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The dynamics of the testosterone response of perifused mouse Leydig cells to hCG and Arginine Vasopressin
Vol. 146, No. 1, 1987 July 15, 1987
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 216-223
THE DYNAMICS OF THE TESTOSTERONE RESPONSE OF PERIFUSED MOUSE LEYDIG CELLS TO hCG AND ARGININE
A. Tahri-Joutei,
M.T.
INSERM U. 123 Bld Received
March
23,
166,
Latreille,
and G. Pointis
Maternite
de Port-Royal,
VASOPRESSIN
Baudelocque,
75014
Paris,
France
1987
The effect of hCG and Arginine-Vasopressin (AVP) on testosterone production by purified mouse Leydig cells was examined under dynamic conditions in a perifusion sytem. A rapid and dose-dependent increase in testosterone release was induced by a 5 min exposure of the cells to increasing concentrations of hCG (0.01 to 1 rig/ml). The testosterone response to hCG was Gaussian in distribution with -9 peak value by 100 min. A 12 h pretreatment of Leydig cells with 10 M AVP enhanced testosterone accumulation in the perifusate under basal conditions, but markedly reduced the hCG-stimulated testosterone production. The basal and hCG-stimulated testosterone secretion profiles by freshly isolated Leydig cells were, however, unaffected by the continuous presence of the same dose of AVP. These results support the finding that AVP acts directly on Leydig cells. They support the hypothesis of a possible role of neurohypophysial peptides on reproductive functions in the mouse by modulating steroidogenesis at the testicular level. 17 1987 Academic Press, Inc.
It
has
peptide the
reproductive
physial
of pituitary
in
adrenal
species
circulating
testis
zation
of
specific
0006-291X/87
the
These
the
human.
itself.
that These
AVP receptor
(5)
large
this
peptide
observations,
216
Recently,
of are
effects
on
from
the
result
the neurohypo-
(4,6,7)
deficient
could
(8)
pineal
identi-
from
several
vasopressin-like
together cells
the
have been
testes
amount which
in Leydig
to
and oxytocin and
of
inhibitory
appeared
rats
$1.50
0 I987 by Academic Press, Inc. of reproduction in any form reserved.
exerts
by AVT (2).
ovaries
of Brattleboro indicated
male,
(AVP)
The
administration
effects
gonadotropins
(3,4),
AVP (8) the
(1).
glands
testes
within
to
Arginine-Vasopressin
including in the
that
reported (AVT)
function
hormones
fied
Copyright AN rights
previously
Arginine-Vasotocin
suppression
found
been
peptide
in pituitary
be synthesized with suggested
the
and locally
characteri-
that
these
Vol. 146, No. 1, 1987
BIOCHEMICAL
neurohypophysial normal pure
animal. mouse
effect fied
peptides Recently Leydig
we have
cells
of AVP on basal mouse Leydig
might
(10).
AND BIOPHYSICAL
exert
some
established In
the
and hCG-stimulated
cells
was examined
physiologic
an in vitro present
dynamic
function perifusion
investigation,
testosterone under
RESEARCH COMMUNICATIONS
production conditions
in
the
system the
of
direct
by purias a function
of time. MATERIALS
AND METHODS
MATERIALS. Human chorionic gonadotropin (hCG, 9000 IU/mg) and Arginine' vasopressin (AVP) were provided respectively by Boehringer, Mannheim France and Calbiochem (San Diego, CA, U.S.A.). Bovine serum albumin (BSA) and Collagenase type I (144 u/mg) were from ICN Pharmaceuticals Inc. (Cleveland, OH, U.S.A.), Glucose, Deoxyribonuclease I (DNA-ase I) from Sigma Chemical Co (St Louis, MO, U.S.A.). L-Glutamine, Sodium bicarbonate, N- hydroxyethylpiperazine-N'ethanesulfonic acid (Hepes) and medium 169 were obtained France). from Eurobio Bio-Gel P2 (200-400 mesh) and Percoll were ?Paris, purchased respectively from Bio-Rad Laboratories (Richmond, CA, U.S.A.) and Pharmacia (Uppsala, Sweden). Leydig cells purification. Adult male Swiss mice (Janvier, France) were killed by cervical dislocation and testes were immediately excised and decapsulated. Cell suspension of whole testes was prepared as previously reported (11). Ten decapsulated testes were sustained to collagenase digestion in 10 ml medium 199 containing 0.1 % BSA, 3 mg collagenase and 40 ug DNAase I at 37°C in a shaking water bath for 30 min. After dispersion, the cell suspension was washed twice with 0.9 % NaCl, decanted, filtered through nylon gauze (86 Mm) and centrifuged at 150 g for 15 min. The crude intertubular cell preparation was resuspended in 2 ml BSA-medium 199 and layered on the top of a continuous Percoll-gradient as previously described (12). Bands of highly purified Leydig cells were aspirated and 3 vol BSA-medium 199 were added. After centrifugation at 150 g for 15 min, the cell pellets were resuspended in BSA-medium 199 and the total number of purified