- Email: [email protected]
cholecystokinin (CCK) releasing-peptide (monitor peptide) with epidermal growth factor for binding to 3T3 fibroblasts
Vol. 145, No. 2, 1987 June 15, 1987
BIOCHEMICAL
COMPETITION
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 646-650
OF A GROWTH STIMULATING-/CHOLECYSTOKININ
RELEASING-PEPTIDE
(MONITOR PEPTIDE)
(CCK)
WITH EPIDERMAL
GROWTH FACTOR FOR BINDING TO 3T3 FIBROBLASTS Shin-Ichi
Fukuoka,
+&Institute of Agriculture,
Faculty April
Fushiki, Yasuo Kitagawa", Kazuo Iwail
Etsuro
Laboratory of Nutritional Chemistry, of Food Science and Technology, Faculty Kyoto University, Kyoto 606, Japan
Department
Received
Tohru
20,
for
Sugimoto*,
and
of Agriculture,
Biochemical Regulation, Nagoya University, Nagoya
464,
Japan
1987
SUMMARY: The growth stimulating-/cholecystokinin releasing-peptide (CCK) (monitor peptide) is a peptide purified from rat bile-pancreatic juice on the basis of its stimulatory activity toward pancreatic enzyme secretion. Its multiple functions and peptide sequence suggested that it is distinct from epidermal growth factor (EGF). However, we found that the peptide competes with ['=I]-EGF in the binding to Swiss 3T3 fibroblast cells to almost the same extent as unlabeled EGF does. [1251]-EGF binding was inhibited by 50% by the peptide at 82.8 rig/ml and by unlabeled EGF at 71.4 rig/ml. This suggests that the growth stimulating effect of the peptide on 3T3 fibroblasts is mediated via the EGF receptor, and also suggests that the partial homologous sequence between monitor peptide and EGF is required for the receptor binding, or that o 1987 Academic Press, Inc. the EGF receptor has a broad ligand specificity.
We previously about
6,500,
activity
that
response
this
juice
enzyme
activity,
activity
the
i.ntestine.
Swiss
should
$1.50
0 1987 by Academic Press, of reproduction in any form
Inc. reserved.
646
is
its
found
rat
intestine(Z). enzyme
also with
Professor,
We
by sereval
to
its
Kyoto
lines from
its
CCK-releasing
exhibits
almost
to
secretion
peptide"(5)
addition
of
stimulatory was
supported
peptide
weight
peptide
the
as "monitor
3T3 fibroblasts
be addressed;
of
of pancreatic
In
monitor
molecular
basis
in
and it
peptide
a
The
as a mediator
that
toward
on the
secretion(l).
intake(l),
the
demonstrated
To whom correspondence
0006-291X/87
acts
protein
in
with
activity
We designated role
we
stimulating
peptide
to dietary
physiological
Conright All rights
a peptide,
bile-pancreatic
pancreatic
of evidence(3,b).
1
rat
and purified
cholecystokinin(CCK)-releasing
postulate in
from
toward
exhibit
found
the
a
growth
same
potency
University.
BIOCHEMICAL
Vol. 145, No. 2, 1987 as epidermal complete the
growth
amino
peptide
that
acid
inhibitor
monitor
peptide
other.
It
inhibitor
growth
of monitor
61 amino that
acid of
(pancreatic is
suggests
and has
highly
conserved
related
to other
that
monitor
peptide
to 3T3 fibroblasts activity
trypsin
is
competition
to be
was investigated peptide
an
indicated
amino
acid
region
in
than
they
that
Kazal
type
However,
are
into
the
sequence
PSTI).
classified
to
Kazal
each type
peptide(5).
monitor
to elucidate is
determine
results
PST&
related by
to
inhibitor,
mammalian
PST1 or its
of this
and the
residues
less
communication,
stimulating
a
RESEARCH COMMUNICATIONS
we succeeded
peptide,
secretory
and may be one of rat In this
binding
sequence
resembles
trypsin
Recently
factor(EGF)(6).
comprises
closely
AND BIOPHYSICAL
mediated
peptide
in
whether via
['%I]-EGF or
not
the
the EGF receptor.
