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Total synthesis of dl -elemol
Tetrahedron Letters No.22, p,'u 1779-1782,
Pergamon Press.
1969,
Printed
in Great Britain.
TOTAL SYNTHESIS OF $-ELEMOL E. J. Corey and Emil A. Broger Department
of Chemistry,
Harvard University, ly69;
(Received in USA 27 lkr& Elemol
is a crystalline
this substance
is an indirect
note outlines
a direct
acteristic
sesquiterpenic preparation
synthesis
1,2-divinylcyclohexane
Cambridge,
received in UK for publication 9 April 1969) alcohol
of structure
from (-)a-santonin
of g-1
(4) which involves
closure
which has recently
8-,
allylic
formed
of d-
Although it
intermediate, direct
a novel method for the construction
process
of elemol
and c&-l,
carbocyclic
has previously
via e,
the effect of structure
to humulene synthesis
rings (5-7).
2-divinylcyclohexanes
The intermediate
trans-1,
(ratio 2
5-cyclodecadiene.
on the course
Of special
of the char-
relevance
(11-membered
ring formatio@
additional
required
to the appli-
S-decadiene
was trans-
: 1) by reaction with nickel carbonyl was not an
of trans-1,2-divinylcyclohexane
by a
This fact together with previous
of the nickel carbonyl
of the -trans, trans-cyclodecadiene
(I), and this provided
This
(3).
been used to effect ring
was the finding that l, lO-dibromo-2,
could not be made between the formation
and formation
could lead to a synthesis elemol
with nickel carbonyl
shown in the case of the -cis product that cis, trans-1,5-cyclodecadiene
a distinction
tions regarding application
was
dibromides
and 11- to 18-membered to the synthesis
(7).
been described
of
unit.
cation of this reaction into a mixture
synthesis
II
of acyclic
to form 6-,
The only recorded
I (1, 2).
I
The reaction
02138
Massachusetts
cyclization,
(6), made it seem possible
II, a probable
precursor
observa-
including the that this approach
of elemol
(8), as well as
incentive for this study.
for the cyclization
reaction,
1779
the dibromide
VIId, was synthesized
as
No . 22
I
mpoT III
dOOCH, IV
Va, U = Cl, V = CHQCOZ Vb, U = g-TolCOz,
V = CH3C02
Via,
Vc, U = o-TolC02,
V = OH
VIb, U=OH,
Vd, U = o-TolC02,
V = Br
VIc,
U = g-TolC02,
w = OTHP
W=OTHP
U=W=OTHP
COOCHQ COOCHQ
Vna,
W = OTHP,
VIIb, W=OTHP, VIIc,
X = CHO
VIII
X=H
W = OH, X = H
VIId, W = Br, X = H
\ P Ma,
:Rl
k2
R1 = COOCH3. R2 = H
Ixb, R1 = H, R2 = COOCH3
COOCHQ X
No.22
1781
The trans iodide III, prepared
follows. in acetone, 20
from the corresponding
was allowed to react with sodio dimethyl malonate
bromide
(6) by treatment with sodium iodide
in tetrahydrofuran--dimethylformamide
: 1) for 48 hr. at 40” (after an initial period of 1 hr. at 25”) to give IV (9, 10) in 85% yield.
the sodio derivative tuted malonic
of IV by a similar
ester Via (9, 10).
The bromide
butene (Va) (11) by the sequence: ethanol at 80” for 15 hr., 25” to form Vc,
the o-disubstituted afforded
malonic
hr. produced
Vd (9) was prepared
equiv.
tribromide
of sodium methoxide
(2 equiv. ) in
sodium hydroxide
in ether at 0”.
hydroxide
Treatment
in methanol--toluene
ether VIc (9)
(1
: 3) at -70” for 8
to produce VIIb (79% from VIc) (9)
at 100” under nitrogen for 0.5 hr.
mono ester VIIb was subjected
to acid hydrolysis
this was converted
ester VIId (9) (90% from VIIb) by reaction
of
acid catalyst.
hydride in pentane--toluene
without purification
at
in methanol at 25” for 10 hr.
into the bis-tetrahydropyranyl
in dioxane at 25” with a small amount of ptoluenesulfonic
the aldehyde VIIa which was deformylated
to dibromo
o-toluate
of phosphorus
of diisobutylaluminum
of
from 1-chloro-2-methyl-4-acetoxy-2-
of aqueous ethanolic
of potassium
Alkylation
(85% yield) the o-disubsti-
using 1 equiv.
ester VIb (9) which was transformed
of VIc with 2 equiv.
by heating with 0.2 equiv.
