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Calmodulin modulates prolactin secretion in vitro: Studies with calmodulin containing liposomes
Life Sciences, Vol. 41, pp. 2437-2444 Printed in the U.S.A.
Permagon Journals
CALMODULIN MODULATES PROLACTIN SECRETION IN VITRO: STUDIES WITH CALMODULIN CONTAINING LIPOSOMES Gennaro Schettini, Tullio Florio, Olimpia Meucci, Elisa Landolfi, Michael J. Cronin* and Robert M. MacLeod** Department of Pharmacology, II School of Medicine, University of Naples, via S. Pansini 5, 80181 Naples, ITALY. Departments of *Physiology and ~ I n t e r n a l Medicine, University of Virginia, Charlottesville, Virginia 22908, U.S.A. (Received in final form October 2, 1987) Summary ++
The control of prolactin secretion by Ca +calmodulin and cyclic ++ AMP was studied. Ca ionophore A28187 stimulated both cyclic AMP accumulation and prolactin release by primary culture of anterior pituitary cells in vitro. The increase of cyclic AMP formation by A23187 preceded that of prolactin release. To test the calmodulin involvment in these processes we used either selective calmodulin antagonist, the naphtalene sulphonamide derivative WT, or calmodulin containing liposomes. W7 dose dependently inhibited both basal or A23187 stimulated cyclic ++ AMP accumulation and prolactin secretion. Insertion of Ca + calmodulin within the cells stimulated prolactin secretion without ++ modifying cyclic AMP accumulation. W7 inhibited the Ca +calmodulin containing liposomes stimulation of prolactin release. These results suggest that calmodulin partecipates to the process of prolactin release.
++
Many
regulatory
functions
of
Ca
++
are
mediated
through
the
Ca
binding
++
receptor protein, calmodulin (CDR) (1,2). The binding of Ca to CDR has been suggested as an important step in regulating secretory+ processes in various cells (1,3). In addition CDR is necessary for the Ca mediated stimulation of enzyme activities, such as adenylate cyclase in the brain (4), pancreatic ++ islets (5), adrenal medulla (6), pituitary gland (7,8). Ca and cyclic AMP (cAMP) are intracellular messangers which mediate stimulus-secretion coupling ++ in eukariotic cells. Some secretagougues preferentially alter Ca metabolism to initiate a secretory response, with a subsequent modification in cAMP metabolism; however the reverse sequence of events has been reported (3,1). Both second messangers are involved in the control of prolactin (PRL) release from anterior pituitary cells in vitro (iO,11). In the present study we test the involvment of CDR in regulating PRL secretion either by using a CDR antagonist, the N-(6-aminohexil)-chloro-l-naphtalenesulphonamide derivative W7 (12,13), or by inserting CDR within anterior pitui0024-3205/87 $3.00 + .00 Copyright (c) 1987 Pergamon Journals Ltd.
2438
Calmodulin
tary to
cells
by means
antagonize
into
the
chinese
level
CDR
Indeed within
CDR
allowed
us
are
biological
the
cell
liposomes. ovarian
to
liposomes
effective
of
of PRL S e c r e t i o n
The
CDR-dependent
hamster
similarly
taining
Modulation
CDR
itself
also
The
use
(12).
artificial
compounds
otherwise
liposomal
subcellular
preparations
proven
to
substances,
impermeable
22, 1987
incorporation at
how CDR affects
vescicles
of m a c r o m o l e c u l a r
thymidine
distribute
of
elucidate
lipid
H
to
41, No.
W7 has been demonstrated
and
and
to more directly
carriers
antagonis~
proliferation cells,
Vol°
to
the
be
con-
PRL release. versatile
able
cell
to
and
transport
membrane
(14).
Methods
Pituitary in
cell
monolayer
cells
were
culture: culture
allowed
at
controlled
atmosphere. preincubated
For At
stored
(IBMX)
of
at -20°C
ethanolamine to
the
was
added
the
lipids was
aliquots soaked
the 0.i
medium
N
HCI
Unilamellar
described in
the
test
substances
cells
were
not
was
for
quickly
i0
at
and replaced
for
15
preincubated
removed
minutes
vulume
micelles. in
placed To
the
liposomes Briefly,
amount
two in
the
Then
for
37°C.
2
were
parts.
membrane
I0 mg/ml stream,
was
buffer
to eliminate
first
dialysis
part
were washed
octylglucoside
spinning The
obtained
PRL
All
minutes.
with IBMX. assay,
samples
by detergent
phosphatidylserine
of p h o s p h o s a l i n e
After
second
of
under N
chloroform.
desired
divided
(ig).
vortexing
residual
PBS.
and the
was then removed
and were
till assayed.
formed
and in
with
(Avantl)
with
IBMX
liposomes
study,
up g~n~ly
eliminate
tion
with
preparation:
dried
The
in a humidified
The medium
containing
twice with serum
kept
activity.
sis as previously were
to the plates
and
al.(ll).
phosphodiesterase
extracted
Liposomal
et
(Gibco)
medium
They were washed
prepared
free R P M I - 1 6 4 0
end
was
days to attach
were
Schettini
with 0.2 mM isobutylmethylxantine
experiments
the
cAMP
three
cells by
two hours
fresh the
pituitary described
for
and
with
anterior
previously
least
medium
to inhibit
Rat
as
part
was
Spectrafore
added
CDR
in
used.
The
phospholipids
twice with
diethylether
(Calbiochem) (PBS)
and
the foam, further 3.5 K the
dialy-
and phosphatidyl-
(60 mg/ml)
vortexed
divided
(18mm)
amount
till
the preparain
two
previously of
i mg/ml,
then it was divided in two aliquots and placed in membrane dialysis as above. The four aliquots were dialysed for three days, changing the buffer after 16
hours
and
then
every
24
hours.
