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Pituitary binding sites for [3H]-labelled luteinizing hormone releasing factor (LRF)
BIOCHEMICAL
Vol. 50; No. 3,1973
PITUITARY
BINDING SITES FOR [3H]-LABELLED
LUTEINIZING
HORMONE RELEASING FACTOR (LRF).
G. Grant, The Salk
Received
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
W. Vale
Institute,
December
and .I. Rivier
La Jolla,
18,
California
92037
1972
pituitary cells in culture possess two SUMMARY : Normal rat anterior One is a high affinity (2 X lO"M), low capacity binding sites for [3H]LRF. site which corresponds to the half-maximal biological potency of LRF. The second site has low affinity (2 X 10%) and an enormously higher capacity to bind LRF. This second site shows only partial specificity in that inof [3~l~~~. The active LRF-analogues, although not TRF, compete for binding high affinity site is competible by LRF, LRF-agonists and LRF-antagonists even in the presence of an excess of an inactive LRF-analogue which saturates the low affinity binding site. The interaction with
respect
various
of LRF with
to the biological
synthetic
pituitary
cells
of luteinizing
(FSH)
pituitary
potencies
LRF analogues
gonadotropic
release
its
(1, is
hormone
has been
and intrinsic
2).
The effect
an integrated
activities
of
of an LRF peptide
process
(LH) and follicle
discussed
resulting
in
stimulating
on the
hormone
(3).
It at the
has been level
mechanism
established
that
of the pituitary
of stored
thyroid
has been postulated
(7)
thyrotropin
plasma stimulating
phylogenetically
related
characteristics
of binding
of labelled
cells
reported.
In vitro
apparent
affinity
Although to equal
may be similar
constant only that
receptors,
no direct
of ca.
0.5
Copyright @ 19 73 by Academic Press, Inc. Ail rights of reproduction in any form reserved.
771
the
release
(4-6). that
experiments
of the potency
X lo-'M
have been
acts
Although
the
to be expected
it
thyrotropic to possess
examining
the
of gonadotropic of LRF gives
an
LRF (8).
have been made which
of LRF, several
(TRF)
LRF to the receptors assay
a few analogues
(TSH)
indicates
enough
factor
to initiate
hormone
and some evidence
cells
have been
releasing
membrane
and gonadotropic
close
receptor
synthesized
possess which
potencies competitively
Vol.50;No.3,
1973
BIOCHEMICAL
AND BIOPHYSICAL
antagonize the action of LRF (2) and have either intrinsic
activity.
intrinsic
lower or no detectible
It has been deduced from the biological
that most of the LRF agonistic full
RESEARCH COMMUNICATIONS
activity
analogues have lower affinity
for the LRF receptor,
activity
constants but
while at saturating
concentra-
tions the LRF antagonist5 are unable, or at least only partially activate
a response.
At the level
biological
activity
able, to
of the receptor this would suggest that
all the analogues examined act on the samephysiological This study was carried
data
out to substantiate
data and.to characterize
LRF receptor.
our deduction5 about the
the specificity
of r3H]LRF
binding to the LRP receptor at the membranelevel. MATERIALSANDMETHODS Peptide synthesis The tritiated
luteinizing
hormone releasing factor
[3H-Prog]LRF was The
synthesized by solid-phase methodology on a benzhydrylamine resin. general synthetic
approach and purification
described by Rivier et al. analogues. specific
After
activity
methods used here have been
(9) and Monahan and Rivier
purification
a homogeneousdecapeptide (final
35.6 C/mmole) was obtained;
amino acid ratio
(10) for LRF and radioactive
it possessed the correct
for LRF. Peptides were stored frozen in dilute
acetic
acid. Biological
potencies of LRF, labelled LRF and LRF analogues were
determined in vivo and in vitro. activity
based on the quantitation
Anterior
pituitary
Pituitary (8).
After
addition
of
[3H-Prog]LRP had maximal biological of radioactivity
and amino acid content.
cell5
cells were dispersed and prepared as reported by Vale et al. several day5 in culture 10m3M
the cell5 were removed from the dish by
EDTA in Hepes buffer with glucose (5 minutes) followed by
gentle scraping of the dish with a rubber policeman. [3H]LRF binding The experiments were carried out essentially 772
as those reported for
BIOCHEMICAL
Vol. 50, No. 3,1973
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure 1. Binding curve of [3H-Prog]LRF to dispersed cultured normal rat Non-competible binding was controlled by addition of pituitary cells. excess (1 mM) LRF to the incubation mixture.