Leydig cells was determined by counting aliquots in a haemocytometer. Cell viability assessed by trypan blue exclusion was greater than 95 %. The percentage of Leydig cells as determined by histochemical staining for 3/3-hydroxysteroid dehydrogenase was 90-95 %. Perifusion of purified Leydig cells. Theoperifusion method used was as previously described (13). Approximately 10 Leydig cells were mixed with 0,5 g Bio-Gel P2. A 2 ml plastic syringe served as the perifusion column and a peristaltic pump (Bioblock - G 31098) was used to propel the medium through the perifusion chamber at approximately 0.1 mljmin. The perifusate used consisted of medium 199 containing 0.1 % BSA, 7 umolfml L-Glutamine, 350 ug/ml NaHCO , 1 mmol/ ml Hepes, 50 ug/ml gentamycin-sulfate and 4.5 mg/ml glucose. T?Ie columns were placed in a 37°C water bath and the out-flow line was connected to a fraction collector with which eluate samples were When indicated in the results section AVP or obtained at 5 min intervals. The eluates collected were stored at -20°C hCG were added to the medium. Since the rates of testosterone secretion varied until testosterone assay. each experiment (as represented by somewhat from one experiment to another, one panel in the figures) was performed with parallel columns using the same preparation of purified Leydig cells at the same time. Steroid assay. after appropriate
Testosterone dilutions
levels in the eluate from columns were assayed by a specific radioimmunoassay as previously
217
Vol. 146, No. 1, 1987
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
described (11) and expressed as ng/1063P-HSD-positive cells. The sensitiThe inter and intra-assay coefficients vity of the assay was 7 pglsample. variation for the assay were < 8 %. The cross-reaction with W-dihydrotestosterone was 36 % but was < 2 % with other steroid hormones.
of
RESULTS Dose-response rone
was
of Leydig achieved
which
time
the
(Fig.
1A).
After
trations testosterone
when
level
ranging
of
As shown
the
end of the
Leydig
cells
were
testosterone
equilibrium
from
0.01
production.
min.
to hCG. A stable
this
presented
lation,
cells
time,
in Fig.lA
(lag
a maximal
experiment
induced
c+c ++ H *+
11
10
period
around
control 0.01 rig/ml hCG 0.1 rig/ml hCG 1 rig/ml hCG
of testoste-
for
about 0.5
6-
in
hCG-stimu-
< 15 min)
to a peak
was obtained
with
1 ngfml
testosterone
levels
value
by 100 hCG. At remai-
l . .
H no incubation H12h incubatior *-+ 18h incubatior
1 o-
6
fraction
increase
acute
0
9-
ng per
at
of hCG at concen-
after
6 h, the
9
60 min,
a dose-dependent
profiles
response
lasting
perifused
a 5 min infusion
The testosterone rise
release
was approximately
to 1 rig/ml,
a rapid
basal
;:l 4
12
Figure
1.
20
28
Effect response
taining
36
of
44
52
hCG and of of perifused
freshly
60
68 Fraction
4 number
preincubation mouse Leydig
isolated
12
period cells.
(A) or preincubated
20
28
on the Parallel
36
44
testosterone columns
con-
mouse Leydig
cells
for 0, 12 and 18 b in hormone free-medium (Bj, were perifused for 6 h. Eluate samples were collected at 5 min intervals. Where indicated by the arrow, the columns were infused for with hCG. The data were typical of 3 separate experiments,
218
52
60
5 min
68
Vol. 146, No. 1, 1987
BIOCHEMICAL
AND BIOPHYSICAL
l.
E T
.
P
.
.
00
-AVP
M
AVP
.
0
(10-5M)
l
.
!2 0
RESEARCH COMMUNICATIONS
0
.
l
0
*
0.5
l 0
5 zLT
0
F 2
-.
4
12
20
28
36
FRACTION
Figure
2.
44
52
60
NUMBER
Effect of AVP pretreatment on basal testosterone secretion. Purified mouse Leydig cell were preincubated for 12 h in the -5. presence or absence of 10 >I AVP. After this incubation period, the columns were washed for 30 min and perifused in parallel for 6 h with hc>rmone-free medium. The data were typical of 3 separate
experiments.
ned,
however,
1 rig/ml
of hCG were
a longer not
than
higher
time
the basal
used,
period
the
and
values.
When concentrations
stimulation
a slow
was maintained
time-dependent
higher
than
at a plateau
decrease
during
was observed
(data
shown).
Effect
of
shows
that
the
compared
response for
at
end of
incubation
Effect
effect
Leydig
cells
that
cells.
Fig,lB
The loss
of the
cell-incu-
examination
cell-viability
hCG.
was markedly
60 and 86 % after
Microscopic
showed
on basal of
profiles
terone
secretion
preincubated
show that over
analysis to
(P < 0.02,
and hCG-stimulated
AVP on basal
simultaneously
cretion
corresponding
Leydig
was about
to
cell-incubation
isolated
18 h respectively.
the
perifused
Statistical
of freshly
experiment
response
to hCG after
peak values
of AVP treatment
containing
higher
the
testosterone
of the
was
cells
unaffected
by
period.
