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Effect of 17β-estradiol and testosterone on guanosine 3′, 5′-cyclic monophosphate in the rat adrenal cortex
Vol. 100, No. 4,1981
BIOCHEMICAL
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RESEARCH
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Pages 1727-1734
June 30, 1981
EZ?PECIOF 17B-ESTRADIOLANDTES'IOSTERD~ON 1<
GrJAN3SDJE
3’,
MONOPHOSPHATF IN THE
5’-CYCLJC
RAT FUXENALCOl-tI'EX Josette GUIILEWNI'~
Serge CXTILLENU'T
Faculte de Midecine Pitie-Salp&riere 75634
Received
April
PARIS
CEDEX
13
- FRANCE
1981
21,
The levels of guanosine 3', 5'-cyclic monophosphate (CGMP)were measured in the rat adrenal cortex after administration of a single dose of either 176-estradiol or testosterone. Young immature rats received 10 ug 17B-e&radio1 (females) or 100 ug testosterone (males). After testosterone administration, cCW levels progressively rose to about 150 per cent of the control values after 4-6 hrs, and remained elevated until at least 9 hr. Administration of 176-e&radio1 resulted in a similar increase in cZ%?, which began at 2 hr and persisted until 9 hr, reaching levels of about 180 per cent of the controls. Our data are further evidence of general effect of steroid horrmnes on &%? in their target tissues.
There is nm increasing evidence that hormonal steroids affect c%lP levels in their
respective
target
tissues. At first,
were shown to be able to induce a transitory
estrogens
rise in cCM? in the
rat uterus (1) as well as in the chicken oviduct
(2). Then, two other
steroid hormnes were found to orcduce a similar
effect
target
tissues : 1,25-dihydroxyvitamin
(3), and dexamethasone, a synthetic adrenal cortex
the steroid-induced
parallelled
D3 in the chick intestinal glucocorticosteroid,
mucosa
in the rat
(4). The mechanismof the &@ response to estrogens in
the uterus has been the mst
nuclear receptor
in tm distinct
thoroughly
studied.
increase in cc'rlp level
It has been shown that
is dependent on the cytosol-
system since (a) the time course of changes in c<;Mplevels
that of the steroid nuclear occupancy, and (b) the effect
on
0006-291X/81/121727-08$01.00/0 1727
Copyrighr E 1981 b-v A twdemic Press, Inc. AN rrghrs of reproduction in an-v form reserved.
Vol. 100, No. 4,19Bl
&NPlevelswas tested
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AND
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RESEARCH
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propxtionaltotheestrogenicpotencyofeach
(5). Moreover, the parallelism
knmn estrogenic effects
between the @
such as water Mition
ampound response and other
of the uterus suggest a
hormonal action. Since the existence of receptors for andmgens (6, 7) and for estrogens (8) hadbeendemxstrated toverifywhetherbothkinds increase in adrenccortical
in the ratadrenalgland,wedecided
of steroidhomneswere
able to induce an
c.QQ levels as we had previously
with dexamethasone in the sametissue
shown to occm
(4).
MATERIALsANDME!rHoDs Inmature Wistar rats weighing 55 g (104 males and 120 females) ore supplied by IFFA CREDO,Saint-C&main-sur-l'A.rbresle, France. They were housed in the laboratory for 3 days before being used. Meanwhile, they were fed dry rat pellets (UAR, Villeaoisson, France) and tap water ad libitum and kept at their adrenals quickly removed 20 + 2' C. They were killed by decapitation, and the fasciculata-reticularis zones isolated as previously described (4). Female rat uterine hornswere collected, freed frcm fatandkept on dry ice until lyotiilisation. The lyophylized tissues were homogenized by sonication and the cyclic nucleotides measured by a radioimmunological method (9, 10). Protein was detemined by the mthod of Imry et al. (11) with E%SA as standard. Homeadministration : Testostemne andl7B-estradiolwere dissolved in absolute ethanol and adninistered by im injection in the thigh (50 M/rat). Controlanirnalswere injectedwithethauolonlyandkilledatthe sane time as the corresponding home-injected groups. RESULTS Effect
of testcetercme Twodistinct
experimentswere
presented in Table 1. In the first
carriedout,
the results ofwhich
(short-tern)
experiment, oZ%' and cAW
were measmed before and 2, 4 and 6 hrs after (100 pg/rat).