[3H]TRF binding (4). filter
Two saline washes of the incubation mixture on the
were used to reduce the non-specific
established by the addition of a final
binding.
Background was
concentration
of 10% LRF. Filtra-
tion of whole cell preparations was carried out using only WhatmanGF/c filters
as aromatic, hydrophobic peptides adsorb to cellulose nitrate
filters
used previously
in the assay of TRF binding sites
tions were carried out at 0.2 ml final
(4, 5).
volume in Hepes buffer
Incuba-
(8).
RESULTSANDDISCUSSION Analogous to the binding kinetics their
cellular
receptors
(Q.,
[3H]LRF binds to two distinct has an affinity
TRF (ll), sites
of a number of peptide hormones to oxytocin
(Figure la).
close to the determined biological
(12) and insulin
One [%I]LRF binding site activity
ca. 2 X lo-'M LRF; the other has a much lower affinity but a higher capacity
to bind [$]LRF.
The role,
(13)),
constant of
(ca. 2 X 10'8M LRF)
if any, of a low affinity
Vol. 50, No. 3, 1973
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I I
I
1 IO COMPETITOR
I 100
CONCENTRATION
(ycg)
Competition curves of LRF and LRF analogues for the binding of to the low affinity, high capacity, non-specific binding site. Percent biological potent of each analogue is iven in parentheses A. LRF (100) B. [OMe-Tyr3 ILRF (35) C. des-Arg B-LRF (< 10e4) D. des-
site in the activation to its high capacity,
of the secretion rate of LH and FSHis unknown; due its
presence on the cells renders the examination of
the second, high affinity,
apparently
physiological,
receptor technically
very difficult.
In preliminary
the low affinity
site it was possible to show that although this site has
the ability
to recognize [3H]LRF with somedegree of preference,
not show the same specificity (8).
experiments examining the specificity
characteristics
as the physiological
Although TRF does not compete with r3H]LRF for binding,
of
it does receptor
high activity
analogues (such as [OMe-Tyr5]LRF (35% potency of LRF) compete for r3H]LRF binding with a lower than expected affinity LRF derivatives
and someessentially
inactive
such as des-Arg8-LRF (<.OOOl%potency of LRF) compete to an
equal degree (1) for this high capacity site suggest that the dispersed pituitary
(Figure 2).
cells possess a site
These observations (affinity
constant
2 X lo-8M LRF) for binding LRF related peptides, but that this site is not 774
Vol. 50; No. 3, 1973
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3H-LRF
(MX
IO-‘)
Figure 3. Binding curve of [31GProg]LRF to the high affinity site in the absence (A. A-A) and presence (B. o----o) of the des-Arg*-LRP analogue (1.5 mM).
the physiological
LRF binding
affinity
and lack
of specificity.
reported
for
neoplastic but
the
low affinity
pituitary
to a degree
addition
titration analogues. absence
which
site
affinity
of excess
Figure
site
of
which
3 shows
contrast
altered
by strenuous
affinity, curve
demonstrating
775
close
that
to that
by saturating
the
binding
t3H]LRF
and
(11).
was accomplished
examining
of
analysis
qualitatively
[%I]LRP
normal specificities
constant
The saturation
low LRF the observations
in both
slightly
and then
its
with
binding
was examined
a binding
of 1.5 mM des-Arg*-LRF,
[3I]TRF
from both
has an affinity
site.
high
in
demonstrable
des-Arg8-LRF
residual
is
indicated
experiments
low
of the
as concluded This
was only
binding
in secretion
the non-specific, the
cells
which
The [3HlLRF obtained
site
LRF binding inactive
competitive
by various in
by
the presence
the kinetic
LRF and
parameters
of
Vol. 50, No. $1973
Table
1.
BIOCHEMICAL
Competition
pituitary
for
cells
in
AN0
BIOPHYSICAL RESEARCH COMMUNICATIONS
the binding
of
the presence
[3H]LRF
to normal
rat
of 1.5 mM des-Arg*-LRF.
Treatmentb
cpm [3H]LRFa
None (21)
bound
+ S.E.M.
