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β-Endorphin: Structure-activity relationships in the guinea pig ileum and opiate receptor binding assays
Vol. 74, No. 2, 1977
BIOCHEMICAL
/3-ENDORPHIN:
STRUCTURE-ACTIVITY
GUINEA
PIG Byron
ILEUM A.
Ping Hormone
OPIATE
RECEPTOR
David
Law*,
Horace
H.
and San
*Department Francisco,
Laboratory California,
of November
AND
29.
RESEARCH COMMUNICATIONS
RELATIONSHIPS
Doneen,
Yee
Research
Received
AND BIOPHYSICAL
Chung,
BINDING
Donald
Lob*
IN
THE
ASSAYS
Yamashiro,
and
Choh
Hao
Li
of Pharmacology, California 94143
University
1976
SUMMARY: The opiate activities of some derivatives and enzymatic digests of camel and human P-endorphin were determined in the guinea pig ileum and rat Derivatives of (3-endorphins altered within brain opiate receptor binding assays. the amino-terminal five residues showed pronounced losses in activity. Anisylation of the C-terminal glutamic acid residue of Ph-endorphin produced only Chymotryptic digestion greatly weakened the opiate small reductions in activity. activities of Ph-endorphin, whereas carboxypeptidase A, tryptic and leucine aminopeptidase digests showed only small losses in potency. The C-terminus of P-endorphin appears to contribute little directly to opiate activity. Amino acid analysis and assay of the leucine aminopeptidase digests suggest that the larger potency of P-endorphin relative to Met-enkephalin may be a consequence of its greater resistance to exopeptidase attack. Several of
brain
have
have
been
the
isolation
the
camel
been
purified and
have
human
which
isolated. from
also
and
and
potent
been
identified
and
opiate in
pituitary -(61-91), Abbreviations: P-endorphin; P,-LPH, sponding
f3-LPH
and (8,
respectively.
correspond Each
Met-enkephalin, /3h-endorphin, sheep p-lipotropin; to residues (61-65),
Copyrighr 0 I977 by Academic All rights of reproduction in any
brain
the
of these
pituitary
to
(1,2).
Li
been
peptides
656
the
opiate and
and
peptide
of the
within
possess
, of the
reported from
untriakontapig
(4),
sheep the
(5),
pig
of Met-enkephalin, the
-(61-76),
enkephalin; PC -MSH,
(3)
from
sequences
contained
Chung
(P-endorphin)
characterized acid
receptors
Leu-enkephalin,
homologous
p-LPH-(61-65),
methionine human P-endorphin; p-LPH-(61-65),-(61-76), -(61-76), etc.
Press, Inc. form reserved.
Met-
glands
amino are
named
The
have The
for
acid
activities.
P-endorphins
9)and
ligands
amino
y-Endorphins (7).
y-endorphins,
bovine
of a thirty-one
neurohypophysis-hypothalamus a-
endogenous pentapeptides,
porcine
with
(I-
(5,6).
are Two
structure
pituitary
peptides and
peptides
substantial
sequence
of
-(61-77),
and
morphine-like
PC-endorphin, camel camel (3-melanotropin; etc., that peptide corresequence of /3-lipotropin.
Vol. 74, No. 2, 1977
activities
when
specific
binding
widely
to
--in
brain
in
action
mice
enkephalins
Phe4
assays.
Met5
or
(14-
17).
We
Results
the
guinea
when
measured weak
rats
injected
Leu5
residues
have by
guinea
of these
studies
are
2,6,7). --in
vivo. analgesic
centrally
(12)
or
have the
for
the ileum
reported
and
intravenously
vitro
opiate
and
as
display Leuafter
(3-endorphin
the
first
and action
shown --in
or they
Met-
contrast,
for
assay,
However,
In
pig
Materials
ileum
(10-13).
analyzed
of /3-endorphin
pig
transient
relationships
and
relationships
in
(1,
or
when
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
receptors
display
Structure-activity
W-l,
as
activities
a-endorphin
injection analgesic
vitro
opiate
opiate and
intracranial potent
measured
different
enkephalins
BIOCHEMICAL
has (13).
importance
time
the
rat
brain
of the
activities
of
structure-activity opiate
receptor
herein.
Methods
PC-Endorphin (18), Ph-endorphin (19) and (3,-MSH (20) were and p,-LPH were purified as thesized by the solid-phase method. p,was one of the tryptic fragments (T-17) described (8,9). Ph-LPH-(61-69) in the amino acid sequence determination of Ph-LPH (9). Met-enkephalin purchased from Bachem Laboratories (Marina de1 Reyes, Ca. ).
