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Regulation of cyclic AMP and cyclic GMP levels by adrenocorticotropic hormone in cultured neurons
Vol.
133,
No. 1, 1985
November
27,
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1985
Pages
286-292
REGULATION OF CYCLIC AMP AND CYCLIC GMP LEVELS BY ADRENOCORTICOTROPIC HORMONE IN CULTURED NEURONS Patrick
Anglard,
Jean
Centre
Received
October
Guy
Zwiller,
Vincendon
and
Jean-Claude
de Neurochimie du CNRS, 5 rue Blaise 67084 STRASBOURG Cedex, France 23,
Louis
Pascal
1985
SUMMARY. The effect of adrenocorticotropic hormone (ACTH) on the intracellular concentration of cyclic nucleotides was studied in cultures of neurons from embryonic chick cerebral hemispheres. Incubation of neurons with ACTH(l-24) in the presence of phosphodiesterase inhibitor isobutylincrease in cyclic AMP while methylxanthine resulted in a sustained rise in cyclic GMP level was transient. The values obtained for halfmaximal stimulation were 0.5 lo M and 0.03 nM for cyclic AMP and cyclic ACTH( l-24) stimulated guanylate cyclase GMP respectively. Concomitantly, activity (half-maximal stimulation at 0.02nM). These results suggest the existence of two distinct populations of ACTH receptors in neurons and provide the first evidence that cyclic GMP does mediate the action 0 1985 Academic Press, Inc. of ACTH in neurons. It is
is
taken
produced
and
affecting
both
phorylation tion
of
of ACTH
on
In
spite
and
membrane
of
been
proposed
tissue
metabolism
in
been
cyclic
neurons studies,
on
nerve
cells
recently,
(4)
cultured
rat
cortical
the
present
ACTH
AMP
metabolism,
to
for
is
was
to
the
be
in
phos-
neurotropic
effects
to promote glucose
of ACTH
action
effect
of ACTH
survi-
uptake
(5).
mechanism
in
of
Cyclic
AMP
rat
subcortical
on cyclic
and
astroglial
ACTH
increases
has
AMP cells
(8)
reported. is
reported
AMP
as
in well
as
$1.50 0 1985 by Acudemic Press, qf reproduction in an.y .form
of cyclic
Inc. reserved.
paper GMP in
286
that
cultured
?
protein
molecular
(7)
cl,21
of RNA and
elucidated.
neurons
system
phosphoryla-
shown
regulate
(ACTH)
involved
regulation
underlying
messenger
evidence
nervous
demonstrated
and
the
hormone
(3).
ACTH
remain
second
central
in
recently
neurons.
these
the
and
We
all
as
(61 and
It
behaviour
of
of
the
cyclic
31.
cultures
adrenocorticotropic
within
proteins
in
maturation
action
0006-291X/85 Copyrighr All rights
metabolism
pure
ACTH
of
widely
(reviewed
and
that
occurs
synaptic
val
granted
of phosphatidylinositol,
synthesis
have
for
chick
embryo
the
levels cortical
Vol.
133,
No.
1, 1985
neurons,
the
BIOCHEMICAL
hormone
being
AND
BIOPHYSICAL
lO,OOO-fold
more
RESEARCH
potent
in
COMMUNICATIONS
increasing
cyclic
GMP level. MATERIALS
AND
METHODS
and chemicals. Peptides Synthetic ACTH(l-24) was generously provided by Drs R. Andreatta and K. Scheibli (Ciba-Geigy, Basle, Switzerland). ACTH(l-10)) ACTHIL-101, ACTH(4-111, ACTH(l-131, a -melanocyte stimulating hormone ( a-MSH) and isobutylmethylxanthine were purchased from Sigma (St Louis, MO, USA). [y.?2P]-guanosine triphosphate, cyclic AMP assay kits and cyclic GMP RIA kits were from the Radiochemical Centre, Amersham (Les Ulis, France). Culture media and sera were from Flow Laboratories ( AsniPres, France 1. Falcon plastic culture dishes were used. Cultures of neurons from embryonic chick cerebral hemispheCell culture. res were maintained as described (4,5). Cultures were initiated and for 3 days in Dulbecco’s Modified Eagle’s Medium (DMEM) supplegrown mented with 20% fetal calf serum, penicillin (25 U/ml) and streptomycin From the fourth day, cultures were grown in serum-free (25 pg/mll. DMEM containing glucose (33 mM) , transferrin (100 ug/ml) , insulin (5 putrescin (0.1 mM), progesterone (10 nM), selenium (30 nM) pg/ml), and antibiotics as described (5). Cultures were grown for 7 days in 60 mm plastic dishes. Media were renewed at alternate days. Measurement
of
ACTH-induced
changes
in
cyclic
nucleotides
levels.