Two
dialysing
buffers
were
prepared:
PBS
with or without CaCI lOOuM in order to obtaine the following samples of lipo2 somes to test: sample i, liposomes alone, dialysed only against PBS; sample ++ 2, liposomes with Ca , dialysed against PBS + CaCI2; sample 3, liposomes++ with CDR added, dialysed against PBS alone; sample 4, liposomes with Ca and CDR, dialysed against PBS + CaCI . Two samples of the second aliquots 2 of liposomes were added with SIO0 or parvalbumin (PVA) (img/iml) respectively instead of CDR and dialysed against PBS + CaCI . The six liposomal preparations 2 were incubated for 2 hours with primary culture of anterior pituitary cells to Lest their effect on PRL secretion. To check the interaction of liposomes with cells, the fluorescent dye 6 - c a r b o x y f l u o r e s c e i n (Eastman) was used (16). The relative uniform distribution most of the dye has been released
of fluorescence in the cells suggests that within the cytoplasm following cells liposo-
Vol.
41, No.
22, 1987
mes fusion.
The percentage
Radioimmunoassay: and
protocols
Results
were
system
maximal
did
not
provided
Center
Test substances: The
in
by
terms
were measured
(17),
and Training
provided
expressed
varied
with a double
the of
National
NIADDK
according by
cells
of PRL S e c r e t i o n
the
from 40 to 60%.
antibody
Hormone
rat
PRL of
RIA using materials
and
RP-2
to the procedures
University
2439
Pituitary
standard.
Program.
Cyclic
of Gammaflow
Virginia
AMP
automated
Diabetes
Research
RIA core laboratory.
W5 and W7 (Caabco),
concentration
affect
Modulation
oF fluorescent
PRL was determined
kindly
concentrations RIA
Calmodulin
cAMP
of
formation
A23187
ethanol or
were dissolved
(1%)
PRL
at
which
secretion.
in absolute
the
IBMX
cells
was
ethanol.
were
dissolved
exposed directly
in RPMI 1640 medium. All agents were freshly prepared. CDR, SIO0 and PVA were a generous gift of Dr. Kretsinger, Dept of Biology, University of Virginia. All other reagents Statistics: dishes.
Assays
Data
from SIGMA
were
were
if not otherwise
performed
expressed
Statistical
once.
were
in duplicate
as mean
significance
+ SEM;
specified.
on samples
experiments
was determined
from
were
quadruplicates
repeated
at least
using ANOVA.
Results
++ Ca
ionophore
effect
of
ionophore content
A23187
A23187
on
(+200%; of
greater
cAMP
than
by A23187
until
Addition
of
At
3,
7,
than
at
l.B
control
values.
3 min
(p(O.05)
W7
to
release
till
was
of W7, 65%
preparations
we
60
min,
release.
exposure the
(p(O.Ol) (data
The
to the
intraeellular but was
significantly
always
stimulated
(Fig i). not
presented)
and
(Fig 2).
had
a less
reduction tested
PRL
of
to p~O.Ol)
basal
and PRL release
and
min
not
at 30 min
inhibited
analogue
liposomal
1.5
(p(O.05
produced
different
less
30,
min
and peaked cells
cAMP accumulation a
15,
accumulation after
active
six
WB,
pituitary
PRL
cAMP
peaked
both parameters. At lOOuM, W7 reduction in cAMP accumulation. The
contrast
less
both
formation
p(O.Ol). was
A23187-stimulated In
stimulated cAMP
were
++
alone, liposomes + Ca , liposomes + CDR, liposomes PVA. Aliquots (3,10,30,5Oui) of each preparation of
powerful
in PRL
effect
release
divided
in:
and
on 90%
liposomes
++
+ Ca + CDR or SIO0 or liposomes were added and
incubated
for 2 hours with primary cultures of anterior pituitary cells. Lipo++ somes prepared in absence of added Ca , containing only phospholipids (liposomes alone), or phospholipids + CDR (liposomes + CDR), and liposomes containing ++ phospholipids + Ca (liposomes + Ca ++ ) did not significantly stimulated PRL ++ release, while 30 and 50ul of liposomes containing Ca + CDR significantly enhanced PRL secretion (p
2440
Calmodulin
Modulation
of PRL Secretion
2
30 25
-
"6 ° E CL
Vol.
41, No.
22, 1987
1200 1000
I
20
_~F--
--
--
~ 800
15 10
,),
~ /~ 2OO
.53
7
15
30
60
.53
7
15
60
MINUTES FIG i Time
course
and
PRL
of
the
release
by
effect
of
primary
i0
Each
value
represents
the
mean
Left
panel
represents
the
control
the cells
exposed
A
,7, -= 50 2~
0
,
-6
A23187
on cAMP
of anterior
+ SEM
of
four
values.
accumulation
pituitary
samples
Right
panel
cells.
per
group.
represents
to lOuM of A23187.
125[ ~
'~
uM
culture
-5 log M W 5 or W7
~ 125
~
50.
=.
25
-4
-6 log M W 5 or W 7
FTG 2
Effect
of W5 and
W7
on A 2 3 1 8 7 - s ~ i m u l a t e d
cAMP accumulation
A) and PRL release (panel B) by primary cultures of pituitary cells. W5 did not affect A 2 3 1 8 7 - s t i m u l a t e d cAMP lation or PRL release, w7 significantly inhib-'zed (o{0.01) stimulabed cAMP accumulation at 5, i0, 50 and i00 uM release at i0 (p(O.05), 50 and i00 uM (p40.Ol).