synpreviously utilized was
Acetone-treated Ph-endorphin was prepared by reaction of 12.8 mg of the peptide in 50% aqueous acetone (20 ml) for 21 hr at 24’. Partition chromatography on Sephadex G-50 in 1-butanol-pyridine-0.6 M NH40Ac (5:3:10) gave essentially one peak with Rf 0.48 (Rf of Ph-endorphin, 0.37) and 9.1 mg of product. On paper electrophoresis (pH 3.7, 400 V, 4 hr) the substance behaved as a more acidic material (Rf 0.48 relative to lysine as compared to Rf 0. 54 for P-endorphin). A sample heated in 0. 1% acetic acid for 10 min at 100” liberated acetone. All these properties parallel the behavior of acetone-oxytocin whose structure (21) consists of an isopropylidene bridge between the N-terminal amino group and the nitrogen of the peptide bond between sequence positions 1 and 2. (Anisylated-Glu31)-(3h-endorphin synthesis of h-endorphin (19) and was on Sephadex G-50 in 1-butanol-pyridine-0. gave a Rf of 0.53. Amino acid analysis, peptide mapping indicated an anisylated C-terminus.
endorphin (Eastman
(Homoserine5)-(3h-endorphin in 0. 5 ml 70% After Organic).
formic stirring
acid
was isolated as a by-product in the purified by partition chromatography 1% acetic acid (5:3:11) in which it ultraviolet spectral analysis and glutamic acid residue (22) at the
further
was produced by dissolving 10 mg phfollowed by addition of 20 mg CNBr at 24” for 24 hr in the dark, the solution
657
Vol. 74, No. 2, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
was diluted with a large volume of water and lyophilized. Peptide mapping and end-group analysis showed that no cleavage occurred. The Met-Thr bond has previously been shown to be resistant to CNBr cleavage in 70% formic acid (23). The amino acid analysis indicated that Met5 was converted to homoFormic acid treated-Ph-endorphin was produced as above serine by CNBr. except no CNBr was added. Carboxypeptidase A digestion of ph -endorphin 1.6 mg of Ph-endorphin in 0. 1 ml, pH 8.5, Tris-HCl carboxypeptidase A (Worthington). The suspension 8 hr and the peptide recovered by lyophilization.
was done buffer and was incubated
by dissolving adding 0. 05 mg at 37 a for
Tryptic digestion of Ph-endorphin was performed by dissolving Ph-endorphin in 0.2 ml 0.2 M NH4 OAc buffer (pH 8. 0). Trypsin (Serva), was added and the solution incubated at 37 ’ for 8 hr. The reaction was by addition of 1. 8 ml 0. 05 N HCl. Chymotryptic digestion of Ph-endorphin done as above except that chymotrypsin (Calbiochem) was used.
1. 1 mg 0.02 stopped was
Leucine aminopeptidase digested peptides were prepared as follows: PC-endorphin (0. 34 mg) and Met-enkephalin (0. 06 mg) were each dissolved in 0.1 ml pH 8. 5 Tris buffer. Leucine aminopeptidase (0. 007 mg, Worthington) was added to both samples, and the solutions incubated for 2 hr at 37’. The digests were acidified to pH 3, lyophilized, and portions removed for amino acid analysis 0 Narcotic agonist activities were measured from the depression of electrically-stimulated contractions of the guinea pig ileum prepared as Briefly, a 2-3 cm segment of ileum was mounted previously described (24). between internal and external platinum electrodes in a 25 ml bath containing Kreb’s solution (with 125 nM diphenyamine as antihistamine) at 37’ and aerated with 95% 0215% CO2. Tension changes evoked by rectilinear electrical pulses (0.4 msec duration, 0.1 Hz, 80 V) were recorded by a Grass 2 g) coupled to a model 7 Grass Isometric Pressure Transducer (tension, Polygraph. Peptides and normorphine were assayed on two ileum preparations at 3- 5 concentrations. Opioid activity was also assayed as the inhibition of stereospecific 10 Ci/mmole) binding to lysed rat f 3H]-morphine (New England Nuclear, synaptic plasma membranes prepared essentially as described (25). Synaptic plasma membranes (200 yg protein) were preincubated in 2 ml sodium-free HEPES buffer (26 mM, pH 7.5) at 25” for 10 min with peptides, morphine sulfate or dextrorphan. Next [ 3H] -morphine was added (4 nM) and the incuAssays were terminated by filtration followed by bation continued for 15 min. three 4 ml rinses with ice-cold buffer on glass fiber filters (Whatman GF/c). Filters were dried and counted by liquid scintillation spectrophotometry. Stereospecific opiate binding, the difference between [ 3H] -morphine binding in the presence of dextrorphan (1 x 10e6M) and morphine sulfate (1 x 10e6M) was 45% of the total binding. Peptides were assayed in quadruplicate; standard errors of the mean c-p. m. were always less than 6%.
the
IC50
Potencies (inhibiting
of peptides in molar concentration
both
assays - 50%)
658
were calculated as to that of PC-endorphin.
the
ratio
of
mg,
Vol. 74, No. 2, 1977
BIOCHEMICAL
Table Opiate
Activities
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I
of (3, -Endorphin
and
Related
Preparation
Peptides
Relative pig
Guinea ileum
Potency:k in Brain opiate receptor binding
Pc-endorphin
1.00
1.00
Ph-endorphin
1.00
1.00
Met-
0.25
0.