Seven-
day-old neuronal cultures were preincubated for 20 min in the absence of peptide, followed by incubation with various concentrations of ACTHIl24) or its related peptides. Incubations were carried out in 2 ml of Hepes-buffered Krebs-Ringer solution (KRH: NaCl 125 mM, KC1 4.8 mM, MgSO, 1.3 mM, KH ,PO, 1.2 mM, glucose 1 g/l, Hepes 25 mM, pH 7.4) containing 1 mM isobutylmethylxanthine (IBMX). The reaction was terminated by aspiration of the media and addition of 350 1.11 of ice-cold 1 M perchloric acid. Cellular proteins were centrifuged at 5,000 g for 15 min. The supernatants were neutralized with 3 M K, CO 3 and cyclic nucleotide content was determined with the cyclic AMP assay kit and the cyclic GMP RIA kit from Amersham. Protein was determined on the resuspended pellet by the method of Lowry. Guanylate cyclase assay. Cultures were incubated for 5 min with various concentrations of ACTH(l-241 in complete serum-free DMEM. Cells were then homogenized in 250 u 1 of ice-cold 10 mM Tris-HCl buffer, pH 7.5, containing 0.5 mM EDTA and 10 mM B-mercaptoethanol. Guanylate cyclase activity was measured as previously reported (9). RESULTS
Incubation ce
of
the
of chick
increase
trations
(figure cyclic
min)
neurons
phosphodiesterase
a rapid
The
cortical
AMP
of the 1).
with
Maximal
response
incubations,
while
a
Accumulation
of
cyclic
cyclic
AMP
stimulations
was
in
and
were
slightly
only
decline
in
the
isobutylmethylxanthine
inhibitor
intracellular
ACTH(l-24)
the
produced
cyclic
GMP concen-
achieved
after
decreased cyclic
GMP
presen-
with
6-8
min.
longer
(30
was
more
response
rapid.
of
ACTH(l-24)
treatment
is
nucleotides represented 287
in in
neurons figure
at 2.
The
various
doses
concentrations
Vol.
133,
No.
1, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
I
0
10 20 Time of incubation (inin)
10 Time of incubation
30
30
20 (min)
Time-course of ACTH-induced increase of cyclic AMP (A) and (B) levels in cultured neurons. Seven-day-old cultures were incubated in Hepes-buffered KRH, pH 7.4, in the presence (0) or in the absence (m ) of ACTH(l-24) (10 FM in A and 10 nM in B). All incubations were in the presence of 1 mM IBMX. After the indicated times, intracellular cyclic AMP and cyclic GMP contents were determined with the Amersham kits. Each point is the mean ? S.D. of 6-10 determinations.
:*
of
MP
ACTH
and
( l-24)
most
cyclic
GMP
respectively.
concentrations was
of
much
cyclase and
activity
served A to
shown
efficiency cyclase
number
affect
(at
of
containing
compounds
the
AMP,
but
less
than
tides
were
not
able
to
the
ACTH-peptides
ACTH(l-24)
(EC,,:
ACTH(4-lo), (l-10), and
five-fold
response. AMP
level,
the
0.5
p M)
less Furthermore, were
unable
found
in
(4-11) efficient
than
PM).
twenty-fold
affect
By
and cyclic
288
1
to a -MSH,
GMP
that
production.
while
ob-
rise. ability
in
increasing
all
former
pep-
potency the
1 J.IM)
induce
the
that
the
in
nM)
shows
The
potent
0.02
their
effective
less
:
GMP
Table
contrast,
guanylate
for
for
(EC5,,:
ACTH(l-24)
ACTH(l-13)
same
decreased
a-MSH
5-10
(ECSo
receptors.
higher
GMP
on
cyclic
suggests
response
cyclic
tested
were
ACTH
a ACTH(l-13), so:
the
neurons.
This
AMP
were
to
for
(4-10)
for
the
AMP
stimulation
potency
were
activate
cyclic
(EC
The
cyclic at
ACTH(l-24)
essentially
sequence
fully
for
and
of
ACTH(l-24).
