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Synthesis and biological activities of pseudopeptide analogues of LH-RH: Agonists and antagonists
Vol.
97, No.
3, 1980
December
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Pages 1014-1023
16, 1980
SYNTHESISAND BIOLOGICALACTIVITIES OF PSEUDOPEPTIDE ANALOGUES OF LH-Ml: AGONISTSANDANTAGONISTS
F. Spatola: Nirankar S. Agarwal, Anthony L. Bettag, and John A. Yankeelov, Jr.?; Departments of Chemistry and Biochemistry, University of Louisville, Louisville, KY 40292 Arno
and
Cyril
Y. Bowers, Tulane University School of Medicine New Orleans, Louisiana 70112 and
Wylie W. Vale< The Salk Institute, Neuroendocrinology Laboratory, LaJolla, California Received
September
92037
22,198O
Sulrullary
Using solid phase methods, seven agonist and antagonist analogues of LH-RH have been prepared containing enzyme-resistant CH2Slinkages as selected amide bond replacements. Agonists modified at the S-6, 6-7 and 9-10 of LH-RH, respectively. position had 2, < 0.1, and 10% of the in vitro activity Amongpotential antagonists, 6-7 posit%xogues showedonly minimal inhibitory activity but N- and C-terminal modified analogues retained substantial LH-RH-LHand FSH inhibitory activity. In addition, a l-2 osition methylene thioether analogue of the parent [Ac-Prol, D-Phe2, D-Trp 3*i]LH-BH antagonist was completely inhibitory at 30 ng -in vitro and represents the first such structure-modification that may be at least as active as its corresponding amide linked congener. However, neither l-2 nor 9-10 methylene thioether position antagonists showed--in vivo antiovulatory activity at the 250 pg level. * To whomcorrespondence should be addressed. +
Deceased, April
** Abbreviations follicle
6, 1979.
used:
stimulating
LH-RH,
TFA,
sulfonyl;
hormone-releasing hormone; FSH,
hormone, LH, luteinizing
Cbz, benzyloxycarbonyl; amine;
luteinizing
DCC, dicyclohexylcarbodimide;
trifluoroacctic
Bzl, bcnzyl;
hormone, Boc, t-butyloxycarbonyl,
acid;
DMF, dimcthylformamidc;
pGlu, pyroglutamyl;
HPLC, high pressure liquid
DIEA, diisopropylethyl
thiomethylone
ether
p-tolucnc
t lc, thin layer chromatography;
chromatography; TEAP (Triethylammonium phosphate) ;
J, refers to the replacement of the normal amide linkage, the
Tos,
moiety,
OOOS-2glX/80/231014-10$01.00/O Copyright 0 1980 by Academic Press, Inc. All rights of reproduction in any form reserved.
[CH2S].
1014
[CONH]
by
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
INTRODUCTION
Both
LH-RU
agents
superagonists
by virtue
bioactivity
of their
would
antiovulatory
that
prove
use of the link
resistant
ether
LH-Rlt as established position
potent
subjected
to this
pseudopeptide
selective
Boc-Protected followed Also,
chosen
the
bond
for
suitable
surrogate)
of each of these solid
described
Koch -L’ et al
(3)
JLH-RH
inhibitory
of but
other
to LH-RH based (4) have
also
been
of synthesizing activity. I
of the
three
methods
routes
elsewhere
for (7).
first
acids).
of the
amide
into
prepared prepared
psoudodipcptides
amino
analogues
the it
Boc-X J, Cly type
varieties
phase
contains
were
WC have prcparcd chiral
of these
to incorporate
(7)
has been first bond replacement
the pcptidc.
Tho
by Yankoelov
-ct --al
p (5)
by Spatola
ct al.,
(6).
of the
X$Y
typo
The procedure
pseudodipeptides
has been described
MATERIALS Synthetic
Our major
bonds
the objective
long-lasting
synthesis
GlyJIX,
X and Y represent
by standard
with
which
and then
by dipeptides then
the
dipeptide
dipeptides,
since
D-Trp3’6
amide
D-pGlu-D-Phe-D-Trp-Ser-Tyr-D-Trp-Leu-Arg-Pro-GlyNH2
The strategy
(amide
have
(I).
Antagonists
the
the
6-7 and 9-10
and by
synthesized.
analogucs
for
LH-RH structure
(2)
D-Phe’,
peptide
we have examined
of the
modification that
to prepare
candidates
pGlu-His-Trp-Ser-Tyr-Gly-Leu-Arg-Pro-GlyNH2
LH-RH’ Antagonist
to prepare
been
[D-pGlu’,
analogues
LH- RH
lability
Prolonged
useful
as a replacement
the
and Stern
have also
inhibitor
[CH2S]
(1).
for
degradation,
within
known
by Marks
analogues
on the
moiety
positions by the
corequisite
In an effort
to enzymatic
thiomethylene
as antifertility
of LH and FSH release
activity.
was predicated
have potential
to be a necessary
[CUNH] in critical
focus
both
inhibition
appear
possessing would
and antagonists
into
for
(whcrc incorporation
the peptides
in the present
study.
AND METHODS
the pseudodipeptides The incorporation
1015
used of the
in this Boc-protected
study
have been derivatives
Vol.
97, No.
BIOCHEMICAL
3, 1980
Table
I
AND
Methodology
BIOPHYSICAL
For Solid
Time (Min)
1
CH2Cl*
L
TFA/anisole/CH2C12
3
CH2Cl *
4
DlEA/CH2c12
b
CH2C12
b
k&-amino
7
DCC/CH2C12 (2.5 equiv.)a
gob
s
CI12C12 (3x)
1
9
wx1
1
1
(3x1 (40:2:51)
(10: 90) (2x)
1
acid/CH2C12
(2.5 equiv.)”
of 2-12 hr. each for
into
peptides
laboratory.
Table
synthesis;
chiral
specified.
Side (Ser
amino chain
Vega Biochemicals,
acids
Bachem,
1% cross-linked
or
were
dipeptides,
although
catalyzed
deprotections,
Peptides
necessary
were
hydrogen
fluoride
30 min.
at O” C. G-15 using
are of the
in the
scavengers
from
containing The extracted
used
employed
for
used
were
amino
acids
polymers
extent
(0.4-0.5
products
25% or 30% HOAc.
