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Oxytocin biotransformation in the rat limbic brain: Chemical characterization of two oxytocin fragments and proposed pathway for oxytocin conversion
Vol.
97, No.
December
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATlONS
16, 1980
10051013
Pages
OXYTOCIN BIOTRANSFORMATION CHEMICAL CHARACTERIZATION
IN THE RAT LIMBIC
BRAIN:
OF TN0 OXYTOCIN FRAGMENTS AND
PROPOSED PATHWAY FOR OXYTOCIN CONVERSION J.P.H.
Burbach,
P. Schotman+
and E.R de Kloet
Rudolf Magnus Institute for Pharmacology, Medical Faculty, University of Utrecht, Vondellaan 6, and +Division of Molecular Neurobiology, Institute of Molecular Biology and Laboratory of Physiological Chemistry, University of Utrecht, Padualaan 8, Utrecht, The Netherlands Received
September
17,198O
SUMMARY Two peptide fragments of oxytocin were isolated by high-pressure liquid chromatography from digests of oxytocin obtained after exposure to a SPM preparation of the rat limbic brain. The structures of these peptides, being Gln-Asn-Cys(0)x-Pro-Ieu-GlyNH2 and Gln-Asn-Cys(-S-S-Cys)-Pro-Leu-GlyNH2, were combined with the determination assessed by quantitative amino acid analysis, of N-terminal end groups and cysteic acid residues after performic acid treatment. The fragments comprised the 4-9 and 1,4-9 sequences of oxytocin, respectively. The types of proteolytic enzymes involved in their formation are discussed and a pathway for the conversion of oxytocin by SPM is proposed. INTRODUCTION The neurohypophyseal to affect midbrain
brain
which
molecules,
elicit
tion
of the
activities
related
are thought are devoid central
in the central
which
studies, are
to mediate
effects
as well.
Therefore,
might
have been (1,2).
processes.
endocrine
Limbic
Fragments
effects
be a regulating
and of both
of their
proteolytic factor
shown
parent
fragmentaof their
system.
we have partially
involved
and memory
these
classical
hormones nervous
and vasopressin,
to learning
of the
neurohypophyseal
In previous peptidases
mechanisms
structures
hormones,
hormones , oxytocin
in the proteolytic
characterized conversion
SPM associated of oxytocin
Abbreviations: SPM = synaptosomal plasma membrane(s), HPLC = high-pressure quid chromatography, DNS= dansyl-, l-dimethylaminonaphthalene-S-sulfonyl-. The amino acid residue numbers refer to the primary structure of oxytocin: CysI-Tyr-Ile3-Gln-AsnS-Cys-Pro7-Leu-GlyNH2g. 1 4
1005
(3‘4). li-
0006-291X/80/231005-09$01.00/0 Copyright 0 1980 by Academic Press, Inc. AN rights of reproduction in any form reserved.
Vol.
97, No.
In these
3, 1980
BIOCHEMICAL
experiments
structure
the accumulation
was observed residue,
it
graphically
distinct
from
We termed
The present from oxytocin previously ed to point preparations
was devoid
paper
described our
this
and their data
routes
of the rat
This
of the
the C-terminal
describes
digests
BIOPHYSICAL
of an oxytocin
in the digests.
glycinamide
and Leu-GlyNH2.
AND
chemical
on oxytocin
in a pathway limbic
residue
and dipeptides,
tentatively isolation
oxytocin
of multiple
characterization. converting
for
fragment contained
tyrosine-2 tri-
fragment the
peptide
RESEARCH
oxytocin
peptidase conversion
COMMUNICATIONS
of unknown the
C-terminal
and chromatoPro-Leu-GlyNH2 x-9
(OXT x-9).
OXT x-9 These
components
and the
activities mediated
allowby SPM
brain.
MATERIALS AND METHODS Synthetic oxytocin, C$s-Tyr-Ile-Gln-Asn-Cys-Pro-Leu-GlyNH2, and its fragments 1-8, l-7, 1-6, 7-9 and 8-9 were kindly provided by Dr. H.M. Greven and Dr. J.W. van Nispen (Organon International B.V., Oss, The Netherlands). [9-GlyNH2-l-l4 C] -oxytocin was a generous gift of the late Dr. R. Walter (University of Illinois, Chicago, USA). A SPM fraction from rat limbic brain tissue (hippocampus, hypothalamus plus septum) was pre ared by the method of Zwiers et al. (5). Oxytocin (2x10 -E M; 4~10~ dpm of [14C-GlyNH2]-oxytocin was incubated with SPM preparations (1.7 mg protein/ml) at 37OC for 3 h in 1.5 ml 25 mM sodium phosphate buffer, pH 6.9 . The reaction was terminated by heating the suspension in a boiling water bath for 10 min and membranes were removed by centrifugation. The supernatant was subjected to HPLC fractionation. Reversed-phase HPLC of the oxytocin digests was carried out on a uBondapak Cl8 column (0.39 x 30 cm), which was eluted with a linear gradient over 25 min of 5% to 40% acidified methanol (1.5 ml acetic acid per liter methanol) in 10 mM ammonium acetate, pH 4.15, at a flow rate of 2 ml/min. The eluate was monitored continuously by UV absorbance at 210 nm and fractions of 1.0 ml were collected. Aliquots of the fractions were subjected to scintillation counting. At the guidance of the radioactivity distribution fractions were pooled and lyophilized after removal of methanol in vacua at 60°C. Freeze dried samples (circa 2 nmoles) were hydrolyzed with 6 M hydrogen chloride containing 1 I.~M thioglycolic acid in evacuated glass tubes in a constant boiling toluene bath (11OOC) for 22 h as described by Zwiers et al. (6). The amino acid composition was determined by automated analysis (TSM, Technicon) using a stainless steel column (0.21 x 18 cm) packed with Durrum DC-5A resin and fluorescence detection with o-phtaldialdehyde (7). Quantification using a computing integrator (Pye Unicam, DPlOl) was achieved by comparison to norleucine as internal standard and to standard mixtures of amino acids. The oxidative cleavage of disulfide bridges with performic acid was carried out as described previously (8,9). Briefly, performic acid was prepared by mixing 1 volume of 30% hydrogen peroxide and 19 VOlUmeS of 99% formic acid and was allowed to stand at room temperature for 2 h in a closed vessel. Performic acid (50 ~1) was added to the peptide material (3-4 nmoles) which was dissolved in 25 ~1 99% formic acid containing 5 ~1 anhydrous methanol.
