- Email: [email protected]
Short-step synthesis of amino acids and N-hydroxyamino acids from amines
Tetrahedron Letters,Vol.28,No.51,pp Printed in Great Britain
SHORT-STEP
SYNTHESIS
OF AMINO
Shun-Ichi Department Osaka
Summary:
University,
to give
inexpensive
method
Recently
for synthesis
that
hydrogen
peroxide
dioxide2
catalysts
reaction
of nitrones
strategy
for the introduction
We report acids
here
hydrogenation
Scheme
1)
H202,
nucleophiles
provides
acids
cyanation,
with
step.
The
a potential
at the a-position
amines,
of amines.
(2) and amino hydrolysis,
and
1.
CN
Na2W0,, c
2)
CN
H20,
KCN,
R’ R2&N-R3
HCI
, AH
C02H
H+
R’ R2&N-R3
t
C02H H2
R’R2&N-R3
1 AH
*
R’ R’&N-R3 H
cat
AH
I
?.
N-Hydroxyamino
acids
bearing
accessible,
bearing
3
secondary
although N-hydroxyamino 3 prepared. Only one report
acids
and
or selenium
in a single
R3 H-
amino
amines
tungstatel
nitrones
in Scheme
(1).
catalytic
efficient,
of secondary
of N-hydroxyamino
of secondary
peroxide
from amines.
sodium
of substituents
as depicted
undergo
is a simple,
of either
synthesis
hydrogen
a-cyanohydroxylamines
acids
the oxidation
with
with
560, Japan
1
R’ R’CH-N
readily
This
of amino
thus obtained
short-step
gave
Science,
Osaka
(2), which
the corresponding
(3) by the oxidation
catalytic
(3).
in the presence gave
amines
cyanide
FROM AMINES
Shiota
Toyonaka,
acids
acids
ACIDS
of Engineering
of secondary
hydrogen
amino
we reported
and Tatsuki
Machikaneyama,
with
0040-4039/87 $3.00 + .OO Perqamon Journals Ltd.
N-HYDROXYAMINO
Faculty
of 1 gave N-hydroxyamino
hydrogenation
AND
Murahashi-
oxidation
by treatment
Hydrolysis
ACIDS
of Chemistry,
Catalytic
followed
6469-6472,1987
amino
groups
are hardly
acids with
primary
deals
the synthesis
with
amino
groups
can be
of N-hydroxy-
amino groups by Cope rearrangement of 4 acid N-oxides. N-Hydroxyamino acids are biologically
N-cyanoethylamino
secondary
important
ciass
are produced by metabolism of amino acids 6 and act as antibiotics and growth factors. For synthesis of amino acids 7 bearing secondary amino groups there are few general methods. Cyclization reactions
are generaily
steps
of compounds
and expensive
used,
starting
which
however, materials 6469
they are tedious 8 are required.
because
5
long reaction
6470 u-Cyanohydroxylamines amines
with
tungstate cyanide
are readily
30% hydrogen
in water
peroxide
or methanol
and 4 N hydrochloric
the preparation
and subsequent acid
in 72% isolated
gives
reaction
It is noteworthy corresponding cyanide.
that
nitrones
substituted
(4) with
Hydrolysis N-hydroxyamino
the treatment
acids
in excellent
palladium
on charcoal
Preparation
of
gave
of proline,
was
can be converted
into
of secondary
exclusively.
the reaction
conditions.
can be converted
bases
by elimination
into the
of hydrogen
of Z-cyano-l-hydroxy-
solution
l-pyrroline
gave
under
yields
acidic
as shown acids
the corresponding
a -Cyanohydroxylamines CI-Cyanohydroxylamine
N-oxide.
conditions
in Table
2.
over palladium
amino
from b
Further black
Proline
acids.
