Titanium Alkoxide-Based Regioselective Alkyne-Alkyne Reductive Coupling Mediated by in Situ Generated Arylamidate

Article abstract of DOI:10.1021/jacs.0c00550

Titanium alkoxide-based alkyne-alkyne reductive coupling mediated by in situ generated arylamidate is described. A high level of regioselectivity is achieved in 37 examples, where (E,E)-dienes are exclusively formed. To the best of our knowledge, this stu

Full text of DOI:10.1021/jacs.0c00550

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Communication
Titanium Alkoxide-Based Regioselective Alkyne-Alkyne
Reductive Coupling Mediated by in situ Generated Arylamidate
Bin Cai, and James S. Panek
J. Am. Chem. Soc., Just Accepted Manuscript • DOI: 10.1021/jacs.0c00550 • Publication Date (Web): 12 Feb 2020
Downloaded from pubs.acs.org on February 17, 2020
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Journal of the American Chemical Society
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Titanium Alkoxide-Based Regioselective Alkyne-Alkyne Reductive
Coupling Mediated by in situ Generated Arylamidate
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Bin Cai and James S. Panek*
Department of Chemistry, Metcalf Center for Science and Engineering, Boston University, 590 Commonwealth Avenue,
Boston, Massachusetts 02215, United States
Supporting Information Placeholder
developed over the past decades. These strategies include steric
differentiation,² π conjugation,³ and directed carbometalation,⁴
and have been actively implemented by research groups including
Sato,^2,5 Buchwald,⁶ Montgomery,⁷ Krische,⁸ Jamison,^3,9 and
Micalizio^1f-h,4,10 (Scheme 1A and 1B). Among these strategies,
substrate-directed transformations¹¹ enable the formation of
highly organized transition states or intermediates through the
association of a reagent with the substrate. The resulting
conformationally rigid systems allow selective reactions, enabling
useful levels of regioselectivity. The atom-economy and
remarkable convergency provided by this strategy has been
demonstrated by its application in several elegant total synthesis
of natural products and complex molecules.¹² However, the use of
in situ generated alkoxide was the only directing group strategy
realized in the context of titanium-mediated reductive coupling.
Underdevelopment limited the substrate scope for this
transformation and subsequent applications, but allows for
discovery and development of an alternative directing-group
strategy.⁴
ABSTRACT:
A
titanium alkoxide-based alkyne-alkyne
reductive coupling mediated by in situ generated arylamidate is
described. High level of regioselectivity is achieved in 37
examples, where (E,E)-dienes are formed exclusively. To the best
of our knowledge, this study represents the first example of an
apparent amide and carbamate directing effect in metal-mediated
reductive coupling.
Stereochemically well-defined, functionalized (E,E)-dienes are
common structural features embedded in polyketide-derived
natural products and related pharmaceutical agents.¹ In that
context, transition-metal-mediated alkyne-alkyne reductive
coupling reactions have recently emerged as step- and atom-
economical carbon-carbon bond-forming reactions to access
(E,E)-dienes by avoiding
a prefunctionalization step. The
principle challenges that lie within this strategy are the control of
reactivity and olefin selectivity. In response to these challenges in
the reductive coupling
