Vol. 82, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
May 30,1978
Pages 731-737
SOMATOSTATIN RELEASE FROM ISOLATED PERFUSED RAT STOMACH T. Chiba, H. Abe,
Y. Seino,
Y. Kato,
Y. Goto,
S. Kadowaki,
S. Matsukura,
T. Taminato,
M. Nozawa* and H. Imura**
Third Division, Department of Medicine, Kobe University School of Medicine, Kusunoki-cho, Ikuta-ku, Kobe 650, * Department of Osaka Medical School, Daigaku-cho, Takatsuki 569 and Surgery, ** Second Division, Department of Medicine, Kyoto University School of Medicine, Kawahara-cho, Shogoin, Sakyo-ku, Kyoto 606, Japan Received
April
18,
1978 SUMMARY
Gastric somatostatin release from the isolated rat stomach was studied using a perfusion technique. Somatostatin released from the isolated perfused rat stomach was found to be identical in molecular size and inununoreactively with synthetic somatostatin. Infusion of glucagon (10D7M) caused biphasic increase of gastric somatostatin release. Gastric somatostatin release was also stimulated Fy infusion of theophylline (10m3M) and dibutyryl cyclic AMP (10 M). These results indicate the possible involvement of adenylate cyclase-cyclic AMP system in the regulatory mechanism of gastric somatostatin release.
INTRODUCTION Immunoreactive the central (3,
nervous
4) and the
enylate
system
stomach
cyclase-cyclic
somatostatin
(3).
(1,
the
The present inununoreactive the
release study
2),
AMP system
demonstrated but
also
not
a possible
role
in the release
(5,
6).
was performed
of adenylate
of
in
of ad-
pancreatic
little
However,
is
somatostatin.
to examine
from perfused
only
in the pancreas
mechanism of gastric
somatostatin involvement
is
Recently,
has been suggested
known about
elucidate
somatostatin
rat
the release
of
stomach and to
cyclase-cyclic
AMP
OOQ6-291X/78/0822-0731$01.00/0 731
Copyright 0 I978 by Academic Press, fnc. AlI rights of reproduction in any form reserved
Vol. 82, No. 2, 1978
system
BIOCHEMICAL
in the regulatory
AND BIOPHYSICAL
mechanism of gastric
RESEARCH COMMUNICATIONS
somatostatin
release. MATERIALS AND METHODS Stomachs were isolated from 24 h fasted Perfusion of stomach: male Wistar rats weighing 300-350 g by the metnod of Lefebvre Polyethylene cannulae were inserted into the left gastric (7). artery and the gastric vein. All other vessels were ligated and a whole pancreas was carefully excluded by ligation. After a catheter was inserted into the stomach cardia was ligated, throu h the pyloric ring to drain the gastric juice. 4.6 S DKRBG7 was infused into the left gastric artery at a rate of 2 ml/min without recirculation. The perfusate was equilibrated immediately before use with a gas phase of 95 % O2 / 5 % CO2 at 37OC and the stomach preparation was kept at 37OC throughout the experiment. After the pre-perfusion period (20 min) when 4.6 % DKRBG was infused, 4.6 % DKRBG with or without various agents was infused into the artery for 15 min. The venous effluents were collected every 1 min in chilled tubes containing Bacitracin-Trasylol mixture (2 x 10m5M and 1000 U/ml, respectively), frozen immediately and stored at -20°C until assayed. 20 ml of the perfusate was pooled and Gel chromatography: shaked gently for 1 min with 2 volumes of 98 % acetone containing 0.35 N acetic acid. After centrifugation at 3500 rpm for 30 min, the supernatant was evaporated under air to remove acetone and then lyophilized. The residue was reconstituted to 1.5 ml with 0.2 N acetic acid and applied to Sephadex G-25 column (1.8 x 70 cm). Each 2 ml fraction was collected using 0.2 N acetic acid as an elution buffer, and eluates were assayed for immunoreactive somatostatin. Radioimmunoassay: Somatostatin levels were measured by a specific radioimmunoassay with a modification of the method described by Arimura et al. (9). Specific antiserum (RA-623) to somatostatin was produced in the rabbit by repeated immunization with synthetic somatostatin (Protein Researc!l Institute, Osaka, Japan) coupled to crystallized bovine serum albumin (Armour Pharmaceutical Co. Chicago). Antiserum RA-823 was found to have no cross-reactivity with insulin, glucagon, secretin, gastrin, motilin, VIP, substance-P, bombesin, met5enkephalin, ACTH, TRH, LH-RH and TSH. N-tyrosyl somatostatin was iodinated with lz51-Na by chloramin-T method (8) subsequently purified on Sephadex G-25 column. The minimum detectable quantity of the assay was 10 pg/ml (Fig. 1). An intraassay and an interassay variation were 5.4 % and 8.5 %, respectively. 1Abbreviations: DKRBG, dextran Krebs-Ringer bicarbonate buffer (pH 7.4) containing 5.5 mM glucose; VIP, vasoactive intestinal polypeptide; TRH, thyrotropin releasing hormone; LH-RH, luteinizing hormone-releasing hormone; TSH, thyroid stimulating hormone; db-CAMP, N6, 02-Dibutyryladenosine-3',5'-cyclicphosphate, Sodium Salt.