1016
where
[Arg
and His)
purchased
lyophilized
pcptidc otherwise and
from resins
Boc-Glycine
or the No unusual
Boc-pseudo-
employed
and amino
and 10% ethyl
The major
phase
except
involving
by treatment
were
solid
mmol/g.
were
cleavage
resins
in our
meq. nitrogen/g)
with
antioxidants
10% anisole
were
reactions
fluoride the
tosyl
of 0.15-0.35
coupling
Boc-pscudodipcptidcs.
Benzhydrylamine
(DCC mediated)
and/or
hydrogen
cleaved
methods
Beckman Biochemicals.
to the
for
Boc-pseudodipcptides.
L-configuration
groups
condensed
pseudodipeptide
Gquivalents
methodology
polystyrene
Biochemicals,
3.0
standard
Common protected
precautions
Sephadex
the
protecting
and Tyr).
Beckman
follows
I describes
-
(3x)
by two couplings
LH-RH
2-10
(3x)
Substituted
to
25
1
b.
related
5 and
(5x1
of 1.5 thru
Boc-ProJIGly
Synthesis
IkilgL!nt
by two couplings
from
COMMUNICATIONS
9
Substituted
used wcrc
Psptide
Phase
il.
bcnzyl
RESEARCH
during
acid
hydrolyses.
with
anhydrous
methyl
sulfide
and desalted
peak was collected,
acid-
for over lyophilized
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 97, No. 3, 1980
and purified
by gel
reversed
phase
columns,
employing
liquid
and monitoring to remove tic
chromatography methanol/ammonium
HF’LC employing
and monitoring
separable integrating
purity
rats.
Zorbax
gradiont
acid
solvent
showed
the
analysis
all
resulting
including
(Table
weakly
products
amino
acid
of the
of the
rcpcatcdly
techniques
III),
absorbing free
via
Model
3837
conditions
pseudodipeptide
units
of the pseudodipeptide
partial
enzymatic
fragments
Details
impurities.
of HPLC-
hydrolysis
and position
and gradient
on a Hewlett-Packard
confirmed
systems
lyophilizcd
any possible
were
C-18
phosphatc/acetonitrile
were
The LH and FSH agonist
over
peptides
of nanograms
and NIAMDD rat The second dissociated
tests
via -
of the
rat
hemipituitaries
degradation,
chemical
latter
procedure
will
of the
Lh-LER-1240-2
standards (2.1
x NIH-FSH-Sl
--in vitro
system
anterior
pituitary
release
of luteinizing
of LH-RH was the basis
Values (0.60
cell
(91.
Multiple
tested rates
(8).
Sprague-
were
and adding
primary
cells
secretion
female
were
dctcrmincd
LH-RH and calculated
NIH-LH-Sl
in
(units/mg)
units/mg.).
utilized
were
old
systems.
activities
solution
elsewhere
hormone the
and antagonist
6 h as described
FSH RP-1
in two distinct
of 20-day
in Ringers
and an LH-RH standard
luteinizing
performed
the use of hemipituitaries
test
concentration
amino
analyses.
biological
the
to inhibit
using
by standard
The presence
and III
850)
elsewhere.
by incubating
the
II
and analysis
involved
peptides
II),
was by semi-prcparativc
was collected,
rearrangement)
mass spectrometric
The first
terms
peak
cases,
products.
The --in vitro
Dawley
buffer
procedure
apparent
compounds
be reported
acetate
and analyzed
In several
to ninhydrin-negative
ionization
Model
to > 95% as monitored
(through
derivatization,
(DuPont
a triethylammonium
by this
recorder. loss
purification
at 210 nm to detect
impurities
in
salt,
x, y, and z (Table
The analytical
units
The major
ammonium acetate
by analytical
caused
The final
at 254 nm.
on solvents
system
filtration.
for
their
by these hormone
of the
1017
cells.
stimulated antagonist
cultures dose abilities
of enzymatically levels
of pseudo-
to increase
The ability
of analogues
by a constant assay,
where
[D-pClu’,
[Tyr
(Pro$G1ySHZ
[DpGlu’,D-Phe*,
III
I\
v
D-Phe’.
HPLC
Tic
b.
System:
Solvent Systems: (7:3). :I EtOH:H,O
Solvent
LH-RH
[Ac-Pro$D-Phel-*,
x,
C.
A. B.
II.
Properties
HI’LC
of
C
C
B
B
System=Ret
Synthetic
14.7
12.0
10.7
12.9
l-7.0
11.9
12.7
‘II
HPLC
Lti-RH
9.05
(15:3:1?:10);
Triethylammonium Triethylammonium Triethylammonium
Solvent
n-bu011:H0,\c:t!20:I~)‘ridi~~c
Acetonitrile/O.ZSN Acetonitrile/O.ZSW Acetonitrile/O.2W
D-T~P~‘~]
D-Trp3’6
D-Trp3,
Pro $ G1ySH2’-“]LH-RH
[D-pGlu’,
D-Ser
D-Trp3,
$J Leu6-7]LH-RH
Gly $ Leu6-7]LH-RH
[D-pGlu’,D-Phe*,
a.
VIII
VII
VI
JI ClysV6]LH-RH
[Cly
II
‘-“]LH-RH
$J Leu6-‘]LH-RH
LH-RH
I
Peptide
Table
(MN)
y.
pH 3.5; pH 3.5; pH 3.5;
0.64
0.60
0.56
0.57
0.42
0.52
0.43
0.24
Rf*
r,-euotl:I!Or\c:EtO-\c:l120
phosphate; phosphate; phosphate;
Time
.Xnalogues.
12-25: 20-30cr 25-508
0.64
0.66
0.53
0.56
0.44
0.50
0.39
0.33
RfY
0.67
0.6s
0.60
0.61
Rf
(1:l:l:lj;
gradient gradient gradient
TLCb
min)
min) min)
(15
(15 (25
Vol.
97, No.
3, 1980
BIOCHEMICAL
'lablc
Structure
Clu
As&lo-acid
111.
Phc
AND
BIOPHYSICAL
Analysis Ratios Amino Acid Ratios
Trp
His
Ser
Tyr
ClY
0.97
1.04
RESEARCH
of Ui-IU
COMMUNICATIONS
AIldOgS
Lou
An?
h-0
0.87
1.13
1.02
a,b
Other
NU.
