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Danazol inhibits human adrenal 21-and 11β-hydroxylation in vitro
251
2531 DANAZOL INHIBITS HUMAN 118-HYDROXYLATION Robert
ADRENAL Pl-AND IN VITRO --
L. Barbieri, Rapin Osathanondh, Jacob A. Canick, Robert J. Stillman+, and Kenneth J. Ryan
Laboratory of Human Reproduction and Reproductive Biology and Department of Obstetrics and Gynecology Boston Hospital for Women Harvard Medical School 02115 Boston, Massachusetts and +Division of Reproductive Endocrinology Department of Obstetrics and Gynecology The George Washington University School of Medicine Washington, DC 20037 Received 7-30-79 ABSTRACT The effects of danazol on steroidogenesis in vitro in the 16-20 week old human fetal adrenal were examinedy studying: danazol binding to adrenal microsomal and mitochondrial1) cytochrome P-450, and 2) enzyme kinetics of danazol inhibition of the adrenal microsomal 21-hydroxylase and the The addition of danazol to mitochondrial 118-hydroxylase. preparations of adrenal microsomes or mitochondria elicited Danazol bound a type I cytochrome P-450 binding spectrum. to microsomal cytochrome P-450 with a high affinity apparent spectral dissociation constant (KS) of 1 nM and with a Danazol bound to mitochondrial lower affinity K'S of 10 PM. cytochrome P-450 with a KS of 5 uM. In addition, danazol competitively inhibited the microsomal 21-hydroxylase (apparent enzymatic inhibition constant KI = 0.8 ~.IM)and the These findings mitochondrial 118-hydroxylase (KI = 3 PM). demonstrate that low concentrations of danazol directly inhibit steroidogenesis in the human fetal adrenal -~ in vitro. INTRODUCTION Danazol
is being
used
endometriosis
(l-3),
chronic
cious
(6,7) and congenital
puberty
Although
the mechanisms
peutic
effects
stated
that danazol
minimal
androgenic
studies
in men
clinically cystic
by which
are poorly
danazol
S
TDROIDII
exerts
edema
antigonadotropin
women
However,
(8).
its thera-
it has been
(.l-5,7,8).
of
(3-5), preco-
angioneurotic
is a selective
(9), premenopausal
VoZwne 35, Number 3
mastitis
understood,
effects
in the management
repeatedly with
clinical
(10) and children
(6)
March, 1980
252
have
shown
gonadal
that danazol
steroids
LH or FSH.
without
These
can significantly significantly
observations
suggest
one of its primary
pharmacologic
inhibiting
steroidogenesis.
ported
gonadal
that danazol
of rat adrenal observations on human
competitively
and testicular
prompted
adrenal
suppress
serum
suppressing
serum
that danazol
effects
by directly
We have inhibits
recently
multiple
steroidogenesis
us to examine
exerts
enzymes
(11,lZ).
the effects
re-
These
of danazol
steroidogenesis. MATERIALS
AND METHODS
Adrenals were obtained from 16-20 week old human fetuses legally aborted with prostaglandin F2u. Unlabelled 17-hydroxyprogesterone, deoxycorticosterone and corticosterone urchased from Steraloids and recrystallized were before use. [1,2- t; HI-17-hydroxyprogesterone (SA = 40.4 Ci/mmol) and [1,2-3H]-deoxycorticosterone (SA = 46.8 Ci/mmol) were purchased from New England Nuclear and purified by thin layer chromatography using a solvent system of ehloroform:methanol Danazol was supplied by the Sterling-Winthrop c97:3 v/v). Research Institute. Preparation of mitochondrial an.d microsomal suspensions: Adrenals were homogenized in three parts 0.25 M sucrose The 750g supercontaining 0.01 M Tris-HGL, pH 7.2 at 25O. This pellet natant was centrifuged at 12,000g for 10 min. was resuspended in 0.15 M KCL containing 0.01 M 'Iris, and centrifuged at 12,OOOg for 10 min. The final pellet was homogenized in a small volume of KCL-Tris, sonicated and used The 12,000g supernatant as the mitochondrial suspension. This pellet was was centrifuged at 100,OOOg for 60 min. resuspended in 0.15 M KCL containing 0.01 M Tris and recentrifuged at 100,OOOg for 60 min. The final pellet was Protein concenhomogenized in a small volume of KCL-Tris. tration was determined by the method of Lowry -et al. (13) with bovine serum albumin as the standard, All spectral determinations Spectral determinations: were made usins a DW-2 UV-visible spectronhometer (American Instrument Co.; Silver Spring, MD).- Cytochrome P-450 concentrations were measured by the method of Estabrook et al. (14). To determine the spectral changes caused by the addition of steroids to microsomal or mitochondrial preparation, 6 ml of a 1 mg protein/ml microsomal or mitothondrial suspension was divided between sample and reference cuvettes, and a base-
