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Five ingol esters and a 17-hydroxyingenol ester from the latex of Euphorbia Kamerunica . Assignment of esters using 13C.N.M.R. methods.
Tetrahedron Letters,Vo1.25,No.34,pp Printed in Great Britain
3773-3776,1984
FIVE INGOL ESTERS AND A 17-HYDROXYINGENOL EUPHORBIA
KAMERUNICA.
ASSIGNMENT
0040-4039/84 $3.00 + .oo 01984 Perqamon Press Ltd.
ESTER FROM THE LATEX OF
OF ESTERS USING
13C N.M.R. METHODS.
By Joseph D. Connolly*, Christopher 0. Fakunle+ and David S. Rycroft Department of Chemistry, University of Glasgow, Glasgow G12 8QQ. Scotland. Summary The structures of five ingol esters and a 17-hydroxyingenol ester from the latex of Euphorbia kamerunica have been determined. The 13C n.m.r. spectra of these compounds have been assigned using 2D 6C/6H correlations. The specific positions of attachment of esters have been assigned unambiguously using 13C n.m.r. methods including 2D long range 6c/6H correlations. The diterpenoids
of the Euphorbiaceae
have been a source of great interest
because of their biological
activity.'
nucleus
and it is difficult
to obtain pure compounds
various
positions
of the diterpenoid However,
solve the ester problem. cation
can occur during partial
These compounds
nucleus.
chemists
and to decide which ester is attached
In the past partial
while it has been reported'
hydrolysis
to organic
often occur as mixed esters of the same
this has not always
hydrolysis
to the
has been used to
that intramolecular
transesterifi-
been taken into account 3 in the
structural assignments. We have been able to circumvent the difficulties of transesterification 13 13 using C n.m.r. methods. Surprisingly there are few reports of C chemical shift data for 13 these compounds in the literature.' C chemWe now report the structural elucidation and the ical shifts of five ingol esters and a 17-hydroxyingenol Multiple
ester
preparative
(l), (2), (7), (lO),and
(16) [as its 3-deacetyl
(17) from the latex of Euphorbia
t.1.c. of the ether extract
third band in order of increasing
derivative
(15)1
kamerunica.
of the latex afforded
several
The
bands.
gave a crystalline mixture of compounds (1) and (2) in 13 C n.m.r. spectra (Tables 1 and 2) by comparison the ratio 3:2. It was evident from the 'H and 4 that with ingol tetra-acetate (31, whose relative stereochemistry has recently been reassigned, both compounds
contain
there are resonances cated
yielded
parative
t.1.c.
an ingol nucleus
for a tiglate
that the methoxyl
mixture
polarity
group
in (1) and a benzoate
is attached
the corresponding
(6).
to C-8 in both
3-deacetyl
derivatives
Thus the tiglate
Further
in (1) and
partial
and a methoxyl in (2). (1) and
group.
The chemical Partial
(2).
In addition shift of H-8 indihydrolysis
of the
(5) which were separated by pre13 C shifts, relative to (1) and the expected
In both cases C-2 and C-3 exhibited
(21, for removal of the 3-acetate. acetate
with two acetates
(4) and
hydrolysis
(4) must be attached
of
(4) gave 8-O-methyl-ingol-12-
to C-7.
The benzoate
group of
(5), and hence of (2) was shown to be attached to C-7 by selective decoupling experiments in the 13 C n.m.r. spectrum. Irradiation of H-7 (6 5.59) resulted in removal of a coupling 3 (3J = 3 Hz) to the benzoyl carbonyl group which then appeared as a triplet, J (H-ortho) = 3 Hz.
fully coupled
Similarly
for the acetate
(3J) and left a quartet
carbonyl
carbon
(2J = 7 Hz).
8-g-methyl-ingol-3,12-diacetate-7-tiglate
irradiation
of H-12
Thus the structures
(6 4.87) removed
of (1) and
a 4 Hz coupling
(2) are established
and 8-g-methyl-ingol-3,12-diacetate-7-benzoate
as respect-
ively. The third ingol ester, less polar +SeniOr
Commonwealth
Universities
than
(1) and
(2). was assigned
Fellow on leave from the University
3773
structure
(7), ingol-
of Ife, Nigeria.