1007
f
28
30 ng LRF (6)
820
f
39
100 ng LRF (6)
799
+
50
300 ng LRF (6)
807
f
18
1 ug LRF (5)
651
f
38
100 ng LRF (3)
611
k
51
758
f
29
688
k
34
662
f
36
855
i
80
756
f
53
619
zk
21
797
f
100
680
-+
53
10 pg des-His'-LRF
(6)
100 ng des-His'-LRF
(6)
1 mg des-His2-LRF
(6)
10 ug [Gly21LRF
(3)
100 ng [Gly2]LRF
(3)
1 mg [Gly2]LRF
(3)
100 ng [OMe-Tyr5]LRF
(3)
1 ug [OMe-Tyr5]LRF aFinal b(
concentration ) = number
the binding presence binding
of the
tion order
of 1 X lo-*M
of replicates
to this
high
inactive
of a number
two antagonistic binding
(3)
above background curves
indicate
of magnitude
per
affinity
treatment.
r3H]LRF binding Table
LRF analogue.
of high
peptides.
[3~l~~~.
and low Although
activity
competition as the affinity
for
r3H]LRF constants
‘7’76
are
1 shows data LRF agonist
the marginal
makes quantitation
site
level
virtually binding ascertained
unaffected
by the
on the
competitive
analogues
and also
of competible impossible,
at levels
concentraof the
biologically.
same
BIOCHEMICAL
Vol. 50, No. 3,1973
These
data
substantiate
antagonistic
LRF peptides
common binding
sites
The dispersed experiments detected having
sites
analogues The second
site
having
anterior
of ca.
to the known
between
for
used in these
(3H]LRF.
1 X 18'M
of these
to the
constant
activities
(2 X 10%)
and inactive
LRF receptor
LRF and a specificity
activities
binding
One of the
of the physiological
relevance
active
and
of LH and FSH via
cells
sites
biological
affinity
the agonistic
rate
pituitary
the parameters
constant
both
secretion
binding
has no apparent
to distinguish
for analogues.
of the
and lacking
LRF derivatives,
LRF
releasing
an ability
but
able
to
them from TRF. The binding
only
rat
that
fashion.
two distinct
a lower
the
competitive
possesses
similar
discern
in
possess
(2)
conclusions
manipulate
normal
an affinity
factor
our
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of
LRF agonists
equivalent
i3H]LRF
but
to their
to the high
also
known
the
affinity
two reported
inhibitory
site
is
competible
LRF antagonists
by not
at concentrations
activities.
ACKNOWLEDGEMENTS We would A. Nussey, (Contract
like
to acknowledge
the technical
expertise
C. Otto
and J. White.
This
is
No. AID/csd
2785),
the Ford
research Foundation
supported
of W. Hewitt, by AID
and the Rockefeller
Foundation. REFERENCES 1. 2. 3. 4. 5. 6. 7.
Vale, W., G. Grant and R. Guillemin, in kin 1973, L. Martini and W. Ganong (eds.), Oxford University Press, New York, 1973, in press. Vale, W., G. Grant, 3. Rivier, M. Monahan, M. Amoss, R. Blackwell, R. Burgus and R. Guillemin, Science, 176, 933, 1972. McCann, S., in Frontiers in Neuroendocrinology, L. Martini and W. Ganong (eds.), Oxford University Press, New York, 1971, p. 209. Grant, G., W. Vale and R. Guillemin, Biochem. Biophys. Res. Commun., 66, 28, 1972. Labrie, F., N. Barden, G. Poirier and A. DeLean, Proc. Nat. Acad. Sci. &A, tY& 283, 1972. Guillemin, R., R. Burgus and W. Vale, in Vitamins and Hormones, 29, P. Munson (ed.), Academic Press, New York, 1971, p. 1. Grant, G. and W. Vale, Nature (New Biology), 237, 182, 1972.
777
Vol. 50, No. 3, 1973
8. 9. 10. 11. 12. 13.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vale, W., G. Grant, El. Amoss, R. Blackwell and R. Guillemin, Endocrinology, 9l, 562, 1972. Rivier, J., IL Monahan, W. Vale, G. Grant, M. Amoss, R. Blackwell, R. Guille& and R. Burgus, Chimia, 2, 300, 1972. Monahan, M. and J. Rivier, Biochem. Biophys. Res. Commun.,48, 1100, 1912. Grant, G., W. Vale and R. Guillemin, Endocrinology, submitted for publication. Borkaert, J., M. Imhert, S. Jard and F. Morel, Molecular Pharm., 8, 230, 1972. Freychet, P., in Proceedings of the IVth International Congress of Endocrinology, Excerpta Medica, Amsterdam, in press.