Vd afforded
to Vb using benzyltrimethylammonium
ester Via with 1.3 equiv.
of dihydropyran
Treatment
using the bromide
acetyl cleavage
with 0.5 molar
the hydroxy malonic
using 1.5 equiv.
conversion
selective
and reaction
procedure
Q.
to form the corresponding
dihydroxy
ester VIIc (i),
with phosphorus
The
and
tribromide
in ether
at -5”. Slow addition (over 14 hr.) carbonyl
in N-methylpyrrolidone
isomeric
cyciization
0.08,
products
by tic analysis
ether,
1
at 47-50” under an atmosphere
of Ilf 0.45,
: 3 petroleum ether--ether,
Gf 0.08,
32% yield) consisted
orientation
of carboxyl
methylmagnesium m. p. 37 -38”.
bromide
preparatively 0.23, and 3
Reaction
afforded, n. m. r.
to 7 equiv.
of carbon monoxide
ether--ether
by column chromatography
and 0.08 were eluted respectively
Rf 0.45,
(3
of 0.23,
: 1) as’eluant.
of the mixture by 1
using the same
: 1 petroleum ether--
: 5 : 1 petroleum ether--ether--benzene.
The most polar fraction
by CA. 10% of the diastereomer
of the pure ester VIII (9, 12), obtained by preparative
after the usual isolation,
of nickel
led to a mixture
into three components,
gel with petroleum
of the ester VIII contaminated
at C*.
The infrared,
an authentic sample
nitrate on silica
were separated
The products
ester VIId in N-methylpyrrolidone
(total yield 83%) which was resolved
using 20% silver
These three materials adsorbent.
of the dibromo
85% yield of g-elemol
differing
(I) (13) as needles,
, and mass spectra of the synthetic product were identical with those of
(14) of natural elemol.
The cyclization
product from VIId of _Rf 0.23 (27% yield) was identified
Ma and IXb (differing
in orientation
of carboxyl).
Both isomers
as an 8
: 1 mixture of isomers
were obtained pure by preparative
gc (15).
The product from VIId of _Rf 0.45 (11% yield) was identified as the -_ cis, cis or -cis, trans isomer analytical
and spectroscopic
measurements
(9, 16) and the finding that thermolysis The g,
in the vapor phase yielded mainly IXa and IXb. structure periods
should afford VIII upon thermolysis of time and also the n. m. r. spectrum
In summary,
in
gc, with excess
the reaction
(8).
trans formulation
In addition,
the thermal
of X by
at 285” (minimum
temp.)
for X can be ruled out since this stability
of X at 100° for long
(8) argue against the -trans, trans geometry.
of the dibromide
VIId with nickel carbonyl
has afforded
a synthetic
route to
1782
g-elemol
No 22 ”
(I), but not to the isomeric
trans, trans-cyclodecadiene --
II (17).
REFERENCES 1.
See V. Sy’kora,
V. Herout,
and F. germ,
Collect.
Czech.
Chem.
Commun.
2. -
220 (1955) and earlier
papers therein cited. 2.
For absolute
configuration
see (a) T. G. Halsall,
D. W. Theobald,
1029 (1964) and (b) A. D. Wagh, S. K. Paknikar, 3.
L. J. Patil and A. S. Rao,
4.
All synthetic
5.
(a) E. J. Corey and E. Hamanaka,
J. Am.
Semmelhack,
6237 (1966).
6. 7. 8.
IO.
reported
Tetrahedron
Letters
II has been reported
Infrared
and n. m. r. spectra
Chem.
Sot.
This intermediate
agreement
was purified by preparative
centers
layer chromatography
by considerable
V-VII,
were not obtained for these liquids.
11.
W. Oro’shnik
12.
The following (calcd.,
analyses
and R. Mallory,
222.1620)
exhibited
(AEI-MS-9
absorption
n. m. r. spectrum methylene
at 5.75 (CO),
6.08
g,
(4 H, multiplet)
“hedycaryol,”
1229 (1968).
structure.
using silica
for this substance
possessing
Commun.
gel.
Since distillation
and also most of the products
4608 (1950).
C, 75.45;
H, 9.91;
molecular
ion at -m/e
222.1620
The infrared spectrum of VIII (CC14) H* 9.95 and 11.0 ( ,C=CH2), and 11.21 p (:C=CH2).
instrument).