ACTH(4-11) (4-10)
effects
peptides levels
cyclic
than
as
ACTH-related
nucleotides
cyclic
PM)
3.
for
declined
0.5
were
activation
nM
half-maximal
figure
1 nM)
1
for
(EC,,,:
in
and response
value
dose-response
are
guanylate
AMP
PM GMP
The
cyclic
The
100
cyclic
peptide.
for
nM).
maximal
The
the
higher
0.03
(EC,,:
were
efficacious
of
sequence:
>ACTH(l-lo),
ACTH (ECso the affecting
fragments := cyclic
10
nM) GMP cyclic
Vol.
133,
No.
BIOCHEMICAL
1, 1985
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
6-
i
y’12
11 - I09
10 [ACT,
9
6
7
l-24].(~)
=F
Concentration-response curves for the increase in the levels of cyc K AMP (0) and cyclic GMP (0) induced by ACTH(l-24) in cultured neurons. Cultures were incubated in KRH with the indicated concentrations of ACTH( l-24) in the presence of 1 mM IBMX. The intracellular contents of cyclic nucleotides were measured after incubation for 7.5 min. Each point is the mean * S.D. of 6 different cultures.
Figure 3. Concentration-response curve for the activation of guanylate cyclase in cultured neurons. Cultures were incubated with the indicated concentrations of ACTH(l-24) in serum-free DMEM for 5 min at 37°C. Homogenates in 10 mM Tris-HCl buffer, pH 7.5, containing 0.5 mM EDTA and 10 mM B -mercaptoethanol were used for determination of guanylate cyclase activity (9). Each point is the mean +_ S.D. of duplicate determinations of 4-6 different cultures.
TABLE Structure-activity on
relationship cyclic
nucleotide
1
for
various
proruction
in
Percentage
Peptide cyclic
AMP
ACTH-related cultured
increase
peptides
neurons
in: cyclic
GMP
ACTH ( l-24)
95
102
ACTH(
58
20
l-10)
ACTH(4-10)
49
18
ACTH(L-11)
57
20
ACTH(l-13)
63
NS
80
NS
NS
NS
a-MSH ACTH(
18-39)
Cultured neurons were incubated in the presence of the different peptides listed (concentration range: 1 nM-10 y M). The intracellular cyclic AMP and cyclic GMP contents were measured after incubation for 7.5 min at 37°C in the presence of IBMX. Values are the mean of ACTH-induced increases of cyclic nucleotide levels from 3-6 independent experiments. NS: not significantly different from control values.
289
6
5
Vol.
133,
No. 1, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
DISCUSSION The cyclic
present
GMP
results
formation
by
cerebral
hemispheres.
for
ACTH
in
the
reguIation
this
is
the
first
report
the
effect
of
of
These
two
and
responses
of
observed
in
messenger
adrenal
There
13).
is
a
in
cyclic
response
in showing
AMP.
The
our
neuronal
reported
in
rat
brain
neurons
(7)
and
rat
(ECaO:
10
potent This
may
types
(8)
be or
for
the
cultures
subcortical cells
to use
was
(81,
cyclic
forskolin
in in
animal
the
a
the
second
two
for
cyclic GMP
the
similar
cyclic to
rat
was,
in
cyclic
cultured
response
already
as
for
almost In
GMP
(reviewed on
ACTH(l-24) AMP
differences
of
(6).
cyclic
AMP
(0.5pM)
found
involve-
were
potency
value
tissue
inducing
attributed to
EC,,
on
cyclic
elicited
higher
estimated
ACTH
comprehended
response much
astroglial
nM)
fully
activity.
the
(12)
of
transient
concentration
suggesting
role
is
the
and
activity
the
gland
difference
in
cyclase
this
rapid
mediates
cyclase
of
role
(6.7,8),
GMP
ACTH(l-24)
Effect
although
ACTH(l-24)
for
AMP
cortex,
nM
thereby
guanylate
ACTH
nucleotides, than
and
for
1
desensitization.
(10,ll)
tissues
guanylate
at
a
cyclic a
and chick
suggested
that
stimulated
AMP
embryonic
nerve
caused
concentrations,
receptor-mediated
formation
and achieved
higher
in
evidence
cyclic
from have
levels
ACTH(l-24)
were
at
neurons
AMP
provide
GMP
of
reports
cyclic
neurons.
stimulation
cultured
several
to
in
the
in
of
cyclic
decreased
ment
ACTH Whereas
ACTH
accumulation
demonstrate
that
cortical
however,
than
in
species
our
system.
(7,8),
estimation
of
the
tempting
to
argue
more
in
ACTH
cell
effect
(7).
