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Removal of C-terminal peptide amides from a 3-nitro-4-aminomethyl-benzoyl amide resin by photolysis
100.5, pp JO1 - 304, 1975.
Tetmbodron Letton
Per&smotl Press. PrintedlaQwtBritaia.
RBMOVAL OF C-TERMINAL 3-NITRO-4-AMINOM%THYL-BENZOYL
PEPTIDE AMIDES FROM A AMIDE RESIN BY PHOTOLYSIS K.
Daniel H. Rich and S. School of Pharmacy,
University
Gurwara
of Wisconsin,
Madison, Wisconsin
53706
(Roceivsdin UBA 28 Ootober 1974; raoeived in UK for abliostion 23 Ibomber 1974) The C-terminal
amide group is present
including deamino-oxytocin, 1 LH_m;*'3
However,
these conditions
groups which restrict
are
as the valine methods
to amminolysis
Furthermore,
in secretin.
for preparing
C-terminal
amides
4-aminomethylbenzoylamide
can be difficult
Resin 1 was prepared with N-bromosuccinimide 81% yield7"
acid
derivative &by clohexylamine
to illustrate
4
such
Thus new
from a solid phase as the
Protected peptides
can be removed
under conditions which do not The syn-
the method. Bromination
of E-toluic
gave *brano-E-toluic
acid
acid
(L)
(2) in
of 2 in 90% nitric acid at -lO°C for 2.5 hr gave 3acid
(1) in 85% yield,8 which upon reaction
in 72% yield.
(mp 205-207OC)
by coupling the Boc-nitro
converted
to its Boc-
in D14S08 anti characterized
(85%).
in liquid
gave 3-nitro-4-aminomethylbenzoic
Amino acid &was
reaction with Boc-azide salt z
residues.
groups nor aranatic amino acids.
for 48 hr at 4OC in a pressure bottle
(2) (mp 235-237OC)
prepared
resin 1.
in refluxing benzene
nitro-4-brancmethylbenzoic ammonia
peptides
as shown in Scheme I.
Nitration
C-terminal
to remove from the resin.
amide by photolysis
dedtroy acid or base labile protecting thesis of LH-RH is presented
and, therefore,
We report here the synthesis of the 3-nitro-
polystyrene
from resin 1 as the C-terminal
6
groups which can be used to synthe-
peptides with hindered
be useful.
or transesterification.
or transesterification,
and removing protected
would
amide of the pro-
the use of side chain ester protecting
the type of acid labile protecting
size the peptide.
active peptides
These peptides have been
from the resin by amminolysis necessitate
resistent
and secretin.
4
in which the C-terminal
synthesized by solid phase methods' tected peptide was removed
in several biologically
Resin 1
as tbe dicy-
(0.23 mmol/g Boc-NH) WaS
acid 5a in DMF using DCC with the aminomethyl
302
MO. 5
(0.23 mmol/g NH2), which was prepared by amination
resin 5
polystyrene chloride.'**
of chloromethylated
(0.23 mmol/g Cl, 1% divinyl benzene) with liquid ammonia
in methylene
Resin 2 was prepared by treating resin 2 with 50% TFA/CH2C12
followed by neutralization
with triethylamine
prepared by coupling Boc-Gly
in CH2C12.
Resins 2 and J& were
and Boc-Val with resin 2 in DMF using DCC.
Scheme I BocNR CH2Br $3
I
$2B=
CO,H
C02E
CO,H
5a (=2*2 3
Resin 0 u-
y2m2
C02R
P2
C02R
Re~iie&l~Ni-@CR:-R
cRC13
NO2 1,
a
R -
Boc
t33R=I.l
R - Boc-Glyl0? B - Boc-Val2,
Protected (Scheme II).
amino acid amides were formed upon photolysis The resin was suspended
absence of oxygen. 3200 3.
and Boc-Val-NH2
that hindered
at 3500 4 in the
(11)' were isolated in quantitative
amino acid derivatives
from resin -10 under mild conditions. group
and irradiated
A 40% CuSO4 solution was used to filter out wavelengths
Boc-Gly-NH2
which established
in methanol
of resins 2 and 10
can be removed
below
yield,
efficiently
In addition to the Boc group, the 0-benzyl
(on Ser, Tyr, Asp and Glu), and the tosyl group
(on Arg and His) are not
removed by photolysis. Scheme II
The C-terminal III).