II
1.00
0.84
0.81
0.91
III
0.96:
0.81
0.91
0.78
IV
0.99
0.83
1.02
1.00
L
u.L)o
0.93
0.90
1.04
1.00
1.03
1.02
1.08
1.00
1.03
0.90
0.92
1.01
K.U. Tyr IJ(;I;/ N.D. Pro v tily 1.06
1.05
0.94
Cly0 VI
0.99
c
0.76
0.89
1.02
VI-1
1.05
1.10
1.64
0.92
1.03
Vlll
1.76
a.
Incorporated Pseudodipeptide
11.
N.D.
c.
U-&r
0.82
1.00
0.96 0.96
1.00
0.98
1.02
c N.D. Pro
0.90
1.10
0.94
0.99
Lcu
li, Lcu
+ Phc
due to low ninhydrin 1.89,
-
amino-acids
Cly
N.D. Pro
= not dotcrmincd
Q
0 D-NW
response
peaks are virtually
suporimposoblc.
D-Phe*, D-Trp 3'6]LH-RH was used as a standard and arbitrarily
assigned a
potency of 1. Antiovulatory
assays were carried
Worcester, Mass., using dissolved in corn oil the ova were counted
female
Sprague-Dawley
and injected the
next
out at the Mason Research Institute, rats.
The peptides were
subcutaneously on noon of proestrus
and
morning.
RESULTSAND DISCUSSION As
shown in Table IV, LH-RHanalogues whose only structural
involved biological III
amide
bond
activities.
variations
replacements at 5-6, 6-7 and 9-10 displayed widely divergent Though none were as active
as LH-RH, LH-RHpseudopcptides
and IV with amide bond replacements at 5-6 or 9-10 were l-2 orders of
magnitude more active containing
with respect to LH and FSHrelease than
a 6-7 modified linkage.
to be the most susceptible
Since the 6-7 linkage
the
has been
analogue shown
site of degradation of the LH-RHmoleculL1*.3!
1019
Vol.
97, No.
3, 1980
BIOCHEMICAL
TABLE IV.
AND
--IN VITRO AGONIST A"WITY
Pseudopeptide
[Gly$
Analogue
Ln-RH nglrnl of medium
P
A.ng/nl of medium
SEM 4)
P
3 450 5 187 849
5 23 3 44 198
"S .Ol ,001
470 7856 304 5562 9332
133 1462 87 648 981
ns .OOl ,001
29 1057 595 1256 .1607
15 148 74 105
. 001 ,001
179 5840 4487 8364 12846
33 607 702 829 1106
. 001 .OOl ,001
407 -6 25
49 11 14 8
.OOl ,001 ,001
5627 -155 -26 1966
281 112 240
.OOl ,001
282
,001
Leu6-711mH 0.6
0.6 30 100 1000
rlGlyWl2
g-'o]LH-pJ
0.6
0.6
6 60 aAs determined b As determined
the above conformat for
incubations
in pituitary
cell
results
change.
contains
insertion
- See experimental
culture
suggest
ional
LbRI1
thus,
by hemipituitary
vs.
standard
that
the
Perhaps
a bend or of the
of a preferred
low energy
than
bond.
While
by the
equipotent
the
amide
been ruled some type activity
out
of bend found
additional
in the (Table
now-modified with
which
the
the
it
may more readily
in the --in vitro
6-7 amide
bond proved
at
link
junction
(lo),
acids
is the
greater
seems possible activity
of the
antagonist
to substitution
1020
content
LH-FUI analogue of
(11).
residual
1 and 10 (12). overall
An
lipophilicity
by HPLC retontion
more readily phase
the
seems to have
in view
amino
reversed
interact
and,
is more flexible
position
this
folding
lipophilic
intolerant
0.10
Momany model(s)
, as ascertained
II
that
rcsuits
0.02
may have reduced
especially
analogues
structure
proposed
of an NO-Me-Leu7
analogue
to the
greater
se
that
interpretation
bend region
A substantially
w;1s noted
substituted
6-7
site
likely,
analogues among these
6-7
II);
is
c 0.001
an unfavorable
the CHgS substitution
activity
region
cyclic
correlation
observed times
for
per
the
at the
since
a g-turn
induces
that
at this
conformer
in this
is
turn
linkage
Pot*ncyb LH-P&l - 1
section.
6-7 pseudolinkage
hairpin
Relative
section.
- See experimental
pertinent
pseudo
FSI? SEM (*I
[Tyr ~Gly5-61LH-lW
COMMUNICATIONS
OF PSEUDDPEPTIDES RELATED T O LH-FJi
A, w/m1 of medium
100 1000 10000
ho
RESEARCH
LHa
DOS.? Peptide ngJm1 of medium
BIOPHYSICAL
substrate
column
although
dcpcndoncc
of
analogucs even with
the
CX~OSCS
still tho
speculative. pscudopcptidcs
(Table
V).
a 6-D-residue
While
Vol.
97, No.
3, 1980
BIOCHEMICAL
TABLE V.
AND
Peptide ngfm1 of medium
Pnalogue
[D-pG1ul, D-Phe'. D-Trp’, Gly $Leu 6-‘lLN-F.H
[D-pGlu', D-Ser
LAP lx-lw nglml of medium
10 100 1000 10,000
.6 .6 .6 .6 .6
6 450 366 415 380 268
10,000 50,000
.6 .6 .6 .6 .6
7 532 594 553 563 226
23 144 82 108 97 16
10 30 100 1000
.6 .6 .6 .6 .6
-2 636 251 164 19 -20
10 72 31 27 2s 13
-16 526 26 25 9 5
D-Phe', D-Trp' $Leu6-'ILki-PH
D-Phe’, D-Trp3j6 Pro’4 GlytW2 g-'o]&gH
$D-Phel-',
aA~ determined b As determined
D-Trp'%"-RN
VI),
Peptide its
with
parents
is unknown Both assayed
for
administering
124 <.OOl 1462 563 672 803 373
.OS ns ns IIS
ns ns ns .05
127 5339 4265 4600 4988 2081
185 1282 250 542 871 371
ns ns ns .05
.OOl ,001 ,001 .OOl
375 7241 3852 2420 360 -283
207 953 1251 305 287 165
.05 ,001 .OOl ,001
2 e.001 41 10 ,001 24 ,001 5 ,001 11 .OOl
-15 7871 773 386 -23 -117
< 0.001
c 0.001
153 c.001 231 225 ,001 156 ,001 75 .OOl 96 .OOl
0.47
(.30-.71)
0.60
(0.40-1.0)
were
considerably
activity; the least
retained
moreover, [AC-Pro
1-2
in the
LH-IUi suggest bond at l-2 l-2
position
a role
in these
more than
compared
QD-Phe
as active
at the
more expendable. SO%
to the
, D-Trp
3D6]
LH-KH
hemipituitary
assay.