On exist
may of
the two
receptors
AMP acting increase existence
basis sets may
production. with
of
these
of be
The ACTH
of
of
ACTH
types
to
second
leading
type to
is
populations
adenylate of
receptors
seems
cyclase
concentration. come
290
in
cyclase
receptors
guanylate
Ca++ of
it
receptor
coupled
intracellular two
data,
from
the
neurons.
to
there One
responsible
activation, Further
that
for
operate
by
cyclic inter-
probably arguments
structure-activity
set
via for
the stu-
Vol. 133,No.
1, 1985
dies.
ACTH(l-24)
cyclic
AMP
nal
they
are
cannot
of
rat
has
brain
and
protein
tide
response
tion
of
cyclase
is
cellular response
kinase is
is
shown
ACTH(I-13)
our
and
form,
induce functiona
a-MSH,
GMP
on
populations
system
the of
on
its
stimulated
cyclic
regulate
C activity known
GMP
both
N-termi-
cyclic
response. same
AMP Whether
neuron,
neurons
in
of elevation
protein
kinase in
the
polyphosphoinositlde
(14) in
to be
(17).
GMP
involved
to
membranes
a substrate
and
distinct
in
COMMUNICATIONS
or
the
if
culture
presently. been
cyclic
are
two
synaptic
cyclic
to
RESEARCH
peptide
amidated
unable
by
be concluded ACTH
Whereas
receptors
expressed
BIOPHYSICAL
potent
C-terminal
were
types
AND
most
GMP.
and they
two
the
cyclic
acetylated
these
lated,
was
and
productton,
in
BIOCHEMICAL
the
and
in
adrenal
accompanied
cortex in
Recent
demonstration
protein
kinase
C (18)
achieved
by
is
C activation. cellular
adrenal (16).
cortex
(15)
Phosphoinosi-
many
cell
types
by
that
rat
brain
guanylate
suggests
that
ACTH
How
functions
the
metabolism
via
the
eleva-
intra-
phosphoinositide
cyclic
GMP,
once
accumu-
regulated
by
ACTH
remains
to be elucidated.
ACKNOWLEDGEMENTS We thank Mrs Marie-Odile and Dr Anant N. Malviya work was supported in part Malmaison, France).
Revel for help for critically by a research
with guanylate cyclase assays reading the manuscript. This grant from Ciba-Geigy (Rueil-
REFERENCES 1.
;: 4. 5. 6. 7.
8. 9.
10.
Brownstein, M. J. (1980) Neural peptides and neuronal communication, pp. 93-99, Raven Press, New York. Krieger, D.T. (1983) Science 222, 975-985. J. (1982) Physiol. Rev. 62, 977-1059. de Wied, D. and Jolles, Daval, J.L., Louis, J.C., Gerard, M.J. and Vincendon, G. (1983) Neurosci. Lett . 36, 299-304. Daval, J.L., Anglard, P., Gerard, M-J., Vincendon, G. and Louis, J.C. (1985) J. Cell. Physiol. 124, 75-80. Wiegant, V.M., Dunn, A-J., Schotman, P. and Gispen, .W.H. 119791 Brain Res. 168, 565-584. Weiss, S., Sebben, M. and Bockaert, J. (1985) J. Neurochem. 45, 869-874. Van Calker, D., Loffler, F. and Hamprecht, B. (1983) J. Neurothem. 40, 418-427. Zwiller, J. , Basset, P. and Mandel, P. (1981) Biochim. Biophys. Acta 658, 64-75. Perchellet, J .P. and Sharma, R.K. (1979) Science 203, 1259-1260. 291
Vol.
11. 12. 13. 14. 15. 16. 17. 18.
133,
No.
1, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Hayashi, K., Sala, G., Catt, K. and Dufau, M.L. (1979) J. Blol. Chem. 254, 6678-6683. Nambi, P., Aiyar, N.V. and Sharma, R.K. (1982) Arch. Biochem. Biophys. 217, 638-646. Saez, J.M., Morera, A.M. and Dazord, A. (1981) Advances in cyclic nucleotide research, vol. 14, pp. 563-579, Raven Press, New York. Jolles, J., Zwiers, H., van Dongen, C., Schotman, P., Wirtz, K.W.A. and Gispen, W.H. (1980) Nature 286, 623-625. Farese, R., Sabir, M.A. and Larson, R.E. (1980) J. Biol. Chem. 255, 7232-7237. Vilgrain, I., Cachet, C. and Chambaz, E. (1984) J. Biol. Chem. 259, 3403-3405. Michell, R.H. (1975) Biochim. Biophys. Acta 415, 81-147. Zwiller, J., Revel, M.O. and Malviya, A.N. 11985) J. Biol. Chem. 260, 1350-1353.