1006
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
The reaction was carried out at -5OC to -1OOC for 2.5 h and was terminated by adding 400 ~1 distilled water. The samples were subsequently lyophilized. Dansylation of N-terminal amino acids was carried out essentially. according to Gray and Smith (10). After hydrolysis and lyophilization the residues routinely were taken up in 25 ~1 distilled water and extracted with 10 ~1 ethylacetate. For the identification of DNS-cysteic acid 10 ~1 pyridine-water (1 : 1, v/v) or ethanol-water-acetic acid (100 : 5 : 3, v/v/v) was added to the dried residues. DNS-amino acids were identified on doublefaced micropolyamide F-1700 sheets (5 x 5 cm; Schleicher & Schbll), which were developed in a three solvent system (11). DNS-cysteic acid was resolved from DNS-OH with a fourth solvent, 1 M ammonium hydroxyde-ethanol (1 : 1, v/v), run in the second dimension (11).
Incubation limbic
of
brain
yielded
was seen from of the
(fig.
1B).
glycinamide
while
intact
which
was previously
phoresis,
material
for
as indicated
by the
14 C-oxytocin
incubations. the yields
Dansyl glutamic pective peptides
fractions
volume
after
were
residue.
faintly
of radiolabeled from
1B).
by W in
fig.
(fractions
3-6), OXT x-8,
paper
electro-
was resolved
These
fractions
to prepare
sufficient
of oxytocin,
omitting
B and C
were
products
from parallel
the specific
B and fraction
of 14C-
activity
C from a single
obtained
incubation
respectively.
determination
of fractions
demonstrated that residue
fluorescent
incubations
, as
53-57).
It
In order
out and fractions
As calculated
and indicated
E (fractions
products.
HPLC distribution
This
of the column
HPLC fractionation.
analyses,
of fraction
detectable as indicated
C (fig.
rat
HPLC fractionation
peak by high-voltage
B and fraction
carried
also
pooled
in fraction
digestion
was the glutamine-
an additional,
the void
as a single
and 1.8 nmoles,
end group
acid
were
of the
14C-glycinamide after
were
Fractions
structural
oxytocin,
1.6 nmoles
in
fraction
radiolabeled
oxytocin,
1A).
heterogenous
the principal
a SPM preparation
the C-terminal
components
was collected
two components,
peptide
were
Several
detected
appeared
represented
retaining
eluted
oxytocin
with
of the radioactivity
at 210 nm (fig.
1B. Free
into
products
the distribution
digests
absorbance
['4C-GlyNH2]-oxytocin
the
the purity
of peptides
N-terminal
amino
of oxytocin. spot
B and C showed
was visible,
1007
acid
In fraction which
a single
in the resof both C, however,
did
DNS-
not
co-
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
10
s '; E 0"
6.
0
6
16
24
32
&O
46
56
61
72 froctm
nmba
Fisure 1. HPLC fractionation of a digest of oxytocin which was obtained by incubation with a SPM preparation for 3 h at pIi 6.9. Chromatography was performed by gradient elution with acidified methanol and ammonium acetate buffer. The HPX eluate was monitored continuously by IJV absorbance (A) and aliquots of the collected fractions were counted for radioactivity (B). For experimental details see Methods. Fractions were pooled as indicated by the horizontal bars (fractions A to E). The vertical arrows show the elution position of synthetic oxytocin and related fragments.
migrate of
with
fraction
B and
fraction
B as
oxytocin, two cystine
one
well
of
the
reference
fraction as
DNS-amino
C shown that
in
in
table
fraction
and
differed proline
in residues
mobility
in were
The
I indicated
C comprised
Gln-Asn-(Cys)-(Pro)-Leu-GlyNIi2.
peptides
acids.
not
the
This
finding
HPLC
system.
detected
1008
the
with
amino
acid
that
the
4 to was However,
the
compositions peptide
9 sequence surprising cysteine,
o-phtaldialdehyde
in of as
the
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
Table AMINO amino
ACID
COMMUNICATIONS
I
CCHPOSITION
position
acid
RESEARCH
OF HPLC FRACTIONS
in
fraction
B
fraction
C
oxytocin
Crs+ Tyr
1,6 2
0.0
0.1
1le
3
0.2
0.3
GlX
4
1.0
1.0
ASX
5
0.7
0.8
pro+
7
Leu
8
0.6
0.7
GUY
9
1.3
1.2
+Cysteine
and proline are not detected method. The indicated numbers of residues were obtained in the analyses by the highest The amino acids are those contained in
reagent
in
between
the To
C
subjected
to
this
experimental
fraction
acid
and
design,
in
the
reference
it
was
absent
in
showed
additionally
and
peptide
samples Based
on
cysteic
amino
acid
Thin
as
described
in
acid
content,
spot,
peptides. fraction
the
compositions, the
following
fraction
B:
Gln-Asn-Cys(0)x-Pro-Deu-GlyND2,
fraction
C:
Gln-Asn-Cys(S-S-Cys)-Pro-Ieu-GlyND2.