732
Vol. 82, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Irmnunoreactive insulin was measured by radioimmunoassay with a polyethylene glycol method described previously (10). Immunoreactive glucagon was determined by radioimmunoassay with a talc adsorption technique (11) using antiserum 30 K. N-tyrosyl somatostatin was kindly supplied from Drs. D.H. Coy and A. Arimura, V.A. Hospital, New Orleans. Antiserum 30 K was purchased from Daibetes Research Fund, Dallas. Theophylline and db-CAMP were purchased from Nakarai Chemicals, Ltd., Kyoto and Sigma Chemical Co., St. Louis, respectively. Secretin, motilin, VIP, substance-P, bombesin (generous gifts from Dr. N. Yanaihara, Shizuoka College of Pharmacy, Shizuoka), human gastrin I (a gift from I.C.I. Ltd. Macclesfield Cheshire), human ACTH (supplied from Takeda Chemical Industries Ltd., (purchased from Protein Research InOsaka), met5-enkephaline stitute, Osaka), TRII, LH-RH (obtained from Tanabe Pharmaceutical co., Osaka) and TSH (purchased from Armour Pharmaceutical Co., Chicago) were of synthetic origin. Highly purified pork insulin and crystalline beef-pork glucagon were supplied from NOVO, Copenhagen and Lilly Lab., Indianapolis, respectively. RESULTS Three from
peaks of
immunoreactive
the perfusate
of
Sephadex
G-25 column
the void
volume
tion
of
the stomach by gel chromatography (Fig.
of
somatostatin curve
basal
somatostatin
217 pg/ml,
which
were not
the infusion
Infusion
somatostatin pg/ml
of
release
(mean i- SE)
the
(3 min after
second of
758 ? 101 pg/ml
(Fig.
3),
both
basal
levels
of which (P < 0.01
to the
1). levels
ranged
significantly
of DKRBG (mean + SE, 183 ?r 2 pg/ml)
glucagon
with
of immunoreacparallel
study,
changed
3).
curve
(Fig.
to
second peak.
to be completely
assay system
from 160 pg/ml
near
at a posi-
by a small
dilution
on
peak was eluted
in the main peak was quite
In the perfusion
(Fig.
preceded
A serial
in the
during
The first
the main peak was found
to charcoal.
standard
2).
somatostatin
Immunoreactivity
tive
were obtained
and the main peak was demonstrated
synthetic
adsorbed
somatostatin
(10s7M) first the
peak value start
(15 min after
were significantly and P < 0.001,
733
evoked
of the
biphasic of
1024 + 152
infusion) start greater
respectively).
and the
of
infusion)
than
the
After
the
BIOCHEMICAL
Vol. 82, No. 2, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
B/F 09 Dilution 130
0.6
of extract 1:&o 1:20
of perfusate 1:10 1:s
76
31.2
07 0.6 0.5 0.4 0.3
‘:\
0.2 0.1 0
1
1.0
2D
3.9
156
Somatostatin
625
125
250
500
(pgltube)
Fig.