Boc-amino
procedure
peptide
using resin 2
(Scheme
acids were coupled stepwise with resin 2 with DCC following the
of Merrifield.4
as described
amide, LH-RH -14 was synthesized
The protected
and after chromatography
decapeptide
resin
and crystallization
(2)
was photolyzed
the protected
decapep-
303
No. 5
tide amide -13 was isolated 8 Gly-resin 2. Scheme
in analytically
pure form in 65% yield based on Boc-
III
O-R synthesis
Na/NE$(liq) p-Glu-His-Trp-Ser-Tyr-Gly-I,eu-Arg-Pro-Gly-RR2 14 -
Decapeptide
13 was converted 10
to LPI-RR -14 by reaction with sodium in liquid
The LPI-RR (l4) was isolated
ammonia
aa described.
parable
to the yields we obtain
in 46% yield
(which is com-
for this reaction on LH-RH prepared
dard solid phase resins) and shown to be identical with authentic protected prepared
heptapeptide
LH-RR. *
The
Boc-Ser(Bzl)-'Pyr(Bzl)-Gly-Leu-Arg(Tos)-Pro-Gly-NEI2
by this method was isolated
Boc-Gly-resin
using stan-
in 56% yield
also
(182 mg),8 based on starting
2, and shown to be identical with a sample prepared by standard
solid phase synthesis. These results establish peptides
as the C-terminal
C-terminal conditions. amide which
that resin 1 can be used to synthesize amides in good yield on a preparative
protected
scale.
Hindered
amino acids, e.g. Val, Leu, Phe, are removed under normal photolysis Thus resin 1 can be useful is difficult
to remove
for the synthesis
from the Merrifield
of C-terminal
peptide
resin under mild condi-
tions. This work was supported by a grant from the National (AM-15507). partial
We thank the Graduate
Institutes
School of the University
of Health
of Wisconsin
for
support of this work.
References 1.
H. Takashima, 1323
(1968).
V. du Vigneaud,
and R. B. Merrifield,
J. Amer. Cbem. &.,
90,
2.
A. V. Schally, A. Arimura",Y. Baba, R. M. G. Nair, Ii.Matsuo, T. W. Redding, L. Debeljuk, and W. F. White, Biochem. Bionhvs. m.
3.
Abbreviations used are:
m.,
43, 393 (1971).
LH-RH, luteinizing hormone-releasing hormone: TFA,
trifluoroacetic acid; DCC, dicyclohexylcarbodiimide; Tos, tosyl; BOC, wbutoxy carbonyl; TEA, triethylamine. 4.
M. Bodansky and J. T. Sheehan, -Chem. Ind. (London), 1597 (1966).
5.
R. B. Merrifield, J. Amer. Chem. a.,
85, 2149 (1963); Intra-Sci. Chem.
Reports, 3, 183 (1971). 6.
El.C. Beyennan, H. Hindriks, and E. W. B. de Leer, 2. C. S. Chem. Comm., 1668 (1968).
7.
D. H. Rich and S. K. Gurwara, 168th National Meeting of the American Chemical Society, Atlantic City, N. J., Sept. 1974, Orgn. 125.
8.
Satisfactory microanalysis, amino acid analysis, mar, ir, tic, and mass spectral data were obtained.
9.
R. Schwyzer, A. Costopanagiotin, and P. Sieber, -Helv. Chim. m,
‘$5, 870
(1970). .O.
M. Manning, E. Coy, and A. Schally in Chemistry and Biology of Peptides, J. Meienhofer, ed., Ann Arbor Science Publishers, 1972, pp. 235-238.
