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Basic fibroblast growth factor in rat corpus luteum stimulates prostaglandin F2-alpha production
Vol.
178,
No.
July
15,
1991
BIOCHEMICAL
1, 1991
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
393-399
BASIC FIBROBLAST GROWTHFACTOR IN RAT CORPUS LUTEUM STIMULATES PROSTAGLANDIN FZ-ALPHA PRODUCTION Kazuhiro
Tamura:
Rei Asakai,
and Ryohei
Okamoto
Department of Endocrinology, Medical Research Institute, Tokyo Medical and Dental University, 5-45, Yushima I-chome, Bunkyo-ku Tokyo, 113, Japan Received June 1, 1991 SUMMARY: Rat luteal cells (LC) were incubated with or without basic fibroblast growth factor (bFGF) in a serum-free medium. Prostaglandin F2d (PGFzd) production was stimulated in a dosedependent manner at 0.03~ 1 rig/ml of bFGF. One rig/ml of bFGF caused approximately 5-fold the increment of PGF2d at every stage of LC after 48 hrs of incubation. bFGF also raised progesterone secretion from LC, and this stimulatory effect on progesterone was more distinguishable in an early-, than a middleand a latestage. Additionally, bFGF concentration throughout the luteal phase was assessed using western blot analysis. The protein with typical molecular weight 18 kDa form was in high concentration throughout the luteal phase. These results suggest that bFGF may play a role in the regulation of PGFzd and progesterone production B 1991 Academic as autocrine, but not in mitosis in corpus luteum. Press,
Inc.
Recently, growth factors reported to have possibilities and modulate
the
synthesized in the ovary have been to regulate ovarian steroidogenesis
gonadotropin
actions
Basic fibroblast growth factor (bFGF) fied in the pituitary gland and brain, bovine
corpus
luteum
(CL)
(3).
onto
ovarian
function
which was originally was also isolated
Moreover,
the
mRNA encoding
was expressed in both luteal cells (4) and granulosa These facts prompted us to study the biological role luteal
function.
known as one of function
(6,7,8)
as well
as that
In addition, the
important
and it of
prostaglandin factors may
for be
bFGF
cells (5). of bFGF in
F2d (PGF2d ) is well regulation
has been shown that
uterus-derived
(1,2). identifrom
of
PGFld of
involved
in
luteal
luteal
origin
the
*To whomcorrespondence should be addressed. bFGF, basic fibroblast growth factor; The abbreviations used are Fld; PRG, Progesterone; CL, Corpus luteum; PGFz~ , Prostaglandin PMSG, pregnant mare serum gonadotropin; hCG, LC, Luteal cells; human chorionic gonadotropin.
393
0006-291X/91 $1.50 Copyright 0 1991 by Academic Press, inc. All rights of reproduction in any form reserved.
Vol.
178, No. 1, 1991
luteolysis on the
in rats
BtOCHEMtCAL
(9).
Therefore,
PGF2d and progesterone
MATERIALS
AND BtOPHYStCAL RESEARCH COMMUNtCATtONS
we studied
synthesis
the
by luteal
effects cells
of in
bFGF
vitro.
AND METHODS
In order to obtain a well-defined Animals and preparation of CL: generationof CL, immature female rats of the Sprague-Dawley strain (24b32-day-old) were SC injected at 0800 with 8 IU of by an ip injecpregnant mare serum gonadotropin (PMSG), followed tion with 10 IU human chorionic gonadotropin (hCG) at 1700 2 days after PMSG injection (normal ovulation model). Ovulation took place in the morning of the next day after hCG injection (IO) and were observed in all rats. an average of 13 f 3.2 (n=9) oocytes The day of hCG administration was defined as day-0 and the CL isolated from the rat which was observed ovulating was designated as numbering up to a g-day-old CL a l-day-old CL, with consecutive For the experiment of western (9 days after hCG treatment). blotting, higher doses of 50 IU PMSG and 25 IU hCG were used to obtain a sufficient number of luteal cells. However, it is known that no significant differences were found between the two models with regard to the microscopic appearance of LC or the response to various stimuli (11). Luteal offhag tissue saline fetal After cells times
cell
preparation : All CL removed from ovary was cleaned ovarian tissue under a dissecting microscope. The CL was digested in Cazf- and Mgftfree phosphate buffer containing 0.2 % collagenase, 250 ug/ml DNase and 1 % bovine serum in a shaking water bath at 37 *C for 90 min. cell suspension was filtered through a nylon mesh, luteal (LC) were collected by centrifugation and then washed 3 in an incubation medium.
