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Natural occurrence of guanidinooxypropylamine in Wistaria floribunda and the sword bean Canavalia gladiata
Vol.
129,
No.
May
31,
1985
1, 1985
BIOCHEMICAL
BIOPHYSICAL
AND
COMMUNICATIONS
RESEARCH
Pages
NATURAL OCCURRENCE OF GUANIDINOOXYPROPYLAMINE IN Wistaria AND THE SWORD BEAN CanavaZia gladiata Koei
Hamana and Shigeru
46-51
fZoribunda
Matsuzaki*
College of Medical Care and Technology and *Department of Physiology, Institute of Endocrinology, Gunma University, Maebashi 371, Japan Received
April
16,
1985
SUMMARY: We found a new guanidinooxyamine in Wistaria ftoribunda seeds and seedlings of the sword bean, Canavalia gladiata. This amine was not only ninhydrin-positive but also gave a positive alkaline nitroprussideferricyanide reaction. It was characterized as y-guanidinooxypropylamine [H2N(NH=)CNHO(CH2)$H21 by comparison with the authentic compound on column and thin-layer chromatograms visualized with specific reagents and by reductive cleavage. Evidence for the occurrence of another unusual guanidino amine, homoagmatine in W. floribunda seeds was also presented. 0 1985 Academic Press, Inc.
Polyamines molecular
have
biosynthesis
have
been found
have
been detected
cadaverine
in higher
plants
have
also
course
have
observed
gave
a positive
corresponded
of
several
plants,
in Lathyrus
unknown
on our column
nitroprusside-ferricyanide to either
leguminous
plants
contain
canavanine
(6-8),
we speculated
it
amino
This
products ation
of these product
several
agmatine
acids.
of L-canavanine.
guanidino would
The present
0006-291X/85 $1.50 Copyr&ht All rights
0 1985 by Academic Press, of reproduction in any form
Inc. reserved.
46
them.
Several
bean,
seedlings
for
(5).
in leguminous
be one of
plants,
chromatograms. though
acids the
compound communication
example,
CanavaZia
it
or homoagmatine. amino
unknown
and spermine
plants,
reaction,
L-canavanine,
of
in sword
sativus
polyamines
1,3-diaminopropane,
number
on polyamines
peaks
of macro-
spermidine
in particular
canavalmine
control
common and "unusual"
while
been found
investigations
in the
Putrescine,
in a limited
(3),
(4) and homoagmatine
Both
(2).
are found
in sandalwood
In the
(1).
in many different
polyamines
homospermidine
to be implicated
and growth
and agmatine
"unusual"
gZadiata
been shown
One of did
we them
not
Since
including
L-
decarboxylation was indeed deals
a decarboxylwith
the
Vol.
129,
No.
1, 1985
BIOCHEMICAL
and characterization
isolation
in Wistaria
AND
BIOPHYSICAL
of a hitherto
RESEARCH
unrecognized
COMMUNICATIONS
guanidinooxyamine
and C. gladiata.
floribunda
MATERIALS AND METHODS Chemicals_L-ArginineeHCl, L-homoarginine.HCl, L-canavanine.H2SOh, putrescine*2HCl, cadaverines2HC1, spermidines3HC1, spermines4HC1, arcaine.H2SOk hirudonine*H2SOh, agmatineeH2S04, octopine, o-methylisourea sulfate and palladium-barium sulfate were purchased from Sigma (St. Louis, MO). 3-Hydroxypropylamine was obtained from Wako Pure Chemicals (Osaka). Ten aliphatic pentaamines which contain aminopropyl and/or aminobutyl moieties were kindly supplied by Dr. K. Samejima of Josai University. Homospermidine and aminobutylhomospermidine (homospermine) were synthesized according to Okada et al The synthesis of homoagmatine (monoamidinocadaverine) and audouine (9). (diamidinocadaverine) was achieved by guanidation of cadaverine with ocadaverinee2HCl was treated with o-methylisoureamethylisourea (5). Briefly, HCl in 2M NaOH at pH 10.5 for 5 days at 25'C. Homoagmatine and audouine were separated from unreacted cadaverine with a column (9 x 120 mm) of ion-exchange resin (Hitachi Custom 2612). The conversion of sulfate forms of L-canavanine, agmatine and o-methylisourea to hydrochloride forms was achieved by passing through a column of Dowex l-X8 before use. Guanidinooxypropylamine was enzymatically synthesized from L-canavanine. L-CanavanineeHCl was incubated with acetone-dried Escherichia coli 7020 (IF0 3544) in 0.2M acetate buffer (pH 5.25) at 3O'C for 1 hr (10). After the termination of the reaction with cold 0.5N HClOt+, the decarboxylation product of L-canavanine was purified by column chromatography as described above.