A significant
administration
(P < 0.05 and P < 0.01) rise in cc;Mpwas observed
at 4 and 6 hrs, shming that testosterone A
testosterone
are
action lasted for a longer time.
second, long-term experiment was designed to account for the circadian
variations
incyclicn~leotidelevelswhichhavebeen~trated
rat adrenal cortex
(12). cCNPand cAMPwere measured at different
1728
inthe times after
Vol. 100, No. 4,198l
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TABLE1 : CYCLIC NXLEIXILlELEVELSINTHE ADRBGGCORTEXOFYouNGIMWlVREM?GEPATS. EFF'EYXOFTES~ ADlINI~TICN EXP-1
Tim after 'injection
n
CxaP CAMP % ofunt.reatedcontrols mean -+ SE-I IEarl -+ SEM
hOWS
Untreated controls Testosterone
2 4 6
6
loo+10
loO+
6 6 6
103 + 10 141 T lsa 190 T- 24b
loo+11 loo + 17 95 z 5
ExPERIMTSr2
CXWP
8
CAMP
%of vehicle-injected oxkrols lTlxin+sm mean-+ SEX Testosterone
2 4 6 9 24
8 8 8 8 8
111 117 149 149 113
+ T T T +
11 13 lib 12b 10
92 124 132 62 88
+ 7 + T -T
11 16 9 gb 10
Testosterone (100 ug/rat) in 50 1.1ethanol was injected intra-muscularly et zero t&x. Experiment
1. &mrone-treated
(Student's t-test).
animals
were ampared
with
untreated
controls
E5qerimnt 2.At each tims point, each hormne-injected group was cxqared with a vehicle-injected one (Student"s t-test). a RO.05 b RO.01
the injection
of either
testosterone
or the vehicle
alone. The pattern of
changes in dXP is presented in Figure 1. It shows a progressive rise waking at 6 hr and returning Effect
to ccntrol
levels at 24 hr.
of 17&estradiol The results
of two distinct
Short-term eqerinrmt
experimants are sumarized
1 shows the effect
tissues, the adrmalcortexandthe before and 1, 2, 3 and 4 hrs after
of 17B-estradiol
uterus.
administration.
was different
1729
on two different
c@P andcAMPweremasured
17&estradiol
course of changes in cGlP concentration
in Table 2.
The tims
between the adrenals
BIOCHEMICAL
Vol. 100, No. 4,198l
AND
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2
4
6
9
hours
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Figure 1. T~courseofchangesincCMPintheratadrenalcortexaftertheadministration of a single dose (100 pg/rat) of testosterone to young imnatumrnale rats. Ateach tim-pointkmmne-treated animalsware canparedwith vehicle-injected controls (Student's t-test). Significant increases (P cO.01) were observedat and 9 hr.5 after testos~ aclministration . Eachvaluerepresentsthemean-sEMof8subjects.
andthe uterus. at2
In the uterus the rise in cG4Pwa.s very t.ransient,peaking
hrandretmningtobasallevels
at4
hr,whereas
persisted up to 4 hr. Experiment 2 was therefore tern effects
of 17B-estradiol
on adrenocortical
in the adrenals it
designed to test the longc%BP. As explained above
(Table 1, experiment 2), each hormone-injected group was roved vehicle-injected variations
with a
one at the samehours in order to account for the circadian
and the effects
of the vehicle,
if any. The tima comse of changes
in cQ4P is presented in Figure 2. As it could be expected from the results of experimant 1, the effects
of 178-estradiol
on c@lP were more prolonged in the
adrenals than in the uterus.
DISCUSSION The pssibility effects
nucleotides
to mediate part or all of the
of steroid honmnes was hypothesized scme years ago and &VP was
the first brief
for cyclic
to be investigated.
rise in uterine
After
administration
CAMPwas described, similar
1730
of estrogens, an early to that observed in other
8lOCHEMlCAL
Vol. 100, No. 4,198l
TASLF2
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
: CYCLIC NKLKYTJDELEVFLSINTHEADRDlALCDRTEX ANDTHEUl'EFUJSOFYCUNGlMATUPE
FTimTAE RATS.