Cell culture and PGFad and progesterone assay: LC was dispersed -inserum-free culture maurn comprised of 1:l mixture of Eagle's minimum essential medium and Ham'F 12 supplemented with 10 mM Hepes, 2 mM L-glutamine and antibiotics (100 U/ml penicillin, 100 ug/ml streptomycin and 625 rig/ml fungizone). Cells were incubated at a density of 5 x IO4 cells/dish in 500 pl medium at 37 'C with or without recombinant bFGF (human; Takeda) or LH (ovine; NIADDKoLH-26) under a water saturated atmosphere of 5 % CO2 and 95 % The amount of PGF,d was determined using RIA kit (Baxter air. Healthcare Corp.). The content of progesterone (PRG) was measured by RIA with specific antiserum (BioMaker, Israel) as described in detail earlier (12,131. The coefficients of the intraand interassay variations in each RIA were smaller than 10 %. Experimental data are presented as the mean f SE and evaluated by analysis of variance with Bartlett's test followed by Student's t-test. A difference of PcO.05 was considered significant. Western blot analysis: CL tissues (200 mg) of each day-old (3,6 and 9) were homogenized with 2 ml of 25 mM tris-HCl buffer (pH 7.45) containing 3 M NaCl, 1 mM phenylmethylsulfonyl fluoride , 4 uM leupeptin and 2 nM pepstatin at 4 "C using a glass homogenizer. After 10 min., the homogenates were diluted to 0.5 M NaCl with 25 mM tris-HCl containing protease inhibitors and centrifuged twice at 14,000 x g for 15 min at 4 OC. Supernatants were loaded onto 50 pl of heparin-sepharose column. The column was washed with 25 mM tris-HCl containing 50 ml of 1 M NaCl and then resin particles were transferred to an Eppendorf tube and boiled for 3 min in SDSPAGE sample buffer. Buffer containing recombinant bFGF was also 394
Vol.
178, No.,l,
1991
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
performed the same procedure with the column. Proteins were electrophoresed on SDS-15 % polyacrylamide gel and were transferred to a polyvinylidene difluoride (PVDF) membrane (Immobilon). The membrane was incubated in 25 mM tris-saline buffer containing 1 % BSA at room temperature with Iodinated [laI]-anti-bFGF monoclonal antibody (5 x 105 cpm/ml, MoAb 98, Takeda) for 5 hr, and then washed and exposed to film (Kodak X-OMAT AR X-ray film) for an autoradiography (-70 'C). RESULTS AND DISCUSSION PGFM production of
bFGF in
under
3-day-old
bFGF stimulated
various
concentrations
LC was measured
(Fig.
1).
(0.03-3
rig/ml)
As shown in fig.
1,
the
PGFZd production between 0.03 and 1 rig/ml of bFGF in a dose-dependent manner. The PGF2d levels significantly increased by treatment with 0.1 rig/ml of bFGF (P
significantly
rig/ml)
8
stimulated
PGFld production
J&!EGd
of
that bFGF by 6 hrs
bFGFllng/mI)
6
i
the
rig/ml
1
LHllOng/ml~
4
/
2
c
6
49
24
Incubation Ihrl
Con1
time
8 1 OControl
~bFGF(lng/ml)
l
A
01
cont.
A03
0.1 bFGF
0.3 i rig/ml
1
3
c/
1
days old:
3
6
Fiq.
1,Dose response effect of bFGF on PGFm production in cultured rat luteal cells. IU, ip) at 57 hrs Immature rats were injected with hCG (10 after PMSG (5 IU, SC) treatment. Luteal cells, which were collected 3 days after hCG treatment, were cultured for 48 hrs in the presence of various doses of bFGF. PGF2(y in the shows the mean f medium was determined by RIA. Each value Similar results were obtained SE of quadruplicate cultures. by three additional experiments.The inset shows thetimecourse of the effect of bFGF on PGFWproduction. A maximal was used. Each point stimulatory dose of bFGF (1 rig/ml) represents the mean + SE of triplicate cultures.
Fiq.
2,Stimulatory effects of bFGF on PGF~Q production in 3, 6 and 9 days after hCG treatment. luteal cells which were collected 3, 6 and 9 days Luteal cells, after hCG treatment,were cultured for 48 hrs in the presence by RIA. of bFGF (1 rig/ml). PGF2a in the medium was measured obtained in a Each value shows the mean f SE of 12 cultures third series of identical experiments. *P
9
Vol.
178,
No.
BIOCHEMICAL
1, 1991
of culture, during the
were
But,
the
similar
though
the
culture
as
tion
with
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
elevated gradually the PGFld levels period. Treatment for 48 hrs with bFGF suggesting that the stimulative number,
and afterwards 48 hrs culture
had no effect on cell effect of bFGF can not number.
AND
to
be attributed
PGFrd that
levels of
PRG levels shown
in
LH tended
the
in
in
the
control
inhibit
an increase
LH (10 group
this group 3. We also
Fig. to
to
the
of
rig/ml)-treated
during
the
were stimulated observed that ability
cell
of
group 48 hrs,
at bFGF
bFGF
to
al-
24 hrs of in combinastimulate
the luteal PGFIa production (data not shown). The stimulatory was also recognized on 6effect of bFGF on the PGFZd p reduction or g-day-old LC as observed on 3-day-old LC (Fig. 2). Levels of the same in each day-old, albFGF-stimulated PGFZd were almost though control compared with rig/ml) old
on luteal LC (Fig.
culture group
levels that of
started, peaked
3).
on g-day-old a 6-day-old.