0.65
---
enkephalin
Normorphine
34
Ps-LPH
< 0.01
<
0.01
Ph-LPH
<
0.01
<
0.01
Pc-MSH
<
0.01
<
0.01
Ph-LPH-(61-69) Acetone
treated
-Ph-endorphin
(anisylated-Glu31) Formic
-Ph-endorphin
acid-treated-Sh-endorphin
(5-homoserine)-Ph-endorphin
<
p h -endorphin:
Carboxypeptidase
Ph-endorphin:
Chymotryptic
Ph-endorphin:
Tryptic
digest
Leucine
aminopeptidase
PC
-endorphin:
Met-enkephalin:
digest
* Potency of PC -endorphin -endorphin standard to PC in the guinea pig ileum binding assay.
to PC-endorphin are
summarized
activities as in
of
measured Table
<
digest
0.01
0.02
0.76
0.75
1.00
1.00
< 0.01
1.00
1.00
0.13
0.03
0.71
0.61
0.97
0.93
0.01
<
is defined as 1.00. Other preparations on a molar basis. IC50 of PC-endorphin: assay; 1. 2 -3.7 x 10s7M in the rat brain
Results Opiate
digest
aminopeptidase
0.26
0.01
A digest
Leucine
0.20
I.
and the
0.01 were compared 2.5-g. 0 x 10s8 opiate receptor
Discussion
various
peptides
in
the
guinea
In
the
ileum
pig assay
CFQ
and ileum PC-
enzymatic and
and
rat
digests brain
Ph-endorphins
relative
receptor
assays were
each
M
Vol. 74, No. 2, 1977
55%
more
potent
BIOCHEMICAL
than
normorphine,
Similarly
in
the
compared
to
(3-endorphins.
was In
opiate
somewhat
less
contrast,
when
tested
SC-MSH endorphin
to
the
which
incorporates
(opiate
receptor
Whereas residue
with
opiate
the
its at
In
opiate
activities
in as
well
Ph-endorphin residues
had
residues
other
potency reduced
/3,-LPH-(61-69),
may
be
little
of
in activities which
directly
(71%)
even
P,-LPH
and
or
SC-
by
a bridge
(ileum)
and
2%
anisylated in
the
carboxyl-terminal
the
interaction to
chymotrypsin
5-
at
opiate
activities. glutamic
of Ph-endorphin homoserine
diminished
be
expected On
residues.
the
no
specificity
within
A)
or
(trypsin)
limited
been
shown
to
again
the
digestion, and
still be
to
can
Trypsin
can
1%
decline
of Met5
indicating
(4),
were
26).
Tyr’-Gly’
only
essential,
with
A has
ileum
assay,
Ph-endorphin.
having
action.
(11,26).
either
also
between
a modest
conversion
(carboxypeptidase
opiate
in
Sh-Endorphin,
showed
aromatic
enzymes
l-9),
observed
to normorphine
activity.
Chymotrypsin
LPH-(61-91)
for
endorphin these
no
at
(see
Tyr’,displayed
residue,
Carboxypeptidase porcine
of
addition,
assays.
as with
activities. from
group
of Ph-endorphin both
(34%)
to Sh-endorphin-(
activity
M
cyclized
contribute
receptors.
-6
x 10
potency
shown).
Tyr to
no
Met-enkephalin.
reduced
previously
antagonism
of Ph-endorphin
appears
potency Phe4
amino
acid
Hydrolysis
5.0
Sh-endorphin,
amino-terminal
the
showed
of
than
corresponding as
SC -MSH
not
treated
glutamic
abolished
-69))
naloxone-like
(data
active had
Met-enkephalin, and
show
assay)
its
acid
than
more
Met-enkephalin
concentration
ileum
C-terminal
assay,
Sh-LPH
failed
Acetone
its
potent
high
in
4-times
Sh-LPH-(61
at the
also
and
receptor
and
S,-
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
greater
expected
to
to
receptor than
the
be
produced
cleave
&-endOrphin
other
hand,
the
amino-terminal effects
cleave
the
digestion
Gly9’-Gln91
reduced
of the the
opiate dipeptide
of these
somewhat (61%).
activities by
vitro
nature
binding
of five
on --in
non-essential
however,
opiate
considerably
action
ph-
Interestingly, nonapeptide of trypsin
on
Vol. 74, No. 2, 1977
(3h-endorphin. or
BIOCHEMICAL
Therefore,
some
other
the
tryptic
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
trypsin
digest
or
fragment,
contains
fragments
in
undigested
&-endorphin
combination,
having
opiate
activity. PC-Endorphin aminopeptidase detected
was as
by
acid
showed
Met-enkephalin, lost
all
residue
by
protected
known
to
potent
[ D-Ala21
rapidly
P-endorphin greater
only
especially
resistance,
to
(28). Met-enkephalin at
differ
This work was Acknowledgements. National Institutes of Health (GM-2907) B.A.D. is a recipient of a Fellowship Metabolism and Digestive Diseases.