Scheme 2. Arylacetamide Directing Effect in Alkyne-
(A)
Presence of the acidic proton greatly influences the reactivity and regioselectivity
Scheme 1. Alkyne-Alkyne Reductive Coupling for the
Selective Synthesis of (E,E)-Dienes
1) 2 eq ClTi(Oi-Pr)₃
4 eq cC₅H₉MgCl
-50^oC, 5h, PhMe
OMeOBn
Me
OMeOBn
O
t-BuSH
AlCl₃
(A)
Steric and electronic control with proximal substituents in metallacycle-mediated
reductive coupling by the Sato group
AcHN
AcHN
OMe
NFAT-68
Me
Me Me
2) -50 ^oC, 12h, PhMe
CO₂Me
L_n
M
OMe
1
OMe
R₂
R₂
R₁
R₁
R₁
R
+
R₂
2
R
"Original conditions" failed to produce desired product
R
R= TMS, esters
Alkoxide-directed titanium-mediated reductive coupling by the Micalizio group
Condition re-evaluation
(B)
OMe
Me
O
Ti
R₂
Me Me
OH OR₁
Me
OH OR₁
OMeOBn
Me
Ti-alkyne complex
generation
*
N
Carbometalation
and H⁺ quench
AcHN
R₂
+
R₂
OiPr
R₁O
Ti
*
*
*
*
*
*
OBn OMe
2
O
Me
Me
Me
Me Me
R₁= PMB, Me
Me
O
Me Me Me
r.r. > 10:1
r.r. = regioselectivity ratio
Me
OMeOBn
Ti OiPr
OMe
1
N
(C) This work:
regioselective alkyne-alkyne reductive coupling mediated by in situ
Me
Me
generated arylamidate
int-1
OMe
Me Me
n
R
R
R₂
O
Carbometalation
Original
Ti-alkyne complex generation
OR₁
Me
OR₁
O
N
O
HN
Ti
OiPr
HN
R₂
R₁
O
R₃
R₃
Updated
R
n
Original
Updated
6 equiv
-40 ^o
90%
Absence of the acidic proton leads to eroded regioselectivity
*
*
n
Me Me
*
O
*
n
R₂
R
OR₁
Me
Temperature
Time
-50 ^o
C
rt
Ti OiPr
Grignard
Temperature
int-1)
4 equiv
N
n= 1, 2
R= CH₃, OBn, OtBu
high regioselectivities
R₂
Me Me
-50 ^o
C
C
12h
0
2h
Bioactive natural products containing E,E-diene
2
Yield (
)
45%
Yield (
<10%
OMe
O
(B)
O
OH OH
O
2 eq ClTi(Oi-Pr)₃
4 eq cC₅H₉MgCl
OMeOBn
Me
OMeOBn
O
N
H
Ac
Ac
AcHN
CO₂Me
(Me)₂
N
N
NH
CO₂Me
Me
Me
Me
OMe
Me
OMe
Me Me
Me Me
OH
Me
Me Me
30% yield
r.r.: 2.7:1:2.2
-50 ^oC, 5h, PhMe
-50 ^oC, 12h, PhMe
N
OH
OMe
OMe
4
MeO
"Original conditions"
3
Me Me
NFAT-68
Immunosuppressant
Trichostatin A
Antifungal antibiotic
Micalizio's intermediate to
Hsp90 inhibitor analoges
Alkyne Reductive Coupling
In line with our previous studies on reductive couplings¹²ⁿ and
between internal alkynes and carbonyl-based π-systems or
alkynes, useful strategies to control regioselection have been
inspired by Micalizio⁴ and Schafer’s work,¹³ we report a highly
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Page 2 of 9
regiocontrolled synthesis of (E,E)-dienes mediated by in situ
generated arylamidate (Scheme 1C). This strategy takes
Table 1. Arylacetamide Directing Effect in Alkyne-Alkyne Reductive Coupling
advantage
of
1
2
3
4
5
6
7
8
1. 2 equiv ClTi(OiPr)₃
OR₁
OR₁
Me
6 equiv
cC₅H₉MgCl
R₂
AcHN
R₂
AcHN
R₃
PhMe, -40 ^oC, 3h
*
*
Me
*
*
n
n
+
R₃
Me Me
n= 1, 2
entry
2. -78 ^oC to rt
n= 1, 2
A1
, R₃
A2
, R₃
A3
, R₃
=
=
=
Me
(
, yield^,a, r.r.^b)
OTBS
OTBS
Me
9
A: Terminal Alkyne Substrate Scope
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
OMe OBn
AcHN
OMe OBn
OMe OBn
OMe OBn
AcHN
AcHN
AcHN
N
Me
5
Me Me
OMe
Me Me
Me Me
Me Me
, 62%, E,E only, r.r>20:1
OMe
OMe
OMe
8
5
6
7
8
, 57%, E,E only, r.r. > 20:1
, 50%, E,E only, r.r. > 20:1
, 61%, E,E only, r.r. > 20:1
, 62%, E,E only, r.r. > 20:1
OMe OBn
OMe OBn
OMe OBn
OMe OBn
O
AcHN
AcHN
AcHN
AcHN
Me
OTBS
N
OMe
Me Me
Me Me
Me Me
OMe
Me Me
OMe
OMe
10
OMe
9
11
12
, 45%, E,E only, r.r. > 20:1
, 61%, E,E only, r.r. > 20:1
, 60%, E,E only, r.r. > 20:1
, 65%, E,E only, r.r. > 20:1
B: Internal Alkyne Substrate Scope
OBn
Me
OBn
Me
AcHN
OBn
OTBS
AcHN
OTBS
Me Me
Me Me
Me Me
AcHN
AcHN
14