Canavalia gladiata seeds were fZoribunda seeds were collected in water imbibition for 12 hr, the seeds in the dark on moistened filter paper
Materials
Wistaria After grow
purchased from a local seed dealer. botanical gardens in Maebashi. were germinated and allowed to discs.
Polyaminc analysis Seeds and seedlings were homogenized in 3 volumes of 0.5N HC~OL,. After centrifugation of the homogenates, the supernatants were passed through a column (2.5 x 2 cm) of Dowex-50 W to concentrate polyamines Polyamines were analyzed by highand to eliminate amino acids (11). performance ion-exchange column chromatography as described previously (12) The identity of polyamines was also established with slight modifications. by thin-layer chromatography on cellulose and silica gel (13). Amines on chromatograms were visualized by spraying either ninhydrin, Sakaguchi or alkaline nitroprusside-ferricyanide (pentacyanoferrate) reagent. Large
scale isolation of guanidinooxypropylamine Approximately 1 kg of seeds and CanavaZia seedings were homogenized in 10 1 of 0.5N Hc101+. Polyamines and unknown compounds in HC104 extracts were concentrated by the and then separated by a column of Hitachi Custom use of a Dowex-50 W column, 2612 (13).
Wistaria
RESULTS When analyzed chromatography, were
detected
appeared
the use of our highly
with putrescine,
in the
in seedlings
seed of
spermidine,
Wisttia
of W. floribunda
sensitive
homospermidine, f~orib~nda
(1B)
(Fig.
high-performance spermine 1A).
liquid
and agmatine
Cadaverine
and Canava~ia gZadiata
(li).
Vol.
129,
No.
BIOCHEMICAL
1, 1985
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1 2 ‘7 /3 1
50
5 LL- d 1
’
:‘I
IF-
60
o”o-
ELUTION
Fig.
Besides
polyamines
This
identical
to
peak
such
The retention including
tested
such
eluted
both
authentic systems
prior
not
seeds
norepinephrine, tryptamine,
and Canavalia
not
were (Fig.
any of
seedlings whenever
shown). 48
the
10 penta-
compounds
(diamidinoputrescine),
also lD),
was not
Other
behaved different
[N2-(l-
octopamine,
histamine,
excluded. though
audouine
octopine
cystamine,
and
and homospermine.
normetanephrine,
tyramine,
seedlings
(data
of
(diamidinospermidine),
guanidinooxypropylamine used
to that
spermine
It
thermospermine
arcaine
hirudonine
in C. gladiata
between
and homocaldopentamine.
and N-carbamylputrescine
were
0
to canavalmine.
correspond
as aminopropylcadaverine,
serotonin,
Wistaria
60
(min)
as norspermine,
caldopentamine
carboxyethyl)-L-arginine],
appeared
7x2
peak Xl was found
a little
of Xl did
(diamidinocadaverine),
histamine,
TIME
a prominent
tetraamines
time
amines
dopamine,
40
1. Elution profiles of polyamines found in Wistaria f~or'hndu and Camvalia ghfiata. Polyamines were separated by highperformance ion-exchange chromatography from the seeds (A and C) and seedlings (B and D) of W. fZoribu?da and C. ghdiata, Elution patterns of the polyamines were followed respectively. The numbers above the peaks correspond to: by o-pthalaldehyde. (1) putrescine; (2) cadaverine; (3) spermidine; (4) homospermidine; (5) spermine; (6) canavalmine; (7) agmatine and (8) homoagmatine. Xl and X2, unknown compounds. Dotted lines indicate the curves at 25 times the standard sensitivity.
these
agmatine.
