- Email: [email protected]
Intramolecular formal iron-catalyzed ene reactions: The stereoselective and regiocontrolled formation of substituted tetrahydropyrans
Tetrahedron Letters,Vo1.28,No.46,pp Printed in Great Britain
INTRAMOLECULAR
FORMAL
5627-5630,1987
IRON-CATALYZED
REGIOCONTROLLED
ENE REACTIONS:
FORMATION
0040-4039/87 $3.00 + .OO Perqamon Journals Ltd.
THE STEREOSELECTIVE
OF SUBSTITUTED
AND
TETRAHYDROPYRANS
James M. Takacs*, Lawrence G. Anderson, Mark W. Creswell, and Beckie E. Takacs' Department
of Chemistry,
University
of Utah, Salt Lake City, Utah 84112
SUmARY: The iron-catalyzed six-membered ring carbocyclizations of 5-oxa-2,8,10-undecatriene derivatives proceed with high regio- and stereoselectivity to yield trans-3,4-disubstituted tetrahydropyrans. Substrates containing an alkyl substituent at the 4- or the 7-position of the starting triene ether cyclize with high secondary stereoinduction to produce trans,transtrisubstituted derivatives. Diastereomeric (X)- and (.X)-substrates cyclize via complementary [4+4]- and [4+2]-ene reaction pathways.
Transition-metal
mediated
carbocyclization
reactions
are providing
the synthetic
chemist
with an increasingly versatile array of methodologies for the construction 2 ring systems. We have recently reported the bpy*Fe(O) catalyzed carbocyclizations (2E,7!)-,
and (22,7E)-2,7,9-decatrien-l-01
disubstituted
cyclopentanes,
cyclizations
proceed
iron mediated
functionality
within
Treatment iron-catalyzed
to yield
3-8h).
mixture
formation
benzene,
through
is treated
pyran
of substituted
are formed.
2.
with greater
under standard a formal
[4+4I-
Upon complete
ethylene
glycol
to remove
(cat. TsOH,
by flash chromatography
analysis
of the crude acetal
than 5O:l trans simple dias-
pyrans
While additional
5627
the cyclizations
(1:l EtOAc-hexanes)
pyran 3a is isolated
gas chromatographic
proceeds
catalyst
ethers
Florisil
of our of additional
tetrahydropyrans.
25"C, 7h), effects
with excess
Less than 1% of any cis-substituted
trans-substituted
in scope to the construc-
the applicability
this end we have investigated
of cis- and trans-enol is filtered
capillary
shows that the cyclization
are limited
la with the bpy*Fe(O)
The trans-3,4-disubstituted Careful
[4+4]-ene
ring sizes and to the incorporation
ether
and the crude product
yield.5
tereoselectivity. isomeric
mixture
iron catalyzed
in examining
(10 mol% bpy*Fe(O)
a mixture
the reaction
in 84% overall
substrates
Toward
of
and c-1,2-
followed by the regioselective 4 Since many transition to the diene moiety.
to the stereoselective
ene conditions
the iron catalyst THF, 25X,
the ring system.
leading
rise to c-
bond formation
interested
of other
of the (21,8E)-triene
ene cyclization
hydrogen
of acyclic
rings, we were
to the construction
of triene ethers
cyclization,
of an allylic
carbocyclizations
tion of five-membered methodology
These formal
respectively.3
via initial carbon-carbon
transfer
metal mediated
ethers giving
organic
of common
and less than 1.5% of an alkyl substituents
on the
5628
diene moiety
tend to slow down the rate of the iron-catalyzed
methyl-triene
ether
the trans-pyran
lb cyclizes
readily
3b in 57% isolated
under the influence
yield
and greater
OCH,Ph R
(R I CH,)
10 mol% bpy Fe(O)
H
*
/eq 1)
3a (R = H) 3b (R = CH,)
new strategies
is an important
goal
(2?,8E)-triene
substituent
stereochemical
adjacent
bias toward
be expected
acetalization
of transition
ethers
secondary
over the trans,cis-diastereomer 5b in 68% overall
yield
Tt?ANS:CIS
of stereochemistry bond constructions.
could
cyclization-
simple diastereoselectivity of the crude acetal mix-
pyran 5a is formed with a minimum
The 7,10-dimethyl
a
substituent
the iron-catalyzed
gc analysis
and in greater
6
impose a significant
While a simple methyl
Careful
6.