(panel
anterior accumuA23187and PRL
_m >" ~
Vol.
41, No.
22, 1987
C a l m o d u l i n M o d u l a t i o n of PRL S e c r e t i o n
2441
TABLE I ++
E f f e c t of l i p o s o m a l p r e p a r a t i o n s c o n t a i n i n g Ca
++
, CDR, or Ca
+ CDR on
PRL s e c r e t i o n by p r i m a r y c u l t u r e of a n t e r i o r p i t u i t a r y cells in vitro. a m o u n t of l i p o s o m e s
RIA PRL n g / w e l l 3
10
30
50
l i p o s o m e s a l o n e+ +
3 0 4 +. 9
3 5 0 +. 2 0
345+12
356+16
liposomes
+ Ca
278+6
338+19
375+14
liposomes
+ CDR + +
2 9 6 +. 7
liposomes
+ Ca + +
+ CDR
liposomes
+ Ca + +
liposomes
+ Ca
Each value posed
to
liposomes with
was
(ul)
alone
liposomes
3 0 2 +. 1 7
3 4 8 +. 1 0
.
3 6 5 +. 1 6
.
+ PVA
3 1 5 +. 8
.
3 4 8 +. 1 4
.
+ $100
333+13
the for
treated
hours,
group.
effective
.
351+18
mean + SEM o f
two
was 2 8 4 + 1 2
significantly
.
305+14 .
represents liposomes
.
6 wells
*p(O.05;
The a v e r a g e
~p
per
346+14
348+18
570+24**
429+14 ~
341+9
337+6
337+9
345+17
group,
<0.01
PRL v a l u e
Cells
versus of
cells
were
ex-
respective not
treated
ng/well.
only
at
the h i g h e r
concentration used
(TABLE
II).
CDR d i r e c t l y a d d e d to cell c u l t u r e did not m o d i f i e d PRL secretion.
T A B L E II
E f f e c t of W5 and W7 on the s t i m u l a t i o n of PRL s e c r e t i o n by 30ul l i p o s o m e s ++ c o n t a i n i n g Ca + CDR. RIA PRL n g / w e l l control
liposomes
253+9
++
l i p o s o m e s + Ca
+ CDR
356±17§
++
W7 i0 uN + l i p o s o m e s + Ca
+ CDR
354+10
+ CDR
269+18 ~
++
W7 30 uN + l i p o s o m e s + Ca ++
W7 60 u M + l i p o s o m e s + Ca
+ CDR
200+11 *~
++
W7 i00 uM + l i p o s o m e s + Ca
+ CDR
2 4 4 + 1 2 *~
++
W5 30 uM + l i p o s o m e s + Ca
+ CDR
314+17
+ CDR
310+20
++
W5 60 uM + l i p o s o m e s + Ca ++
W5 i00 uN + l i p o s o m e s + Ca
+ CDR
252+23 ~
E a c h v a l u e r e p r e s e n t s the mean ! SEN of 6 wells per group.
Cells were p r e -
t r e a t e d for 30 min w i t h W5 or W7 and then, s i m u l t a n e o u s l y ,
e x p o s e d to W5
or W7 + Ca ++ + CDR + l i p o s o m e s for 2 hours. CDR c o n t a i n i n g l i p o s o m e s t r e a t e d cells.
*p40.05;
*~p~O.Ol versus
Ca++ +
§p O.O1 v e r s u s c o n t r o l l i p o s o m e s
2442
Calmodulin Modulation
of PRL S e c r e t i o n
Vol.
41, No.
22,
1987
Discussion
++ Ca
and
cAMP
activities (ii)
in
been
proposed
PRL
are
(3).
the
release
and
often
several
control
of
PRL
(ii).
We
showed
from
significantly release,
integral
Although
secretion
pituitary
stimulates
suggesting
action
modulation
of the s t i m u l u s - s e c r e t i o n
Calmodulin
has been r e c e n t l y
tion
(11,18,19).
derivative
W7
In
(12,13),
cAMP a c c u m u l a t i o n The
inhibition
effect
on
our
of
cAMP
et al
(13),
similar
diesterase and
PRL
dent
PRL
between
to
(PDE)
the
(13)
and
W7 as
to
also
of m a g n i t u d e
higher
compared
sensitivity
cannot
could
possible
to
test
the plates. In contrast to
CDR
was
and
less
Thus
the
since less
to
were
unable
for
W7
showed
insertion
PRL
an
CDR
to
inhibit
the
present
to
inhibit
PRL secre-
A23187
PRL
PRL
3
stimulated
from
the
W7
sensitivity
activated
study,
action.
WS,
release basal
and
in PRL
by
show
activities.
affecting
this
has
the
also
not
been
cells
from
3 d i s p l a c e d Hkr7 binding
240uM
respectively
concentration stimulated
The
results
cellular
detach
which
liposomes
lacto~rophs.
almost one order
of W7,
and
in the
formation ++ Ca depen-
These
but
phospho-
cAMP
phospholipid
secretion,
of 210uM
of
than
HW7 from CDR was 31uM
CDR
concentrations
IC50
involvment
marked
among different
antagonist
range
cAMP
we
we
(13), used.
formation
and
p r e p a r e d liposomes ++ Ca + CDR was
containing
other
liposomal
preparations
stimulate PRL release. Thus CDR inserted within ++ in Ca bound form, stimulates PRL release, s u g g e s t i n g
in the control
experiment
IBMX,
thus
the
Hence
the
This
in the
of
formation
and
cells
by
apparent
performed
PDE
of PRL secretory
cAMP
of basal
within
formation.
cells.
the
sulphonamide
different
to displace
concentratios
W7
preparation
modulation
that
the
PRL
enzyme and the PRL secretory
inhibiting
reduce
inhibit
CDR
release
with in
to
the
inhibition
of
A23187
significantly
CDR
nucleotide
CDR
with
a
secretion
the
via liposomes,
as
and
but for c o n c e n t r a t i o n s
higher
CDR
PDE
W7
that CDR is involved As
reported
higher
to reduce
only
to
that
regulating
less
to
address
enhace
the cells
W7 in
(20,21)
was
due
activity.