the possible
and 9-10 after
structure
for
importance
agonist
activity.
substitution activity
of relationships
time.
antagonists their
plays
467 7856 4400 7091 7061 5807
substitution
of the peptide
linkage
at this
bonds
structure,
lipophilicity
Relative Poteneyb [DpGlu', D-Phe’, D-Tq3’61ui-Rli = 1
P
section.
of Pro JI G~YNH~‘-~’
function
pseudopeptide
amide
to be at
P
section.
pseudopeptide
linked
SFm (+I
A. nsln1 of medium
6 ~001 23 74 ns 20 ns 53 "S 15 . 001
- see experimental
biological
proved
increased
standard
9-10
and those
carbonyl
Whether
vs.
and 9-10
the
(VIII)
results
of the
l-2
amide
antagonist These
culture
--in vitro
corresponding
the
cell
the
VII
.6 .6 .6 .6 .6 - see experimntal
30 100 1000 10.000 incub%rions
in pituitary
(peptide
of
_
by hemipituitary
COMMUNICATIONS
FSI? SEM ('1
A. w/m1 of medium
[D-pGlu',
[AC-Pro
RESEARCH
--IN VITRO ANTAGONIST ACTIVITY OF PSSUCOPEPTIDES RELATED T O LH-RH. DOW
Pseudopeptide
BIOPHYSICAL
displaying --in vivo
250 ug
substantial
antiovulatory
peptide/animal
in vitro A-
activity on
the
1021
activity
in female
day of proestrus.
were adult
rats
next by
Vol.
97, No.
3, 1980
Surprisingly
BIOCHEMICAL
both of the pseudopeptide
at which
the corresponding
have been fully to determine degradation
active
such findings analogues
are unique
peptide
analogues,
in the tight
antagonists
antagonists
that
even when the replacement
involves
of the replacement the question
terminal
role. positions
can yield
of such substitutions
Appreciation for
support
Karten
for
of this helpful
technical
through
discussions.
Mr. Benjamin Van Osdol, for expert
retention
active
We
injection
of full
for
orally
and this
Ms. Georgeann Reynolds
changes. again
once
in peptides
may have a
at N and C
tends
to support peptide
active
NO l-HD-8-2882
are indebted
potency,
and polarity
or blocking
1022
poor
(in vivo).
biological
steric
analogues
assistance.
are involved
and the possible
to the NIH Contraceptive Contract
modified
the problems
which perhaps
amide replacements
in the search
is expressed work
between
backbone elements
highly
and --in vivo
of amide bonds in LH-RH analogue
as a mode of retarding
by endo- and exopeptidases
between --in vitro
subcutaneous
that
non-
lipophilic
does appear to be critical
The observation
or
preferred
highly
Other
(in vitro)
substantial
as to whether
problem,
whether
to distinguish
the replacement with
is in progress
Work
By the use of suitably
at the LH-RH receptor
suggest
(11).
and to establish
of the analogues
is not incompatible
functional
(14).
after
at dosages
mechanisms,
lack of correlation
of the analogue
Our results
components,
lipophilicity
bending
transportation
by unexpected
it may be possible
and global
assay
to LH-RH pseudopeptides.
of LH-RH analogue
COMMUNICATIONS
amide linkages
may be due to a transport
to extracellular
results
raises
this
have shown a similar
of local
with
RESEARCH
were inactive
in the rat antiovulatory
to what extent
binding
BIOPHYSICAL
analogues
analogues
of the amide surrogates
reversible
‘111~ site
AND
the use
degradation
analogues.
Development
Branch
and to Dr. Marvin
to Mr. Scott
Mack,
and Ms. Karen Von Dessonneck
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
REFERENCES 1.
Vale, W., M. Brown, C. Rivier, M. Perrin and J. Rivier, in Brain A New Endocrinology, A. M. Gotto, Jr., E. F. Peck, Jr. Peptides: and A. E. Boyd, III, Ed., Elsevier, Amsterdam p. 71 (1979).
2.
Marks,
3.
Koch, A. T. Barum, P. Chobsieng, and Commun., 61, 95 (1974).
4.
Rivier,
5.
J. A. Yankeelov, J. A., Jr., Chcm., 43, 1623 (1978).
6.
Spatola, A. F., H. Saneii, K. F. Fok and J. A. Yankeelov, Jr., Chemical Congress, Honolulu, Hawaii, Abstract #18 (1979).
7.
Spatola, A. F., N. S. Agarwal, Jr., in preparation.
8.
Humphries, J., J. P. Wan, K. Folkers and C. Y. Bowers, J. Med. Chem., 2, 120 (1978).
9.
Vale, W., G. Grant, 91, 562 (1972).
N. and F. Stern,
Biochem. Biophys. Res. Commun.,3,
J. and W. Vale, Life Sci.,
M.
M.
2,
Fridkin,
Biochem. Biophys. Rcs.
869 (1978).
K. F. Fok and D. J. Carothers,
A.
1458 (1974).
J. Org.
L. Bettag, H. Saneii and J.
Amoss, R. Blackwell,
and R. Guillemin,
ACS/CSJ A.
Yankeelov,
Endocrinology,
10.
Momany. F. A., J. Med. Chem., 21, 63 (1978).
Il.
Ling, N. and W. Vale, Biochem. Biophys. Res. Commun.,63, 801 (1975).
12.
Scprodi, J.. D. H. Coy, J. A. Vilchoz-Martinez, E. Pedroza, W. Y. Iluang, and A. V. Schally, J. Med. Chem., 21, 993 (1978).
13.
Humphries, J., T. Wasiak, Y. P. Wan and K. Folkers, Res. Commun.,5, 709 (1978).
14.
Bowers, C. Y., J. Humphries, T. Wasiak, and L. E. Reichert, Jr., Endocrinology,
1023
Biochem. Biophys.