1:
Dose response curve of radioimmunoassay for somatostatin and dilution curve of the extract of perfusate Antiserum RA-823 was used from isolated rat stomach. Nonat a final concentration with 1:8000 dilution. specific binding of the assay after treatment with dextran-coated charcoal was 2.4 %. B and F show bound Standard somatoand free radioactivity, respectively. ) and the extract from gastric perfusate statin (oe (o----o) are shown.
Fig.
2:
Gel chromatography of the extract of perfusates from isolated rat stomach on Sephadex G-25 column (1.8 x 70 cm) in 0.2 N acetic acid at a flow rate of 25 ml/h. The column was calibrated with synthetic somatostatin (the cross-hatched bar) and dextran blue (void volume = Vo). Each fraction volume was 2 ml. 734
Vol. 82, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Time(min)
Fig.
3:
end of
Effects of glucagon (10V7M), theophylline (10s3M) and db-CAMP (10s3M) on immunoreactive somatostatin release from isolated perfused rat stomach. All drugs were perfused for 15 min following a pre-perfusion period (20 min) as shown. Heavy solid lines (-) represent somatostatin responses to stimuli and light solid lines (0~ ) show the control study (glucose only). Mean rt SE values are shown. Number of animals is 6 for each group. Student's "t" test was used for statistical analysis and shown as follows : * P < 0.05, ** P < 0.005 compared with the control group.
infusion,
pre-perfusion
level
theophylline statin
somatostatin
(10 -3M)
release
after
the
with
start
db-CAMP (10 -3M) release
within
with
15 min after
of
6 min
produced
infusion
Immunoreactive
insulin
of
of
somatoat 11 min
(Fig.
3).
Infusion
rise
of
somatostatin
644 f 34 pg/ml
infusion
of
685 ?r 135 pg/ml
a gradual of
to the
Infusion
increase
(P < 0.01)
the peak value of
3).
a gradual
elicited
start
were decreased
(Fig.
the peak value
also
the
levels
(Fig.
and glucagon
(P < 0.001)
of
at
3). were not
detected
any perfusate. DISCUSSION The present statin
study
was released
revealed
from
that
isolated
immunoreactive
perfused
735
rat
somato-
stomach and
in
BIOCHEMICAL
Vol. 82, No. 2, 1978
responded
to various
ered
to be identical
with
synthetic
tive
somatostatin
synthetic serial
curve
studies
was parallel (5,
of pancreatic
somatostatin
release,
of
cyclase-cyclic
adenylate
anism of It
gastric could
since
pancreatic
fluenced study
suggests,
gastric not
detectable
especially release
however,
might
al.
be a regulator
somatostatin various
(13,
stimuli
somatostatin
it
release,
is
that
the
with
in
involvement mech-
(12).
to be inThe present
in
the case of were
stomach throughout gastric
the
hormones, somatostatin
future. pancreatic
homeostasis.
a possible
stomach,
and glucagon
gastric
that
from the
release
the
reported
other
in the
of nutrient
emphasizes
is
insulin
of
14) suggested
was released
showed
gastric
somatostatin
unlikely
since
may interact
in nutrient
study
the regulatory
the pancreas
that
be elucidated
cyclasemechanism
possible
in
gastric
release
The possibility
should
adenylate
The present
the
and its
curve.
regulatory
and glucagon
hormones in
gastrin,
Ipp et --
that
in the perfusates
experiments.
in the
to
release.
somatostatin
somatostatin
standard
that
also
by insulin
by these
to the
AMP system
be considered
be influenced
corresponding
and db-CAMP stimulated
indicating
immunoreac-
G-25 chromatography
release.
somatostatin
might
fractions
be involved
theophylline
glucagon,
and immunoreactively
6) demonstrated
somatostatin
was consid-
the main peak of
in the
on Sephadex
RESEARCH COMMUNICATIONS
somatostatin
size
since
was eluted
AMP system might
that
Gastric
in molecular
somatostatin
Recent cyclic
stimuli.
somatostatin,
dilution
AND BIOPHYSICAL
somatostatin
The fact
stomach responding involvement
that to
of gastric
homeostasis. ACKNOWLEDGEMENTS
We are grateful to Drs. D.H. Coy and A. Arimura, Hospital, New Orleans, for a g.enerous gift of N-tyrosyl
736
V.A.
Vol. 82, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
somatostatin. We are also indebted to Prof. College of Pharmacy, Shizuoka, for synthetic hormones.