(C=C),
at 4.50-5.02
at 3.62 and 1.01 ppm (3 H each),
ppm, and an olefinic
The
olefinic
methine proton (1 H, ABE quartet)
ppm.
Found for &I-I:
14.
The sample was kindly provided
15.
The following
C, 81.33;
H, 11. 95; molecular by Prof.
0.
infrared
C=CH2); n.m.r.
5.17 (m, 4 H, 2 C=CH2),
absorption absorption
6. W-6.60
Found for X:
C, 75. 99; H, 10.30;
17.
This work was generously
Jeger,
Zurich. C, 75.61;
(CC14) at 5.75
H, 9.97;
molecular
(C=O), 6.08 (C=C),
(q, 1 H, Cg=CH2).
9.95,
Satisfactory
analytical
ion at -m/e 10.92,
ion at -m/e
by the Hoffmann-La
222.1260
(calcd.,
Roche Co.
222.1620
and 11.22 p
3.63 (s, 3 H, CH3), 4.57and spectroscopic
of IXb.
molecular
supported
222.
(CC14) (in ppm) at 1.03 (s, 3 H, CH3),
were also obtained for the diastereomer 16.
ion at -m/e
Found:
data were obtained for Ma.
, 222.1620);
(CH=CH2,
Found:
double focusing
13.
(calcd.
Chem. Sot.
of VIII showed sharp methyl singlets
protons
at 5.50-6.03
J. Am.
decomposition
data were obtained for VIII.
were obtained as racemates.
Chem.
with the assigned
in vacua was accompanied -elemental
Sot.
2647 (1964).
86, 1641 (1964); (b) E. J. Corey and M. F. =
by R. V. H. Jones and M. D. Sutherland, were in excellent
20, -
2273 (1967).
herein which contain asymmetric
Letters
J. Chem.
Tetrahedron
E. J. Corey and E. Hamanaka, J. Am. Chem. Sot. 89, 2758 (1967). = E. J. Corey and E. K. W. Wat, --ibid. 89, 2757 (1967). Since completion of the present study the isolation of a new sesquiterpene, structure
9.
substances
Tetrahedron
and K. B. Walshaw,
and S. C. Bhattacharyya,
222.1260).
data
Pergamon Press.
1969,
Printed
in Great Britain.
TOTAL SYNTHESIS OF $-ELEMOL E. J. Corey and Emil A. Broger Department
of Chemistry,
Harvard University, ly69;
(Received in USA 27 lkr& Elemol
is a crystalline
this substance
is an indirect
note outlines
a direct
acteristic
sesquiterpenic preparation
synthesis
1,2-divinylcyclohexane
Cambridge,
received in UK for publication 9 April 1969) alcohol
of structure
from (-)a-santonin
of g-1
(4) which involves
closure
which has recently
8-,
allylic
formed
of d-
Although it
intermediate, direct
a novel method for the construction
process
of elemol
and c&-l,
carbocyclic
has previously
via e,
the effect of structure
to humulene synthesis
rings (5-7).
2-divinylcyclohexanes
The intermediate
trans-1,
(ratio 2
5-cyclodecadiene.
on the course
Of special
of the char-
relevance
(11-membered
ring formatio@
additional
required
to the appli-
S-decadiene
was trans-
: 1) by reaction with nickel carbonyl was not an
of trans-1,2-divinylcyclohexane
by a
This fact together with previous
of the nickel carbonyl
of the -trans, trans-cyclodecadiene
(I), and this provided
This
(3).
been used to effect ring
was the finding that l, lO-dibromo-2,
could not be made between the formation
and formation
could lead to a synthesis elemol
with nickel carbonyl
shown in the case of the -cis product that cis, trans-1,5-cyclodecadiene
a distinction
tions regarding application
was
dibromides
and 11- to 18-membered to the synthesis
(7).
been described
of
unit.
cation of this reaction into a mixture
synthesis
II
of acyclic
to form 6-,
The only recorded
I (1, 2).
