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Synthesis of isocaryophyllene by titanium-induced keto ester cyclization.
Tetrahedron Letters,Vol.24,No.l8,pn Printed in C-reat Britain
SYNTHESIS
0040-4039/83/181885-04$03.00/C 01983 Pergamon Press Ltd.
lR85-1888,1383
OF ISOCARYOPHYLLENE
BY TITANIUM-INDUCED
and Dennis D. Miller
John E. MC Murry"
Department
KETO ESTER CYCLIZATION.
of Chemistry,
Cornell University,
Baker Laboratory
Ithaca, NY
14853
Abstract: A total synthesis of d,l isocaryophyllene is reported that employs the titanium-induced cyclization of a keto ester as the key step in forming the cyclononenone ring. The synthesis requires four steps starting from ethyl geranylacetate, and the key cyclization occurs in 38% yield. We have recently undergo reagent
discovered
an intramolecular 1
.
The method
to be of great value
W-i&,
We now wish to report nine-membered-ring
coupling
of cycloalkanone reaction
natural
isolated
double-bond
stereochemistry.
8 C-OEt
1. TiC1-JLiA1H4
J
2. H$+
four through
fourteen,
titanium
and promises
product,
>
of this new method
isocaryophyllene
from oil of cloves2,
differs
Both compounds
(1).
to the synthesis Isocaryophyllene,
from its isomer,
have been previously
\ -9
1
in which keto esters
with a low-valent
synthesis.
the application
hydrocarbon
synthesis
on treatment
works well on all ring sizes studied, in organic
8 R-C c
a new method
dicarbonyl
of the a sesquiterpene
caryophyllene
, only in
synthesized3.
\ -9.)
Isocar.yoohyllene
2 -*
lF85
Caryophyllene
1886
We began this work with the intention the intramolecular should
titanium-induced
it be successful,
unusual
carbocyclic
involved
would represent
ring system.
attempted
alkylations
of synthesizing
coupling
caryophyllene
an extraordinarily
Although
using,
of keto ester 2 to cyclononenone
our initial
as our key step,
6.
This coupling,
direct and simple approach
attempts
of 3,3_dimethylcyclobutanone,
at preparing
to this
keto ester 2
we soon found that 5 could be
synthesized
in two simple steps according to the route shown in the Scheme. Thus, cycloaddition 4. of dichloroketene with ethyl geranylacetate5 (3) led in 75% yield to the unstable dichlorocyclobutanone The cycloaddition
4, which was dechlorinated
proved
bond of ethyl geranylacetate; The cyclization
no isomeric
titanium
reagent
suspension
of Tic13
(728 mg, 4.72 mmol)
for 5 rain at room temperature,
slurry was refluxed
cyclobutanone
was prepared
by adding LiA1H4
triethylamine
mixture
addition
of 5 mL methanol
The filtrate
the formation
with brine, dried
on neutral
cm-l; 'H NMR (CDC13)
alumina
had occurred prepared
of natural
phosphorane
in DMSO solution 7 spectroscopic comparison . How does double-bond itself
cyclizations that occurs believe
diluted
titanium
product
and the
reagent.
titanium
3 h period of reflux.
with 10 mL ether,
filtered
through
quenched
Purification
occur?
of diketones,
Treatment
by IR (neat> 1695
that the isomerization
occurring
strain of the E double here is unique
experiment
studies
of the
step is a pinacol-type titanium
particles
reaction 8
.
Thus, we
reaction
and the double
bond is rigidly
held in close
when
the two ends of the keto ester molecule
by isomerization.
strained
that
double-bond
to come close enough to bond and deoxygenate
bond is relieved to the highly
mechanistic
sample by
the cyclization
Evidently,
of the metal.
but are unable
with an authentic
during
proximity
particle
sample of 1,
by analogy with our work on the related bond-forming
particle
to the surface
identical
on the surface of insoluble
is most likely
isomerization
with an authentic
and does not undergo
out detailed
we assume
that the carbon-carbon manner
215.6,
of z with methylenetriphenyl-
We have shown in a control
conditions
we have not carried
by
lead to 6, which could be converted
to find that double-bond
was identical
then gave isocaryophyllene,
keto ester cyclization,
slurry The
a small pad of Florisil.
