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Piscicidal cis-clerodane diterpenes from solidago altissima l: absolute configurations of 5α, 10α-cis-clerodanes
Tetrahedron Letters,Vo1.25,No.26,up 2809-2812,1984 Printed in Great Britain
PISCICIDAL
cis-CLERODANE
ABSOLUTE
DITERPENES
CONFIGURATIONS
oo4o-4039/84 $3.00 + .OO 61984 Peraamon Press Ltd.
FROM SOLIDAGO AwISSIMA
L:
OF 5a,lOa-cis-CLERODANES
a* b Shunichi Manabea Masami Kazuib and Takao Matsuzaki Chikao Nishino aMitsubishi-Kasei Institite of Life Sciencis 11 Minamiooya, Machida, Tokyo 194, Japan b Research Center of Mitsubishi Chemical Industries, 1000 Kamoshida-cho, Midori-ku, Yokohama Kanagawa 227, Japan
Sumnary : From Solidago aZtissima L. (Compositae), a new 5a,lOa-cis-clerodane diterpene (Solidagolactone VIII) and known solidagolactones were isolated as piscicidal constituents. The structures of the constituents including absolute configurations were determined, and a revised structure was given to solidagolactone VII. Continuing weed, SoZidago
our investigations1 aZtissima
of the biologically
L. (a goldenrod,
ents with the 5a,lOa-cis-clerodane
Compositae),
skeleton
active constituents we isolated
[activity,
around
four piscicidal
limit) to killifish
(Gryzias Zatipes)] from the aerial parts of the plant. to be a new compound
from the plant.
They revised
trans-clerodanes
proposed
cal transformations, solidagolactones lactones structure
VIII
spectral
and VII,
giving
respectively.
by piscicidal
(except for flowers)
were required.
lactone VIII):
new (2)
data, the structures
and a revised
of the piscicidal
(2 -t 2a) structure
to solidago-
is made of on the absolute
diterpenes. from the methanol
The physical
-27.4”
further
extract
of the aerial parts
(2.7 g) and 5_ (1.4 g) were first isolated 5c on Florisil 5a, silicage15b and alumina .
AgN03(10%)-silicage15d
data of the compounds
(c 0.3)6a;
vmax 1780, 1750, 1705, 1650, 1640, 1268 cm-'; (3H, s, H3-20),
et a2.2
of the extract
(250mg),
C25H3605; [a],
by Yamamura
of the solidagolactones to cis-clerodanes from 4 . In this paper, on the basis of chemi-
(3.4 Kg) of the plant, G
To isolate la_ (124mg) and2
One (12) of the
and Okazaki
activity,
chromatographies
constitu-
The others were
and V (6_), isolated
Also the first description
of the 5a,lOa-cis-clerodane
after successive
IV (3
and X-ray analytical
are reported,
By monitoring
graphies
the structures
by McCrindle3
VIII.
named as solidagolactone
VII (2a),
to known solidagolactones,
rank
10 ppm in TLm (median tolerance
four was elucidated assigned
of a heinous
1.21 (3H, s, y3-19),
were as follows:
UV: Amax 209.1
k
nm (E 25700)6b;
chromato-
(solidago-
IR (film):
’ H NMR6c: 6 0.88 (3H, d, J = 6.4, H3-17), 1.03
1.29 (3H, s, H3-18),
(CH~)], 1.89 [3H, m, W3(CO)C=CH(CH3)],
and silicage15e
1.81 [3H, d, J = 6.8, CH3(CO)C$H
2.75 (lH, bs, H-3), 4.75
(2H, d, J = 1.8, H-16),
5.40 (lH, dd, J = 2.4, 3.5, H-6), 5.84 (lH, tt, J = 1.5, 1.8, H-14), 6.90 [lH, qq, J = 1.2, 6.8, CH3(CO)C&(CH3)]; CH(CH3)]
MS: m/z 416 (M+), 401 (M+-CH3),
(exact MS: 333.2076,
(solidagolactone mp 119"-120"
VII):
C20H2g04),
C25H3605
(hexane-EtOAc);
(Anal,Calcd.:
[a]
1745, 1695, 1640, 1272, 1248 cm- P;
-28.4O
C, 72.08; H, 8.71.
333 [M+-CH,(CO)C=
(317.2118,
C20H2g03).
3
Found: C, 72.48; H, 8.76);
(C 1.2); imax 211.8 nm (E 26500);
vmax (KBr) 1780,
6 0.88 (3H, d, J = 6.6, H3-17), 1.03 (3H, s, H3-20), 1.22
(3H, s, H E3 -19), 1.31 (3H, s, H3-18), CH3(CO)C
398 (Mf-H20),
317 CM+-CH,(C~,)=CH(CH,)]
1.97 [3H, m, fZ3(CO)&CH(CH3)],
2.03 (3H, d, J = 7.0,
2.75 (lH, bs, H-3), 4.76 (2H, d, J = 1.8, H-16), 5.44 (lH, dd, J = 2.5,
2809
2810 3.6, H-6), 5.84 (lH, tt, J = 1.5, 1.8, H-14), 6.07 [lH, qq, J = 1.2, 7.0, C;3(CO)C&f(CH3)]; 416 (M+), 401 (M+-CH~),
m/z
2
(solidagolactone
mp 137"-138'
IV):
398 (M+-~~0),
333 CM+-CH,(CO)C==CH(CH,)],
C20H3003(Anal. Calcd.: C, 75.43; H, 9.50.