Secondary
gave
or
(7_) and
Aminesa Isolated
Yield/%
C3H7$H-tj-C,,H9
(C4Hg12NH
CN OH
0fl
2
72
I! OH
80
3
4
70
s OH
5=
92 CN
a)
The
reaction
b)
The
products
c)
Nitrone
was carried gave
was prepared
out
similar
satisfactory in CH30H
to the
The
of l-cyano-Z-hydroxy-
of a solution
of N-hydroxyamino
Amine
1=
NaOH
of
1.
1-cyano-3,4-dihydro-
under
with
of n-cyanohydroxylamines
hydrogenation
Entry
formed
treatment
an aqueous
catalytic
1.
gave
results
in Table
nitrones
u-cyanohydroxylamines
upon
For example,
pyrrolidine
once
potassium
the oxidation
from dehydration
is derived
1,2,3,4-tetrahydroisoquinoline
Table
(z), because
stable
of secondary
% of sodium
with
are summarized
of i,2,3,4-tetrahydroisoquinoline (6), which
treatment
2-dethylpiperidine
yield.
thermodynamicaliy
isoquinoline
of 4 mol
(4_), -which is a precursor
2-cyano-l-hydroxy-2-methylpiperidine amines
by the oxidation
The representative
in water.
of a-cyanohydroxylamines
2-Cyano-1-hydroxypyrrolidine obtained
prepared
in the presence
procedure
IR,
NMR,
mass spectral
by
using
3 equiv
described data,
of H202.
in the and
text.
elemental
analyses.
6i171
pipecolinic acid
acid
(9), which
(8_)were shows
obtained
peculiar
in excellent
behavior
yields. a-Methylpipecolinic 9 was also prepared
in proteins,
readily. As a typical described.
example,
To a solution
(0.358 g, 5.03 mmol)
in H20
(1.28 g, 11.3 mmol)
dropwise
O-5 'C, to the reaction mmol)
stirring
by adding CH2C12
followed
acetate
at O-10
a few dropps
under
was
added
argon.
NaOH
chromatography
and Pd-black
(i$)l'
temperature
under
solution.
on silica
solution
reduced
Careful
Removal
(1 atm).
After to pH 8-9
extraction
with
(eluent=hexane/ethyl A solution
stirred
pressure
of 4
at 50 'C for 8 h and ion exchange acid buffer)
(2 mL) was
stirred
of the solvent
at
gave proline
(0.107 g, 93%).
(1)12
The present practical Further,
Table
because various
2.
method
for synthesis
of amino
acid
is convenient
and
of high yields and the use of inexpensive reagents. 14 [l- Cl-labelled amino acids, which are important class
Preparation
of N-Hydroxyamino
a-Cyanohydroxylamine
Entry
Acids
N-Hydroxyb amino Acid
and
Amino
YieldCl%
1
Acidsa
Amino
Acidb
Yield’/%
CL
93
!
C02H
93
7 _
2
C02H
86d
CM3
3
CM3
d
CO2H
8ge
e
C02H
go
g7
OH rt a)
gave
of ;fJ (0.131 g, 1.00 mmol)
(2 mL) and methanol
hydrogen
at
(0.490 g, 7.52
ice cooling.
M pyridine-acetic A mixture
solution
was adjusted
gel
(4 mL) was
under
(0.977 g, 93%).
(0.021 g) in water
H202
4 lo (0.409 g, 72%).
of the solvent
is
3 h of stirring
cyanide
(1.8 mL) with
(Dowex 50W x 2, eluent=0.2
N-hydroxyproiine
After
potassium
HCl solution
in cone HCl
Removal
chromatography
a 30% aqueous
argon.
'C for 4.5 h, the solution
of 2 N aqueous
by column
from pyrrolidine
(0.067 g, 0.20 m-nol) and pyrrolidine
at 0 'C under
1:l) gave a-cyanohydroxylamine
(0.896 g, 7.99 mmol)
of proline
(3 mL) was added
mixture
and then a 4 N aqueous
additional
room
the synthesis of Na2W04*2H20
The
reaction
b)
Satisfactory
c)
Isolated
e)
Palladium
was carried IR,
yields.