MATERIALS AND METHODS: Purification of the growth stimulating-/CCK releasing-peptide (monitor peptide) was carried out by the method described elsewhere(5,6). The purity of the peptide was demonstrated by the following lines of evidence: The sharp single peak seen on high performance liquid chromatography (HPLC) with a reverse phase column (Bio-Rad RP 304), as shown in Fig.1, the single band seen on SDS-PAGE(l), and the N-terminal amino acid sequencing results(S). Mouse EGF was purchased from Wako Pure Chemicals (Japan). This EGF preparation was purified by the method described(7), and its purity was investigated by SDS-PAGE. EGF and monitor peptide were separated as distinct peaks on reverse phase HPLC (Fig.1). [lzI]-EGF was obtained from Amersham. Other chemicals used were of the highest purity available from commercial sources.
THE PURIFIED PEPTIDE
50
0
T I M E (min) Fig.1. Reverse phase HPLC analysis of EGF and the growth stimulating-/ EGF (100ng) and/or cholecystokinin (CCK) releasing-peptide (monitor peptide). x 250 monitor peptide (100ng) were applied onto a Bio-Rad RP 304 column (4.6 mm) in a HPLC system with a Model 660 programmer and a Model 550 pumps (Waters). Elution was carried out with a gradient of acetonitrile, as indicated in the figure by the broken line. 647
BIOCHEMICAL
Vol. 145, No. 2, 1987
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Cell culture: The stock cultures of Swiss 3T3 fibroblast cells were maintained in 6Omm dishes (NUNC, Denmark) in Dulbecco's modified Eagle's medium (DMEM) containing 10% fetal bovine serum (FBS, M.A.Bioproducts), penicillin (50units/ml) and streptomycin (25&ml) (the standard medium) at 37°C under a humidified atmosphere of 5% CO2 and 95% air (8). To prepare cultures for [i251]-EGF binding 0.3 ml of a cell suspension (5x104cells/ml) was inoculated and into each well of 'a 24-well (16mm diameter) microtest plate (NUNC), followed by incubation at 37°C under the above conditions for 24 hr. ['%I]-EGF binding radioreceptor assay: The standard medium was removed 0.3 ml and the surface of cultures was washed once with serum-free DMEM. Then amounts of DMEM containing ['%I]-EGF (50ng/ml, 2346 cpm/ng) and the indicated of unlabeled EGF or the purified monitor peptide were added to each well. After incubation at 37°C for 1 hr, unbound [I25 I]-EGF was removed by washing the of 3 ml of phosphate-buffered saline cells five times with a total volume (O.l5M, pH 7.4) containing 0.1% bovine serum albumin. The cells in each well the radioactivity of the cell were lysed with 0.3ml of 0.5N NaOH, and then lysate was measured with an Aloka autowell gammacounter. RESULTS AND DISCUSSION The EGF receptor replacement
of
replacement
with
15-500
rig/ml.
however,
about
(Fig.2).
The
on 3T3 fibroblasts
bound
['251]-EGF
unlabeled
remaining
with
over
EGF was added
the
initial
radioactivity
UNLABELED
demonstrated
unlabeled
EGF was observed
When unlabeled 25 % of
can be
EGF. the
in
FACTOR
the
binding presence
ADDED
In
the
our
specific
range
up to 2,500 was of
the
study,
concentration
at concentrations
[1251]-EGF
by
still excess
of
rig/ml, observed EGF
(rig/ml)
Fig.2.
Competition by unlabeled EGF (0) and the purified growth stimulating-/ cholecystokinin(CCK) releasing-peptide (monitor peptide) (0) in ['25Il-EGF binding to Swiss 3T3 fibroblasts. The indicated amounts of each unlabeled factor and 15 ng of ['=I]-EGF (2346 cpm/ng) were added simultaneously culture wells containing 0.3ml of the standard binding medium. Binding of incubation at 37'c, ['26I]-EGF to fibroblasts was determined after 1 hr described under "MATERIALS AND METHODS". Each point represents the average duplicate determinations.
to the as for
was
BIOCHEMICAL
Vol. 145, No. 2, 1987 considered
to
subtracting
be
this
50% inhibition rig/ml.