15 no coupled product
, 48%, E,E only, r.r. > 20:1
,
13
, 58%, E,E only, r.r. > 20:1
OBn
OBn
OBn
OMe
Me
AcHN
Me
OTBS
AcHN
Me
OH
AcHN
Me Me
Me Me
, 20%, E,E only, r.r. > 20:1
Me Me
Me Me
, 54%, E,E only, r.r. > 20:1
Br
17
18
19
, 40%, E,E only, r.r. > 20:1
16
, 62% E,E only, r.r. > 20:1
OMe OBn
Me
AcHN
OMe OBn
Me
OMe OBn
Me
OTBS
OTBS
AcHN
OTBS
Me Me Me
Me Me Me
, 49%, E,E only, r.r. > 20:1
Me Me Me
, 59%, E,E only, r.r. > 20:1
AcHN
20
21
22
, 49%, E,E only, r.r. > 20:1
^aIsolated yield after chromatographic purification over silica gel. ^bRegioselectivity was based on the analysis of the ¹H NMR spectra of the
crude products; r.r. = regioselectivity ratio.
the commonly used amine protecting groups, acetyl (Ac), tert-
butyloxycarbonyl (Boc), and carboxybenzyl (Cbz) groups, to
render the directing effects and achieves useful levels of
regioselectivity. This protocol represents the first examples of
apparent amide and carbamate directing effects in metal-mediated
reductive coupling.
producing 2 as a single regioisomer. Collectively, the presence of
an acetamide on the aryl ring had a pronounced impact on the
reactivity and selectivity of the reaction. Interestingly, the N-
methylated counterpart 3 (Scheme 2B) produced diene 4 with
significantly eroded regioselectivity under the “original
conditions” and led to decomposition under the updated
conditions. This control experiment provided evidence that the in
situ generated amidate anion may have played an important role
on the selectivity of this coupling reaction. Enlightened by
Schafer’s work¹³ on employing monoanionic N,O-chelating
ligands with a tight bite angle including amidates in titanium-
catalyzed reactions, we hypothesized that the in situ generated
arylamidate might associate with the titanium center to direct the
coupling reaction.
The development of this methodology originated from our
previous investigation concerning the reductive coupling between
internal alkynes obtained from asymmetric propargylation
reactions and acetylenic esters (Scheme 2).¹²ⁿ In an effort to apply
this strategy to the total synthesis of NFAT-68,¹²ⁿ we were
surprised to find that previous reaction conditions (“original
conditions”) for the reductive coupling failed to produce the
desired diene 2 using alkynyl acetamide 1 and methyl propiolate,
requiring reinvestigation of the reaction conditions (Scheme 2A).
For the generation of the presumed titanacyclopropene complex,
(1) two additional equivalents (six vs four) of the Grignard
reagent were required to achieve full conversion, indicating that
an excess amount of Grignard reagent was necessary for the
deprotonation of the acetamide proton; (2) a higher reaction
temperature was required to initiate the formation of int-1, where
the thermodynamic effect of the deprotonated amide on the
successful generation of Ti-alkyne complex has not been
previously described in reductive coupling reactions. For the
intermolecular carbometalation process, elevated coupling
temperature was needed for complete consumption of int-1,
On that basis, we surveyed the coupling of alkynyl acetamide 1
with a range of terminal alkynes bearing diverse functionality
(Table 1). To our delight, (E,E)-diene products (5-12) were
formed with excellent regioselectivity in all cases. Aryl, pyridyl
(5-7), silyl ether (10), alkyl amine (11) ,and ester (12) were all
well-tolerated, demonstrating the broad functional group tolerance
of this coupling reaction.