NMR, d)
on charcoal
out
similar
mass spectral
The
hydrolysis
(5%)
was used
to the data,
procedure and
was carried
described
elemental out
at
as a hydrogenation
analyses 100 OC. catalyst.
in the were
text. obtained.
of
6472
compounds
with
respects
can be readily
and biosynthesis, labelled
to the tracer
prepared
Mitsui,
3)
T. Shiota,
and T. Shiota,
and G. B. Brown,
H. T. Nagasawa, Is,
483
Chem.,
and 0. W. Griffith,
Bull.
Yuki
a) G. C. Barrett,
Gosei
Marcel
Yoneda,
Pharm.
Polym.
J., g1
C. G. Overberger 1413
and Hall,
2583
Chem.
Chem.
(1987).
(1976); b) E.
and A. A. Mikhail,
J. Med.
J. Mol.
z,
2748
(1979);
86,
63
697
(1986).
(1982).
of the Amino
Acids",
Ed. by
1985, p 246; b) A. B. Mauger,
Acids,
New York,
Chem.,
(1974); c) H. C. J.
Rev., 40,
New York,
of Amino
Dekker,
Sot. Jpn., 9,
Chem.
2383
2092
Peptides,
1977, vol
Catal.,
and Proteins",
Ed.
4, p 179; c) I<.
41,
135
Synthesis,
Korenczlci, Synthesis, Eur.
Sot.,
(1967).
J. Biol.
Kyokaishi,
and S. Asada,
S. Nishii,
a) H. J. Monteiro, Chem.
J. Chem.
28,
3,
265
and Biochemistry
and Biochemistry
by B. Weinstein,
Bull.
Kagaku
"Chemistry
G. C. Barret-t, Chapman
Izawa,
32,
Sot. Jpn., 47,
and J. D. M. Herscheid,
7)
10) 4:
with
(1972).
Chem.
"Chemistry
Lett.,
P. S. Fraser,
b) A. Ahmad, Ottenheijm
Murahashi,
J. Org. Chem.,
J. Org.
a) A. J. L. Cooper
M. Akiyama,
9)
and S.-I.
J. G. Kohlhoff,
6)
8)
reactions
and Notes
Tetrahedron
a) T. Polofiski and A. Chimiak,
Chem., 5)
the present
874.
Murahashi
S.-I.
Buehler 4)
S. Zenki,
1984,
Commun., 2)
by using
of metabolism
K14CN.13
References
H.
for the study
experiments
1974, 137; b) T, Fujii -1341 (1975); c) H. Yasuo,
(1987).
and M. Miyoshi, M. Suzuki,
and N.
Bull.,
27 1931 (1.979); d) L. Kisfaludy and F. ---I 1982 163; e) C. G. Overberger and M. D. Shalati, ---I 1055 (1983).
and ii. S. Jon, J. Polym.
Sci,,
Polym.
Chem.
Ed., 15,
(1977). 'H NMR
-CH2N-),
(neat) 3325 Calcd
(CDC13)
3-86
S 1.56-2-4'7 (m, 4 H, -CH2-),
(t, J := 7.2 Hz, 1 H, -CH(CN)-),
(O-H), 2260
for C5H8N20:
c,
(CrN) cm.-1; mass
53.56;
2.73-3,52
(m, 2 H,
'7.18 (br, s, 1 H, OH);
spectrum
H, 7.19; N, 25.13.
m/e
112
Found:
(M').
IR
Anal.
C, 53.48;
H,
7.21; N, 25.08. mp 129-151 *C (decomp.); -LH NMR (D20) 6 2.20-3.29 11) I?: (m, 4 H, -CH2-), 3.74-4-50 (m, 2 H, -CW2N--) I 4.75 (t, J = 7.6 Hz, 1 H, -CH(C02H-) s Anal. Calcd
for C5H9NO3:
6-82, N, i0.54, 7: ‘111 NMR ! 11.O) 12) ,”
‘.