EFFECT OF 17B-ESTVADIOL ADXINISTRATI@l EXPE~PIMDJT 1
Adrenal
Tine after injection hours
n
c??e CM@ %ofuntreatedomtrols m3Il+sl31 Iwan + SE31
cortex
8
Untreated controls
100 + 9
Estradiol
83 132 145 189
+ i 5 -
9 3d 17b 22c
75 109 81 100
+ 7 : ;
8 9 5 9
uterus Untreated controls
8
100 + 10
Estradiol
83 170 123 98
EXPEPJl?ENT2
4 6 9 24
17Bestradiol
(10 pg/rat)
8 8 8 8
tissues
1. Hormne-treated t-test).
animals
was injected
ware cmpared
+ T 7 -
gc 6d lSc 10
124 119 82 106
intra-muscularly with
untreated
+ + 7 7
14 23 6 10
at zero tine. controls
each hormone-treated grow was ccqxred with t-test). The 2 hr tima Fint (see figure 2) vehicle-injected was available for -ison.
P
under
the
influence
experiments
shmed
to suppress
the estrogen-induced
cal
136 171 178 112
in 50 pl ethanol
Experiamt 2. At each time pint, a vehicle-injected one (Student's was anitted since no corresponding a b c d
21 23a 19 12
CQ-fP CAMP % of vehicle-injected controls aWl+SEX Il-E?Xl+tTEV
Estradiol
Experiment (Student's
+ + -f +
responses
(14,
that
15).
of peptide
propanolol,
Nevertheless,
homnes a B-adrenergic
CAMD respmse scma other
1731
(13).
Hmever,
blocking without
altering
mdifications
subsequent agent,
was able
other in the
physiologi@$W level
Vol. 100, No. 4,15%1
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Estrsdiol
0
Vehicle
.*
I 246
9
houra
24
F@LIE 2. Tlme~seofchangesincGMPintheratadrenalcortexaftertheadministration of a single dose (10 pg/rat) of 178-estradiol to young im mture fenalerats. Ateachtim-pointbxnme -trea~animalS~ m with vehicle-injected controls (Student's t-test). Significant increases vere observed at 4 hr (PC0.011, at 6 hr (P
have been described. A modest but significant
decrease was shcxm to occur in the
uterus between 2 and12 hrs afterestradioladministration hasbeenshcxm tooccurwithdexmethasone decreasewas neither
adrenals (4). Hmever, that
found in the chick intestinalmucosa
of 1 cx, 25-dihydxoxycholecalciferol generalized.
inthe
(1) : the samething
after
administration
(3) nor in the present work, and cannot be
Ontheotherhand,administrationofestrogen
to immtureor
ovariectcenized female rats hasbeen found to increase cQlp concentrations the uterus (1). That&@
responsewas characterizedbya
delayed (about1 hr)
progressive and prolonged rise.
Lateron,
response on the cytosol-nuclear
receptor system was established
other tissues inwhicha&NP
the dependency of the uterine cQIP
response tosteroidhomes
are kncxm to contain the corresponding hormone receptors of the uterine cG@ response have been shcmn to follm involved
in the transfer
in
of the cytosol-receptor
1732
has beendemmstrat~~3 (16, 17). The kinetics by about an hour those
amplex to the nucleus and
then to persist roughly as long as the steroid-receptor In the present study the estradiol-induced
(5), and all
nuclear occupancy (5).
cXXP rise was mre prolonged in the
Vol. 100. No. 4,1981
BIOCHEMICAL
AND
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RESEARCH
adrenals than in the uterus. That phenamnon might therefore reflecting
be interpreted
a longer steroid nuclear cxxupancy. In addition,
obsemedafter
testosterone
intracellular
administration
nkatabolization
elucidated.
Recent findings
in the transitory
shming a direct
by steroids favor the first
and ventral
the consequenceofits
accumulation of &ZJP, either
prostate
hypothesis. Z-to 5-fold
activation
the stimulation
in rat liver,
of guanylate cyclase oxurred
(19). It
within
trating
that testosterone
adrenal function,
That discrepancy was determined in the thus
mechanisms.
series, one could expect dexamthasone, estradiol adrenal effects.
should be noted that
ha-rcgenization of the tissue,
If we consider the cSW respmse as the first
similar
muscle
on helxatic and uterine
steroid adninistration.