To determine
were
to that
12 h and
on
response
to hCG at the
bation
the
period
testosterone
decreased
the
incubation
with
showed 60 min
testosterone with
that
n = 5 ; paired
testosterone the
start t-test) 219
10 -5M
without
cells
of the
production.
secretion,
medium.
of the
throughout
after
or
hormone-free
pretreatment
controls
testosterone
two
columns
AVP for
12 h ,
The testosterone
se-
by AVP enhanced
perifusion
period
secretion
in
of
perifusion
in
AVP-pretreated
was
the
testos(Fig.
2).
fraction
significantly cells
than
in
Vol. 146, No. 1, 1987
BIOCHEMICAL
AND BIOPHYSICAL
Table
RESEARCH COMMUNICATIONS
1
Purified mzyse Leydig cells were preincubated for 12 h with or without 10 M AVP. After this time, the two separate columns were washed for 30 min and perifused in parallel with hormonefree medium. Each value represents testosterone secretion in the fraction corresponding to 60 nin after the start of perifusion. Values given were from 5 different experiments. TESTOSTERONE
(ng/5
min)
TREATMENT
EXP.
CONTROLS
AVP (10-51Q
1
0.581
0.673
2
0.463
0.582
3
0.593
0.720
4
0.656
0.989
5
0.532
0.616
AVP-treated significantly paired t-test).
controls
(Table
0.573
Zk. 0.038
cells
respectively.
1). and
different
from
The means 2 s.e.m. 0.756 In
f
0.077
contrast,
controls
(P < 0.02
(ng testosterone/5
in
control
the
and
min)
in
pretreatment
;
were
AVP-pretreated of
Leydig
Leydig
cells
by AVP
B 5-
Ca
-AVP
H
AVP
(10-5M)
I?
4-
l-
4
Figure
12
20
3.
28
36
44
52
60
68 FRACTION
4 12 NUMBER
20
28
36
44
52
80
Effect of AVP treatment on the hCG-stimulated testosterone response. Freshly purified mouse Leydig cells were continuously perifuz$d in parallel columns with medium containing or not 10 M AVP (A). Mouse Leydig cefls were preincubated for 12 h in the presence or absence of 10 M AVP. After this incubation period, columns were washed and perifused simultaneously with hormone-free medium (R). Where indicated by the arrow, the columns were infused for 5 min with 1 rig/ml hCG. These data were typical of 3 separate experiments.
220
68
Vol. 146, No. 1, 1987
induced
a marked
compared
to
40 % under -with
BIOCHEMICAL
decrease
the
untreated
control
a longer
of
at the
isolated
peak
effects
Leydig
testosterone
This
cells
of
of
were
reduction
values.
period
and inhibitory
freshly
hCG-stimulated
(Fig.3B).
AVP-pretreatment
stimulatory
RESEARCH COMMUNICATIONS
the
cells
levels
AND BIOPHYSICAL
Similar
the
was approximately results
cells
AVP were,
(data
however,
continuously
production
were not
not
perifused
with
obtained
shown).
Such
observed
when
AVP (Fig.3A).
DISCUSSION The
present
study
testosterone ported
production
by the
dogenic tion
fact
capacity our
show
respectively
on are
oxytocin rat
decrease
the
in
this It
is
this
is
observations those
the
cultured
exposed that
authors
is The
to
(16)
such
due
perifusion
to
by a pure an effect
cells
methodological system
by
has been 221
to
hCG.
AVP alone.
stimulatory Leydig
of
A more were To
our
effect
of
has been
reported
for
oxytocin
(15).
such from
the
rat.
differences used
for
a our
preparation.
a stimulatory
largely
since
levels
observe
species
from
an accumulation
production
or
hypothesis
result
testosterone
derived
AVP and
cell
of
not
the
testosterone
cells
These
in cultured
activities,
of a direct
basal
interstitial
could
basal
concentrations
who did
synthesis
Leydig
production
low
with
exposed
demonstration
that
agreement
cells
effects
both
production
Leydig
the
AVP stimulates
testicular
discrepancy
of
In addi-
production.
showed
that
steroi-
system.
observations) of
sup-
the
show that
17,20_desmolase
however,
first
to note
of other
unknown.
perifusate
strongly
and negative
which
in
influence
affects
positive
data
also
(unpublished
on testosterone
cells
are
is
testosterone
recent
and
pretreatment
interesting
luteal
exerts
on testosterone
is,
This
testosterone
They
effect
the
after
peptide
with
directly
in a perifusion
hCG-stimulated
(14).