this
(27),
but
The
greater vivo
and from
in
digest
contrast,
to
part
NIDA grants the National
by
bond, the
amino
of Met-enkephalin and
plasma
readily
analgesic result
of
Tyrl-Gly’
brain
less
may
in
in
that
as
digest
Therefore,
amino-terminus,
supported
enzyme
of the
from
leucine
of tyrosine
activities;
Enzymes
--in its
1,
opiate
attack.
enkephalins
to
Table
digestion.
appears
with
amounts
hydrolysis
aminopeptidase
-Met-enkepahlin compared
of
hydrolysis
trace
in
stoichiometric
exopeptidase
inactivate
shown
dimunition
of PC-endorphin from
limited
of only
As
slight
leucine
very
liberation
showed
after
terminal
by
to
analysis.
which
activity
being
indicated
amino
PC-endorphin
susceptible
the
potency in
enzymic
a grant (DA-01314 Institute
part
are
more of
from
its
digestion.
from
the
and DA-00564). of Arthritis,
References 1.
2. 3. 4. 5. 6. 7.
Hughes, Morgan, Simantov, 2515-2519.
J., B.
Kosterlitz, H. W., Fothergill, L. Smith, T. W., A. and Morris, H. R. (1975) Nature 258, 577-579, R. and Snyder, J. H. (1976) Proc. Natlxcad. Sci.
A., USA
- 73,
Li, C. H. and Chung, D. (1976) Proc. Natl. Acad. Sci. USA 73, 1145-1148. Bradbury, A. F., Smyth, D. G., Snell, C. R., Birdsall, N.?-.M. and Hulme, C. E. (1976) Nature 260, 793-795. Chrktien, M., Benjannet, S.,ragon, N., Seidah, N. G. and Lis, M. (1976) Biochem. Biophys. Res. Commun. 72, 472-478. D. and Doneen, B. A. (1976) Biochem. Biophys. Res. Li, C. H., Chung, Commun. 72, 1542-1547. Guillemin,R., Ling, N. and Burgus, R. (1976) S&ances Acad. Sci. Ser. 282, 783-785.
D.
Vol. 74, No. 2, 1977
8. 9. 10. 11. 12. 13. 14. 15.
16. 17. 18. 19.
20. 21.
22. 23. 24.
25. 26. 27. 28.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
L., Chr&ien, M. and Chung, D. (1966) Excerpta Med. Li, C. H., Barnafi, Int. Congr. Ser., 111, 349-364. Li, C. H. and ChuG D. (1976) Nature 260, 622-624. Belluzzi, J. D., Grant, N., Garsky, V=arantakis, D., Wise, C. 0. and Stein, L. (1976) Nature 260, 626-627. A. ZyBajusz, S., Cseh, G. and Szkkely, J. I. (1976) G&f, L. , Romai, FEBS Letters 64, 181-184. Loh, H. H., Txng, L. F., Wei, E. and Li, C. H. (1976) Proc. Natl. Acad. Sci. USA 73, 2895-2898. Tseng, LFF., Loh, H. H. and Li, C. H. (1976) Nature 263, 239-240. Chang, J-K., Fong, B. T.W., Pert, A. and Pert, C. B.(1976) Life Sci. 18, 1473-1482. Day, A. R., Lujin , M., Dewey, W. L., Harris, L. S., Redding, J. A. and Freer, R. J. (1976) Res. Commun. Chem. Path. Pharmacol. 14, 597-603. Terenius, L., Wohlstrbm, A., Lindeberg, G., Karlsson, S. and Ragnarsson, U. (1976) Biochem. Biophys. Res. Commun. 71, 175-179. Ling, N. and Guillemin, R. (1976) Proc. Natl. Acad. Sci. =A - 73, 3308-3310. Li, C. H., Lemaire, S., Yamashiro, D. and Doneen, B. A. (1976) Biochem. Biophys. Res. Commun. 71, 19-25. D., Tseng, L-F., and Loh, H. H. (1976) Li, C. H., Yamashiro, J. Med. Chem. (in press). D. and Lemaire, S. (1975) Biochem. 14, 953-956. Li, C. H., Yamashiro, Hruby, V. J., Yamashiro, D. and du Vigneaud, V. (1968) J. Amer. Chem. Sot. 90, 7106-7110. FeinbGg, R. S. and Merrifield, R. B. (1975) J. Amer. Chem. Sot. -’97 3485-3496. Schroeder, W. A., Shelton, J. B. and Shelton, J. R. (1969) Arch. Biochem. Biophys. 130, 551-556. Kosterlitz,. W., Lydon, R. T. and Watt, A. F. (1970) Brit. J. Pharmacol 39, 398-413. Whittaker, V. P. and Sheridan, M. N. (1965) J. Neurochem. 12, 363-372. Goldstein, A. and Li, C. H. (1976) Proc. Natl. Acad. Sci. USA Cox, B. M., 73, 1821-1823. Hambrook, J. M., Morgan, B. A., Rance, M. J. and Smith, C. F.C. (1976) Nature 262, 782. Pert, C. B. , Pert, A. , Chang, J-K., and Fong, B. T. W. (1976) Science 194, 330-332.