'nonspecific'.
This
The
nonspecific of the
AND BIOPHYSICAL
value.
specific
'specific'
binding
The concentration
['%I]-EGF
concentration
RESEARCH COMMUNICATIONS
shows
calculated
of unlabeled
binding
good
was
was
agreement
EGF
estimated
with
by
to
causing be
previously
71.4
reported
values(9,lO). The purified competed equal
growth
in the
to that
binding
['% I]-EGF
peptide
of excess initial
excess
EGF was added.
almost
the
The peptide juice
described
as a substance
recently
found
points(6):
Monitor
inhibitory
activity
peptide that
(mouse
interstingly, 5-18
explain in
the
EGF binding
curves
for
These
EGF receptor was
are
toward
from
peptide
to
EGF or alpha-tumor region
(-19
were
ref.5). EGF-like to the
14 amino
This
partial
growth
that
the
22% when
EGF
have
affinities
of
rat
bile-pancreatic
secretion,
but
[3 HI-thymidine
are about
was
incorporation,
3T3 fibroblasts
peptide of
it
with
similar
in
6,500
a
some
and
shows
EGF has a
molecular
weight
trypsin-like
enzyme.
However,
monitor
(transforming) does
growth
not
peptide (57.1%)
homology
cell.
649
peaks are
(a-TGF)
of the
peptide peptide
with
with and
that EGF
Whereas, with
to
in
column,
(Fig.1).
comprared
can be seen
of monitor
activity
phase
a reverse
as distinct
acids
factor
show any homology
with
of monitor
stimulating
and
the
Similarly,
separated
8 of
peptide
from
weight
residues)
20-33
seen
of Swiss
On HPLC analysis clearly
the same as that this
EGF and this
a
about
enzyme
and proliferation
binds
In
was
purified
stimulates
trypsin(l,5).
['=I]-EGF
rig/ml.
binding
indicate
pancreatic
has a molecular
specific
almost
similar.
first
also
peptide)
a potency
of 82.8
nonspecific
results
peptide
when residues
3, from
almost
of EGF(6).
of mouse EGF(7),
(Fig.
being
peptide
EGF or (Y -TGF(S).
and monitor
this
to that
N-terminal
of either
binding,
stimulated
EGF) and
differs its
the
incorporation
comparable
of 6,000
this
the
at a concentration
r&ml)
here
that
that
[35S]-methionine potency
the
of
(2,500
(Fig.2).
and EGF for
(monitor showing
Inhibition
The dose-response
same profile
peptide
50%
was observed
['251]-EGF
releasing-peptide
to 3T3 fibroblasts,
EGF.
peptide
of the
the
binding
of unlabeled
by this
presence
stimulating-/CCK
be
residues identical EGF
might
competition
Vol. 145, No. 2, 1987 Monitor
peptide
Mouse EGF(5-18)
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
GNPPAEVNGKTPNCPKQIMGCPRIYDPVCGTNGITYPSECSLCFENRKFGTSIHIQRRGGC .;i+>*c $f+F -:t +;* -GCPSSYDGYCLNNG-
Fig.3. Comparison of amino acid sequence of the growth stimulating-/ cholecystokinin (CCK) releasing-peptide (monitor peptide) with mouse EGF. The one letter amino acid abbreviations are used: A;Ala, C;Cys, D;Asp, E;Glu, F;Phe, G;Gly, H;His, I;Ile, K;Lys, L;Leu, M;Met, N;Asn, P;Pro, Q;Gln, R;Arg, S;Ser, T;Thr, V;Val, Y;Tyr. Identical amino acid residues are indicated by These results are from ref.5. (i').
