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Peptide sequencing using the combination of Edman degradation, carboxypeptidase digestion and Fast Atom Bombardment mass spectrometry
Vol. 104, No. 4, 1982 February 26, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Pages 1223-1230
PEPTIDE SEQUENCING USING THE COMBINATION OF EDMAN DEGRADATION, CARBOXYPEPTIDASE DIGESTION AND FAST ATOM BOMBARDMENTMASS SPECTROMETRY Carol Chemical
University
and Dudley Lensfield
H. Williams Road, Cambridge,
Michael R. Hanley Pharmacology Unit, Medical Cambridge
Neurochemical
Received
V. Bradley Laboratory,
November
23,
Research
Centre,
CB2 1EW
Hills
Road
1981
It is shown that the application of Fast Atom Bombardment (FAB) mass spectrometry to the sequence determination of peptides can be aided if the technique is used in conjunction with systemBoth the Edman degradation and atic cleavage of the peptides. carboxypeptidase digestion have been successfully applied in the sequence analysis of model synthetic peptides and mixtures of such peptides. Introduction Peptide of N-acetyl special
sequencing permethyl
advantages
N-terminally (lo-30
containing sequenced
by this
the
ability
size;
studied
to
study
with
are routinely
1,2
required
residues
and has some
in the study
mixtures.
Small
of amounts
and peptides
can be conveniently
of FAB mass spectrometry technique
for
to
study
peptide
sequencing
peptides; larger
4 and 20 amino acid
our present
by Barber
advantages
underivatized
facility
between
mass spectrometry
established
sequencing
and their
The most significant
and the
containing
peptides
(EI)
technique.
another
spectrometry.
is well
4 and 9 amino acid
The introduction has provided
impact
conventional
of peptide
between
electron
derivatives
over
blocked
nanomoles)
using
et al3
by mass
of this
method are
a reduction
in sample
peptides.
4s
residues
are conveniently
Peptides
equipment. 0006-291X/82/041223-08$01.00/0 1223
Copyright 0 1982 by Academic Press, Inc. All nghrs of reproduciion in any form reserved.
BIOCHEMICAL
Vol. 104, No. 4, 1982
A sample size sufficient
for
of
approximately
molecular
weight
or negative
ion mode, but
amino acids
to be determined.
between
both
are observed
complete
sequence
and negative
of sequence
is clearly
(>50 nanomoles) for
not
often
some peptides.
and the allow
peptide
the complete
EI mass spectrometry mass spectrometry6 sample sizes nanomoles
of generating digestion removal
to generate
reported
Materials
molecular
a mixture
and their
varies
dependent since
is
considerably. on sample size
large
extensive
sample sizes
sequence
frequently
sequence
peptides
For weight
information
with
This
the
in the positive
information
not ions
complete
does not
complements
from the disadvantage
amino acid
alternative.
model peptides
factor
required.
coupled
may enable
determination.
suffers
high
of N-terminal
mising
sample sizes peptides,
residues
via
larger
less
than
fragments, the
preliminary
methods
and chemica
subtractive offer
has been successfully
mixtures,and
a pro-
applied
results
are
and Methods peptides
San Carlos,
were obtained
California. 1224
20
Carboxypeptidase
FAB mass spectrometry
strategy
that
alternative
are desirable. of C-terminal
FAB
here.
Synthetic Inc.,
but
sequence
Edman degradation,
in part
of derivatized
are usually
and for
is
C or N terminal
sequence
and this
of peptides
to provide
either
Sequ-
ion modes from
available
Sequence information
absence of
information.
to be determined.