1.3)
c,
45.80;
H, 6.92; N, 10.68.
d 2:1.7-3,18 (II?,4 H, -CH2.*), 3.86
Found:
C, 45.54;
(t, J = 6.5 Hz,
H,
2 H,
SHORT-STEP
SYNTHESIS
OF AMINO
Shun-Ichi Department Osaka
Summary:
University,
to give
inexpensive
method
Recently
for synthesis
that
hydrogen
peroxide
dioxide2
catalysts
reaction
of nitrones
strategy
for the introduction
We report acids
here
hydrogenation
Scheme
1)
H202,
nucleophiles
provides
acids
cyanation,
with
step.
The
a potential
at the a-position
amines,
of amines.
(2) and amino hydrolysis,
and
1.
CN
Na2W0,, c
2)
CN
H20,
KCN,
R’ R2&N-R3
HCI
, AH
C02H
H+
R’ R2&N-R3
t
C02H H2
R’R2&N-R3
1 AH
*
R’ R’&N-R3 H
cat
AH
I
?.
N-Hydroxyamino
acids
bearing
accessible,
bearing
3
secondary
although N-hydroxyamino 3 prepared. Only one report
acids
and
or selenium
in a single
R3 H-
amino
amines
tungstatel
nitrones
in Scheme
(1).
catalytic
efficient,
of secondary
of N-hydroxyamino
of secondary
peroxide
from amines.
sodium
of substituents
as depicted
undergo
is a simple,
of either
synthesis
hydrogen
a-cyanohydroxylamines
acids
the oxidation
with
with
560, Japan
1
R’ R’CH-N
readily
This
of amino
thus obtained
short-step
gave
Science,
Osaka
(2), which
the corresponding
(3) by the oxidation
catalytic
(3).
in the presence gave
amines
cyanide
FROM AMINES
Shiota
Toyonaka,
acids
acids
ACIDS
of Engineering
of secondary
hydrogen
amino
we reported
and Tatsuki
Machikaneyama,
with
0040-4039/87 $3.00 + .OO Perqamon Journals Ltd.
N-HYDROXYAMINO
Faculty
of 1 gave N-hydroxyamino
hydrogenation
AND
Murahashi-
oxidation
by treatment
Hydrolysis
ACIDS
of Chemistry,
Catalytic
followed
6469-6472,1987
amino
groups
are hardly
acids with
primary
deals
the synthesis
with
amino
groups
can be
of N-hydroxy-
amino groups by Cope rearrangement of 4 acid N-oxides. N-Hydroxyamino acids are biologically
N-cyanoethylamino
secondary
important
ciass
are produced by metabolism of amino acids 6 and act as antibiotics and growth factors. For synthesis of amino acids 7 bearing secondary amino groups there are few general methods. Cyclization reactions
are generaily
steps
of compounds
and expensive
used,
starting
which
however, materials 6469
they are tedious 8 are required.
because
5
long reaction
6470 u-Cyanohydroxylamines amines
with
tungstate cyanide
are readily
30% hydrogen
in water
peroxide
or methanol
and 4 N hydrochloric
the preparation
and subsequent acid
in 72% isolated
gives
reaction
It is noteworthy corresponding cyanide.
that
nitrones
substituted
(4) with
Hydrolysis N-hydroxyamino
the treatment
acids
in excellent
palladium
on charcoal
Preparation
of
gave
of proline,
was
can be converted
into
of secondary
exclusively.
the reaction
conditions.
can be converted
bases
by elimination
into the
of hydrogen
of Z-cyano-l-hydroxy-
solution
l-pyrroline
gave
under
yields
acidic
as shown acids
the corresponding
a -Cyanohydroxylamines CI-Cyanohydroxylamine
N-oxide.
conditions
in Table
2.
over palladium
amino
from b
Further black
Proline
acids.
Secondary
gave
or
(7_) and
Aminesa Isolated
Yield/%
C3H7$H-tj-C,,H9
(C4Hg12NH
CN OH
0fl
2
72
I! OH
80
3
4
70
s OH
5=
92 CN
a)
The
reaction
b)
The
products
c)
Nitrone
was carried gave
was prepared
out
similar
satisfactory in CH30H
to the
The
of l-cyano-Z-hydroxy-
of a solution
of N-hydroxyamino
Amine
1=
NaOH
of
1.