CDR;
able
such
W7
is likely due to its CDR i n h i b i t i n g
directly
containing
and
showed
activities.
required
to the
potent
of
for
inhibit,
that
activated
ability
IC50
effectively
effective
PRL release To
the CDR
has
accumulation
naphtalene
basal
cyclase
to the W7 effect
exclude
more
by
likely
cellular
been
(C-kinase)
we
inhibited
is
concentration
kinase
C-kinase
we
antagonist
the a d e n y l a t e
that
the
release.
However
CDR
produced
This
of various
reported
different
Here
in the m e c h a n i s m s
the
secretion
protein
the
cAMP
and cAMP role
c o u p l i n g of PRL.
dependently
accumulation.
the r e s u l t a n t
Hidaka
(I0)
a complementary
before the ionophore enhances +÷ and cAMP are i n t e g r a t e d in
Ca
implicated
study,
dose
(ii).
many cellular
Ca
and PRL release.
to the CDR blockade, process,
of
for
stimulates
vitro
accumulation
the
roles
recently
A23187
in
in c o n t r o l l i n g
suggest
only
that
cells
cAMP
that
interactive
studies
could
changes
in
stimulated means
of
liposomes
activated
cellular
cAMP
process.
concerned, cAMP
by
may the the
the
studies
accumulation,
liposomes
discrepancy
with be
is
be
did
not
explained
cells
were
insertion
content
could
with
while
modified by
the
the the fact
not p r e t r e a t e d ++ Ca ~ CDR
of be
difficult
to
detect if both adenylate cyclase and PDE a c t i v i t i e s were increased c o n c u r r e n t l y ++ by Ca + CDR. Moreover, recently has been r e p o r t e d that in the membrane prepa-
Vol.
41, No. 22, 1987
Calmodulin Modulation
of PRL Secretion
2443
rations of anterior pituitary glands, adenylate cyclase activity was stimulated ++ by Ca and CDR. Thus reduction of cAMP formation induced by W? may likely partecipate to the W7 inhibition of PRL secretion, being cAMP one of the component involved
in the control of PRL secretory
process.
In conclusion these results show that CDR partecipates in the mechanisms gover++ ning PRL release and that the involvment o f Ca in the stimulus - secretion coupling
of
an activation
PRL
appears
to
be
mediated
of cAMP generating
system
via
CDR,
and may be partially
due
to
in the lactotrophs.
Acknowledgement
We and of
gratefully
acknowledge
G.Meyers. CDR,
SIO0
Virginia 07535
for
the technical
We
also
wish
to
and
PVA,
and
the
assaying
(R.M.M.);
cAMP.
NS 18409
thank
assistance
Dr
Diabetes
This
Core
research
(M.J.C.);
of C.Valdenegro,
R.H.Kretsinger Laboratory
was
1 F05 TWO
gift
of the University
supported
3267
M.MacOeen
for the generous by
(G.S.);
USPHS
Grant
CNR cont.
of CA-
860062404
(G.S.).
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i.
W.J.
2.
A.R. MEANS and J.R.
3.
H. RASMUSSEN, Calcium New York (1981).
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C.O. Acad.
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Science 207 19-27
BROSTROM,
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Y.C.
and
HUANG,
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(1980).
Nature 288 73-77 cAMP B.M.
as
BRECHENRIDGE
I. VALVERDE, A. VANDERPIEERS, 206 2 2 5 - 2 2 7 ( 1 9 7 9 ) .
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G. SCHETTINI, E.L. HEWLETT, M.J. CRONIN, MACLEOD, Neuroendoerinology 44 1-7 (1986).
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G. SCHETTINI, (1983).
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H. HIDAKA, Y. SASAKI, T. TANAKA, T. ENDO, S. OHNO, Y. F U J I I and T. NAGATA, P r o c . N a t l . Acad, S c i . USA 78 4 3 5 4 - 4 3 5 7 ( 1 9 8 1 ) . H. HIDAKA, T. ASANO and T. TANAKA, Mol. Pharmacol. 20 571-579 (1981). R.E. PAGANO and J.N. WEINSTEIN, Ann. Rev. Biophys. Bioeng. 7 435-468
13. 14.
M.J.
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112
1801-1807
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M.C. CORREA-FREIRE, (1984).
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M.W.
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PARRISH
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Calmodulin Modulation of PRL Secretion
Vol. 41, No. 22, 1987
Bioehem. Biophys. Acta 596 420-425 (1980). G. BROOKER, W.L. TERASAKI and M.G. PRICE, Science 194 270-276 (1976). G° SCHETTINI, A.M. JUDD and R.M. MACLEOD, Endocrinology 112 64-71 (1983). J,E. MERRIT, S. TONLINSON and B.L. BROWN, FENS Lett. 85 107-110 (1981). B.C. WISE, D.B. GLASS, C.H. JENCHOU, R.L. RAYNOR, N. KATO, R.C. SCHTZMAN, R, SCOTT-TURNER, R.F. KIBLER and J.F. KUO, J. Biol. Chem. 257 8489-8~95 (1982). D.N. HELFMAN, B.D. APPELBAUM, W.R. VOGLER and J.F. KUO, Biochem. Biophys. Res. Comm. iii 847-853 (1983).