these
these
experiments l-6,
layer
was
expected,
method
ortho-DNS-tyrosine
performic fractions
arginine-vaso-
section. acid
that as
treated
was In
residues,
with
identified the
peptides,
chromatography
co-migrated
spot
As
difference
in
DNS-glutamic
which
This 8.
the
oxytocin.
with
the
amounts
residues.
oxytocin
acid.
pmole
reaction In
oxytocin,
to
of
bridge
cleavage
addition
the
the
cysteine
hydrolysis.
a fluorescent
from
the
cysteic
acid
fluorescence
that
a disulfide
synthetic
DNS-cysteic
C contained
tained
and
cystine
identify
in
of oxidative
o-phtaldialdehyde
anticipated
located
the
with
vasotocin,
used
and
to
compared
be
the
calculated by dividing common factor. the primary structure
was
possibility
dansylation
were
pressin,
acid
could the
to
It
analyses.
components
were prior
B and
acid
investigate
samples acid
amino
by
ob-
DNS-cysteic reference
derivative.
radioactivity,
N-terminal
structures
are
(x
= 0,1,2,3),
proposed:
end
groups
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
DISCUSSION Oxytocin
is
preparations lytic
obtained
process
accumulate.
amino
acid
as a single
were
resolved
primary
However,
the peptides acid
residues
suggested
is
and
in their
prior
to isolation.
is probably
very
residue
occurs
to determine
14
C-radioactivity,
peptides,
was attached
The remaining
sulfhydryl
to oxidation. oxidation,
residue
of
was absent
peptide
group
was
of cysteine-6,
As in the experiments it
form,
to the peptide
residue
of this
of
dansylation
the cysteine-1
bridge
in an oxidized
glycinamide
acid,
cysteine-1
the disulfide
with
The presence
performic
residue
the
respectively.
residues.
with
This
susceptible
of both
C-terminal
and the
detected
assessed.
acid
may represent
have been made to prevent
cysteine-6
were
was in agreement
to cysteine-6. that
fragments
composition,
treatment
it
proteo-
electrophoresis
structures
cysteine
this
this
have been
The 4 to 9 sequence
glutamic
that
which
allowed
SPM
peptide
paper
techniques
acid
Therefore,
linked
fragments,
high-voltage
with
During
and several
by HPLC and their
C after
cleaved
is
suggested
indicated
that
as CYST
no
the in the
structure.
The two isolated of the oxytocin acids
oxytocin
activity
of the peptide
involved
in its
is
about
known
peptides
molecule.
from
aminopeptidase bridge
after
differed
B, indicating
amino
two main
amino
in fraction
precautions
released
from different
bridge.
which
off
are
study
in fraction
by a disulfide
proposed
(3,4).
limbic
by dansylation
hydrolysis
however,
brain
of the N-terminal
as detected
oxytocin,
the rat
by their
residues
and acid
are associated
of the two peptides.
was indicated
cysteic
which
component
data
structure
the presence
by peptidases,
and isolated
The combined
which
from
In the present
previously (4),
converted
the tyrosine
In previous
studies
oxytocin
1,4-9
do not
aminopeptidases
(3,4).
prior
with
1010
successive
residues release
and the involvement
indicates
require
and isoleucine the
has been observed has been suggested
formation brain
lack
of an
The conserved that
of these
disulfide
the aminopeptidases
reduction
such a specificity.
of this
bond.
Pliska
Little et al.
Vol.
97, No.
8lOCHEMlCAL
3, 1980
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
OXYTDCIN
CVS-TVR-ILE-GLN-ASN-CYS-PRO-LEU-
GLvNH~
CP / PCE
5.2
Gin-Aan-Cyr-Pm-Lcu-GlyMM*
E”P I
XI = -s-s-cy* x2 - -5”. -S(Ol,
LN
+
GW,
Figure 2. Pathway for oxytocin conversion by SPM preparations of rat brain. The proteolytic events occurring in the N-terminal and C-terminal parts of the oxytocin molecule are presented as separate routes. Several types Of activities, which nay be involved in the conversion process, are indicated: Amp= aminopeptidase (12) CaP = carboxamidopeptidase (18,19) PCE = post-proline cleaving enzyme (20) CP = carboxypeptidase ExP = exopeptidase TPDO = thiol:protein-disulfide oxidoreductase (16.17)
have demonstrated ring
portion
the
of oxytocin
studies
suggest
can act
on oxytocin
ed slowly
cleavage
that
(13,14,15).
the tyrosine
Under relatively
suggesting our
by minced
arylamidases,
cerebral enzymes
that
while
with
residues
and acted
the
reduced
conditions the
cortex
isoleucine
rapidly hormone the
in the
preparations
purified
intact
(12).
on open nonaserved
activity,
and octa-
of oxytocin rapidly
releas-
in the presence
as substrate
appears
Other
from brain,
from oxytocin
degradation
residue
1011
bond
aminopeptidase-like
One such enzyme,
agents
experimental
slowly,
cysteinyl-tyrosyl
and isoleucine
of sulfhydryl-reducing peptides,
of the
(15). proceeds after
the
Vol.