The present activity It
of the peptide
remains
between
results
toward
to be further
monitor
or whether
support
the
peptide
the
3T3 fibroblasts
determined and EGF is
EGF receptor
hypothesis
required
the for
ligand
ACKNOWLEDGEMENT: This work was supported Research (No.61108006 to K-1.) from the Culture of Japan.
the
is mediated
whether
has a broad
that
the
partial binding
growth via
the
stimulating EGF receptor.
homologous to the
sequence
EGF receptor,
specificity.
by a Ministry
Grant-in-Aid of Education,
for
Scientific Science and
REFERENCES 1. Fushiki,T., Fukuoka,S. and Iwai,K. (1984) Biochem. Biophys. Res. Commun. 118, 532-537 2. Iwai,K., Fukuoka,S., Fushiki,T., Kodaira,T. and Ikei,N. (1986) Biochem. Biophys. Res. Commun. 136, 701-706 3. Fushiki,T., Fukuoka,S. and Iwai,K. (1984) Agric. Biol. Chem. 48, 1867-1874 Fushiki,T. and Iwai,K. (1986) J. Nutr. 116, 15404. Fukuoka,S., Tsujikawa,M., 1546 5. Iwai,K., Fukuoka,S., Fushiki,T., Tsujikawa,M., Hirose,M., Tsumasawa,S., and Sakiyama,F. (1987) J. Biol. Chem. in the press. Sugimoto,E. and Iwai,K. (1986) Biochem. 6. Fukuoka,S., Fushiki,T., Kitagawa,Y., Biophys. Res. Commun. 139, 545-550 7. Carpenter,G. and Cohen,S. (1979) Ann. Rev. Biochem. 48, 193-216 8. Morita,A., Aratani,Y., Sugimoto,E. and Kitagawa,Y. (1984) J. Biochem. 95, 743-750 9. O'Keefe,E., Hollenberg,M.D. and Cuatrecasas,P. (1974) Arch. Biochem. Biophys 164, 518-526 10. Carpenter,G., Lembach,K.J., Morrison,M.M. and Cohen,S. (1975) J. Biol. Chem. 250, 4297-4304
650
BIOCHEMICAL
COMPETITION
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 646-650
OF A GROWTH STIMULATING-/CHOLECYSTOKININ
RELEASING-PEPTIDE
(MONITOR PEPTIDE)
(CCK)
WITH EPIDERMAL
GROWTH FACTOR FOR BINDING TO 3T3 FIBROBLASTS Shin-Ichi
Fukuoka,
+&Institute of Agriculture,
Faculty April
Fushiki, Yasuo Kitagawa", Kazuo Iwail
Etsuro
Laboratory of Nutritional Chemistry, of Food Science and Technology, Faculty Kyoto University, Kyoto 606, Japan
Department
Received
Tohru
20,
for
Sugimoto*,
and
of Agriculture,
Biochemical Regulation, Nagoya University, Nagoya
464,
Japan
1987
SUMMARY: The growth stimulating-/cholecystokinin releasing-peptide (CCK) (monitor peptide) is a peptide purified from rat bile-pancreatic juice on the basis of its stimulatory activity toward pancreatic enzyme secretion. Its multiple functions and peptide sequence suggested that it is distinct from epidermal growth factor (EGF). However, we found that the peptide competes with ['=I]-EGF in the binding to Swiss 3T3 fibroblast cells to almost the same extent as unlabeled EGF does. [1251]-EGF binding was inhibited by 50% by the peptide at 82.8 rig/ml and by unlabeled EGF at 71.4 rig/ml. This suggests that the growth stimulating effect of the peptide on 3T3 fibroblasts is mediated via the EGF receptor, and also suggests that the partial homologous sequence between monitor peptide and EGF is required for the receptor binding, or that o 1987 Academic Press, Inc. the EGF receptor has a broad ligand specificity.
We previously about
6,500,
activity
that
response
this
juice
enzyme
activity,
activity
the
i.ntestine.