3174
3,8,12-triacetate-7-tiglate, presence
of a 7-tiglate
on the basis of its spectroscopic
was established
based on long range couplings, carbonyl
group.
in particular
A more detailed
properties
by 2D &C/&H correlation
(Tables 1 and 2).
using polarisation
the three bond coupling
between
The
transfer
H-7 and the tiglate
of the use of the above methods for determining 5 will appear elsewhere. Partial hydrolysis of (7) yielded 6 inter alia ingol-12-acetate-8-tiglate (8) which, on acetylation, afforded (9). isomeric with the -sites of specific
natural
ester
hydroxyl
(7).
groups
structures recently
This result confirms
based on such evidence.
described3
these compounds
(9), 8-angelate
The least polar
The presence
the 3-deacetyl aration
of the tiglate
of a 7-angelate
(11) was obtained.
derivative
(see below) and also afforded
(13) and the 12-acetate The 3-deacetyl
(14).
derivative
by partial
hydrolysis
of
(11) enabled
(10) as a minor contaminant,
of (12) gave the natural product
method described
First
the sep-
as its 3-deacetyl
(12). the 12-acetate-8-angel-
on the basis of its spectroscopic
tion of the 2D long range hc/6H correlation
proper-
in two stages.
of the fifth ingol ester was readily assigned
8-g-methyl-ingol-12-acetate-7-angelate,
des(7).
with those of the tiglate
hydrolysis
the 12-acetate-7-angelate
Acetylation
to those of
(lo), has spectroscopic
resonances,
Further partial
of the fifth ingol ester, which accompanied
data for a compound
similarity
for
data3
at C-12.
apart from the angelate in (10) was proved
from E. kamerunica
of the published
The published
also bear remarkable
the C-7 and C-8 of assigning
of ingol-3,7,12-triacetate
Comparison
ingol-3,8,12-triacetate-7-angelate
identical,
derivative
(7).
this suggestion.
for the location
compound,
between
the hazards
and 8-benzoate
'I-esters, including
with our data supports
was presented
that ester transfer and illustrates
Thus it seems likely that the compounds
as the 8-tiglate
ties which are virtually
ate
hydrolysis
as ingol-3,7,8-triacetate-12-tiglate
No evidence
(7).
the report'
can occur during partial
are, in fact, the corresponding
cribed
description
ester attachment
(10).
structure
properties.
above confirmed
(15), Applica-
the presence
of the
7-angelate. Thus the natural ingol ester is 8-c-methyl-ingol-3,12-diacetate-7-angelate (16). 13 The C chemical shifts of these ingol esters were largely assigned using 2D 6c/6H correlations.
The problem
sidering
their long range proton couplings.
is a sharp quartet
of the assignment
show that the 6 73.4 resonance
the 6 71.1 signal is coupled
structure
data for ingol tetra-acetate
the torsion
expected.
6 73.4 is assigned
The most polar compound
has three acetates on C-15.
approximately function
and an angelate
The l3C resonances
138-9',
attached
of the geminal
is C-17
in (17) resonates (Table 3).
[rSH4.98
(H-3), 5.37
Using
the crystal C-15, C-4, C-5,
near zero are
to an ingenol methyls
(H-5), 4.07 and 4.16
(H-8), 0.89
nucleus
bearing
(H-13), 1.11
to cause an upfield
series appear
Introduction
(ABq,
(H-14)1,
an acyloxymethyl
in the ingol and ingenol
and 29 ppm for the a-methyl.
to either methyl would be expected
acyloxymethyl
to H-5, H-2 and H-18
to H-la.
for which =JCH values
(ABq, J 12.2 Hz, 2H-20), 4.32
16 ppm for the S-methyl
Since the only t-methyl
is coupled
to C-4 and 6 71.1 to C-15.
(171, m.p.
