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Erymelanthine, a new type of erythrina alkaloid containing a 16-azaerythrinane skeleton
Tetrahedron Letters,Vol.24,No.46,pp Printed in Great Britain
5@67-5070,1983
A NEW TYPE OF ERYTHRINA
ERYMELANTHINE,
16-AZAERYTHRINANE
Ermias Institut
Dagne
fiir Organische
Gerhard-Domagk-Stral3e
Summary: represents
the first member
a 16-azaerythrinane
As part we have
isolated
279
Kenya
1380, nm
1340,
dd, J=12+5 3.55
Hz, H-4
Hz, H-14),
1 differs
3.75
ever,
occurs
two singlets
312
(12); IR
(m, H-10
species with
to occur
from EthiopiaA
erysovine
in southern
properties:
!M+, C,8H20N203,
CDC13):
(CHC13): UV
6 1.91
eq
(m, H-IO,,),
3.96
(2) Ethiopia,
2950,
1720,
(361, 281
(EtOH) Amax(
(dd, J=10+2
1590,
270
4.00
3.31
1430,
2.51
(br.
(s, 0CH3),
(m, H-31,
Hz, H-21,
(loo),
(3000), 230
Hz, H-4,,),
(m, 2H, H-11),
[ali
160-161°C;
297
(s, C02CH3),
6.61
mp
79%),
(dd, J=l2+10
1, 3.10
alkaloids
of a second
attached
in the spectrum
atom.
4
5.76
8.00
(d, J=l
so far from Erythrina Its MS exhibits
of the 1,6-diene
series5,
to rings A, B and C correspond
of erysovine
in the aromatic
region.
having
shifts
chemical
isolated
nitrogen
for an alkaloid
for the protons
observed
containing
(br. d, J=l Hz, H-17).
pattern
those
melanacantha,
alkaloid
(l) along
and spectral
930, 820/cm;
from all the other
fragmentation
1, FRG
3
(d, J=lO Hz, H-l),
ties by the presence
signals
1100,
2.77
eg)'
6.10
8.50
Bonn
a tree known
193
49),
(400 MHz,
(m, 2H, H-8),
(br. s, H-7),
der Universitat
of Erythrina
erymelanthine
MS: m/z
1230,
'H NMR
(8000);
1, D-5300
and Tanzania.
(C15H13N2,
1290,
und Biochemie
on the alkaloids
physical
(c = 0.11, MeOH); (28), 221
Steglich*
of a new type of erythrina
of E. melanacantha,
1 has the following +87O
A
SKELETON'
from the seeds of Erythrina
a new alkaloid
northern
CONTAINING
skeleton.
of our studies
from the seeds Somalia,
isolated
Erymelanthine,
ALKALOID
and Wolfgang Chemie
OO40-4039/83 $3.00 + .OO 01983 Pergamon Press Ltd.
Whereas between
5067
(2). A dramatic in 2 and other
spe-
the normal and the 'H NMR closely
difference, erythrina
to how-
alkaloids
6.5 and 7.0 ppm may be observed
506 8
for H-14
and H-17,
(6 8.00 and 8.50, pyridine
unit
positions.
the corresponding respectively).
signals
This may be explained
in ring D, substituted
From
the coupling
by a carbomethoxy
constant
ring.
at 6 8.50 is broadened
by benzylic
be shown
experiments.
as could
thrinane
derivative
occupy
by decoupling
and is in full accord
at unusually
group
the aromatic
coupling This
of a
at one of the a-
a- and B'-positions
with
low field
by the presence
Hz between
that
atC(11)
protons
of J=l
can be concluded The signal
these
of 1 appear
signals
it
of the pyridine with
the protons
excludes
a 15-ery-
a 16-azaerythrinane
structure
B
for erymelanthine.
.
1
Structure melanthine
2 is further
with
C(1)
to C(11)
both
alkaloids.
Table
Carbon 1
2 3 4 5 6 7 8 10 11
2
those
supported
recently
by comparison
published
in rings A, B and C exhibit The chemical
1. I3 C NMR data
shifts
of the
nearly
identical
6
124.9
131.7 75.4 40.4 66.5 145.7 123.4 56.1 42.3 21.3
d d d t s
in the pyridine
shifts
for for
ring of 1
(2) in CDCl3
1 =
c
J=l56 Hz 154 137 126 -
: t t t
a) Sharp singlet in H-coupled d) Qa, 3JcH= 4.5 Hz.
chemical
(1) and erysovine
1 =
No.