(39 mg) in 38% yield;
of 5 would
the keto ester is bound to the titanium
observed
After
found 206.1666.
caryophyllene6.
isomerization
in a heterogeneous
to a titanium
of the low-valent
we were surprised
is stable to reaction
Although
isomerization. titanium-induced
(DME) under argon.
and concentrated.
Thus, our product
cyclization.
by degradation
caryophyllene
206.1671;
that the cyclization
by Wittig reaction,
during
A slurry of the
6 1.00 (s, 6 H), 1.70 (d, 3 H), 5.20 (m, 1 H); 13C NMR (CDC13)
we had assumed
into caryophyllene
(MgS04),
gave the cyclized
136.7, 124.0; MS calcd for C14H220, Although
manner:
(97 mg, 2.5 mmol) to a stirred
by an additional
and vacuum
and 5 mL water,
acid. double
were detected.
(0.35 mL, 2.5 mmol) was added,
was then cooled to ice temperature,
was washed
chromatography
in acetic
for the terminal
in 18 mL DME was slowly added to the refluxing
over a 16.5 h period via syringe pump, followed reaction
products
in the following
in 32 mL dimethoxyethane
for 1.5 h to complete
Keto ester 2 (127 mg, 0.50 mmol)
with zinc-copper
and stereoselective
of keto ester 2 was accomplished
low-valent
stirring
by treatment
to be both regioselective
caryophyllene
That the double-bond ring system
bind
until the
isomerization
is attested
to by the
1887
fact that we have never before observed 8 titanium-induced couplings . In summary,
we have demonstrated
used in the synthesis synthesis
such an isomerization
how our new method
of macrocarbocyclic
natural
in all our prior work with
of cycloalkanone
products.
preparation
We are continuing
can be
our work on the
of other such molecules.
Acknowledgment:
We wish to thank the donors of the Petroleum
Chemical
for their support
Society
of this work through
-A>
COOEt
Research
5
Cl
0
Cl
2
Fund of the American
grant No. 11879-ACl.
’
EtOOC
-4
b %
\ +cJ 0
Scheme.
Synthesis
z.
\
POC13, Zn-Cu, ether,
LiA1H4,
6
\ -YJ
-1
of Isocaryophyllene
(a) C13COC1, (c) TiC13,
d
0
75%;
Et3N, then H30t, 38%;
(b) Zn-Cu, HOAc, 61%; (d) Ph3P=CH2,
DMSO, 55%.
1888
References
1. 2.
J. E. Mc Murry
and D. D. Miller,
For a discussion
of early studies
D. H. R. Barton,
"The Terpenes,"
J. Am. Chem. Sot., in press, on caryophyllene
and isocaryophyllene,
Vol. III, Cambridge
University
see: J. Simonsen
Press, Cambridge,
and
England,
1952, pp. 39-75. 3.
Isocaryophyllene b) A. Kumar,
a) M. Bertrand
syntheses:
and J. -L. Gras, Tetrahedron,
A. Singh, and D. Devprabhakara,
D. Devprabhakara,
Synthesis,
461 (1976).
Tetrahedron
Caryophyllene
Lett.,
30,
793 (1974);
2177 (1976); c) A. Kumar and
synthesis:
E. J. Corey, R. B. Mitra,
and H. Uda, J. Am. Chem. Sot., 86, 485 (1964). 4.
L. R. Krepski
and A. Hassner,
5.
I. Kuwajima
6.
R. Kaiser
7.
The synthetic
and natural
spectroscopy,
and capillary
8.
We have previously
and Y. Doi, Tetrahedron
and D. Lamparsky,
dicarbonyl
coupling
isocaryophyllenes
reactions
evidence
in USA
28
1803 (1976).
were identical
by ir, 300 MHz nmr, mass
on a fused silica column
in support
occur on the surface of titanium
January
by other workers:
1983)
(180,000
plates),
of our belief that titanium-induced
K. L. Kees, and L. R. Krepski,
J. Org. Chem., ft_z,248 (1982).
(Received
1163 (1972).
gas chromatography
support has been presented
H. Geise,
Lett.,
Helv. Chim. Acta, 2,
presented
MC Murry, M. P. Fleming, Further
J. Org. Chem., 43, 2879 (1978).
particles.