line drawn. The steroid sample, dissolved in propylene glyThe spectrum co1 alone was added to the reference cuvette. The propylene glycol concenfrom 370 to 500 urn was scanned. Hanes tration in the cuvettes never exceeded 1.0% (v/v). plots were prepared as previously described (15). The assay Inhibition of enzymes of steroidogenesis: for the 21-hydroxylase and the llg-hydroxylase utilized a reaction mixture containing 0.15 M KCL, 50 mM Tris, pH 7.4 at 37O, 500 F\M NADPH, 50 mM glucose-6-phosphate, 5 units of glucose-6-phosphate dehydrogenase, 5 mM MgC12, 0.5 PCi of radiolabelled substrate and appropriate amounts of unlabelled substrate and danazol in a final volume of 0.3 ml. The reaction was started by the addition of 0.1 ml of microsomal or mitochondrial protein. Lineweaver-Burk plots were prepared as previously discribed (16). For the 21-hydroxylase assay the substrate was 17hydroxyprogesterone and the product was ll-deoxycortisol. Progesterone was not chosen as the substrate for the 21hydroxylase assay because mid-trimester human fetal adrenal microsomes can efficiently convert progesterone to deoxycorticosterone, 17-hydroxyprogesterone and 16cchydroxyprogesterone (17,18). In contrast, mid-trimester human fetal adrenal microsomes can only efficiently convert 17-hydroxyprogesterone to 11-deoxycortisol (19). For the 118-hydroxylase assay the substrate was deoxycorticosterone and the product was corticosterone. Samples in the il-hydroxylase assay were incubated for 3 and 6 minutes. For the 118-hydroxylase assay, samples were incubated for 6 and 12 minutes. After incubation, the reaction was stopped by the addition of 0.4 ml methanol. An aliquot of the reaction mixture was then applied to silica gel thin layer plates and the product and the substrate were separated using a solvent system of chloroform:methanol 97:3 v/v (17hydroxyprogesterone rf = 0.66; and corticosterone rf = 0.25). The product was scraped from the plate, eluted from the gel and the radioactivity measured by liquid scintillation spectrometry. The purity of the products of the two reactions was established by recrystallization of representative samples to constant specific radioactivity. In no case was the purity of the product isolated by initial chromatopraphy less than 90%. RESULTS Danazol P-450
interaction
concentrations
chondria
prepared
adrenals
ranged
with
obtained
cytochrome
from microsomes
from four pairs
from
0.50
P-450:
of pooled
to 0.60 nmoles/mg
Cytochrome
and mitohuman
fetal
protein
for the
microsomes
and 0.45
to 0.50 nmoles/mg
protein
for the mito-
chondria. Addition in a type
of danazol
I difference
to microsomal
spectrum
with
380 and 390 nm and a Soret minimum the titration
of a microsomal
demonstrated
a high
affinity
constant
(K'S) of 10 PM
difference minimum
spectrum
at 420 nm.
suspension
with
To a microsomal in the sample achieve This
(Pig. 1).
to microsomal with
suspension cuvette,
of 17-hydrox-
elicited
already
a type
I
at 388 and Soret
of the titration
J.7-hydroxyprogesterone
dissociation
dissociation
Addition
a Soret maximum
of
danazol
spectral
affinity
between
Analysis
with
preparations
Analysis
of a microsomal
yielded
containing
17-hydroxyprogesterone
a concentration
resulted
at 418 nm.
apparent
(KS) of 1 uM and a lower
resulted
a Soret maximum
suspension
Constant
yprogesterone
preparations
a KS of 0.8 PM. 100 pH danazol was
added
to
of 35 PM 17-hydroxyprogesterone,
in a 50% increase
in the type
I difference
spectrum. Addition gave
a type
between
I difference
to mitochondrial spectrum
with
suspensions
a Soret maximum
380 and 390 nm and a Soret minimum
Analysis with
of danazol
of the titration
danazol
corticosterone producing
demonstrated bound
of a mitochondrial
suspension
a KS of 5 I.IM(Pig. 21.
to mitocbondrial
a type, I difference
respectively.
at 419 nm.
spectrum
cytochrome
DeoxyP-450
at 390 nm and 420 nm
The KS of deoxycorticosterone
binding
to
mitochondrial drial
suspension
sample added
cytochrome
cuvette, to aehleve
already
I difference
was
containing
corticosterone
This
0.75 p&f.
To a mitochon-
3.5 pM danazol
in the
or deoxycorticosterone
a concentration
or deoxycorticosterone. type
P-450
were
of 30 ~119cortieosrerone
resulted
in no change
In the
spectrum.
Figure 1. Danazol binding to human adrenal microsomal. cytochrome P-450. Concentrations of danazol: 11 0.33 pi%, 2) 1.00 pM, 4) 3.00 pM, 5) 4.33 PM, 6) 7.00 PM, 7) 20.33 p%, 8) 17.0 j.tM,9) 23.67 YEI, 10) 37 yM, and 11) 63.67 PM. Inset: Hanes plot of danazol bjlnding to micxosomal cytochxome P-45#. % = 3. y&2, K'S fz 10 pM.