778
Vol. 50; No. 3,1973
PITUITARY
BINDING SITES FOR [3H]-LABELLED
LUTEINIZING
HORMONE RELEASING FACTOR (LRF).
G. Grant, The Salk
Received
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
W. Vale
Institute,
December
and .I. Rivier
La Jolla,
18,
California
92037
1972
pituitary cells in culture possess two SUMMARY : Normal rat anterior One is a high affinity (2 X lO"M), low capacity binding sites for [3H]LRF. site which corresponds to the half-maximal biological potency of LRF. The second site has low affinity (2 X 10%) and an enormously higher capacity to bind LRF. This second site shows only partial specificity in that inof [3~l~~~. The active LRF-analogues, although not TRF, compete for binding high affinity site is competible by LRF, LRF-agonists and LRF-antagonists even in the presence of an excess of an inactive LRF-analogue which saturates the low affinity binding site. The interaction with
respect
various
of LRF with
to the biological
synthetic
pituitary
cells
of luteinizing
(FSH)
pituitary
potencies
LRF analogues
gonadotropic
release
its
(1, is
hormone
has been
and intrinsic
2).
The effect
an integrated
activities
of
of an LRF peptide
process
(LH) and follicle
discussed
resulting
in
stimulating
on the
hormone
(3).
It at the
has been level
mechanism
established
that
of the pituitary
of stored
thyroid
has been postulated
(7)
thyrotropin
plasma stimulating
phylogenetically
related
characteristics
of binding
of labelled
cells
reported.
In vitro
apparent
affinity
Although to equal
may be similar
constant only that
receptors,
no direct
of ca.
0.5
Copyright @ 19 73 by Academic Press, Inc. Ail rights of reproduction in any form reserved.
771
the
release
(4-6). that
experiments
of the potency
X lo-'M
have been
acts
Although
the
to be expected
it
thyrotropic to possess
examining
the
of gonadotropic of LRF gives
an
LRF (8).
have been made which
of LRF, several
(TRF)
LRF to the receptors assay
a few analogues
(TSH)
indicates
enough
factor
to initiate
hormone
and some evidence
cells
have been
releasing
membrane
and gonadotropic
close
receptor
synthesized
possess which
potencies competitively
Vol.50;No.3,
1973
BIOCHEMICAL
AND BIOPHYSICAL
antagonize the action of LRF (2) and have either intrinsic
activity.
intrinsic
lower or no detectible
It has been deduced from the biological
that most of the LRF agonistic full
RESEARCH COMMUNICATIONS
activity
analogues have lower affinity
for the LRF receptor,
activity
constants but
while at saturating
concentra-
tions the LRF antagonist5 are unable, or at least only partially activate
a response.
At the level
biological
activity
able, to
of the receptor this would suggest that
all the analogues examined act on the samephysiological This study was carried
data
out to substantiate
data and.to characterize
LRF receptor.
our deduction5 about the
the specificity
of r3H]LRF
binding to the LRP receptor at the membranelevel. MATERIALSANDMETHODS Peptide synthesis The tritiated
luteinizing
hormone releasing factor
[3H-Prog]LRF was The
synthesized by solid-phase methodology on a benzhydrylamine resin. general synthetic
approach and purification
described by Rivier et al. analogues. specific
After
activity
methods used here have been
(9) and Monahan and Rivier
purification
a homogeneousdecapeptide (final
35.6 C/mmole) was obtained;
amino acid ratio
(10) for LRF and radioactive
it possessed the correct
for LRF. Peptides were stored frozen in dilute
acetic
acid. Biological
potencies of LRF, labelled LRF and LRF analogues were
determined in vivo and in vitro. activity
based on the quantitation
Anterior
pituitary
Pituitary (8).
After
addition
of
[3H-Prog]LRP had maximal biological of radioactivity
and amino acid content.
cell5
cells were dispersed and prepared as reported by Vale et al. several day5 in culture 10m3M
the cell5 were removed from the dish by
EDTA in Hepes buffer with glucose (5 minutes) followed by
gentle scraping of the dish with a rubber policeman. [3H]LRF binding The experiments were carried out essentially 772
as those reported for
BIOCHEMICAL
Vol. 50, No. 3,1973
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure 1. Binding curve of [3H-Prog]LRF to dispersed cultured normal rat Non-competible binding was controlled by addition of pituitary cells. excess (1 mM) LRF to the incubation mixture.