J. Org. Chem., 2,
R. Dams, M. Malinowski,
See:
J. E.
2655 (1977). I. Westdorp,
and
SYNTHESIS
0040-4039/83/181885-04$03.00/C 01983 Pergamon Press Ltd.
lR85-1888,1383
OF ISOCARYOPHYLLENE
BY TITANIUM-INDUCED
and Dennis D. Miller
John E. MC Murry"
Department
KETO ESTER CYCLIZATION.
of Chemistry,
Cornell University,
Baker Laboratory
Ithaca, NY
14853
Abstract: A total synthesis of d,l isocaryophyllene is reported that employs the titanium-induced cyclization of a keto ester as the key step in forming the cyclononenone ring. The synthesis requires four steps starting from ethyl geranylacetate, and the key cyclization occurs in 38% yield. We have recently undergo reagent
discovered
an intramolecular 1
.
The method
to be of great value
W-i&,
We now wish to report nine-membered-ring
coupling
of cycloalkanone reaction
natural
isolated
double-bond
stereochemistry.
8 C-OEt
1. TiC1-JLiA1H4
J
2. H$+
four through
fourteen,
titanium
and promises
product,
>
of this new method
isocaryophyllene
from oil of cloves2,
differs
Both compounds
(1).
to the synthesis Isocaryophyllene,
from its isomer,
have been previously
\ -9
1
in which keto esters
with a low-valent
synthesis.
the application
hydrocarbon
synthesis
on treatment
works well on all ring sizes studied, in organic
8 R-C c
a new method
dicarbonyl
of the a sesquiterpene
caryophyllene
, only in
synthesized3.
\ -9.)
Isocar.yoohyllene
2 -*
lF85
Caryophyllene
1886
We began this work with the intention the intramolecular should
titanium-induced
it be successful,
unusual
carbocyclic
involved
would represent
ring system.
attempted
alkylations
of synthesizing
coupling
caryophyllene
an extraordinarily
Although
using,
of keto ester 2 to cyclononenone
our initial
as our key step,
6.
This coupling,
direct and simple approach
attempts
of 3,3_dimethylcyclobutanone,
at preparing
to this
keto ester 2
we soon found that 5 could be
synthesized
in two simple steps according to the route shown in the Scheme. Thus, cycloaddition 4. of dichloroketene with ethyl geranylacetate5 (3) led in 75% yield to the unstable dichlorocyclobutanone The cycloaddition
4, which was dechlorinated
proved
bond of ethyl geranylacetate; The cyclization
no isomeric
titanium
reagent
suspension
of Tic13
(728 mg, 4.72 mmol)
for 5 rain at room temperature,
slurry was refluxed
cyclobutanone
was prepared
by adding LiA1H4
triethylamine
mixture
addition
of 5 mL methanol
The filtrate
the formation
with brine, dried
on neutral
cm-l; 'H NMR (CDC13)
alumina
had occurred prepared
of natural
phosphorane
in DMSO solution 7 spectroscopic comparison . How does double-bond itself
cyclizations that occurs believe
diluted
titanium
product
and the
reagent.
titanium
3 h period of reflux.
with 10 mL ether,
filtered
through
quenched
Purification
occur?
of diketones,
Treatment
by IR (neat> 1695
that the isomerization
occurring
strain of the E double here is unique
experiment
studies
of the
step is a pinacol-type titanium
particles
reaction 8
.
Thus, we
reaction
and the double
bond is rigidly
held in close
when
the two ends of the keto ester molecule
by isomerization.
strained
that
double-bond
to come close enough to bond and deoxygenate
bond is relieved to the highly
mechanistic
sample by
the cyclization
Evidently,
of the metal.
but are unable
with an authentic
during
proximity
particle
sample of 1,
by analogy with our work on the related bond-forming
particle
to the surface
identical
on the surface of insoluble
is most likely
isomerization
with an authentic
and does not undergo
out detailed
we assume
that the carbon-carbon manner
215.6,
of z with methylenetriphenyl-
We have shown in a control
conditions
we have not carried
by
lead to 6, which could be converted
to find that double-bond
was identical
then gave isocaryophyllene,
keto ester cyclization,
slurry The
a small pad of Florisil.