N. Yanaihara, a kind supply
Shizuoka of various
REFERENCES 1. Brazeau, P., Vale, W., Burgus, R., Ling, N., Butcher, M., Rivier, J. and Guillemin, R. (1973) Science 179, 77-79. 2. Hockfelt, T., Effendic! S., Johansson, O., Luft, R. and Arimura, A. (1974) Brain Res. 80, 165-169. 3. Arimura, A., Sato, H., Dupont,A., Nishi, N. and Schally, A.V. (1975) Science 189 1007-1009. -' 4. Dubois, M.P. (1975) Proc. Natl. Acad. Sci. U.S.A. 72, 1340-1343. 5. Barden, N., Urbina, G-A., C6te, J.P. and DuPont, A. (1976) Biochem. Biophys. Res. Commun. 71, 840-844. 6. Schauder, P., McIntosh, C., Arends, J., Arnold, R., Frerichs, H. and Creutzfeld, W. (1977) Biochem. Biophys. Res. Commun. 2, 630-634. 7. Lefebvre, P.J. and Luyckx, A.S. (1977) J. Clin. Invest. 59 -' 716-722. 8. Hunter, W.M. and Greenwood, F.C. (1962) Nature 194, 495-496. 9. Arimura, A., Sato, H., Coy, D.H. and Schally, A.V. (1975) Proc. Sot. Exp. Biol. Med. 148, 784-789. 10. Goto, Y., Seino, Y., Tarnina% T. and Imura, H. (1976) J. Endocrinol. 69, 295-296. 11. Sakurai, H. and Imrua, H. (1976) Japan J. Nucl. Med. 10, 135-136. 12. Unger, R.H. and Orci, L. (1977) Diabetes -26, 241-244. 13. Ipp, E., Dobbs, R.E., Arimura, A., Vale, W., Harris, V. and Unger, R.H. (1977) J. Clin. Invest. 60, 760-765. 14. Ipp, E., Dobbs, R.E., Harris, V., Arimura, A., Vale, W. and Unger, R.H. (1977) J. Clin. Invest. 60, 1216-1219. -
737
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
May 30,1978
Pages 731-737
SOMATOSTATIN RELEASE FROM ISOLATED PERFUSED RAT STOMACH T. Chiba, H. Abe,
Y. Seino,
Y. Kato,
Y. Goto,
S. Kadowaki,
S. Matsukura,
T. Taminato,
M. Nozawa* and H. Imura**
Third Division, Department of Medicine, Kobe University School of Medicine, Kusunoki-cho, Ikuta-ku, Kobe 650, * Department of Osaka Medical School, Daigaku-cho, Takatsuki 569 and Surgery, ** Second Division, Department of Medicine, Kyoto University School of Medicine, Kawahara-cho, Shogoin, Sakyo-ku, Kyoto 606, Japan Received
April
18,
1978 SUMMARY
Gastric somatostatin release from the isolated rat stomach was studied using a perfusion technique. Somatostatin released from the isolated perfused rat stomach was found to be identical in molecular size and inununoreactively with synthetic somatostatin. Infusion of glucagon (10D7M) caused biphasic increase of gastric somatostatin release. Gastric somatostatin release was also stimulated Fy infusion of theophylline (10m3M) and dibutyryl cyclic AMP (10 M). These results indicate the possible involvement of adenylate cyclase-cyclic AMP system in the regulatory mechanism of gastric somatostatin release.
INTRODUCTION Immunoreactive the central (3,
nervous
4) and the
enylate
system
stomach
cyclase-cyclic
somatostatin
(3).
(1,
the
The present inununoreactive the
release study
2),
AMP system
demonstrated but
also
not
a possible
role
in the release
(5,
6).
was performed
of adenylate
of
in
of ad-
pancreatic
little
However,
is
somatostatin.