J 11.7 Hz. 2H-17), 4.11 and 4.55
of
angles C-4, C-15, C-l,H-laand
to be -105.2O and 111.6O respectively,
by con-
(7) the signal at 6 73.4 C of triplets (J 2, 7 Hz). The 2D
spectrum
to H-2, H-18 and more weakly
H-5 are inferred Hence
carbons , C-4 and C-15, was solved
In the coupled
(J 7 Hz) and that at 6C 71.1 a broad doublet
long range 6c/6H correlations whereas
of the epoxide
group at
of an acyloxy
shift of the remaining
methyl.
at 24.1 ppm it must be a, i.e. C-16, and hence the
377s
The position
of the angelate
of attachment
afforded
the 17-acetate-3-angelate
angelate
(19) [gH 4.39
(S, H-S),
of a 17-angelate of
(18) yielded
[6 4.95
C-3 are at lower
(s, H-S)]
in (17) since ester transfer
(H-3), 5.40
that the natural
3.65
compound
whereas
Formation
between
field than normal,
presumably
ester
(17).
Similarly
at 172.4 ppm.
hydrolysis
of
(18), followed
'H n.m.r.
(H-13), 1.15
16-hydroxyingenol
spectrum
tetra-acetate.
that the literature Table
(3)
(19) afforded
Acetylation
the isomer
(ZH-2011.
3.69
(21)
It follows,
therefore,
one acetate
[6.06 (H-l) , 4.93
1.
hydroxyl
is more deshielded
of the 20-angelate
derivatives
afforded (H-3), 5.37
(H-5), 6.21
for a compound
The 'H spectra of the isomers were predicted' 8. is identical to (22).
tetra-
(H-7), 4.37
(ABq, J 11.9 Hz, 2H-17), 4.57 and 4.14 to that published'
(19) and
hydrolysis.
17-hydroxyingenol
13C Chemical
Shifts of
Ingol
Derivatives
(ABq,
described to differ
as and
(CDC13)
(7)
(9)
(1)
(2)
(4)
(5)
1
31.3
31.5
31.7
31.5
31.4
31.5
31.5
31.8
31.7
2 3 4 5 6 7 8 9 10
29.3
29.5
31.9
29.5
29.3
29.4
29.4
31.9
31.9
76.2
76.5
76.1
76.6
76.3
76.8
76.9
76.1
75.9
73.3
73.4
75.7
73.4
73.4
73.5
74.4
75.7
75.7
117.0
117.0
117.5
116.8
116.8
116.7
117.1
117.3
117.6
139.5
139.8
139.5
139.9
139.9
140.0
139.7
139.5
139.2
76.8
76.6
73.6
76.7
77.0
74.0
74.6
73.7
74.3
71.2
71.5
78.8
71.7
71.2
78.8
78.8
78.9
78.9
24.7
25.1
27.2
25.0
25.0
27.2
27.2
27.1
27.1
19.3
19.3
19.2
19.3
19.3
19.3
19.4
19.2
19.2
11
30.6
30.7
30.5
30.7
30.8
30.5
30.5
30.4
30.5
12
70.6
70.6
71.0
70.6
70.8
71.0
71.0
70.8
71.0
13
42.9
43.1
42.9
43.1
43.0
43.0
43.1
43.0
43.0
14
207.4
207.6
207.8
207.6
207.6
207.6
207.6
207.8
207.8
15
71.0
71.1
72.8
71.1
71.1
71.1
71.2
72.8
72.8
16
16.9
16.9
16.1
16.9
17.0
16.9
16.9
16.1
16.1
17
17.3
17.5
17.8
17.5
17.4
17.7
17.8
17.8
17.8
18
29.0
29.1
29.2
29.2
29.2
29.3
29.3
29.3
29.3
19
16.0
16.1
16.5
16.1
16.1
16.5
16.5
16.5
16.5
20
13.3
13.4
13.2
13.3
13.4
13.3
13.3
13.2
13.2
Table
2. 9
1 H Chemical
Shifts of Ingol Derivatives
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
(11)
(12)
(13)
(14)
(15)
3
5.20
5.13
4.24 5.42 2.90
4.19 5.59 2.98
4.37 4.34 2.85
5.22 5.21 4.58
4.31 4.26 4.55
5.35 5.12 4.64
5.23 5.20 4.58
4.25 5.29 4.59
4.25 5.23 3.55
4.33
4.30
4.25
4.28 4.62
3.36
2.90
4.85
4.87
4.85
4.87
4.86
4.88
4.86
4.86
4.87
4.87
4.82
4.85
7
5.33
5.54
8
2.91
2.99
5.29 5.03 4.52
12
4.85
4.90
4.81
-4.13
to
than
compound
(15)
(10)
carbonyl
can occur during partial
by acetylation,
similarity
to the tertiary
is 167.3 ppm in (21) and moves downfield
The formation
(H-14), 4.22 and 4.11
J 12.7 Hz, 2H-20)] bears a striking
we suspect
of
as a result of H-bonding
carbonyl
(20) shows that, as in the ingol series , ester transfer
(22) whose
(s, H-3),
the possibility
The
usual in (21) and resonates
(H-8), 0.93
(20) [6D 4.41
(20) excludes
C-17 and C-20 is impossible.