97, No.
release
3, 1980
BIOCHEMICAL
of tyrosine
nonapeptide
oxytocin
initial
step,
rapidly
proceeding This
mechanism
indicates
aminopeptidase
action
(3,4). Leu-GlyNH2
supporting
the view
activity
(20)
digests,
which
activity
(18,19).
The various
pathway
and several
types
Several
molecules synthetic
are
distinctly
Leu-GlyNH2
(1,2).
for
Therefore,
may have a modulatory
(16,17)
is
low amounts
a
present.
of the C-terminal
of glycinamide
were
by a post-proline
was a minor
found,
cleaving
enzyme
by unidentified component
in the
of a carboxamjdopeptidase
routes
are
enzymes,
summarized
which
the neurohypophyseal
peptides
different
that
in a proposed
are known
to act
on
may serve
as
2). that
fragments
and suggests
to
portion
of the involvement
(fig.
amounts
in the C-terminal
l-8
of proteolytic
is
of the disulfide
of the dipeptide
convertive
residue
cleavages
amounts
oxytocin
has been postulated
precursor
oxytocin
in favour
are indicated
It
cases
is
Woreover,
and of
of rat
of Leu-GlyNH 2 formation
(15).
of a slow
SPM preparations
constant
cleavage
the open
in isolated
studies
by rapid
detect
in equimolar
enzyme
over
and accumulating
followed
exopeptidases
oxytocin,
occurs
that
COMMUNICATIONS
bond,
reduction 4-9
prevails
In these
not
the glutamine
require
reduction
we have demonstrated
of oxytocin
till
of oxytocin
that
we did
cysteinyl-tyrosyl
action
does not
RESEARCH
may be indicative
oxidoreductase-like
Recently,
dipeptide
experiments
of the
the detection
1,4-9
BIOPHYSICAL
arguments
the cleavage
thiol:protein-disulfide
brain
These
aminopeptidase
However,
oxytocin
1n these
1,2-9.
being
encountered. bridge.
(3,4).
AND
with
retain from
specific
the enzymes, role
functions
behavioural oxytocin
in the
hormones
in the brain
activities, itself,
which
in
(21,22). some
such as the dipeptide
involved
in the
conversion
central
effects
of this
of neuro-
peptide. REFERENCES 1. van Ree, J.M., Bohus, B., Pharmacol. 27, 1793-1800. 2. de Wied, D., and Versteeg, 3. Burbach, J.P.H., de Kloet, supp1. 225, 250.
Versteeg,
D.H.G.,
and de Wied,
D.H.G. (1979) Fed. E.R., and de Wied,
1012
D. (1978)
Biochem.
Proc. 38, 2348-2354. D. (1979) Acta Endocrinol.
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
4. Burbach, J.P.H., de Kloet, E.R., and de Wied, D. (1980) Brain Res., in press. H., Veldhuis, H.D., Schotman, P., and Gispen, W.H. (1976) Neurochem. 5. Zwiers, Res. 1, 669-677. 6. Zwiers, H., Schotman, P., and Gispen, W.H. (1980) 3. Neurochem. 34, 16891699. 7. Zwiers, H., Verhoef, J., Schotman, P., and Gispen, W.H. (1980) FEBS Lett. 112, 168-172. Vol. XI, Enzyme Structure a. Hirs, C.H.W. (1967) In: Methods in Enzymology, (Hirs, C.H.W., ed.), pp. 197-199, Academic Press, New York and London. E., and Fontana, A. (1975). In: Molecular Biology, Biochemistry 9. Scoffone, and Biophysics, Vol. 8, Protein Sequence Determination (Needleman, S.B., ea.), pp. 162-201, Springer Verlag, Berlin. (1979) Anal. Biochem. 33, 36-42. 10. Gray, W.R., and Smith, J.F. 11. Narita, K., Matsuo, H., and Nakajima, T. (1975) In: Molecular Biology, BioVol. 8, Protein Sequence Determination (Needleman, chemistry and Biophysics, Springer Verlag, Berlin. S.B., ea.), pp. 30-103, 12. Pliska, V., Thorn, N.A., and Vilhardt, M. (1971) Acta Endocrinol. 67, 12-22. H-D. (1975) Acta Endocrinol. 78, 634-648. 13. Kuhl, H., and Taubert, 14. Kuhl, H., Sandow, J., Krauss, B., and Taubert, H-D. (1979) Neuroendocrinology 28, 339-348. 15. Marks, N., Abrash, L., and Walter, R. (1973) Proc. Sot. Exp. Biol. Med. 142, 455-460. L.A., Ferrier, B.M., and Celhoffer, L. (1972) Can. J. Biochem. 50, 16. Branda, 507-509. W.B. (1974) Nature 251, 237-239. 17. Small, C.W., and Watkins, Schwartz, I.L., and Walter, R. (1969) Proc. Natl. Acad. Sci. 18. Glass, J.D., USA 63, 1426-1430. 19. Simmons, W-M., and Walter, R. (1980) Biochemistry 19, 39-48. 20. Koida, M., and Walter, R. (1976) J. Biol. Chem. 251, 7593-7599. 21. Walter, R. (1974) In: Psychoneuroendocrinology (Hatotani, N., ea.), pp. 285-294, Karger, Basel. 22. de Wied, D. (1977) Life Sci. 20, 195-204.