Swiss
should
$1.50
0 1987 by Academic Press, of reproduction in any form
Inc. reserved.
646
is
its
found
rat
intestine(Z). enzyme
also with
Professor,
We
by sereval
to
its
Kyoto
lines from
its
CCK-releasing
exhibits
almost
to
secretion
peptide"(5)
addition
of
stimulatory was
supported
peptide
weight
peptide
the
as "monitor
3T3 fibroblasts
be addressed;
of
of pancreatic
In
monitor
molecular
basis
in
and it
peptide
a
The
as a mediator
that
toward
on the
secretion(l).
intake(l),
the
demonstrated
To whom correspondence
0006-291X/87
acts
protein
in
with
activity
We designated role
we
stimulating
peptide
to dietary
physiological
Conright All rights
a peptide,
bile-pancreatic
pancreatic
of evidence(3,b).
1
rat
and purified
cholecystokinin(CCK)-releasing
postulate in
from
toward
exhibit
found
the
a
growth
same
potency
University.
BIOCHEMICAL
Vol. 145, No. 2, 1987 as epidermal complete the
growth
amino
peptide
that
acid
inhibitor
monitor
peptide
other.
It
inhibitor
growth
of monitor
61 amino that
acid of
(pancreatic is
suggests
and has
highly
conserved
related
to other
that
monitor
peptide
to 3T3 fibroblasts activity
trypsin
is
competition
to be
was investigated peptide
an
indicated
amino
acid
region
in
than
they
that
Kazal
type
However,
are
into
the
sequence
PSTI).
classified
to
Kazal
each type
peptide(5).
monitor
to elucidate is
determine
results
PST&
related by
to
inhibitor,
mammalian
PST1 or its
of this
and the
residues
less
communication,
stimulating
a
RESEARCH COMMUNICATIONS
we succeeded
peptide,
secretory
and may be one of rat In this
binding
sequence
resembles
trypsin
Recently
factor(EGF)(6).
comprises
closely
AND BIOPHYSICAL
mediated
peptide
in
whether via
['%I]-EGF or
not
the
the EGF receptor.
MATERIALS AND METHODS: Purification of the growth stimulating-/CCK releasing-peptide (monitor peptide) was carried out by the method described elsewhere(5,6). The purity of the peptide was demonstrated by the following lines of evidence: The sharp single peak seen on high performance liquid chromatography (HPLC) with a reverse phase column (Bio-Rad RP 304), as shown in Fig.1, the single band seen on SDS-PAGE(l), and the N-terminal amino acid sequencing results(S). Mouse EGF was purchased from Wako Pure Chemicals (Japan). This EGF preparation was purified by the method described(7), and its purity was investigated by SDS-PAGE. EGF and monitor peptide were separated as distinct peaks on reverse phase HPLC (Fig.1). [lzI]-EGF was obtained from Amersham. Other chemicals used were of the highest purity available from commercial sources.
THE PURIFIED PEPTIDE
50
0
T I M E (min) Fig.1. Reverse phase HPLC analysis of EGF and the growth stimulating-/ EGF (100ng) and/or cholecystokinin (CCK) releasing-peptide (monitor peptide). x 250 monitor peptide (100ng) were applied onto a Bio-Rad RP 304 column (4.6 mm) in a HPLC system with a Model 660 programmer and a Model 550 pumps (Waters). Elution was carried out with a gradient of acetonitrile, as indicated in the figure by the broken line. 647
BIOCHEMICAL
Vol. 145, No. 2, 1987
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Cell culture: The stock cultures of Swiss 3T3 fibroblast cells were maintained in 6Omm dishes (NUNC, Denmark) in Dulbecco's modified Eagle's medium (DMEM) containing 10% fetal bovine serum (FBS, M.A.Bioproducts), penicillin (50units/ml) and streptomycin (25&ml) (the standard medium) at 37°C under a humidified atmosphere of 5% CO2 and 95% air (8). To prepare cultures for [i251]-EGF binding 0.3 ml of a cell suspension (5x104cells/ml) was inoculated and into each well of 'a 24-well (16mm diameter) microtest plate (NUNC), followed by incubation at 37°C under the above conditions for 24 hr. ['%I]-EGF binding radioreceptor assay: The standard medium was removed 0.3 ml and the surface of cultures was washed once with serum-free DMEM. Then amounts of DMEM containing ['%I]-EGF (50ng/ml, 2346 cpm/ng) and the indicated of unlabeled EGF or the purified monitor peptide were added to each well. After incubation at 37°C for 1 hr, unbound [I25 I]-EGF was removed by washing the of 3 ml of phosphate-buffered saline cells five times with a total volume (O.l5M, pH 7.4) containing 0.1% bovine serum albumin. The cells in each well the radioactivity of the cell were lysed with 0.3ml of 0.5N NaOH, and then lysate was measured with an Aloka autowell gammacounter. RESULTS AND DISCUSSION The EGF receptor replacement
of
replacement
with
15-500
rig/ml.