292
133,
No. 1, 1985
November
27,
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1985
Pages
286-292
REGULATION OF CYCLIC AMP AND CYCLIC GMP LEVELS BY ADRENOCORTICOTROPIC HORMONE IN CULTURED NEURONS Patrick
Anglard,
Jean
Centre
Received
October
Guy
Zwiller,
Vincendon
and
Jean-Claude
de Neurochimie du CNRS, 5 rue Blaise 67084 STRASBOURG Cedex, France 23,
Louis
Pascal
1985
SUMMARY. The effect of adrenocorticotropic hormone (ACTH) on the intracellular concentration of cyclic nucleotides was studied in cultures of neurons from embryonic chick cerebral hemispheres. Incubation of neurons with ACTH(l-24) in the presence of phosphodiesterase inhibitor isobutylincrease in cyclic AMP while methylxanthine resulted in a sustained rise in cyclic GMP level was transient. The values obtained for halfmaximal stimulation were 0.5 lo M and 0.03 nM for cyclic AMP and cyclic ACTH( l-24) stimulated guanylate cyclase GMP respectively. Concomitantly, activity (half-maximal stimulation at 0.02nM). These results suggest the existence of two distinct populations of ACTH receptors in neurons and provide the first evidence that cyclic GMP does mediate the action 0 1985 Academic Press, Inc. of ACTH in neurons. It is
is
taken
produced
and
affecting
both
phorylation tion
of
of ACTH
on
In
spite
and
membrane
of
been
proposed
tissue
metabolism
in
been
cyclic
neurons studies,
on
nerve
cells
recently,
(4)
cultured
rat
cortical
the
present
ACTH
AMP
metabolism,
to
for
is
was
to
the
be
in
phos-
neurotropic
effects
to promote glucose
of ACTH
action
effect
of ACTH
survi-
uptake
(5).
mechanism
in
of
Cyclic
AMP
rat
subcortical
on cyclic
and
astroglial
ACTH
increases
has
AMP cells
(8)
reported. is
reported
AMP
as
in well
as
$1.50 0 1985 by Acudemic Press, qf reproduction in an.y .form
of cyclic
Inc. reserved.
paper GMP in
286
that
cultured
?
protein
molecular
(7)
cl,21
of RNA and
elucidated.
neurons
system
phosphoryla-
shown
regulate
(ACTH)
involved
regulation
underlying
messenger
evidence
nervous
demonstrated
and
the
hormone
(3).
ACTH
remain
second
central
in
recently
neurons.
these
the
and
We
all
as
(61 and
It
behaviour
of
of
the
cyclic
31.
cultures
adrenocorticotropic
within
proteins
in
maturation
action
0006-291X/85 Copyrighr All rights
metabolism
pure
ACTH
of
widely
(reviewed
and
that
occurs
synaptic
val
granted
of phosphatidylinositol,
synthesis
have
for
chick
embryo
the
levels cortical
Vol.
133,
No.
1, 1985
neurons,
the
BIOCHEMICAL
hormone
being
AND
BIOPHYSICAL
lO,OOO-fold
more
RESEARCH
potent
in
COMMUNICATIONS
increasing
cyclic
GMP level. MATERIALS
AND
METHODS
and chemicals. Peptides Synthetic ACTH(l-24) was generously provided by Drs R. Andreatta and K. Scheibli (Ciba-Geigy, Basle, Switzerland). ACTH(l-10)) ACTHIL-101, ACTH(4-111, ACTH(l-131, a -melanocyte stimulating hormone ( a-MSH) and isobutylmethylxanthine were purchased from Sigma (St Louis, MO, USA). [y.?2P]-guanosine triphosphate, cyclic AMP assay kits and cyclic GMP RIA kits were from the Radiochemical Centre, Amersham (Les Ulis, France). Culture media and sera were from Flow Laboratories ( AsniPres, France 1. Falcon plastic culture dishes were used. Cultures of neurons from embryonic chick cerebral hemispheCell culture. res were maintained as described (4,5). Cultures were initiated and for 3 days in Dulbecco’s Modified Eagle’s Medium (DMEM) supplegrown mented with 20% fetal calf serum, penicillin (25 U/ml) and streptomycin From the fourth day, cultures were grown in serum-free (25 pg/mll. DMEM containing glucose (33 mM) , transferrin (100 ug/ml) , insulin (5 putrescin (0.1 mM), progesterone (10 nM), selenium (30 nM) pg/ml), and antibiotics as described (5). Cultures were grown for 7 days in 60 mm plastic dishes. Media were renewed at alternate days. Measurement
of
ACTH-induced
changes
in
cyclic
nucleotides
levels.