PRG production PRG levels because
between
12
LC significantly Next, the effect was
were the
and
studied
measured
PRG levels 24 hrs
of
increased of bFGF
on 3-, at
in culture
6-
24 hrs
control as
and
after or
as (1
g-day-
the
LH-treated
previously
re-
-46
-21.5
-14.3
Fiq.
Fig.
3,;;F;;ts
of bFGF on progesterone production in luteal 3, 6 and 9 days after hCG treatment. Luteal cells, which were collected 3, 6 and 9 days after hCG treatment, were cultured for 24 hrs in the presence of bFGF (1 The progesterone level in the medium was rig/ml) or LH (IO rig/ml). measured by RIA. Each value shows the mean f SE of quintuplicate cultures. Similar results were obtained in five additional experiments. *P~0.05,**P<0.01,***P~0.001 vs. control of each control.QP
Vol.
178,
No.
ported
1, 1991
bFGF
(13).
examined,
as
in
human placenta LC (14). The creased as in 3-day-old,
-4
that
thereafter responsibility But, spite
the of
to
PGF1d
Western which
the
18 kDa
prepared
proteins
4). not
also in
the
as reported However,
showed
there in
release is found for
is
of
was why stage
at
as
CL
day-l
to
undetectable
almost
the
decrease
of
PGF2d production of receptors for
to bFGF bFGF.
the
parallel
with
levels of not clear
bFGF-stimuat present.
antibody
revealed
affinity
6-
and
which
were
in while
constant of CL is
bFGF monoclonal
presence
to
vivo.
lack
purified
g-day-old of
of
bFGF
components
of
luteinized
bFGF
levels
indicates luteal reportedly
between
that bFGF of phase. The exissuggested (16,
immunoreactive
detected
bFGF-like
between
discussion
whether
All
of
a signal
the
and
21.5
the
30 kDa
bFGF enhances
translational
sequence
which
via the normal secretory pathway in the extracellular matrix (20,211 its
release
is
may not
not
data).
These
be fully in the
would
although
Our
the
be possible 391
from
result
cell
with
that the dose of LC in vivo, regard
to
the
immuno-
showed compartthat
the
and extra-
is very low. Therefore, of bFGF used in this
Assuming milieu
whereas the of
imply
the
of
direct
(18,19),
observations
secreted vivo doses
concentrations. concentration in will
understood.
PG and
products
using the bFGF monoclonal antibody bFGF was mainly in intracellular
bFGF concentration to conclude that
are physiological physiological lowing
(2.68-fold g-day-old).
decreased
result,
not in number
the
LC (unpublished
bFGF molecule cellular difficult
this
a question
LC in
histochemical staining that a localization of ments
from
level in
bFGF receptor were
The apparant difference observed. This result exist in CL thoughout forms of bFGF has been
ovary,
bFGF mRNA appear
mechanism
3-,
purified
previously.
PRG synthesis their bFGF
of
heparin
from
day-old
PGFLd production was high receptor in late stage of CL,
using in
was
levels
and
the
all
analysis
at
Figure
receptor
of bFGF-stimulated amount of the
high concentration tence of larger 17).
in
in
every
each control and 1.24-fold
levels
by bFGF addition in CL. The reason
ovaries (Fig. each days was
bFGF which
5-day-old
production
band were
high the
LC of
COMMUNICATIONS
the PRG release from 3 N 4-day-old on PRG production gradually de-
bFGF
decrease
blotting
a main
PGFld.
Considering from in PRG production,
levels a small
PRG production receptor site lated
that
at
(15).
due
of
RESEARCH
from
compared with in 6-day-old,
relative fell
BIOPHYSICAL
PRG secretion
case
observed
and
be
the
AND
also stimulated stimulative effect
suddenly
may
raised
CL aged, as 1.50-fold
We recently aged
BIOCHEMICAL
it study
is
is a the fol-
physiologi-
Vol.
178,
Cal
No.
1, 1991
BIOCHEMICAL
significance
istration (luteolysis)
of
of
al.
recently
rat
ovary
PGF2d has been in many species, reported
PGFrd the
exerts
pseudopregnant
denied luteolytic have
CL, was
PGF26 effect.
a luteotropic
progesterone
role CL. enhanced action
in
production
physiological is required.
role
of
in
old
(before
in
vitro
bFGF-enhanced
old
PGF2d
of
has
because
PGFZd
(24,25).