NMR data of ery-
for erysovine 6 (table 1). Signals
of the carbons
of erymelanthine
"C
163 134 132 125
1%mm
125.6 132.0 75.9 41.4 66.8 142.4 122.4 56.8 44.0 24.2
spsctrum-I
12 13 14 15 17 CO,CH, CO,CH, OCH,
134.0 140.4 122.1 149.6 150.4 165.9 52.8 56.5
s
-
:a
158 171 141 135
itI s
b) Dt, 3JCH= 3 Hz; c) d,
3
125.2 131.5 111.0 145.6 112.5 55.7
JCH= 11 Hz;
5069
are in close 6 149.6 and ring occur split
agreement
150.4, which as a singlet
into triplets
further
support
by
C NMR
Jj
I
spectrum
4ax
12 Hz) for these
region
adds
vage
1
coupling
gives
respectively, with
to two signals
support
biosynthetic between
to this
C(16)
1 must
and C(17)
of E. melanacantha
erythrina diol
have
alkaloids
proposed
melanthine
seems
The possibility
to advocate that
ammonia
10
work-up
with
acantha
by a procedure
2 with lends
two pathwpys
a is an artefact was excluded
at 1720/cm. J3
constants
I
4es
(5 and
stereochemistry.
in the 220-260
involve
nm
extradiol
by formation
ammonia.
clea-
of the pyridine
The co-occurrence
of
to this hypothesis.
for the conversion which
cleavage.
involve The
of aromatic either
isolation
intraof ery-
pathway. formed
by isolating
ammonia
may
support
[C(16)-C(17)]
the latter
omitting
165.9 in the
assignment.
followed
into a- and B-erythroidines,
[C-(15)-C(16)I or extradiol
lends
at C(15).
of an IR band
the same
at
further
This
at 6 52.8 and
possess
to erymelanthine
l and 2 in the seeds
9
group
from the coupling
stereochemical
of the intermediate
et al.
being
at C(11).
of i and 2 particularly
route
The signals
a Since 1 and 2 show the same values
ring by condensation
Barton
the protons
7
of the pyridine
the latter
for the presence
constants,
of the CD spectra
systems.
of the carbomethoxy
rise
spectrum.
coupling
of erysovine
of similar
at C-3 may be deduced
H NMR
further
A plausible
and doublet, 3JCH
data
to the a- and a '-positions
and is responsible
in the
The similarity
correspond
group
The stereochemistry and
literature
for the positioning
The carbomethoxy 13
with
during
from
intermediate
1 from the seeds the extraction.
2 during of E. -- melan-
5070
Acknowledgment: Alexander
von Humboldt-Stiftung.
availablethrough
References
a grant
The Bruker
from the Deutsche
to Professor
E. Dagne
acknowledges
a fellowship
from the
WM 400 NMR spectrometer
was made
Forschungsgemeinschaft.
and Notes
1) Dedicated 2)
E. D. gratefully
Sir Derek
and W. Steglich,
Barton
on the occasion
Phytochemistry,
of his
65
th
birthday.
in press.
3) The seeds
of -* E melanacantha were collected in April 1982 in south Ethiopia from trees growing in the province of Borana, 58 km west of Negelle town at
an altitude Tadesse
of 980 m above
of the Biology
description
of this plant
E. Milne-Redhead Crown
Agents,
4) Recently atom
sea level.
Department,
an erythrina
folius:
M. Juichi, (1981).
555
5) R.B. Boar 6) A.S.
alkaloid,
R.M.
(Eds.), Flora --
erythramide,
group
Y. Fujitani,
and D.A. Widdowson,
Chawla,
was
identified
University. Polhill
by Ato Mesfin
For a botanical and B. Verdcourt
of Tropical
in
East Africa, -____
1971, p. 552.
in form of a carboxamino
16,
Ababa
see: J.B. Gillet,
and R.M. Polhill
London
The plant
Addis
T. Shingu
J. Chem. - --
S. Chunchatprasert
possessing
has been
an extra
B, 1970,
Jackson,
nitrogen
from Cocculus
and H. Furukawa,
Sot.
and A.H.
isolated
lauri-
Heterocycles,
1591.
Org. s.
Reson.
11,
39
(1983). 7) E. Breitmaier
and G. Bauer,
13
C-NMR-Spektroskopie,
G. Thieme,
Stuttgart
1977,
p. 367. 8) S.F. Dyke and S.N. Quessy The Alkaloids, 9) D.H.R.
a, IO)
Vol.
Barton,
R.D. Bracho,
C.J.
Manske
and R.G.A.
Rodrigo
Fress,
New York
Potter
and D.A. Widdowson,
(Eds.),
1981, p. 11. J.C.S. ---
Perkin
2278.
Cf. the formation H.-G.
in R.H.F.
17, Academic
Floss,
(Received
of gentianine
U. Mothes
in Germany
from gentiopicroside
and A. Rettig,
1 September
1983)
2. Naturforsch.
or swertiamarine: 19 b, 1106 --
(1964).