662
BIOCHEMICAL
/3-ENDORPHIN:
STRUCTURE-ACTIVITY
GUINEA
PIG Byron
ILEUM A.
Ping Hormone
OPIATE
RECEPTOR
David
Law*,
Horace
H.
and San
*Department Francisco,
Laboratory California,
of November
AND
29.
RESEARCH COMMUNICATIONS
RELATIONSHIPS
Doneen,
Yee
Research
Received
AND BIOPHYSICAL
Chung,
BINDING
Donald
Lob*
IN
THE
ASSAYS
Yamashiro,
and
Choh
Hao
Li
of Pharmacology, California 94143
University
1976
SUMMARY: The opiate activities of some derivatives and enzymatic digests of camel and human P-endorphin were determined in the guinea pig ileum and rat Derivatives of (3-endorphins altered within brain opiate receptor binding assays. the amino-terminal five residues showed pronounced losses in activity. Anisylation of the C-terminal glutamic acid residue of Ph-endorphin produced only Chymotryptic digestion greatly weakened the opiate small reductions in activity. activities of Ph-endorphin, whereas carboxypeptidase A, tryptic and leucine aminopeptidase digests showed only small losses in potency. The C-terminus of P-endorphin appears to contribute little directly to opiate activity. Amino acid analysis and assay of the leucine aminopeptidase digests suggest that the larger potency of P-endorphin relative to Met-enkephalin may be a consequence of its greater resistance to exopeptidase attack. Several of
brain
have
have
been
the
isolation
the
camel
been
purified and
have
human
which
isolated. from
also
and
and
potent
been
identified
and
opiate in
pituitary -(61-91), Abbreviations: P-endorphin; P,-LPH, sponding
f3-LPH
and (8,
respectively.
correspond Each
Met-enkephalin, /3h-endorphin, sheep p-lipotropin; to residues (61-65),
Copyrighr 0 I977 by Academic All rights of reproduction in any
brain
the
of these
pituitary
to
(1,2).
Li
been
peptides
656
the
opiate and
and
peptide
of the
within
possess
, of the
reported from
untriakontapig
(4),
sheep the
(5),
pig
of Met-enkephalin, the
-(61-76),
enkephalin; PC -MSH,
(3)
from
sequences
contained
Chung
(P-endorphin)
characterized acid
receptors
Leu-enkephalin,
homologous
p-LPH-(61-65),
methionine human P-endorphin; p-LPH-(61-65),-(61-76), -(61-76), etc.
Press, Inc. form reserved.
Met-
glands
amino are
named
The
have The
for
acid
activities.
P-endorphins
9)and
ligands
amino
y-Endorphins (7).
y-endorphins,
bovine
of a thirty-one
neurohypophysis-hypothalamus a-
endogenous pentapeptides,
porcine
with
(I-
(5,6).
are Two
structure
pituitary
peptides and
peptides
substantial
sequence
of
-(61-77),
and
morphine-like
PC-endorphin, camel camel (3-melanotropin; etc., that peptide corresequence of /3-lipotropin.
Vol. 74, No. 2, 1977
activities
when
specific
binding
widely
to
--in
brain
in
action
mice
enkephalins
Phe4
assays.
Met5
or
(14-
17).
We
Results
the
guinea
when
measured weak
rats
injected
Leu5
residues
have by
guinea
of these
studies
are
2,6,7). --in
vivo. analgesic
centrally
(12)
or
have the
for
the ileum
reported
and
intravenously
vitro
opiate
and
as
display Leuafter
(3-endorphin
the
first
and action
shown --in
or they
Met-
contrast,
for
assay,
However,
In
pig
Materials
ileum
(10-13).
analyzed
of /3-endorphin
pig
transient
relationships
and
relationships
in
(1,
or
when
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
receptors
display
Structure-activity
W-l,
as
activities
a-endorphin
injection analgesic
vitro
opiate
opiate and
intracranial potent
measured
different
enkephalins
BIOCHEMICAL
has (13).
importance
time
the
rat
brain
of the
activities
of
structure-activity opiate
receptor
herein.
Methods
PC-Endorphin (18), Ph-endorphin (19) and (3,-MSH (20) were and p,-LPH were purified as thesized by the solid-phase method. p,was one of the tryptic fragments (T-17) described (8,9). Ph-LPH-(61-69) in the amino acid sequence determination of Ph-LPH (9). Met-enkephalin purchased from Bachem Laboratories (Marina de1 Reyes, Ca. ).
