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Brain natriuretic peptide-32: N-terminal six amino acid extended form of brain natriuretic peptide identified in porcine brain
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages 726-732
September 15, 1988
B R A I N NATRI[R~ETIC PEPTIDE-32: B R A I N NATRIURETIC
N-TERMINaL
PEPTIDE
SIX A M I N O A C I D w~TE~DED F O R M OF
IDENTIFIED
IN PORCINE B R A I N
Tetsuji SUDOH #, Naoto MINAMINO*, Kenji KANGAWA & Hisayuki MATSUO
Departments of Biochemistry and Anesthesiology*,
Miyazaki Medical College,
5200 Kihara, Kiyotake, Miyazaki 889-16, Japan #Tokyo Research Institute, Daiichi Pure Chemicals Co. Ltd., Narihira,
Sumida-ku, Tokyo 130, Japan
Received July 28, 1988
SUMMARY: Brain natriuretic peptide (BNP) is a newly identified peptide of 26 residues, which has a remarkable homology to but is distinct from atrial natriuretic peptide. The peptide exerts natriuretic-diuretic activity as well as potent chick rectum relaxant activity. By using radioimmunoassay specific to BNP and immunoaffinity chromatography, we have isolated from porcine brain a novel peptide of 32 residues carrying a BNP structure at the C-terminus. The amino acid sequence of this peptide was determined to be: Ser-Pro-Lys-ThrMet -Arg-Asp- Ser-Gly- Cys-Phe-Gly-Arg-Arg-Leu-Asp-Arg- Ile-Gly- Ser-Leu- Ser-GlyLeu-Gly-Cys-Asn-Val-Leu-Arg-Arg-Tyr. This peptide is an N-terminal six amino acid extended form of BNP and henceforth is designated BNP-32~ BNP and BNP-32 are found to be major forms of BNP family in porcine brain. © 1988 Academic Press, Inc.
During the course of our search for undiscovered neuropeptides brain,
we
residues,
very
recently
designated
have
"brain
pharmacological remarkably
high
sequence
in porcine brain suggests maintaining
a novel
peptide
peptide
(BNP)",
spectrum very similar to that of ANP. homology
atrial natriuretic peptide
for
identified natriuretic
to ANP
(ANP) (I).
but
is
of
in porcine
26-amino
which
acid
elicits
a
The peptide also has a
definitely
different
from
The occurrence of BNP along with ANP
that two types of natriuretic peptides may function
homeostatic
developed radioimmunoassay
balance
of
(RIA) for BNP
screened BNP-related peptides
in
body
fluid.
By
using
a recently
(to be reported elsewhere),
porcine brain extracts
we have
and have isolated a
different form consisting of the original
26-residue BNP with an additional 6
amino acids attached at the N-terminus.
This new peptide we have designated
BNP-32.
In this
paper we
report isolation
and structural
determination
of
BNP-32.
MATERIALS AND METHODS Tissue extraction and isolation: Extraction and purification of BNP-32 were performed by the method similar to those used for the isolation of BNP, ~-
0006-291X/88 $1.50 Copyright © 1988 by Academic Press, Inc. All rights of reproduction in any form reserved.
726
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ANP[4-28] and ~--ANP[5-28] (i,2). Brain tissue (ca. 21o4 kg wet weight) excluding cerebellum was collected from 250 pigs soon after killing. Diced tissue was heated at 95-I00°C for 10 min in two volumes of water to inactivate proteases. After addition of glacial acetic acid (IM final concentration), the boiled tissue was homogenized by a Polytron mixer. The resulting homogenates were centrifuged at 20,000 x g for 30 min. The supernatant was then concentrated by filtration with a Pellicon PCAC membrane (#000-05, Millipore), which retained materials larger than IK daltons. The concentrate was precipitated by addition of acetone (final concentration=66%) and centrifuged. The supernatant thus obtained was then evaporated under reduced pressure. The residual materials were dissolved in 0.5M acetic acid and pumped onto a C-18 silica gel column (1.4 L, Chemco LC-SORB ODS); the materials adsorbed on the column were eluted with 60% CH_CN containing 0.1% 3 trifluoroacetic acid (TFA) % The eluates were evaporated and loaded onto a SP-Sephadex C-25 column (H -form, 3 x 28cm, Pharmacia) in 1M acetic acid. Successive elutions with IM acetic acid, 2M pyridine, and 2M pyridine-acetate (pH 5.0) yielded three fractions: SP-I, SP-II and SP-III, respectively. The SP-III fraction containing basic peptides was then subjected to successive gel filtrations on a Sephadex G-50 fine column (7.5 x 140 cm, Pharmacia) and on a Sephadex G-25 fine column (7.5 x 135 cm, Pharmacia) using IM acetic acid as an elution solvent. An aliquot of each fraction was submitted to RIA for BNP. A fraction containing immunoreactive BNP was + further separated by cation exchange chromat(~raphy on a CM-52 column (NH 4 -form, 2.4 x 45 cm, Whatman). Two major peaks of ir-BNP were each subjected to immunoaffinity chromatography on an anti-BNP IgG-AFFI-GEL column (see Delow). The peptide fraction adsorbed on the immunoaffinity column was then subjected to reverse phase high performance liquid chromatography (HPLC) on a 219TP54 diphenyl column (4.6 x 250 mm, Vydac) with a linear gradient elution of CH3CN in the solvent system of H20-CH3CN-10%TFA at a flow rate of 1.0 ml/min. The column effluents of HPLC were monitored by measuring absorbance at 210 nm and 280 nm. Structural analyses: After reductive S-carboxymethylation (RCM) of cystine with dithiothreitol and monoiodoacetic acid, the purified RCM-BNP-32 (ca. 150 pmol) and RCM-BNP (ca. 200 pmol) were each sequenced with a gas-phase sequencer, equipped with reverse phase HPLC for identification of the resulting phenylthiohydantoin (PTH) amino acids (Applied Biosystems, 470A/120A). Amino acid analyses were carried out with IRICA A-5550 amino acid analyzer, after acid hydrolysis of RCM-peptides (ca. 200 pmol) in 6M HCI containing 0.1% phenol and 0.02% 2-mercaptoethanol at II0°C for 24hr. Syntheses: BNP-32 was synthesized by solid phase techniques conducted on a chloromethylated polystyrene resin in a manner similar to those used for BNP (i). Correct synthesis was confirmed by amino acid analysis and sequencing. RIA for BNP: Details on preparation of an antiserum against BNP and characterization of RIA for BNP will be reported in a separate paper. In brief, an antiserum (#158-4) mainly recognizes the portion flanked by a disulfi~inkage, and BNP-32 has an affinity with the antiserum comparable to BNP. [~-~I]-BNP was prepared by the lactoperoxidase method and purified by reverse phase HPLC. Half-maximum inhibition of binding was observed at 9 fmol/tube of BNP, and peptides were measurable in a range of i-i00 fmol/tube. Immunoaffinity chromatography: Immunoglobulin G (IgG) fraction was purified by Protein A-Sepharose CL-4B (Pharmacia) from 2 ml of antiserum #158-5. IgG fraction was then coupled with 2 ml of AFFI-GEL I0 (Bio-Rad) in 0.1M sodium phosphate buffer (pH 7.4). Samples were d i s s o l v e d i n 0.1M sodium phosphate buffer (pH 7.4), loaded onto the column (gel volume, 1.0 ml), and washed with the same buffer; the adsorbed materials were then eluted with a solution of IM acetic acid containing 10% CH_CNo Bioassa~: Chick rectum relaxant effect, natriuretic-diuretic activity, and hypotensive activity of BNP-32 were assayed as reported (3,4). RESULTS AND DISCUSSION BNP-32 was
isolated
from porcine
brain by immunoaffinity
chromatography
and reverse phase HPLC coupled with RIA specific to BNP in a manner similar to
727
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1,o! 2
I° o
2;
30
4'0
5'o
Frectlon number
60
Figure i. Sephadex G-25 gel filtration of the basic peptide fraction obtained from 21.4 kg of porcine brain. Sample: Basic peptide fraction of molecular weight IK-5K daltons (dry weight, 1.48 g). Column: Sephadex G-25, fine (7.5 x 135 cm). Flow rate: 120 ml/hr. Fraction size: 100 ml/tube. Solvent: 1M acetic acid. The arrows indicate the elution positions of bovine serum albumin (BSA), gastrin releasing peptide (GRP) and neurotensin (NT), respectively. The fraction shown with a hatched bar was submitted to CM ion exchange chromatography.
those used
in our previous purification
of ~-ANP[4-28]
From the acid extracts of porcine brain was prepared
by Pellicon
(21.4 kg),
ultrafiltration,
chromatographies on a reverse phase C-18 25 ion exchange column.
acetone
and ~-ANP[5-28]
the basic peptide fraction precipitation,
shown),
(ir-)
The resulting SP-III
fraction
(dry weight,
Most of the
BNPs were eluted in a region of 2K-4K daltons
(data not The bulk
subjected
to ion exchange
combined i ~ u n o r e a c t i v i t y
ir-BNP on the chromatogram
(Fig. I),
chromatography
peaks of ir-BNP emerged at fractions A),
2.61 g)
and were further separated by Sephadex G-25 gel filtration.
of ir-BNP was eluted in fractions #32-36 then
step-wise
silica gel column and SP-Sephadex C-
was first subjected to gel filtration on a Sephadex G-50 column. immunoreactive
(2).
#68-71
which were lyophilized and
on a CM-52
column.
Two major
(Fr B) and fractions
#98-101
(Fr
of which corresponded to more than 70% of total
(Fig. 2).
After desalting with a C-18 cartridge,
Fr A and Fr B were each loaded onto an anti-BNP IgG in~nunoaffinity column, and the adsorbed materials were eluted with 1M acetic acid containing The peptides
related to BNP were
thus effectively
reverse phase HPLC on a diphenyl column,
purified.