1013
97, No.
December
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATlONS
16, 1980
10051013
Pages
OXYTOCIN BIOTRANSFORMATION CHEMICAL CHARACTERIZATION
IN THE RAT LIMBIC
BRAIN:
OF TN0 OXYTOCIN FRAGMENTS AND
PROPOSED PATHWAY FOR OXYTOCIN CONVERSION J.P.H.
Burbach,
P. Schotman+
and E.R de Kloet
Rudolf Magnus Institute for Pharmacology, Medical Faculty, University of Utrecht, Vondellaan 6, and +Division of Molecular Neurobiology, Institute of Molecular Biology and Laboratory of Physiological Chemistry, University of Utrecht, Padualaan 8, Utrecht, The Netherlands Received
September
17,198O
SUMMARY Two peptide fragments of oxytocin were isolated by high-pressure liquid chromatography from digests of oxytocin obtained after exposure to a SPM preparation of the rat limbic brain. The structures of these peptides, being Gln-Asn-Cys(0)x-Pro-Ieu-GlyNH2 and Gln-Asn-Cys(-S-S-Cys)-Pro-Leu-GlyNH2, were combined with the determination assessed by quantitative amino acid analysis, of N-terminal end groups and cysteic acid residues after performic acid treatment. The fragments comprised the 4-9 and 1,4-9 sequences of oxytocin, respectively. The types of proteolytic enzymes involved in their formation are discussed and a pathway for the conversion of oxytocin by SPM is proposed. INTRODUCTION The neurohypophyseal to affect midbrain
brain
which
molecules,
elicit
tion
of the
activities
related
are thought are devoid central
in the central
which
studies, are
to mediate
effects
as well.
Therefore,
might
have been (1,2).
processes.
endocrine
Limbic
Fragments
effects
be a regulating
and of both
of their
proteolytic factor
shown
parent
fragmentaof their
system.
we have partially
involved
and memory
these
classical
hormones nervous
and vasopressin,
to learning
of the
neurohypophyseal
In previous peptidases
mechanisms
structures
hormones,
hormones , oxytocin
in the proteolytic
characterized conversion
SPM associated of oxytocin
Abbreviations: SPM = synaptosomal plasma membrane(s), HPLC = high-pressure quid chromatography, DNS= dansyl-, l-dimethylaminonaphthalene-S-sulfonyl-. The amino acid residue numbers refer to the primary structure of oxytocin: CysI-Tyr-Ile3-Gln-AsnS-Cys-Pro7-Leu-GlyNH2g. 1 4
1005
(3‘4). li-
0006-291X/80/231005-09$01.00/0 Copyright 0 1980 by Academic Press, Inc. AN rights of reproduction in any form reserved.
Vol.
97, No.
In these
3, 1980
BIOCHEMICAL
experiments
structure
the accumulation
was observed residue,
it
graphically
distinct
from
We termed
The present from oxytocin previously ed to point preparations
was devoid
paper
described our
this
and their data
routes
of the rat
This
of the
the C-terminal
describes
digests
BIOPHYSICAL
of an oxytocin
in the digests.
glycinamide
and Leu-GlyNH2.
AND
chemical
on oxytocin
in a pathway limbic
residue
and dipeptides,
tentatively isolation
oxytocin
of multiple
characterization. converting
for
fragment contained
tyrosine-2 tri-
fragment the
peptide
RESEARCH
oxytocin
peptidase conversion
COMMUNICATIONS
of unknown the
C-terminal
and chromatoPro-Leu-GlyNH2 x-9
(OXT x-9).
OXT x-9 These
components
and the
activities mediated
allowby SPM
brain.
MATERIALS AND METHODS Synthetic oxytocin, C$s-Tyr-Ile-Gln-Asn-Cys-Pro-Leu-GlyNH2, and its fragments 1-8, l-7, 1-6, 7-9 and 8-9 were kindly provided by Dr. H.M. Greven and Dr. J.W. van Nispen (Organon International B.V., Oss, The Netherlands). [9-GlyNH2-l-l4 C] -oxytocin was a generous gift of the late Dr. R. Walter (University of Illinois, Chicago, USA). A SPM fraction from rat limbic brain tissue (hippocampus, hypothalamus plus septum) was pre ared by the method of Zwiers et al. (5). Oxytocin (2x10 -E M; 4~10~ dpm of [14C-GlyNH2]-oxytocin was incubated with SPM preparations (1.7 mg protein/ml) at 37OC for 3 h in 1.5 ml 25 mM sodium phosphate buffer, pH 6.9 . The reaction was terminated by heating the suspension in a boiling water bath for 10 min and membranes were removed by centrifugation. The supernatant was subjected to HPLC fractionation. Reversed-phase HPLC of the oxytocin digests was carried out on a uBondapak Cl8 column (0.39 x 30 cm), which was eluted with a linear gradient over 25 min of 5% to 40% acidified methanol (1.5 ml acetic acid per liter methanol) in 10 mM ammonium acetate, pH 4.15, at a flow rate of 2 ml/min. The eluate was monitored continuously by UV absorbance at 210 nm and fractions of 1.0 ml were collected. Aliquots of the fractions were subjected to scintillation counting. At the guidance of the radioactivity distribution fractions were pooled and lyophilized after removal of methanol in vacua at 60°C. Freeze dried samples (circa 2 nmoles) were hydrolyzed with 6 M hydrogen chloride containing 1 I.~M thioglycolic acid in evacuated glass tubes in a constant boiling toluene bath (11OOC) for 22 h as described by Zwiers et al. (6). The amino acid composition was determined by automated analysis (TSM, Technicon) using a stainless steel column (0.21 x 18 cm) packed with Durrum DC-5A resin and fluorescence detection with o-phtaldialdehyde (7). Quantification using a computing integrator (Pye Unicam, DPlOl) was achieved by comparison to norleucine as internal standard and to standard mixtures of amino acids. The oxidative cleavage of disulfide bridges with performic acid was carried out as described previously (8,9). Briefly, performic acid was prepared by mixing 1 volume of 30% hydrogen peroxide and 19 VOlUmeS of 99% formic acid and was allowed to stand at room temperature for 2 h in a closed vessel. Performic acid (50 ~1) was added to the peptide material (3-4 nmoles) which was dissolved in 25 ~1 99% formic acid containing 5 ~1 anhydrous methanol.