>98:2
in order to test whether
64% yield with excellent
stereoinduction.
ture shows that the __trans,trans-3,4,5_trisubstituted trans,trans-pyran --
moiety
diastereodifferentiation,
in overall
control
metal catalyzed
4 were prepared
to the 8,10-diene
to impose minimal
LJIASTEREOSELECTIVITY
and predictable
attack on the diene system.
of 4a proceeds
and with excellent
for the efficient
in the investigations
substituted
non-chelating
preference
H
cat TsOH / THF
2
Uncovering
might
to give
HOCH,CH,OH >
SIMPLE
The 7-methyl
catalyst
R
PhH I25”C / 3-8h
(R = H)
of the bpy*Fe(O)
than 96% isomeric purity.
R
H
la
the (21,8E)-lo-
OCH,Ph H
lb
ene reaction,
analogue
than 95% isomeric
4b yields
7O:l
the
purity.
OCH,Ph
I
1
10 mol% bpy Fe(O) PhH/25’C/Bh
2. HOCH,CH,OH,
*
lH$’
+
(eq 2)
4a
(R = H)
5a
(R = H)
4b
(R = CH,)
5b
(R = CH,)
SECONDARY
Similar
results
the (2Z)-olefin overall)
are observed
functionality.
stereochemistry
between
6
STEREOlNDLJCTlON
when a non-chelating
The 4-ethyl
TRANS,TRANS-:TRANS,CIS
is incorporated
(2Z,8E)-triene pyran 8 in which
the three contiguous
stereogenic
Preliminary
applying
studies,
>70:1
substituent
substituted
to give the -trans,trans-2,3,4_trisubstituted
than 3O:l selectivity.
;z&--
H+
centers
molecular
ether
adjacent
7 cyclizes
(60%
the relative
is controlled modelling
with greater
techniques
to
to
5629
evaluate
the steric/strain
in each case cyclization
energies
of the relevant
has proceeded
metallacyclic
intermediates,
suggest
via the most stable of the diastereomeric
that
metallacycles.
OCH,Ph H 1. 10 mol% bpy Fe(O) PhH/25”C/Bh * 2. HOCH,CH,OH
@I
/ H+
7
9 SECONDARY
Considering
the mechanism
clear that the cyclizations proceed
via the initial
mediates. derived
(2!,8E)-triene
formation
1.
Hence,
product
ene cyclization,4
diastereomeric
triene
products
11.
10 cyclizes
only with respect
the regioselective
TFlANS,TRANS-:ClS,TRANS-
and (EL)-triene
are indeed borne out.
w-substituted
[4+2]-ene
12 and 13 differ
iron catalyzed
(21)-triene
of non-interconvertible
speculations
12, while
>30:1
that 10 might give rise to a product
exclusively
formal
trans,exo-metallacycle -diastereomers
These
10 yields
is the regioisomeric
o-bond.
of the intramolecular
Hence, we anticipated
from triene
9 STEREOINDUCTION
of the diastereomeric
Cyclization
metallacyclic
While cyclization (61% overall),
of la proceeds
to the stereochemistry observed
must
inter-
isomeric with that of the
the major
isomer
via intermediate
via the trans,endo-intermediate
C-H bond formation
it is
substrates
13.
The
about the iron-carbon
in the intramolecular
iron-
1. 10 mol% L Fe(O) PhH/25T/8h 2
10
HOCH,CH,OH
i H+
11
REGIOSELECTIYITY:
la
-
3)
3a
L I
bipyridine
94:
L I
pyridine
15
6
:
85
by Fe(O) -
W W’J)
10
5630
catalyzed
ene cyclization
alkoxymethyl
moiety,
is apparently
which
In the bimolecular had observed
that both between
For example,
the bpy*Fe(O)
pyr*Fe(O)
dependency
catalyst
la,
catalyst,
these conditions
cyclizations product,
catalyst
catalyst
based upon recovered the pyrBFe(0) under
[4+2]- and [4+4]-ene
proceeding
products
reaction
modes of la and 10.
preference
for the [4+4]-ene
REFERENCES
AND NOTES
cyclization
selectivity
upon the choice distribution,
of the (2!,8E)-triene
the regioselectivity.
in a ]4+2]-ene
la
3a (50% overall 10 with
The major product ratio.