So,
PGFld
in
a
stimulate of CL may and will
CL might been
can to
CL, of
luteolysis
development possibility age
et the
some
of
day-4
PGFzd-induced
the the
hand,
CL,
CL
In
age
that bFGF markedly than the late-stage in
admin-
of
(9).
in
age
to
by bFGF other
regression
only
young
of bFGF Therefore,
On the
exogenous
luteolysis
refractory
COMMUNICATIONS
the rat (7.8). Olofsson was produced locally in
action
namely
The
cause
functional
Our observation in the early-,
influential of functional that
to
including PGFld which
in
RESEARCH
by bFGF.
shown
luteolytic
rat),
(22,23). Moreover, the PRG production indicate tenance
that
functional
BIOPHYSICAL
enhanced
may be involved
reports, whereas
PGF,d
AND
the mainnot be have
postuated
to
stimulate
understand
LC,
a
further
the study
ACKNOW We are grateful to Dr. K. Kato and Dr. M. Seno of Takeda Chemical Industries, LTD. for the generous gift of recombinant bFGF and its antibody. The authors wish to thank Dr. Y. Sato (Tokyo Women's Medical College) and Dr. H. Kogo (Tokyo College of Pharmacy) for their valuable advise and the National Hormone and Pituitary Program (NIADDK, NIH) for the LH used in this study.
REFERENCES Sporn, M.B. and Roberts, A.B. (1990) Handbook of Experimental Peptide Growth Factors and Their Receptors I, Pharmacology; Springer-Verlag Berlin Heidelberg, Germany. 2. Hsueh, A.J.W., et al. (1989) Recent Progress In Hormone 45: 221-226, Academic Press, London. Research, 3. Gospodorowicz, D., Cheng, J., Lui, G.M., Baird, A., Esch, F. and Bohlen, P. (1985) Endocrinol. 117: 2383-2391. 4. Stirling, D., Magness, R.R., Stone, R., Watermann, M.R. and Simpson, E.R. (1990) J. Biol. Chem. 265: 5-8. 5. Neufeld, G., Ferrara, N., Schweigerer, L., Mitchell, R. and Gospodarowicz, D. (1987) Endocrinol. 121: 597-603. 6. Auletta, F.J. and Flint, A.P.F. (1988) Endocrine Review 9: 1.
88-105. 7.
Keyes,
P.L.
and
Wiltbank,
M.C.
(1988)
Ann.
Rev.
Physiol.
50:
465-482. 8.
9. 0.
Niswender, G.D. and Nett, T.M. (1988) Physiology of Reproduction,(E, Knobil. and J. Neill. Eds.), 489-525. Raven Press, New York. Olofsson, J., Norjavaara, E. and Selstam, G. (1990) Biol. Reprod. 42: 792-800. Kogo, H., Tamura, K., Satoh, T., Taya, K. and Sasamoto, (1990) Prostagr. Leuktr. Essential Fatty Acids 37: 177-181. 398
S.
Vol.
11.
178, No. 1, 1991
BIOCHEMICAL
AND BIOPHYSICAL
Baum, M. and Rosberg,
Sender
S.
(1987)
RESEARCH COMMUNICATIONS
Endocrinol.
120:
1019-1026
Hillensjo, T., Bauminger, S., Ah&, K. (1976) Endocrinol. 99: 996-l 002. 13. Kumai, A., Asakai, R., Sakamoto, S., Sassa, S. and Okamoto, R. (1986) Acta Endocrinol. 111: 387-393. 14. Tamura, K, Asakai, R., Okamoto, R. (1990) Japan. J. Pharmacol. 52, supplement.1: 127. 15. Asakai, R., Tamura, K., Kumai, A., Okamoto, R., Iwamoto, M., K. (1991) Japan. J. Pharmacol.55, Kato, Y. and Kato, supplement.1: 54. 16. Presta, M., Rusnati, M., Maier, J.A.M. and Ragnotti, G. (1988) Biochem. Biophys. Res. Commun. 155: 1161-1172. 17. Moscatelli, D., Joseph-Silverstein, J., Manejias, R. and Rifkin, D.B. (1987) Proc. Natl. Acad. Sci. USA 84: 5778-5782. 18. Rifkin, D.B. and Moscatelli, D. (1989) J. Cell. Biol. 109:
12.
l-6. 19. 20.
Abraham, J.A., Mergia, A., Whang, J.L., Tumolo, A., Friedman, J Hjerrild, K.A., Gospodarowicz, D. and Fiddes, J.C. (1986) Silence 233: 545-548. Baird, A. and Ling, N. (1987) Biochem. Biophys. Res. Commun. 142:
21. 22.
428-435.
Folkman, J., Klagsbrun, M., Sasse, D. and Vlodavsky, I. (1988) Am. J. Wright, K., Pang, C.Y. and Berman, 106:
1333-I
337.
Berman, H.R., Grinwich, D.L. Prostaglandin and Thromboxane Paoletti. Eds.) Vol. 2: 655, 24. Speroff, L. and Ramwell, P.W. Metab. 30: 345-350. 25. Berman, H.R., Yoshinaga, K., 221: 189-193. Am. J. Physiol.