The alkyne substrate scope was evaluated subsequently, where
the variation of acetamide substitution pattern, stereochemistry,
electronics on the aryl ring, hydroxyl protecting groups, and tether
length was investigated (Table 1). While meta- and para-
substituted arenes delivered dienes (13 and 14) with good
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reactivity and excellent selectivity, the ortho-substitution failed to
1
2
3
4
5
6
7
8
give a coupled product, but gave only alkyne reduction (15).
Table 2. Arylcarbamate Directing Effect in Alkyne-Alkyne Reductive Coupling
1. 2 equiv ClTi(OiPr)₃
OR₁
Me
OR₁
6 equiv
cC₅H₉MgCl
R₂
R₂
RHN
R₃
PhMe, -40 ^oC, 3h
*
*
Me
*
n
n
*
RHN
R₃
+
Me Me
2. -30 ^o
C
n= 1, 2
R= Boc, Cbz
n= 1, 2
A1
,
A2
,
A3
,
R
R
R
=
=
=
3
3
3
Me
(
, yield^,a, r.r.^b)
entry
OTBS
OTBS
Me
9
Internal Alkyne Substrate Scope
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
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40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
OBn
Me
OBn
Me
OBn
Me
NHR OMe
RHN
Me
OH
OH
RHN
OTBS
OTBS
Me Me
Me Me
Me Me
Me Me
RHN
R= Boc, 23a
R= Cbz, 23b
R= Boc, 24a
R= Cbz, 24b
R= Boc, 25a
R= Cbz, 25b
R= Boc, 26a
R= Cbz, 26b
, 65%, E,E only, r.r. > 20:1
, 61%, E,E only, r.r. > 20:1
, 62%, E,E only, r.r. > 20:1
, 52%, E,E only, r.r. > 20:1
, 56%, E,E only, r.r. > 20:1
, 51%, E,E only, r.r. > 20:1
, 58%, E,E only, r.r. > 20:1
, 50%, E,E only, r.r. > 20:1
OTBS
OBn
Me
OMe OBn
Me
RHN
OTBS
RHN
OTBS
OMe
OMe
OTBS
Me Me
Me Me
Br
Me Me
OMe
R= Boc, 28a
R= Cbz, 28b
RHN
Me Me
R= Boc, 27a
R= Cbz, 27b
, 58%, E,E only, r.r. > 20:1
, 67%, E,E only, r.r. > 20:1
, 66%, E,E only, r.r. > 20:1
, 63%, E,E only, r.r. > 20:1
RHN
, 56%, r.r. = 5:1
, 51%, r.r. = 5:1
R= Boc, 29a
R= Cbz, 29b
OBn
NHR OBn OBn
Me
OBn OBn
Me
OBn OBn
Me
OTBS
OR₃
RHN
OR₃
OTBS
Me Me
Me Me Me
Me Me Me
Me Me Me
RHN
RHN
R= Boc, R = TBS 31a
R= Boc, R = TBS 32a
, , 60%, E,E only, r.r. > 20:1
3
R= Cbz, R = H 32b
, , 54%, E,E only, r.r. > 20:1
3
,
, 51%, E,E only, r.r. > 20:1
, 45%, E,E only, r.r. > 20:1
R= Boc, 30a
R= Cbz, 30b
R= Boc, 33a
R= Cbz, 33b
, 56%, E,E only, r.r. > 20:1
, 51%, E,E only, r.r. > 20:1
3
, 47%, E,E only, r.r. > 20:1
, 50%, E,E only, r.r. > 20:1
R= Cbz, R = H 31b
,
3
^aIsolated yield after chromatographic purification over silica gel. ^bRegioselectivity was based on the analysis of the ¹H NMR spectra of the
crude products; r.r. = regioselectivity ratio.