Tetmbodron Letton
Per&smotl Press. PrintedlaQwtBritaia.
RBMOVAL OF C-TERMINAL 3-NITRO-4-AMINOM%THYL-BENZOYL
PEPTIDE AMIDES FROM A AMIDE RESIN BY PHOTOLYSIS K.
Daniel H. Rich and S. School of Pharmacy,
University
Gurwara
of Wisconsin,
Madison, Wisconsin
53706
(Roceivsdin UBA 28 Ootober 1974; raoeived in UK for abliostion 23 Ibomber 1974) The C-terminal
amide group is present
including deamino-oxytocin, 1 LH_m;*'3
However,
these conditions
groups which restrict
are
as the valine methods
to amminolysis
Furthermore,
in secretin.
for preparing
C-terminal
amides
4-aminomethylbenzoylamide
can be difficult
Resin 1 was prepared with N-bromosuccinimide 81% yield7"
acid
derivative &by clohexylamine
to illustrate
4
such
Thus new
from a solid phase as the
Protected peptides
can be removed
under conditions which do not The syn-
the method. Bromination
of E-toluic
gave *brano-E-toluic
acid
acid
(L)
(2) in
of 2 in 90% nitric acid at -lO°C for 2.5 hr gave 3acid
(1) in 85% yield,8 which upon reaction
in 72% yield.
(mp 205-207OC)
by coupling the Boc-nitro
converted
to its Boc-
in D14S08 anti characterized
(85%).
in liquid
gave 3-nitro-4-aminomethylbenzoic
Amino acid &was
reaction with Boc-azide salt z
residues.
groups nor aranatic amino acids.
for 48 hr at 4OC in a pressure bottle
(2) (mp 235-237OC)
prepared
resin 1.
in refluxing benzene
nitro-4-brancmethylbenzoic ammonia
peptides
as shown in Scheme I.
Nitration
C-terminal
to remove from the resin.
amide by photolysis
dedtroy acid or base labile protecting thesis of LH-RH is presented
and, therefore,
We report here the synthesis of the 3-nitro-
polystyrene
from resin 1 as the C-terminal
6
groups which can be used to synthe-
peptides with hindered
be useful.
or transesterification.
or transesterification,
and removing protected
would
amide of the pro-
the use of side chain ester protecting
the type of acid labile protecting
size the peptide.
active peptides
These peptides have been
from the resin by amminolysis necessitate
resistent
and secretin.
4
in which the C-terminal
synthesized by solid phase methods' tected peptide was removed
in several biologically
Resin 1
as tbe dicy-
(0.23 mmol/g Boc-NH) WaS
acid 5a in DMF using DCC with the aminomethyl
302
MO. 5
(0.23 mmol/g NH2), which was prepared by amination
resin 5
polystyrene chloride.'**
of chloromethylated
(0.23 mmol/g Cl, 1% divinyl benzene) with liquid ammonia
in methylene
Resin 2 was prepared by treating resin 2 with 50% TFA/CH2C12
followed by neutralization
with triethylamine
prepared by coupling Boc-Gly
in CH2C12.
Resins 2 and J& were
and Boc-Val with resin 2 in DMF using DCC.
Scheme I BocNR CH2Br $3
I
$2B=
CO,H
C02E
CO,H
5a (=2*2 3
Resin 0 u-
y2m2
C02R
P2
C02R
Re~iie&l~Ni-@CR:-R
cRC13
NO2 1,
a
R -
Boc
t33R=I.l
R - Boc-Glyl0? B - Boc-Val2,
Protected (Scheme II).
amino acid amides were formed upon photolysis The resin was suspended
absence of oxygen. 3200 3.
and Boc-Val-NH2
that hindered
at 3500 4 in the
(11)' were isolated in quantitative
amino acid derivatives
from resin -10 under mild conditions. group
and irradiated
A 40% CuSO4 solution was used to filter out wavelengths
Boc-Gly-NH2
which established
in methanol
of resins 2 and 10
can be removed
below
yield,
efficiently
In addition to the Boc group, the 0-benzyl
(on Ser, Tyr, Asp and Glu), and the tosyl group
(on Arg and His) are not
removed by photolysis. Scheme II
The C-terminal III).