acetylation
which
the 17-acetate-20-
(17), the most irritant of those isolated, is 17-acetoxyingenol-5,2013 C chemical shifts of the carbonyl group of the ester attached to
ester
168.8 ppm in the natural
acetate
of
hydrolysis
(s, H-5)1,
and the 20-angelate
(2H-17) , 4.31 and 4.55
(H-S), 4.13 and 4.24
Thus the l3C shift of the angelate
Complete
by partial
(s, 2H-20), 4.04
(ABq, J 11.7 Hz, 2~-17)].
the natural
diacetate-3-angelate.
group.
(s, H-3),
3.74 and 3.84
was determined
(18) [6H 4.13
5.47
3776
Table (17)
(22)
131.5 133.7 81.5 85.7 74.6
131.8 133.6
13 C Chemical
3.
82.0 85.7 74.6
Shifts of Ingenol Derivatives (17)
(22)
131.0
11 12
30.5 30.6
43.1 204.6 71.8
13 14 15
23.1 23.9 27.5
38.6 30.8 23.2 24.0 27.7
(17)
(22)
6
135.9
135.8
7
130.8
I3 9 10
43.1 204.6 71.9
(17) and
(22)
16 17 18 19 20
V7)
(22)
24.1 65.6 16.5 15.3 65.6
24.2 65.7 16.6 15.4 65.7
R4
16
19
OR” (1) 12) (3) (4) (5) (6! (7) (81 (9) (10) (11) (12) (131 (14) (15) (16)
R’
R2
R3
R4
AC AC AC
tig PhCO AC tiq PhCO H tig H AC ang ang ang H H
Me Me AC Me Me Me AC tig tiq AC AC H ang 9 Me Me
AC AC AC AC AC AC AC AC AC AC AC AC AC AC AC AC
H H H
AC H
AC AC H H H H H AC
ang ang
(17) (18) (19) (20) (21) (22)
R1
R2 R3
R4
ang w
AC H H H AC AC
AC AC AC H AC AC
H
H AC AC
AC H ang ang ang AC
References 1.
F.J. Evans and S.E. Taylor,
Progress
in the Chem. of Org. Nat. Prod.,'1983,
2.
K.A. Abo and F.J. Evans, J. Nat. Prod.,
1982, 45, 365.
3.
K.A. Abo and F.J. Evans, Planta Medica,
1981, 2,
J.D. Connolly,
C.O. Fakunle
and D.S. Rycroft,
J. Chem. Res., submitted.
5.
J.D. Connolly,
C.O. Fakunle
and D.S. Rycroft,
J. Chem. Res., submitted.
6.
H.J. Opferkuch
and E. Hecker,
7.
K.A. Abo and F.J. Evans, Phytochemistry,
8.
H.J. Opferkuch
9.
Only chemical
and E. Hecker,
Tetrahedron
shift data are given.
as reported
for the parent
(Received
in UK 4 June
1981, g, Letters,
Multiplicities
compounds. 1984)
Letters,
l-99.