observation
knowledge
cells
hormone
and
results
progesterone
increased
Leydig
17a-hydroxylase
own preliminary
testis. peptide
gonadotropin-stimulated
inhibitory
surprising
mouse
AVP can
neurohypophysial
consistent
cells
of
adult
this
basal
inhibit
this
this
that
partly
testicular
that
by the
that
that
indicates
of purified
data
results
clearly
Our kinetic differ
from
effect Whether is
the
human
in this
presently
study
of
the
BIOCHEMICAL
Vol. 146, No. 1, 1987 steroidogenic
regulatory
analogies
with
in static
cificity
could
cells
are
affect
rone
production
testis
point
out
On the
other
incubations. discrepancy.
be that Such
As yet
to
AVP exposure
of
by
steroid
hormones
were
undetectable
stimulatory for
phenomenon
of
proteins
is
In conclusion, the
ficance
of
de-novo
processes our
Leydig
peptides
studies
are
these
peptides
with
other
testicular
of
further
new
steroidogenic
capacity
in the
overall
side-chain in
the
of the
basal
conditions,
AVP occurred
rat
steroi-
The present
C21 results
only
puzzling.
after
A similar
agents
such
as
AVP response
as a func-
AVP-receptors,
regulatory
both
modulators
to elucidate
A likely
the step
also
study
investigations.
AVP affects
as local
cells.
regulatory
of the
locally
testoste-
suggested
in
of
that
required
cholesterol
perifusate.
appearance
needs
act
the
not spe-
The present
Leydig
AVP are
induction
results
cell
neurohypophysial Additional
to
the
the
to
of basal
been
are
mouse Leydig
known
the
since
effects
cells
for
Whether
due
or to other
tively
reported
(19).
time
inhibitory
12 h of Leydig
has been
catecholamines tion
and
in
are
some
a species that
(1.8).
regarding
AVP exposure,
that
increase
by AVP has
we have no information
phenomena hand,
rat
increases
a regulation
affected
pretreatment
in the the
peptide
presents
which
for
the
which
noteworthy
cause
pathway
both
is
agonists
capacity
dogenic
that
It
precise
response
activity. (16).
could
the
in could
cleavage
situation
androgenic
to identify
explanation
model
to LHRH and its
testicular
has failed
This
this
unresponsive
the
(17).
long-term
explain
RESEARCH COMMUNICATIONS
mechanisms
the --in vivo
revealed
AND BIOPHYSICAL
the
function
positively
support
the
of exact
and negafinding
testicular
function.
physiological
of the
that
signi-
testis.
ACKNOWLEDGEMENTS The authors wish to Mrs M. Verger for careful
thank Dr L. Cedard for her preparation of the manuscript.
critical
comments
and
REFERENCES 1. Vaughan, 939. 2. Vaughan, crinology
M.K.,
Vaughan,
G.M.
M.K., 104,
Blask, D.E., 212-217.
and Klein, Johnson,
222
D.C. L.Y.
(1974)
and Reiter,
Science
186,
R.J.
(1979)
938Endo-
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146,
No.
1, 1987
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
3. Ang, V.T.Y. and Jenkins, J.S. (1984) J. Clin. Endocrinol. Metab. 58, 688-691. 4. Nicholson, H.D., Swann, R.W., Burford, G.D., Wathes, D.C., Porter, D.G. and Pickering, B.T. (lS84) Regul. Peptides 8, 141-146. 5. Wathes, D.C., Swann, R.W., Pickering, B.T., Porter, D.G., Hull, M.G.R. and Drife, J.O. (1982) Lancet 2, 410-412. 6. Guldenaar, S.E.F. and Pickering, B.T. (1985) Cell Tissue Res. 240, 485487. 7. Nicholson, H.D., Worley, R.T.S., Charlton, H.M. and Pickering, B.T. (1986) J. Endocr. 110, 159-167. 8. Kasson, B.G. and Hsueh, A.J.W. (1986) Endocrinology 118, 23-31. (1985) Endocrinology 116, 416-423. 9. Meidan, R. and Hsueh, A.J.W. Latreille, M.T. and Pointis, G. (1986) Ann. Endocrin. 47, 10. Tahri, J.A., 282, Abst. N" 147. 11. Rao, B., Pointis, G. and Cedard, L. (1982) J. Reprod. Fert. 66, 341-348. 12. Browning, J.Y., D'Agata, R. and Grotjan Jr. H.E. (1981) Endocrinology 109, 667-669. 13. Gillies, G. and Lowry, P.J. (1978) Endocrinology 103, 521-527. 14. Adashi, E.Y. and Hsueh, A.J.W. (1981) Nature (Land) 293, 650-652. 15. Tan, G.J.S., Tweedale, R. and Biggs, J.S.G. (1982) J. Endocr. 95, 6570. 16. Adashi, E.Y., Tucker, E.M. and Hsueh, A.J.W. (1984) J. Biol. Chem. 259, 5440-5446. Puett, D. and Ascoli, M. (1981) Endocrinology 108, 63217. Segaloff, D.L., 638. 18. Hunter, M.G., Sullivan, M.H.E., Dix, C.J., Alred, L.F. and Cooke, B.A. (1982) Mol. Cell. Endocrinol. 27, 31-44. 19. Cooke, B.A., Golding, M., Dix, C.J. and Hunter, M.G. (1982) Mol. Cell. Endocrinol. 27, 221-231.