(hexane-EtOAc);
[al0 t3.6'
= 6.8, H3-17),
(hexane);
[alO t125.2"
285.
(c 1.2); XmaX 205.3 nm
1750, 1705, 1668, 1640 cm-'; 6 0.83 (3H, d,J = 6.8, H3-17), 4.75 (2H, d,J = 1.8,
(3H, d, J = 1.2, H3-18), 1.8, H-14); m/z
316 (M+) (316.2032),
The presence
1.15
(2H, d, J = 1.8, H-16),
2
(solidagolactone
(E
20800);
V): C20H2803;
vrnax (film) 1780,
1.22 (6H, s, H3-19 and 20), 1.52
H-16), 5.63 (lH, m, H-3), 5.82 (lH, tt, J = 1.5,
301 (M+-CH3),
of a B-substituted
vrnax (KBr) 3530,
1.03 (3H, s, H3-20),
3.71 (lH, t, J = 2.8, H-6), 4.75
1.70 (3H, bs, H3-18),
5.83 (2H, m, H-3 and H-14); m/z 318 (M+), 300 (M+-H20), mp 106.5"-107"
Found: C, 75.84; H, 9.68);
(e 0.9); imaX 204.9 nm (E 18100);
3480 (sh), 1800, 1750, 1640 cm-'; 6 0.88 (3H, d,J (3H, s, H3-19),
317 [M -CH3(C02)C~~(~~3)].
287.
AayB -butenolide
ring was suggested
in IR (vmax 1800 or
1780, 1750 or 1745, 1640 cm-') and 'H NMR (6 4.76 or 4.75, 5.82 - 5.84) of all the compounds. The other IR and 'H NMR spectral
VII,
lactones
characteristics
IV and V, respectively,
in &, 2a
,5_and 6_ resembled
and the spectra were identical
those in solidago-
with those presented
by
Yamamura2. Similarity 333, 3171.
between
E
skeleton
Chemical
splitting
G
was observed
in their mass spectra
In the 'H NMR spectra, similar resonances
on the clerodane shifts,
6.07 in g
and 2
and its pendant methyls patterns
and coupling
were due to protons on angelate
to protons
on tiglate
moiety.
also appeared
416 (M+), 401, 398,
[m/z
for the signals
of protons
(H-3, H-6, H3-17, H3-18, H3-19 and H3-20). constants
moiety,
whereas
Thus the structure
2
of the signals
at 6 1.97, 2.03 and
those at 6 1.81, 1.89 and 6.90 in
could be given to the new compound.
,.. ^n LP y :A
1o 1
OR
k
R=C
l,b R=CO
2
R=CwH
2b
R=CO
E
R=H
qjtko
XH
i@%.
R
OR
2
R=,Y-OH
J,
R=COxH
6
R==O
k
R=H
Figure 1. molecular 6
‘2 ‘J.
R’=
H
R1=OC+?
R2= COOH
(3. &COOH
ORTEP drawing structure
of the
of p-bromobenzoate
2811
The four piscicidal derived
compounds
were structurally Epoxybutenolides,
from 5_ (Jones' oxidation).
into epoxyfurano-compounds, of a s-substituted
c7
correlated.
and 2,b8, with DIBAL
furan ring was indicated
in the
2
with a hydroxyl
group
(z)'
V (2) was
and 2,", were respectively
(THF, -35" -+ -ZOO, 3.5 hr).
converted The presence
IR band (vmax 880 cm-') and 'H NMR Signals
[6 6.25 (lH, m), 7.21 (lH, m), 7.35 (lH, t, J = 1.5)] of G compound
Solidagolactone
and 3
which yielded
the same
(film) 3480 cm-'; 6 1.37 (3H, S, H3-18),
[vmax
3.01 (lH,
d, J = 2.4, H-3), 4.13 (lH, t, J = 2.6, H-6), 5.44 (lH, bs, OH)] on LiA1H4 reduction Solidagolactone
3hr).
acid (CH2C12, According
room temp, 1 hr), 2 yielded
to the usual epoxidation
was expected
On treatment
IV (5~) was also correlated with z.
to have an epoxide
(yield ratio, 1.7:1). 12 alcohols , the main product, 2,
3a1' _ anddl
two epoxides,
mechanism
(THF, 15',
with p-bromoperbenzoic
of homoallylic
ring with the same configuration
(s-epoxide)
as the B-OH group.