Seven-
day-old neuronal cultures were preincubated for 20 min in the absence of peptide, followed by incubation with various concentrations of ACTHIl24) or its related peptides. Incubations were carried out in 2 ml of Hepes-buffered Krebs-Ringer solution (KRH: NaCl 125 mM, KC1 4.8 mM, MgSO, 1.3 mM, KH ,PO, 1.2 mM, glucose 1 g/l, Hepes 25 mM, pH 7.4) containing 1 mM isobutylmethylxanthine (IBMX). The reaction was terminated by aspiration of the media and addition of 350 1.11 of ice-cold 1 M perchloric acid. Cellular proteins were centrifuged at 5,000 g for 15 min. The supernatants were neutralized with 3 M K, CO 3 and cyclic nucleotide content was determined with the cyclic AMP assay kit and the cyclic GMP RIA kit from Amersham. Protein was determined on the resuspended pellet by the method of Lowry. Guanylate cyclase assay. Cultures were incubated for 5 min with various concentrations of ACTH(l-241 in complete serum-free DMEM. Cells were then homogenized in 250 u 1 of ice-cold 10 mM Tris-HCl buffer, pH 7.5, containing 0.5 mM EDTA and 10 mM B-mercaptoethanol. Guanylate cyclase activity was measured as previously reported (9). RESULTS
Incubation ce
of
the
of chick
increase
trations
(figure cyclic
min)
neurons
phosphodiesterase
a rapid
The
cortical
AMP
of the 1).
with
Maximal
response
incubations,
while
a
Accumulation
of
cyclic
cyclic
AMP
stimulations
was
in
and
were
slightly
only
decline
in
the
isobutylmethylxanthine
inhibitor
intracellular
ACTH(l-24)
the
produced
cyclic
GMP concen-
achieved
after
decreased cyclic
GMP
presen-
with
6-8
min.
longer
(30
was
more
response
rapid.
of
ACTH(l-24)
treatment
is
nucleotides represented 287
in in
neurons figure
at 2.
The
various
doses
concentrations
Vol.
133,
No.
1, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
I
0
10 20 Time of incubation (inin)
10 Time of incubation
30
30
20 (min)
Time-course of ACTH-induced increase of cyclic AMP (A) and (B) levels in cultured neurons. Seven-day-old cultures were incubated in Hepes-buffered KRH, pH 7.4, in the presence (0) or in the absence (m ) of ACTH(l-24) (10 FM in A and 10 nM in B). All incubations were in the presence of 1 mM IBMX. After the indicated times, intracellular cyclic AMP and cyclic GMP contents were determined with the Amersham kits. Each point is the mean ? S.D. of 6-10 determinations.
:*
of
MP
ACTH
and
( l-24)
most
cyclic
GMP
respectively.
concentrations was
of
much
cyclase and
activity
served A to
shown
efficiency cyclase
number
affect
(at
of
containing
compounds
the
AMP,
but
less
than
tides
were
not
able
to
the
ACTH-peptides
ACTH(l-24)
(EC,,:
ACTH(4-lo), (l-10), and
five-fold
response. AMP
level,
the
0.5
p M)
less Furthermore, were
unable
found
in
(4-11) efficient
than
PM).
twenty-fold
affect
By
and cyclic
288
1
to a -MSH,
GMP
that
production.
while
ob-
rise. ability
in
increasing
all
former
pep-
potency the
1 J.IM)
induce
the
that
the
in
nM)
shows
The
potent
0.02
their
effective
less
:
GMP
Table
contrast,
guanylate
for
for
(EC5,,:
ACTH(l-24)
ACTH(l-13)
same
decreased
a-MSH
5-10
(ECSo
receptors.
higher
GMP
on
cyclic
suggests
response
cyclic
tested
were
ACTH
a ACTH(l-13), so:
the
neurons.
This
AMP
were
to
for
(4-10)
for
the
AMP
stimulation
potency
were
activate
cyclic
(EC
The
cyclic at
ACTH(l-24)
essentially
sequence
fully
for
and
of
ACTH(l-24).