to examine
from perfused
only
in the pancreas
mechanism of gastric
somatostatin involvement
is
Recently,
has been suggested
known about
elucidate
somatostatin
rat
the release
of
stomach and to
cyclase-cyclic
AMP
OOQ6-291X/78/0822-0731$01.00/0 731
Copyright 0 I978 by Academic Press, fnc. AlI rights of reproduction in any form reserved
Vol. 82, No. 2, 1978
system
BIOCHEMICAL
in the regulatory
AND BIOPHYSICAL
mechanism of gastric
RESEARCH COMMUNICATIONS
somatostatin
release. MATERIALS AND METHODS Stomachs were isolated from 24 h fasted Perfusion of stomach: male Wistar rats weighing 300-350 g by the metnod of Lefebvre Polyethylene cannulae were inserted into the left gastric (7). artery and the gastric vein. All other vessels were ligated and a whole pancreas was carefully excluded by ligation. After a catheter was inserted into the stomach cardia was ligated, throu h the pyloric ring to drain the gastric juice. 4.6 S DKRBG7 was infused into the left gastric artery at a rate of 2 ml/min without recirculation. The perfusate was equilibrated immediately before use with a gas phase of 95 % O2 / 5 % CO2 at 37OC and the stomach preparation was kept at 37OC throughout the experiment. After the pre-perfusion period (20 min) when 4.6 % DKRBG was infused, 4.6 % DKRBG with or without various agents was infused into the artery for 15 min. The venous effluents were collected every 1 min in chilled tubes containing Bacitracin-Trasylol mixture (2 x 10m5M and 1000 U/ml, respectively), frozen immediately and stored at -20°C until assayed. 20 ml of the perfusate was pooled and Gel chromatography: shaked gently for 1 min with 2 volumes of 98 % acetone containing 0.35 N acetic acid. After centrifugation at 3500 rpm for 30 min, the supernatant was evaporated under air to remove acetone and then lyophilized. The residue was reconstituted to 1.5 ml with 0.2 N acetic acid and applied to Sephadex G-25 column (1.8 x 70 cm). Each 2 ml fraction was collected using 0.2 N acetic acid as an elution buffer, and eluates were assayed for immunoreactive somatostatin. Radioimmunoassay: Somatostatin levels were measured by a specific radioimmunoassay with a modification of the method described by Arimura et al. (9). Specific antiserum (RA-623) to somatostatin was produced in the rabbit by repeated immunization with synthetic somatostatin (Protein Researc!l Institute, Osaka, Japan) coupled to crystallized bovine serum albumin (Armour Pharmaceutical Co. Chicago). Antiserum RA-823 was found to have no cross-reactivity with insulin, glucagon, secretin, gastrin, motilin, VIP, substance-P, bombesin, met5enkephalin, ACTH, TRH, LH-RH and TSH. N-tyrosyl somatostatin was iodinated with lz51-Na by chloramin-T method (8) subsequently purified on Sephadex G-25 column. The minimum detectable quantity of the assay was 10 pg/ml (Fig. 1). An intraassay and an interassay variation were 5.4 % and 8.5 %, respectively. 1Abbreviations: DKRBG, dextran Krebs-Ringer bicarbonate buffer (pH 7.4) containing 5.5 mM glucose; VIP, vasoactive intestinal polypeptide; TRH, thyrotropin releasing hormone; LH-RH, luteinizing hormone-releasing hormone; TSH, thyroid stimulating hormone; db-CAMP, N6, 02-Dibutyryladenosine-3',5'-cyclicphosphate, Sodium Salt.
732
Vol. 82, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Irmnunoreactive insulin was measured by radioimmunoassay with a polyethylene glycol method described previously (10). Immunoreactive glucagon was determined by radioimmunoassay with a talc adsorption technique (11) using antiserum 30 K. N-tyrosyl somatostatin was kindly supplied from Drs. D.H. Coy and A. Arimura, V.A. Hospital, New Orleans. Antiserum 30 K was purchased from Daibetes Research Fund, Dallas. Theophylline and db-CAMP were purchased from Nakarai Chemicals, Ltd., Kyoto and Sigma Chemical Co., St. Louis, respectively. Secretin, motilin, VIP, substance-P, bombesin (generous gifts from Dr. N. Yanaihara, Shizuoka College of Pharmacy, Shizuoka), human gastrin I (a gift from I.C.I. Ltd. Macclesfield Cheshire), human ACTH (supplied from Takeda Chemical Industries Ltd., (purchased from Protein Research InOsaka), met5-enkephaline stitute, Osaka), TRII, LH-RH (obtained from Tanabe Pharmaceutical co., Osaka) and TSH (purchased from Armour Pharmaceutical Co., Chicago) were of synthetic origin. Highly purified pork insulin and crystalline beef-pork glucagon were supplied from NOVO, Copenhagen and Lilly Lab., Indianapolis, respectively. RESULTS Three from
peaks of
immunoreactive
the perfusate
of
Sephadex
G-25 column
the void
volume
tion
of
the stomach by gel chromatography (Fig.