392.
4.
Tetrahedron
44,
1973, 3611. 2535. 1974, 261. and coupling
constants
are essentially
3773-3776,1984
FIVE INGOL ESTERS AND A 17-HYDROXYINGENOL EUPHORBIA
KAMERUNICA.
ASSIGNMENT
0040-4039/84 $3.00 + .oo 01984 Perqamon Press Ltd.
ESTER FROM THE LATEX OF
OF ESTERS USING
13C N.M.R. METHODS.
By Joseph D. Connolly*, Christopher 0. Fakunle+ and David S. Rycroft Department of Chemistry, University of Glasgow, Glasgow G12 8QQ. Scotland. Summary The structures of five ingol esters and a 17-hydroxyingenol ester from the latex of Euphorbia kamerunica have been determined. The 13C n.m.r. spectra of these compounds have been assigned using 2D 6C/6H correlations. The specific positions of attachment of esters have been assigned unambiguously using 13C n.m.r. methods including 2D long range 6c/6H correlations. The diterpenoids
of the Euphorbiaceae
have been a source of great interest
because of their biological
activity.'
nucleus
and it is difficult
to obtain pure compounds
various
positions
of the diterpenoid However,
solve the ester problem. cation
can occur during partial
These compounds
nucleus.
chemists
and to decide which ester is attached
In the past partial
while it has been reported'
hydrolysis
to organic
often occur as mixed esters of the same
this has not always
hydrolysis
to the
has been used to
that intramolecular
transesterifi-
been taken into account 3 in the
structural assignments. We have been able to circumvent the difficulties of transesterification 13 13 using C n.m.r. methods. Surprisingly there are few reports of C chemical shift data for 13 these compounds in the literature.' C chemWe now report the structural elucidation and the ical shifts of five ingol esters and a 17-hydroxyingenol Multiple
ester
preparative
(l), (2), (7), (lO),and
(16) [as its 3-deacetyl
(17) from the latex of Euphorbia
t.1.c. of the ether extract
third band in order of increasing
derivative
(15)1
kamerunica.
of the latex afforded
several
The
bands.
gave a crystalline mixture of compounds (1) and (2) in 13 C n.m.r. spectra (Tables 1 and 2) by comparison the ratio 3:2. It was evident from the 'H and 4 that with ingol tetra-acetate (31, whose relative stereochemistry has recently been reassigned, both compounds
contain
there are resonances cated
yielded
parative
t.1.c.
an ingol nucleus
for a tiglate
that the methoxyl
mixture
polarity
group
in (1) and a benzoate
is attached
the corresponding
(6).
to C-8 in both
3-deacetyl
derivatives
Thus the tiglate
Further
in (1) and
partial
and a methoxyl in (2). (1) and
group.
The chemical Partial
(2).
In addition shift of H-8 indihydrolysis
of the
(5) which were separated by pre13 C shifts, relative to (1) and the expected
In both cases C-2 and C-3 exhibited
(21, for removal of the 3-acetate. acetate
with two acetates
(4) and
hydrolysis
(4) must be attached
of
(4) gave 8-O-methyl-ingol-12-
to C-7.
The benzoate
group of
(5), and hence of (2) was shown to be attached to C-7 by selective decoupling experiments in the 13 C n.m.r. spectrum. Irradiation of H-7 (6 5.59) resulted in removal of a coupling 3 (3J = 3 Hz) to the benzoyl carbonyl group which then appeared as a triplet, J (H-ortho) = 3 Hz.
fully coupled
Similarly
for the acetate
(3J) and left a quartet
carbonyl
carbon
(2J = 7 Hz).
8-g-methyl-ingol-3,12-diacetate-7-tiglate
irradiation
of H-12
Thus the structures
(6 4.87) removed
of (1) and
a 4 Hz coupling
(2) are established
and 8-g-methyl-ingol-3,12-diacetate-7-benzoate
as respect-
ively. The third ingol ester, less polar +SeniOr
Commonwealth
Universities
than
(1) and
(2). was assigned
Fellow on leave from the University
3773
structure
(7), ingol-
of Ife, Nigeria.