the only
fail
sequence of
typically
and negative
information
ions
the positive
the
sample sizes,
of the peptide
sequence
allow
some sequence
ion FAB mass spectra
The abundance but this
Larger
is generally
in either
normally
in the positive
of the
The amount of
determination
afford
the N- and C-termini
RESEARCH COMMUNICATIONS
0.1 nanomoles
does not
1 and 5 nanomoles,
ence ions
AND BIOPHYSICAL
from Peninsula
Laboratories
to
BIOCHEMICAL
Vol. 104, No. 4, 1982
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Edman Degradation: Various modifications of the Edman reaction sequence were investigated. The most successful method for combination with FAB mass spectrometry appeared to be the following: 1. Coupling: 5-10 nmol of peptide were dissolved in 200~1 of 50% aqueous pyridine. 100~1 of 5% phenylisothiocyanate in pyridine were added and purged with oxygen-free nitrogen, at 37OC for 1 hour. The solution was capped, and incubated extracted twice with heptane:ethyl acetate 2:l v/v and lyopholized. 2. Cleavage: 150~1 of trifloroacetic acid were added to the above product, the solution purged with oxygen-free nitrogen, at 37OC for 30 minutes, and then lyopholized. capped, incubated 3. Extraction: The lyopholized product was suspended in 1 ml of distilled water and the phenvlthiocarbodimide amino acid derivative extracted into l-ml of n-butyl acetate. The aqueous layer was lyopholized and the product redissolved in 200~1 of 50% pyridine. 40 ~1 (l-2 nmol of peptide) were withdrawn, lyopholized and analysed by FAB mass spectrometry. The remaining solution was subjected to the next cycle of degradation. Carboxypeptidase Y Digestion: The peptide mixture (ca. 10 nmol) was digested using carboxypeptidase Y from Bakers Yeast (Sigma Chemical Company) with a 5O:l molar ratio of substrate to enzyme in 1 ml of distilled water. The solution was incubated at 37OC and samples (ca. 2 nmol) were withdrawn at 2,4,6 and 18 hour intervals, and the mixture of products isolated by lyopholization.
Results
and Discussion
Figure molecular
1 shows the positive ion regions
Edman degradation LYS
Pro
of peptides
l(a)
and the
generated
of nona-substance Gln
IA--I-AI 965 868 Figure
ion FAB mass spectra
Gln 740
shows a mixture
sodium salt
Phe
Phe
at -m/z 1094 and the
octa-peptide
have the
Met
NH2 -1
of the
of
glutamine
GUY Leu
612
The mass difference
an N-terminal
subtractive
P (1).
protonated
m/z 988 obtained --
indicates
by the
of the
128 between
lysine
same nominal
after the
intact
generated or glutamine
molecular the
first
ion m/z 966 --
Edman cycle.
nona-substance by Edman degradation residue.
(Lysine
mass but may be distinguished 1235
P MH+
and by
Vol. 104, No. 4, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
MNO+ 891
MH* 741
MN2 763
Figure
1:
acetylation
The positive ion FAB mass spectra of the molecular ion regions of peptides generated by the subtractive Edman degradation of nona-substance P.
of
heptapeptide in Figure
former).
generated l(b).
sodium salt
The molecular
after
The protonated
The ions
ated molecular
Edman cycles
residues
the
of
are reproduced
ions
for
ions
of the is
reproduced
ion at -m/z 869 and the
second N-terminal
form
amino acid
907 are due to the (oxidation
proton-
of methionine)
respectively.
the
the
products
in Figures
hexapeptide
741 and 613 respectively. molecular
molecular
ion of the oxidized
sodium salt,
ion region
second Edman cycle
at -m/z 885 and m/z --
The FAB mass spectra
molecular
the
at -m/z 891 establish
as proline.
and the
the
establish
as two glutamines.
of the third
and fourth
and l(d).
Protonated
l(c)
and pentapeptide
Mass differences the
third
and fourth
In the positive 1226
of
occur
128 between N-terminal
ion
spectrum
at m/z -the amino acid of
the
Vol. 104, No. 4, 1982
pentapeptide,
Figure
to the product amino acid
BIOCHEMICAL
l(d),
obtained
residues
Edman degradation
size
of -ca.
RESEARCH COMMUNICATIONS
at m/z 629 is again -of methionine.
However,
the
fourth
in principle
of
further
of the
cycle
N-terminal
has been achieved
with
by the
sample
allowing
to observe
degree
unambiguous
of N-terminal amenable mixture
residues.
to the
study
containing
of simple
5 nanomoles
Ll965
cs
r
706
578
Gln
mixtures. of both
presented
For example, eledoisin-related
assignment here
is
is
a synthetic peptide
P (2) was subjected
to the Edman degradation.