S
256
I ,
TDEIBOXDB
6 I
380
I
400
420
I
440
Wavelength
1
I
460
480
500
(nm)
Figure 2. Danazol binding to human adrenal mitochsndrial Concentrations of danazol: cytochrome P-450. 1) 1.6 NJ, 2) 4.27 I.IM,3) 10.93 PM, 4) 17.6 pM, 5) 3Q.93 JAM. Inset: Hanes plot of danazol binding to mitochondrial cytochrome P-450 Kg = 5 I.IM. Enzyme
the 21-hydroxylase The apparent danazol
!JM.
was
minute
constant
(Fig. 3,4). (KT) for
was 0.8 PM. (KM) of 17-
in the Zl-hydroxylase inhibition
inhihited
assay was
assay was
incubations
2.8 PM.
4
of the 118-hydrox-
The KM for deoxycorticosterone
3 PM.
ll$-hydroxylase
constant
of the 21-hydroxylase
The KT for danazol
ylase
inhibition
Michaelis-Menton
hydroxyprogesterone
competitively
and the llfi-hydroxylase
enzymatic
inhibition
The apparent
Danazol
inhibition:
The three
for the 21-hydroxylase
in the and six
assay
gave
S similar
reaction
incubations reaction product
257
The six and twelve
velocities.
for the lib-hydroxylase
velocities. formation
The values concentration,
These
over
assay
results
similar
to values fetal
P-450
which
reported
obtained
have been Cytochrome
(20).
binding
in these reported P-450
C-23). When
added
enzymatic
inhibition
enzymatic Addition suspension
suggests
of deoxycorticosterone already
saturated
spectrum.
competitively
llg-hydroxylase
with
(KT = 3 pM)
dissociation
adrenal
(21).
of adrenal
1 difference
that danazol. binds
site of the human
adrenal
(22) and the lib-
constant
spectral
to values
as the terminal
that danazol
mitochondrial
s.lmilar to the apparent (4s = 5 pM)
a type
P-450
to cortico-
to a preparation
and the observation
apparent
elicits
adult
implicated
This
the adrenal
mitochondrial.
for the human
for
the Kg for
are similar
21-hydroxylase
are
reported
conversion
experiments
danazof
inhibits
been
to adrenal
mitochondria finding
P-450
in this paper
In addition,
has been
of the adrenal
hydroxylaae
cytochrome
previously
and the KM for deoxycorticosterone
oxidase
of
studied.
microsomal
have
adrenal
deoxycorticosterone
which
linearity
and the KS for 17-hydroxyprogesterone
to microsomal
sterone
minute
had similar
indicate
the time period
for adrenal
binding
the human
TEIROXDS
constant
to the active
lie-hydroxylase.
to a mitochondrial with
danazol
did not
change
an
the size
of the type I difference
it can be inferred chondrial
spectrum.
that danazol
cytochrome
P-450
can bind
sites
Therefore,
to all the mito-
available
to deoxycor-
ticosterone. Human eytochrome
fetal
adrenal
P-450
involved
roid hydroxylations: ylase,
micrasomes
in at least
adrenal
microsomes
difference
complicates
spectra
elicited
microsomaf F3
P-450
= 1 PM, RrS = 10 PM)
the active
The results
@omen been
reported
never
to have Adrenal
(24).
the adrenal
than the serum suggest daily,
that
adrenal
here
adrenal
serum
concentration
in women
the adrenal
to the enzymatic
orally
However,
taking
the
to adrenal
I spectrum bfnds
that
to
danazol
is
in vitro. --
per day have
concentrations
as high
of danasol. have
However,
in humans.
of
21-hydroxylase.
steroidogenesfs
concentrations
concentration
a type
indicate
danazol
fetal
inhibits
that danazol
400 mg of danazof
been measured
animals
eliciting
suggests
presented
of human
receiving
as 2 PM
the interpretation
competitively
site of the human
sn inh%bitor
in human
fK, = 0.8 $IM) and that it binds
cytochrome
(17,X8).
in these microsomes,
the ob.servation that danazol 2X-hydroxylase
P-450
ste-
the Pl-hydrox-
and the 17,20-lyase
of the cytochrome
of
four different
the Z7a-hydroxylase,
the Iba-hydroxylase,
The heterogeneity
species
contain
in laboratory
of danasol. is higher
(25).
These
observations
400 mg or more
concentration
of the drug
KT 's for danazol
inhibition
of danasol is similar of the adre-
nal 21-hydroxylase data
suggest
that
and Ll@-hydroxylase. danazol
sis few investigators steroidogenesis et al.
increase
metyrapone synthetic
have
that
in women
in urinary
stimulation
1
adrenal
receiving
examined
adrenal
danazol.
receiving
response
was within
these
steroidogene-
Went2
danazol
17-hydroxycorticoids
and the incremental ACTH
alter
carefully
in patients
(26) reported
percent
may
Although
after
of cortisol
normal
the
to
limits.