37,000 X g supernatant obtained after
skeletal
15 rain, whereas -in vivo
may be explained by the fact that the enzymatic activity
bypassing cmplex intracellular
of guanylate cyclase
kidney,
(18). E&radio1 had the sameeffect
&NP did not rise before 1 hr after
remains to be
Testosterone was found to enhance
guanylate cylase of female rats and guinea-pigs
biochemical event in a
and testosterone
to induce
Although many experimants have been performed demnsand estradiol
they have failed
confusing results are not surprising where these steroids are knm
and dexamethasone were able to influence
to give uneguivocal results
(20). These
with regard to the extra-adrenal
sites
to act.
The discovery of an adrenal cGQ response after and e&radio1
the delayed response
of synthesis or by suppression of degradation,
guanylate cyclase activity
as
into dihydrotestosterone.
The mechanisminvolved by stimulation
couldbe
COMMUNICATIONS
administration
of testosterone
should suggest a new approach to the role of that cyclic
tide in the adrenal and is new evidence that the alterations may be considered as a general cellular
in cc;Mp levels
response to steroid hormones.
1733
nucleo-
Vol. 100, No. 4,198l
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1. Kuehl, F.A., Jr., Ham, E.A., Zanetti, M.E., Sanford, C.H., Nicol, S.E., and Goldberg, N.D. (1974) Proc. Natl. Acad. Sci. U.S.A. 71, 1866-1870. 2. Schumacher, M., Seidel, I., and Strgtling, W.H. (1977) Biochem. Biophys. Rfs. coMnun. 74, 614-620. 3. Guillmant, J., and Guillemnt, S. (1980) Biochem. Bioohys. Res. Ccmmn, 93, 906-911. 4. Guillemnt, J., and Guillemnt, S. (1979) Biochem. Biophys. Res. Ccamun, 88, 163-169. 5. Flandroy, L., and Galand, P. (1979) I%l. Cell. Endccrinol. 13, 281-290. 6. Calandra, R.S., Purvis, K., Naess, O., Attramdal, A., Djoseland, O., and Hanson, V. (1978) J. Steroid Biochem. 9, 1009-1015. 7. Rifka, S.M., Cutler, G.B., Jr., Sauer, M.A., and lmiaux, D.L. (1978) Endocrinology 103, 1103-1110. 8. Cutler, G.B., Jr., Barnes, K.M., Sauer, M.A., and Loriaux, D.L. (1978) Endocrinolcqv, 102, 252-257. 9. Cailla, H-L., Racine-Weisbuch, MS., and Delaage, M.A. -(1973) Anal. Bicchem. 56, 394-407 10. Cailla, H.L., Vannier, C.J., and Delaage, M.A. (1976) Anal. Biochem. 70, 195-202. 11. Lc%rrlr, D.H., Rosebrough, N.J., Farr, A.L., and Randall, R.J. (1951) J. Biol. Chm. 193, 265-275. 12. Guillemnt, J., Reinberg, A. and Guillemnt, S. (1980) Acta Endocrinol. (KM) 95, 382-387. 1.3. szego, C.M., and Davis, J.S. (1967) Pi-cc. Natl. Acad. Sci. USA 58, 17111718. 14. Rosenfeld, MC,., and OWalley, B.M. (1970) Science 168, 253-255 15. Dupont-Mairesse, N., Van Sande, J., Rooryck, J., Fastrez-Boute, A., and Galand, P. (1974) J. Steroid Biochem. 5, 173-178. 16. Tsai, H.C., and Norman, A.W. (1973) J. Biol. Chem. 248, 5967-5975. 17. Loose, D.S., Do, Y.S., Chen, T.L., and Felcbxan, D. (1980) Endocrinology, 137-146. 18. Vesely, D.L. (1979) Proc. Natl. Acad. Sci. USA 76, 3491-3494. 19. Vesely, D.L., and Hill, D.E. (1980) Endocrinology 107, 2104-2109. 20. Kitay, J-1. (1968) in Functions of the Adrenal Cortex, p 775-811, North Holland, Amsterdam.