Permagon Journals
CALMODULIN MODULATES PROLACTIN SECRETION IN VITRO: STUDIES WITH CALMODULIN CONTAINING LIPOSOMES Gennaro Schettini, Tullio Florio, Olimpia Meucci, Elisa Landolfi, Michael J. Cronin* and Robert M. MacLeod** Department of Pharmacology, II School of Medicine, University of Naples, via S. Pansini 5, 80181 Naples, ITALY. Departments of *Physiology and ~ I n t e r n a l Medicine, University of Virginia, Charlottesville, Virginia 22908, U.S.A. (Received in final form October 2, 1987) Summary ++
The control of prolactin secretion by Ca +calmodulin and cyclic ++ AMP was studied. Ca ionophore A28187 stimulated both cyclic AMP accumulation and prolactin release by primary culture of anterior pituitary cells in vitro. The increase of cyclic AMP formation by A23187 preceded that of prolactin release. To test the calmodulin involvment in these processes we used either selective calmodulin antagonist, the naphtalene sulphonamide derivative WT, or calmodulin containing liposomes. W7 dose dependently inhibited both basal or A23187 stimulated cyclic ++ AMP accumulation and prolactin secretion. Insertion of Ca + calmodulin within the cells stimulated prolactin secretion without ++ modifying cyclic AMP accumulation. W7 inhibited the Ca +calmodulin containing liposomes stimulation of prolactin release. These results suggest that calmodulin partecipates to the process of prolactin release.
++
Many
regulatory
functions
of
Ca
++
are
mediated
through
the
Ca
binding
++
receptor protein, calmodulin (CDR) (1,2). The binding of Ca to CDR has been suggested as an important step in regulating secretory+ processes in various cells (1,3). In addition CDR is necessary for the Ca mediated stimulation of enzyme activities, such as adenylate cyclase in the brain (4), pancreatic ++ islets (5), adrenal medulla (6), pituitary gland (7,8). Ca and cyclic AMP (cAMP) are intracellular messangers which mediate stimulus-secretion coupling ++ in eukariotic cells. Some secretagougues preferentially alter Ca metabolism to initiate a secretory response, with a subsequent modification in cAMP metabolism; however the reverse sequence of events has been reported (3,1). Both second messangers are involved in the control of prolactin (PRL) release from anterior pituitary cells in vitro (iO,11). In the present study we test the involvment of CDR in regulating PRL secretion either by using a CDR antagonist, the N-(6-aminohexil)-chloro-l-naphtalenesulphonamide derivative W7 (12,13), or by inserting CDR within anterior pitui0024-3205/87 $3.00 + .00 Copyright (c) 1987 Pergamon Journals Ltd.
2438
Calmodulin
tary to
cells
by means
antagonize
into
the
chinese
level
CDR
Indeed within
CDR
allowed
us
are
biological
the
cell
liposomes. ovarian
to
liposomes
effective
of
of PRL S e c r e t i o n
The
CDR-dependent
hamster
similarly
taining
Modulation
CDR
itself
also
The
use
(12).
artificial
compounds
otherwise
liposomal
subcellular
preparations
proven
to
substances,
impermeable
22, 1987
incorporation at
how CDR affects
vescicles
of m a c r o m o l e c u l a r
thymidine
distribute
of
elucidate
lipid
H
to
41, No.
W7 has been demonstrated
and
and
to more directly
carriers
antagonis~
proliferation cells,
Vol°
to
the
be
con-
PRL release. versatile
able
cell
to
and
transport
membrane
(14).
Methods
Pituitary in
cell
monolayer
cells
were
culture: culture
allowed
at
controlled
atmosphere. preincubated
For At
stored
(IBMX)
of
at -20°C
ethanolamine to
the
was
added
the
lipids was
aliquots soaked
the 0.i
medium
N
HCI
Unilamellar
described in
the
test
substances
cells
were
not
was
for
quickly
i0
at
and replaced
for
15
preincubated
removed
minutes
vulume
micelles. in
placed To
the
liposomes Briefly,
amount
two in
the
Then
for
37°C.
2
were
parts.
membrane
I0 mg/ml stream,
was
buffer
to eliminate
first
dialysis
part
were washed
octylglucoside
spinning The
obtained
PRL
All
minutes.
with IBMX. assay,
samples
by detergent
phosphatidylserine
of p h o s p h o s a l i n e
After
second
of
under N
chloroform.
desired
divided
(ig).
vortexing
residual
PBS.
and the
was then removed
and were
till assayed.
formed
and in
with
(Avantl)
with
IBMX
liposomes
study,
up g~n~ly
eliminate
tion
with
preparation:
dried
The
in a humidified
The medium
containing
twice with serum
kept
activity.
sis as previously were
to the plates
and
al.(ll).
phosphodiesterase
extracted
Liposomal
et
(Gibco)
medium
They were washed
prepared
free R P M I - 1 6 4 0
end
was
days to attach
were
Schettini
with 0.2 mM isobutylmethylxantine
experiments
the
cAMP
three
cells by
two hours
fresh the
pituitary described
for
and
with
anterior
previously
least
medium
to inhibit
Rat
as
part
was
Spectrafore
added
CDR
in
used.
The
phospholipids
twice with
diethylether
(Calbiochem) (PBS)
and
the foam, further 3.5 K the
dialy-
and phosphatidyl-
(60 mg/ml)
vortexed
divided
(18mm)
amount
till
the preparain
two
previously of
i mg/ml,
then it was divided in two aliquots and placed in membrane dialysis as above. The four aliquots were dialysed for three days, changing the buffer after 16
hours
and
then
every
24
hours.