The
peptides
peptides.
thus
isolated
were
into their respective
Amino acid analysis data
peptide B were
By subsequent
peptide A and peptide B were finally
purified to a homogeneous state from Fr A and Fr B, respectively
after conversion
10% CH3CN.
each
submitted
to
(Fig. 3).
structural
analyses
reduced and S-carboxymethylated (Table i) indicated
composed of 32 and 26 amino acid residues
728
(RCM-)
that peptide A and respectively,
each
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
i00 v
o
1
0.2
o 1.o .~ 0,5~
20
0
40
60
80 i00 Fraction number
120
140
160
Figure 2. CM ion exchange chromatography of ir-BNP fraction in Sephadex G-25 gel filtration. Sample: Fractions #32-36 from Sephadex G-25 gel fil~ration (hatched area in Fig. I) (dry weight, 440 rag). ColLmun: CM-52 (NH 4 -form, 2.4 x 45 cm), pre-equilibrated with solvent (I). Flow rate: 35 ml/hr. Fraction size: 20 ml/tube. Solvent system: Started with solvent (I), and changed at fraction #6 to a linear gradient elution from (I) (1.5 L) to (If) (1.5 L). (I) i0 mM HCOONH 4 (pH 6.6) : CH_CN = 90 : i 0 (v/v). (If) 0.5 M HCOONH 4 (pH 6.6) CH3CN 90 l0 (v/v).
with
2 cysteine
to that of BNP, residues yields peptide
in were
residues. while
addition
peptide to
estimated
B, s t a r t i n g
Peptide
to
B had
an amino
A consisted
those
of
be
about
BNP.
of 32 amino Based
560
acid composition
pmol
from 21.4 kg of p o r c i n e
acids
on these
for
peptide
containing
data, A
identical
and
the 750
6 more
isolation ix~ol for
brain.
a
60~ 40
0.1
2O >
o(
8
o
b 0,ii
ol
10
20
30
40 50 T t m e (mln)
60
70
80
Figure 3. Reverse phase HPLC of anti-BNP inununoaffinity purified fractions. Sample: Anti-BNP immunoaffinifty purified fractions of (a) Fr A and (b) Fr B in CM ion exchange chromatography (Fig. 2). Column: 219TP54 diphenyl (4.6 x 250 ram, Vydac). Flow rate: 1.0 ml/min. solvent system: H_O:CH_CN:I0%TFA = (I) 90:10:1, (II) 40:60:1 (v/v). Linear gradient e~utioJn from (1) to (If) for 120 rain. BNP irmuunoreaetivity was observed only at the black bar regions.
729
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table i.
Amino acid compositions (residues per mole) of RCM-BNP-32 and RCM-BNP
amino acid
BNP-32*
CmCys Asp Thr Ser Pro Gly Val Met
1.85 3.00 i.I0 3.73 0.90 5.21 1.01 0.95
Ile
Leu Tyr Phe Lys Arg
BNP #
(2) (3) (i) (4) (i) (5) (i)
1.81 3.02 2.84 5.04 1.18
1.07
(1) (1)
0.97
(1)
3.98 0.98 0.97 1.12 5.95
(4) (i) (i) (i) (6)
3.93 1.05 1.09 4.91
(4) (i) (i)
total
(2) (3) (3) (5) (i)
(5)
(32)
(26)
*) purified from Fr A. #) purified from Fr B. Numbers in parentheses represent the nearest integers.
Sequence gas-phase degradation peptides,
analysis
was p e r f o r m e d
sequencer.
PTH-amino
was s u c c e s s f u l l y as
shown
in
on 150-200
acid
identified
Fig.
4.
pmol of each R C M - p e p t i d e
liberated
at
each
up to the C - t e r m i n a l
Peptide
B was
cycle
of
residues
determined
to
be
of both exactly
a 60 <
40
D G F~ R
o 2o vo.
I
S
G k
l/
~
DR
~
\^GLG \/\ /"-'k N
"
S
L R
Y
o TD
100
L >-
50
L
~
GLG
i
Cycle number
Figure 4. Yield of PTH-amino acid at each cycle of Edman degradation. Sample: (a) RCM-BNP-32 and (b) RCM-BNP, prepared by reductive carboxymethylation of isolated peptides (Figs. 3a and 3b) followed by reverse phase HPLC purification. One letter amino acid notation is used. CmC; carboxymethyl cysteine.
730
by a Edman
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1
10
20
30
D-S-G-C-F-G-R-R-L-D-R-I-G-S-L-S-G-L-G-C-N-V-L-R-R-Y i
BNP
I
S~K-T-M~D~G[C-F-GIRR LD-R-I-GS-L.S-G-L-G-C-NIV-L-R ~
BNP-32
R-S-S-C-F-G-G-R-M-D-R-I-G-A-Q-S-G-L-G-C-N-S-F--R-Y t,.
a-hANP[4-28]
i
Figure 5. The amino acid sequences of BNP, BNP-32, y-ANP (human) and ~-ANP[4-28]. Identical residues of BNP-32 and y-ANP are boxed with solid lines. One letter amino acid notation is used.
identical
to BNP,
determined
to
which
the
of
deduced
natural
containing
been
an
isolated
peptide-32
(1).
an additional
at the N-terminus.
"brain natriuretic
structure
HPLC
previously
be a form of BNP carrying
(Ser-Pro-Lys-Thr--Met-Arg-) designated
had
6 amino
Hereafter,
(BNP-32)".
with
intramolecular
an
identically
disulfide
acid sequence
Positive confirmation
sequenced
linkage.
on reverse synthetic
Synthetic
BNP-32
and
identified,
relaxant
activity.
Thus,
thus
identified
was
found
to
elicit
at its N-terminus observed
intrinsic bioactivity
of BNP.