K. Folkers, G. A. Reynolds, 106, 674 (1980).
97, No.
3, 1980
December
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Pages 1014-1023
16, 1980
SYNTHESISAND BIOLOGICALACTIVITIES OF PSEUDOPEPTIDE ANALOGUES OF LH-Ml: AGONISTSANDANTAGONISTS
F. Spatola: Nirankar S. Agarwal, Anthony L. Bettag, and John A. Yankeelov, Jr.?; Departments of Chemistry and Biochemistry, University of Louisville, Louisville, KY 40292 Arno
and
Cyril
Y. Bowers, Tulane University School of Medicine New Orleans, Louisiana 70112 and
Wylie W. Vale< The Salk Institute, Neuroendocrinology Laboratory, LaJolla, California Received
September
92037
22,198O
Sulrullary
Using solid phase methods, seven agonist and antagonist analogues of LH-RH have been prepared containing enzyme-resistant CH2Slinkages as selected amide bond replacements. Agonists modified at the S-6, 6-7 and 9-10 of LH-RH, respectively. position had 2, < 0.1, and 10% of the in vitro activity Amongpotential antagonists, 6-7 posit%xogues showedonly minimal inhibitory activity but N- and C-terminal modified analogues retained substantial LH-RH-LHand FSH inhibitory activity. In addition, a l-2 osition methylene thioether analogue of the parent [Ac-Prol, D-Phe2, D-Trp 3*i]LH-BH antagonist was completely inhibitory at 30 ng -in vitro and represents the first such structure-modification that may be at least as active as its corresponding amide linked congener. However, neither l-2 nor 9-10 methylene thioether position antagonists showed--in vivo antiovulatory activity at the 250 pg level. * To whomcorrespondence should be addressed. +
Deceased, April
** Abbreviations follicle
6, 1979.
used:
stimulating
LH-RH,
TFA,
sulfonyl;
hormone-releasing hormone; FSH,
hormone, LH, luteinizing
Cbz, benzyloxycarbonyl; amine;
luteinizing
DCC, dicyclohexylcarbodimide;
trifluoroacctic
Bzl, bcnzyl;
hormone, Boc, t-butyloxycarbonyl,
acid;
DMF, dimcthylformamidc;
pGlu, pyroglutamyl;
HPLC, high pressure liquid
DIEA, diisopropylethyl
thiomethylone
ether
p-tolucnc
t lc, thin layer chromatography;
chromatography; TEAP (Triethylammonium phosphate) ;
J, refers to the replacement of the normal amide linkage, the
Tos,
moiety,
OOOS-2glX/80/231014-10$01.00/O Copyright 0 1980 by Academic Press, Inc. All rights of reproduction in any form reserved.
[CH2S].
1014
[CONH]
by
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
INTRODUCTION
Both
LH-RU
agents
superagonists
by virtue
bioactivity
of their
would
antiovulatory
that
prove
use of the link
resistant
ether
LH-Rlt as established position
potent
subjected
to this
pseudopeptide
selective
Boc-Protected followed Also,
chosen
the
bond
for
suitable
surrogate)
of each of these solid
described
Koch -L’ et al
(3)
JLH-RH
inhibitory
of but
other
to LH-RH based (4) have
also
been
of synthesizing activity. I
of the
three
methods
routes
elsewhere
for (7).
first
acids).
of the
amide
into
prepared prepared
psoudodipcptides
amino
analogues
the it
Boc-X J, Cly type
varieties
phase
contains
were
WC have prcparcd chiral
of these
to incorporate
(7)
has been first bond replacement
the pcptidc.
Tho
by Yankoelov
-ct --al
p (5)
by Spatola
ct al.,
(6).
of the
X$Y
typo
The procedure
pseudodipeptides
has been described
MATERIALS Synthetic
Our major
bonds
the objective
long-lasting
synthesis
GlyJIX,
X and Y represent
by standard
with
which
and then
by dipeptides then
the
dipeptide
dipeptides,
since
D-Trp3’6
amide
D-pGlu-D-Phe-D-Trp-Ser-Tyr-D-Trp-Leu-Arg-Pro-GlyNH2
The strategy
(amide
have
(I).
Antagonists
the
the
6-7 and 9-10
and by
synthesized.
analogucs
for
LH-RH structure
(2)
D-Phe’,
peptide
we have examined
of the
modification that
to prepare
candidates
pGlu-His-Trp-Ser-Tyr-Gly-Leu-Arg-Pro-GlyNH2
LH-RH’ Antagonist
to prepare
been
[D-pGlu’,
analogues
LH- RH
lability
Prolonged
useful
as a replacement
the
and Stern
have also
inhibitor
[CH2S]
(1).
for
degradation,
within
known
by Marks
analogues
on the
moiety
positions by the
corequisite
In an effort
to enzymatic
thiomethylene
as antifertility
of LH and FSH release
activity.
was predicated
have potential
to be a necessary
[CUNH] in critical
focus
both
inhibition
appear
possessing would
and antagonists
into
for
(whcrc incorporation
the peptides
in the present
study.
AND METHODS
the pseudodipeptides The incorporation
1015
used of the
in this Boc-protected
study
have been derivatives
Vol.
97, No.
BIOCHEMICAL
3, 1980
Table
I
AND
Methodology
BIOPHYSICAL
For Solid
Time (Min)
1
CH2Cl*
L
TFA/anisole/CH2C12
3
CH2Cl *
4
DlEA/CH2c12
b
CH2C12
b
k&-amino
7
DCC/CH2C12 (2.5 equiv.)a
gob
s
CI12C12 (3x)
1
9
wx1
1
1
(3x1 (40:2:51)
(10: 90) (2x)
1
acid/CH2C12
(2.5 equiv.)”
of 2-12 hr. each for
into
peptides
laboratory.
Table
synthesis;
chiral
specified.
Side (Ser
amino chain
Vega Biochemicals,
acids
Bachem,
1% cross-linked
or
were
dipeptides,
although
catalyzed
deprotections,
Peptides
necessary
were
hydrogen
fluoride
30 min.
at O” C. G-15 using
are of the
in the
scavengers
from
containing The extracted
used
employed
for
used
were
amino
acids
polymers
extent
(0.4-0.5
products
25% or 30% HOAc.