1734
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RESEARCH
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Pages 1727-1734
June 30, 1981
EZ?PECIOF 17B-ESTRADIOLANDTES'IOSTERD~ON 1<
GrJAN3SDJE
3’,
MONOPHOSPHATF IN THE
5’-CYCLJC
RAT FUXENALCOl-tI'EX Josette GUIILEWNI'~
Serge CXTILLENU'T
Faculte de Midecine Pitie-Salp&riere 75634
Received
April
PARIS
CEDEX
13
- FRANCE
1981
21,
The levels of guanosine 3', 5'-cyclic monophosphate (CGMP)were measured in the rat adrenal cortex after administration of a single dose of either 176-estradiol or testosterone. Young immature rats received 10 ug 17B-e&radio1 (females) or 100 ug testosterone (males). After testosterone administration, cCW levels progressively rose to about 150 per cent of the control values after 4-6 hrs, and remained elevated until at least 9 hr. Administration of 176-e&radio1 resulted in a similar increase in cZ%?, which began at 2 hr and persisted until 9 hr, reaching levels of about 180 per cent of the controls. Our data are further evidence of general effect of steroid horrmnes on &%? in their target tissues.
There is nm increasing evidence that hormonal steroids affect c%lP levels in their
respective
target
tissues. At first,
were shown to be able to induce a transitory
estrogens
rise in cCM? in the
rat uterus (1) as well as in the chicken oviduct
(2). Then, two other
steroid hormnes were found to orcduce a similar
effect
target
tissues : 1,25-dihydroxyvitamin
(3), and dexamethasone, a synthetic adrenal cortex
the steroid-induced
parallelled
D3 in the chick intestinal glucocorticosteroid,
mucosa
in the rat
(4). The mechanismof the &@ response to estrogens in
the uterus has been the mst
nuclear receptor
in tm distinct
thoroughly
studied.
increase in cc'rlp level
It has been shown that
is dependent on the cytosol-
system since (a) the time course of changes in c<;Mplevels
that of the steroid nuclear occupancy, and (b) the effect
on
0006-291X/81/121727-08$01.00/0 1727
Copyrighr E 1981 b-v A twdemic Press, Inc. AN rrghrs of reproduction in an-v form reserved.
Vol. 100, No. 4,19Bl
&NPlevelswas tested
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
propxtionaltotheestrogenicpotencyofeach
(5). Moreover, the parallelism
knmn estrogenic effects
between the @
such as water Mition
ampound response and other
of the uterus suggest a
hormonal action. Since the existence of receptors for andmgens (6, 7) and for estrogens (8) hadbeendemxstrated toverifywhetherbothkinds increase in adrenccortical
in the ratadrenalgland,wedecided
of steroidhomneswere
able to induce an
c.QQ levels as we had previously
with dexamethasone in the sametissue
shown to occm
(4).
MATERIALsANDME!rHoDs Inmature Wistar rats weighing 55 g (104 males and 120 females) ore supplied by IFFA CREDO,Saint-C&main-sur-l'A.rbresle, France. They were housed in the laboratory for 3 days before being used. Meanwhile, they were fed dry rat pellets (UAR, Villeaoisson, France) and tap water ad libitum and kept at their adrenals quickly removed 20 + 2' C. They were killed by decapitation, and the fasciculata-reticularis zones isolated as previously described (4). Female rat uterine hornswere collected, freed frcm fatandkept on dry ice until lyotiilisation. The lyophylized tissues were homogenized by sonication and the cyclic nucleotides measured by a radioimmunological method (9, 10). Protein was detemined by the mthod of Imry et al. (11) with E%SA as standard. Homeadministration : Testostemne andl7B-estradiolwere dissolved in absolute ethanol and adninistered by im injection in the thigh (50 M/rat). Controlanirnalswere injectedwithethauolonlyandkilledatthe sane time as the corresponding home-injected groups. RESULTS Effect
of testcetercme Twodistinct
experimentswere
presented in Table 1. In the first
carriedout,
the results ofwhich
(short-tern)
experiment, oZ%' and cAW
were measmed before and 2, 4 and 6 hrs after (100 pg/rat).