In the IR (CHC13) of 3a, an absorption of intramolecular hydrogen bond of the 0H13 was shown -1 which was unaffected by dilution, but the spectrum showed no absorption at 3600 ,
at 3470 cm
cm-l (free OH) which
appeared
3475 cm-l which was affected suggested
by a sharpened
proton of2 molecular
resonated hydrogen
the u-oriented
at d around
bonding
epoxide
Because
identified to 2
bonding
nature
in very lower field
These evidences
suggest
chemical
shift
the presence
by
the structure
Yamamura
was
the OH
of an intraepoxide
In C& no such interaction to that of 3a.z
a furano-derivative
of solidagolactone
of
a free form of the B-OH
(6 5.44) of the OH proton of 2
(THF, -35" + -25", 3.5 hr) to yield
proposed
of the 0H14 in 2
(6 5.41), whereas
the B-OH group and the oxygen atom of a B-oriented
3.02 [lH, d, J = 2.4, H-33) in ,3$.
Accordingly,
as 33.
from2
signal
1.8 (m).
between
In 6, a weak IR band was observed at
The hydrogen
[B 1.40 (3H, s), 3.11 (lH, d, J = 5.1)] causes
of similar
was reacted with DIBAL
IR (CHC13) of2.
broad singlet
ring (6 1.37 (3H, s, H3-18),
group.
in the
by dilution.
which was
VII was revealed
to revise
et a2.2
In cis-clerodane was determined
with a confirmed establish effects
type diterpenes, the absolute configuration for a 5B,lOs-cis-clerodane 15 by a structural correlation of this compound with (-)-hardwickiic acid 16 absolute structure . For 5a,lOa-cis-clerodanes, McCrindle17 attempted to
for2
the absolute
configurations
of solidagoic
acid A (2)
and B (u)
in the CD curves of a C-2 ketone and a similar enone derivative.
ambiguities
in the entire
effects were affected Crystalline established
absolute
by possible
p-bromobenzoate
by X-ray analysis
for the piscicidal
compounds
structure,
since interpretation
conformations
from 2,
a = 11.782
for the signs of Cotton
and its absolute
Hence, the absolute
as the first example
Crystal datalg: Monoclinic,
configuration
(2), b = 10.526
ite monochromated ties of Friedel
(2ac150") were measured Cu-Ka Radiation
with an Enraf-Nonius
and an w/20 scanning
pairs, 2373, independent
reflections
structure
was solved by the direct method
including
all non-hydrogen
and refined
atoms with anisotropic
with isotropic
temperature
factors.
the calculated
positions.
The absolute
and calculated
structure
factors
The final R-index configuration
of 23 Friedel
Intensity
After averaging
factors
the intensi-
supported
The
least squares methods,
and 5 hydrogen
for 2373 reflections was determined
pairs which
data for using graph-
(IF/) were used.
by the full-matrix
temperature
(2) 1, B = 96.13
(AD4 diffractometer
IFI >3a
was
diterpenes.
(3), c = 10.273
technique.
with
structure
could be determined
for 5u,lOa-cis-clerodane
(l)", U = 1267 i, Z = 2, DC = 1.356, lo = 27.191 cm-', space group P 21. 5539 reflections
some
for the derivatives.
(i)18 was obtained
(Fig. 1).
based on Cotton He left however
atoms
were 0.097 at
by comparing the absolute
the observed
2812
configurations
shown in Fig. 1.
AcknowZedgment: NMR spectra
We wish to thank Prof. S. Yamamura,
of solidagolactones
Keio University,
for the IR and 'H
VII, IV and V. References and Notes
C. Nishino and T. Tsuzuki, BEtyu-&g&u, 40, 62 (1975). :: M. Niwa and S. Yamamura, Tetrahedron Letters, 22, 2789 (1981). T. Anthonsen and R. McCrindle, Acta Ckem. Seana’., 23, 1068 (1969). :: T. Okazaki, A. Ohsuka and M. Kotake, Nippon Kagaku Kaiski, 1973, 584. 5. a: EtOAc (active fraction) after hexane; b: hexane-EtOAc 10% stepwise; Activity, 70% and 80% EtOAc in hexane. c: Benzene-EtOAc 5% stepwise; Activity, 30-40% (&), 40-50% (to subsequent chromatographies to isolate l,a and ,!S)and 55-60% (2) EtOAc in benzene. d: HexaneEtOAc 5% stepwise; Activity, 90-95% (Q) and 100% (to final chromatography to obtain,6) EtOAc in hexane. e: Benzene-EtOAc (4:l); Activity, fractions lo-13 (j). 6. a: In EtOH at 25". B: In EtOH. c: In CDCl3 at 90 MHz. Coupling constant (J) in Hz. 7. L$: C25H3604 (Anal. Calcd.: C, 74.96; H, 9.06. Found: C, 75.17; H, 9.21); mp 84.5"-86" (hexane); [alo -31.9" (e 0.4); vmax (film) 1710, 1655, 1270, 880 cm-l; 6 0.85 (3H, d, J = 6.6, H3-171, 1.04 (3H, s, Hs-20), 1.27 (3H, s, H3-19), 1.29 (3H, s, Hs-18), 1.80 [3H, m,CHs(CO)C=CH(CHa)l, 2.75 (lH, bs, H-3), 5.41
a.