2bHYDROXYLASE
i I/(i7+iydroxyprogesteronef fpM_‘)
plots of danazol inhibition of Figure 3. Lineweaver-Burk Zl-hydroxylase substrate: 17-hydroxyprogesterone, product: ll-deoxycortisol) protein concentration 12.5 ug/ml. Danazol concentrations: O-O,+1 pM,A-2 nM,A-5 JIM. Enzymatic inhibition constant = 0.8 nM. These
studies
present
suggest
in women
that no g1ucocoricoS.d
receiving
danazol.
deficiency
However,
is
s.tudies b*y
Stillman itative et
al.
et
(27)
of
after
the
studied once
on as
Danazol
ficant
change
sulted
in
effect
the
of
danazol
before Five
6th
of
day
and
and
of
danazol
increase
control
orally
menagain per
in no
progesterone,
androstenedione
con-
cosyntro-
and
concentration, in
serum
consecutive
mg
qual-
menstruating
resulted
cortisol
the
after
two
600
the
Stillman
on
normally
administration
a significant
alters
synthesis.
a pre-treatment
in baseline
droepiandrosterone
danazol
steroid
steroids
administration
6 days.
that
stimulation.
cycles; the
adrenal
of various
were
strual
suggest
measured
(AcTH~_~~~)
women
for
(27)
pattern
centration pin
al.
day
signibut
re-
dehy-
concentrations.
li/3-HYDROXYLASE
I
2
I/(Desoxycorticosterone)
(PM)-’
Figure 4. Lineweaver-Burk plot of danazol inhibition of llf3-hydroxylase (substrate: deoxycorticosterone, product: corticosterone) protein concentration 625 pg/ml. Danazol concentrations: @-0,&-l uM,m-5 uM. Enzymatic inhibition constant = 3 @I. The
administration
of
cosyntropin
during
the
danazol
treat-
ment
period
resulted
in greater
and deoxycortisol
and smaller
and cortisol
that seen
findings
than
suggest
ylase
sufficient
to assess
hydroxylase.
centration,
the effects danazol
does not
but may
adrenal
steroids.
danazol
on human
further
study.
produces
obtained
In summary
800 mg per day)
in progesterone
alter
alter
adrenal
These
inhibition
and the 118-hydrox-
in the study were of danazol
baseline
serum
(600cortisol
concentration
elucidation
steroidogenesis
not
on the 21-
administration
the serum
Complete
period.
a partial
oxidoreductase
The data
in vivo. --
increments
in pregnenolone
in the control
that danazol
of the 3S-hydroxysteroid
increments
of other
of the effects in vivo --
con-
of
awaits
ACKNOWLEDGEMENTS Supported by United States HD07923-06 and Rockefeller SYSTEMIC
EQUIVALENTS
androstenedione corticosterone cortisol danazol dehydroepiandrosterone deoxycorticosterone 11-deoxycortisol 16a-hydroxyprogesterone 17-hydroxyprogesterone pregnenolone progesterone
Public Health Service Grant Foundation Grant RF77045.
OF TRIVIAL
NAMES
AND ABBREVIATIONS
4-androstene-X,17-dione llS,Zl-dihydroxypregn-4ene-3,20-dione llfi,l7,21-trihydroxypregn4-ene-3,20-dione 17B-pregn-4-en-20-yno(2.3-d)isoxazol-17-01 ?B-hvdroxv-5-androsten-1'78-one Zl-hydroxypregn-4-ene-3, 20-dione 17,21-dihydroxypregn-4-ene3,20-dione 16a-hydroxypregn-4-ene-3, 20-dione 17-hydroxypregn-4-ene-3, 20-dione 3$-h@ro~-+preffnen-2O-one pregn-4-ene-3,20-dione
262
KS KI
S Apparent Apparent
T13EOIJ3_
spectral dissociation constant enzymatic inhibition constant
REFERENCES
1.
2. 3. 4. 5. 6. 7. 8. 9. 10.
11.
12.
13. 14.
15. 16. 17.
18. 19.
20.
Dmowski, W.P. and Cohen, M.R., OBSTET. GYNEC. 46, 147 (1975). Lauersen, N.H., Wilson, K.H. and Birnbaum, S., AMER. J. OBSTET. GYNEC. 123, 742 (1975). Lauersen, N.H., Wilson, K.H. and Birnbaum, S., FERTIL. STERIL. 26,193 (1975). Lauersen, N.H., and Wilson, K.H., OBSTET. GYNEC. @,93 (1976). Asch, R.H. and Greenblatt, R.B., AMER. J. OBSTET. GYNEC. 127,130 (1977). Lee, P.x Thompson, R.G., Migeon, C.J., and Blizzard, R.M., JOHNS HOPKINS MED. J. 137,265 (1975). Greenblatt, R.B., Dmowski, W.P., Mahesh, V., and Scholler, H.F.L., FERTIL. STERIL. 22,102 (1971). Gelfand, J.A., Sherins, R.J., Alling, D.W., and Frank, M.M., N. ENGL. J. MED. 295,1444 (1976). Sherins, R.J., Gandy, Hz, Thorslund, T.W., and Paulsen, C.A., J. CLIN. ENDOCRINOL. METAB. 35,522 (1971). Wood, G.P., Wu, C.H., Flickenger, G.H., and Mikhail, G ., OBSTET. GYNECOL. 45,302 (1975). Barbieri, R.L., Canick, J.A., and Ryan, K.J., ENDOCRINOLOGY 101,1676 (1977). Barbieri, R.L.,anick, J.A., Makris, A., Todd, R.B., Davies, I.J., and Ryan, K.J., FERTIL. STERIL. 28,809 (1977). Lowry, O.H., Rosebrough, N.J., Farr, A.L., and Randall, R.J., J. BIOL. CHEM. 193,265 (1951). Estabrook, R.W., Peterson, J., Baron, J., and Hildebrandt, A., in Chignell, C.F., (ed) METHODS IN PHARMACOLOGY, 2,203 (1972). Hanes, C.S., BIOCHEM. J. =,1406 (1932). H. and Burk, D., J. AM. CHEM. SOC. Lineweaver, 56,658 (1934). Bird, C.E., Wigvist, N., Diczfalusy, E., and Soloman, S., J. CLIN. ENDOCRIN. METAB. 26,1144 (1966). Villee, D.B., Engel, L.L., Lorring, J.M., and 69,354 (1961). Villee, C.A., ENDOCRINOLOGY Yoshida, N., Sekiba, K., Shibusawa, A., Sano, Y., Yanaihara, T., Okinaga, S., and Arai, K., ENDOCRINOL. JAPON 25,191 (1978). Zachariah, P.K., and Juchau, M.R., LIFE SCI. l6,55 (1974).