3174
3,8,12-triacetate-7-tiglate, presence
of a 7-tiglate
on the basis of its spectroscopic
was established
based on long range couplings, carbonyl
group.
in particular
A more detailed
properties
by 2D &C/&H correlation
(Tables 1 and 2).
using polarisation
the three bond coupling
between
The
transfer
H-7 and the tiglate
of the use of the above methods for determining 5 will appear elsewhere. Partial hydrolysis of (7) yielded 6 inter alia ingol-12-acetate-8-tiglate (8) which, on acetylation, afforded (9). isomeric with the -sites of specific
natural
ester
hydroxyl
(7).
groups
structures recently
This result confirms
based on such evidence.
described3
these compounds
(9), 8-angelate
The least polar
The presence
the 3-deacetyl aration
of the tiglate
of a 7-angelate
(11) was obtained.
derivative
(see below) and also afforded
(13) and the 12-acetate The 3-deacetyl
(14).
derivative
by partial
hydrolysis
of
(11) enabled
(10) as a minor contaminant,
of (12) gave the natural product
method described
First
the sep-
as its 3-deacetyl
(12). the 12-acetate-8-angel-
on the basis of its spectroscopic
tion of the 2D long range hc/6H correlation
proper-
in two stages.
of the fifth ingol ester was readily assigned
8-g-methyl-ingol-12-acetate-7-angelate,
des(7).
with those of the tiglate
hydrolysis
the 12-acetate-7-angelate
Acetylation
to those of
(lo), has spectroscopic
resonances,
Further partial
of the fifth ingol ester, which accompanied
data for a compound
similarity
for
data3
at C-12.
apart from the angelate in (10) was proved
from E. kamerunica
of the published
The published
also bear remarkable
the C-7 and C-8 of assigning
of ingol-3,7,12-triacetate
Comparison
ingol-3,8,12-triacetate-7-angelate
identical,
derivative
(7).
this suggestion.
for the location
compound,
between
the hazards
and 8-benzoate
'I-esters, including
with our data supports
was presented
that ester transfer and illustrates
Thus it seems likely that the compounds
as the 8-tiglate
ties which are virtually
ate
hydrolysis
as ingol-3,7,8-triacetate-12-tiglate
No evidence
(7).
the report'
can occur during partial
are, in fact, the corresponding
cribed
description
ester attachment
(10).
structure
properties.
above confirmed
(15), Applica-
the presence
of the
7-angelate. Thus the natural ingol ester is 8-c-methyl-ingol-3,12-diacetate-7-angelate (16). 13 The C chemical shifts of these ingol esters were largely assigned using 2D 6c/6H correlations.
The problem
sidering
their long range proton couplings.
is a sharp quartet
of the assignment
show that the 6 73.4 resonance
the 6 71.1 signal is coupled
structure
data for ingol tetra-acetate
the torsion
expected.
6 73.4 is assigned
The most polar compound
has three acetates on C-15.
approximately function
and an angelate
The l3C resonances
138-9',
attached
of the geminal
is C-17
in (17) resonates (Table 3).
[rSH4.98
(H-3), 5.37
Using
the crystal C-15, C-4, C-5,
near zero are
to an ingenol methyls
(H-5), 4.07 and 4.16
(H-8), 0.89
nucleus
bearing
(H-13), 1.11
to cause an upfield
series appear
Introduction
(ABq,
(H-14)1,
an acyloxymethyl
in the ingol and ingenol
and 29 ppm for the a-methyl.
to either methyl would be expected
acyloxymethyl
to H-5, H-2 and H-18
to H-la.
for which =JCH values
(ABq, J 12.2 Hz, 2H-20), 4.32
16 ppm for the S-methyl
Since the only t-methyl
is coupled
to C-4 and 6 71.1 to C-15.
(171, m.p.