[3H]TRF binding (4). filter
Two saline washes of the incubation mixture on the
were used to reduce the non-specific
established by the addition of a final
binding.
Background was
concentration
of 10% LRF. Filtra-
tion of whole cell preparations was carried out using only WhatmanGF/c filters
as aromatic, hydrophobic peptides adsorb to cellulose nitrate
filters
used previously
in the assay of TRF binding sites
tions were carried out at 0.2 ml final
(4, 5).
volume in Hepes buffer
Incuba-
(8).
RESULTSANDDISCUSSION Analogous to the binding kinetics their
cellular
receptors
(Q.,
[3H]LRF binds to two distinct has an affinity
TRF (ll), sites
of a number of peptide hormones to oxytocin
(Figure la).
close to the determined biological
(12) and insulin
One [%I]LRF binding site activity
ca. 2 X lo-'M LRF; the other has a much lower affinity but a higher capacity
to bind [$]LRF.
The role,
(13)),
constant of
(ca. 2 X 10'8M LRF)
if any, of a low affinity
Vol. 50, No. 3, 1973
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I I
I
1 IO COMPETITOR
I 100
CONCENTRATION
(ycg)
Competition curves of LRF and LRF analogues for the binding of to the low affinity, high capacity, non-specific binding site. Percent biological potent of each analogue is iven in parentheses A. LRF (100) B. [OMe-Tyr3 ILRF (35) C. des-Arg B-LRF (< 10e4) D. des-
site in the activation to its high capacity,
of the secretion rate of LH and FSHis unknown; due its
presence on the cells renders the examination of
the second, high affinity,
apparently
physiological,
receptor technically
very difficult.
In preliminary
the low affinity
site it was possible to show that although this site has
the ability
to recognize [3H]LRF with somedegree of preference,
not show the same specificity (8).
experiments examining the specificity
characteristics
as the physiological
Although TRF does not compete with r3H]LRF for binding,
of
it does receptor
high activity
analogues (such as [OMe-Tyr5]LRF (35% potency of LRF) compete for r3H]LRF binding with a lower than expected affinity LRF derivatives
and someessentially
inactive
such as des-Arg8-LRF (<.OOOl%potency of LRF) compete to an
equal degree (1) for this high capacity site suggest that the dispersed pituitary
(Figure 2).
cells possess a site
These observations (affinity
constant
2 X lo-8M LRF) for binding LRF related peptides, but that this site is not 774
Vol. 50; No. 3, 1973
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3H-LRF
(MX
IO-‘)
Figure 3. Binding curve of [31GProg]LRF to the high affinity site in the absence (A. A-A) and presence (B. o----o) of the des-Arg*-LRP analogue (1.5 mM).
the physiological
LRF binding
affinity
and lack
of specificity.
reported
for
neoplastic but
the
low affinity
pituitary
to a degree
addition
titration analogues. absence
which
site
affinity
of excess
Figure
site
of
which
3 shows
contrast
altered
by strenuous
affinity, curve
demonstrating
775
close
that
to that
by saturating
the
binding
t3H]LRF
and
(11).
was accomplished
examining
of
analysis
qualitatively
[%I]LRP
normal specificities
constant
The saturation
low LRF the observations
in both
slightly
and then
its
with
binding
was examined
a binding
of 1.5 mM des-Arg*-LRF,
[3I]TRF
from both
has an affinity
site.
high
in
demonstrable
des-Arg8-LRF
residual
is
indicated
experiments
low
of the
as concluded This
was only
binding
in secretion
the non-specific, the
cells
which
The [3HlLRF obtained
site
LRF binding inactive
competitive
by various in
by
the presence
the kinetic
LRF and
parameters
of
Vol. 50, No. $1973
Table
1.
BIOCHEMICAL
Competition
pituitary
for
cells
in
AN0
BIOPHYSICAL RESEARCH COMMUNICATIONS
the binding
of
the presence
[3H]LRF
to normal
rat
of 1.5 mM des-Arg*-LRF.
Treatmentb
cpm [3H]LRFa
None (21)
bound
+ S.E.M.