13 can give rise to a ]4+2]-ene
reaction
the ligand
of the (ZL,8E)-triene to yield
for
of ligand.
while the
investigated
3a, formed in a 15:85 11:3a
via the endo-diastereomer ligand directs
Treatment
Treatment
changes
product
product
regioselgctivity
purity).
dramatically
is the [4+4]-ene
and the bipyridine
dependent
We have, therefore,
with unchanged
98% diastereomeric however,
The kinetic
were formed.'
]4+2]:]4+4]
gave a 6:94 mixture.
proceeds
of the
of isoprene with ally1 benzyl ether, we
modes was strongly
gave a 73:27
orientation
donor
ene reactions
these two reaction
of the [4+2]:[4+43
with the pyr*Fe(O)
as the B-hydride
iron-catalyzed
partitioning
analogous
serves
exo/endo of the --
a consequence
Thus, only cyclization
sense overcoming
an inherent
mode.
1. Financial support from the NIH (GM-34927) is gratefully acknowledged. High-field NMR spectra were obtained using 300 MHz instruments purchased with grants from the NSF and DOD. Molecular modelling was carried out using equipment purchased with a grant from the NIH. 2. a. b. c. d. e. f. g. h. i.
Trost, B.M.; MacPherson, D.T. J. Amer. Chem. Sot. 1987, 109, 3483-3484; Nugent, W.A.; Thorn, D.L.; Harlow, R.L. J. Amer. Chem. Sot. 1987, 109, 2788-2796; Wender, P.A.; Snapper, M.L. Tetrahedron Lett. 1987, 28, 2221-2224; Magnus, P.; Principe, L.M.; Slater, M.J. J. Org. Chem. 1987, 52, 1483-1486; Tsada, T.; Sumiya, R.; Saegusa, T. Synth. Commun. 1987, lJ, 147-154; Taber, D.F.; Raman, K.; Gaul, M.D. J. Org. Chem. 1987, 52, 28-34; Negishi, E. Accts. Chem. Res. 1987, 20, 65-72; Hayes, T.K.; Freyer, A.J.; Parvez, M.; Weinreb, S.M. J. Org. Chem. 1986, 51, 5501; Snider, B.B.; Mohan, R.; Kates, S.A. J. Org. Chem. 1985, 50, 3659-3661.
3. Takacs, J-M.; 4. Takacs, J.M.; Organometallics
Anderson,
L.G. J. Amer. Chem. Sot. 1987,
Anderson, L.G.; Madhavan, 1986, 5, 2395-2398.
G.V.B.;
109,
Creswell,
2200-2202.
M.W.; Seely,
F.L.; Devroy,
W.F.
5. The stereochemical assignments of compounds 3, 5, 8, and 11 are consistent with coupling constant analysis of the vicinal hydrogens at 300 MHz. For example, the trans stereochemistry in compound 3a was assigned based upon the observed 9.2 Hz coupling constant between the ring of methine hydrogens (determined by series of decoupling experiments), consistent with the trans diaxial relationship: 3a (300 MHz, CDCl,) 6 5.45 ppm (dq, lH, J = 11.0, 6.8 Hz, CH=CHCH,), 5.15 (ddq, lH, J = 9.0, 11.0, 1.7 Hz, CH=CHCH,), 4.83 (dd, lH, J = 4.8, 4.8 Hz, CH(OR),), 4.14 (dd, lH, J = 4.5, 11.2 Hz, ROCtI,(e)CHR), 3.92 (m, 3H, OCH,Cti,O and 0CH2CHZCH), 3.81 (m, 2H, OCH,C&O), 3.40 (m, lH, 0CH2CH2CH), 3.09 (dd, lH, J = 11.1, 11.2 tlz, OCH,(a)CHR), 2.21 (m, lH, CH=CHCH), 1.79 (ddd, ZH, J = 2.9, 4.8, 13.8 Hz, Cli,CH(OR),), 1.7-1.6 (lH, CHCH,CH(OR),) overlapping with 1.61 (dd, 3H, J = 1.7, 6.8 Hz, CH=CH-CHJ), 1.51 (m, 2H, CH2CH,0), and 1.26 (ddd, lH, J = 4.8, 9.7, 13.8 Hz, CH,CH(OR),). 6. a. Brown, J.M. Angew. Chem. Int. Ed. Engl. 1987, 26, 190-203; b. Apsimon, J.W.; Collier, T.L. Tetrahedron 1986, 42, 5157-5254. 7. Takacs,
J.M.; Anderson,
(Received
in USA
L.G.; Madhavan,
8 July
1987)
G.V.B.;
Seely,
F.L. Anqew.