9. ;tb: CzoH3003; [aID -28.0" (c 0.9); vmax (film) 3480, 875 cm-l; 6 0.85 (3H d, J = 7.0, Hs-17), 1.02 (3H, s, Hs-20), 1.19 (3H, S, Hs-19), 1.37 (3H, S, H3-l8), 3.01 (lH, d, J = 2.4, H-3), 4.13 (lH, t, J=2.6, H-6), 5.44 (lH, bs, OH), 6.25 (lH, m, furanoid), 7.20 (lH, m, furanoid), 7.35 (lH, t, J = 1.5, furanoid); m/z 318 (M+) (318.2192), 300 (M+-H20). 10. 3a: C20H3004; [CZ] -27.2" (C 1.1); (CHC13) 3470, 1785, 1750, 1640 cm-l; 6 0.87 (3H x J = 6.8, Hs-177, 1.00 (3H, S, H3???7, 1.14 (3H, S, Hs-19), 1.37 (3H, S, H3-l8), 3.02' (lH, d, J = 2.4, H-3), 4.13 (lH, bt, J = 2.7, H-6), 4.75 (2H, d, J = 1.8 H-16, 5.41 (lH, bs, OH), 5.83 (lH, tt, J = 1.5, 1.8, H-14); m/z 334 (M') (334.2145), 316 (M+-H20). 11. 8: CzoH3004; [a]D -17.1" (e 1.3); vmax (CHCls) 3600, 3475, 1785, 1750, 1640 cm-l; 6 0.87 'I3H, d, J = 6.4, H3-171, 0.97 (3H, S, H3-20), 1.16 (3H, S, Hs-19), 1.40 (3H, S, H3-l8), around 1.8 (lH, OH), 3.11 (lH, d, J = 5.1, H-3), 3.82 (lH, bt, J = 2.6, H-6), 4.73 (2~, d, J = 1.8, H-16 4, 5.82 (lH, tt, J = 1.5, 1.8, H-14) m/z 334 (M+) (334.2183), 319 (M+-CH3), 316 (M -H20). I, 12. E.W. Colvin, S.M. Malchenko, R.A. Raphael and J.S. Roberts, J. Ckem. Sot. Perkin 1973, 1989. 1374. 13. P.C. Chamberlain, M.L. Roberts and G.H. Whitham, J. Ckem. SOC. (ET), m, 14. S. Mynderse and R.E. Moore, J. Org. Ckem., Q., 4359 (1978). 15. M.S. Henderson, R.D.H. Murray, R. McCrindle and D. McMaster, Can. J. Ckem., 51, 1322 A.B. Anderson, R. McCrindle and E. Nakamura, J. Ckem. Sot. Ckem. Corm., 1974, (1973). 453. R. McCrindle, E. Nakamura and A.B. Anderson, J. Ckem. Sot. Perkin I, 1976, 1590. Letters, 1968, 2681. 16. R. Misra, R.C. Pandey and S. Dev, Tetrahedron 17. T. Anthonsen, M.S. Henderson, A. Martin, R.D.H. Murray, R. McCrindle and D. McMaster, Can. J. Ckem., 3, 1332 (1973). Found: C, 62.75; H, 6.31; Br, la. $,: C27Hss0sBr (Anal. Calcd.: C, 62.67; H, 6.43; Br, 15.44. 242.9 (e 17200), 200.6 nm (E 34000); 15.50); mp 192.5" - 194"; [a] -10.7' (C 0.5); A (KBr) 1790 1750 1715 7645 1598 1490 cmmTx 6 0.89 (3H, d, J = 6.6, H3-17), 1.07 i"!#; s, Hs-20),'1.26 [3H, s: H&), l.jO (3H, s, &18), 2.75 (1H d J = 1 5 H-3) 4.76 (2H, d, J = 1.8, H-16), 5.57 (lH, dd, J = 2.4, 3.5, H-6), 5.86 (iH, tt,'J'= 1.5: 7.97 (2H, dm, J = 8.7, aromatic); m/z 518 1.8, H-14), 7.58 (2H, d, J = 8.7, aromatic) (M++2)/516 (M+) (l:l), 503 (M++2-CHs)/501 (M+-CH,) (l:l), 333 (M+-BrCsHbCO), 316 (M+-BrC6H4C02H). 19. The atomic co-ordinates for this work are available on request from the director of the Cambridge Crystallographic Data Centre, University Chemical Laboratory, Lensfield Road, Cambridge CB2 lEW, UK.