A significant
administration
(P < 0.05 and P < 0.01) rise in cc;Mpwas observed
at 4 and 6 hrs, shming that testosterone A
testosterone
are
action lasted for a longer time.
second, long-term experiment was designed to account for the circadian
variations
incyclicn~leotidelevelswhichhavebeen~trated
rat adrenal cortex
(12). cCNPand cAMPwere measured at different
1728
inthe times after
Vol. 100, No. 4,198l
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH
COMMUNICATIONS
TABLE1 : CYCLIC NXLEIXILlELEVELSINTHE ADRBGGCORTEXOFYouNGIMWlVREM?GEPATS. EFF'EYXOFTES~ ADlINI~TICN EXP-1
Tim after 'injection
n
CxaP CAMP % ofunt.reatedcontrols mean -+ SE-I IEarl -+ SEM
hOWS
Untreated controls Testosterone
2 4 6
6
loo+10
loO+
6 6 6
103 + 10 141 T lsa 190 T- 24b
loo+11 loo + 17 95 z 5
ExPERIMTSr2
CXWP
8
CAMP
%of vehicle-injected oxkrols lTlxin+sm mean-+ SEX Testosterone
2 4 6 9 24
8 8 8 8 8
111 117 149 149 113
+ T T T +
11 13 lib 12b 10
92 124 132 62 88
+ 7 + T -T
11 16 9 gb 10
Testosterone (100 ug/rat) in 50 1.1ethanol was injected intra-muscularly et zero t&x. Experiment
1. &mrone-treated
(Student's t-test).
animals
were ampared
with
untreated
controls
E5qerimnt 2.At each tims point, each hormne-injected group was cxqared with a vehicle-injected one (Student"s t-test). a RO.05 b RO.01
the injection
of either
testosterone
or the vehicle
alone. The pattern of
changes in dXP is presented in Figure 1. It shows a progressive rise waking at 6 hr and returning Effect
to ccntrol
levels at 24 hr.
of 17&estradiol The results
of two distinct
Short-term eqerinrmt
experimants are sumarized
1 shows the effect
tissues, the adrmalcortexandthe before and 1, 2, 3 and 4 hrs after
of 17B-estradiol
uterus.
administration.
was different
1729
on two different
c@P andcAMPweremasured
17&estradiol
course of changes in cGlP concentration
in Table 2.
The tims
between the adrenals
BIOCHEMICAL
Vol. 100, No. 4,198l
AND
BIOPHYSICAL
RESEARCH
COMMUNlCATlONS
.v
2
4
6
9
hours
24
Figure 1. T~courseofchangesincCMPintheratadrenalcortexaftertheadministration of a single dose (100 pg/rat) of testosterone to young imnatumrnale rats. Ateach tim-pointkmmne-treated animalsware canparedwith vehicle-injected controls (Student's t-test). Significant increases (P cO.01) were observedat and 9 hr.5 after testos~ aclministration . Eachvaluerepresentsthemean-sEMof8subjects.
andthe uterus. at2
In the uterus the rise in cG4Pwa.s very t.ransient,peaking
hrandretmningtobasallevels
at4
hr,whereas
persisted up to 4 hr. Experiment 2 was therefore tern effects
of 17B-estradiol
on adrenocortical
in the adrenals it
designed to test the longc%BP. As explained above
(Table 1, experiment 2), each hormone-injected group was roved vehicle-injected variations
with a
one at the samehours in order to account for the circadian
and the effects
of the vehicle,
if any. The tima comse of changes
in cQ4P is presented in Figure 2. As it could be expected from the results of experimant 1, the effects
of 178-estradiol
on c@lP were more prolonged in the
adrenals than in the uterus.
DISCUSSION The pssibility effects
nucleotides
to mediate part or all of the
of steroid honmnes was hypothesized scme years ago and &VP was
the first brief
for cyclic
to be investigated.
rise in uterine
After
administration
CAMPwas described, similar
1730
of estrogens, an early to that observed in other
8lOCHEMlCAL
Vol. 100, No. 4,198l
TASLF2
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
: CYCLIC NKLKYTJDELEVFLSINTHEADRDlALCDRTEX ANDTHEUl'EFUJSOFYCUNGlMATUPE
FTimTAE RATS.