of
somatostatin curve
basal
somatostatin
217 pg/ml,
which
were not
the infusion
Infusion
somatostatin pg/ml
of
release
(mean i- SE)
the
(3 min after
second of
758 ? 101 pg/ml
(Fig.
3),
both
basal
levels
of which (P < 0.01
to the
1). levels
ranged
significantly
of DKRBG (mean + SE, 183 ?r 2 pg/ml)
glucagon
with
of immunoreacparallel
study,
changed
3).
curve
(Fig.
to
second peak.
to be completely
assay system
from 160 pg/ml
near
at a posi-
by a small
dilution
on
peak was eluted
in the main peak was quite
In the perfusion
(Fig.
preceded
A serial
in the
during
The first
the main peak was found
to charcoal.
standard
2).
somatostatin
Immunoreactivity
tive
were obtained
and the main peak was demonstrated
synthetic
adsorbed
somatostatin
(10s7M) first the
peak value start
(15 min after
were significantly and P < 0.001,
733
evoked
of the
biphasic of
1024 + 152
infusion) start greater
respectively).
and the
of
infusion)
than
the
After
the
BIOCHEMICAL
Vol. 82, No. 2, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
B/F 09 Dilution 130
0.6
of extract 1:&o 1:20
of perfusate 1:10 1:s
76
31.2
07 0.6 0.5 0.4 0.3
‘:\
0.2 0.1 0
1
1.0
2D
3.9
156
Somatostatin
625
125
250
500
(pgltube)
Fig.
1:
Dose response curve of radioimmunoassay for somatostatin and dilution curve of the extract of perfusate Antiserum RA-823 was used from isolated rat stomach. Nonat a final concentration with 1:8000 dilution. specific binding of the assay after treatment with dextran-coated charcoal was 2.4 %. B and F show bound Standard somatoand free radioactivity, respectively. ) and the extract from gastric perfusate statin (oe (o----o) are shown.
Fig.
2:
Gel chromatography of the extract of perfusates from isolated rat stomach on Sephadex G-25 column (1.8 x 70 cm) in 0.2 N acetic acid at a flow rate of 25 ml/h. The column was calibrated with synthetic somatostatin (the cross-hatched bar) and dextran blue (void volume = Vo). Each fraction volume was 2 ml. 734
Vol. 82, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Time(min)
Fig.
3:
end of
Effects of glucagon (10V7M), theophylline (10s3M) and db-CAMP (10s3M) on immunoreactive somatostatin release from isolated perfused rat stomach. All drugs were perfused for 15 min following a pre-perfusion period (20 min) as shown. Heavy solid lines (-) represent somatostatin responses to stimuli and light solid lines (0~ ) show the control study (glucose only). Mean rt SE values are shown. Number of animals is 6 for each group. Student's "t" test was used for statistical analysis and shown as follows : * P < 0.05, ** P < 0.005 compared with the control group.
infusion,
pre-perfusion
level
theophylline statin
somatostatin
(10 -3M)
release
after
the
with
start
db-CAMP (10 -3M) release
within
with
15 min after
of
6 min
produced
infusion
Immunoreactive
insulin
of
of
somatoat 11 min
(Fig.
3).
Infusion
rise
of
somatostatin
644 f 34 pg/ml
infusion
of
685 ?r 135 pg/ml
a gradual of
to the
Infusion
increase
(P < 0.01)
the peak value of
3).
a gradual
elicited
start
were decreased
(Fig.
the peak value
also
the
levels
(Fig.
and glucagon
(P < 0.001)
of
at
3). were not
detected
any perfusate. DISCUSSION The present statin
study
was released
revealed
from
that
isolated
immunoreactive
perfused
735
rat
somato-
stomach and
in
BIOCHEMICAL
Vol. 82, No. 2, 1978
responded
to various
ered
to be identical
with
synthetic
tive
somatostatin
synthetic serial
curve
studies
was parallel (5,
of pancreatic
somatostatin
release,
of
cyclase-cyclic
adenylate
anism of It
gastric could
since
pancreatic
fluenced study
suggests,
gastric not
detectable
especially release
however,
might
al.