(Received
in Japan
13 March
1984)
PISCICIDAL
cis-CLERODANE
ABSOLUTE
DITERPENES
CONFIGURATIONS
oo4o-4039/84 $3.00 + .OO 61984 Peraamon Press Ltd.
FROM SOLIDAGO AwISSIMA
L:
OF 5a,lOa-cis-CLERODANES
a* b Shunichi Manabea Masami Kazuib and Takao Matsuzaki Chikao Nishino aMitsubishi-Kasei Institite of Life Sciencis 11 Minamiooya, Machida, Tokyo 194, Japan b Research Center of Mitsubishi Chemical Industries, 1000 Kamoshida-cho, Midori-ku, Yokohama Kanagawa 227, Japan
Sumnary : From Solidago aZtissima L. (Compositae), a new 5a,lOa-cis-clerodane diterpene (Solidagolactone VIII) and known solidagolactones were isolated as piscicidal constituents. The structures of the constituents including absolute configurations were determined, and a revised structure was given to solidagolactone VII. Continuing weed, SoZidago
our investigations1 aZtissima
of the biologically
L. (a goldenrod,
ents with the 5a,lOa-cis-clerodane
Compositae),
skeleton
active constituents we isolated
[activity,
around
four piscicidal
limit) to killifish
(Gryzias Zatipes)] from the aerial parts of the plant. to be a new compound
from the plant.
They revised
trans-clerodanes
proposed
cal transformations, solidagolactones lactones structure
VIII
spectral
and VII,
giving
respectively.
by piscicidal
(except for flowers)
were required.
lactone VIII):
new (2)
data, the structures
and a revised
of the piscicidal
(2 -t 2a) structure
to solidago-
is made of on the absolute
diterpenes. from the methanol
The physical
-27.4”
further
extract
of the aerial parts
(2.7 g) and 5_ (1.4 g) were first isolated 5c on Florisil 5a, silicage15b and alumina .
AgN03(10%)-silicage15d
data of the compounds
(c 0.3)6a;
vmax 1780, 1750, 1705, 1650, 1640, 1268 cm-'; (3H, s, H3-20),
et a2.2
of the extract
(250mg),
C25H3605; [a],
by Yamamura
of the solidagolactones to cis-clerodanes from 4 . In this paper, on the basis of chemi-
(3.4 Kg) of the plant, G
To isolate la_ (124mg) and2
One (12) of the
and Okazaki
activity,
chromatographies
constitu-
The others were
and V (6_), isolated
Also the first description
of the 5a,lOa-cis-clerodane
after successive
IV (3
and X-ray analytical
are reported,
By monitoring
graphies
the structures
by McCrindle3
VIII.
named as solidagolactone
VII (2a),
to known solidagolactones,
rank
10 ppm in TLm (median tolerance
four was elucidated assigned
of a heinous
1.21 (3H, s, y3-19),
were as follows:
UV: Amax 209.1
k
nm (E 25700)6b;
chromato-
(solidago-
IR (film):
’ H NMR6c: 6 0.88 (3H, d, J = 6.4, H3-17), 1.03
1.29 (3H, s, H3-18),
(CH~)], 1.89 [3H, m, W3(CO)C=CH(CH3)],
and silicage15e
1.81 [3H, d, J = 6.8, CH3(CO)C$H
2.75 (lH, bs, H-3), 4.75
(2H, d, J = 1.8, H-16),
5.40 (lH, dd, J = 2.4, 3.5, H-6), 5.84 (lH, tt, J = 1.5, 1.8, H-14), 6.90 [lH, qq, J = 1.2, 6.8, CH3(CO)C&(CH3)]; CH(CH3)]
MS: m/z 416 (M+), 401 (M+-CH3),
(exact MS: 333.2076,
(solidagolactone mp 119"-120"
VII):
C20H2g04),
C25H3605
(hexane-EtOAc);
(Anal,Calcd.:
[a]
1745, 1695, 1640, 1272, 1248 cm- P;
-28.4O
C, 72.08; H, 8.71.
333 [M+-CH,(CO)C=
(317.2118,
C20H2g03).
3
Found: C, 72.48; H, 8.76);
(C 1.2); imax 211.8 nm (E 26500);
vmax (KBr) 1780,
6 0.88 (3H, d, J = 6.6, H3-17), 1.03 (3H, s, H3-20), 1.22
(3H, s, H E3 -19), 1.31 (3H, s, H3-18), CH3(CO)C
398 (Mf-H20),
317 CM+-CH,(C~,)=CH(CH,)]
1.97 [3H, m, fZ3(CO)&CH(CH3)],
2.03 (3H, d, J = 7.0,
2.75 (lH, bs, H-3), 4.76 (2H, d, J = 1.8, H-16), 5.44 (lH, dd, J = 2.5,
2809
2810 3.6, H-6), 5.84 (lH, tt, J = 1.5, 1.8, H-14), 6.07 [lH, qq, J = 1.2, 7.0, C;3(CO)C&f(CH3)]; 416 (M+), 401 (M+-CH~),
m/z
2
(solidagolactone
mp 137"-138'
IV):
398 (M+-~~0),
333 CM+-CH,(CO)C==CH(CH,)],
C20H3003(Anal. Calcd.: C, 75.43; H, 9.50.