In the
~-hANP
and
isolate
definitely
biological
activity,
present
isolation,
we
employed
unfavorable
degradation
neuromedins
BNP and BNP-32
(5-7).
heat
in comparable
from 21.4 kg of porcine
amounts
fact
(750 pmol
that
we
intrinsic
confirmed in
in our previous
the
respectively)
of
isolation were
able
of to
and 560 pmol starting
in the present
study indicates
that BNP and BNP-32 are most likely to be two major endogenous
entities of BNP
family in porcine brain.
brain,
inactivation
which had been
of peptides Therefore,
This indicates
in BNP-32 may not change any
at the earliest stage of purification,
minimizing
diuretic-
was
to that induced by BNP of 26 amino acid residues.
that the six residues
proteases
BNP-32
peptide
as shown in Fig. 5.
BNP-32 comparable
rectum
of
phase
was also
found to have an identical potency to native BNP-32 in hypotensive, natriuretic,
A was
peptide A will be
above was made by co-chromatographies
BNP-32
Peptide
It is of interest that the ANP family found in brain
also consists of two molecular These
two
central
related
control
data obtained porcine
brain
ir-ANP
(0.03
families
forms,
of
i.e.,
natriuretic
of water-electrolyte
~-ANP[4-28] peptides
balance
may
and ~-ANP[5-28] participate
and blood pressure
in the present study reveal that the concentration (0.3 pmol/g wet tissue) pmol/g
wet
tissue)
is about ten times
(2).
This
also
in
(8-12).
(2). the RIA
of ir-BNP in
higher than that of
suggests
the
physiologic
importance of BNP family in the neural control of body fluid homeostasis. At present,
the entire
processing
compared with that of the ANP family.
pattern
However,
731
of the
BNP family
identification
cannot be
of BNP-32 along
Vol. 155, No. 2, 1988
with BNP family. precursor, is
may help
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
us elucidate
the processing
ANP of higher mammals
is initially
events involved synthesized as
from which y-ANP of 126 residues is processed.
cleaved in
response to
the Pro-Arg
generate the 28-residue ~-ANP
(13).
signal preceding
in the BNP
a 151-residue
The y-ANP in turn the e-ANP
In the BNP-32 molecule,
unit to
however,
the
Pro-Lys sequence replaces the Pro-Arg signal found in a similar region of the ANP family and remains uncut.
Moreover,
the ANP family in brain undergoes
further processing at the site of the Arg-Arg pair (corresponding to position 3-4 in e-ANP) to yield yet shorter ~-ANP[4-28] of the Arg-Arg sequence found in ~-ANP, These
varying
amino
acid
and e-ANP[5-28]
( 2 ) . Instead
BNP-32 has only one Arg at this site.
substitutions
in
the
BNP
family
may
reflect
a
different processing pattern than that for the ANP family. ACKNOWLEDGEMENTS: The authors are grateful to Dro S. Ueda and Miss T. Hatoh for RIA and synthesis. This work was supported in part by a Grant-in-Aid from the Ministry of Education, Science and Culture of Japan.
REFERENCES i. sudoh, T., Kangawa, K., Minamino, N. & Matsuo, H. (1988) Nature, 332, 78-81. 2. Ueda, S., Sudoh, T. Fukuda, K°, Kangawa, K., Minamino, N. & Matsuo, H. (1987) Biochem. Biophys. Res. Commun., 149, 1055-1062. 3. Kangawa, K. & Matsuo, H. (1984) Biochem. Eiophys. Res. Commun., 118, 131-139. 4. Currie, M.C., Geller, D.M~, Cole, B.R., Boylar, J.G., YuSheng, W., Holmberg, S.W. & Needleman, P. (1983) Science, 221, 71-73. 5. Miyata, Ao, Kangawa, K., Toshimori, T., Hatoh, T. & Matsuo, H. (1985) Biochem. Biophys. ReSo Commun. 129, 248-255. 6. Minamino, N., Masuda, H., Kangawa, K. & Matsuo, H. (1984) Biochem. Biophys. Res. Commun. 124, 731-738. 7. Minamino, N°, Kangawa, K. & Matsuo, H. (1984) Biochem. Biophys. Res. Commun. 124, 925-932. 8. Quirion, R., Daple, M., de Lean, A., Gutkowska, J., Cantin, M. & Genest, J. (1984) Peptides, 5, 1167-1172. 9. Saper, C.B., Standaert, D.G., Currie, M.G., Schwartz, D., Geller, D.M. & Needleman, P. (1985) Science, 227, 1047-1049. i0. Kawata, M., Nakao, K., Morii, N., Kiso, Y., yamashita, H., Imura, H. & Sano, Y. (1985) Neuroscience, 16, 521-546. ii. Jacobowitz, D.M., Skofitsch, G., Keiser, H.R., Eskay, R.L. & Zamir, N. (1985) Neuroendocrinology, 40, 92-94. 12. Nakao, K., Morii, N., Itoh, H., Yamada, T., Shiono, S., Sugawara, A., saito, Y., Mukoyama, M., Arai, H., Sakamoto, M. Imura, H. (1986) J. Hypertension 4 (Suppl. 6), S492-496. 13. Matsuo, H. & Nakazato, H. (1987) Endocrin. Metab. Clin. North America, 16, 43-61.