Ile
NH2
Gly
Leu
Met
Phe
Phe
GUY Leu
ion FAB mass spectrum reproduced
in Figure
and associated
Met
NH2
from structure
related
peptide
Both visible
the
protonated (in
metal
generated
-2 produced
the
salts
same spectrum
I227
the
first
molecular
at -m/z 891 and
by removal
of N-terminal
of the eledoisin-
a pentapeptide
molecular
and 907) at -m/z 579 and 601 respectively
after
The protonated
Edman degradation
2.
structure
obtained
2.
alkali
heptapeptide
proline
are clearly
strategy
a high
-3
907 are due to the
578.
for
the
868
ion at -m/z 869,
weight
the
requires
all
of
2 -
Gln
The positive Edman cycle
peptide
However,
(2) and octa-substance
Pro
original
the
FAB mass spectrometry
although it is not always possible 5 components. The classical Edman degradation of the
sample
determinations.
mixtures,
of purity
four
subtrac-
on a total
a proportion
degradation
attributed
The first
been determined
and FAB mass spectrometry
after
Some success
ion
by oxidation
10 nanomoles.
remained
possibility
the
have therefore
tive
still
AND BIOPHYSICAL
of molecular
ion and the that (Figure
gives 2).
sodium salt
m/z 869, --
891
Vol. 104, No. 4, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
I
MH+ 579
MNa*
Figure
2:
The positive ion FAB mass spectrum of peptides from eledoisin-related peptide and octa-substance after the first Edman cycle.
Subtractive
Edman degradation
fragments,
for
successful
presumably
organic for
example
extraction
peptides
used in this unable
success
of C-terminal sequence using
peptides
C-termini,
subtractive
the
were less
information
carboxypeptidase
in the
noticeable for
substance
example
the
P related
peptides
Edman degradation
was
information.
use of carboxypeptidase
peptide
1228
peptide
are more soluble
was particularly
sequence
problem,
on shorter
and tripeptides,
common to the
Hence the
this
C-terminal obtained
This
C-terminal
mixtures
was
small
hydrophobic
sequence
study.
To overcome
determine
since
containing
to provide
generate
tetrapeptides
solvents.
X-Gly-Leu-Met-NH2
studies
generated P
fragments,
and hence to
was investigated. Y to
to
digest
Some a mixture
Vol. 104, No. 4, 1982
of
BIOCHEMICAL
5 nmol eledoisin-related
variation
of the
enable
the
example,
ion of
peptide
enzyme:substrate
observation
analysis
essentially
AND BIOPHYSICAL
of
of the
unchanged
all
and octa-substance ratio
C-terminal
2 hour digestion
octa-substance
time
However, did not
fragments.
For
sample by FAB showed
P and a small
peptide
P.
and reaction
possible
the eledoisin-related
RESEARCH COMMUNICATIONS
to give
the
amount of digestdigestion
products
-a and -b shown in -4. Phe
LYS
b
C
Six
hour digestion
octa-substance products
fragment
a large
amount of unreacted
no intact
digestion
Gln
study
Phe
it
digestion
would
provide
differing
rates
for
observation
GUY Leu
However no additiona
Met
that
C-terminal
sequencg since
C-terminal
peptide
of
C-terminal
fragments.
all
reduces
the possible
NH2
carboxypeptidase
cleaving
and often
determined,
provides
some
C-terminal
by two amino acid
sequence
limiting
the possible 1229
However,
compositions.
are often
combinations.
the
information,
amino acid
residues
the
bonds do not
sum of the masses of two amino acid
thus
obtained
-5
unlikely
a complete
generally
and hence the
peptide
--I d
appears
mixture
differing
and an
P and a small
peptide.
Phe
digestion
Products
products
octa-substance
I
the
P, 2,
from eledoisin-related
e
allow
digestion
were observed.
Gln
From this
of undigested
However,
octa-substance
eledoisin-related
products Pro
for
carboxypeptidase
revealed
proportion
peptide.
-e was generated
of the
18 hours
digestion
-4
P and eledoisin-related
Analysis
after
indicated
a and e were observed
additional --4
again
a
observed
residues
may be
Vol. 104, No. 4, 1982
It
is
digestion
concluded
that
offers
ation
from peptides.
AND BIOPHYSICAL
the
and subtractive
metry
to small
BIOCHEMICAL
combination
of
Edman degradation
a promising
strategy
carboxypeptidase with
FAB mass spectro-
from obtaining
The combination
sample sizes
RESEARCH COMMUNICATIONS
and extensive
sequence
of techniques purification
inform-
is applicable
of peptides
is
unneccessary. References 1.
Morris, H-R., Williams, J ., 125, 189-201.