(hexane-EtOAc);
[al0 t3.6'
= 6.8, H3-17),
(hexane);
[alO t125.2"
285.
(c 1.2); XmaX 205.3 nm
1750, 1705, 1668, 1640 cm-'; 6 0.83 (3H, d,J = 6.8, H3-17), 4.75 (2H, d,J = 1.8,
(3H, d, J = 1.2, H3-18), 1.8, H-14); m/z
316 (M+) (316.2032),
The presence
1.15
(2H, d, J = 1.8, H-16),
2
(solidagolactone
(E
20800);
V): C20H2803;
vrnax (film) 1780,
1.22 (6H, s, H3-19 and 20), 1.52
H-16), 5.63 (lH, m, H-3), 5.82 (lH, tt, J = 1.5,
301 (M+-CH3),
of a B-substituted
vrnax (KBr) 3530,
1.03 (3H, s, H3-20),
3.71 (lH, t, J = 2.8, H-6), 4.75
1.70 (3H, bs, H3-18),
5.83 (2H, m, H-3 and H-14); m/z 318 (M+), 300 (M+-H20), mp 106.5"-107"
Found: C, 75.84; H, 9.68);
(e 0.9); imaX 204.9 nm (E 18100);
3480 (sh), 1800, 1750, 1640 cm-'; 6 0.88 (3H, d,J (3H, s, H3-19),
317 [M -CH3(C02)C~~(~~3)].
287.
AayB -butenolide
ring was suggested
in IR (vmax 1800 or
1780, 1750 or 1745, 1640 cm-') and 'H NMR (6 4.76 or 4.75, 5.82 - 5.84) of all the compounds. The other IR and 'H NMR spectral
VII,
lactones
characteristics
IV and V, respectively,
in &, 2a
,5_and 6_ resembled
and the spectra were identical
those in solidago-
with those presented
by
Yamamura2. Similarity 333, 3171.
between
E
skeleton
Chemical
splitting
G
was observed
in their mass spectra
In the 'H NMR spectra, similar resonances
on the clerodane shifts,
6.07 in g
and 2
and its pendant methyls patterns
and coupling
were due to protons on angelate
to protons
on tiglate
moiety.
also appeared
416 (M+), 401, 398,
[m/z
for the signals
of protons
(H-3, H-6, H3-17, H3-18, H3-19 and H3-20). constants
moiety,
whereas
Thus the structure
2
of the signals
at 6 1.97, 2.03 and
those at 6 1.81, 1.89 and 6.90 in
could be given to the new compound.
,.. ^n LP y :A
1o 1
OR
k
R=C
l,b R=CO
2
R=CwH
2b
R=CO
E
R=H
qjtko
XH
i@%.
R
OR
2
R=,Y-OH
J,
R=COxH
6
R==O
k
R=H
Figure 1. molecular 6
‘2 ‘J.
R’=
H
R1=OC+?
R2= COOH
(3. &COOH
ORTEP drawing structure
of the
of p-bromobenzoate
2811
The four piscicidal derived
compounds
were structurally Epoxybutenolides,
from 5_ (Jones' oxidation).
into epoxyfurano-compounds, of a s-substituted
c7
correlated.
and 2,b8, with DIBAL
furan ring was indicated
in the
2
with a hydroxyl
group
(z)'
V (2) was
and 2,", were respectively
(THF, -35" -+ -ZOO, 3.5 hr).
converted The presence
IR band (vmax 880 cm-') and 'H NMR Signals
[6 6.25 (lH, m), 7.21 (lH, m), 7.35 (lH, t, J = 1.5)] of G compound
Solidagolactone
and 3
which yielded
the same
(film) 3480 cm-'; 6 1.37 (3H, S, H3-18),
[vmax
3.01 (lH,
d, J = 2.4, H-3), 4.13 (lH, t, J = 2.6, H-6), 5.44 (lH, bs, OH)] on LiA1H4 reduction Solidagolactone
3hr).
acid (CH2C12, According
room temp, 1 hr), 2 yielded
to the usual epoxidation
was expected
On treatment
IV (5~) was also correlated with z.
to have an epoxide
(yield ratio, 1.7:1). 12 alcohols , the main product, 2,
3a1' _ anddl
two epoxides,
mechanism
(THF, 15',
with p-bromoperbenzoic
of homoallylic
ring with the same configuration
(s-epoxide)
as the B-OH group.