X1 6
2’
8
J I;+4 40
l-methyl-
The same peak
not
in the
seeds.
chromatographically columns
and solvent
as Xl Xl from like
Vol.
129,
No.
1, 1985
BIOCHEMICAL
When pooled were
analyzed
is
A-I
by thin-layer
propylamine which
fractions
(Fig.
3).
specific
homoagmatine,
which
produced.
All
of which
COMMUNICATIONS
contained
Xl
just
like
(Fig.
compounds.
Unlike
to Natelson
show that
(14),
reaction,
agmatine
When reduced
and
in the presence
Xl disappeared
is indeed
of
and new
and 3-hydroxypropylamine Xl
2)
guanidinooxy-
nitroprusside-ferricyanide
to guanidine
findings
RESEARCH
Xl behaved
a positive
according
corresponded these
both
Sakaguchi-positive.
sulfate
compounds
gave
guanidinooxy
Xl was not
palladium-barium
and B-I
BIOPHYSICAL
chromatography, It
for
AND
were
identical
to guanidinooxy-
propylamine. A-II
was identified
techniques
(Fig.
and seed.Lings amount A minor
of this
3).
of
Agmatine
of W. ftoribunda guanidino
peak which
seedlings
as agmatine is
amine
but
the most
(0.6-0.8
not
and thin-layer
abundant
pmoles/g
was detected
corresponded
Wistaria,
by column
polyamine weight),
to homoagmatine
other F
F
VOLUME
(ml)
03 O
only
a small (Fig.
in both
5
minor
peaks
3 Gua 0
0
B
O:H-Agm
0
H-A~Q ACQ Call
andard
/ B-I
A-l A-II
0
andard
6-I
A-I A-II
Fig.
separation of polyamines and Xl from W. fZoribunda 2. Large-scale (A) and C. gZa&iata (B). Polyamines were detected by ninhydrinreagent at 570 nm. Pooled fractions A-I, A-II and B-I were used for further analysis.
Fig.
chromatographic separation of A-I, A-II and B-I 3. Thin-layer on cellulose (A) and silica gel G (B). Arginine (Arg), homoarginine (H-Arg), canavanine (Can), agmatine (Agm), homoagmatine (H-Amg) and guanidinooxypropylamine (Gus) were run Spots on chromatograms were visualized by stimulataneously. spraying alkaline nitroprusside-ferricyanide (open circle) or Sakaguchi (dotted circle) reagent. Solvent systems used were isopropanol-ammonia (7:3, V/V) (A) and chloroform-methanol-ammonia (2:2:1, V.V) (B). 0, origin; F, solvent front. 49
1D).
seeds
A
:Q,. H-Agm .Q.Agm .e. 0,. - GM 0
ELUTION
seeds
seedlings
was observed Several
in both
while
in CanavaZia
in CanavaZia.
chromatographic
and
were
Vol.
129,
No.
found
1, 1985
BIOCHEMICAL
in Canavalia
identified
seeds
from
formula,
the
AND
BIOPHYSICAL
and seedlings.
retention
times
RESEARCH
The unknown as pentaamine
H~N(CH~)~NH(CH~)I+NH(CH~)~NH(CH~)~NH~
peak
of
X2 was tentatively
the
among the
COMMUNICATIONS
constitutional 10 pentaamines
examined,
DISCUSSION L-Canavanine acid
first
(a-amino-y-guanidinooxybutyric
found
in the
to occur
in a number
especially
abundant
(8).
It
these
plants.
jack
of
in the
can be converted
this
by E. coZi
contain
experiments
It
is
detoxicated
metabolite
of interest
to note
not
a decarboxylase amino
acid
amounts
known,
this
for
the
for
content
for
arginine
substrate
but
an inhibitor
(18).