synpreviously utilized was
Acetone-treated Ph-endorphin was prepared by reaction of 12.8 mg of the peptide in 50% aqueous acetone (20 ml) for 21 hr at 24’. Partition chromatography on Sephadex G-50 in 1-butanol-pyridine-0.6 M NH40Ac (5:3:10) gave essentially one peak with Rf 0.48 (Rf of Ph-endorphin, 0.37) and 9.1 mg of product. On paper electrophoresis (pH 3.7, 400 V, 4 hr) the substance behaved as a more acidic material (Rf 0.48 relative to lysine as compared to Rf 0. 54 for P-endorphin). A sample heated in 0. 1% acetic acid for 10 min at 100” liberated acetone. All these properties parallel the behavior of acetone-oxytocin whose structure (21) consists of an isopropylidene bridge between the N-terminal amino group and the nitrogen of the peptide bond between sequence positions 1 and 2. (Anisylated-Glu31)-(3h-endorphin synthesis of h-endorphin (19) and was on Sephadex G-50 in 1-butanol-pyridine-0. gave a Rf of 0.53. Amino acid analysis, peptide mapping indicated an anisylated C-terminus.
endorphin (Eastman
(Homoserine5)-(3h-endorphin in 0. 5 ml 70% After Organic).
formic stirring
acid
was isolated as a by-product in the purified by partition chromatography 1% acetic acid (5:3:11) in which it ultraviolet spectral analysis and glutamic acid residue (22) at the
further
was produced by dissolving 10 mg phfollowed by addition of 20 mg CNBr at 24” for 24 hr in the dark, the solution
657
Vol. 74, No. 2, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
was diluted with a large volume of water and lyophilized. Peptide mapping and end-group analysis showed that no cleavage occurred. The Met-Thr bond has previously been shown to be resistant to CNBr cleavage in 70% formic acid (23). The amino acid analysis indicated that Met5 was converted to homoFormic acid treated-Ph-endorphin was produced as above serine by CNBr. except no CNBr was added. Carboxypeptidase A digestion of ph -endorphin 1.6 mg of Ph-endorphin in 0. 1 ml, pH 8.5, Tris-HCl carboxypeptidase A (Worthington). The suspension 8 hr and the peptide recovered by lyophilization.
was done buffer and was incubated
by dissolving adding 0. 05 mg at 37 a for
Tryptic digestion of Ph-endorphin was performed by dissolving Ph-endorphin in 0.2 ml 0.2 M NH4 OAc buffer (pH 8. 0). Trypsin (Serva), was added and the solution incubated at 37 ’ for 8 hr. The reaction was by addition of 1. 8 ml 0. 05 N HCl. Chymotryptic digestion of Ph-endorphin done as above except that chymotrypsin (Calbiochem) was used.
1. 1 mg 0.02 stopped was
Leucine aminopeptidase digested peptides were prepared as follows: PC-endorphin (0. 34 mg) and Met-enkephalin (0. 06 mg) were each dissolved in 0.1 ml pH 8. 5 Tris buffer. Leucine aminopeptidase (0. 007 mg, Worthington) was added to both samples, and the solutions incubated for 2 hr at 37’. The digests were acidified to pH 3, lyophilized, and portions removed for amino acid analysis 0 Narcotic agonist activities were measured from the depression of electrically-stimulated contractions of the guinea pig ileum prepared as Briefly, a 2-3 cm segment of ileum was mounted previously described (24). between internal and external platinum electrodes in a 25 ml bath containing Kreb’s solution (with 125 nM diphenyamine as antihistamine) at 37’ and aerated with 95% 0215% CO2. Tension changes evoked by rectilinear electrical pulses (0.4 msec duration, 0.1 Hz, 80 V) were recorded by a Grass 2 g) coupled to a model 7 Grass Isometric Pressure Transducer (tension, Polygraph. Peptides and normorphine were assayed on two ileum preparations at 3- 5 concentrations. Opioid activity was also assayed as the inhibition of stereospecific 10 Ci/mmole) binding to lysed rat f 3H]-morphine (New England Nuclear, synaptic plasma membranes prepared essentially as described (25). Synaptic plasma membranes (200 yg protein) were preincubated in 2 ml sodium-free HEPES buffer (26 mM, pH 7.5) at 25” for 10 min with peptides, morphine sulfate or dextrorphan. Next [ 3H] -morphine was added (4 nM) and the incuAssays were terminated by filtration followed by bation continued for 15 min. three 4 ml rinses with ice-cold buffer on glass fiber filters (Whatman GF/c). Filters were dried and counted by liquid scintillation spectrophotometry. Stereospecific opiate binding, the difference between [ 3H] -morphine binding in the presence of dextrorphan (1 x 10e6M) and morphine sulfate (1 x 10e6M) was 45% of the total binding. Peptides were assayed in quadruplicate; standard errors of the mean c-p. m. were always less than 6%.
the
IC50
Potencies (inhibiting
of peptides in molar concentration
both
assays - 50%)
658
were calculated as to that of PC-endorphin.
the
ratio
of
mg,
Vol. 74, No. 2, 1977
BIOCHEMICAL
Table Opiate
Activities
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I
of (3, -Endorphin
and
Related
Preparation
Peptides
Relative pig
Guinea ileum
Potency:k in Brain opiate receptor binding
Pc-endorphin
1.00
1.00
Ph-endorphin
1.00
1.00
Met-
0.25
0.
