. Metab. 80,
3381–3383.

96. Ferrari, P., Obeyesekere, V. R., Li, K., Wilson, R. C., New, M. I., Funder, J. W.
& Krozowski, Z. S. (1996) Mol. Cell Endocrinol. 119, 21–24.

97. Hellman, L., Nakada, F., Zumoff, B., Fukushima, D., Bradlow, H. L. &
Gallagher, T. F. (1971) J. Clin. Endocrinol. Metab. 33, 52– 62.

98. Shackleton, C. H., Rodriguez, J., Arteaga, E., Lopez, J. M. & Winter, J. S.
(1985) Clin. Endocrinol. (Oxford) 22, 701–712.

99. Stewart, P. M., Corrie, J. E., Shackleton, C. H. & Edwards, C. R. (1988) J. Clin.
Invest. 82, 340 –349.

100. Batista, M. C., Mendonca, B. B., Kater, C. E., Arnhold, I. J., Rocha, A.,
Nicolau, W. & Bloise, W. (1986) J. Pediatr. 109, 989 –993.

101. Monder, C., Shackleton, C. H., Bradlow, H. L., New, M. I., Stoner, E., Iohan,
F. & Lakshmi, V. (1986) J. Clin. Endocrinol. Metab. 63, 550 –557.

102. Kitanaka, S., Tanae, A. & Hibi, I. (1996) Clin. Endocrinol. (Oxford) 44,
353–359.

103. Sann, L., Revol, A., Zachmann, M., Legrand, J. C. & Bethenod, M. (1976)
J. Clin. Endocrinol. Metab. 43, 265–271.

104. Shackleton, C. H., Honour, J. W., Dillon, M. J., Chantler, C. & Jones, R. W.
(1980) J. Clin. Endocrinol. Metab. 50, 786 –702.

105. Honour, J. W., Dillon, M. J., Levin, M. & Shah, V. (1983) Arch. Dis. Child.
58, 1018 –1020.

106. Milford, D. V., Shackleton, C. H. L. & Stewart, P. M. (1995) Clin. Endocrinol.
(Oxford) 43, 241–246.

107. Muller-Berghaus, J., Homoki, J., Michalk, D. V. & Querfeld, U. (1996) Acta
Paediatr. 85, 111–113.

108. Fiselier, T. J., Otten, B. J., Monnens, L. A., Honour, J. W. & van Munster, P. J.
(1982) Horm. Res. 16, 107–114.

109. Harinck, H. I., van Brummelen, P., Van Seters, A. P. & Moolenaar, A. J.
(1984) Clin. Endocrinol. (Oxford) 21, 505–514.

110. Winter, J. S. D. & McKenzie, J. K. (1977) in Juvenile Hypertension, eds. New,
M. I. & Levine, S. (Raven, New York), pp. 123–132.

111. Gourmelen, M., Saint-Jacques, I., Morineau, G., Soliman, H., Julien, R. &
Fiet, J. (1996) Eur. J. Endocrinol. 135, 238 –244.

112. Wilson, R. C., Dave-Sharma, S., Wei, J., Obeyesekere, V. R., Li, K., Ferrari,
P., Krozowski, Z. S., Shackleton, C. H. L., Bradlow, L., Wiens, T., et al. (1998)
Proc. Natl. Acad. Sci. USA 95, 10200 –10205.

113. New, M. I., DuPont, B., Grumbach, K. & Levine, L. S. (1983) in The Metabolic
Basis of Inherited Disease, eds. Stanbury, J. B., Wyngaarden, J. B., Fredrickson,
D. S., Goldstein, J. L. & Brown, M. S. (McGraw–Hill, New York), p. 973–1000.

114. Wedel, D. C. (1974) The Story of Alexanderwohl (Mennonite Press, Newton,
KA).

115. Mercado, A. B., Wilson, R. C., Chung, K. C., Wei, J.-Q. & New, M. I. (1995)
J. Clin. Endocrinol. Metab. 80, 2014 –2020.

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