In the IR (CHC13) of 3a, an absorption of intramolecular hydrogen bond of the 0H13 was shown -1 which was unaffected by dilution, but the spectrum showed no absorption at 3600 ,
at 3470 cm
cm-l (free OH) which
appeared
3475 cm-l which was affected suggested
by a sharpened
proton of2 molecular
resonated hydrogen
the u-oriented
at d around
bonding
epoxide
Because
identified to 2
bonding
nature
in very lower field
These evidences
suggest
chemical
shift
the presence
by
the structure
Yamamura
was
the OH
of an intraepoxide
In C& no such interaction to that of 3a.z
a furano-derivative
of solidagolactone
of
a free form of the B-OH
(6 5.44) of the OH proton of 2
(THF, -35" + -25", 3.5 hr) to yield
proposed
of the 0H14 in 2
(6 5.41), whereas
the B-OH group and the oxygen atom of a B-oriented
3.02 [lH, d, J = 2.4, H-33) in ,3$.
Accordingly,
as 33.
from2
signal
1.8 (m).
between
In 6, a weak IR band was observed at
The hydrogen
[B 1.40 (3H, s), 3.11 (lH, d, J = 5.1)] causes
of similar
was reacted with DIBAL
IR (CHC13) of2.
broad singlet
ring (6 1.37 (3H, s, H3-18),
group.
in the
by dilution.
which was
VII was revealed
to revise
et a2.2
In cis-clerodane was determined
with a confirmed establish effects
type diterpenes, the absolute configuration for a 5B,lOs-cis-clerodane 15 by a structural correlation of this compound with (-)-hardwickiic acid 16 absolute structure . For 5a,lOa-cis-clerodanes, McCrindle17 attempted to
for2
the absolute
configurations
of solidagoic
acid A (2)
and B (u)
in the CD curves of a C-2 ketone and a similar enone derivative.
ambiguities
in the entire
effects were affected Crystalline established
absolute
by possible
p-bromobenzoate
by X-ray analysis
for the piscicidal
compounds
structure,
since interpretation
conformations
from 2,
a = 11.782
for the signs of Cotton
and its absolute
Hence, the absolute
as the first example
Crystal datalg: Monoclinic,
configuration
(2), b = 10.526
ite monochromated ties of Friedel
(2ac150") were measured Cu-Ka Radiation
with an Enraf-Nonius
and an w/20 scanning
pairs, 2373, independent
reflections
structure
was solved by the direct method
including
all non-hydrogen
and refined
atoms with anisotropic
with isotropic
temperature
factors.
the calculated
positions.
The absolute
and calculated
structure
factors
The final R-index configuration
of 23 Friedel
Intensity
After averaging
factors
the intensi-
supported
The
least squares methods,
and 5 hydrogen
for 2373 reflections was determined
pairs which
data for using graph-
(IF/) were used.
by the full-matrix
temperature
(2) 1, B = 96.13
(AD4 diffractometer
IFI >3a
was
diterpenes.
(3), c = 10.273
technique.
with
structure
could be determined
for 5u,lOa-cis-clerodane
(l)", U = 1267 i, Z = 2, DC = 1.356, lo = 27.191 cm-', space group P 21. 5539 reflections
some
for the derivatives.
(i)18 was obtained
(Fig. 1).
based on Cotton He left however
atoms
were 0.097 at
by comparing the absolute
the observed
2812
configurations
shown in Fig. 1.
AcknowZedgment: NMR spectra
We wish to thank Prof. S. Yamamura,
of solidagolactones
Keio University,
for the IR and 'H
VII, IV and V. References and Notes
C. Nishino and T. Tsuzuki, BEtyu-&g&u, 40, 62 (1975). :: M. Niwa and S. Yamamura, Tetrahedron Letters, 22, 2789 (1981). T. Anthonsen and R. McCrindle, Acta Ckem. Seana’., 23, 1068 (1969). :: T. Okazaki, A. Ohsuka and M. Kotake, Nippon Kagaku Kaiski, 1973, 584. 5. a: EtOAc (active fraction) after hexane; b: hexane-EtOAc 10% stepwise; Activity, 70% and 80% EtOAc in hexane. c: Benzene-EtOAc 5% stepwise; Activity, 30-40% (&), 40-50% (to subsequent chromatographies to isolate l,a and ,!S)and 55-60% (2) EtOAc in benzene. d: HexaneEtOAc 5% stepwise; Activity, 90-95% (Q) and 100% (to final chromatography to obtain,6) EtOAc in hexane. e: Benzene-EtOAc (4:l); Activity, fractions lo-13 (j). 6. a: In EtOH at 25". B: In EtOH. c: In CDCl3 at 90 MHz. Coupling constant (J) in Hz. 7. L$: C25H3604 (Anal. Calcd.: C, 74.96; H, 9.06. Found: C, 75.17; H, 9.21); mp 84.5"-86" (hexane); [alo -31.9" (e 0.4); vmax (film) 1710, 1655, 1270, 880 cm-l; 6 0.85 (3H, d, J = 6.6, H3-171, 1.04 (3H, s, Hs-20), 1.27 (3H, s, H3-19), 1.29 (3H, s, Hs-18), 1.80 [3H, m,CHs(CO)C=CH(CHa)l, 2.75 (lH, bs, H-3), 5.41
a.