I,
5@67-5070,1983
A NEW TYPE OF ERYTHRINA
ERYMELANTHINE,
16-AZAERYTHRINANE
Ermias Institut
Dagne
fiir Organische
Gerhard-Domagk-Stral3e
Summary: represents
the first member
a 16-azaerythrinane
As part we have
isolated
279
Kenya
1380, nm
1340,
dd, J=12+5 3.55
Hz, H-4
Hz, H-14),
1 differs
3.75
ever,
occurs
two singlets
312
(12); IR
(m, H-10
species with
to occur
from EthiopiaA
erysovine
in southern
properties:
!M+, C,8H20N203,
CDC13):
(CHC13): UV
6 1.91
eq
(m, H-IO,,),
3.96
(2) Ethiopia,
2950,
1720,
(361, 281
(EtOH) Amax(
(dd, J=10+2
1590,
270
4.00
3.31
1430,
2.51
(br.
(s, 0CH3),
(m, H-31,
Hz, H-21,
(loo),
(3000), 230
Hz, H-4,,),
(m, 2H, H-11),
[ali
160-161°C;
297
(s, C02CH3),
6.61
mp
79%),
(dd, J=l2+10
1, 3.10
alkaloids
of a second
attached
in the spectrum
atom.
4
5.76
8.00
(d, J=l
so far from Erythrina Its MS exhibits
of the 1,6-diene
series5,
to rings A, B and C correspond
of erysovine
in the aromatic
region.
having
shifts
chemical
isolated
nitrogen
for an alkaloid
for the protons
observed
containing
(br. d, J=l Hz, H-17).
pattern
those
melanacantha,
alkaloid
(l) along
and spectral
930, 820/cm;
from all the other
fragmentation
1, FRG
3
(d, J=lO Hz, H-l),
ties by the presence
signals
1100,
2.77
eg)'
6.10
8.50
Bonn
a tree known
193
49),
(400 MHz,
(m, 2H, H-8),
(br. s, H-7),
der Universitat
of Erythrina
erymelanthine
MS: m/z
1230,
'H NMR
(8000);
1, D-5300
and Tanzania.
(C15H13N2,
1290,
und Biochemie
on the alkaloids
physical
(c = 0.11, MeOH); (28), 221
Steglich*
of a new type of erythrina
of E. melanacantha,
1 has the following +87O
A
SKELETON'
from the seeds of Erythrina
a new alkaloid
northern
CONTAINING
skeleton.
of our studies
from the seeds Somalia,
isolated
Erymelanthine,
ALKALOID
and Wolfgang Chemie
OO40-4039/83 $3.00 + .OO 01983 Pergamon Press Ltd.
Whereas between
5067
(2). A dramatic in 2 and other
spe-
the normal and the 'H NMR closely
difference, erythrina
to how-
alkaloids
6.5 and 7.0 ppm may be observed
506 8
for H-14
and H-17,
(6 8.00 and 8.50, pyridine
unit
positions.
the corresponding respectively).
signals
This may be explained
in ring D, substituted
From
the coupling
by a carbomethoxy
constant
ring.
at 6 8.50 is broadened
by benzylic
be shown
experiments.
as could
thrinane
derivative
occupy
by decoupling
and is in full accord
at unusually
group
the aromatic
coupling This
of a
at one of the a-
a- and B'-positions
with
low field
by the presence
Hz between
that
atC(11)
protons
of J=l
can be concluded The signal
these
of 1 appear
signals
it
of the pyridine with
the protons
excludes
a 15-ery-
a 16-azaerythrinane
structure
B
for erymelanthine.
.
1
Structure melanthine
2 is further
with
C(1)
to C(11)
both
alkaloids.
Table
Carbon 1
2 3 4 5 6 7 8 10 11
2
those
supported
recently
by comparison
published
in rings A, B and C exhibit The chemical
1. I3 C NMR data
shifts
of the
nearly
identical
6
124.9
131.7 75.4 40.4 66.5 145.7 123.4 56.1 42.3 21.3
d d d t s
in the pyridine
shifts
for for
ring of 1
(2) in CDCl3
1 =
c
J=l56 Hz 154 137 126 -
: t t t
a) Sharp singlet in H-coupled d) Qa, 3JcH= 4.5 Hz.
chemical
(1) and erysovine
1 =
No.