2.
Morris,
3.
Barber, M., Bordoli, (1981) Nature, 293,
4.
Williams, Biochem.
5.
Morris, H.R., Panico, M., Barber, M., Bordoli, R.D., and Tyler, A.N., (1981) Biochem. Biophys. 101, 623-631.
6.
Williams, D.H., Bojesen, G., Auffret, (1981) FEBS. Letts., 128, 37-39.
H.R.,
(1980)
D-H., Nature,
and Ambler, 286,
C.V.,
1230
(1971)
Biochem.
447-452.
R-S., Sedgwick, 270-275.
D.H., Bradley, J., in press.
R.P.,
R-D.,
Santikarn,
A.D.,
and Tyler, S.,
A.N.,
and Bojesen,
G.,
R.S., Sedgwick, Res. Comm.,
and Taylor,
L.C.E.,
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Pages 1223-1230
PEPTIDE SEQUENCING USING THE COMBINATION OF EDMAN DEGRADATION, CARBOXYPEPTIDASE DIGESTION AND FAST ATOM BOMBARDMENTMASS SPECTROMETRY Carol Chemical
University
and Dudley Lensfield
H. Williams Road, Cambridge,
Michael R. Hanley Pharmacology Unit, Medical Cambridge
Neurochemical
Received
V. Bradley Laboratory,
November
23,
Research
Centre,
CB2 1EW
Hills
Road
1981
It is shown that the application of Fast Atom Bombardment (FAB) mass spectrometry to the sequence determination of peptides can be aided if the technique is used in conjunction with systemBoth the Edman degradation and atic cleavage of the peptides. carboxypeptidase digestion have been successfully applied in the sequence analysis of model synthetic peptides and mixtures of such peptides. Introduction Peptide of N-acetyl special
sequencing permethyl
advantages
N-terminally (lo-30
containing sequenced
by this
the
ability
size;
studied
to
study
with
are routinely
1,2
required
residues
and has some
in the study
mixtures.
Small
of amounts
and peptides
can be conveniently
of FAB mass spectrometry technique
for
to
study
peptide
sequencing
peptides; larger
4 and 20 amino acid
our present
by Barber
advantages
underivatized
facility
between
mass spectrometry
established
sequencing
and their
The most significant
and the
containing
peptides
(EI)
technique.
another
spectrometry.
is well
4 and 9 amino acid
The introduction has provided
impact
conventional
of peptide
between
electron
derivatives
over
blocked
nanomoles)
using
et al3
by mass
of this
method are
a reduction
in sample
peptides.
4s
residues
are conveniently
Peptides
equipment. 0006-291X/82/041223-08$01.00/0 1223
Copyright 0 1982 by Academic Press, Inc. All nghrs of reproduciion in any form reserved.
BIOCHEMICAL
Vol. 104, No. 4, 1982
A sample size sufficient
for
of
approximately
molecular
weight
or negative
ion mode, but
amino acids
to be determined.
between
both
are observed
complete
sequence
and negative
of sequence
is clearly
(>50 nanomoles) for
not
often
some peptides.
and the allow
peptide
the complete
EI mass spectrometry mass spectrometry6 sample sizes nanomoles
of generating digestion removal
to generate
reported
Materials
molecular
a mixture
and their
varies
dependent since
is
considerably. on sample size
large
extensive
sample sizes
sequence
frequently
sequence
peptides
For weight
information
with
This
the
in the positive
information
not ions
complete
does not
complements
from the disadvantage
amino acid
alternative.
model peptides
factor
required.
coupled
may enable
determination.
suffers
high
of N-terminal
mising
sample sizes peptides,
residues
via
larger
less
than
fragments, the
preliminary
methods
and chemica
subtractive offer
has been successfully
mixtures,and
a pro-
applied
results
are
and Methods peptides
San Carlos,
were obtained
California. 1224
20
Carboxypeptidase
FAB mass spectrometry
strategy
that
alternative
are desirable. of C-terminal
FAB
here.