ACTH(4-11) (4-10)
effects
peptides levels
cyclic
than
as
ACTH-related
nucleotides
cyclic
PM)
3.
for
declined
0.5
were
activation
nM
half-maximal
figure
1 nM)
1
for
(EC,,,:
in
and response
value
dose-response
are
guanylate
AMP
PM GMP
The
cyclic
The
100
cyclic
peptide.
for
nM).
maximal
The
the
higher
0.03
(EC,,:
were
efficacious
of
sequence:
>ACTH(l-lo),
ACTH (ECso the affecting
fragments := cyclic
10
nM) GMP cyclic
Vol.
133,
No.
BIOCHEMICAL
1, 1985
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
6-
i
y’12
11 - I09
10 [ACT,
9
6
7
l-24].(~)
=F
Concentration-response curves for the increase in the levels of cyc K AMP (0) and cyclic GMP (0) induced by ACTH(l-24) in cultured neurons. Cultures were incubated in KRH with the indicated concentrations of ACTH( l-24) in the presence of 1 mM IBMX. The intracellular contents of cyclic nucleotides were measured after incubation for 7.5 min. Each point is the mean * S.D. of 6 different cultures.
Figure 3. Concentration-response curve for the activation of guanylate cyclase in cultured neurons. Cultures were incubated with the indicated concentrations of ACTH(l-24) in serum-free DMEM for 5 min at 37°C. Homogenates in 10 mM Tris-HCl buffer, pH 7.5, containing 0.5 mM EDTA and 10 mM B -mercaptoethanol were used for determination of guanylate cyclase activity (9). Each point is the mean +_ S.D. of duplicate determinations of 4-6 different cultures.
TABLE Structure-activity on
relationship cyclic
nucleotide
1
for
various
proruction
in
Percentage
Peptide cyclic
AMP
ACTH-related cultured
increase
peptides
neurons
in: cyclic
GMP
ACTH ( l-24)
95
102
ACTH(
58
20
l-10)
ACTH(4-10)
49
18
ACTH(L-11)
57
20
ACTH(l-13)
63
NS
80
NS
NS
NS
a-MSH ACTH(
18-39)
Cultured neurons were incubated in the presence of the different peptides listed (concentration range: 1 nM-10 y M). The intracellular cyclic AMP and cyclic GMP contents were measured after incubation for 7.5 min at 37°C in the presence of IBMX. Values are the mean of ACTH-induced increases of cyclic nucleotide levels from 3-6 independent experiments. NS: not significantly different from control values.
289
6
5
Vol.
133,
No. 1, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
DISCUSSION The cyclic
present
GMP
results
formation
by
cerebral
hemispheres.
for
ACTH
in
the
reguIation
this
is
the
first
report
the
effect
of
of
These
two
and
responses
of
observed
in
messenger
adrenal
There
13).
is
a
in
cyclic
response
in showing
AMP.
The
our
neuronal
reported
in
rat
brain
neurons
(7)
and
rat
(ECaO:
10
potent This
may
types
(8)
be or
for
the
cultures
subcortical cells
to use
was
(81,
cyclic
forskolin
in in
animal
the
a
the
second
two
for
cyclic GMP
the
similar
cyclic to
rat
was,
in
cyclic
cultured
response
already
as
for
almost In
GMP
(reviewed on
ACTH(l-24) AMP
differences
of
(6).
cyclic
AMP
(0.5pM)
found
involve-
were
potency
value
tissue
inducing
attributed to
EC,,
on
cyclic
elicited
higher
estimated
ACTH
comprehended
response much
astroglial
nM)
fully
activity.
the
(12)
of
transient
concentration
suggesting
role
is
the
and
activity
the
gland
difference
in
cyclase
this
rapid
mediates
cyclase
of
role
(6.7,8),
GMP
ACTH(l-24)
Effect
although
ACTH(l-24)
for
AMP
cortex,
nM
thereby
guanylate
ACTH
nucleotides, than
and
for
1
desensitization.
(10,ll)
tissues
guanylate
at
a
cyclic a
and chick
suggested
that
stimulated
AMP
embryonic
nerve
caused
concentrations,
receptor-mediated
formation
and achieved
higher
in
evidence
cyclic
from have
levels
ACTH(l-24)
were
at
neurons
AMP
provide
GMP
of
reports
cyclic
neurons.
stimulation
cultured
several
to
in
the
in
of
cyclic
decreased
ment
ACTH Whereas
ACTH
accumulation
demonstrate
that
cortical
however,
than
in
species
our
system.
(7,8),
estimation
of
the
tempting
to
argue
more
in
ACTH
cell
effect
(7).