I
The reaction
02138
Massachusetts
cyclization,
(6), made it seem possible
II, a probable
precursor
observa-
including the that this approach
of elemol
(8), as well as
incentive for this study.
for the cyclization
reaction,
1779
the dibromide
VIId, was synthesized
as
No . 22
I
mpoT III
dOOCH, IV
Va, U = Cl, V = CHQCOZ Vb, U = g-TolCOz,
V = CH3C02
Via,
Vc, U = o-TolC02,
V = OH
VIb, U=OH,
Vd, U = o-TolC02,
V = Br
VIc,
U = g-TolC02,
w = OTHP
W=OTHP
U=W=OTHP
COOCHQ COOCHQ
Vna,
W = OTHP,
VIIb, W=OTHP, VIIc,
X = CHO
VIII
X=H
W = OH, X = H
VIId, W = Br, X = H
\ P Ma,
:Rl
k2
R1 = COOCH3. R2 = H
Ixb, R1 = H, R2 = COOCH3
COOCHQ X
No.22
1781
The trans iodide III, prepared
follows. in acetone, 20
from the corresponding
was allowed to react with sodio dimethyl malonate
bromide
(6) by treatment with sodium iodide
in tetrahydrofuran--dimethylformamide
: 1) for 48 hr. at 40” (after an initial period of 1 hr. at 25”) to give IV (9, 10) in 85% yield.
the sodio derivative tuted malonic
of IV by a similar
ester Via (9, 10).
The bromide
butene (Va) (11) by the sequence: ethanol at 80” for 15 hr., 25” to form Vc,
the o-disubstituted afforded
malonic
hr. produced
Vd (9) was prepared
equiv.
tribromide
of sodium methoxide
(2 equiv. ) in
sodium hydroxide
in ether at 0”.
hydroxide
Treatment
in methanol--toluene
ether VIc (9)
(1
: 3) at -70” for 8
to produce VIIb (79% from VIc) (9)
at 100” under nitrogen for 0.5 hr.
mono ester VIIb was subjected
to acid hydrolysis
this was converted
ester VIId (9) (90% from VIIb) by reaction
of
acid catalyst.
hydride in pentane--toluene
without purification
at
in methanol at 25” for 10 hr.
into the bis-tetrahydropyranyl
in dioxane at 25” with a small amount of ptoluenesulfonic
the aldehyde VIIa which was deformylated
to dibromo
o-toluate
of phosphorus
of diisobutylaluminum
of
from 1-chloro-2-methyl-4-acetoxy-2-
of aqueous ethanolic
of potassium
Alkylation
(85% yield) the o-disubsti-
using 1 equiv.
ester VIb (9) which was transformed
of VIc with 2 equiv.
by heating with 0.2 equiv.
Vd afforded
to Vb using benzyltrimethylammonium
ester Via with 1.3 equiv.
of dihydropyran
Treatment
using the bromide
acetyl cleavage
with 0.5 molar
the hydroxy malonic
using 1.5 equiv.
conversion
selective
and reaction
procedure
Q.
to form the corresponding
dihydroxy
ester VIIc (i),
with phosphorus
The
and
tribromide
in ether
at -5”. Slow addition (over 14 hr.) carbonyl
in N-methylpyrrolidone
isomeric
cyciization
0.08,
products
by tic analysis
ether,
1
at 47-50” under an atmosphere
of Ilf 0.45,
: 3 petroleum ether--ether,
Gf 0.08,
32% yield) consisted
orientation
of carboxyl
methylmagnesium m. p. 37 -38”.
bromide
preparatively 0.23, and 3
Reaction
afforded, n. m. r.
to 7 equiv.
of carbon monoxide
ether--ether
by column chromatography
and 0.08 were eluted respectively
Rf 0.45,
(3
of 0.23,
: 1) as’eluant.
of the mixture by 1
using the same
: 1 petroleum ether--
: 5 : 1 petroleum ether--ether--benzene.
The most polar fraction
by CA. 10% of the diastereomer
of the pure ester VIII (9, 12), obtained by preparative
after the usual isolation,
of nickel
led to a mixture
into three components,
gel with petroleum
of the ester VIII contaminated
at C*.
The infrared,
an authentic sample
nitrate on silica
were separated
The products
ester VIId in N-methylpyrrolidone
(total yield 83%) which was resolved
using 20% silver
These three materials adsorbent.
of the dibromo
85% yield of g-elemol
differing
(I) (13) as needles,
, and mass spectra of the synthetic product were identical with those of
(14) of natural elemol.
The cyclization
product from VIId of _Rf 0.23 (27% yield) was identified
Ma and IXb (differing
in orientation
of carboxyl).
Both isomers
as an 8
: 1 mixture of isomers
were obtained pure by preparative
gc (15).