however,
about
(Fig.2).
The
on 3T3 fibroblasts
bound
['251]-EGF
unlabeled
remaining
with
over
EGF was added
the
initial
radioactivity
UNLABELED
demonstrated
unlabeled
EGF was observed
When unlabeled 25 % of
can be
EGF. the
in
FACTOR
the
binding presence
ADDED
In
the
our
specific
range
up to 2,500 was of
the
study,
concentration
at concentrations
[1251]-EGF
by
still excess
of
rig/ml, observed EGF
(rig/ml)
Fig.2.
Competition by unlabeled EGF (0) and the purified growth stimulating-/ cholecystokinin(CCK) releasing-peptide (monitor peptide) (0) in ['25Il-EGF binding to Swiss 3T3 fibroblasts. The indicated amounts of each unlabeled factor and 15 ng of ['=I]-EGF (2346 cpm/ng) were added simultaneously culture wells containing 0.3ml of the standard binding medium. Binding of incubation at 37'c, ['26I]-EGF to fibroblasts was determined after 1 hr described under "MATERIALS AND METHODS". Each point represents the average duplicate determinations.
to the as for
was
BIOCHEMICAL
Vol. 145, No. 2, 1987 considered
to
subtracting
be
this
50% inhibition rig/ml.
'nonspecific'.
This
The
nonspecific of the
AND BIOPHYSICAL
value.
specific
'specific'
binding
The concentration
['%I]-EGF
concentration
RESEARCH COMMUNICATIONS
shows
calculated
of unlabeled
binding
good
was
was
agreement
EGF
estimated
with
by
to
causing be
previously
71.4
reported
values(9,lO). The purified competed equal
growth
in the
to that
binding
['% I]-EGF
peptide
of excess initial
excess
EGF was added.
almost
the
The peptide juice
described
as a substance
recently
found
points(6):
Monitor
inhibitory
activity
peptide that
(mouse
interstingly, 5-18
explain in
the
EGF binding
curves
for
These
EGF receptor was
are
toward
from
peptide
to
EGF or alpha-tumor region
(-19
were
ref.5). EGF-like to the
14 amino
This
partial
growth
that
the
22% when
EGF
have
affinities
of
rat
bile-pancreatic
secretion,
but
[3 HI-thymidine
are about
was
incorporation,
3T3 fibroblasts
peptide of
it
with
similar
in
6,500
a
some
and
shows
EGF has a
molecular
weight
trypsin-like
enzyme.
However,
monitor
(transforming) does
growth
not
peptide (57.1%)
homology
cell.
649
peaks are
(a-TGF)
of the
peptide peptide
with
with and
that EGF
Whereas, with
to
in
column,
(Fig.1).
comprared
can be seen
of monitor
activity
phase
a reverse
as distinct
acids
factor
show any homology
with
of monitor
stimulating
and
the
Similarly,
separated
8 of
peptide
from
weight
residues)
20-33
seen
of Swiss
On HPLC analysis clearly
the same as that this
EGF and this
a
about
enzyme
and proliferation
binds
In
was
purified
stimulates
trypsin(l,5).