Scheme 3. Control Experiments
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R₂
Me
1. ClTi(OiPr)₃
R₂
1
2
3
4
cC₅H₉MgCl
OR₁
Me
OR₁
OR₁
OR₁
R
A1
R
R
R
N
PhMe, -40 ^oC, 3h
R₂
N
N
N
*
*
Me
Me
*
*
*
*
*
Me Me
Me
Me
Me
+
*
or
Me
+
+
2. -30 ^oC, 1h
Me Me
Me Me
R= Ac, Cbz, Boc or H
34
Z
X
Y
OTBS
yield^a, r.r. (X:Y:Z)^b
A3
5
6
7
8
(A)
When acetamide acidic proton is absent
1.2 equiv ClTi(OiPr)₃
4 equiv
PhMe, -30 ^oC, 1h
cC₅H₉MgCl
OMe
Me
OMe
Ac
N
Ac
Me
Me
N
+
Me
Me
2. -30 ^oC, 1h
A1
Me
34a
Me Me
9
35, 41%, 8.3:1:1
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
(B)
When carbamate acidic proton is absent
1.2 equiv ClTi(OiPr)₃
4 equiv
cC₅H₉MgCl
OBn
Me
Me
OBn
Me
Me
Cbz
N
Cbz
N
Me
PhMe, -30 ^oC, 1h
2. -30 ^oC, 1h
OTBS
OTBS
+
+
OTBS
Me
Me
Me
Me
Me Me
A3
36, 46%, 7.1:1:1
34b
1.2 equiv ClTi(OiPr)₃
4 equiv
cC₅H₉MgCl
OBn
OBn
Boc
N
Me
Boc
N
PhMe, -30 ^oC, 1h
2. -30 ^oC, 1h
OTBS
Me
Me
Me Me
A3
34c
37, 48%, 3:1.4:1
c
(C)
When carbonyl is absent
1.2 equiv ClTi(OiPr)₃
6 equiv
PhMe, -30 ^oC, 1h
cC₅H₉MgCl
OBn
Me
OBn
Me
H
N
Me
H
N
OTBS
+
OTBS
Me
Me
2. -30 ^oC, 1h
Me
Me Me
A3
34d
38, 40%, 2.3.1.5:1
c
(D)
When bearing an aniline moiety
Me
1.2 equiv ClTi(OiPr)₃
6 equiv
PhMe, -30 ^oC, 1h
cC₅H₉MgCl
OBn
Me
A1
or
H₂N
complex mixtures
+
2. -30 ^oC, 1h
Me
34e
Me
OTBS
A3
^aCombined yields of all regioisomers after chromatographic purification over silica gel. ^bRegioselectivity was based on the analysis of the
¹H NMR spectra of the crude products; r.r. = regioselectivity ratio. ^c6 equivalents of cC₅H₉MgCl was used.