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26. 27.
Cheng, S.C., Suzuki, K., Wolfgang, S., Harding, B.W., ENDOCRINOLOGY =,1097 (1976). Estabrook, R.W., Cooper, D.Y., and Rosenthal, O., BIOCHEM. Z. 338,741 (1963). Cooper, D-Y., Schleyer, H. and Rosenthal, O., HOPPESEYLER's Z. PHYSIOL. CHEM. =,1592 (1962). Williams, T.A., Edelson, .I., and Ross, R-W,, STEROIDS 31,205 (1978). Summary of basis for FDA approval of danazof, Food and Drug Administration, Dept. HEW, Rockville, MD, 1976. Wentz, A.C., Jones, G.S., Andrews, M.C. and King, T.M., FERTIL. STERIL. %,1113 (1975). Stillman, R.T., Fencl, M., Schiff, I., Barbieri, R.L., and Tulchinsky, D., FERTIL. STERIL. (in press).
2531 DANAZOL INHIBITS HUMAN 118-HYDROXYLATION Robert
ADRENAL Pl-AND IN VITRO --
L. Barbieri, Rapin Osathanondh, Jacob A. Canick, Robert J. Stillman+, and Kenneth J. Ryan
Laboratory of Human Reproduction and Reproductive Biology and Department of Obstetrics and Gynecology Boston Hospital for Women Harvard Medical School 02115 Boston, Massachusetts and +Division of Reproductive Endocrinology Department of Obstetrics and Gynecology The George Washington University School of Medicine Washington, DC 20037 Received 7-30-79 ABSTRACT The effects of danazol on steroidogenesis in vitro in the 16-20 week old human fetal adrenal were examinedy studying: danazol binding to adrenal microsomal and mitochondrial1) cytochrome P-450, and 2) enzyme kinetics of danazol inhibition of the adrenal microsomal 21-hydroxylase and the The addition of danazol to mitochondrial 118-hydroxylase. preparations of adrenal microsomes or mitochondria elicited Danazol bound a type I cytochrome P-450 binding spectrum. to microsomal cytochrome P-450 with a high affinity apparent spectral dissociation constant (KS) of 1 nM and with a Danazol bound to mitochondrial lower affinity K'S of 10 PM. cytochrome P-450 with a KS of 5 uM. In addition, danazol competitively inhibited the microsomal 21-hydroxylase (apparent enzymatic inhibition constant KI = 0.8 ~.IM)and the These findings mitochondrial 118-hydroxylase (KI = 3 PM). demonstrate that low concentrations of danazol directly inhibit steroidogenesis in the human fetal adrenal -~ in vitro. INTRODUCTION Danazol
is being
used
endometriosis
(l-3),
chronic
cious
(6,7) and congenital
puberty
Although
the mechanisms
peutic
effects
stated
that danazol
minimal
androgenic
studies
in men
clinically cystic
by which
are poorly
danazol
S
TDROIDII
exerts
edema
antigonadotropin
women
However,
(8).
its thera-
it has been
(.l-5,7,8).
of
(3-5), preco-
angioneurotic
is a selective
(9), premenopausal
VoZwne 35, Number 3
mastitis
understood,
effects
in the management
repeatedly with
clinical
(10) and children
(6)
March, 1980
252
have
shown
gonadal
that danazol
steroids
LH or FSH.
without
These
can significantly significantly
observations
suggest
one of its primary
pharmacologic
inhibiting
steroidogenesis.
ported
gonadal
that danazol
of rat adrenal observations on human
competitively
and testicular
prompted
adrenal
suppress
serum
suppressing
serum
that danazol
effects
by directly
We have inhibits
recently
multiple
steroidogenesis
us to examine
exerts
enzymes
(11,lZ).