Boc-amino
procedure
peptide
using resin 2
(Scheme
acids were coupled stepwise with resin 2 with DCC following the
of Merrifield.4
as described
amide, LH-RH -14 was synthesized
The protected
and after chromatography
decapeptide
resin
and crystallization
(2)
was photolyzed
the protected
decapep-
303
No. 5
tide amide -13 was isolated 8 Gly-resin 2. Scheme
in analytically
pure form in 65% yield based on Boc-
III
O-R synthesis
Na/NE$(liq) p-Glu-His-Trp-Ser-Tyr-Gly-I,eu-Arg-Pro-Gly-RR2 14 -
Decapeptide
13 was converted 10
to LPI-RR -14 by reaction with sodium in liquid
The LPI-RR (l4) was isolated
ammonia
aa described.
parable
to the yields we obtain
in 46% yield
(which is com-
for this reaction on LH-RH prepared
dard solid phase resins) and shown to be identical with authentic protected prepared
heptapeptide
LH-RR. *
The
Boc-Ser(Bzl)-'Pyr(Bzl)-Gly-Leu-Arg(Tos)-Pro-Gly-NEI2
by this method was isolated
Boc-Gly-resin
using stan-
in 56% yield
also
(182 mg),8 based on starting
2, and shown to be identical with a sample prepared by standard
solid phase synthesis. These results establish peptides
as the C-terminal
C-terminal conditions. amide which
that resin 1 can be used to synthesize amides in good yield on a preparative
protected
scale.
Hindered
amino acids, e.g. Val, Leu, Phe, are removed under normal photolysis Thus resin 1 can be useful is difficult
to remove
for the synthesis
from the Merrifield
of C-terminal
peptide
resin under mild condi-
tions. This work was supported by a grant from the National (AM-15507). partial
We thank the Graduate
Institutes
School of the University
of Health
of Wisconsin
for
support of this work.
References 1.
H. Takashima, 1323
(1968).
V. du Vigneaud,
and R. B. Merrifield,
J. Amer. Cbem. &.,
90,
2.
A. V. Schally, A. Arimura",Y. Baba, R. M. G. Nair, Ii.Matsuo, T. W. Redding, L. Debeljuk, and W. F. White, Biochem. Bionhvs. m.
3.
Abbreviations used are:
m.,
43, 393 (1971).
LH-RH, luteinizing hormone-releasing hormone: TFA,
trifluoroacetic acid; DCC, dicyclohexylcarbodiimide; Tos, tosyl; BOC, wbutoxy carbonyl; TEA, triethylamine. 4.
M. Bodansky and J. T. Sheehan, -Chem. Ind. (London), 1597 (1966).
5.
R. B. Merrifield, J. Amer. Chem. a.,
85, 2149 (1963); Intra-Sci. Chem.
Reports, 3, 183 (1971). 6.
El.C. Beyennan, H. Hindriks, and E. W. B. de Leer, 2. C. S. Chem. Comm., 1668 (1968).
7.
D. H. Rich and S. K. Gurwara, 168th National Meeting of the American Chemical Society, Atlantic City, N. J., Sept. 1974, Orgn. 125.
8.
Satisfactory microanalysis, amino acid analysis, mar, ir, tic, and mass spectral data were obtained.
9.
R. Schwyzer, A. Costopanagiotin, and P. Sieber, -Helv. Chim. m,
‘$5, 870
(1970). .O.
M. Manning, E. Coy, and A. Schally in Chemistry and Biology of Peptides, J. Meienhofer, ed., Ann Arbor Science Publishers, 1972, pp. 235-238.