23.
J., Wadzinski, M., Ingber, Pathol. 130: 393-400. H.R. (1980) Endocrinol.
and Hichens, M. In Advances in Research, (B. Samuelson and R. Raven Press, New York. (1970) J. Clin. Endocrinol. Wywan,
399
H. and Greep,
R.O.
(1971)
178,
No.
July
15,
1991
BIOCHEMICAL
1, 1991
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
393-399
BASIC FIBROBLAST GROWTHFACTOR IN RAT CORPUS LUTEUM STIMULATES PROSTAGLANDIN FZ-ALPHA PRODUCTION Kazuhiro
Tamura:
Rei Asakai,
and Ryohei
Okamoto
Department of Endocrinology, Medical Research Institute, Tokyo Medical and Dental University, 5-45, Yushima I-chome, Bunkyo-ku Tokyo, 113, Japan Received June 1, 1991 SUMMARY: Rat luteal cells (LC) were incubated with or without basic fibroblast growth factor (bFGF) in a serum-free medium. Prostaglandin F2d (PGFzd) production was stimulated in a dosedependent manner at 0.03~ 1 rig/ml of bFGF. One rig/ml of bFGF caused approximately 5-fold the increment of PGF2d at every stage of LC after 48 hrs of incubation. bFGF also raised progesterone secretion from LC, and this stimulatory effect on progesterone was more distinguishable in an early-, than a middleand a latestage. Additionally, bFGF concentration throughout the luteal phase was assessed using western blot analysis. The protein with typical molecular weight 18 kDa form was in high concentration throughout the luteal phase. These results suggest that bFGF may play a role in the regulation of PGFzd and progesterone production B 1991 Academic as autocrine, but not in mitosis in corpus luteum. Press,
Inc.
Recently, growth factors reported to have possibilities and modulate
the
synthesized in the ovary have been to regulate ovarian steroidogenesis
gonadotropin
actions
Basic fibroblast growth factor (bFGF) fied in the pituitary gland and brain, bovine
corpus
luteum
(CL)
(3).
onto
ovarian
function
which was originally was also isolated
Moreover,
the
mRNA encoding
was expressed in both luteal cells (4) and granulosa These facts prompted us to study the biological role luteal
function.
known as one of function
(6,7,8)
as well
as that
In addition, the
important
and it of
prostaglandin factors may
for be
bFGF
cells (5). of bFGF in
F2d (PGF2d ) is well regulation
has been shown that
uterus-derived
(1,2). identifrom
of
PGFld of
involved
in
luteal
luteal
origin
the
*To whomcorrespondence should be addressed. bFGF, basic fibroblast growth factor; The abbreviations used are Fld; PRG, Progesterone; CL, Corpus luteum; PGFz~ , Prostaglandin PMSG, pregnant mare serum gonadotropin; hCG, LC, Luteal cells; human chorionic gonadotropin.
393
0006-291X/91 $1.50 Copyright 0 1991 by Academic Press, inc. All rights of reproduction in any form reserved.
Vol.
178, No. 1, 1991
luteolysis on the
in rats
BtOCHEMtCAL
(9).
Therefore,
PGF2d and progesterone
MATERIALS
AND BtOPHYStCAL RESEARCH COMMUNtCATtONS
we studied
synthesis
the
by luteal
effects cells
of in
bFGF
vitro.
AND METHODS
In order to obtain a well-defined Animals and preparation of CL: generationof CL, immature female rats of the Sprague-Dawley strain (24b32-day-old) were SC injected at 0800 with 8 IU of by an ip injecpregnant mare serum gonadotropin (PMSG), followed tion with 10 IU human chorionic gonadotropin (hCG) at 1700 2 days after PMSG injection (normal ovulation model). Ovulation took place in the morning of the next day after hCG injection (IO) and were observed in all rats. an average of 13 f 3.2 (n=9) oocytes The day of hCG administration was defined as day-0 and the CL isolated from the rat which was observed ovulating was designated as numbering up to a g-day-old CL a l-day-old CL, with consecutive For the experiment of western (9 days after hCG treatment). blotting, higher doses of 50 IU PMSG and 25 IU hCG were used to obtain a sufficient number of luteal cells. However, it is known that no significant differences were found between the two models with regard to the microscopic appearance of LC or the response to various stimuli (11). Luteal offhag tissue saline fetal After cells times
cell
preparation : All CL removed from ovary was cleaned ovarian tissue under a dissecting microscope. The CL was digested in Cazf- and Mgftfree phosphate buffer containing 0.2 % collagenase, 250 ug/ml DNase and 1 % bovine serum in a shaking water bath at 37 *C for 90 min. cell suspension was filtered through a nylon mesh, luteal (LC) were collected by centrifugation and then washed 3 in an incubation medium.