223
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 216-223
THE DYNAMICS OF THE TESTOSTERONE RESPONSE OF PERIFUSED MOUSE LEYDIG CELLS TO hCG AND ARGININE
A. Tahri-Joutei,
M.T.
INSERM U. 123 Bld Received
March
23,
166,
Latreille,
and G. Pointis
Maternite
de Port-Royal,
VASOPRESSIN
Baudelocque,
75014
Paris,
France
1987
The effect of hCG and Arginine-Vasopressin (AVP) on testosterone production by purified mouse Leydig cells was examined under dynamic conditions in a perifusion sytem. A rapid and dose-dependent increase in testosterone release was induced by a 5 min exposure of the cells to increasing concentrations of hCG (0.01 to 1 rig/ml). The testosterone response to hCG was Gaussian in distribution with -9 peak value by 100 min. A 12 h pretreatment of Leydig cells with 10 M AVP enhanced testosterone accumulation in the perifusate under basal conditions, but markedly reduced the hCG-stimulated testosterone production. The basal and hCG-stimulated testosterone secretion profiles by freshly isolated Leydig cells were, however, unaffected by the continuous presence of the same dose of AVP. These results support the finding that AVP acts directly on Leydig cells. They support the hypothesis of a possible role of neurohypophysial peptides on reproductive functions in the mouse by modulating steroidogenesis at the testicular level. 17 1987 Academic Press, Inc.
It
has
peptide the
reproductive
physial
of pituitary
in
adrenal
species
circulating
testis
zation
of
specific
0006-291X/87
the
These
the
human.
itself.
that These
AVP receptor
(5)
large
this
peptide
observations,
216
Recently,
of are
effects
on
from
the
result
the neurohypo-
(4,6,7)
deficient
could
(8)
pineal
identi-
from
several
vasopressin-like
together cells
the
have been
testes
amount which
in Leydig
to
and oxytocin and
of
inhibitory
appeared
rats
$1.50
0 I987 by Academic Press, Inc. of reproduction in any form reserved.
exerts
by AVT (2).
ovaries
of Brattleboro indicated
male,
(AVP)
The
administration
effects
gonadotropins
(3,4),
AVP (8) the
(1).
glands
testes
within
to
Arginine-Vasopressin
including in the
that
reported (AVT)
function
hormones
fied
Copyright AN rights
previously
Arginine-Vasotocin
suppression
found
been
peptide
in pituitary
be synthesized with suggested
the
and locally
characteri-
that
these
Vol. 146, No. 1, 1987
BIOCHEMICAL
neurohypophysial normal pure
animal. mouse
effect fied
peptides Recently Leydig
we have
cells
of AVP on basal mouse Leydig
might
(10).
AND BIOPHYSICAL
exert
some
established In
the
and hCG-stimulated
cells
was examined
physiologic
an in vitro present
dynamic
function perifusion
investigation,
testosterone under
RESEARCH COMMUNICATIONS
production conditions
in
the
system the
of
direct
by purias a function
of time. MATERIALS
AND METHODS
MATERIALS. Human chorionic gonadotropin (hCG, 9000 IU/mg) and Arginine' vasopressin (AVP) were provided respectively by Boehringer, Mannheim France and Calbiochem (San Diego, CA, U.S.A.). Bovine serum albumin (BSA) and Collagenase type I (144 u/mg) were from ICN Pharmaceuticals Inc. (Cleveland, OH, U.S.A.), Glucose, Deoxyribonuclease I (DNA-ase I) from Sigma Chemical Co (St Louis, MO, U.S.A.). L-Glutamine, Sodium bicarbonate, N- hydroxyethylpiperazine-N'ethanesulfonic acid (Hepes) and medium 169 were obtained France). from Eurobio Bio-Gel P2 (200-400 mesh) and Percoll were ?Paris, purchased respectively from Bio-Rad Laboratories (Richmond, CA, U.S.A.) and Pharmacia (Uppsala, Sweden). Leydig cells purification. Adult male Swiss mice (Janvier, France) were killed by cervical dislocation and testes were immediately excised and decapsulated. Cell suspension of whole testes was prepared as previously reported (11). Ten decapsulated testes were sustained to collagenase digestion in 10 ml medium 199 containing 0.1 % BSA, 3 mg collagenase and 40 ug DNAase I at 37°C in a shaking water bath for 30 min. After dispersion, the cell suspension was washed twice with 0.9 % NaCl, decanted, filtered through nylon gauze (86 Mm) and centrifuged at 150 g for 15 min. The crude intertubular cell preparation was resuspended in 2 ml BSA-medium 199 and layered on the top of a continuous Percoll-gradient as previously described (12). Bands of highly purified Leydig cells were aspirated and 3 vol BSA-medium 199 were added. After centrifugation at 150 g for 15 min, the cell pellets were resuspended in BSA-medium 199 and the total number of purified Leydig cells was determined by counting aliquots in a haemocytometer. Cell viability assessed