1-cyano-3,4-dihydro-
under
with
of n-cyanohydroxylamines
hydrogenation
Entry
formed
treatment
an aqueous
catalytic
1.
gave
results
in Table
nitrones
u-cyanohydroxylamines
upon
For example,
pyrrolidine
once
potassium
the oxidation
from dehydration
is derived
1,2,3,4-tetrahydroisoquinoline
Table
(z), because
stable
of secondary
% of sodium
with
are summarized
of i,2,3,4-tetrahydroisoquinoline (6), which
treatment
2-dethylpiperidine
yield.
thermodynamicaliy
isoquinoline
of 4 mol
(4_), -which is a precursor
2-cyano-l-hydroxy-2-methylpiperidine amines
by the oxidation
The representative
in water.
of a-cyanohydroxylamines
2-Cyano-1-hydroxypyrrolidine obtained
prepared
in the presence
procedure
IR,
NMR,
mass spectral
by
using
3 equiv
described data,
of H202.
in the and
text.
elemental
analyses.
6i171
pipecolinic acid
acid
(9), which
(8_)were shows
obtained
peculiar
in excellent
behavior
yields. a-Methylpipecolinic 9 was also prepared
in proteins,
readily. As a typical described.
example,
To a solution
(0.358 g, 5.03 mmol)
in H20
(1.28 g, 11.3 mmol)
dropwise
O-5 'C, to the reaction mmol)
stirring
by adding CH2C12
followed
acetate
at O-10
a few dropps
under
was
added
argon.
NaOH
chromatography
and Pd-black
(i$)l'
temperature
under
solution.
on silica
solution
reduced
Careful
Removal
(1 atm).
After to pH 8-9
extraction
with
(eluent=hexane/ethyl A solution
stirred
pressure
of 4
at 50 'C for 8 h and ion exchange acid buffer)
(2 mL) was
stirred
of the solvent
at
gave proline
(0.107 g, 93%).
(1)12
The present practical Further,
Table
because various
2.
method
for synthesis
of amino
acid
is convenient
and
of high yields and the use of inexpensive reagents. 14 [l- Cl-labelled amino acids, which are important class
Preparation
of N-Hydroxyamino
a-Cyanohydroxylamine
Entry
Acids
N-Hydroxyb amino Acid
and
Amino
YieldCl%
1
Acidsa
Amino
Acidb
Yield’/%
CL
93
!
C02H
93
7 _
2
C02H
86d
CM3
3
CM3
d
CO2H
8ge
e
C02H
go
g7
OH rt a)
gave
of ;fJ (0.131 g, 1.00 mmol)
(2 mL) and methanol
hydrogen
at
(0.490 g, 7.52
ice cooling.
M pyridine-acetic A mixture
solution
was adjusted
gel
(4 mL) was
under
(0.977 g, 93%).
(0.021 g) in water
H202
4 lo (0.409 g, 72%).
of the solvent
is
3 h of stirring
cyanide
(1.8 mL) with
(Dowex 50W x 2, eluent=0.2
N-hydroxyproiine
After
potassium
HCl solution
in cone HCl
Removal
chromatography
a 30% aqueous
argon.
'C for 4.5 h, the solution
of 2 N aqueous
by column
from pyrrolidine
(0.067 g, 0.20 m-nol) and pyrrolidine
at 0 'C under
1:l) gave a-cyanohydroxylamine
(0.896 g, 7.99 mmol)
of proline
(3 mL) was added
mixture
and then a 4 N aqueous
additional
room
the synthesis of Na2W04*2H20
The
reaction
b)
Satisfactory
c)
Isolated
e)
Palladium
was carried IR,
yields.