1006
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
The reaction was carried out at -5OC to -1OOC for 2.5 h and was terminated by adding 400 ~1 distilled water. The samples were subsequently lyophilized. Dansylation of N-terminal amino acids was carried out essentially. according to Gray and Smith (10). After hydrolysis and lyophilization the residues routinely were taken up in 25 ~1 distilled water and extracted with 10 ~1 ethylacetate. For the identification of DNS-cysteic acid 10 ~1 pyridine-water (1 : 1, v/v) or ethanol-water-acetic acid (100 : 5 : 3, v/v/v) was added to the dried residues. DNS-amino acids were identified on doublefaced micropolyamide F-1700 sheets (5 x 5 cm; Schleicher & Schbll), which were developed in a three solvent system (11). DNS-cysteic acid was resolved from DNS-OH with a fourth solvent, 1 M ammonium hydroxyde-ethanol (1 : 1, v/v), run in the second dimension (11).
Incubation limbic
of
brain
yielded
was seen from of the
(fig.
1B).
glycinamide
while
intact
which
was previously
phoresis,
material
for
as indicated
by the
14 C-oxytocin
incubations. the yields
Dansyl glutamic pective peptides
fractions
volume
after
were
residue.
faintly
of radiolabeled from
1B).
by W in
fig.
(fractions
3-6), OXT x-8,
paper
electro-
was resolved
These
fractions
to prepare
sufficient
of oxytocin,
omitting
B and C
were
products
from parallel
the specific
B and fraction
of 14C-
activity
C from a single
obtained
incubation
respectively.
determination
of fractions
demonstrated that residue
fluorescent
incubations
, as
53-57).
It
In order
out and fractions
As calculated
and indicated
E (fractions
products.
HPLC distribution
This
of the column
HPLC fractionation.
analyses,
of fraction
detectable as indicated
C (fig.
rat
HPLC fractionation
peak by high-voltage
B and fraction
carried
also
pooled
in fraction
digestion
was the glutamine-
an additional,
the void
as a single
and 1.8 nmoles,
end group
acid
were
of the
14C-glycinamide after
were
Fractions
structural
oxytocin,
1.6 nmoles
in
fraction
radiolabeled
oxytocin,
1A).
heterogenous
the principal
a SPM preparation
the C-terminal
components
was collected
two components,
peptide
were
Several
detected
appeared
represented
retaining
eluted
oxytocin
with
of the radioactivity
at 210 nm (fig.
1B. Free
into
products
the distribution
digests
absorbance
['4C-GlyNH2]-oxytocin
the
the purity
of peptides
N-terminal
amino
of oxytocin. spot
B and C showed
was visible,
1007
acid
In fraction which
a single
in the resof both C, however,
did
DNS-
not
co-
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
10
s '; E 0"
6.
0
6
16
24
32
&O
46
56
61
72 froctm
nmba
Fisure 1. HPLC fractionation of a digest of oxytocin which was obtained by incubation with a SPM preparation for 3 h at pIi 6.9. Chromatography was performed by gradient elution with acidified methanol and ammonium acetate buffer. The HPX eluate was monitored continuously by IJV absorbance (A) and aliquots of the collected fractions were counted for radioactivity (B). For experimental details see Methods. Fractions were pooled as indicated by the horizontal bars (fractions A to E). The vertical arrows show the elution position of synthetic oxytocin and related fragments.
migrate of
with
fraction
B and
fraction
B as
oxytocin, two cystine
one
well
of
the
reference
fraction as
DNS-amino
C shown that
in
in
table
fraction
and
differed proline
in residues
mobility
in were
The
I indicated
C comprised
Gln-Asn-(Cys)-(Pro)-Leu-GlyNIi2.
peptides
acids.
not
the
This
finding
HPLC
system.
detected
1008
the
with
amino
acid
that
the
4 to was However,
the
compositions peptide
9 sequence surprising cysteine,
o-phtaldialdehyde
in of as
the
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
Table AMINO amino
ACID
COMMUNICATIONS
I
CCHPOSITION
position
acid
RESEARCH
OF HPLC FRACTIONS
in
fraction
B
fraction
C
oxytocin
Crs+ Tyr
1,6 2
0.0
0.1
1le
3
0.2
0.3
GlX
4
1.0
1.0
ASX
5
0.7
0.8
pro+
7
Leu
8
0.6
0.7
GUY
9
1.3
1.2
+Cysteine
and proline are not detected method. The indicated numbers of residues were obtained in the analyses by the highest The amino acids are those contained in
reagent
in
between
the To
C
subjected
to
this
experimental
fraction
acid
and
design,
in
the
reference
it
was
absent
in
showed
additionally
and
peptide
samples Based
on
cysteic
amino
acid
Thin
as
described
in
acid
content,
spot,
peptides. fraction
the
compositions, the
following
fraction
B:
Gln-Asn-Cys(0)x-Pro-Deu-GlyND2,
fraction
C:
Gln-Asn-Cys(S-S-Cys)-Pro-Ieu-GlyND2.