Two
dialysing
buffers
were
prepared:
PBS
with or without CaCI lOOuM in order to obtaine the following samples of lipo2 somes to test: sample i, liposomes alone, dialysed only against PBS; sample ++ 2, liposomes with Ca , dialysed against PBS + CaCI2; sample 3, liposomes++ with CDR added, dialysed against PBS alone; sample 4, liposomes with Ca and CDR, dialysed against PBS + CaCI . Two samples of the second aliquots 2 of liposomes were added with SIO0 or parvalbumin (PVA) (img/iml) respectively instead of CDR and dialysed against PBS + CaCI . The six liposomal preparations 2 were incubated for 2 hours with primary culture of anterior pituitary cells to Lest their effect on PRL secretion. To check the interaction of liposomes with cells, the fluorescent dye 6 - c a r b o x y f l u o r e s c e i n (Eastman) was used (16). The relative uniform distribution most of the dye has been released
of fluorescence in the cells suggests that within the cytoplasm following cells liposo-
Vol.
41, No.
22, 1987
mes fusion.
The percentage
Radioimmunoassay: and
protocols
Results
were
system
maximal
did
not
provided
Center
Test substances: The
in
by
terms
were measured
(17),
and Training
provided
expressed
varied
with a double
the of
National
NIADDK
according by
cells
of PRL S e c r e t i o n
the
from 40 to 60%.
antibody
Hormone
rat
PRL of
RIA using materials
and
RP-2
to the procedures
University
2439
Pituitary
standard.
Program.
Cyclic
of Gammaflow
Virginia
AMP
automated
Diabetes
Research
RIA core laboratory.
W5 and W7 (Caabco),
concentration
affect
Modulation
oF fluorescent
PRL was determined
kindly
concentrations RIA
Calmodulin
cAMP
of
formation
A23187
ethanol or
were dissolved
(1%)
PRL
at
which
secretion.
in absolute
the
IBMX
cells
was
ethanol.
were
dissolved
exposed directly
in RPMI 1640 medium. All agents were freshly prepared. CDR, SIO0 and PVA were a generous gift of Dr. Kretsinger, Dept of Biology, University of Virginia. All other reagents Statistics: dishes.
Assays
Data
from SIGMA
were
were
if not otherwise
performed
expressed
Statistical
once.
were
in duplicate
as mean
significance
+ SEM;
specified.
on samples
experiments
was determined
from
were
quadruplicates
repeated
at least
using ANOVA.
Results
++ Ca
ionophore
effect
of
ionophore content
A23187
A23187
on
(+200%; of
greater
cAMP
than
by A23187
until
Addition
of
At
3,
7,
than
at
l.B
control
values.
3 min
(p(O.05)
W7
to
release
till
was
of W7, 65%
preparations
we
60
min,
release.
exposure the
(p(O.Ol) (data
The
to the
intraeellular but was
significantly
always
stimulated
(Fig i). not
presented)
and
(Fig 2).
had
a less
reduction tested
PRL
of
to p~O.Ol)
basal
and PRL release
and
min
not
at 30 min
inhibited
analogue
liposomal
1.5
(p(O.05
produced
different
less
30,
min
and peaked cells
cAMP accumulation a
15,
accumulation after
active
six
WB,
pituitary
PRL
cAMP
peaked
both parameters. At lOOuM, W7 reduction in cAMP accumulation. The
contrast
less
both
formation
p(O.Ol). was
A23187-stimulated In
stimulated cAMP
were
++
alone, liposomes + Ca , liposomes + CDR, liposomes PVA. Aliquots (3,10,30,5Oui) of each preparation of
powerful
in PRL
effect
release
divided
in:
and
on 90%
liposomes
++
+ Ca + CDR or SIO0 or liposomes were added and
incubated
for 2 hours with primary cultures of anterior pituitary cells. Lipo++ somes prepared in absence of added Ca , containing only phospholipids (liposomes alone), or phospholipids + CDR (liposomes + CDR), and liposomes containing ++ phospholipids + Ca (liposomes + Ca ++ ) did not significantly stimulated PRL ++ release, while 30 and 50ul of liposomes containing Ca + CDR significantly enhanced PRL secretion (p
2440
Calmodulin
Modulation
of PRL Secretion
2
30 25
-
"6 ° E CL
Vol.
41, No.
22, 1987
1200 1000
I
20
_~F--
--
--
~ 800
15 10
,),
~ /~ 2OO
.53
7
15
30
60
.53
7
15
60
MINUTES FIG i Time
course
and
PRL
of
the
release
by
effect
of
primary
i0
Each
value
represents
the
mean
Left
panel
represents
the
control
the cells
exposed
A
,7, -= 50 2~
0
,
-6
A23187
on cAMP
of anterior
+ SEM
of
four
values.
accumulation
pituitary
samples
Right
panel
cells.
per
group.
represents
to lOuM of A23187.
125[ ~
'~
uM
culture
-5 log M W 5 or W7
~ 125
~
50.
=.
25
-4
-6 log M W 5 or W 7
FTG 2
Effect
of W5 and
W7
on A 2 3 1 8 7 - s ~ i m u l a t e d
cAMP accumulation
A) and PRL release (panel B) by primary cultures of pituitary cells. W5 did not affect A 2 3 1 8 7 - s t i m u l a t e d cAMP lation or PRL release, w7 significantly inhib-'zed (o{0.01) stimulabed cAMP accumulation at 5, i0, 50 and i00 uM release at i0 (p(O.05), 50 and i00 uM (p40.Ol).