NMR, d)
on charcoal
out
similar
mass spectral
The
hydrolysis
(5%)
was used
to the data,
procedure and
was carried
described
elemental out
at
as a hydrogenation
analyses 100 OC. catalyst.
in the were
text. obtained.
of
6472
compounds
with
respects
can be readily
and biosynthesis, labelled
to the tracer
prepared
Mitsui,
3)
T. Shiota,
and T. Shiota,
and G. B. Brown,
H. T. Nagasawa, Is,
483
Chem.,
and 0. W. Griffith,
Bull.
Yuki
a) G. C. Barrett,
Gosei
Marcel
Yoneda,
Pharm.
Polym.
J., g1
C. G. Overberger 1413
and Hall,
2583
Chem.
Chem.
(1987).
(1976); b) E.
and A. A. Mikhail,
J. Med.
J. Mol.
z,
2748
(1979);
86,
63
697
(1986).
(1982).
of the Amino
Acids",
Ed. by
1985, p 246; b) A. B. Mauger,
Acids,
New York,
Chem.,
(1974); c) H. C. J.
Rev., 40,
New York,
of Amino
Dekker,
Sot. Jpn., 9,
Chem.
2383
2092
Peptides,
1977, vol
Catal.,
and Proteins",
Ed.
4, p 179; c) I<.
41,
135
Synthesis,
Korenczlci, Synthesis, Eur.
Sot.,
(1967).
J. Biol.
Kyokaishi,
and S. Asada,
S. Nishii,
a) H. J. Monteiro, Chem.
J. Chem.
28,
3,
265
and Biochemistry
and Biochemistry
by B. Weinstein,
Bull.
Kagaku
"Chemistry
G. C. Barret-t, Chapman
Izawa,
32,
Sot. Jpn., 47,
and J. D. M. Herscheid,
7)
10) 4:
with
(1972).
Chem.
"Chemistry
Lett.,
P. S. Fraser,
b) A. Ahmad, Ottenheijm
Murahashi,
J. Org. Chem.,
J. Org.
a) A. J. L. Cooper
M. Akiyama,
9)
and S.-I.
J. G. Kohlhoff,
6)
8)
reactions
and Notes
Tetrahedron
a) T. Polofiski and A. Chimiak,
Chem., 5)
the present
874.
Murahashi
S.-I.
Buehler 4)
S. Zenki,
1984,
Commun., 2)
by using
of metabolism
K14CN.13
References
H.
for the study
experiments
1974, 137; b) T, Fujii -1341 (1975); c) H. Yasuo,
(1987).
and M. Miyoshi, M. Suzuki,
and N.
Bull.,
27 1931 (1.979); d) L. Kisfaludy and F. ---I 1982 163; e) C. G. Overberger and M. D. Shalati, ---I 1055 (1983).
and ii. S. Jon, J. Polym.
Sci,,
Polym.
Chem.
Ed., 15,
(1977). 'H NMR
-CH2N-),
(neat) 3325 Calcd
(CDC13)
3-86
S 1.56-2-4'7 (m, 4 H, -CH2-),
(t, J := 7.2 Hz, 1 H, -CH(CN)-),
(O-H), 2260
for C5H8N20:
c,
(CrN) cm.-1; mass
53.56;
2.73-3,52
(m, 2 H,
'7.18 (br, s, 1 H, OH);
spectrum
H, 7.19; N, 25.13.
m/e
112
Found:
(M').
IR
Anal.
C, 53.48;
H,
7.21; N, 25.08. mp 129-151 *C (decomp.); -LH NMR (D20) 6 2.20-3.29 11) I?: (m, 4 H, -CH2-), 3.74-4-50 (m, 2 H, -CW2N--) I 4.75 (t, J = 7.6 Hz, 1 H, -CH(C02H-) s Anal. Calcd
for C5H9NO3:
6-82, N, i0.54, 7: ‘111 NMR ! 11.O) 12) ,”
‘.
1.3)
c,
45.80;
H, 6.92; N, 10.68.
d 2:1.7-3,18 (II?,4 H, -CH2.*), 3.86
Found:
C, 45.54;
(t, J = 6.5 Hz,
H,
2 H,