9. ;tb: CzoH3003; [aID -28.0" (c 0.9); vmax (film) 3480, 875 cm-l; 6 0.85 (3H d, J = 7.0, Hs-17), 1.02 (3H, s, Hs-20), 1.19 (3H, S, Hs-19), 1.37 (3H, S, H3-l8), 3.01 (lH, d, J = 2.4, H-3), 4.13 (lH, t, J=2.6, H-6), 5.44 (lH, bs, OH), 6.25 (lH, m, furanoid), 7.20 (lH, m, furanoid), 7.35 (lH, t, J = 1.5, furanoid); m/z 318 (M+) (318.2192), 300 (M+-H20). 10. 3a: C20H3004; [CZ] -27.2" (C 1.1); (CHC13) 3470, 1785, 1750, 1640 cm-l; 6 0.87 (3H x J = 6.8, Hs-177, 1.00 (3H, S, H3???7, 1.14 (3H, S, Hs-19), 1.37 (3H, S, H3-l8), 3.02' (lH, d, J = 2.4, H-3), 4.13 (lH, bt, J = 2.7, H-6), 4.75 (2H, d, J = 1.8 H-16, 5.41 (lH, bs, OH), 5.83 (lH, tt, J = 1.5, 1.8, H-14); m/z 334 (M') (334.2145), 316 (M+-H20). 11. 8: CzoH3004; [a]D -17.1" (e 1.3); vmax (CHCls) 3600, 3475, 1785, 1750, 1640 cm-l; 6 0.87 'I3H, d, J = 6.4, H3-171, 0.97 (3H, S, H3-20), 1.16 (3H, S, Hs-19), 1.40 (3H, S, H3-l8), around 1.8 (lH, OH), 3.11 (lH, d, J = 5.1, H-3), 3.82 (lH, bt, J = 2.6, H-6), 4.73 (2~, d, J = 1.8, H-16 4, 5.82 (lH, tt, J = 1.5, 1.8, H-14) m/z 334 (M+) (334.2183), 319 (M+-CH3), 316 (M -H20). I, 12. E.W. Colvin, S.M. Malchenko, R.A. Raphael and J.S. Roberts, J. Ckem. Sot. Perkin 1973, 1989. 1374. 13. P.C. Chamberlain, M.L. Roberts and G.H. Whitham, J. Ckem. SOC. (ET), m, 14. S. Mynderse and R.E. Moore, J. Org. Ckem., Q., 4359 (1978). 15. M.S. Henderson, R.D.H. Murray, R. McCrindle and D. McMaster, Can. J. Ckem., 51, 1322 A.B. Anderson, R. McCrindle and E. Nakamura, J. Ckem. Sot. Ckem. Corm., 1974, (1973). 453. R. McCrindle, E. Nakamura and A.B. Anderson, J. Ckem. Sot. Perkin I, 1976, 1590. Letters, 1968, 2681. 16. R. Misra, R.C. Pandey and S. Dev, Tetrahedron 17. T. Anthonsen, M.S. Henderson, A. Martin, R.D.H. Murray, R. McCrindle and D. McMaster, Can. J. Ckem., 3, 1332 (1973). Found: C, 62.75; H, 6.31; Br, la. $,: C27Hss0sBr (Anal. Calcd.: C, 62.67; H, 6.43; Br, 15.44. 242.9 (e 17200), 200.6 nm (E 34000); 15.50); mp 192.5" - 194"; [a] -10.7' (C 0.5); A (KBr) 1790 1750 1715 7645 1598 1490 cmmTx 6 0.89 (3H, d, J = 6.6, H3-17), 1.07 i"!#; s, Hs-20),'1.26 [3H, s: H&), l.jO (3H, s, &18), 2.75 (1H d J = 1 5 H-3) 4.76 (2H, d, J = 1.8, H-16), 5.57 (lH, dd, J = 2.4, 3.5, H-6), 5.86 (iH, tt,'J'= 1.5: 7.97 (2H, dm, J = 8.7, aromatic); m/z 518 1.8, H-14), 7.58 (2H, d, J = 8.7, aromatic) (M++2)/516 (M+) (l:l), 503 (M++2-CHs)/501 (M+-CH,) (l:l), 333 (M+-BrCsHbCO), 316 (M+-BrC6H4C02H). 19. The atomic co-ordinates for this work are available on request from the director of the Cambridge Crystallographic Data Centre, University Chemical Laboratory, Lensfield Road, Cambridge CB2 lEW, UK.
(Received
in Japan
13 March
1984)