1016
where
[Arg
and His)
purchased
lyophilized
pcptidc otherwise and
from resins
Boc-Glycine
or the No unusual
Boc-pseudo-
employed
and amino
and 10% ethyl
The major
phase
except
involving
by treatment
were
solid
mmol/g.
were
cleavage
resins
in our
meq. nitrogen/g)
with
antioxidants
10% anisole
were
reactions
fluoride the
tosyl
of 0.15-0.35
coupling
Boc-pscudodipcptidcs.
Benzhydrylamine
(DCC mediated)
and/or
hydrogen
cleaved
methods
Beckman Biochemicals.
to the
for
Boc-pseudodipcptides.
L-configuration
groups
condensed
pseudodipeptide
Gquivalents
methodology
polystyrene
Biochemicals,
3.0
standard
Common protected
precautions
Sephadex
the
protecting
and Tyr).
Beckman
follows
I describes
-
(3x)
by two couplings
LH-RH
2-10
(3x)
Substituted
to
25
1
b.
related
5 and
(5x1
of 1.5 thru
Boc-ProJIGly
Synthesis
IkilgL!nt
by two couplings
from
COMMUNICATIONS
9
Substituted
used wcrc
Psptide
Phase
il.
bcnzyl
RESEARCH
during
acid
hydrolyses.
with
anhydrous
methyl
sulfide
and desalted
peak was collected,
acid-
for over lyophilized
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 97, No. 3, 1980
and purified
by gel
reversed
phase
columns,
employing
liquid
and monitoring to remove tic
chromatography methanol/ammonium
HF’LC employing
and monitoring
separable integrating
purity
rats.
Zorbax
gradiont
acid
solvent
showed
the
analysis
all
resulting
including
(Table
weakly
products
amino
acid
of the
of the
rcpcatcdly
techniques
III),
absorbing free
via
Model
3837
conditions
pseudodipeptide
units
of the pseudodipeptide
partial
enzymatic
fragments
Details
impurities.
of HPLC-
hydrolysis
and position
and gradient
on a Hewlett-Packard
confirmed
systems
lyophilizcd
any possible
were
C-18
phosphatc/acetonitrile
were
The LH and FSH agonist
over
peptides
of nanograms
and NIAMDD rat The second dissociated
tests
via -
of the
rat
hemipituitaries
degradation,
chemical
latter
procedure
will
of the
Lh-LER-1240-2
standards (2.1
x NIH-FSH-Sl
--in vitro
system
anterior
pituitary
release
of luteinizing
of LH-RH was the basis
Values (0.60
cell
(91.
Multiple
tested rates
(8).
Sprague-
were
and adding
primary
cells
secretion
female
were
dctcrmincd
LH-RH and calculated
NIH-LH-Sl
in
(units/mg)
units/mg.).
utilized
were
old
systems.
activities
solution
elsewhere
hormone the
and antagonist
6 h as described
FSH RP-1
in two distinct
of 20-day
in Ringers
and an LH-RH standard
luteinizing
performed
the use of hemipituitaries
test
concentration
amino
analyses.
biological
the
to inhibit
using
by standard
The presence
and III
850)
elsewhere.
by incubating
the
II
and analysis
involved
peptides
II),
was by semi-prcparativc
was collected,
rearrangement)
mass spectrometric
The first
terms
peak
cases,
products.
The --in vitro
Dawley
buffer
procedure
apparent
compounds
be reported
acetate
and analyzed
In several
to ninhydrin-negative
ionization
Model
to > 95% as monitored
(through
derivatization,
(DuPont
a triethylammonium
by this
recorder. loss
purification
at 210 nm to detect
impurities
in
salt,
x, y, and z (Table
The analytical
units
The major
ammonium acetate
by analytical
caused
The final
at 254 nm.
on solvents
system
filtration.
for
their
by these hormone
of the
1017
cells.
stimulated antagonist
cultures dose abilities
of enzymatically levels
of pseudo-
to increase
The ability
of analogues
by a constant assay,
where
[D-pClu’,
[Tyr
(Pro$G1ySHZ
[DpGlu’,D-Phe*,
III
I\
v
D-Phe’.
HPLC
Tic
b.
System:
Solvent Systems: (7:3). :I EtOH:H,O
Solvent
LH-RH
[Ac-Pro$D-Phel-*,
x,
C.
A. B.
II.
Properties
HI’LC
of
C
C
B
B
System=Ret
Synthetic
14.7
12.0
10.7
12.9
l-7.0
11.9
12.7
‘II
HPLC
Lti-RH
9.05
(15:3:1?:10);
Triethylammonium Triethylammonium Triethylammonium
Solvent
n-bu011:H0,\c:t!20:I~)‘ridi~~c
Acetonitrile/O.ZSN Acetonitrile/O.ZSW Acetonitrile/O.2W
D-T~P~‘~]
D-Trp3’6
D-Trp3,
Pro $ G1ySH2’-“]LH-RH
[D-pGlu’,
D-Ser
D-Trp3,
$J Leu6-7]LH-RH
Gly $ Leu6-7]LH-RH
[D-pGlu’,D-Phe*,
a.
VIII
VII
VI
JI ClysV6]LH-RH
[Cly
II
‘-“]LH-RH
$J Leu6-‘]LH-RH
LH-RH
I
Peptide
Table
(MN)
y.
pH 3.5; pH 3.5; pH 3.5;
0.64
0.60
0.56
0.57
0.42
0.52
0.43
0.24
Rf*
r,-euotl:I!Or\c:EtO-\c:l120
phosphate; phosphate; phosphate;
Time
.Xnalogues.
12-25: 20-30cr 25-508
0.64
0.66
0.53
0.56
0.44
0.50
0.39
0.33
RfY
0.67
0.6s
0.60
0.61
Rf
(1:l:l:lj;
gradient gradient gradient
TLCb
min)
min) min)
(15
(15 (25
Vol.
97, No.
3, 1980
BIOCHEMICAL
'lablc
Structure
Clu
As&lo-acid
111.
Phc
AND
BIOPHYSICAL
Analysis Ratios Amino Acid Ratios
Trp
His
Ser
Tyr
ClY
0.97
1.04
RESEARCH
of Ui-IU
COMMUNICATIONS
AIldOgS
Lou
An?
h-0
0.87
1.13
1.02
a,b
Other
NU.