be a regulator
somatostatin various
(13,
stimuli
somatostatin
it
release,
is
that
the
with
in
involvement mech-
(12).
to be inThe present
in
the case of were
stomach throughout gastric
the
hormones, somatostatin
future. pancreatic
homeostasis.
a possible
stomach,
and glucagon
gastric
that
from the
release
the
reported
other
in the
of nutrient
emphasizes
is
insulin
of
14) suggested
was released
showed
gastric
somatostatin
unlikely
since
may interact
in nutrient
study
the regulatory
the pancreas
that
be elucidated
cyclasemechanism
possible
in
gastric
release
The possibility
should
adenylate
The present
the
and its
curve.
regulatory
and glucagon
hormones in
gastrin,
Ipp et --
that
in the perfusates
experiments.
in the
to
release.
somatostatin
somatostatin
standard
that
also
by insulin
by these
to the
AMP system
be considered
be influenced
corresponding
and db-CAMP stimulated
indicating
immunoreac-
G-25 chromatography
release.
somatostatin
might
fractions
be involved
theophylline
glucagon,
and immunoreactively
6) demonstrated
somatostatin
was consid-
the main peak of
in the
on Sephadex
RESEARCH COMMUNICATIONS
somatostatin
size
since
was eluted
AMP system might
that
Gastric
in molecular
somatostatin
Recent cyclic
stimuli.
somatostatin,
dilution
AND BIOPHYSICAL
somatostatin
The fact
stomach responding involvement
that to
of gastric
homeostasis. ACKNOWLEDGEMENTS
We are grateful to Drs. D.H. Coy and A. Arimura, Hospital, New Orleans, for a g.enerous gift of N-tyrosyl
736
V.A.
Vol. 82, No. 2, 1978
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
somatostatin. We are also indebted to Prof. College of Pharmacy, Shizuoka, for synthetic hormones.
N. Yanaihara, a kind supply
Shizuoka of various
REFERENCES 1. Brazeau, P., Vale, W., Burgus, R., Ling, N., Butcher, M., Rivier, J. and Guillemin, R. (1973) Science 179, 77-79. 2. Hockfelt, T., Effendic! S., Johansson, O., Luft, R. and Arimura, A. (1974) Brain Res. 80, 165-169. 3. Arimura, A., Sato, H., Dupont,A., Nishi, N. and Schally, A.V. (1975) Science 189 1007-1009. -' 4. Dubois, M.P. (1975) Proc. Natl. Acad. Sci. U.S.A. 72, 1340-1343. 5. Barden, N., Urbina, G-A., C6te, J.P. and DuPont, A. (1976) Biochem. Biophys. Res. Commun. 71, 840-844. 6. Schauder, P., McIntosh, C., Arends, J., Arnold, R., Frerichs, H. and Creutzfeld, W. (1977) Biochem. Biophys. Res. Commun. 2, 630-634. 7. Lefebvre, P.J. and Luyckx, A.S. (1977) J. Clin. Invest. 59 -' 716-722. 8. Hunter, W.M. and Greenwood, F.C. (1962) Nature 194, 495-496. 9. Arimura, A., Sato, H., Coy, D.H. and Schally, A.V. (1975) Proc. Sot. Exp. Biol. Med. 148, 784-789. 10. Goto, Y., Seino, Y., Tarnina% T. and Imura, H. (1976) J. Endocrinol. 69, 295-296. 11. Sakurai, H. and Imrua, H. (1976) Japan J. Nucl. Med. 10, 135-136. 12. Unger, R.H. and Orci, L. (1977) Diabetes -26, 241-244. 13. Ipp, E., Dobbs, R.E., Arimura, A., Vale, W., Harris, V. and Unger, R.H. (1977) J. Clin. Invest. 60, 760-765. 14. Ipp, E., Dobbs, R.E., Harris, V., Arimura, A., Vale, W. and Unger, R.H. (1977) J. Clin. Invest. 60, 1216-1219. -
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