732
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages 726-732
September 15, 1988
B R A I N NATRI[R~ETIC PEPTIDE-32: B R A I N NATRIURETIC
N-TERMINaL
PEPTIDE
SIX A M I N O A C I D w~TE~DED F O R M OF
IDENTIFIED
IN PORCINE B R A I N
Tetsuji SUDOH #, Naoto MINAMINO*, Kenji KANGAWA & Hisayuki MATSUO
Departments of Biochemistry and Anesthesiology*,
Miyazaki Medical College,
5200 Kihara, Kiyotake, Miyazaki 889-16, Japan #Tokyo Research Institute, Daiichi Pure Chemicals Co. Ltd., Narihira,
Sumida-ku, Tokyo 130, Japan
Received July 28, 1988
SUMMARY: Brain natriuretic peptide (BNP) is a newly identified peptide of 26 residues, which has a remarkable homology to but is distinct from atrial natriuretic peptide. The peptide exerts natriuretic-diuretic activity as well as potent chick rectum relaxant activity. By using radioimmunoassay specific to BNP and immunoaffinity chromatography, we have isolated from porcine brain a novel peptide of 32 residues carrying a BNP structure at the C-terminus. The amino acid sequence of this peptide was determined to be: Ser-Pro-Lys-ThrMet -Arg-Asp- Ser-Gly- Cys-Phe-Gly-Arg-Arg-Leu-Asp-Arg- Ile-Gly- Ser-Leu- Ser-GlyLeu-Gly-Cys-Asn-Val-Leu-Arg-Arg-Tyr. This peptide is an N-terminal six amino acid extended form of BNP and henceforth is designated BNP-32~ BNP and BNP-32 are found to be major forms of BNP family in porcine brain. © 1988 Academic Press, Inc.
During the course of our search for undiscovered neuropeptides brain,
we
residues,
very
recently
designated
have
"brain
pharmacological remarkably
high
sequence
in porcine brain suggests maintaining
a novel
peptide
peptide
(BNP)",
spectrum very similar to that of ANP. homology
atrial natriuretic peptide
for
identified natriuretic
to ANP
(ANP) (I).
but
is
of
in porcine
26-amino
which
acid
elicits
a
The peptide also has a
definitely
different
from
The occurrence of BNP along with ANP
that two types of natriuretic peptides may function
homeostatic
developed radioimmunoassay
balance
of
(RIA) for BNP
screened BNP-related peptides
in
body
fluid.
By
using
a recently
(to be reported elsewhere),
porcine brain extracts
we have
and have isolated a
different form consisting of the original
26-residue BNP with an additional 6
amino acids attached at the N-terminus.
This new peptide we have designated
BNP-32.
In this
paper we
report isolation
and structural
determination
of
BNP-32.
MATERIALS AND METHODS Tissue extraction and isolation: Extraction and purification of BNP-32 were performed by the method similar to those used for the isolation of BNP, ~-
0006-291X/88 $1.50 Copyright © 1988 by Academic Press, Inc. All rights of reproduction in any form reserved.
726
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ANP[4-28] and ~--ANP[5-28] (i,2). Brain tissue (ca. 21o4 kg wet weight) excluding cerebellum was collected from 250 pigs soon after killing. Diced tissue was heated at 95-I00°C for 10 min in two volumes of water to inactivate proteases. After addition of glacial acetic acid (IM final concentration), the boiled tissue was homogenized by a Polytron mixer. The resulting homogenates were centrifuged at 20,000 x g for 30 min. The supernatant was then concentrated by filtration with a Pellicon PCAC membrane (#000-05, Millipore), which retained materials larger than IK daltons. The concentrate was precipitated by addition of acetone (final concentration=66%) and centrifuged. The supernatant thus obtained was then evaporated under reduced pressure. The residual materials were dissolved in 0.5M acetic acid and pumped onto a C-18 silica gel column (1.4 L, Chemco LC-SORB ODS); the materials adsorbed on the column were eluted with 60% CH_CN containing 0.1% 3 trifluoroacetic acid (TFA) % The eluates were evaporated and loaded onto a SP-Sephadex C-25 column (H -form, 3 x 28cm, Pharmacia) in 1M acetic acid. Successive elutions with IM acetic acid, 2M pyridine, and 2M pyridine-acetate (pH 5.0) yielded three fractions: SP-I, SP-II and SP-III, respectively. The SP-III fraction containing basic peptides was then subjected to successive gel filtrations on a Sephadex G-50 fine column (7.5 x 140 cm, Pharmacia) and on a Sephadex G-25 fine column (7.5 x 135 cm, Pharmacia) using IM acetic acid as an elution solvent. An aliquot of each fraction was submitted to RIA for BNP. A fraction containing immunoreactive BNP was + further separated by cation exchange chromat(~raphy on a CM-52 column (NH 4 -form, 2.4 x 45 cm, Whatman). Two major peaks of ir-BNP were each subjected to