by trypan blue exclusion was greater than 95 %. The percentage of Leydig cells as determined by histochemical staining for 3/3-hydroxysteroid dehydrogenase was 90-95 %. Perifusion of purified Leydig cells. Theoperifusion method used was as previously described (13). Approximately 10 Leydig cells were mixed with 0,5 g Bio-Gel P2. A 2 ml plastic syringe served as the perifusion column and a peristaltic pump (Bioblock - G 31098) was used to propel the medium through the perifusion chamber at approximately 0.1 mljmin. The perifusate used consisted of medium 199 containing 0.1 % BSA, 7 umolfml L-Glutamine, 350 ug/ml NaHCO , 1 mmol/ ml Hepes, 50 ug/ml gentamycin-sulfate and 4.5 mg/ml glucose. T?Ie columns were placed in a 37°C water bath and the out-flow line was connected to a fraction collector with which eluate samples were When indicated in the results section AVP or obtained at 5 min intervals. The eluates collected were stored at -20°C hCG were added to the medium. Since the rates of testosterone secretion varied until testosterone assay. each experiment (as represented by somewhat from one experiment to another, one panel in the figures) was performed with parallel columns using the same preparation of purified Leydig cells at the same time. Steroid assay. after appropriate
Testosterone dilutions
levels in the eluate from columns were assayed by a specific radioimmunoassay as previously
217
Vol. 146, No. 1, 1987
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
described (11) and expressed as ng/1063P-HSD-positive cells. The sensitiThe inter and intra-assay coefficients vity of the assay was 7 pglsample. variation for the assay were < 8 %. The cross-reaction with W-dihydrotestosterone was 36 % but was < 2 % with other steroid hormones.
of
RESULTS Dose-response rone
was
of Leydig achieved
which
time
the
(Fig.
1A).
After
trations testosterone
when
level
ranging
of
As shown
the
end of the
Leydig
cells
were
testosterone
equilibrium
from
0.01
production.
min.
to hCG. A stable
this
presented
lation,
cells
time,
in Fig.lA
(lag
a maximal
experiment
induced
c+c ++ H *+
11
10
period
around
control 0.01 rig/ml hCG 0.1 rig/ml hCG 1 rig/ml hCG
of testoste-
for
about 0.5
6-
in
hCG-stimu-
< 15 min)
to a peak
was obtained
with
1 ngfml
testosterone
levels
value
by 100 hCG. At remai-
l . .
H no incubation H12h incubatior *-+ 18h incubatior
1 o-
6
fraction
increase
acute
0
9-
ng per
at
of hCG at concen-
after
6 h, the
9
60 min,
a dose-dependent
profiles
response
lasting
perifused
a 5 min infusion
The testosterone rise
release
was approximately
to 1 rig/ml,
a rapid
basal
;:l 4
12
Figure
1.
20
28
Effect response
taining
36
of
44
52
hCG and of of perifused
freshly
60
68 Fraction
4 number
preincubation mouse Leydig
isolated
12
period cells.
(A) or preincubated
20
28
on the Parallel
36
44
testosterone columns
con-
mouse Leydig
cells
for 0, 12 and 18 b in hormone free-medium (Bj, were perifused for 6 h. Eluate samples were collected at 5 min intervals. Where indicated by the arrow, the columns were infused for with hCG. The data were typical of 3 separate experiments,
218
52
60
5 min
68
Vol. 146, No. 1, 1987
BIOCHEMICAL
AND BIOPHYSICAL
l.
E T
.
P
.
.
00
-AVP
M
AVP
.
0
(10-5M)
l
.
!2 0
RESEARCH COMMUNICATIONS
0
.
l
0
*
0.5
l 0
5 zLT
0
F 2
-.
4
12
20
28
36
FRACTION
Figure
2.
44
52
60
NUMBER
Effect of AVP pretreatment on basal testosterone secretion. Purified mouse Leydig cell were preincubated for 12 h in the -5. presence or absence of 10 >I AVP. After this incubation period, the columns were washed for 30 min and perifused in parallel for 6 h with hc>rmone-free medium. The data were typical of 3 separate
experiments.
ned,
however,
1 rig/ml
of hCG were
a longer not
than
higher
time
the basal
used,
period
the
and
values.
When concentrations
stimulation
a slow
was maintained
time-dependent
higher
than
at a plateau
decrease
during
was observed
(data
shown).
Effect
of
shows
that
the
compared
response for
at
end of
incubation
Effect
effect
Leydig
cells
that
cells.
Fig,lB
The loss
of the
cell-incu-
examination
cell-viability
hCG.
was markedly
60 and 86 % after
Microscopic
showed
on basal of
profiles
terone
secretion
preincubated
show that over
analysis to
(P < 0.02,
and hCG-stimulated
AVP on basal
simultaneously
cretion
corresponding
Leydig
was about
to
cell-incubation
isolated
18 h respectively.
the
perifused
Statistical
of freshly
experiment
response
to hCG after
peak values
of AVP treatment
containing
higher
the
testosterone
of the
was
cells
unaffected
by
period.