EFFECT OF 17B-ESTVADIOL ADXINISTRATI@l EXPE~PIMDJT 1
Adrenal
Tine after injection hours
n
c??e CM@ %ofuntreatedomtrols m3Il+sl31 Iwan + SE31
cortex
8
Untreated controls
100 + 9
Estradiol
83 132 145 189
+ i 5 -
9 3d 17b 22c
75 109 81 100
+ 7 : ;
8 9 5 9
uterus Untreated controls
8
100 + 10
Estradiol
83 170 123 98
EXPEPJl?ENT2
4 6 9 24
17Bestradiol
(10 pg/rat)
8 8 8 8
tissues
1. Hormne-treated t-test).
animals
was injected
ware cmpared
+ T 7 -
gc 6d lSc 10
124 119 82 106
intra-muscularly with
untreated
+ + 7 7
14 23 6 10
at zero tine. controls
each hormone-treated grow was ccqxred with t-test). The 2 hr tima Fint (see figure 2) vehicle-injected was available for -ison.
P
under
the
influence
experiments
shmed
to suppress
the estrogen-induced
cal
136 171 178 112
in 50 pl ethanol
Experiamt 2. At each time pint, a vehicle-injected one (Student's was anitted since no corresponding a b c d
21 23a 19 12
CQ-fP CAMP % of vehicle-injected controls aWl+SEX Il-E?Xl+tTEV
Estradiol
Experiment (Student's
+ + -f +
responses
(14,
that
15).
of peptide
propanolol,
Nevertheless,
homnes a B-adrenergic
CAMD respmse scma other
1731
(13).
Hmever,
blocking without
altering
mdifications
subsequent agent,
was able
other in the
physiologi@$W level
Vol. 100, No. 4,15%1
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Estrsdiol
0
Vehicle
.*
I 246
9
houra
24
F@LIE 2. Tlme~seofchangesincGMPintheratadrenalcortexaftertheadministration of a single dose (10 pg/rat) of 178-estradiol to young im mture fenalerats. Ateachtim-pointbxnme -trea~animalS~ m with vehicle-injected controls (Student's t-test). Significant increases vere observed at 4 hr (PC0.011, at 6 hr (P
have been described. A modest but significant
decrease was shcxm to occur in the
uterus between 2 and12 hrs afterestradioladministration hasbeenshcxm tooccurwithdexmethasone decreasewas neither
adrenals (4). Hmever, that
found in the chick intestinalmucosa
of 1 cx, 25-dihydxoxycholecalciferol generalized.
inthe
(1) : the samething
after
administration
(3) nor in the present work, and cannot be
Ontheotherhand,administrationofestrogen
to immtureor
ovariectcenized female rats hasbeen found to increase cQlp concentrations the uterus (1). That&@
responsewas characterizedbya
delayed (about1 hr)
progressive and prolonged rise.
Lateron,
response on the cytosol-nuclear
receptor system was established
other tissues inwhicha&NP
the dependency of the uterine cQIP
response tosteroidhomes
are kncxm to contain the corresponding hormone receptors of the uterine cG@ response have been shcmn to follm involved
in the transfer
in
of the cytosol-receptor
1732
has beendemmstrat~~3 (16, 17). The kinetics by about an hour those
amplex to the nucleus and
then to persist roughly as long as the steroid-receptor In the present study the estradiol-induced
(5), and all
nuclear occupancy (5).
cXXP rise was mre prolonged in the
Vol. 100. No. 4,1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
adrenals than in the uterus. That phenamnon might therefore reflecting
be interpreted
a longer steroid nuclear cxxupancy. In addition,
obsemedafter
testosterone
intracellular
administration
nkatabolization
elucidated.
Recent findings
in the transitory
shming a direct
by steroids favor the first
and ventral
the consequenceofits
accumulation of &ZJP, either
prostate
hypothesis. Z-to 5-fold
activation
the stimulation
in rat liver,
of guanylate cyclase oxurred
(19). It
within
trating
that testosterone
adrenal function,
That discrepancy was determined in the thus
mechanisms.
series, one could expect dexamthasone, estradiol adrenal effects.
should be noted that
ha-rcgenization of the tissue,
If we consider the cSW respmse as the first
similar
muscle
on helxatic and uterine
steroid adninistration.