immunoaffinity chromatography on an anti-BNP IgG-AFFI-GEL column (see Delow). The peptide fraction adsorbed on the immunoaffinity column was then subjected to reverse phase high performance liquid chromatography (HPLC) on a 219TP54 diphenyl column (4.6 x 250 mm, Vydac) with a linear gradient elution of CH3CN in the solvent system of H20-CH3CN-10%TFA at a flow rate of 1.0 ml/min. The column effluents of HPLC were monitored by measuring absorbance at 210 nm and 280 nm. Structural analyses: After reductive S-carboxymethylation (RCM) of cystine with dithiothreitol and monoiodoacetic acid, the purified RCM-BNP-32 (ca. 150 pmol) and RCM-BNP (ca. 200 pmol) were each sequenced with a gas-phase sequencer, equipped with reverse phase HPLC for identification of the resulting phenylthiohydantoin (PTH) amino acids (Applied Biosystems, 470A/120A). Amino acid analyses were carried out with IRICA A-5550 amino acid analyzer, after acid hydrolysis of RCM-peptides (ca. 200 pmol) in 6M HCI containing 0.1% phenol and 0.02% 2-mercaptoethanol at II0°C for 24hr. Syntheses: BNP-32 was synthesized by solid phase techniques conducted on a chloromethylated polystyrene resin in a manner similar to those used for BNP (i). Correct synthesis was confirmed by amino acid analysis and sequencing. RIA for BNP: Details on preparation of an antiserum against BNP and characterization of RIA for BNP will be reported in a separate paper. In brief, an antiserum (#158-4) mainly recognizes the portion flanked by a disulfi~inkage, and BNP-32 has an affinity with the antiserum comparable to BNP. [~-~I]-BNP was prepared by the lactoperoxidase method and purified by reverse phase HPLC. Half-maximum inhibition of binding was observed at 9 fmol/tube of BNP, and peptides were measurable in a range of i-i00 fmol/tube. Immunoaffinity chromatography: Immunoglobulin G (IgG) fraction was purified by Protein A-Sepharose CL-4B (Pharmacia) from 2 ml of antiserum #158-5. IgG fraction was then coupled with 2 ml of AFFI-GEL I0 (Bio-Rad) in 0.1M sodium phosphate buffer (pH 7.4). Samples were d i s s o l v e d i n 0.1M sodium phosphate buffer (pH 7.4), loaded onto the column (gel volume, 1.0 ml), and washed with the same buffer; the adsorbed materials were then eluted with a solution of IM acetic acid containing 10% CH_CNo Bioassa~: Chick rectum relaxant effect, natriuretic-diuretic activity, and hypotensive activity of BNP-32 were assayed as reported (3,4). RESULTS AND DISCUSSION BNP-32 was
isolated
from porcine
brain by immunoaffinity
chromatography
and reverse phase HPLC coupled with RIA specific to BNP in a manner similar to
727
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1,o! 2
I° o
2;
30
4'0
5'o
Frectlon number
60
Figure i. Sephadex G-25 gel filtration of the basic peptide fraction obtained from 21.4 kg of porcine brain. Sample: Basic peptide fraction of molecular weight IK-5K daltons (dry weight, 1.48 g). Column: Sephadex G-25, fine (7.5 x 135 cm). Flow rate: 120 ml/hr. Fraction size: 100 ml/tube. Solvent: 1M acetic acid. The arrows indicate the elution positions of bovine serum albumin (BSA), gastrin releasing peptide (GRP) and neurotensin (NT), respectively. The fraction shown with a hatched bar was submitted to CM ion exchange chromatography.
those used
in our previous purification
of ~-ANP[4-28]
From the acid extracts of porcine brain was prepared
by Pellicon
(21.4 kg),
ultrafiltration,
chromatographies on a reverse phase C-18 25 ion exchange column.
acetone
and ~-ANP[5-28]
the basic peptide fraction precipitation,
shown),
(ir-)
The resulting SP-III
fraction
(dry weight,
Most of the
BNPs were eluted in a region of 2K-4K daltons
(data not The bulk
subjected
to ion exchange
combined i ~ u n o r e a c t i v i t y
ir-BNP on the chromatogram
(Fig. I),
chromatography
peaks of ir-BNP emerged at fractions A),
2.61 g)
and were further separated by Sephadex G-25 gel filtration.
of ir-BNP was eluted in fractions #32-36 then
step-wise
silica gel column and SP-Sephadex C-
was first subjected to gel filtration on a Sephadex G-50 column. immunoreactive
(2).
#68-71
which were lyophilized and
on a CM-52
column.
Two major
(Fr B) and fractions
#98-101
(Fr
of which corresponded to more than 70% of total
(Fig. 2).
After desalting with a C-18 cartridge,
Fr A and Fr B were each loaded onto an anti-BNP IgG in~nunoaffinity column, and the adsorbed materials were eluted with 1M acetic acid containing The peptides
related to BNP were
thus effectively
reverse phase HPLC on a diphenyl column,
purified.