these
these
experiments l-6,
layer
was
expected,
method
ortho-DNS-tyrosine
performic fractions
arginine-vaso-
section. acid
that as
treated
was In
residues,
with
identified the
peptides,
chromatography
co-migrated
spot
As
difference
in
DNS-glutamic
which
This 8.
the
oxytocin.
with
the
amounts
residues.
oxytocin
acid.
pmole
reaction In
oxytocin,
to
of
bridge
cleavage
addition
the
the
cysteine
hydrolysis.
a fluorescent
from
the
cysteic
acid
fluorescence
that
a disulfide
synthetic
DNS-cysteic
C contained
tained
and
cystine
identify
in
of oxidative
o-phtaldialdehyde
anticipated
located
the
with
vasotocin,
used
and
to
compared
be
the
calculated by dividing common factor. the primary structure
was
possibility
dansylation
were
pressin,
acid
could the
to
It
analyses.
components
were prior
B and
acid
investigate
samples acid
amino
by
ob-
DNS-cysteic reference
derivative.
radioactivity,
N-terminal
structures
are
(x
= 0,1,2,3),
proposed:
end
groups
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
DISCUSSION Oxytocin
is
preparations lytic
obtained
process
accumulate.
amino
acid
as a single
were
resolved
primary
However,
the peptides acid
residues
suggested
is
and
in their
prior
to isolation.
is probably
very
residue
occurs
to determine
14
C-radioactivity,
peptides,
was attached
The remaining
sulfhydryl
to oxidation. oxidation,
residue
of
was absent
peptide
group
was
of cysteine-6,
As in the experiments it
form,
to the peptide
residue
of this
of
dansylation
the cysteine-1
bridge
in an oxidized
glycinamide
acid,
cysteine-1
the disulfide
with
The presence
performic
residue
the
respectively.
residues.
with
This
susceptible
of both
C-terminal
and the
detected
assessed.
acid
may represent
have been made to prevent
cysteine-6
were
was in agreement
to cysteine-6. that
fragments
composition,
treatment
it
proteo-
electrophoresis
structures
cysteine
this
this
have been
The 4 to 9 sequence
glutamic
that
which
allowed
SPM
peptide
paper
techniques
acid
Therefore,
linked
fragments,
high-voltage
with
During
and several
by HPLC and their
C after
cleaved
is
suggested
indicated
that
as CYST
no
the in the
structure.
The two isolated of the oxytocin acids
oxytocin
activity
of the peptide
involved
in its
is
about
known
peptides
molecule.
from
aminopeptidase bridge
after
differed
B, indicating
amino
two main
amino
in fraction
precautions
released
from different
bridge.
which
off
are
study
in fraction
by a disulfide
proposed
(3,4).
limbic
by dansylation
hydrolysis
however,
brain
of the N-terminal
as detected
oxytocin,
the rat
by their
residues
and acid
are associated
of the two peptides.
was indicated
cysteic
which
component
data
structure
the presence
by peptidases,
and isolated
The combined
which
from
In the present
previously (4),
converted
the tyrosine
In previous
studies
oxytocin
1,4-9
do not
aminopeptidases
(3,4).
prior
with
1010
successive
residues release
and the involvement
indicates
require
and isoleucine the
has been observed has been suggested
formation brain
lack
of an
The conserved that
of these
disulfide
the aminopeptidases
reduction
such a specificity.
of this
bond.
Pliska
Little et al.
Vol.
97, No.
8lOCHEMlCAL
3, 1980
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
OXYTDCIN
CVS-TVR-ILE-GLN-ASN-CYS-PRO-LEU-
GLvNH~
CP / PCE
5.2
Gin-Aan-Cyr-Pm-Lcu-GlyMM*
E”P I
XI = -s-s-cy* x2 - -5”. -S(Ol,
LN
+
GW,
Figure 2. Pathway for oxytocin conversion by SPM preparations of rat brain. The proteolytic events occurring in the N-terminal and C-terminal parts of the oxytocin molecule are presented as separate routes. Several types Of activities, which nay be involved in the conversion process, are indicated: Amp= aminopeptidase (12) CaP = carboxamidopeptidase (18,19) PCE = post-proline cleaving enzyme (20) CP = carboxypeptidase ExP = exopeptidase TPDO = thiol:protein-disulfide oxidoreductase (16.17)
have demonstrated ring
portion
the
of oxytocin
studies
suggest
can act
on oxytocin
ed slowly
cleavage
that
(13,14,15).
the tyrosine
Under relatively
suggesting our
by minced
arylamidases,
cerebral enzymes
that
while
with
residues
and acted
the
reduced
conditions the
cortex
isoleucine
rapidly hormone the
in the
preparations
purified
intact
(12).
on open nonaserved
activity,
and octa-
of oxytocin rapidly
releas-
in the presence
as substrate
appears
Other
from brain,
from oxytocin
degradation
residue
1011
bond
aminopeptidase-like
One such enzyme,
agents
experimental
slowly,
cysteinyl-tyrosyl
and isoleucine
of sulfhydryl-reducing peptides,
of the
(15). proceeds after
the
Vol.