the effects
re-
These
of danazol
steroidogenesis. MATERIALS
AND METHODS
Adrenals were obtained from 16-20 week old human fetuses legally aborted with prostaglandin F2u. Unlabelled 17-hydroxyprogesterone, deoxycorticosterone and corticosterone urchased from Steraloids and recrystallized were before use. [1,2- t; HI-17-hydroxyprogesterone (SA = 40.4 Ci/mmol) and [1,2-3H]-deoxycorticosterone (SA = 46.8 Ci/mmol) were purchased from New England Nuclear and purified by thin layer chromatography using a solvent system of ehloroform:methanol Danazol was supplied by the Sterling-Winthrop c97:3 v/v). Research Institute. Preparation of mitochondrial an.d microsomal suspensions: Adrenals were homogenized in three parts 0.25 M sucrose The 750g supercontaining 0.01 M Tris-HGL, pH 7.2 at 25O. This pellet natant was centrifuged at 12,000g for 10 min. was resuspended in 0.15 M KCL containing 0.01 M 'Iris, and centrifuged at 12,OOOg for 10 min. The final pellet was homogenized in a small volume of KCL-Tris, sonicated and used The 12,000g supernatant as the mitochondrial suspension. This pellet was was centrifuged at 100,OOOg for 60 min. resuspended in 0.15 M KCL containing 0.01 M Tris and recentrifuged at 100,OOOg for 60 min. The final pellet was Protein concenhomogenized in a small volume of KCL-Tris. tration was determined by the method of Lowry -et al. (13) with bovine serum albumin as the standard, All spectral determinations Spectral determinations: were made usins a DW-2 UV-visible spectronhometer (American Instrument Co.; Silver Spring, MD).- Cytochrome P-450 concentrations were measured by the method of Estabrook et al. (14). To determine the spectral changes caused by the addition of steroids to microsomal or mitochondrial preparation, 6 ml of a 1 mg protein/ml microsomal or mitothondrial suspension was divided between sample and reference cuvettes, and a base-
line drawn. The steroid sample, dissolved in propylene glyThe spectrum co1 alone was added to the reference cuvette. The propylene glycol concenfrom 370 to 500 urn was scanned. Hanes tration in the cuvettes never exceeded 1.0% (v/v). plots were prepared as previously described (15). The assay Inhibition of enzymes of steroidogenesis: for the 21-hydroxylase and the llg-hydroxylase utilized a reaction mixture containing 0.15 M KCL, 50 mM Tris, pH 7.4 at 37O, 500 F\M NADPH, 50 mM glucose-6-phosphate, 5 units of glucose-6-phosphate dehydrogenase, 5 mM MgC12, 0.5 PCi of radiolabelled substrate and appropriate amounts of unlabelled substrate and danazol in a final volume of 0.3 ml. The reaction was started by the addition of 0.1 ml of microsomal or mitochondrial protein. Lineweaver-Burk plots were prepared as previously discribed (16). For the 21-hydroxylase assay the substrate was 17hydroxyprogesterone and the product was ll-deoxycortisol. Progesterone was not chosen as the substrate for the 21hydroxylase assay because mid-trimester human fetal adrenal microsomes can efficiently convert progesterone to deoxycorticosterone, 17-hydroxyprogesterone and 16cchydroxyprogesterone (17,18). In contrast, mid-trimester human fetal adrenal microsomes can only efficiently convert 17-hydroxyprogesterone to 11-deoxycortisol (19). For the 118-hydroxylase assay the substrate was deoxycorticosterone and the product was corticosterone. Samples in the il-hydroxylase assay were incubated for 3 and 6 minutes. For the 118-hydroxylase assay, samples were incubated for 6 and 12 minutes. After incubation, the reaction was stopped by the addition of 0.4 ml methanol. An aliquot of the reaction mixture was then applied to silica gel thin layer plates and the product and the substrate were separated using a solvent system of chloroform:methanol 97:3 v/v (17hydroxyprogesterone rf = 0.66; and corticosterone rf = 0.25). The product was scraped from the plate, eluted from the gel and the radioactivity measured by liquid scintillation spectrometry. The purity of the products of the two reactions was established by recrystallization of representative samples to constant specific radioactivity. In no case was the purity of the product isolated by initial chromatopraphy less than 90%. RESULTS Danazol P-450
interaction
concentrations
chondria
prepared
adrenals
ranged
with
obtained
cytochrome
from microsomes
from four pairs
from
0.50
P-450:
of pooled
to 0.60 nmoles/mg
Cytochrome
and mitohuman
fetal
protein
for the
microsomes
and 0.45
to 0.50 nmoles/mg
protein
for the mito-
chondria. Addition in a type
of danazol
I difference
to microsomal
spectrum
with
380 and 390 nm and a Soret minimum the titration
of a microsomal
demonstrated
a high
affinity
constant
(K'S) of 10 PM
difference minimum
spectrum
at 420 nm.
suspension
with
To a microsomal in the sample achieve This
(Pig. 1).
to microsomal with
suspension cuvette,
of 17-hydrox-
elicited
already
a type
I
at 388 and Soret
of the titration
J.7-hydroxyprogesterone
dissociation
dissociation
Addition
a Soret maximum
of
danazol
spectral
affinity
between
Analysis
with
preparations
Analysis
of a microsomal
yielded
containing
17-hydroxyprogesterone
a concentration
resulted
at 418 nm.