(panel
anterior accumuA23187and PRL
_m >" ~
Vol.
41, No.
22, 1987
C a l m o d u l i n M o d u l a t i o n of PRL S e c r e t i o n
2441
TABLE I ++
E f f e c t of l i p o s o m a l p r e p a r a t i o n s c o n t a i n i n g Ca
++
, CDR, or Ca
+ CDR on
PRL s e c r e t i o n by p r i m a r y c u l t u r e of a n t e r i o r p i t u i t a r y cells in vitro. a m o u n t of l i p o s o m e s
RIA PRL n g / w e l l 3
10
30
50
l i p o s o m e s a l o n e+ +
3 0 4 +. 9
3 5 0 +. 2 0
345+12
356+16
liposomes
+ Ca
278+6
338+19
375+14
liposomes
+ CDR + +
2 9 6 +. 7
liposomes
+ Ca + +
+ CDR
liposomes
+ Ca + +
liposomes
+ Ca
Each value posed
to
liposomes with
was
(ul)
alone
liposomes
3 0 2 +. 1 7
3 4 8 +. 1 0
.
3 6 5 +. 1 6
.
+ PVA
3 1 5 +. 8
.
3 4 8 +. 1 4
.
+ $100
333+13
the for
treated
hours,
group.
effective
.
351+18
mean + SEM o f
two
was 2 8 4 + 1 2
significantly
.
305+14 .
represents liposomes
.
6 wells
*p(O.05;
The a v e r a g e
~p
per
346+14
348+18
570+24**
429+14 ~
341+9
337+6
337+9
345+17
group,
<0.01
PRL v a l u e
Cells
versus of
cells
were
ex-
respective not
treated
ng/well.
only
at
the h i g h e r
concentration used
(TABLE
II).
CDR d i r e c t l y a d d e d to cell c u l t u r e did not m o d i f i e d PRL secretion.
T A B L E II
E f f e c t of W5 and W7 on the s t i m u l a t i o n of PRL s e c r e t i o n by 30ul l i p o s o m e s ++ c o n t a i n i n g Ca + CDR. RIA PRL n g / w e l l control
liposomes
253+9
++
l i p o s o m e s + Ca
+ CDR
356±17§
++
W7 i0 uN + l i p o s o m e s + Ca
+ CDR
354+10
+ CDR
269+18 ~
++
W7 30 uN + l i p o s o m e s + Ca ++
W7 60 u M + l i p o s o m e s + Ca
+ CDR
200+11 *~
++
W7 i00 uM + l i p o s o m e s + Ca
+ CDR
2 4 4 + 1 2 *~
++
W5 30 uM + l i p o s o m e s + Ca
+ CDR
314+17
+ CDR
310+20
++
W5 60 uM + l i p o s o m e s + Ca ++
W5 i00 uN + l i p o s o m e s + Ca
+ CDR
252+23 ~
E a c h v a l u e r e p r e s e n t s the mean ! SEN of 6 wells per group.
Cells were p r e -
t r e a t e d for 30 min w i t h W5 or W7 and then, s i m u l t a n e o u s l y ,
e x p o s e d to W5
or W7 + Ca ++ + CDR + l i p o s o m e s for 2 hours. CDR c o n t a i n i n g l i p o s o m e s t r e a t e d cells.
*p40.05;
*~p~O.Ol versus
Ca++ +
§p O.O1 v e r s u s c o n t r o l l i p o s o m e s
2442
Calmodulin Modulation
of PRL S e c r e t i o n
Vol.
41, No.
22,
1987
Discussion
++ Ca
and
cAMP
activities (ii)
in
been
proposed
PRL
are
(3).
the
release
and
often
several
control
of
PRL
(ii).
We
showed
from
significantly release,
integral
Although
secretion
pituitary
stimulates
suggesting
action
modulation
of the s t i m u l u s - s e c r e t i o n
Calmodulin
has been r e c e n t l y
tion
(11,18,19).
derivative
W7
In
(12,13),
cAMP a c c u m u l a t i o n The
inhibition
effect
on
our
of
cAMP
et al
(13),
similar
diesterase and
PRL
dent
PRL
between
to
(PDE)
the
(13)
and
W7 as
to
also
of m a g n i t u d e
higher
compared
sensitivity
cannot
could
possible
to
test
the plates. In contrast to
CDR
was
and
less
Thus
the
since less
to
were
unable
for
W7
showed
insertion
PRL
an
CDR
to
inhibit
the
present
to
inhibit
PRL secre-
A23187
PRL
PRL
3
stimulated
from
the
W7
sensitivity
activated
study,
action.
WS,
release basal
and
in PRL
by
show
activities.
affecting
this
has
the
also
not
been
cells
from
3 d i s p l a c e d Hkr7 binding
240uM
respectively
concentration stimulated
The
results
cellular
detach
which
liposomes
lacto~rophs.
almost one order
of W7,
and
in the
formation ++ Ca depen-
These
but
phospho-
cAMP
phospholipid
secretion,
of 210uM
of
than
HW7 from CDR was 31uM
CDR
concentrations
IC50
involvment
marked
among different
antagonist
range
cAMP
we
we
(13), used.
formation
and
p r e p a r e d liposomes ++ Ca + CDR was
containing
other
liposomal
preparations
stimulate PRL release. Thus CDR inserted within ++ in Ca bound form, stimulates PRL release, s u g g e s t i n g
in the control
experiment
IBMX,
thus
the
Hence
the
This
in the
of
formation
and
cells
by
apparent
performed
PDE
of PRL secretory
cAMP
of basal
within
formation.
cells.
the
sulphonamide
different
to displace
concentratios
W7
preparation
modulation
that
the
PRL
enzyme and the PRL secretory
inhibiting
reduce
inhibit
CDR
release
with in
to
the
inhibition
of
A23187
significantly
CDR
nucleotide
CDR
with
a
secretion
the
via liposomes,
as
and
but for c o n c e n t r a t i o n s
higher
CDR
PDE
W7
that CDR is involved As
reported
higher
to reduce
only
to
that
regulating
less
to
address
enhace
the cells
W7 in
(20,21)
was
due
activity.