II
1.00
0.84
0.81
0.91
III
0.96:
0.81
0.91
0.78
IV
0.99
0.83
1.02
1.00
L
u.L)o
0.93
0.90
1.04
1.00
1.03
1.02
1.08
1.00
1.03
0.90
0.92
1.01
K.U. Tyr IJ(;I;/ N.D. Pro v tily 1.06
1.05
0.94
Cly0 VI
0.99
c
0.76
0.89
1.02
VI-1
1.05
1.10
1.64
0.92
1.03
Vlll
1.76
a.
Incorporated Pseudodipeptide
11.
N.D.
c.
U-&r
0.82
1.00
0.96 0.96
1.00
0.98
1.02
c N.D. Pro
0.90
1.10
0.94
0.99
Lcu
li, Lcu
+ Phc
due to low ninhydrin 1.89,
-
amino-acids
Cly
N.D. Pro
= not dotcrmincd
Q
0 D-NW
response
peaks are virtually
suporimposoblc.
D-Phe*, D-Trp 3'6]LH-RH was used as a standard and arbitrarily
assigned a
potency of 1. Antiovulatory
assays were carried
Worcester, Mass., using dissolved in corn oil the ova were counted
female
Sprague-Dawley
and injected the
next
out at the Mason Research Institute, rats.
The peptides were
subcutaneously on noon of proestrus
and
morning.
RESULTSAND DISCUSSION As
shown in Table IV, LH-RHanalogues whose only structural
involved biological III
amide
bond
activities.
variations
replacements at 5-6, 6-7 and 9-10 displayed widely divergent Though none were as active
as LH-RH, LH-RHpseudopcptides
and IV with amide bond replacements at 5-6 or 9-10 were l-2 orders of
magnitude more active containing
with respect to LH and FSHrelease than
a 6-7 modified linkage.
to be the most susceptible
Since the 6-7 linkage
the
has been
analogue shown
site of degradation of the LH-RHmoleculL1*.3!
1019
Vol.
97, No.
3, 1980
BIOCHEMICAL
TABLE IV.
AND
--IN VITRO AGONIST A"WITY
Pseudopeptide
[Gly$
Analogue
Ln-RH nglrnl of medium
P
A.ng/nl of medium
SEM 4)
P
3 450 5 187 849
5 23 3 44 198
"S .Ol ,001
470 7856 304 5562 9332
133 1462 87 648 981
ns .OOl ,001
29 1057 595 1256 .1607
15 148 74 105
. 001 ,001
179 5840 4487 8364 12846
33 607 702 829 1106
. 001 .OOl ,001
407 -6 25
49 11 14 8
.OOl ,001 ,001
5627 -155 -26 1966
281 112 240
.OOl ,001
282
,001
Leu6-711mH 0.6
0.6 30 100 1000
rlGlyWl2
g-'o]LH-pJ
0.6
0.6
6 60 aAs determined b As determined
the above conformat for
incubations
in pituitary
cell
results
change.
contains
insertion
- See experimental
culture
suggest
ional
LbRI1
thus,
by hemipituitary
vs.
standard
that
the
Perhaps
a bend or of the
of a preferred
low energy
than
bond.
While
by the
equipotent
the
amide
been ruled some type activity
out
of bend found
additional
in the (Table
now-modified with
which
the
the
it
may more readily
in the --in vitro
6-7 amide
bond proved
at
link
junction
(lo),
acids
is the
greater
seems possible activity
of the
antagonist
to substitution
1020
content
LH-FUI analogue of
(11).
residual
1 and 10 (12). overall
An
lipophilicity
by HPLC retontion
more readily phase
the
seems to have
in view
amino
reversed
interact
and,
is more flexible
position
this
folding
lipophilic
intolerant
0.10
Momany model(s)
, as ascertained
II
that
rcsuits
0.02
may have reduced
especially
analogues
structure
proposed
of an NO-Me-Leu7
analogue
to the
greater
se
that
interpretation
bend region
A substantially
w;1s noted
substituted
6-7
site
likely,
analogues among these
6-7
II);
is
c 0.001
an unfavorable
the CHgS substitution
activity
region
cyclic
correlation
observed times
for
per
the
at the
since
a g-turn
induces
that
at this
conformer
in this
is
turn
linkage
Pot*ncyb LH-P&l - 1
section.
6-7 pseudolinkage
hairpin
Relative
section.
- See experimental
pertinent
pseudo
FSI? SEM (*I
[Tyr ~Gly5-61LH-lW
COMMUNICATIONS
OF PSEUDDPEPTIDES RELATED T O LH-FJi
A, w/m1 of medium
100 1000 10000
ho
RESEARCH
LHa
DOS.? Peptide ngJm1 of medium
BIOPHYSICAL
substrate
column
although
dcpcndoncc
of
analogucs even with
the
CX~OSCS
still tho
speculative. pscudopcptidcs
(Table
V).
a 6-D-residue
While
Vol.
97, No.
3, 1980
BIOCHEMICAL
TABLE V.
AND
Peptide ngfm1 of medium
Pnalogue
[D-pG1ul, D-Phe'. D-Trp’, Gly $Leu 6-‘lLN-F.H
[D-pGlu', D-Ser
LAP lx-lw nglml of medium
10 100 1000 10,000
.6 .6 .6 .6 .6
6 450 366 415 380 268
10,000 50,000
.6 .6 .6 .6 .6
7 532 594 553 563 226
23 144 82 108 97 16
10 30 100 1000
.6 .6 .6 .6 .6
-2 636 251 164 19 -20
10 72 31 27 2s 13
-16 526 26 25 9 5
D-Phe', D-Trp' $Leu6-'ILki-PH
D-Phe’, D-Trp3j6 Pro’4 GlytW2 g-'o]&gH
$D-Phel-',
aA~ determined b As determined
D-Trp'%"-RN
VI),
Peptide its
with
parents
is unknown Both assayed
for
administering
124 <.OOl 1462 563 672 803 373
.OS ns ns IIS
ns ns ns .05
127 5339 4265 4600 4988 2081
185 1282 250 542 871 371
ns ns ns .05
.OOl ,001 ,001 .OOl
375 7241 3852 2420 360 -283
207 953 1251 305 287 165
.05 ,001 .OOl ,001
2 e.001 41 10 ,001 24 ,001 5 ,001 11 .OOl
-15 7871 773 386 -23 -117
< 0.001
c 0.001
153 c.001 231 225 ,001 156 ,001 75 .OOl 96 .OOl
0.47
(.30-.71)
0.60
(0.40-1.0)
were
considerably
activity; the least
retained
moreover, [AC-Pro
1-2
in the
LH-IUi suggest bond at l-2 l-2
position
a role
in these
more than
compared
QD-Phe
as active
at the
more expendable. SO%
to the
, D-Trp
3D6]
LH-KH
hemipituitary
assay.