Thus,
it
formed
by arginine
remains
that
is
it
no
amine
occurs
L-canavanine
in these
plants
(15).
of Leguminosae
which
as a normal is merely
an inert
active
increases induced
L-
contains
Possibly
species
in
from
this
gladiata.
is
acid
and Wistaria
normally
has shown
whether
L-canavanine
amine.
in CanavaZia during
or It
is
seedlings.
germination
like
(16).
seeds
contain
enormous it
formation
substrate
of Canavalia
or a biologically
amine
amino
by decarboxylation
other
however,
of guanidinooxypropylamine,
responsible
This
guanidinooxypropylamine
decarboxylases
W. fZoribunda
Since
contain
of L-canavanine that
8).
as by arginase
that
amino
(7) and has been shown
bacterium
and CanavaZia as well
a nonprotein
shown to be formed
this study
revealed
also
constituent.
other
though
floribuda
L-canavanine
Probably
(lo),
by decarboxylation
Our preliminary
(6, species
has been
The present
in Wistaria
is metabolized
of various
amine
7020
guanidinooxypropylamine. naturally
ensifomis
of Leguminosae
seeds
is
to guanidinooxypropylamine
In fact,
canavanine
Canavalia
bean,
species
acid)
of these
decarboxylase for
is possible amines.
decarboxylase
that
(17),
decarboxylase
whether
of agmatine
or not
and large
a common enzyme
Although
of E. co2-i
argine
unknown
amounts
L-canavanine it
does
purified
not from
is serve oat
decarboxylase
a as a
seedlings
guanidinooxypropylamine
or by a specific
is
is in leguminous
plants. Our present in Wistaria
study
seedlings.
has provided This
amine
evidence was first
50
for
the
reported
occurrence in Lathyms
of homoagmatine sativus
Vol.
129,
No.
seedlings
1, 1985
(5).
BIOCHEMICAL
We also
found
other
the hitherto
recognized
amines.
corresponded
to some of
the
these
compounds
are
under
AND
minor
RESEARCH
peaks
corresponded
Our preliminary
10 aliphatic
way in our
ACKNOWLEDGMENTS: We are indebted the kind supply of 10 different
BIOPHYSICAL
which
experiments
pentaamines.
Attempts
COMMUNICATIONS
to none
showed
that
of
they
to characterize
laboratories.
to Dr. K. Samejima pentaamines.
of Josai
University
for
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
U. (1973) Function of Naturally Occurring Polyamines. Academic Bachrach, Press, New York. Smith, T. A. (1975) Phytochemistry 14, 865-890. Kuttan, P., Radhakrishnan, A. N., Spande, T. and Witkop, B. (1971) Biochemistry 10, 361-365. Fujihara, S., Nakashima, T. and Kurogochi, Y. (1982) Biochem. Biophys. Res. Commun. 107, 403-410. Ramakrishna, S. and Adiga, P. R. (1974) Phytochemistry 12, 2691-2695. Bell, E. A. (1958) Biochem. J. 70, 617-619. Kitagawa, M. and Tomiyama, T. (1929) J. Biochem. (Tokyo) 11, 265-271. Nakatu, S., Matugaki, Z., Simada, H., Kasida, T., Motomura, T., Oshima, M. and Sakai, N. (1962) Seikagaku 34, 253-257. Okada, M., Kawashima, S. and Imahori, K. (1979) J. Biochem. (Tokyo) 85, 1235-1243. Makisumi, S. (1961) J. Biochem. (Tokyo) 49, 292-296. Inoue, H. and Mizutani, A. (1973) Anal. Biochem. 56, 408-416. Matsuzaki, S., Hamana, K., Imai, K. and Matsuura, K. (1982) Biochem. Biophys. Res. Commun. 107, 307-313. Hamana, K. and Matsuzaki, S. (1984) J. Biochem. (Tokyo), 95, 1105-1110. Natelson, S. (1985) Experientia 41, 257-259. G. A. and Cohen, W. S. (1983) Plant Physiol. Downum, K. R., Rosenthel, 73, 965-968. Altman, A., Friedman, R. and Levin, N. (1982) Plant Physiol. 69, 876-879. E. A. and Snell, E. E. (1968) 3. Biol. Chem. 243, Blethen, S. L., Boeker, 1671-1677. Smith, T. A. (1979) Phytochemistry 18, 1447-1452.