CDR;
able
such
W7
is likely due to its CDR i n h i b i t i n g
directly
containing
and
showed
activities.
required
to the
potent
of
for
inhibit,
that
activated
ability
IC50
effectively
effective
PRL release To
the CDR
has
accumulation
naphtalene
basal
cyclase
to the W7 effect
exclude
more
by
likely
cellular
been
(C-kinase)
we
inhibited
is
concentration
kinase
C-kinase
we
antagonist
the a d e n y l a t e
that
the
release.
However
CDR
produced
This
of various
reported
different
Here
in the m e c h a n i s m s
the
secretion
protein
the
cAMP
and cAMP role
c o u p l i n g of PRL.
dependently
accumulation.
the r e s u l t a n t
Hidaka
(I0)
a complementary
before the ionophore enhances +÷ and cAMP are i n t e g r a t e d in
Ca
implicated
study,
dose
(ii).
many cellular
Ca
and PRL release.
to the CDR blockade, process,
of
for
stimulates
vitro
accumulation
the
roles
recently
A23187
in
in c o n t r o l l i n g
suggest
only
that
cells
cAMP
that
interactive
studies
could
changes
in
stimulated means
of
liposomes
activated
cellular
cAMP
process.
concerned, cAMP
by
may the the
the
studies
accumulation,
liposomes
discrepancy
with be
is
be
did
not
explained
cells
were
insertion
content
could
with
while
modified by
the
the the fact
not p r e t r e a t e d ++ Ca ~ CDR
of be
difficult
to
detect if both adenylate cyclase and PDE a c t i v i t i e s were increased c o n c u r r e n t l y ++ by Ca + CDR. Moreover, recently has been r e p o r t e d that in the membrane prepa-
Vol.
41, No. 22, 1987
Calmodulin Modulation
of PRL Secretion
2443
rations of anterior pituitary glands, adenylate cyclase activity was stimulated ++ by Ca and CDR. Thus reduction of cAMP formation induced by W? may likely partecipate to the W7 inhibition of PRL secretion, being cAMP one of the component involved
in the control of PRL secretory
process.
In conclusion these results show that CDR partecipates in the mechanisms gover++ ning PRL release and that the involvment o f Ca in the stimulus - secretion coupling
of
an activation
PRL
appears
to
be
mediated
of cAMP generating
system
via
CDR,
and may be partially
due
to
in the lactotrophs.
Acknowledgement
We and of
gratefully
acknowledge
G.Meyers. CDR,
SIO0
Virginia 07535
for
the technical
We
also
wish
to
and
PVA,
and
the
assaying
(R.M.M.);
cAMP.
NS 18409
thank
assistance
Dr
Diabetes
This
Core
research
(M.J.C.);
of C.Valdenegro,
R.H.Kretsinger Laboratory
was
1 F05 TWO
gift
of the University
supported
3267
M.MacOeen
for the generous by
(G.S.);
USPHS
Grant
CNR cont.
of CA-
860062404
(G.S.).
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i.
W.J.
2.
A.R. MEANS and J.R.
3.
H. RASMUSSEN, Calcium New York (1981).
4.
C.O. Acad.
CHEUNG,
Science 207 19-27
BROSTROM,
DEDMAN,
Y.C.
and
HUANG,
Sci. USA 72 64-68
(1980).
Nature 288 73-77 cAMP B.M.
as
BRECHENRIDGE
I. VALVERDE, A. VANDERPIEERS, 206 2 2 5 - 2 2 7 ( 1 9 7 9 ) .
6.
N.C.
LE DONNE Jr and C.J. COFFEE,
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G.T.
PEAKE and SMOAKE,
8.
G. SCHETTINI, E.L. HEWLETT, M.J. CRONIN, MACLEOD, Neuroendoerinology 44 1-7 (1986).
9.
M.J. BERRIDGE, Verlag, Berlin M.O.
TNORNER,
31 390-402
R.
ANJANEYULU Fed. Proc.
Endocrinology
Handbook (1982). J.T.
messangers,
and D.J.
John
WOLFF,
Whiley,
Proc.
Natl.
(1975).
5.
i0.
(1980).
synarehic
and
W.J.
Science
38 317 (1979).
116 2098-2102
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MALAISSE,
(1985).
K. KOIKE,
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T. YASU~IOTO
and R.M.
58 227-245,
Springer
H A C K E T T , F. MURAD and R.M. MACLEOD,
Neuroendocrinology
(1980).
ii.
G. SCHETTINI, (1983).
12.
H. HIDAKA, Y. SASAKI, T. TANAKA, T. ENDO, S. OHNO, Y. F U J I I and T. NAGATA, P r o c . N a t l . Acad, S c i . USA 78 4 3 5 4 - 4 3 5 7 ( 1 9 8 1 ) . H. HIDAKA, T. ASANO and T. TANAKA, Mol. Pharmacol. 20 571-579 (1981). R.E. PAGANO and J.N. WEINSTEIN, Ann. Rev. Biophys. Bioeng. 7 435-468
13. 14.
M.J.
CRONIN
and
R.M.
MACLEOD,
Endocrinology
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