Cell culture and PGFad and progesterone assay: LC was dispersed -inserum-free culture maurn comprised of 1:l mixture of Eagle's minimum essential medium and Ham'F 12 supplemented with 10 mM Hepes, 2 mM L-glutamine and antibiotics (100 U/ml penicillin, 100 ug/ml streptomycin and 625 rig/ml fungizone). Cells were incubated at a density of 5 x IO4 cells/dish in 500 pl medium at 37 'C with or without recombinant bFGF (human; Takeda) or LH (ovine; NIADDKoLH-26) under a water saturated atmosphere of 5 % CO2 and 95 % The amount of PGF,d was determined using RIA kit (Baxter air. Healthcare Corp.). The content of progesterone (PRG) was measured by RIA with specific antiserum (BioMaker, Israel) as described in detail earlier (12,131. The coefficients of the intraand interassay variations in each RIA were smaller than 10 %. Experimental data are presented as the mean f SE and evaluated by analysis of variance with Bartlett's test followed by Student's t-test. A difference of PcO.05 was considered significant. Western blot analysis: CL tissues (200 mg) of each day-old (3,6 and 9) were homogenized with 2 ml of 25 mM tris-HCl buffer (pH 7.45) containing 3 M NaCl, 1 mM phenylmethylsulfonyl fluoride , 4 uM leupeptin and 2 nM pepstatin at 4 "C using a glass homogenizer. After 10 min., the homogenates were diluted to 0.5 M NaCl with 25 mM tris-HCl containing protease inhibitors and centrifuged twice at 14,000 x g for 15 min at 4 OC. Supernatants were loaded onto 50 pl of heparin-sepharose column. The column was washed with 25 mM tris-HCl containing 50 ml of 1 M NaCl and then resin particles were transferred to an Eppendorf tube and boiled for 3 min in SDSPAGE sample buffer. Buffer containing recombinant bFGF was also 394
Vol.
178, No.,l,
1991
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
performed the same procedure with the column. Proteins were electrophoresed on SDS-15 % polyacrylamide gel and were transferred to a polyvinylidene difluoride (PVDF) membrane (Immobilon). The membrane was incubated in 25 mM tris-saline buffer containing 1 % BSA at room temperature with Iodinated [laI]-anti-bFGF monoclonal antibody (5 x 105 cpm/ml, MoAb 98, Takeda) for 5 hr, and then washed and exposed to film (Kodak X-OMAT AR X-ray film) for an autoradiography (-70 'C). RESULTS AND DISCUSSION PGFM production of
bFGF in
under
3-day-old
bFGF stimulated
various
concentrations
LC was measured
(Fig.
1).
(0.03-3
rig/ml)
As shown in fig.
1,
the
PGFZd production between 0.03 and 1 rig/ml of bFGF in a dose-dependent manner. The PGF2d levels significantly increased by treatment with 0.1 rig/ml of bFGF (P
significantly
rig/ml)
8
stimulated
PGFld production
J&!EGd
of
that bFGF by 6 hrs
bFGFllng/mI)
6
i
the
rig/ml
1
LHllOng/ml~
4
/
2
c
6
49
24
Incubation Ihrl
Con1
time
8 1 OControl
~bFGF(lng/ml)
l
A
01
cont.
A03
0.1 bFGF
0.3 i rig/ml
1
3
c/
1
days old:
3
6
Fiq.
1,Dose response effect of bFGF on PGFm production in cultured rat luteal cells. IU, ip) at 57 hrs Immature rats were injected with hCG (10 after PMSG (5 IU, SC) treatment. Luteal cells, which were collected 3 days after hCG treatment, were cultured for 48 hrs in the presence of various doses of bFGF. PGF2(y in the shows the mean f medium was determined by RIA. Each value Similar results were obtained SE of quadruplicate cultures. by three additional experiments.The inset shows thetimecourse of the effect of bFGF on PGFWproduction. A maximal was used. Each point stimulatory dose of bFGF (1 rig/ml) represents the mean + SE of triplicate cultures.
Fiq.
2,Stimulatory effects of bFGF on PGF~Q production in 3, 6 and 9 days after hCG treatment. luteal cells which were collected 3, 6 and 9 days Luteal cells, after hCG treatment,were cultured for 48 hrs in the presence by RIA. of bFGF (1 rig/ml). PGF2a in the medium was measured obtained in a Each value shows the mean f SE of 12 cultures third series of identical experiments. *P
9
Vol.
178,
No.
BIOCHEMICAL
1, 1991
of culture, during the
were
But,
the
similar
though
the
culture
as
tion
with
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
elevated gradually the PGFld levels period. Treatment for 48 hrs with bFGF suggesting that the stimulative number,
and afterwards 48 hrs culture
had no effect on cell effect of bFGF can not number.