(39 mg) in 38% yield;
of 5 would
the keto ester is bound to the titanium
observed
After
found 206.1666.
caryophyllene6.
isomerization
in a heterogeneous
to a titanium
of the low-valent
we were surprised
is stable to reaction
Although
isomerization. titanium-induced
(DME) under argon.
and concentrated.
Thus, our product
cyclization.
by degradation
caryophyllene
206.1671;
that the cyclization
by Wittig reaction,
during
A slurry of the
6 1.00 (s, 6 H), 1.70 (d, 3 H), 5.20 (m, 1 H); 13C NMR (CDC13)
we had assumed
into caryophyllene
(MgS04),
gave the cyclized
136.7, 124.0; MS calcd for C14H220, Although
manner:
(97 mg, 2.5 mmol) to a stirred
by an additional
and vacuum
and 5 mL water,
acid. double
were detected.
(0.35 mL, 2.5 mmol) was added,
was then cooled to ice temperature,
was washed
chromatography
in acetic
for the terminal
in 18 mL DME was slowly added to the refluxing
over a 16.5 h period via syringe pump, followed reaction
products
in the following
in 32 mL dimethoxyethane
for 1.5 h to complete
Keto ester 2 (127 mg, 0.50 mmol)
with zinc-copper
and stereoselective
of keto ester 2 was accomplished
low-valent
stirring
by treatment
to be both regioselective
caryophyllene
That the double-bond ring system
bind
until the
isomerization
is attested
to by the
1887
fact that we have never before observed 8 titanium-induced couplings . In summary,
we have demonstrated
used in the synthesis synthesis
such an isomerization
how our new method
of macrocarbocyclic
natural
in all our prior work with
of cycloalkanone
products.
preparation
We are continuing
can be
our work on the
of other such molecules.
Acknowledgment:
We wish to thank the donors of the Petroleum
Chemical
for their support
Society
of this work through
-A>
COOEt
Research
5
Cl
0
Cl
2
Fund of the American
grant No. 11879-ACl.
’
EtOOC
-4
b %
\ +cJ 0
Scheme.
Synthesis
z.
\
POC13, Zn-Cu, ether,
LiA1H4,
6
\ -YJ
-1
of Isocaryophyllene
(a) C13COC1, (c) TiC13,
d
0
75%;
Et3N, then H30t, 38%;
(b) Zn-Cu, HOAc, 61%; (d) Ph3P=CH2,
DMSO, 55%.
1888
References
1. 2.
J. E. Mc Murry
and D. D. Miller,
For a discussion
of early studies
D. H. R. Barton,
"The Terpenes,"
J. Am. Chem. Sot., in press, on caryophyllene
and isocaryophyllene,
Vol. III, Cambridge
University
see: J. Simonsen
Press, Cambridge,
and
England,
1952, pp. 39-75. 3.
Isocaryophyllene b) A. Kumar,
a) M. Bertrand
syntheses:
and J. -L. Gras, Tetrahedron,
A. Singh, and D. Devprabhakara,
D. Devprabhakara,
Synthesis,
461 (1976).
Tetrahedron
Caryophyllene
Lett.,
30,
793 (1974);
2177 (1976); c) A. Kumar and
synthesis:
E. J. Corey, R. B. Mitra,
and H. Uda, J. Am. Chem. Sot., 86, 485 (1964). 4.
L. R. Krepski
and A. Hassner,
5.
I. Kuwajima
6.
R. Kaiser
7.
The synthetic
and natural
spectroscopy,
and capillary
8.
We have previously
and Y. Doi, Tetrahedron
and D. Lamparsky,
dicarbonyl
coupling
isocaryophyllenes
reactions
evidence
in USA
28
1803 (1976).
were identical
by ir, 300 MHz nmr, mass
on a fused silica column
in support
occur on the surface of titanium
January
by other workers:
1983)
(180,000
plates),
of our belief that titanium-induced
K. L. Kees, and L. R. Krepski,
J. Org. Chem., ft_z,248 (1982).
(Received
1163 (1972).
gas chromatography
support has been presented
H. Geise,
Lett.,
Helv. Chim. Acta, 2,
presented
MC Murry, M. P. Fleming, Further
J. Org. Chem., 43, 2879 (1978).
particles.
J. Org. Chem., 2,
R. Dams, M. Malinowski,
See:
J. E.
2655 (1977). I. Westdorp,
and