The
peptides
peptides.
thus
isolated
were
into their respective
Amino acid analysis data
peptide B were
By subsequent
peptide A and peptide B were finally
purified to a homogeneous state from Fr A and Fr B, respectively
after conversion
10% CH3CN.
each
submitted
to
(Fig. 3).
structural
analyses
reduced and S-carboxymethylated (Table i) indicated
composed of 32 and 26 amino acid residues
728
(RCM-)
that peptide A and respectively,
each
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
i00 v
o
1
0.2
o 1.o .~ 0,5~
20
0
40
60
80 i00 Fraction number
120
140
160
Figure 2. CM ion exchange chromatography of ir-BNP fraction in Sephadex G-25 gel filtration. Sample: Fractions #32-36 from Sephadex G-25 gel fil~ration (hatched area in Fig. I) (dry weight, 440 rag). ColLmun: CM-52 (NH 4 -form, 2.4 x 45 cm), pre-equilibrated with solvent (I). Flow rate: 35 ml/hr. Fraction size: 20 ml/tube. Solvent system: Started with solvent (I), and changed at fraction #6 to a linear gradient elution from (I) (1.5 L) to (If) (1.5 L). (I) i0 mM HCOONH 4 (pH 6.6) : CH_CN = 90 : i 0 (v/v). (If) 0.5 M HCOONH 4 (pH 6.6) CH3CN 90 l0 (v/v).
with
2 cysteine
to that of BNP, residues yields peptide
in were
residues. while
addition
peptide to
estimated
B, s t a r t i n g
Peptide
to
B had
an amino
A consisted
those
of
be
about
BNP.
of 32 amino Based
560
acid composition
pmol
from 21.4 kg of p o r c i n e
acids
on these
for
peptide
containing
data, A
identical
and
the 750
6 more
isolation ix~ol for
brain.
a
60~ 40
0.1
2O >
o(
8
o
b 0,ii
ol
10
20
30
40 50 T t m e (mln)
60
70
80
Figure 3. Reverse phase HPLC of anti-BNP inununoaffinity purified fractions. Sample: Anti-BNP immunoaffinifty purified fractions of (a) Fr A and (b) Fr B in CM ion exchange chromatography (Fig. 2). Column: 219TP54 diphenyl (4.6 x 250 ram, Vydac). Flow rate: 1.0 ml/min. solvent system: H_O:CH_CN:I0%TFA = (I) 90:10:1, (II) 40:60:1 (v/v). Linear gradient e~utioJn from (1) to (If) for 120 rain. BNP irmuunoreaetivity was observed only at the black bar regions.
729
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table i.
Amino acid compositions (residues per mole) of RCM-BNP-32 and RCM-BNP
amino acid
BNP-32*
CmCys Asp Thr Ser Pro Gly Val Met
1.85 3.00 i.I0 3.73 0.90 5.21 1.01 0.95
Ile
Leu Tyr Phe Lys Arg
BNP #
(2) (3) (i) (4) (i) (5) (i)
1.81 3.02 2.84 5.04 1.18
1.07
(1) (1)
0.97
(1)
3.98 0.98 0.97 1.12 5.95
(4) (i) (i) (i) (6)
3.93 1.05 1.09 4.91
(4) (i) (i)
total
(2) (3) (3) (5) (i)
(5)
(32)
(26)
*) purified from Fr A. #) purified from Fr B. Numbers in parentheses represent the nearest integers.
Sequence gas-phase degradation peptides,
analysis
was p e r f o r m e d
sequencer.
PTH-amino
was s u c c e s s f u l l y as
shown
in
on 150-200
acid
identified
Fig.
4.
pmol of each R C M - p e p t i d e
liberated
at
each
up to the C - t e r m i n a l
Peptide
B was
cycle
of
residues
determined
to
be
of both exactly
a 60 <
40
D G F~ R
o 2o vo.
I
S
G k
l/
~
DR
~
\^GLG \/\ /"-'k N
"
S
L R
Y
o TD
100
L >-
50
L
~
GLG
i
Cycle number
Figure 4. Yield of PTH-amino acid at each cycle of Edman degradation. Sample: (a) RCM-BNP-32 and (b) RCM-BNP, prepared by reductive carboxymethylation of isolated peptides (Figs. 3a and 3b) followed by reverse phase HPLC purification. One letter amino acid notation is used. CmC; carboxymethyl cysteine.
730
by a Edman
Vol. 155, No. 2, 1988
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1
10
20
30
D-S-G-C-F-G-R-R-L-D-R-I-G-S-L-S-G-L-G-C-N-V-L-R-R-Y i
BNP
I
S~K-T-M~D~G[C-F-GIRR LD-R-I-GS-L.S-G-L-G-C-NIV-L-R ~
BNP-32
R-S-S-C-F-G-G-R-M-D-R-I-G-A-Q-S-G-L-G-C-N-S-F--R-Y t,.
a-hANP[4-28]
i
Figure 5. The amino acid sequences of BNP, BNP-32, y-ANP (human) and ~-ANP[4-28]. Identical residues of BNP-32 and y-ANP are boxed with solid lines. One letter amino acid notation is used.
identical
to BNP,
determined
to
which
the
of
deduced
natural
containing
been
an
isolated
peptide-32
(1).
an additional
at the N-terminus.
"brain natriuretic
structure
HPLC
previously
be a form of BNP carrying
(Ser-Pro-Lys-Thr--Met-Arg-) designated
had
6 amino
Hereafter,
(BNP-32)".
with
intramolecular
an
identically
disulfide
acid sequence
Positive confirmation
sequenced
linkage.
on reverse synthetic
Synthetic
BNP-32
and
identified,
relaxant
activity.
Thus,
thus
identified
was
found
to
elicit
at its N-terminus observed
intrinsic bioactivity
of BNP.