51
129,
No.
May
31,
1985
1, 1985
BIOCHEMICAL
BIOPHYSICAL
AND
COMMUNICATIONS
RESEARCH
Pages
NATURAL OCCURRENCE OF GUANIDINOOXYPROPYLAMINE IN Wistaria AND THE SWORD BEAN CanavaZia gladiata Koei
Hamana and Shigeru
46-51
fZoribunda
Matsuzaki*
College of Medical Care and Technology and *Department of Physiology, Institute of Endocrinology, Gunma University, Maebashi 371, Japan Received
April
16,
1985
SUMMARY: We found a new guanidinooxyamine in Wistaria ftoribunda seeds and seedlings of the sword bean, Canavalia gladiata. This amine was not only ninhydrin-positive but also gave a positive alkaline nitroprussideferricyanide reaction. It was characterized as y-guanidinooxypropylamine [H2N(NH=)CNHO(CH2)$H21 by comparison with the authentic compound on column and thin-layer chromatograms visualized with specific reagents and by reductive cleavage. Evidence for the occurrence of another unusual guanidino amine, homoagmatine in W. floribunda seeds was also presented. 0 1985 Academic Press, Inc.
Polyamines molecular
have
biosynthesis
have
been found
have
been detected
cadaverine
in higher
plants
have
also
course
have
observed
gave
a positive
corresponded
of
several
plants,
in Lathyrus
unknown
on our column
nitroprusside-ferricyanide to either
leguminous
plants
contain
canavanine
(6-8),
we speculated
it
amino
This
products ation
of these product
several
agmatine
acids.
of L-canavanine.
guanidino would
The present
0006-291X/85 $1.50 Copyr&ht All rights
0 1985 by Academic Press, of reproduction in any form
Inc. reserved.
46
them.
Several
bean,
seedlings
for
(5).
in leguminous
be one of
plants,
chromatograms. though
acids the
compound communication
example,
CanavaZia
it
or homoagmatine. amino
unknown
and spermine
plants,
reaction,
L-canavanine,
of
in sword
sativus
polyamines
1,3-diaminopropane,
number
on polyamines
peaks
of macro-
spermidine
in particular
canavalmine
control
common and "unusual"
while
been found
investigations
in the
Putrescine,
in a limited
(3),
(4) and homoagmatine
Both
(2).
are found
in sandalwood
In the
(1).
in many different
polyamines
homospermidine
to be implicated
and growth
and agmatine
"unusual"
gZadiata
been shown
One of did
we them
not
Since
including
L-
decarboxylation was indeed deals
a decarboxylwith
the
Vol.
129,
No.
1, 1985
BIOCHEMICAL
and characterization
isolation
in Wistaria
AND
BIOPHYSICAL
of a hitherto
RESEARCH
unrecognized
COMMUNICATIONS
guanidinooxyamine
and C. gladiata.
floribunda
MATERIALS AND METHODS Chemicals_L-ArginineeHCl, L-homoarginine.HCl, L-canavanine.H2SOh, putrescine*2HCl, cadaverines2HC1, spermidines3HC1, spermines4HC1, arcaine.H2SOk hirudonine*H2SOh, agmatineeH2S04, octopine, o-methylisourea sulfate and palladium-barium sulfate were purchased from Sigma (St. Louis, MO). 3-Hydroxypropylamine was obtained from Wako Pure Chemicals (Osaka). Ten aliphatic pentaamines which contain aminopropyl and/or aminobutyl moieties were kindly supplied by Dr. K. Samejima of Josai University. Homospermidine and aminobutylhomospermidine (homospermine) were synthesized according to Okada et al The synthesis of homoagmatine (monoamidinocadaverine) and audouine (9). (diamidinocadaverine) was achieved by guanidation of cadaverine with ocadaverinee2HCl was treated with o-methylisoureamethylisourea (5). Briefly, HCl in 2M NaOH at pH 10.5 for 5 days at 25'C. Homoagmatine and audouine were separated from unreacted cadaverine with a column (9 x 120 mm) of ion-exchange resin (Hitachi Custom 2612). The conversion of sulfate forms of L-canavanine, agmatine and o-methylisourea to hydrochloride forms was achieved by passing through a column of Dowex l-X8 before use. Guanidinooxypropylamine was enzymatically synthesized from L-canavanine. L-CanavanineeHCl was incubated with acetone-dried Escherichia coli 7020 (IF0 3544) in 0.2M acetate buffer (pH 5.25) at 3O'C for 1 hr (10). After the termination of the reaction with cold 0.5N HClOt+, the decarboxylation product of L-canavanine was purified by column chromatography as described above.