0.65
---
enkephalin
Normorphine
34
Ps-LPH
< 0.01
<
0.01
Ph-LPH
<
0.01
<
0.01
Pc-MSH
<
0.01
<
0.01
Ph-LPH-(61-69) Acetone
treated
-Ph-endorphin
(anisylated-Glu31) Formic
-Ph-endorphin
acid-treated-Sh-endorphin
(5-homoserine)-Ph-endorphin
<
p h -endorphin:
Carboxypeptidase
Ph-endorphin:
Chymotryptic
Ph-endorphin:
Tryptic
digest
Leucine
aminopeptidase
PC
-endorphin:
Met-enkephalin:
digest
* Potency of PC -endorphin -endorphin standard to PC in the guinea pig ileum binding assay.
to PC-endorphin are
summarized
activities as in
of
measured Table
<
digest
0.01
0.02
0.76
0.75
1.00
1.00
< 0.01
1.00
1.00
0.13
0.03
0.71
0.61
0.97
0.93
0.01
<
is defined as 1.00. Other preparations on a molar basis. IC50 of PC-endorphin: assay; 1. 2 -3.7 x 10s7M in the rat brain
Results Opiate
digest
aminopeptidase
0.26
0.01
A digest
Leucine
0.20
I.
and the
0.01 were compared 2.5-g. 0 x 10s8 opiate receptor
Discussion
various
peptides
in
the
guinea
In
the
ileum
pig assay
CFQ
and ileum PC-
enzymatic and
and
rat
digests brain
Ph-endorphins
relative
receptor
assays were
each
M
Vol. 74, No. 2, 1977
55%
more
potent
BIOCHEMICAL
than
normorphine,
Similarly
in
the
compared
to
(3-endorphins.
was In
opiate
somewhat
less
contrast,
when
tested
SC-MSH endorphin
to
the
which
incorporates
(opiate
receptor
Whereas residue
with
opiate
the
its at
In
opiate
activities
in as
well
Ph-endorphin residues
had
residues
other
potency reduced
/3,-LPH-(61-69),
may
be
little
of
in activities which
directly
(71%)
even
P,-LPH
and
or
SC-
by
a bridge
(ileum)
and
2%
anisylated in
the
carboxyl-terminal
the
interaction to
chymotrypsin
5-
at
opiate
activities. glutamic
of Ph-endorphin homoserine
diminished
be
expected On
residues.
the
no
specificity
within
A)
or
(trypsin)
limited
been
shown
to
again
the
digestion, and
still be
to
can
Trypsin
can
1%
decline
of Met5
indicating
(4),
were
26).
Tyr’-Gly’
only
essential,
with
A has
ileum
assay,
Ph-endorphin.
having
action.
(11,26).
either
also
between
a modest
conversion
(carboxypeptidase
opiate
in
Sh-Endorphin,
showed
aromatic
enzymes
l-9),
observed
to normorphine
activity.
Chymotrypsin
LPH-(61-91)
for
endorphin these
no
at
(see
Tyr’,displayed
residue,
Carboxypeptidase porcine
of
addition,
assays.
as with
activities. from
group
of Ph-endorphin both
(34%)
to Sh-endorphin-(
activity
M
cyclized
contribute
receptors.
-6
x 10
potency
shown).
Tyr to
no
Met-enkephalin.
reduced
previously
antagonism
of Ph-endorphin
appears
potency Phe4
amino
acid
Hydrolysis
5.0
Sh-endorphin,
amino-terminal
the
showed
of
than
corresponding as
SC -MSH
not
treated
glutamic
abolished
-69))
naloxone-like
(data
active had
Met-enkephalin, and
show
assay)
its
acid
than
more
Met-enkephalin
concentration
ileum
C-terminal
assay,
Sh-LPH
failed
Acetone
its
potent
high
in
4-times
Sh-LPH-(61
at the
also
and
receptor
and
S,-
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
greater
expected
to
to
receptor than
the
be
produced
cleave
&-endOrphin
other
hand,
the
amino-terminal effects
cleave
the
digestion
Gly9’-Gln91
reduced
of the the
opiate dipeptide
of these
somewhat (61%).
activities by
vitro
nature
binding
of five
on --in
non-essential
however,
opiate
considerably
action
ph-
Interestingly, nonapeptide of trypsin
on
Vol. 74, No. 2, 1977
(3h-endorphin. or
BIOCHEMICAL
Therefore,
some
other
the
tryptic
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
trypsin
digest
or
fragment,
contains
fragments
in
undigested
&-endorphin
combination,
having
opiate
activity. PC-Endorphin aminopeptidase detected
was as
by
acid
showed
Met-enkephalin, lost
all
residue
by
protected
known
to
potent
[ D-Ala21
rapidly
P-endorphin greater
only
especially
resistance,
to
(28). Met-enkephalin at
differ
This work was Acknowledgements. National Institutes of Health (GM-2907) B.A.D. is a recipient of a Fellowship Metabolism and Digestive Diseases.