J 11.7 Hz. 2H-17), 4.11 and 4.55
of
angles C-4, C-15, C-l,H-laand
to be -105.2O and 111.6O respectively,
by con-
(7) the signal at 6 73.4 C of triplets (J 2, 7 Hz). The 2D
spectrum
to H-2, H-18 and more weakly
H-5 are inferred Hence
carbons , C-4 and C-15, was solved
In the coupled
(J 7 Hz) and that at 6C 71.1 a broad doublet
long range 6c/6H correlations whereas
of the epoxide
group at
of an acyloxy
shift of the remaining
methyl.
at 24.1 ppm it must be a, i.e. C-16, and hence the
377s
The position
of the angelate
of attachment
afforded
the 17-acetate-3-angelate
angelate
(19) [gH 4.39
(S, H-S),
of a 17-angelate of
(18) yielded
[6 4.95
C-3 are at lower
(s, H-S)]
in (17) since ester transfer
(H-3), 5.40
that the natural
3.65
compound
whereas
Formation
between
field than normal,
presumably
ester
(17).
Similarly
at 172.4 ppm.
hydrolysis
of
(18), followed
'H n.m.r.
(H-13), 1.15
16-hydroxyingenol
spectrum
tetra-acetate.
that the literature Table
(3)
(19) afforded
Acetylation
the isomer
(ZH-2011.
3.69
(21)
It follows,
therefore,
one acetate
[6.06 (H-l) , 4.93
1.
hydroxyl
is more deshielded
of the 20-angelate
derivatives
afforded (H-3), 5.37
(H-5), 6.21
for a compound
The 'H spectra of the isomers were predicted' 8. is identical to (22).
tetra-
(H-7), 4.37
(ABq, J 11.9 Hz, 2H-17), 4.57 and 4.14 to that published'
(19) and
hydrolysis.
17-hydroxyingenol
13C Chemical
Shifts of
Ingol
Derivatives
(ABq,
described to differ
as and
(CDC13)
(7)
(9)
(1)
(2)
(4)
(5)
1
31.3
31.5
31.7
31.5
31.4
31.5
31.5
31.8
31.7
2 3 4 5 6 7 8 9 10
29.3
29.5
31.9
29.5
29.3
29.4
29.4
31.9
31.9
76.2
76.5
76.1
76.6
76.3
76.8
76.9
76.1
75.9
73.3
73.4
75.7
73.4
73.4
73.5
74.4
75.7
75.7
117.0
117.0
117.5
116.8
116.8
116.7
117.1
117.3
117.6
139.5
139.8
139.5
139.9
139.9
140.0
139.7
139.5
139.2
76.8
76.6
73.6
76.7
77.0
74.0
74.6
73.7
74.3
71.2
71.5
78.8
71.7
71.2
78.8
78.8
78.9
78.9
24.7
25.1
27.2
25.0
25.0
27.2
27.2
27.1
27.1
19.3
19.3
19.2
19.3
19.3
19.3
19.4
19.2
19.2
11
30.6
30.7
30.5
30.7
30.8
30.5
30.5
30.4
30.5
12
70.6
70.6
71.0
70.6
70.8
71.0
71.0
70.8
71.0
13
42.9
43.1
42.9
43.1
43.0
43.0
43.1
43.0
43.0
14
207.4
207.6
207.8
207.6
207.6
207.6
207.6
207.8
207.8
15
71.0
71.1
72.8
71.1
71.1
71.1
71.2
72.8
72.8
16
16.9
16.9
16.1
16.9
17.0
16.9
16.9
16.1
16.1
17
17.3
17.5
17.8
17.5
17.4
17.7
17.8
17.8
17.8
18
29.0
29.1
29.2
29.2
29.2
29.3
29.3
29.3
29.3
19
16.0
16.1
16.5
16.1
16.1
16.5
16.5
16.5
16.5
20
13.3
13.4
13.2
13.3
13.4
13.3
13.3
13.2
13.2
Table
2. 9
1 H Chemical
Shifts of Ingol Derivatives
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
(11)
(12)
(13)
(14)
(15)
3
5.20
5.13
4.24 5.42 2.90
4.19 5.59 2.98
4.37 4.34 2.85
5.22 5.21 4.58
4.31 4.26 4.55
5.35 5.12 4.64
5.23 5.20 4.58
4.25 5.29 4.59
4.25 5.23 3.55
4.33
4.30
4.25
4.28 4.62
3.36
2.90
4.85
4.87
4.85
4.87
4.86
4.88
4.86
4.86
4.87
4.87
4.82
4.85
7
5.33
5.54
8
2.91
2.99
5.29 5.03 4.52
12
4.85
4.90
4.81
-4.13
to
than
compound
(15)
(10)
carbonyl
can occur during partial
by acetylation,
similarity
to the tertiary
is 167.3 ppm in (21) and moves downfield
The formation
(H-14), 4.22 and 4.11
J 12.7 Hz, 2H-20)] bears a striking
we suspect
of
as a result of H-bonding
carbonyl
(20) shows that, as in the ingol series , ester transfer
(22) whose
(s, H-3),
the possibility
The
usual in (21) and resonates
(H-8), 0.93
(20) [6D 4.41
(20) excludes
C-17 and C-20 is impossible.