The product from VIId of _Rf 0.45 (11% yield) was identified as the -_ cis, cis or -cis, trans isomer analytical
and spectroscopic
measurements
(9, 16) and the finding that thermolysis The g,
in the vapor phase yielded mainly IXa and IXb. structure periods
should afford VIII upon thermolysis of time and also the n. m. r. spectrum
In summary,
in
gc, with excess
the reaction
(8).
trans formulation
In addition,
the thermal
of X by
at 285” (minimum
temp.)
for X can be ruled out since this stability
of X at 100° for long
(8) argue against the -trans, trans geometry.
of the dibromide
VIId with nickel carbonyl
has afforded
a synthetic
route to
1782
g-elemol
No 22 ”
(I), but not to the isomeric
trans, trans-cyclodecadiene --
II (17).
REFERENCES 1.
See V. Sy’kora,
V. Herout,
and F. germ,
Collect.
Czech.
Chem.
Commun.
2. -
220 (1955) and earlier
papers therein cited. 2.
For absolute
configuration
see (a) T. G. Halsall,
D. W. Theobald,
1029 (1964) and (b) A. D. Wagh, S. K. Paknikar, 3.
L. J. Patil and A. S. Rao,
4.
All synthetic
5.
(a) E. J. Corey and E. Hamanaka,
J. Am.
Semmelhack,
6237 (1966).
6. 7. 8.
IO.
reported
Tetrahedron
Letters
II has been reported
Infrared
and n. m. r. spectra
Chem.
Sot.
This intermediate
agreement
was purified by preparative
centers
layer chromatography
by considerable
V-VII,
were not obtained for these liquids.
11.
W. Oro’shnik
12.
The following (calcd.,
analyses
and R. Mallory,
222.1620)
exhibited
(AEI-MS-9
absorption
n. m. r. spectrum methylene
at 5.75 (CO),
6.08
g,
(4 H, multiplet)
“hedycaryol,”
1229 (1968).
structure.
using silica
for this substance
possessing
Commun.
gel.
Since distillation
and also most of the products
4608 (1950).
C, 75.45;
H, 9.91;
molecular
ion at -m/e
222.1620
The infrared spectrum of VIII (CC14) H* 9.95 and 11.0 ( ,C=CH2), and 11.21 p (:C=CH2).
instrument).
(C=C),
at 4.50-5.02
at 3.62 and 1.01 ppm (3 H each),
ppm, and an olefinic
The
olefinic
methine proton (1 H, ABE quartet)
ppm.
Found for &I-I:
14.
The sample was kindly provided
15.
The following
C, 81.33;
H, 11. 95; molecular by Prof.
0.
infrared
C=CH2); n.m.r.
5.17 (m, 4 H, 2 C=CH2),
absorption absorption
6. W-6.60
Found for X:
C, 75. 99; H, 10.30;
17.
This work was generously
Jeger,
Zurich. C, 75.61;
(CC14) at 5.75
H, 9.97;
molecular
(C=O), 6.08 (C=C),
(q, 1 H, Cg=CH2).
9.95,
Satisfactory
analytical
ion at -m/e 10.92,
ion at -m/e
by the Hoffmann-La
222.1260
(calcd.,
Roche Co.
222.1620
and 11.22 p
3.63 (s, 3 H, CH3), 4.57and spectroscopic
of IXb.
molecular
supported
222.
(CC14) (in ppm) at 1.03 (s, 3 H, CH3),
were also obtained for the diastereomer 16.
ion at -m/e
Found:
data were obtained for Ma.
, 222.1620);
(CH=CH2,
Found:
double focusing
13.
(calcd.
Chem. Sot.
of VIII showed sharp methyl singlets
protons
at 5.50-6.03
J. Am.
decomposition
data were obtained for VIII.
were obtained as racemates.
Chem.
with the assigned
in vacua was accompanied -elemental
Sot.
2647 (1964).
86, 1641 (1964); (b) E. J. Corey and M. F. =
by R. V. H. Jones and M. D. Sutherland, were in excellent
20, -
2273 (1967).
herein which contain asymmetric
Letters
J. Chem.
Tetrahedron
E. J. Corey and E. Hamanaka, J. Am. Chem. Sot. 89, 2758 (1967). = E. J. Corey and E. K. W. Wat, --ibid. 89, 2757 (1967). Since completion of the present study the isolation of a new sesquiterpene, structure
9.
substances
Tetrahedron
and K. B. Walshaw,
and S. C. Bhattacharyya,
222.1260).
data