apparent
(KS) of 1 uM and a lower
resulted
a Soret maximum
suspension
Constant
yprogesterone
preparations
a KS of 0.8 PM. 100 pH danazol was
added
to
of 35 PM 17-hydroxyprogesterone,
in a 50% increase
in the type
I difference
spectrum. Addition gave
a type
between
I difference
to mitochondrial spectrum
with
suspensions
a Soret maximum
380 and 390 nm and a Soret minimum
Analysis with
of danazol
of the titration
danazol
corticosterone producing
demonstrated bound
of a mitochondrial
suspension
a KS of 5 I.IM(Pig. 21.
to mitocbondrial
a type, I difference
respectively.
at 419 nm.
spectrum
cytochrome
DeoxyP-450
at 390 nm and 420 nm
The KS of deoxycorticosterone
binding
to
mitochondrial drial
suspension
sample added
cytochrome
cuvette, to aehleve
already
I difference
was
containing
corticosterone
This
0.75 p&f.
To a mitochon-
3.5 pM danazol
in the
or deoxycorticosterone
a concentration
or deoxycorticosterone. type
P-450
were
of 30 ~119cortieosrerone
resulted
in no change
In the
spectrum.
Figure 1. Danazol binding to human adrenal microsomal. cytochrome P-450. Concentrations of danazol: 11 0.33 pi%, 2) 1.00 pM, 4) 3.00 pM, 5) 4.33 PM, 6) 7.00 PM, 7) 20.33 p%, 8) 17.0 j.tM,9) 23.67 YEI, 10) 37 yM, and 11) 63.67 PM. Inset: Hanes plot of danazol bjlnding to micxosomal cytochxome P-45#. % = 3. y&2, K'S fz 10 pM.
S
256
I ,
TDEIBOXDB
6 I
380
I
400
420
I
440
Wavelength
1
I
460
480
500
(nm)
Figure 2. Danazol binding to human adrenal mitochsndrial Concentrations of danazol: cytochrome P-450. 1) 1.6 NJ, 2) 4.27 I.IM,3) 10.93 PM, 4) 17.6 pM, 5) 3Q.93 JAM. Inset: Hanes plot of danazol binding to mitochondrial cytochrome P-450 Kg = 5 I.IM. Enzyme
the 21-hydroxylase The apparent danazol
!JM.
was
minute
constant
(Fig. 3,4). (KT) for
was 0.8 PM. (KM) of 17-
in the Zl-hydroxylase inhibition
inhihited
assay was
assay was
incubations
2.8 PM.
4
of the 118-hydrox-
The KM for deoxycorticosterone
3 PM.
ll$-hydroxylase
constant
of the 21-hydroxylase
The KT for danazol
ylase
inhibition
Michaelis-Menton
hydroxyprogesterone
competitively
and the llfi-hydroxylase
enzymatic
inhibition
The apparent
Danazol
inhibition:
The three
for the 21-hydroxylase
in the and six
assay
gave
S similar
reaction
incubations reaction product
257
The six and twelve
velocities.
for the lib-hydroxylase
velocities. formation
The values concentration,
These
over
assay
results
similar
to values fetal
P-450
which
reported
obtained
have been Cytochrome
(20).
binding
in these reported P-450
C-23). When
added
enzymatic
inhibition
enzymatic Addition suspension
suggests
of deoxycorticosterone already
saturated
spectrum.
competitively
llg-hydroxylase
with
(KT = 3 pM)
dissociation
adrenal
(21).
of adrenal
1 difference
that danazol. binds
site of the human
adrenal
(22) and the lib-
constant
spectral
to values
as the terminal
that danazol
mitochondrial
s.lmilar to the apparent (4s = 5 pM)
a type
P-450
to cortico-
to a preparation
and the observation
apparent
elicits
adult
implicated
This
the adrenal
mitochondrial.
for the human
for
the Kg for
are similar
21-hydroxylase
are
reported
conversion
experiments
danazof
inhibits
been
to adrenal
mitochondria finding
P-450
in this paper
In addition,
has been
of the adrenal
hydroxylaae
cytochrome
previously
and the KM for deoxycorticosterone
oxidase
of
studied.
microsomal
have
adrenal
deoxycorticosterone
which
linearity
and the KS for 17-hydroxyprogesterone
to microsomal
sterone
minute
had similar
indicate
the time period
for adrenal
binding
the human
TEIROXDS
constant
to the active
lie-hydroxylase.
to a mitochondrial with
danazol
did not
change
an
the size
of the type I difference
it can be inferred chondrial
spectrum.
that danazol
cytochrome
P-450
can bind
sites
Therefore,
to all the mito-
available
to deoxycor-
ticosterone. Human eytochrome
fetal
adrenal
P-450
involved
roid hydroxylations: ylase,
micrasomes
in at least
adrenal
microsomes
difference
complicates
spectra
elicited
microsomaf F3
P-450
= 1 PM, RrS = 10 PM)
the active
The results
@omen been
reported
never
to have Adrenal
(24).
the adrenal
than the serum suggest daily,
that
adrenal
here
adrenal
serum
concentration
in women
the adrenal
to the enzymatic
orally
However,
taking
the
to adrenal
I spectrum bfnds
that
to
danazol
is
in vitro. --
per day have
concentrations
as high
of danasol. have
However,
in humans.
of
21-hydroxylase.
steroidogenesfs
concentrations
concentration
a type
indicate
danazol
fetal
inhibits
that danazol
400 mg of danazof
been measured
animals
eliciting
suggests
presented
of human
receiving
as 2 PM
the interpretation
competitively
site of the human
sn inh%bitor
in human
fK, = 0.8 $IM) and that it binds
cytochrome
(17,X8).
in these microsomes,
the ob.servation that danazol 2X-hydroxylase
P-450
ste-
the Pl-hydrox-
and the 17,20-lyase
of the cytochrome
of
four different
the Z7a-hydroxylase,
the Iba-hydroxylase,
The heterogeneity
species
contain
in laboratory
of danasol. is higher
(25).