To determine
were
to that
12 h and
on
response
to hCG at the
bation
the
period
testosterone
decreased
the
incubation
with
showed 60 min
testosterone with
that
n = 5 ; paired
testosterone the
start t-test) 219
10 -5M
without
cells
of the
production.
secretion,
medium.
of the
throughout
after
or
hormone-free
pretreatment
controls
testosterone
two
columns
AVP for
12 h ,
The testosterone
se-
by AVP enhanced
perifusion
period
secretion
in
of
perifusion
in
AVP-pretreated
was
the
testos(Fig.
2).
fraction
significantly cells
than
in
Vol. 146, No. 1, 1987
BIOCHEMICAL
AND BIOPHYSICAL
Table
RESEARCH COMMUNICATIONS
1
Purified mzyse Leydig cells were preincubated for 12 h with or without 10 M AVP. After this time, the two separate columns were washed for 30 min and perifused in parallel with hormonefree medium. Each value represents testosterone secretion in the fraction corresponding to 60 nin after the start of perifusion. Values given were from 5 different experiments. TESTOSTERONE
(ng/5
min)
TREATMENT
EXP.
CONTROLS
AVP (10-51Q
1
0.581
0.673
2
0.463
0.582
3
0.593
0.720
4
0.656
0.989
5
0.532
0.616
AVP-treated significantly paired t-test).
controls
(Table
0.573
Zk. 0.038
cells
respectively.
1). and
different
from
The means 2 s.e.m. 0.756 In
f
0.077
contrast,
controls
(P < 0.02
(ng testosterone/5
in
control
the
and
min)
in
pretreatment
;
were
AVP-pretreated of
Leydig
Leydig
cells
by AVP
B 5-
Ca
-AVP
H
AVP
(10-5M)
I?
4-
l-
4
Figure
12
20
3.
28
36
44
52
60
68 FRACTION
4 12 NUMBER
20
28
36
44
52
80
Effect of AVP treatment on the hCG-stimulated testosterone response. Freshly purified mouse Leydig cells were continuously perifuz$d in parallel columns with medium containing or not 10 M AVP (A). Mouse Leydig cefls were preincubated for 12 h in the presence or absence of 10 M AVP. After this incubation period, columns were washed and perifused simultaneously with hormone-free medium (R). Where indicated by the arrow, the columns were infused for 5 min with 1 rig/ml hCG. These data were typical of 3 separate experiments.
220
68
Vol. 146, No. 1, 1987
induced
a marked
compared
to
40 % under -with
BIOCHEMICAL
decrease
the
untreated
control
a longer
of
at the
isolated
peak
effects
Leydig
testosterone
This
cells
of
of
were
reduction
values.
period
and inhibitory
freshly
hCG-stimulated
(Fig.3B).
AVP-pretreatment
stimulatory
RESEARCH COMMUNICATIONS
the
cells
levels
AND BIOPHYSICAL
Similar
the
was approximately results
cells
AVP were,
(data
however,
continuously
production
were not
not
perifused
with
obtained
shown).
Such
observed
when
AVP (Fig.3A).
DISCUSSION The
present
study
testosterone ported
production
by the
dogenic tion
fact
capacity our
show
respectively
on are
oxytocin rat
decrease
the
in
this It
is
this
is
observations those
the
cultured
exposed that
authors
is The
to
(16)
such
due
perifusion
to
by a pure an effect
cells
methodological system
by
has been 221
to
hCG.
AVP alone.
stimulatory Leydig
of
A more were To
our
effect
of
has been
reported
for
oxytocin
(15).
such from
the
rat.
differences used
for
a our
preparation.
a stimulatory
largely
since
levels
observe
species
from
an accumulation
production
or
hypothesis
result
testosterone
derived
AVP and
cell
of
not
the
testosterone
cells
These
in cultured
activities,
of a direct
basal
interstitial
could
basal
concentrations
who did
synthesis
Leydig
production
low
with
exposed
demonstration
that
agreement
cells
effects
both
production
Leydig
the
AVP stimulates
testicular
discrepancy
of
In addi-
production.
showed
that
steroi-
system.
observations) of
sup-
the
show that
17,20_desmolase
however,
first
to note
of other
unknown.
perifusate
strongly
and negative
which
in
influence
affects
positive
data
also
(unpublished
on testosterone
cells
are
is
testosterone
recent
and
pretreatment
interesting
luteal
exerts
on testosterone
is,
This
testosterone
They
effect
the
after
peptide
with
directly
in a perifusion
hCG-stimulated
(14).