Chem.,
in press.
INTRAMOLECULAR
FORMAL
5627-5630,1987
IRON-CATALYZED
REGIOCONTROLLED
ENE REACTIONS:
FORMATION
0040-4039/87 $3.00 + .OO Perqamon Journals Ltd.
THE STEREOSELECTIVE
OF SUBSTITUTED
AND
TETRAHYDROPYRANS
James M. Takacs*, Lawrence G. Anderson, Mark W. Creswell, and Beckie E. Takacs' Department
of Chemistry,
University
of Utah, Salt Lake City, Utah 84112
SUmARY: The iron-catalyzed six-membered ring carbocyclizations of 5-oxa-2,8,10-undecatriene derivatives proceed with high regio- and stereoselectivity to yield trans-3,4-disubstituted tetrahydropyrans. Substrates containing an alkyl substituent at the 4- or the 7-position of the starting triene ether cyclize with high secondary stereoinduction to produce trans,transtrisubstituted derivatives. Diastereomeric (X)- and (.X)-substrates cyclize via complementary [4+4]- and [4+2]-ene reaction pathways.
Transition-metal
mediated
carbocyclization
reactions
are providing
the synthetic
chemist
with an increasingly versatile array of methodologies for the construction 2 ring systems. We have recently reported the bpy*Fe(O) catalyzed carbocyclizations (2E,7!)-,
and (22,7E)-2,7,9-decatrien-l-01
disubstituted
cyclopentanes,
cyclizations
proceed
iron mediated
functionality
within
Treatment iron-catalyzed
to yield
3-8h).
mixture
formation
benzene,
through
is treated
pyran
of substituted
are formed.
2.
with greater
under standard a formal
[4+4I-
Upon complete
ethylene
glycol
to remove
(cat. TsOH,
by flash chromatography
analysis
of the crude acetal
than 5O:l trans simple dias-
pyrans
While additional
5627
the cyclizations
(1:l EtOAc-hexanes)
pyran 3a is isolated
gas chromatographic
proceeds
catalyst
ethers
Florisil
of our of additional
tetrahydropyrans.
25"C, 7h), effects
with excess
Less than 1% of any cis-substituted
trans-substituted
in scope to the construc-
the applicability
this end we have investigated
of cis- and trans-enol is filtered
capillary
shows that the cyclization
are limited
la with the bpy*Fe(O)
The trans-3,4-disubstituted Careful
[4+4]-ene
ring sizes and to the incorporation
ether
and the crude product
yield.5
tereoselectivity. isomeric
mixture
iron catalyzed
in examining
(10 mol% bpy*Fe(O)
a mixture
the reaction
in 84% overall
substrates
Toward
of
and c-1,2-
followed by the regioselective 4 Since many transition to the diene moiety.
to the stereoselective
ene conditions
the iron catalyst THF, 25X,
the ring system.
leading
rise to c-
bond formation
interested
of other
of the (21,8E)-triene
ene cyclization
hydrogen
of acyclic
rings, we were
to the construction
of triene ethers
cyclization,
of an allylic
carbocyclizations
tion of five-membered methodology
These formal
respectively.3
via initial carbon-carbon
transfer
metal mediated
ethers giving
organic
of common
and less than 1.5% of an alkyl substituents
on the
5628
diene moiety
tend to slow down the rate of the iron-catalyzed
methyl-triene
ether
the trans-pyran
lb cyclizes
readily
3b in 57% isolated
under the influence
yield
and greater
OCH,Ph R
(R I CH,)
10 mol% bpy Fe(O)
H
*
/eq 1)
3a (R = H) 3b (R = CH,)
new strategies
is an important
goal
(2?,8E)-triene
substituent
stereochemical
adjacent
bias toward
be expected
acetalization
of transition
ethers
secondary
over the trans,cis-diastereomer 5b in 68% overall
yield
Tt?ANS:CIS
of stereochemistry bond constructions.
could
cyclization-
simple diastereoselectivity of the crude acetal mix-
pyran 5a is formed with a minimum
The 7,10-dimethyl
a
substituent
the iron-catalyzed
gc analysis
and in greater
6
impose a significant
While a simple methyl
Careful
6.