97, No.
release
3, 1980
BIOCHEMICAL
of tyrosine
nonapeptide
oxytocin
initial
step,
rapidly
proceeding This
mechanism
indicates
aminopeptidase
action
(3,4). Leu-GlyNH2
supporting
the view
activity
(20)
digests,
which
activity
(18,19).
The various
pathway
and several
types
Several
molecules synthetic
are
distinctly
Leu-GlyNH2
(1,2).
for
Therefore,
may have a modulatory
(16,17)
is
low amounts
a
present.
of the C-terminal
of glycinamide
were
by a post-proline
was a minor
found,
cleaving
enzyme
by unidentified component
in the
of a carboxamjdopeptidase
routes
are
enzymes,
summarized
which
the neurohypophyseal
peptides
different
that
in a proposed
are known
to act
on
may serve
as
2). that
fragments
and suggests
to
portion
of the involvement
(fig.
amounts
in the C-terminal
l-8
of proteolytic
is
of the disulfide
of the dipeptide
convertive
residue
cleavages
amounts
oxytocin
has been postulated
precursor
oxytocin
in favour
are indicated
It
cases
is
Woreover,
and of
of rat
of Leu-GlyNH 2 formation
(15).
of a slow
SPM preparations
constant
cleavage
the open
in isolated
studies
by rapid
detect
in equimolar
enzyme
over
and accumulating
followed
exopeptidases
oxytocin,
occurs
that
COMMUNICATIONS
bond,
reduction 4-9
prevails
In these
not
the glutamine
require
reduction
we have demonstrated
of oxytocin
till
of oxytocin
that
we did
cysteinyl-tyrosyl
action
does not
RESEARCH
may be indicative
oxidoreductase-like
Recently,
dipeptide
experiments
of the
the detection
1,4-9
BIOPHYSICAL
arguments
the cleavage
thiol:protein-disulfide
brain
These
aminopeptidase
However,
oxytocin
1n these
1,2-9.
being
encountered. bridge.
(3,4).
AND
with
retain from
specific
the enzymes, role
functions
behavioural oxytocin
in the
hormones
in the brain
activities, itself,
which
in
(21,22). some
such as the dipeptide
involved
in the
conversion
central
effects
of this
of neuro-
peptide. REFERENCES 1. van Ree, J.M., Bohus, B., Pharmacol. 27, 1793-1800. 2. de Wied, D., and Versteeg, 3. Burbach, J.P.H., de Kloet, supp1. 225, 250.
Versteeg,
D.H.G.,
and de Wied,
D.H.G. (1979) Fed. E.R., and de Wied,
1012
D. (1978)
Biochem.
Proc. 38, 2348-2354. D. (1979) Acta Endocrinol.
Vol.
97, No.
3, 1980
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
4. Burbach, J.P.H., de Kloet, E.R., and de Wied, D. (1980) Brain Res., in press. H., Veldhuis, H.D., Schotman, P., and Gispen, W.H. (1976) Neurochem. 5. Zwiers, Res. 1, 669-677. 6. Zwiers, H., Schotman, P., and Gispen, W.H. (1980) 3. Neurochem. 34, 16891699. 7. Zwiers, H., Verhoef, J., Schotman, P., and Gispen, W.H. (1980) FEBS Lett. 112, 168-172. Vol. XI, Enzyme Structure a. Hirs, C.H.W. (1967) In: Methods in Enzymology, (Hirs, C.H.W., ed.), pp. 197-199, Academic Press, New York and London. E., and Fontana, A. (1975). In: Molecular Biology, Biochemistry 9. Scoffone, and Biophysics, Vol. 8, Protein Sequence Determination (Needleman, S.B., ea.), pp. 162-201, Springer Verlag, Berlin. (1979) Anal. Biochem. 33, 36-42. 10. Gray, W.R., and Smith, J.F. 11. Narita, K., Matsuo, H., and Nakajima, T. (1975) In: Molecular Biology, BioVol. 8, Protein Sequence Determination (Needleman, chemistry and Biophysics, Springer Verlag, Berlin. S.B., ea.), pp. 30-103, 12. Pliska, V., Thorn, N.A., and Vilhardt, M. (1971) Acta Endocrinol. 67, 12-22. H-D. (1975) Acta Endocrinol. 78, 634-648. 13. Kuhl, H., and Taubert, 14. Kuhl, H., Sandow, J., Krauss, B., and Taubert, H-D. (1979) Neuroendocrinology 28, 339-348. 15. Marks, N., Abrash, L., and Walter, R. (1973) Proc. Sot. Exp. Biol. Med. 142, 455-460. L.A., Ferrier, B.M., and Celhoffer, L. (1972) Can. J. Biochem. 50, 16. Branda, 507-509. W.B. (1974) Nature 251, 237-239. 17. Small, C.W., and Watkins, Schwartz, I.L., and Walter, R. (1969) Proc. Natl. Acad. Sci. 18. Glass, J.D., USA 63, 1426-1430. 19. Simmons, W-M., and Walter, R. (1980) Biochemistry 19, 39-48. 20. Koida, M., and Walter, R. (1976) J. Biol. Chem. 251, 7593-7599. 21. Walter, R. (1974) In: Psychoneuroendocrinology (Hatotani, N., ea.), pp. 285-294, Karger, Basel. 22. de Wied, D. (1977) Life Sci. 20, 195-204.
1013