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(A)
Micalizio's alkoxide-directed Ti-mediated alkyne-alkyne reductive coupling
1
2
3
4
R₂
R₂
R₂
OR₁ OH
OR₁ OH
highly
unfavorable
X
O
or
OiPr
O
H⁺
Ti
Me Me Me
Me Me Me
not observed
R₁O
minor isomers
Me Me Me
5
int-2
6
7
8
9
Me Me Me
1. nBuLi
2. ClTi(OiPr)₃
cC₅H₉MgCl
OR₁
X
Y
O
OR₁ OH
Me
OR₁ OH
R₂
OiPr
OiPr Ti
R₂
O
Y
Y
O
unfavorable
H⁺
Ti
O
R₁O
Ti OiPr
*deprotonation
Me Me
Me Me Me
minor isomer
*ligand exchange
*alkyne activation
*dimer formation
Me Me Me
int-3
R₂
R₁O
Me Me Me
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
Proposed Ti(II) dimer
O
OiPr R₂
OR₁ OH
O
favorable
H⁺
Ti
R₂
R₁O
Me Me Me
major isomer
Me Me Me
int-4
carbometalation
(B)
Monometallic binding modes of amidate with Ti (Schafer's work)
(1) (2)
possible binding modes
steric effects on the binding modes
Ti(NMe₂)₄
+
NMe₂
O
[Ti]
O
O
N
O
N
R
R
- 3 HNMe₂
25 ^oC, 2h
hexanes
R
[Ti]
Me
O
Ph
Ti
3
N
N
[Ti]
O
R'
R'
R'
Ph
2
Ph
N
H
monodentate monodentate
bidentate
N
Me
Ar
Ar = 2,6-dimethylphenyl
(C)
(1)
this work
Proposed amidate-mediated Ti-based regioselective reductive coupling (
)
Reaction mechanism (arylacetamides and -carbamates not including ortho-acetamide)
Me Me
n
R₂
R
O
HN
R
O
N
ClTi(OiPr)₃
cC₅H₉MgCl
N
Intermolecular
carbometalation
OR₁
OR₁
Me
Ti
OiPr
O
R₃
R₁O
OR₁
HN
R
H⁺
R₃
R
n
OR₁
O
N
OiPr
*
*
*
Ti
n
*
n
O
R₂
R₂
R
*deprotonation
Me Me
Me
n
Ti OiPr
R₂
*ligand exchange
*alkyne activation
*dimer formation
Me Me
n= 1, 2
R= CH₃, OBn, OtBu
high selectivities
R₂
int-6
Me Me
int-5
39
Proposed ¹(O)-amidate-

chelated Ti(II) dimer
(2)
Stereochemical model (Newman projection)
O
R
R
I
II
3
3
OiPr
OiPr
O
Ti
Ti
H
OR₁
H
R
R
OR₁
OR₁
OiPr
OiPr
Me
Me
H
Ti
Ti
N
N
Me
Me
R₁O
H
N
N
R₂
R₂
O
O
Me
41
Me
Me
Me
R₂
R₂
R
R
40
minimization of A^1,3 strain
minimization of A^1,3 strain
int-7
int-8
Syn-stereoisomers
Anti-stereoisomers
Figure 1. Proposed Reaction Mechanism
Contrary to Micalizio’s study, substrate stereochemistry had little
or no impact on reaction selectivity (16 and 17).^1h Additionally,
placement of an electron-withdrawing group or electron-donating
group ortho to the acetamide did not alter the selectivity,
furnishing 18 and 19 as the only isomers. The yield of 18 was
diminished presumably due to the metal/halogen exchange of
Grignard reagent with arylbromide. Importantly, substrates with
extended tether length also proved to be viable for the coupling to
obtain products (20-22) with excellent regioselectivity. Given that
excellent regiocontrol was achieved in complex molecular
settings, we expect this methodology will find wide application in
natural product and complex molecule synthesis. Accordingly,
these results suggest that arylacetamides have a strong directing
group effect on titanium alkoxide-mediated reductive couplings.
moderate yields. In an analogous fashion, factors such as
substitution pattern (23-25), electronic contributions on the aryl
ring (26-28), stereochemistry and hydroxyl protecting groups (25
and 29), and tether length (31-33) were evaluated. All products
were obtained with useful levels of regioselectivity. A decreased
selectivity (29) was observed, when the arene substrate was para-
substituted and an anti-stereochemical relationship between
benzylic methyl ether and homobenzylic methyl group was
present. Accordingly, carbamates (Boc and Cbz) also displayed an
apparent directing effect to render (E,E)-dienes with excellent
levels of selectivity.
Control experiments were conducted to demonstrate the
importance of the directing effect of acetamide¹⁴ or carbamate¹⁵
through in situ formation of arylamidate.¹⁶ As depicted in Scheme
3A and 3B, when the N-H proton was replaced with a methyl
group on acetamide or carbamate, the reaction selectivity was
significantly decreased along with the production of the other two
regioisomers (35-37).¹²ⁿ Additionally, removal of the carbonyl
functionality from the arylamine (Scheme 3C and 3D) led to a
Encouraged by the success with acetamide bearing substrates,
we investigated carbamates (Boc and Cbz) to determine if they
would display a similar directing effect as the amides (Table 2).