NMR data of ery-
for erysovine 6 (table 1). Signals
of the carbons
of erymelanthine
"C
163 134 132 125
1%mm
125.6 132.0 75.9 41.4 66.8 142.4 122.4 56.8 44.0 24.2
spsctrum-I
12 13 14 15 17 CO,CH, CO,CH, OCH,
134.0 140.4 122.1 149.6 150.4 165.9 52.8 56.5
s
-
:a
158 171 141 135
itI s
b) Dt, 3JCH= 3 Hz; c) d,
3
125.2 131.5 111.0 145.6 112.5 55.7
JCH= 11 Hz;
5069
are in close 6 149.6 and ring occur split
agreement
150.4, which as a singlet
into triplets
further
support
by
C NMR
Jj
I
spectrum
4ax
12 Hz) for these
region
adds
vage
1
coupling
gives
respectively, with
to two signals
support
biosynthetic between
to this
C(16)
1 must
and C(17)
of E. melanacantha
erythrina diol
have
alkaloids
proposed
melanthine
seems
The possibility
to advocate that
ammonia
10
work-up
with
acantha
by a procedure
2 with lends
two pathwpys
a is an artefact was excluded
at 1720/cm. J3
constants
I
4es
(5 and
stereochemistry.
in the 220-260
involve
nm
extradiol
by formation
ammonia.
clea-
of the pyridine
The co-occurrence
of
to this hypothesis.
for the conversion which
cleavage.
involve The
of aromatic either
isolation
intraof ery-
pathway. formed
by isolating
ammonia
may
support
[C(16)-C(17)]
the latter
omitting
165.9 in the
assignment.
followed
into a- and B-erythroidines,
[C-(15)-C(16)I or extradiol
lends
at C(15).
of an IR band
the same
at
further
This
at 6 52.8 and
possess
to erymelanthine
l and 2 in the seeds
9
group
from the coupling
stereochemical
of the intermediate
et al.
being
at C(11).
of i and 2 particularly
route
The signals
a Since 1 and 2 show the same values
ring by condensation
Barton
the protons
7
of the pyridine
the latter
for the presence
constants,
of the CD spectra
systems.
of the carbomethoxy
rise
spectrum.
coupling
of erysovine
of similar
at C-3 may be deduced
H NMR
further
A plausible
and doublet, 3JCH
data
to the a- and a '-positions
and is responsible
in the
The similarity
correspond
group
The stereochemistry and
literature
for the positioning
The carbomethoxy 13
with
during
from
intermediate
1 from the seeds the extraction.
2 during of E. -- melan-
5070
Acknowledgment: Alexander
von Humboldt-Stiftung.
availablethrough
References
a grant
The Bruker
from the Deutsche
to Professor
E. Dagne
acknowledges
a fellowship
from the
WM 400 NMR spectrometer
was made
Forschungsgemeinschaft.
and Notes
1) Dedicated 2)
E. D. gratefully
Sir Derek
and W. Steglich,
Barton
on the occasion
Phytochemistry,
of his
65
th
birthday.
in press.
3) The seeds
of -* E melanacantha were collected in April 1982 in south Ethiopia from trees growing in the province of Borana, 58 km west of Negelle town at
an altitude Tadesse
of 980 m above
of the Biology
description
of this plant
E. Milne-Redhead Crown
Agents,
4) Recently atom
sea level.
Department,
an erythrina
folius:
M. Juichi, (1981).
555
5) R.B. Boar 6) A.S.
alkaloid,
R.M.
(Eds.), Flora --
erythramide,
group
Y. Fujitani,
and D.A. Widdowson,
Chawla,
was
identified
University. Polhill
by Ato Mesfin
For a botanical and B. Verdcourt
of Tropical
in
East Africa, -____
1971, p. 552.
in form of a carboxamino
16,
Ababa
see: J.B. Gillet,
and R.M. Polhill
London
The plant
Addis
T. Shingu
J. Chem. - --
S. Chunchatprasert
possessing
has been
an extra
B, 1970,
Jackson,
nitrogen
from Cocculus
and H. Furukawa,
Sot.
and A.H.
isolated
lauri-
Heterocycles,
1591.
Org. s.
Reson.
11,
39
(1983). 7) E. Breitmaier
and G. Bauer,
13
C-NMR-Spektroskopie,
G. Thieme,
Stuttgart
1977,
p. 367. 8) S.F. Dyke and S.N. Quessy The Alkaloids, 9) D.H.R.
a, IO)
Vol.
Barton,
R.D. Bracho,
C.J.
Manske
and R.G.A.
Rodrigo
Fress,
New York
Potter
and D.A. Widdowson,
(Eds.),
1981, p. 11. J.C.S. ---
Perkin
2278.
Cf. the formation H.-G.
in R.H.F.
17, Academic
Floss,
(Received
of gentianine
U. Mothes
in Germany
from gentiopicroside
and A. Rettig,
1 September
1983)
2. Naturforsch.
or swertiamarine: 19 b, 1106 --
(1964).
I,