['=I]-EGF
rig/ml.
binding
indicate
pancreatic
has a molecular
specific
almost
similar.
first
also
peptide)
a potency
of 82.8
nonspecific
results
peptide
when residues
3, from
almost
of EGF(6).
of mouse EGF(7),
(Fig.
being
peptide
EGF or (Y -TGF(S).
and monitor
this
to that
N-terminal
of either
binding,
stimulated
EGF) and
differs its
the
incorporation
comparable
of 6,000
this
the
at a concentration
r&ml)
here
that
that
[35S]-methionine potency
the
of
(2,500
(Fig.2).
and EGF for
(monitor showing
Inhibition
The dose-response
same profile
peptide
50%
was observed
['251]-EGF
releasing-peptide
to 3T3 fibroblasts,
EGF.
peptide
of the
the
binding
of unlabeled
by this
presence
stimulating-/CCK
be
residues identical EGF
might
competition
Vol. 145, No. 2, 1987 Monitor
peptide
Mouse EGF(5-18)
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
GNPPAEVNGKTPNCPKQIMGCPRIYDPVCGTNGITYPSECSLCFENRKFGTSIHIQRRGGC .;i+>*c $f+F -:t +;* -GCPSSYDGYCLNNG-
Fig.3. Comparison of amino acid sequence of the growth stimulating-/ cholecystokinin (CCK) releasing-peptide (monitor peptide) with mouse EGF. The one letter amino acid abbreviations are used: A;Ala, C;Cys, D;Asp, E;Glu, F;Phe, G;Gly, H;His, I;Ile, K;Lys, L;Leu, M;Met, N;Asn, P;Pro, Q;Gln, R;Arg, S;Ser, T;Thr, V;Val, Y;Tyr. Identical amino acid residues are indicated by These results are from ref.5. (i').
The present activity It
of the peptide
remains
between
results
toward
to be further
monitor
or whether
support
the
peptide
the
3T3 fibroblasts
determined and EGF is
EGF receptor
hypothesis
required
the for
ligand
ACKNOWLEDGEMENT: This work was supported Research (No.61108006 to K-1.) from the Culture of Japan.
the
is mediated
whether
has a broad
that
the
partial binding
growth via
the
stimulating EGF receptor.
homologous to the
sequence
EGF receptor,
specificity.
by a Ministry
Grant-in-Aid of Education,
for
Scientific Science and
REFERENCES 1. Fushiki,T., Fukuoka,S. and Iwai,K. (1984) Biochem. Biophys. Res. Commun. 118, 532-537 2. Iwai,K., Fukuoka,S., Fushiki,T., Kodaira,T. and Ikei,N. (1986) Biochem. Biophys. Res. Commun. 136, 701-706 3. Fushiki,T., Fukuoka,S. and Iwai,K. (1984) Agric. Biol. Chem. 48, 1867-1874 Fushiki,T. and Iwai,K. (1986) J. Nutr. 116, 15404. Fukuoka,S., Tsujikawa,M., 1546 5. Iwai,K., Fukuoka,S., Fushiki,T., Tsujikawa,M., Hirose,M., Tsumasawa,S., and Sakiyama,F. (1987) J. Biol. Chem. in the press. Sugimoto,E. and Iwai,K. (1986) Biochem. 6. Fukuoka,S., Fushiki,T., Kitagawa,Y., Biophys. Res. Commun. 139, 545-550 7. Carpenter,G. and Cohen,S. (1979) Ann. Rev. Biochem. 48, 193-216 8. Morita,A., Aratani,Y., Sugimoto,E. and Kitagawa,Y. (1984) J. Biochem. 95, 743-750 9. O'Keefe,E., Hollenberg,M.D. and Cuatrecasas,P. (1974) Arch. Biochem. Biophys 164, 518-526 10. Carpenter,G., Lembach,K.J., Morrison,M.M. and Cohen,S. (1975) J. Biol. Chem. 250, 4297-4304
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