acetylation
which
the 17-acetate-20-
(17), the most irritant of those isolated, is 17-acetoxyingenol-5,2013 C chemical shifts of the carbonyl group of the ester attached to
ester
168.8 ppm in the natural
acetate
of
hydrolysis
(s, H-5)1,
and the 20-angelate
(2H-17) , 4.31 and 4.55
(H-S), 4.13 and 4.24
Thus the l3C shift of the angelate
Complete
by partial
(s, 2H-20), 4.04
(ABq, J 11.7 Hz, 2~-17)].
the natural
diacetate-3-angelate.
group.
(s, H-3),
3.74 and 3.84
was determined
(18) [6H 4.13
5.47
3776
Table (17)
(22)
131.5 133.7 81.5 85.7 74.6
131.8 133.6
13 C Chemical
3.
82.0 85.7 74.6
Shifts of Ingenol Derivatives (17)
(22)
131.0
11 12
30.5 30.6
43.1 204.6 71.8
13 14 15
23.1 23.9 27.5
38.6 30.8 23.2 24.0 27.7
(17)
(22)
6
135.9
135.8
7
130.8
I3 9 10
43.1 204.6 71.9
(17) and
(22)
16 17 18 19 20
V7)
(22)
24.1 65.6 16.5 15.3 65.6
24.2 65.7 16.6 15.4 65.7
R4
16
19
OR” (1) 12) (3) (4) (5) (6! (7) (81 (9) (10) (11) (12) (131 (14) (15) (16)
R’
R2
R3
R4
AC AC AC
tig PhCO AC tiq PhCO H tig H AC ang ang ang H H
Me Me AC Me Me Me AC tig tiq AC AC H ang 9 Me Me
AC AC AC AC AC AC AC AC AC AC AC AC AC AC AC AC
H H H
AC H
AC AC H H H H H AC
ang ang
(17) (18) (19) (20) (21) (22)
R1
R2 R3
R4
ang w
AC H H H AC AC
AC AC AC H AC AC
H
H AC AC
AC H ang ang ang AC
References 1.
F.J. Evans and S.E. Taylor,
Progress
in the Chem. of Org. Nat. Prod.,'1983,
2.
K.A. Abo and F.J. Evans, J. Nat. Prod.,
1982, 45, 365.
3.
K.A. Abo and F.J. Evans, Planta Medica,
1981, 2,
J.D. Connolly,
C.O. Fakunle
and D.S. Rycroft,
J. Chem. Res., submitted.
5.
J.D. Connolly,
C.O. Fakunle
and D.S. Rycroft,
J. Chem. Res., submitted.
6.
H.J. Opferkuch
and E. Hecker,
7.
K.A. Abo and F.J. Evans, Phytochemistry,
8.
H.J. Opferkuch
9.
Only chemical
and E. Hecker,
Tetrahedron
shift data are given.
as reported
for the parent
(Received
in UK 4 June
1981, g, Letters,
Multiplicities
compounds. 1984)
Letters,
l-99.
392.
4.
Tetrahedron
44,
1973, 3611. 2535. 1974, 261. and coupling
constants
are essentially