Gratifyingly, with a lower reaction temperature, (E,E)-dienes (20
examples) were obtained as the exclusive regioisomers in
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complex product mixture. Two additional equivalents of Grignard
pharmaceutical agents are underway in our laboratory and will be
1
2
3
reagent were added for deprotonation of the acidic amine
hydrogen, which excluded the possibility that the transformation
was mediated by a deprotonated arylamine.
reported in due course.
Based on the above-described experiments, we proposed a
likely mechanism (Figure 1C) for reductive coupling mediated by
in situ generated arylamidate that builds on Micalizio’s^1g,
Shafer’s¹³ and our earlier work¹²ⁿ (Figure 1A and 1B). The
Micalizio group has laid a solid foundation in the mechanistic
interpretation of operational intermediates and transition states
leading to selective reductive coupling in the field of directed-
metalation mediated by titanium alkoxide. Specifically, in the
case where the intramolecular coordination of homoallylic
alkoxide with titanium is hampered by significant ring strain, a Ti
(II) dimer is proposed to be the intermediate during the formation
of titanacyclopropene complex. The selectivity of the subsequent
carbometalation and formation of E,E-dienes can be rationalized
by simple steric consideration, where the int-4 has the least
unfavorable steric interactions between Ti(II) dimer and the
incoming terminal alkyne (Figure 1A). On the other hand, the
Shafer group has established the coordination modes of amidates
with Ti(IV) (Figure 1B). The amidates bind in either a bidentate
or monodentate mode through either nitrogen or oxygen atom,
where κ¹-(O) binding will be favored in a sterically congested
environment. Given the considerations described above, we
propose a κ¹-(O)-amidate-chelated Ti(II) dimer (int-5) that is
responsible for the unprecedented selectivity and reactivity
(Figure 1C). In comparison to Micalizio’s strategic placement of
an alkoxide as a directing group, the use of arylamidate in our
case creates a more sterically crowed environment resulting in
better selectivities and lower reactivities (transition states I and II,
highlighted in yellow). Based on this proposal, as the anti-
stereoisomers (int-8) have the ether group (OR₁) positioned closer
to the titanium reacting center compared with the syn-
stereoisomers (int-7), int-8 is sterically more congested than int-
7. The proposition is consistent with the observation that the anti-
substrates were less reactive than their syn-counterparts (Table 1,
14 vs. 16; Table 2, 23 vs. 29, where both the anti-substrates did
not couple with the most sterically hindered terminal alkyne (A3).
Furthermore, different positions of the acetamide and carbamate
functionality on the aryl ring might produce geometrically
different arylamidate-associated intermediates that have distinct
stabilities and steric environment. In particular for para-
substituted carbamates (Table 2, 29), the combination of the
destabilization effect of a bulky carbamate and more sp² character
of the dimer might lead to a weaker coordination of the amidate
with Ti. This may allow for the terminal alkyne to approach from
the inner sphere of the dimer (resembling to pathway X in Figure
1A), explaining the formation of the other regioisomer. In
contrast, a substrate with an ortho-substituted acetamide (15)
would likely to form a dimer featuring less steric interactions and
sp² character, permitting the possibility of a bidentate N,O-
chelation. The ensuing higher coordinated dimer might have the
titanium center shielded by the steric bulk, decreasing its
reactivity for the coupling reaction (Table 1, 15).^13b
ASSOCIATED CONTENT
Supporting Information
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5
6
7
8
9
The Supporting Information is available free of charge on the
ACS Publications website.
Experimental details, analytical data, and ¹H and ¹³C NMR
spectra
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
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AUTHOR INFORMATION
Corresponding Author
*E-mail: panek@bu.edu
Notes
The authors declare no competing financial interests.