Canavalia gladiata seeds were fZoribunda seeds were collected in water imbibition for 12 hr, the seeds in the dark on moistened filter paper
Materials
Wistaria After grow
purchased from a local seed dealer. botanical gardens in Maebashi. were germinated and allowed to discs.
Polyaminc analysis Seeds and seedlings were homogenized in 3 volumes of 0.5N HC~OL,. After centrifugation of the homogenates, the supernatants were passed through a column (2.5 x 2 cm) of Dowex-50 W to concentrate polyamines Polyamines were analyzed by highand to eliminate amino acids (11). performance ion-exchange column chromatography as described previously (12) The identity of polyamines was also established with slight modifications. by thin-layer chromatography on cellulose and silica gel (13). Amines on chromatograms were visualized by spraying either ninhydrin, Sakaguchi or alkaline nitroprusside-ferricyanide (pentacyanoferrate) reagent. Large
scale isolation of guanidinooxypropylamine Approximately 1 kg of seeds and CanavaZia seedings were homogenized in 10 1 of 0.5N Hc101+. Polyamines and unknown compounds in HC104 extracts were concentrated by the and then separated by a column of Hitachi Custom use of a Dowex-50 W column, 2612 (13).
Wistaria
RESULTS When analyzed chromatography, were
detected
appeared
the use of our highly
with putrescine,
in the
in seedlings
seed of
spermidine,
Wisttia
of W. floribunda
sensitive
homospermidine, f~orib~nda
(1B)
(Fig.
high-performance spermine 1A).
liquid
and agmatine
Cadaverine
and Canava~ia gZadiata
(li).
Vol.
129,
No.
BIOCHEMICAL
1, 1985
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1 2 ‘7 /3 1
50
5 LL- d 1
’
:‘I
IF-
60
o”o-
ELUTION
Fig.
Besides
polyamines
This
identical
to
peak
such
The retention including
tested
such
eluted
both
authentic systems
prior
not
seeds
norepinephrine, tryptamine,
and Canavalia
not
were (Fig.
any of
seedlings whenever
shown). 48
the
10 penta-
compounds
(diamidinoputrescine),
also lD),
was not
Other
behaved different
[N2-(l-
octopamine,
histamine,
excluded. though
audouine
octopine
cystamine,
and
and homospermine.
normetanephrine,
tyramine,
seedlings
(data
of
(diamidinospermidine),
guanidinooxypropylamine used
to that
spermine
It
thermospermine
arcaine
hirudonine
in C. gladiata
between
and homocaldopentamine.
and N-carbamylputrescine
were
0
to canavalmine.
correspond
as aminopropylcadaverine,
serotonin,
Wistaria
60
(min)
as norspermine,
caldopentamine
carboxyethyl)-L-arginine],
appeared
7x2
peak Xl was found
a little
of Xl did
(diamidinocadaverine),
histamine,
TIME
a prominent
tetraamines
time
amines
dopamine,
40
1. Elution profiles of polyamines found in Wistaria f~or'hndu and Camvalia ghfiata. Polyamines were separated by highperformance ion-exchange chromatography from the seeds (A and C) and seedlings (B and D) of W. fZoribu?da and C. ghdiata, Elution patterns of the polyamines were followed respectively. The numbers above the peaks correspond to: by o-pthalaldehyde. (1) putrescine; (2) cadaverine; (3) spermidine; (4) homospermidine; (5) spermine; (6) canavalmine; (7) agmatine and (8) homoagmatine. Xl and X2, unknown compounds. Dotted lines indicate the curves at 25 times the standard sensitivity.
these
agmatine.