this
(27),
but
The
greater vivo
and from
in
digest
contrast,
to
part
NIDA grants the National
by
bond, the
amino
of Met-enkephalin and
plasma
readily
analgesic result
of
Tyrl-Gly’
brain
less
may
in
in
that
as
digest
Therefore,
amino-terminus,
supported
enzyme
of the
from
leucine
of tyrosine
activities;
Enzymes
--in its
1,
opiate
attack.
enkephalins
to
Table
digestion.
appears
with
amounts
hydrolysis
aminopeptidase
-Met-enkepahlin compared
of
hydrolysis
trace
in
stoichiometric
exopeptidase
inactivate
shown
dimunition
of PC-endorphin from
limited
of only
As
slight
leucine
very
liberation
showed
after
terminal
by
to
analysis.
which
activity
being
indicated
amino
PC-endorphin
susceptible
the
potency in
enzymic
a grant (DA-01314 Institute
part
are
more of
from
its
digestion.
from
the
and DA-00564). of Arthritis,
References 1.
2. 3. 4. 5. 6. 7.
Hughes, Morgan, Simantov, 2515-2519.
J., B.
Kosterlitz, H. W., Fothergill, L. Smith, T. W., A. and Morris, H. R. (1975) Nature 258, 577-579, R. and Snyder, J. H. (1976) Proc. Natlxcad. Sci.
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Li, C. H. and Chung, D. (1976) Proc. Natl. Acad. Sci. USA 73, 1145-1148. Bradbury, A. F., Smyth, D. G., Snell, C. R., Birdsall, N.?-.M. and Hulme, C. E. (1976) Nature 260, 793-795. Chrktien, M., Benjannet, S.,ragon, N., Seidah, N. G. and Lis, M. (1976) Biochem. Biophys. Res. Commun. 72, 472-478. D. and Doneen, B. A. (1976) Biochem. Biophys. Res. Li, C. H., Chung, Commun. 72, 1542-1547. Guillemin,R., Ling, N. and Burgus, R. (1976) S&ances Acad. Sci. Ser. 282, 783-785.
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L., Chr&ien, M. and Chung, D. (1966) Excerpta Med. Li, C. H., Barnafi, Int. Congr. Ser., 111, 349-364. Li, C. H. and ChuG D. (1976) Nature 260, 622-624. Belluzzi, J. D., Grant, N., Garsky, V=arantakis, D., Wise, C. 0. and Stein, L. (1976) Nature 260, 626-627. A. ZyBajusz, S., Cseh, G. and Szkkely, J. I. (1976) G&f, L. , Romai, FEBS Letters 64, 181-184. Loh, H. H., Txng, L. F., Wei, E. and Li, C. H. (1976) Proc. Natl. Acad. Sci. USA 73, 2895-2898. Tseng, LFF., Loh, H. H. and Li, C. H. (1976) Nature 263, 239-240. Chang, J-K., Fong, B. T.W., Pert, A. and Pert, C. B.(1976) Life Sci. 18, 1473-1482. Day, A. R., Lujin , M., Dewey, W. L., Harris, L. S., Redding, J. A. and Freer, R. J. (1976) Res. Commun. Chem. Path. Pharmacol. 14, 597-603. Terenius, L., Wohlstrbm, A., Lindeberg, G., Karlsson, S. and Ragnarsson, U. (1976) Biochem. Biophys. Res. Commun. 71, 175-179. Ling, N. and Guillemin, R. (1976) Proc. Natl. Acad. Sci. =A - 73, 3308-3310. Li, C. H., Lemaire, S., Yamashiro, D. and Doneen, B. A. (1976) Biochem. Biophys. Res. Commun. 71, 19-25. D., Tseng, L-F., and Loh, H. H. (1976) Li, C. H., Yamashiro, J. Med. Chem. (in press). D. and Lemaire, S. (1975) Biochem. 14, 953-956. Li, C. H., Yamashiro, Hruby, V. J., Yamashiro, D. and du Vigneaud, V. (1968) J. Amer. Chem. Sot. 90, 7106-7110. FeinbGg, R. S. and Merrifield, R. B. (1975) J. Amer. Chem. Sot. -’97 3485-3496. Schroeder, W. A., Shelton, J. B. and Shelton, J. R. (1969) Arch. Biochem. Biophys. 130, 551-556. Kosterlitz,. W., Lydon, R. T. and Watt, A. F. (1970) Brit. J. Pharmacol 39, 398-413. Whittaker, V. P. and Sheridan, M. N. (1965) J. Neurochem. 12, 363-372. Goldstein, A. and Li, C. H. (1976) Proc. Natl. Acad. Sci. USA Cox, B. M., 73, 1821-1823. Hambrook, J. M., Morgan, B. A., Rance, M. J. and Smith, C. F.C. (1976) Nature 262, 782. Pert, C. B. , Pert, A. , Chang, J-K., and Fong, B. T. W. (1976) Science 194, 330-332.
662