ACKNOWLEDGMENT
We are grateful for the financial support provided by the
Department of Chemistry at Boston University. We would like to
thank Dr. Jie Wu from the Department of Chemistry at the
National University of Singapore for insightful discussions and
help with the preparation of this manuscript. We would also like
to thank Saishuai Wen (Porco group, Department of Chemistry,
Boston University) for obtaining NMR data for 34a, 34b and 34c.
We thank Dr. Paul Ralifo and Dr. Norman Lee at the Boston
University Chemical Instrumentation Center for helpful
discussions and assistance with NMR and HRMS.
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Gallina, C. Regio and stereospecific synthesis of and 3-methyl-6-
methylethyl cyclohexenes and 3-methyl-4-methylethylcyclohexenes.
Reactions of allylic acetates and carbamates with Li₂Cu₃Me₅ and
LiCuMe₂. Tetrahedron Lett. 1982, 23, 3093; (e)Goering, H. L.; Kantner,
S. S.; Tseng, C. C. Alkylation of allylic derivatives. 4. On the mechanism
of alkylation of allylic N-phenylcarbamates with lithium dialkylcuprates.
J. Org. Chem. 1983, 48, 715.
and titanium alkoxide-mediated reductive coupling bond construction.
Org. Lett. 2016, 18, 4304; (o) Cheng, X.; Micalizio, G. C. Synthesis of
neurotrophic seco-prezizaane sesquiterpenes (1R,10S)-2-Oxo-3,4-
dehydroneomajucin, (2S)-hydroxy-3,4-dehydroneomajucin, and (-)-
Jiadifenin. J. Am. Chem. Soc. 2016, 138, 1150.
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(13) (a) Leitch, D. C.; Beard, J. D.; Thomson, R. K.; Wright, V. A.;
Patrick, B. O.; Schafer, L. L. N,O‐chelates of group 4 metals: Contrasting
the use of amidates and ureates in the synthesis of metal dichlorides. Eur.
J. Inorg. Chem. 2009, 2691; (b) Payne, P. R.; Thomson, R. K.; Medeiros,
D. M.; Wan, G.; Schafer, L. L. Synthesis, structure, and reactivity of
tris(amidate) mono(amido) and tetrakis(amidate) complexes of group 4
transition metals. Dalton Trans. 2013, 42, 15670; (c) Yim, J. C.; Bexrud,
J. A.; Ayinla, R. O.; Leitch, D. C.; Schafer, L. L. Bis(amidate)bis(amido)
titanium complex: A regioselective intermolecular alkyne hydroamination
catalyst. J. Org. Chem. 2014, 79, 2015; (d) Ryken, S. A.; Schafer, L. L.
N,O-chelating four-membered metallacyclic titanium(IV) complexes for
atom-economic catalytic reactions. Acc. Chem. Res. 2015, 48, 2576.
(14) For selected examples using amides as directing groups (DG) in
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Suzuki cross-couplings. J. Am. Chem. Soc. 2011, 133, 15362; (b) Zhang,
X. G.; Dai, H. X.; Wasa, M.; Yu, J. Q. Pd(II)-catalyzed ortho
trifluoromethylation of arenes and insights into the coordination mode of
acidic amide directing groups. J. Am. Chem. Soc. 2012, 134, 11948; (c)
Crisenza, G. E.; Sokolova, O. O.; Bower, J. F. Branch‐selective alkene
hydroarylation by cooperative destabilization: Iridium‐catalyzed
ortho‐alkylation of acetanilides. Angew. Chem. Int. Ed. 2015, 54, 14866.
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R
R
1. ClTi(OiPr)₃
O
OR₁
Me
OR₁
cC₅H₉MgCl
PhMe, -40 ^oC, 3h
O
HN
R₂
HN
R₂
R₃
*
*
*
*
n
n
2. conditions
R₃
Me
Me Me
n= 1, 2
R= CH₃, OBn, OtBu
37 examples
Me Me
n
R₂
N
O
Ti
OiPr
R₁
O
R
n
O
R
OR₁
Ti OiPr
N
R₂
Me Me
9
Proposed ¹(O)-amidate-
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chelated Ti(II) dimer
Arylamidate-mediated
Excellent regioselectivity
New amide and carbamate directing effects
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