X1 6
2’
8
J I;+4 40
l-methyl-
The same peak
not
in the
seeds.
chromatographically columns
and solvent
as Xl Xl from like
Vol.
129,
No.
1, 1985
BIOCHEMICAL
When pooled were
analyzed
is
A-I
by thin-layer
propylamine which
fractions
(Fig.
3).
specific
homoagmatine,
which
produced.
All
of which
COMMUNICATIONS
contained
Xl
just
like
(Fig.
compounds.
Unlike
to Natelson
show that
(14),
reaction,
agmatine
When reduced
and
in the presence
Xl disappeared
is indeed
of
and new
and 3-hydroxypropylamine Xl
2)
guanidinooxy-
nitroprusside-ferricyanide
to guanidine
findings
RESEARCH
Xl behaved
a positive
according
corresponded these
both
Sakaguchi-positive.
sulfate
compounds
gave
guanidinooxy
Xl was not
palladium-barium
and B-I
BIOPHYSICAL
chromatography, It
for
AND
were
identical
to guanidinooxy-
propylamine. A-II
was identified
techniques
(Fig.
and seed.Lings amount A minor
of this
3).
of
Agmatine
of W. ftoribunda guanidino
peak which
seedlings
as agmatine is
amine
but
the most
(0.6-0.8
not
and thin-layer
abundant
pmoles/g
was detected
corresponded
Wistaria,
by column
polyamine weight),
to homoagmatine
other F
F
VOLUME
(ml)
03 O
only
a small (Fig.
in both
5
minor
peaks
3 Gua 0
0
B
O:H-Agm
0
H-A~Q ACQ Call
andard
/ B-I
A-l A-II
0
andard
6-I
A-I A-II
Fig.
separation of polyamines and Xl from W. fZoribunda 2. Large-scale (A) and C. gZa&iata (B). Polyamines were detected by ninhydrinreagent at 570 nm. Pooled fractions A-I, A-II and B-I were used for further analysis.
Fig.
chromatographic separation of A-I, A-II and B-I 3. Thin-layer on cellulose (A) and silica gel G (B). Arginine (Arg), homoarginine (H-Arg), canavanine (Can), agmatine (Agm), homoagmatine (H-Amg) and guanidinooxypropylamine (Gus) were run Spots on chromatograms were visualized by stimulataneously. spraying alkaline nitroprusside-ferricyanide (open circle) or Sakaguchi (dotted circle) reagent. Solvent systems used were isopropanol-ammonia (7:3, V/V) (A) and chloroform-methanol-ammonia (2:2:1, V.V) (B). 0, origin; F, solvent front. 49
1D).
seeds
A
:Q,. H-Agm .Q.Agm .e. 0,. - GM 0
ELUTION
seeds
seedlings
was observed Several
in both
while
in CanavaZia
in CanavaZia.
chromatographic
and
were
Vol.
129,
No.
found
1, 1985
BIOCHEMICAL
in Canavalia
identified
seeds
from
formula,
the
AND
BIOPHYSICAL
and seedlings.
retention
times
RESEARCH
The unknown as pentaamine
H~N(CH~)~NH(CH~)I+NH(CH~)~NH(CH~)~NH~
peak
of
X2 was tentatively
the
among the
COMMUNICATIONS
constitutional 10 pentaamines
examined,
DISCUSSION L-Canavanine acid
first
(a-amino-y-guanidinooxybutyric
found
in the
to occur
in a number
especially
abundant
(8).
It
these
plants.
jack
of
in the
can be converted
this
by E. coZi
contain
experiments
It
is
detoxicated
metabolite
of interest
to note
not
a decarboxylase amino
acid
amounts
known,
this
for
the
for
content
for
arginine
substrate
but
an inhibitor
(18).