observation
knowledge
cells
hormone
and
results
progesterone
increased
Leydig
17a-hydroxylase
own preliminary
testis. peptide
gonadotropin-stimulated
inhibitory
surprising
mouse
AVP can
neurohypophysial
consistent
cells
of
adult
this
basal
inhibit
this
this
that
partly
testicular
that
by the
that
that
indicates
of purified
data
results
clearly
Our kinetic differ
from
effect Whether is
the
human
in this
presently
study
of
the
BIOCHEMICAL
Vol. 146, No. 1, 1987 steroidogenic
regulatory
analogies
with
in static
cificity
could
cells
are
affect
rone
production
testis
point
out
On the
other
incubations. discrepancy.
be that Such
As yet
to
AVP exposure
of
by
steroid
hormones
were
undetectable
stimulatory for
phenomenon
of
proteins
is
In conclusion, the
ficance
of
de-novo
processes our
Leydig
peptides
studies
are
these
peptides
with
other
testicular
of
further
new
steroidogenic
capacity
in the
overall
side-chain in
the
of the
basal
conditions,
AVP occurred
rat
steroi-
The present
C21 results
only
puzzling.
after
A similar
agents
such
as
AVP response
as a func-
AVP-receptors,
regulatory
both
modulators
to elucidate
A likely
the step
also
study
investigations.
AVP affects
as local
cells.
regulatory
of the
locally
testoste-
suggested
in
of
that
required
cholesterol
perifusate.
appearance
needs
act
the
not spe-
The present
Leydig
AVP are
induction
results
cell
neurohypophysial Additional
to
the
the
to
of basal
been
are
mouse Leydig
known
the
since
effects
cells
for
Whether
due
or to other
tively
reported
(19).
time
inhibitory
12 h of Leydig
has been
catecholamines tion
and
in
are
some
a species that
(1.8).
regarding
AVP exposure,
that
increase
by AVP has
we have no information
phenomena hand,
rat
increases
a regulation
affected
pretreatment
in the the
peptide
presents
which
for
the
which
noteworthy
cause
pathway
both
is
agonists
capacity
dogenic
that
It
precise
response
activity. (16).
could
the
in could
cleavage
situation
androgenic
to identify
explanation
model
to LHRH and its
testicular
has failed
This
this
unresponsive
the
(17).
long-term
explain
RESEARCH COMMUNICATIONS
mechanisms
the --in vivo
revealed
AND BIOPHYSICAL
the
function
positively
support
the
of exact
and negafinding
testicular
function.
physiological
of the
that
signi-
testis.
ACKNOWLEDGEMENTS The authors wish to Mrs M. Verger for careful
thank Dr L. Cedard for her preparation of the manuscript.
critical
comments
and
REFERENCES 1. Vaughan, 939. 2. Vaughan, crinology
M.K.,
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G.M.
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RESEARCH
COMMUNICATIONS
3. Ang, V.T.Y. and Jenkins, J.S. (1984) J. Clin. Endocrinol. Metab. 58, 688-691. 4. Nicholson, H.D., Swann, R.W., Burford, G.D., Wathes, D.C., Porter, D.G. and Pickering, B.T. (lS84) Regul. Peptides 8, 141-146. 5. Wathes, D.C., Swann, R.W., Pickering, B.T., Porter, D.G., Hull, M.G.R. and Drife, J.O. (1982) Lancet 2, 410-412. 6. Guldenaar, S.E.F. and Pickering, B.T. (1985) Cell Tissue Res. 240, 485487. 7. Nicholson, H.D., Worley, R.T.S., Charlton, H.M. and Pickering, B.T. (1986) J. Endocr. 110, 159-167. 8. Kasson, B.G. and Hsueh, A.J.W. (1986) Endocrinology 118, 23-31. (1985) Endocrinology 116, 416-423. 9. Meidan, R. and Hsueh, A.J.W. Latreille, M.T. and Pointis, G. (1986) Ann. Endocrin. 47, 10. Tahri, J.A., 282, Abst. N" 147. 11. Rao, B., Pointis, G. and Cedard, L. (1982) J. Reprod. Fert. 66, 341-348. 12. Browning, J.Y., D'Agata, R. and Grotjan Jr. H.E. (1981) Endocrinology 109, 667-669. 13. Gillies, G. and Lowry, P.J. (1978) Endocrinology 103, 521-527. 14. Adashi, E.Y. and Hsueh, A.J.W. (1981) Nature (Land) 293, 650-652. 15. Tan, G.J.S., Tweedale, R. and Biggs, J.S.G. (1982) J. Endocr. 95, 6570. 16. Adashi, E.Y., Tucker, E.M. and Hsueh, A.J.W. (1984) J. Biol. Chem. 259, 5440-5446. Puett, D. and Ascoli, M. (1981) Endocrinology 108, 63217. Segaloff, D.L., 638. 18. Hunter, M.G., Sullivan, M.H.E., Dix, C.J., Alred, L.F. and Cooke, B.A. (1982) Mol. Cell. Endocrinol. 27, 31-44. 19. Cooke, B.A., Golding, M., Dix, C.J. and Hunter, M.G. (1982) Mol. Cell. Endocrinol. 27, 221-231.
223