AND
to
be attributed
PGFrd that
levels of
PRG levels shown
in
LH tended
the
in
in
the
control
inhibit
an increase
LH (10 group
this group 3. We also
Fig. to
to
the
of
rig/ml)-treated
during
the
were stimulated observed that ability
cell
of
group 48 hrs,
at bFGF
bFGF
to
al-
24 hrs of in combinastimulate
the luteal PGFIa production (data not shown). The stimulatory was also recognized on 6effect of bFGF on the PGFZd p reduction or g-day-old LC as observed on 3-day-old LC (Fig. 2). Levels of the same in each day-old, albFGF-stimulated PGFZd were almost though control compared with rig/ml) old
on luteal LC (Fig.
culture group
levels that of
started, peaked
3).
on g-day-old a 6-day-old.
PRG production PRG levels because
between
12
LC significantly Next, the effect was
were the
and
studied
measured
PRG levels 24 hrs
of
increased of bFGF
on 3-, at
in culture
6-
24 hrs
control as
and
after or
as (1
g-day-
the
LH-treated
previously
re-
-46
-21.5
-14.3
Fiq.
Fig.
3,;;F;;ts
of bFGF on progesterone production in luteal 3, 6 and 9 days after hCG treatment. Luteal cells, which were collected 3, 6 and 9 days after hCG treatment, were cultured for 24 hrs in the presence of bFGF (1 The progesterone level in the medium was rig/ml) or LH (IO rig/ml). measured by RIA. Each value shows the mean f SE of quintuplicate cultures. Similar results were obtained in five additional experiments. *P~0.05,**P<0.01,***P~0.001 vs. control of each control.QP
Vol.
178,
No.
ported
1, 1991
bFGF
(13).
examined,
as
in
human placenta LC (14). The creased as in 3-day-old,
-4
that
thereafter responsibility But, spite
the of
to
PGF1d
Western which
the
18 kDa
prepared
proteins
4). not
also in
the
as reported However,
showed
there in
release is found for
is
of
was why stage
at
as
CL
day-l
to
undetectable
almost
the
decrease
of
PGF2d production of receptors for
to bFGF bFGF.
the
parallel
with
levels of not clear
bFGF-stimuat present.
antibody
revealed
affinity
6-
and
which
were
in while
constant of CL is
bFGF monoclonal
presence
to
vivo.
lack
purified
g-day-old of
of
bFGF
components
of
luteinized
bFGF
levels
indicates luteal reportedly
between
that bFGF of phase. The exissuggested (16,
immunoreactive
detected
bFGF-like
between
discussion
whether
All
of
a signal
the
and
21.5
the
30 kDa
bFGF enhances
translational
sequence
which
via the normal secretory pathway in the extracellular matrix (20,211 its
release
is
may not
not
data).
These
be fully in the
would
although
Our
the
be possible 391
from
result
cell
with
that the dose of LC in vivo, regard
to
the
immuno-
showed compartthat
the
and extra-
is very low. Therefore, of bFGF used in this
Assuming milieu
whereas the of
imply
the
of
direct
(18,19),
observations
secreted vivo doses
concentrations. concentration in will
understood.
PG and
products
using the bFGF monoclonal antibody bFGF was mainly in intracellular
bFGF concentration to conclude that
are physiological physiological lowing
(2.68-fold g-day-old).
decreased
result,
not in number
the
LC (unpublished
bFGF molecule cellular difficult
this
a question
LC in
histochemical staining that a localization of ments
from
level in
bFGF receptor were
The apparant difference observed. This result exist in CL thoughout forms of bFGF has been
ovary,
bFGF mRNA appear
mechanism
3-,
purified
previously.
PRG synthesis their bFGF
of
heparin
from
day-old
PGFLd production was high receptor in late stage of CL,
using in
was
levels
and
the
all
analysis
at
Figure
receptor
of bFGF-stimulated amount of the
high concentration tence of larger 17).
in
in
every
each control and 1.24-fold
levels
by bFGF addition in CL. The reason
ovaries (Fig. each days was
bFGF which
5-day-old
production
band were
high the
LC of
COMMUNICATIONS
the PRG release from 3 N 4-day-old on PRG production gradually de-
bFGF
decrease
blotting
a main
PGFld.
Considering from in PRG production,
levels a small
PRG production receptor site lated
that
at
(15).
due
of
RESEARCH
from
compared with in 6-day-old,
relative fell
BIOPHYSICAL
PRG secretion
case
observed
and
be
the
AND
also stimulated stimulative effect
suddenly
may
raised
CL aged, as 1.50-fold
We recently aged
BIOCHEMICAL
it study
is
is a the fol-
physiologi-
Vol.
178,
Cal
No.
1, 1991
BIOCHEMICAL
significance
istration (luteolysis)
of
of
al.
recently
rat
ovary
PGF2d has been in many species, reported
PGFrd the
exerts
pseudopregnant
denied luteolytic have
CL, was
PGF26 effect.
a luteotropic
progesterone
role CL. enhanced action
in
production
physiological is required.
role
of
in
old
(before
in
vitro
bFGF-enhanced
old
PGF2d
of
has
because
PGFZd
(24,25).