On exist
may of
the two
receptors
AMP acting increase existence
basis sets may
production. with
of
these
of be
The ACTH
of
of
ACTH
types
to
second
leading
type to
is
populations
adenylate of
receptors
seems
cyclase
concentration. come
290
in
cyclase
receptors
guanylate
Ca++ of
it
receptor
coupled
intracellular two
data,
from
the
neurons.
to
there One
responsible
activation, Further
that
for
operate
by
cyclic inter-
probably arguments
structure-activity
set
via for
the stu-
Vol. 133,No.
1, 1985
dies.
ACTH(l-24)
cyclic
AMP
nal
they
are
cannot
of
rat
has
brain
and
protein
tide
response
tion
of
cyclase
is
cellular response
kinase is
is
shown
ACTH(I-13)
our
and
form,
induce functiona
a-MSH,
GMP
on
populations
system
the of
on
its
stimulated
cyclic
regulate
C activity known
GMP
both
N-termi-
cyclic
response. same
AMP Whether
neuron,
neurons
in
of elevation
protein
kinase in
the
polyphosphoinositlde
(14) in
to be
(17).
GMP
involved
to
membranes
a substrate
and
distinct
in
COMMUNICATIONS
or
the
if
culture
presently. been
cyclic
are
two
synaptic
cyclic
to
RESEARCH
peptide
amidated
unable
by
be concluded ACTH
Whereas
receptors
expressed
BIOPHYSICAL
potent
C-terminal
were
types
AND
most
GMP.
and they
two
the
cyclic
acetylated
these
lated,
was
and
productton,
in
BIOCHEMICAL
the
and
in
adrenal
accompanied
cortex in
Recent
demonstration
protein
kinase
C (18)
achieved
by
is
C activation. cellular
adrenal (16).
cortex
(15)
Phosphoinosi-
many
cell
types
by
that
rat
brain
guanylate
suggests
that
ACTH
How
functions
the
metabolism
via
the
eleva-
intra-
phosphoinositide
cyclic
GMP,
once
accumu-
regulated
by
ACTH
remains
to be elucidated.
ACKNOWLEDGEMENTS We thank Mrs Marie-Odile and Dr Anant N. Malviya work was supported in part Malmaison, France).
Revel for help for critically by a research
with guanylate cyclase assays reading the manuscript. This grant from Ciba-Geigy (Rueil-
REFERENCES 1.
;: 4. 5. 6. 7.
8. 9.
10.
Brownstein, M. J. (1980) Neural peptides and neuronal communication, pp. 93-99, Raven Press, New York. Krieger, D.T. (1983) Science 222, 975-985. J. (1982) Physiol. Rev. 62, 977-1059. de Wied, D. and Jolles, Daval, J.L., Louis, J.C., Gerard, M.J. and Vincendon, G. (1983) Neurosci. Lett . 36, 299-304. Daval, J.L., Anglard, P., Gerard, M-J., Vincendon, G. and Louis, J.C. (1985) J. Cell. Physiol. 124, 75-80. Wiegant, V.M., Dunn, A-J., Schotman, P. and Gispen, .W.H. 119791 Brain Res. 168, 565-584. Weiss, S., Sebben, M. and Bockaert, J. (1985) J. Neurochem. 45, 869-874. Van Calker, D., Loffler, F. and Hamprecht, B. (1983) J. Neurothem. 40, 418-427. Zwiller, J. , Basset, P. and Mandel, P. (1981) Biochim. Biophys. Acta 658, 64-75. Perchellet, J .P. and Sharma, R.K. (1979) Science 203, 1259-1260. 291
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AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Hayashi, K., Sala, G., Catt, K. and Dufau, M.L. (1979) J. Blol. Chem. 254, 6678-6683. Nambi, P., Aiyar, N.V. and Sharma, R.K. (1982) Arch. Biochem. Biophys. 217, 638-646. Saez, J.M., Morera, A.M. and Dazord, A. (1981) Advances in cyclic nucleotide research, vol. 14, pp. 563-579, Raven Press, New York. Jolles, J., Zwiers, H., van Dongen, C., Schotman, P., Wirtz, K.W.A. and Gispen, W.H. (1980) Nature 286, 623-625. Farese, R., Sabir, M.A. and Larson, R.E. (1980) J. Biol. Chem. 255, 7232-7237. Vilgrain, I., Cachet, C. and Chambaz, E. (1984) J. Biol. Chem. 259, 3403-3405. Michell, R.H. (1975) Biochim. Biophys. Acta 415, 81-147. Zwiller, J., Revel, M.O. and Malviya, A.N. 11985) J. Biol. Chem. 260, 1350-1353.
292