Thus,
it
formed
by arginine
remains
that
is
it
no
amine
occurs
L-canavanine
in these
plants
(15).
of Leguminosae
which
as a normal is merely
an inert
active
increases induced
L-
contains
Possibly
species
in
from
this
gladiata.
is
acid
and Wistaria
normally
has shown
whether
L-canavanine
amine.
in CanavaZia during
or It
is
seedlings.
germination
like
(16).
seeds
contain
enormous it
formation
substrate
of Canavalia
or a biologically
amine
amino
by decarboxylation
other
however,
of guanidinooxypropylamine,
responsible
This
guanidinooxypropylamine
decarboxylases
W. fZoribunda
Since
contain
of L-canavanine that
8).
as by arginase
that
amino
(7) and has been shown
bacterium
and CanavaZia as well
a nonprotein
shown to be formed
this study
revealed
also
constituent.
other
though
floribuda
L-canavanine
Probably
(lo),
by decarboxylation
Our preliminary
(6, species
has been
The present
in Wistaria
is metabolized
of various
amine
7020
guanidinooxypropylamine. naturally
ensifomis
of Leguminosae
seeds
is
to guanidinooxypropylamine
In fact,
canavanine
Canavalia
bean,
species
acid)
of these
decarboxylase for
is possible amines.
decarboxylase
that
(17),
decarboxylase
whether
of agmatine
or not
and large
a common enzyme
Although
of E. co2-i
argine
unknown
amounts
L-canavanine it
does
purified
not from
is serve oat
decarboxylase
a as a
seedlings
guanidinooxypropylamine
or by a specific
is
is in leguminous
plants. Our present in Wistaria
study
seedlings.
has provided This
amine
evidence was first
50
for
the
reported
occurrence in Lathyms
of homoagmatine sativus
Vol.
129,
No.
seedlings
1, 1985
(5).
BIOCHEMICAL
We also
found
other
the hitherto
recognized
amines.
corresponded
to some of
the
these
compounds
are
under
AND
minor
RESEARCH
peaks
corresponded
Our preliminary
10 aliphatic
way in our
ACKNOWLEDGMENTS: We are indebted the kind supply of 10 different
BIOPHYSICAL
which
experiments
pentaamines.
Attempts
COMMUNICATIONS
to none
showed
that
of
they
to characterize
laboratories.
to Dr. K. Samejima pentaamines.
of Josai
University
for
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
U. (1973) Function of Naturally Occurring Polyamines. Academic Bachrach, Press, New York. Smith, T. A. (1975) Phytochemistry 14, 865-890. Kuttan, P., Radhakrishnan, A. N., Spande, T. and Witkop, B. (1971) Biochemistry 10, 361-365. Fujihara, S., Nakashima, T. and Kurogochi, Y. (1982) Biochem. Biophys. Res. Commun. 107, 403-410. Ramakrishna, S. and Adiga, P. R. (1974) Phytochemistry 12, 2691-2695. Bell, E. A. (1958) Biochem. J. 70, 617-619. Kitagawa, M. and Tomiyama, T. (1929) J. Biochem. (Tokyo) 11, 265-271. Nakatu, S., Matugaki, Z., Simada, H., Kasida, T., Motomura, T., Oshima, M. and Sakai, N. (1962) Seikagaku 34, 253-257. Okada, M., Kawashima, S. and Imahori, K. (1979) J. Biochem. (Tokyo) 85, 1235-1243. Makisumi, S. (1961) J. Biochem. (Tokyo) 49, 292-296. Inoue, H. and Mizutani, A. (1973) Anal. Biochem. 56, 408-416. Matsuzaki, S., Hamana, K., Imai, K. and Matsuura, K. (1982) Biochem. Biophys. Res. Commun. 107, 307-313. Hamana, K. and Matsuzaki, S. (1984) J. Biochem. (Tokyo), 95, 1105-1110. Natelson, S. (1985) Experientia 41, 257-259. G. A. and Cohen, W. S. (1983) Plant Physiol. Downum, K. R., Rosenthel, 73, 965-968. Altman, A., Friedman, R. and Levin, N. (1982) Plant Physiol. 69, 876-879. E. A. and Snell, E. E. (1968) 3. Biol. Chem. 243, Blethen, S. L., Boeker, 1671-1677. Smith, T. A. (1979) Phytochemistry 18, 1447-1452.
51