the possible
and 9-10 after
structure
for
importance
agonist
activity.
substitution activity
of relationships
time.
antagonists their
plays
467 7856 4400 7091 7061 5807
substitution
of the peptide
linkage
at this
bonds
structure,
lipophilicity
Relative Poteneyb [DpGlu', D-Phe’, D-Tq3’61ui-Rli = 1
P
section.
of Pro JI G~YNH~‘-~’
function
pseudopeptide
amide
to be at
P
section.
pseudopeptide
linked
SFm (+I
A. nsln1 of medium
6 ~001 23 74 ns 20 ns 53 "S 15 . 001
- see experimental
biological
proved
increased
standard
9-10
and those
carbonyl
Whether
vs.
and 9-10
the
(VIII)
results
of the
l-2
amide
antagonist These
culture
--in vitro
corresponding
the
cell
the
VII
.6 .6 .6 .6 .6 - see experimntal
30 100 1000 10.000 incub%rions
in pituitary
(peptide
of
_
by hemipituitary
COMMUNICATIONS
FSI? SEM ('1
A. w/m1 of medium
[D-pGlu',
[AC-Pro
RESEARCH
--IN VITRO ANTAGONIST ACTIVITY OF PSSUCOPEPTIDES RELATED T O LH-RH. DOW
Pseudopeptide
BIOPHYSICAL
displaying --in vivo
250 ug
substantial
antiovulatory
peptide/animal
in vitro A-
activity on
the
1021
activity
in female
day of proestrus.
were adult
rats
next by
Vol.
97, No.
3, 1980
Surprisingly
BIOCHEMICAL
both of the pseudopeptide
at which
the corresponding
have been fully to determine degradation
active
such findings analogues
are unique
peptide
analogues,
in the tight
antagonists
antagonists
that
even when the replacement
involves
of the replacement the question
terminal
role. positions
can yield
of such substitutions
Appreciation for
support
Karten
for
of this helpful
technical
through
discussions.
Mr. Benjamin Van Osdol, for expert
retention
active
We
injection
of full
for
orally
and this
Ms. Georgeann Reynolds
changes. again
once
in peptides
may have a
at N and C
tends
to support peptide
active
NO l-HD-8-2882
are indebted
potency,
and polarity
or blocking
1022
poor
(in vivo).
biological
steric
analogues
assistance.
are involved
and the possible
to the NIH Contraceptive Contract
modified
the problems
which perhaps
amide replacements
in the search
is expressed work
between
backbone elements
highly
and --in vivo
of amide bonds in LH-RH analogue
as a mode of retarding
by endo- and exopeptidases
between --in vitro
subcutaneous
that
non-
lipophilic
does appear to be critical
The observation
or
preferred
highly
Other
(in vitro)
substantial
as to whether
problem,
whether
to distinguish
the replacement with
is in progress
Work
By the use of suitably
at the LH-RH receptor
suggest
(11).
and to establish
of the analogues
is not incompatible
functional
(14).
after
at dosages
mechanisms,
lack of correlation
of the analogue
Our results
components,
lipophilicity
bending
transportation
by unexpected
it may be possible
and global
assay
to LH-RH pseudopeptides.
of LH-RH analogue
COMMUNICATIONS
amide linkages
may be due to a transport
to extracellular
results
raises
this
have shown a similar
of local
with
RESEARCH
were inactive
in the rat antiovulatory
to what extent
binding
BIOPHYSICAL
analogues
analogues
of the amide surrogates
reversible
‘111~ site
AND
the use
degradation
analogues.
Development
Branch
and to Dr. Marvin
to Mr. Scott
Mack,
and Ms. Karen Von Dessonneck
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
REFERENCES 1.
Vale, W., M. Brown, C. Rivier, M. Perrin and J. Rivier, in Brain A New Endocrinology, A. M. Gotto, Jr., E. F. Peck, Jr. Peptides: and A. E. Boyd, III, Ed., Elsevier, Amsterdam p. 71 (1979).
2.
Marks,
3.
Koch, A. T. Barum, P. Chobsieng, and Commun., 61, 95 (1974).
4.
Rivier,
5.
J. A. Yankeelov, J. A., Jr., Chcm., 43, 1623 (1978).
6.
Spatola, A. F., H. Saneii, K. F. Fok and J. A. Yankeelov, Jr., Chemical Congress, Honolulu, Hawaii, Abstract #18 (1979).
7.
Spatola, A. F., N. S. Agarwal, Jr., in preparation.
8.
Humphries, J., J. P. Wan, K. Folkers and C. Y. Bowers, J. Med. Chem., 2, 120 (1978).
9.
Vale, W., G. Grant, 91, 562 (1972).
N. and F. Stern,
Biochem. Biophys. Res. Commun.,3,
J. and W. Vale, Life Sci.,
M.
M.
2,
Fridkin,
Biochem. Biophys. Rcs.
869 (1978).
K. F. Fok and D. J. Carothers,
A.
1458 (1974).
J. Org.
L. Bettag, H. Saneii and J.
Amoss, R. Blackwell,
and R. Guillemin,
ACS/CSJ A.
Yankeelov,
Endocrinology,
10.
Momany. F. A., J. Med. Chem., 21, 63 (1978).
Il.
Ling, N. and W. Vale, Biochem. Biophys. Res. Commun.,63, 801 (1975).
12.
Scprodi, J.. D. H. Coy, J. A. Vilchoz-Martinez, E. Pedroza, W. Y. Iluang, and A. V. Schally, J. Med. Chem., 21, 993 (1978).
13.
Humphries, J., T. Wasiak, Y. P. Wan and K. Folkers, Res. Commun.,5, 709 (1978).
14.
Bowers, C. Y., J. Humphries, T. Wasiak, and L. E. Reichert, Jr., Endocrinology,
1023
Biochem. Biophys.
K. Folkers, G. A. Reynolds, 106, 674 (1980).