>98:2
in order to test whether
64% yield with excellent
stereoinduction.
ture shows that the __trans,trans-3,4,5_trisubstituted trans,trans-pyran --
moiety
diastereodifferentiation,
in overall
control
metal catalyzed
4 were prepared
to the 8,10-diene
to impose minimal
LJIASTEREOSELECTIVITY
and predictable
attack on the diene system.
of 4a proceeds
and with excellent
for the efficient
in the investigations
substituted
non-chelating
preference
H
cat TsOH / THF
2
Uncovering
might
to give
HOCH,CH,OH >
SIMPLE
The 7-methyl
catalyst
R
PhH I25”C / 3-8h
(R = H)
of the bpy*Fe(O)
than 96% isomeric purity.
R
H
la
the (21,8E)-lo-
OCH,Ph H
lb
ene reaction,
analogue
than 95% isomeric
4b yields
7O:l
the
purity.
OCH,Ph
I
1
10 mol% bpy Fe(O) PhH/25’C/Bh
2. HOCH,CH,OH,
*
lH$’
+
(eq 2)
4a
(R = H)
5a
(R = H)
4b
(R = CH,)
5b
(R = CH,)
SECONDARY
Similar
results
the (2Z)-olefin overall)
are observed
functionality.
stereochemistry
between
6
STEREOlNDLJCTlON
when a non-chelating
The 4-ethyl
TRANS,TRANS-:TRANS,CIS
is incorporated
(2Z,8E)-triene pyran 8 in which
the three contiguous
stereogenic
Preliminary
applying
studies,
>70:1
substituent
substituted
to give the -trans,trans-2,3,4_trisubstituted
than 3O:l selectivity.
;z&--
H+
centers
molecular
ether
adjacent
7 cyclizes
(60%
the relative
is controlled modelling
with greater
techniques
to
to
5629
evaluate
the steric/strain
in each case cyclization
energies
of the relevant
has proceeded
metallacyclic
intermediates,
suggest
via the most stable of the diastereomeric
that
metallacycles.
OCH,Ph H 1. 10 mol% bpy Fe(O) PhH/25”C/Bh * 2. HOCH,CH,OH
@I
/ H+
7
9 SECONDARY
Considering
the mechanism
clear that the cyclizations proceed
via the initial
mediates. derived
(2!,8E)-triene
formation
1.
Hence,
product
ene cyclization,4
diastereomeric
triene
products
11.
10 cyclizes
only with respect
the regioselective
TFlANS,TRANS-:ClS,TRANS-
and (EL)-triene
are indeed borne out.
w-substituted
[4+2]-ene
12 and 13 differ
iron catalyzed
(21)-triene
of non-interconvertible
speculations
12, while
>30:1
that 10 might give rise to a product
exclusively
formal
trans,exo-metallacycle -diastereomers
These
10 yields
is the regioisomeric
o-bond.
of the intramolecular
Hence, we anticipated
from triene
9 STEREOINDUCTION
of the diastereomeric
Cyclization
metallacyclic
While cyclization (61% overall),
of la proceeds
to the stereochemistry observed
must
inter-
isomeric with that of the
the major
isomer
via intermediate
via the trans,endo-intermediate
C-H bond formation
it is
substrates
13.
The
about the iron-carbon
in the intramolecular
iron-
1. 10 mol% L Fe(O) PhH/25T/8h 2
10
HOCH,CH,OH
i H+
11
REGIOSELECTIYITY:
la
-
3)
3a
L I
bipyridine
94:
L I
pyridine
15
6
:
85
by Fe(O) -
W W’J)
10
5630
catalyzed
ene cyclization
alkoxymethyl
moiety,
is apparently
which
In the bimolecular had observed
that both between
For example,
the bpy*Fe(O)
pyr*Fe(O)
dependency
catalyst
la,
catalyst,
these conditions
cyclizations product,
catalyst
catalyst
based upon recovered the pyrBFe(0) under
[4+2]- and [4+4]-ene
proceeding
products
reaction
modes of la and 10.
preference
for the [4+4]-ene
REFERENCES
AND NOTES
cyclization
selectivity
upon the choice distribution,
of the (2!,8E)-triene
the regioselectivity.
in a ]4+2]-ene
la
3a (50% overall 10 with
The major product ratio.
13 can give rise to a ]4+2]-ene
reaction
the ligand
of the (ZL,8E)-triene to yield
for
of ligand.
while the
investigated
3a, formed in a 15:85 11:3a
via the endo-diastereomer ligand directs
Treatment
Treatment
changes
product
product
regioselgctivity
purity).
dramatically
is the [4+4]-ene
and the bipyridine
dependent
We have, therefore,
with unchanged
98% diastereomeric however,
The kinetic
were formed.'