In the
~-hANP
and
isolate
definitely
biological
activity,
present
isolation,
we
employed
unfavorable
degradation
neuromedins
BNP and BNP-32
(5-7).
heat
in comparable
from 21.4 kg of porcine
amounts
fact
(750 pmol
that
we
intrinsic
confirmed in
in our previous
the
respectively)
of
isolation were
able
of to
and 560 pmol starting
in the present
study indicates
that BNP and BNP-32 are most likely to be two major endogenous
entities of BNP
family in porcine brain.
brain,
inactivation
which had been
of peptides Therefore,
This indicates
in BNP-32 may not change any
at the earliest stage of purification,
minimizing
diuretic-
was
to that induced by BNP of 26 amino acid residues.
that the six residues
proteases
BNP-32
peptide
as shown in Fig. 5.
BNP-32 comparable
rectum
of
phase
was also
found to have an identical potency to native BNP-32 in hypotensive, natriuretic,
A was
peptide A will be
above was made by co-chromatographies
BNP-32
Peptide
It is of interest that the ANP family found in brain
also consists of two molecular These
two
central
related
control
data obtained porcine
brain
ir-ANP
(0.03
families
forms,
of
i.e.,
natriuretic
of water-electrolyte
~-ANP[4-28] peptides
balance
may
and ~-ANP[5-28] participate
and blood pressure
in the present study reveal that the concentration (0.3 pmol/g wet tissue) pmol/g
wet
tissue)
is about ten times
(2).
This
also
in
(8-12).
(2). the RIA
of ir-BNP in
higher than that of
suggests
the
physiologic
importance of BNP family in the neural control of body fluid homeostasis. At present,
the entire
processing
compared with that of the ANP family.
pattern
However,
731
of the
BNP family
identification
cannot be
of BNP-32 along
Vol. 155, No. 2, 1988
with BNP family. precursor, is
may help
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
us elucidate
the processing
ANP of higher mammals
is initially
events involved synthesized as
from which y-ANP of 126 residues is processed.
cleaved in
response to
the Pro-Arg
generate the 28-residue ~-ANP
(13).
signal preceding
in the BNP
a 151-residue
The y-ANP in turn the e-ANP
In the BNP-32 molecule,
unit to
however,
the
Pro-Lys sequence replaces the Pro-Arg signal found in a similar region of the ANP family and remains uncut.
Moreover,
the ANP family in brain undergoes
further processing at the site of the Arg-Arg pair (corresponding to position 3-4 in e-ANP) to yield yet shorter ~-ANP[4-28] of the Arg-Arg sequence found in ~-ANP, These
varying
amino
acid
and e-ANP[5-28]
( 2 ) . Instead
BNP-32 has only one Arg at this site.
substitutions
in
the
BNP
family
may
reflect
a
different processing pattern than that for the ANP family. ACKNOWLEDGEMENTS: The authors are grateful to Dro S. Ueda and Miss T. Hatoh for RIA and synthesis. This work was supported in part by a Grant-in-Aid from the Ministry of Education, Science and Culture of Japan.
REFERENCES i. sudoh, T., Kangawa, K., Minamino, N. & Matsuo, H. (1988) Nature, 332, 78-81. 2. Ueda, S., Sudoh, T. Fukuda, K°, Kangawa, K., Minamino, N. & Matsuo, H. (1987) Biochem. Biophys. Res. Commun., 149, 1055-1062. 3. Kangawa, K. & Matsuo, H. (1984) Biochem. Eiophys. Res. Commun., 118, 131-139. 4. Currie, M.C., Geller, D.M~, Cole, B.R., Boylar, J.G., YuSheng, W., Holmberg, S.W. & Needleman, P. (1983) Science, 221, 71-73. 5. Miyata, Ao, Kangawa, K., Toshimori, T., Hatoh, T. & Matsuo, H. (1985) Biochem. Biophys. ReSo Commun. 129, 248-255. 6. Minamino, N., Masuda, H., Kangawa, K. & Matsuo, H. (1984) Biochem. Biophys. Res. Commun. 124, 731-738. 7. Minamino, N°, Kangawa, K. & Matsuo, H. (1984) Biochem. Biophys. Res. Commun. 124, 925-932. 8. Quirion, R., Daple, M., de Lean, A., Gutkowska, J., Cantin, M. & Genest, J. (1984) Peptides, 5, 1167-1172. 9. Saper, C.B., Standaert, D.G., Currie, M.G., Schwartz, D., Geller, D.M. & Needleman, P. (1985) Science, 227, 1047-1049. i0. Kawata, M., Nakao, K., Morii, N., Kiso, Y., yamashita, H., Imura, H. & Sano, Y. (1985) Neuroscience, 16, 521-546. ii. Jacobowitz, D.M., Skofitsch, G., Keiser, H.R., Eskay, R.L. & Zamir, N. (1985) Neuroendocrinology, 40, 92-94. 12. Nakao, K., Morii, N., Itoh, H., Yamada, T., Shiono, S., Sugawara, A., saito, Y., Mukoyama, M., Arai, H., Sakamoto, M. Imura, H. (1986) J. Hypertension 4 (Suppl. 6), S492-496. 13. Matsuo, H. & Nakazato, H. (1987) Endocrin. Metab. Clin. North America, 16, 43-61.
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