1007
f
28
30 ng LRF (6)
820
f
39
100 ng LRF (6)
799
+
50
300 ng LRF (6)
807
f
18
1 ug LRF (5)
651
f
38
100 ng LRF (3)
611
k
51
758
f
29
688
k
34
662
f
36
855
i
80
756
f
53
619
zk
21
797
f
100
680
-+
53
10 pg des-His'-LRF
(6)
100 ng des-His'-LRF
(6)
1 mg des-His2-LRF
(6)
10 ug [Gly21LRF
(3)
100 ng [Gly2]LRF
(3)
1 mg [Gly2]LRF
(3)
100 ng [OMe-Tyr5]LRF
(3)
1 ug [OMe-Tyr5]LRF aFinal b(
concentration ) = number
the binding presence binding
of the
tion order
of 1 X lo-*M
of replicates
to this
high
inactive
of a number
two antagonistic binding
(3)
above background curves
indicate
of magnitude
per
affinity
treatment.
r3H]LRF binding Table
LRF analogue.
of high
peptides.
[3~l~~~.
and low Although
activity
competition as the affinity
for
r3H]LRF constants
‘7’76
are
1 shows data LRF agonist
the marginal
makes quantitation
site
level
virtually binding ascertained
unaffected
by the
on the
competitive
analogues
and also
of competible impossible,
at levels
concentraof the
biologically.
same
BIOCHEMICAL
Vol. 50, No. 3,1973
These
data
substantiate
antagonistic
LRF peptides
common binding
sites
The dispersed experiments detected having
sites
analogues The second
site
having
anterior
of ca.
to the known
between
for
used in these
(3H]LRF.
1 X 18'M
of these
to the
constant
activities
(2 X 10%)
and inactive
LRF receptor
LRF and a specificity
activities
binding
One of the
of the physiological
relevance
active
and
of LH and FSH via
cells
sites
biological
affinity
the agonistic
rate
pituitary
the parameters
constant
both
secretion
binding
has no apparent
to distinguish
for analogues.
of the
and lacking
LRF derivatives,
LRF
releasing
an ability
but
able
to
them from TRF. The binding
only
rat
that
fashion.
two distinct
a lower
the
competitive
possesses
similar
discern
in
possess
(2)
conclusions
manipulate
normal
an affinity
factor
our
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of
LRF agonists
equivalent
i3H]LRF
but
to their
to the high
also
known
the
affinity
two reported
inhibitory
site
is
competible
LRF antagonists
by not
at concentrations
activities.
ACKNOWLEDGEMENTS We would A. Nussey, (Contract
like
to acknowledge
the technical
expertise
C. Otto
and J. White.
This
is
No. AID/csd
2785),
the Ford
research Foundation
supported
of W. Hewitt, by AID
and the Rockefeller
Foundation. REFERENCES 1. 2. 3. 4. 5. 6. 7.
Vale, W., G. Grant and R. Guillemin, in kin 1973, L. Martini and W. Ganong (eds.), Oxford University Press, New York, 1973, in press. Vale, W., G. Grant, 3. Rivier, M. Monahan, M. Amoss, R. Blackwell, R. Burgus and R. Guillemin, Science, 176, 933, 1972. McCann, S., in Frontiers in Neuroendocrinology, L. Martini and W. Ganong (eds.), Oxford University Press, New York, 1971, p. 209. Grant, G., W. Vale and R. Guillemin, Biochem. Biophys. Res. Commun., 66, 28, 1972. Labrie, F., N. Barden, G. Poirier and A. DeLean, Proc. Nat. Acad. Sci. &A, tY& 283, 1972. Guillemin, R., R. Burgus and W. Vale, in Vitamins and Hormones, 29, P. Munson (ed.), Academic Press, New York, 1971, p. 1. Grant, G. and W. Vale, Nature (New Biology), 237, 182, 1972.
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8. 9. 10. 11. 12. 13.
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Vale, W., G. Grant, El. Amoss, R. Blackwell and R. Guillemin, Endocrinology, 9l, 562, 1972. Rivier, J., IL Monahan, W. Vale, G. Grant, M. Amoss, R. Blackwell, R. Guille& and R. Burgus, Chimia, 2, 300, 1972. Monahan, M. and J. Rivier, Biochem. Biophys. Res. Commun.,48, 1100, 1912. Grant, G., W. Vale and R. Guillemin, Endocrinology, submitted for publication. Borkaert, J., M. Imhert, S. Jard and F. Morel, Molecular Pharm., 8, 230, 1972. Freychet, P., in Proceedings of the IVth International Congress of Endocrinology, Excerpta Medica, Amsterdam, in press.
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