37,000 X g supernatant obtained after
skeletal
15 rain, whereas -in vivo
may be explained by the fact that the enzymatic activity
bypassing cmplex intracellular
of guanylate cyclase
kidney,
(18). E&radio1 had the sameeffect
&NP did not rise before 1 hr after
remains to be
Testosterone was found to enhance
guanylate cylase of female rats and guinea-pigs
biochemical event in a
and testosterone
to induce
Although many experimants have been performed demnsand estradiol
they have failed
confusing results are not surprising where these steroids are knm
and dexamethasone were able to influence
to give uneguivocal results
(20). These
with regard to the extra-adrenal
sites
to act.
The discovery of an adrenal cGQ response after and e&radio1
the delayed response
of synthesis or by suppression of degradation,
guanylate cyclase activity
as
into dihydrotestosterone.
The mechanisminvolved by stimulation
couldbe
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administration
of testosterone
should suggest a new approach to the role of that cyclic
tide in the adrenal and is new evidence that the alterations may be considered as a general cellular
in cc;Mp levels
response to steroid hormones.
1733
nucleo-
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AND BIOPHYSICAL
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1. Kuehl, F.A., Jr., Ham, E.A., Zanetti, M.E., Sanford, C.H., Nicol, S.E., and Goldberg, N.D. (1974) Proc. Natl. Acad. Sci. U.S.A. 71, 1866-1870. 2. Schumacher, M., Seidel, I., and Strgtling, W.H. (1977) Biochem. Biophys. Rfs. coMnun. 74, 614-620. 3. Guillmant, J., and Guillemnt, S. (1980) Biochem. Bioohys. Res. Ccmmn, 93, 906-911. 4. Guillemnt, J., and Guillemnt, S. (1979) Biochem. Biophys. Res. Ccamun, 88, 163-169. 5. Flandroy, L., and Galand, P. (1979) I%l. Cell. Endccrinol. 13, 281-290. 6. Calandra, R.S., Purvis, K., Naess, O., Attramdal, A., Djoseland, O., and Hanson, V. (1978) J. Steroid Biochem. 9, 1009-1015. 7. Rifka, S.M., Cutler, G.B., Jr., Sauer, M.A., and lmiaux, D.L. (1978) Endocrinology 103, 1103-1110. 8. Cutler, G.B., Jr., Barnes, K.M., Sauer, M.A., and Loriaux, D.L. (1978) Endocrinolcqv, 102, 252-257. 9. Cailla, H-L., Racine-Weisbuch, MS., and Delaage, M.A. -(1973) Anal. Bicchem. 56, 394-407 10. Cailla, H.L., Vannier, C.J., and Delaage, M.A. (1976) Anal. Biochem. 70, 195-202. 11. Lc%rrlr, D.H., Rosebrough, N.J., Farr, A.L., and Randall, R.J. (1951) J. Biol. Chm. 193, 265-275. 12. Guillemnt, J., Reinberg, A. and Guillemnt, S. (1980) Acta Endocrinol. (KM) 95, 382-387. 1.3. szego, C.M., and Davis, J.S. (1967) Pi-cc. Natl. Acad. Sci. USA 58, 17111718. 14. Rosenfeld, MC,., and OWalley, B.M. (1970) Science 168, 253-255 15. Dupont-Mairesse, N., Van Sande, J., Rooryck, J., Fastrez-Boute, A., and Galand, P. (1974) J. Steroid Biochem. 5, 173-178. 16. Tsai, H.C., and Norman, A.W. (1973) J. Biol. Chem. 248, 5967-5975. 17. Loose, D.S., Do, Y.S., Chen, T.L., and Felcbxan, D. (1980) Endocrinology, 137-146. 18. Vesely, D.L. (1979) Proc. Natl. Acad. Sci. USA 76, 3491-3494. 19. Vesely, D.L., and Hill, D.E. (1980) Endocrinology 107, 2104-2109. 20. Kitay, J-1. (1968) in Functions of the Adrenal Cortex, p 775-811, North Holland, Amsterdam.
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