These
observations
400 mg or more
concentration
of the drug
KT 's for danazol
inhibition
of danasol is similar of the adre-
nal 21-hydroxylase data
suggest
that
and Ll@-hydroxylase. danazol
sis few investigators steroidogenesis et al.
increase
metyrapone synthetic
have
that
in women
in urinary
stimulation
1
adrenal
receiving
examined
adrenal
danazol.
receiving
response
was within
these
steroidogene-
Went2
danazol
17-hydroxycorticoids
and the incremental ACTH
alter
carefully
in patients
(26) reported
percent
may
Although
after
of cortisol
normal
the
to
limits.
2bHYDROXYLASE
i I/(i7+iydroxyprogesteronef fpM_‘)
plots of danazol inhibition of Figure 3. Lineweaver-Burk Zl-hydroxylase substrate: 17-hydroxyprogesterone, product: ll-deoxycortisol) protein concentration 12.5 ug/ml. Danazol concentrations: O-O,+1 pM,A-2 nM,A-5 JIM. Enzymatic inhibition constant = 0.8 nM. These
studies
present
suggest
in women
that no g1ucocoricoS.d
receiving
danazol.
deficiency
However,
is
s.tudies b*y
Stillman itative et
al.
et
(27)
of
after
the
studied once
on as
Danazol
ficant
change
sulted
in
effect
the
of
danazol
before Five
6th
of
day
and
and
of
danazol
increase
control
orally
menagain per
in no
progesterone,
androstenedione
con-
cosyntro-
and
concentration, in
serum
consecutive
mg
qual-
menstruating
resulted
cortisol
the
after
two
600
the
Stillman
on
normally
administration
a significant
alters
synthesis.
a pre-treatment
in baseline
droepiandrosterone
danazol
steroid
steroids
administration
6 days.
that
stimulation.
cycles; the
adrenal
of various
were
strual
suggest
measured
(AcTH~_~~~)
women
for
(27)
pattern
centration pin
al.
day
signibut
re-
dehy-
concentrations.
li/3-HYDROXYLASE
I
2
I/(Desoxycorticosterone)
(PM)-’
Figure 4. Lineweaver-Burk plot of danazol inhibition of llf3-hydroxylase (substrate: deoxycorticosterone, product: corticosterone) protein concentration 625 pg/ml. Danazol concentrations: @-0,&-l uM,m-5 uM. Enzymatic inhibition constant = 3 @I. The
administration
of
cosyntropin
during
the
danazol
treat-
ment
period
resulted
in greater
and deoxycortisol
and smaller
and cortisol
that seen
findings
than
suggest
ylase
sufficient
to assess
hydroxylase.
centration,
the effects danazol
does not
but may
adrenal
steroids.
danazol
on human
further
study.
produces
obtained
In summary
800 mg per day)
in progesterone
alter
alter
adrenal
These
inhibition
and the 118-hydrox-
in the study were of danazol
baseline
serum
(600cortisol
concentration
elucidation
steroidogenesis
not
on the 21-
administration
the serum
Complete
period.
a partial
oxidoreductase
The data
in vivo. --
increments
in pregnenolone
in the control
that danazol
of the 3S-hydroxysteroid
increments
of other
of the effects in vivo --
con-
of
awaits
ACKNOWLEDGEMENTS Supported by United States HD07923-06 and Rockefeller SYSTEMIC
EQUIVALENTS
androstenedione corticosterone cortisol danazol dehydroepiandrosterone deoxycorticosterone 11-deoxycortisol 16a-hydroxyprogesterone 17-hydroxyprogesterone pregnenolone progesterone
Public Health Service Grant Foundation Grant RF77045.
OF TRIVIAL
NAMES
AND ABBREVIATIONS
4-androstene-X,17-dione llS,Zl-dihydroxypregn-4ene-3,20-dione llfi,l7,21-trihydroxypregn4-ene-3,20-dione 17B-pregn-4-en-20-yno(2.3-d)isoxazol-17-01 ?B-hvdroxv-5-androsten-1'78-one Zl-hydroxypregn-4-ene-3, 20-dione 17,21-dihydroxypregn-4-ene3,20-dione 16a-hydroxypregn-4-ene-3, 20-dione 17-hydroxypregn-4-ene-3, 20-dione 3$-h@ro~-+preffnen-2O-one pregn-4-ene-3,20-dione
262
KS KI
S Apparent Apparent
T13EOIJ3_
spectral dissociation constant enzymatic inhibition constant
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