]4+2]:]4+4]
gave a 6:94 mixture.
proceeds
of the
of isoprene with ally1 benzyl ether, we
modes was strongly
gave a 73:27
orientation
donor
ene reactions
these two reaction
of the [4+2]:[4+43
with the pyr*Fe(O)
as the B-hydride
iron-catalyzed
partitioning
analogous
serves
exo/endo of the --
a consequence
Thus, only cyclization
sense overcoming
an inherent
mode.
1. Financial support from the NIH (GM-34927) is gratefully acknowledged. High-field NMR spectra were obtained using 300 MHz instruments purchased with grants from the NSF and DOD. Molecular modelling was carried out using equipment purchased with a grant from the NIH. 2. a. b. c. d. e. f. g. h. i.
Trost, B.M.; MacPherson, D.T. J. Amer. Chem. Sot. 1987, 109, 3483-3484; Nugent, W.A.; Thorn, D.L.; Harlow, R.L. J. Amer. Chem. Sot. 1987, 109, 2788-2796; Wender, P.A.; Snapper, M.L. Tetrahedron Lett. 1987, 28, 2221-2224; Magnus, P.; Principe, L.M.; Slater, M.J. J. Org. Chem. 1987, 52, 1483-1486; Tsada, T.; Sumiya, R.; Saegusa, T. Synth. Commun. 1987, lJ, 147-154; Taber, D.F.; Raman, K.; Gaul, M.D. J. Org. Chem. 1987, 52, 28-34; Negishi, E. Accts. Chem. Res. 1987, 20, 65-72; Hayes, T.K.; Freyer, A.J.; Parvez, M.; Weinreb, S.M. J. Org. Chem. 1986, 51, 5501; Snider, B.B.; Mohan, R.; Kates, S.A. J. Org. Chem. 1985, 50, 3659-3661.
3. Takacs, J-M.; 4. Takacs, J.M.; Organometallics
Anderson,
L.G. J. Amer. Chem. Sot. 1987,
Anderson, L.G.; Madhavan, 1986, 5, 2395-2398.
G.V.B.;
109,
Creswell,
2200-2202.
M.W.; Seely,
F.L.; Devroy,
W.F.
5. The stereochemical assignments of compounds 3, 5, 8, and 11 are consistent with coupling constant analysis of the vicinal hydrogens at 300 MHz. For example, the trans stereochemistry in compound 3a was assigned based upon the observed 9.2 Hz coupling constant between the ring of methine hydrogens (determined by series of decoupling experiments), consistent with the trans diaxial relationship: 3a (300 MHz, CDCl,) 6 5.45 ppm (dq, lH, J = 11.0, 6.8 Hz, CH=CHCH,), 5.15 (ddq, lH, J = 9.0, 11.0, 1.7 Hz, CH=CHCH,), 4.83 (dd, lH, J = 4.8, 4.8 Hz, CH(OR),), 4.14 (dd, lH, J = 4.5, 11.2 Hz, ROCtI,(e)CHR), 3.92 (m, 3H, OCH,Cti,O and 0CH2CHZCH), 3.81 (m, 2H, OCH,C&O), 3.40 (m, lH, 0CH2CH2CH), 3.09 (dd, lH, J = 11.1, 11.2 tlz, OCH,(a)CHR), 2.21 (m, lH, CH=CHCH), 1.79 (ddd, ZH, J = 2.9, 4.8, 13.8 Hz, Cli,CH(OR),), 1.7-1.6 (lH, CHCH,CH(OR),) overlapping with 1.61 (dd, 3H, J = 1.7, 6.8 Hz, CH=CH-CHJ), 1.51 (m, 2H, CH2CH,0), and 1.26 (ddd, lH, J = 4.8, 9.7, 13.8 Hz, CH,CH(OR),). 6. a. Brown, J.M. Angew. Chem. Int. Ed. Engl. 1987, 26, 190-203; b. Apsimon, J.W.; Collier, T.L. Tetrahedron 1986, 42, 5157-5254. 7. Takacs,
J.M.; Anderson,
(Received
in USA
L.G.; Madhavan,
8 July
1987)
G.V.B.;
Seely,
F.L. Anqew.
Chem.,
in press.