So,
PGFld
in
a
stimulate of CL may and will
CL might been
can to
CL, of
luteolysis
development possibility age
et the
some
of
day-4
PGFzd-induced
the the
hand,
CL,
CL
In
age
that bFGF markedly than the late-stage in
admin-
of
(9).
in
age
to
by bFGF other
regression
only
young
of bFGF Therefore,
On the
exogenous
luteolysis
refractory
COMMUNICATIONS
the rat (7.8). Olofsson was produced locally in
action
namely
The
cause
functional
Our observation in the early-,
influential of functional that
to
including PGFld which
in
RESEARCH
by bFGF.
shown
luteolytic
rat),
(22,23). Moreover, the PRG production indicate tenance
that
functional
BIOPHYSICAL
enhanced
may be involved
reports, whereas
PGF,d
AND
the mainnot be have
postuated
to
stimulate
understand
LC,
a
further
the study
ACKNOW We are grateful to Dr. K. Kato and Dr. M. Seno of Takeda Chemical Industries, LTD. for the generous gift of recombinant bFGF and its antibody. The authors wish to thank Dr. Y. Sato (Tokyo Women's Medical College) and Dr. H. Kogo (Tokyo College of Pharmacy) for their valuable advise and the National Hormone and Pituitary Program (NIADDK, NIH) for the LH used in this study.
REFERENCES Sporn, M.B. and Roberts, A.B. (1990) Handbook of Experimental Peptide Growth Factors and Their Receptors I, Pharmacology; Springer-Verlag Berlin Heidelberg, Germany. 2. Hsueh, A.J.W., et al. (1989) Recent Progress In Hormone 45: 221-226, Academic Press, London. Research, 3. Gospodorowicz, D., Cheng, J., Lui, G.M., Baird, A., Esch, F. and Bohlen, P. (1985) Endocrinol. 117: 2383-2391. 4. Stirling, D., Magness, R.R., Stone, R., Watermann, M.R. and Simpson, E.R. (1990) J. Biol. Chem. 265: 5-8. 5. Neufeld, G., Ferrara, N., Schweigerer, L., Mitchell, R. and Gospodarowicz, D. (1987) Endocrinol. 121: 597-603. 6. Auletta, F.J. and Flint, A.P.F. (1988) Endocrine Review 9: 1.
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Niswender, G.D. and Nett, T.M. (1988) Physiology of Reproduction,(E, Knobil. and J. Neill. Eds.), 489-525. Raven Press, New York. Olofsson, J., Norjavaara, E. and Selstam, G. (1990) Biol. Reprod. 42: 792-800. Kogo, H., Tamura, K., Satoh, T., Taya, K. and Sasamoto, (1990) Prostagr. Leuktr. Essential Fatty Acids 37: 177-181. 398
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Hillensjo, T., Bauminger, S., Ah&, K. (1976) Endocrinol. 99: 996-l 002. 13. Kumai, A., Asakai, R., Sakamoto, S., Sassa, S. and Okamoto, R. (1986) Acta Endocrinol. 111: 387-393. 14. Tamura, K, Asakai, R., Okamoto, R. (1990) Japan. J. Pharmacol. 52, supplement.1: 127. 15. Asakai, R., Tamura, K., Kumai, A., Okamoto, R., Iwamoto, M., K. (1991) Japan. J. Pharmacol.55, Kato, Y. and Kato, supplement.1: 54. 16. Presta, M., Rusnati, M., Maier, J.A.M. and Ragnotti, G. (1988) Biochem. Biophys. Res. Commun. 155: 1161-1172. 17. Moscatelli, D., Joseph-Silverstein, J., Manejias, R. and Rifkin, D.B. (1987) Proc. Natl. Acad. Sci. USA 84: 5778-5782. 18. Rifkin, D.B. and Moscatelli, D. (1989) J. Cell. Biol. 109:
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Abraham, J.A., Mergia, A., Whang, J.L., Tumolo, A., Friedman, J Hjerrild, K.A., Gospodarowicz, D. and Fiddes, J.C. (1986) Silence 233: 545-548. Baird, A. and Ling, N. (1987) Biochem. Biophys. Res. Commun. 142:
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Berman, H.R., Grinwich, D.L. Prostaglandin and Thromboxane Paoletti. Eds.) Vol. 2: 655, 24. Speroff, L. and Ramwell, P.W. Metab. 30: 345-350. 25. Berman, H.R., Yoshinaga, K., 221: 189-193. Am. J. Physiol.
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J., Wadzinski, M., Ingber, Pathol. 130: 393-400. H.R. (1980) Endocrinol.
and Hichens, M. In Advances in Research, (B. Samuelson and R. Raven Press, New York. (1970) J. Clin. Endocrinol. Wywan,
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R.O.
(1971)