Synthetic Inc.,
but
sequence
Edman degradation,
in part
of derivatized
are usually
and for
is
C or N terminal
sequence
and this
of peptides
to provide
either
Sequ-
ion modes from
available
Sequence information
absence of
information.
to be determined.
the only
fail
sequence of
typically
and negative
information
ions
the positive
the
sample sizes,
of the peptide
sequence
allow
some sequence
ion FAB mass spectra
The abundance but this
Larger
is generally
in either
normally
in the positive
of the
The amount of
determination
afford
the N- and C-termini
RESEARCH COMMUNICATIONS
0.1 nanomoles
does not
1 and 5 nanomoles,
ence ions
AND BIOPHYSICAL
from Peninsula
Laboratories
to
BIOCHEMICAL
Vol. 104, No. 4, 1982
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Edman Degradation: Various modifications of the Edman reaction sequence were investigated. The most successful method for combination with FAB mass spectrometry appeared to be the following: 1. Coupling: 5-10 nmol of peptide were dissolved in 200~1 of 50% aqueous pyridine. 100~1 of 5% phenylisothiocyanate in pyridine were added and purged with oxygen-free nitrogen, at 37OC for 1 hour. The solution was capped, and incubated extracted twice with heptane:ethyl acetate 2:l v/v and lyopholized. 2. Cleavage: 150~1 of trifloroacetic acid were added to the above product, the solution purged with oxygen-free nitrogen, at 37OC for 30 minutes, and then lyopholized. capped, incubated 3. Extraction: The lyopholized product was suspended in 1 ml of distilled water and the phenvlthiocarbodimide amino acid derivative extracted into l-ml of n-butyl acetate. The aqueous layer was lyopholized and the product redissolved in 200~1 of 50% pyridine. 40 ~1 (l-2 nmol of peptide) were withdrawn, lyopholized and analysed by FAB mass spectrometry. The remaining solution was subjected to the next cycle of degradation. Carboxypeptidase Y Digestion: The peptide mixture (ca. 10 nmol) was digested using carboxypeptidase Y from Bakers Yeast (Sigma Chemical Company) with a 5O:l molar ratio of substrate to enzyme in 1 ml of distilled water. The solution was incubated at 37OC and samples (ca. 2 nmol) were withdrawn at 2,4,6 and 18 hour intervals, and the mixture of products isolated by lyopholization.
Results
and Discussion
Figure molecular
1 shows the positive ion regions
Edman degradation LYS
Pro
of peptides
l(a)
and the
generated
of nona-substance Gln
IA--I-AI 965 868 Figure
ion FAB mass spectra
Gln 740
shows a mixture
sodium salt
Phe
Phe
at -m/z 1094 and the
octa-peptide
have the
Met
NH2 -1
of the
of
glutamine
GUY Leu
612
The mass difference
an N-terminal
subtractive
P (1).
protonated
m/z 988 obtained --
indicates
by the
of the
128 between
lysine
same nominal
after the
intact
generated or glutamine
molecular the
first
ion m/z 966 --
Edman cycle.
nona-substance by Edman degradation residue.
(Lysine
mass but may be distinguished 1235
P MH+
and by
Vol. 104, No. 4, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
MNO+ 891
MH* 741
MN2 763
Figure
1:
acetylation
The positive ion FAB mass spectra of the molecular ion regions of peptides generated by the subtractive Edman degradation of nona-substance P.
of
heptapeptide in Figure
former).
generated l(b).
sodium salt
The molecular
after
The protonated
The ions
ated molecular
Edman cycles
residues
the
of
are reproduced
ions
for
ions
of the is
reproduced
ion at -m/z 869 and the
second N-terminal
form
amino acid
907 are due to the (oxidation
proton-
of methionine)
respectively.
the
the
products
in Figures
hexapeptide
741 and 613 respectively. molecular
molecular
ion of the oxidized
sodium salt,
ion region
second Edman cycle
at -m/z 885 and m/z --
The FAB mass spectra
molecular
the
at -m/z 891 establish
as proline.
and the
the
establish
as two glutamines.
of the third
and fourth
and l(d).
Protonated
l(c)
and pentapeptide
Mass differences the
third
and fourth
In the positive 1226
of
occur
128 between N-terminal
ion
spectrum
at m/z -the amino acid of
the
Vol. 104, No. 4, 1982
pentapeptide,
Figure
to the product amino acid
BIOCHEMICAL
l(d),
obtained
residues
Edman degradation
size
of -ca.
RESEARCH COMMUNICATIONS
at m/z 629 is again -of methionine.
However,
the
fourth
in principle
of
further
of the
cycle
N-terminal
has been achieved
with
by the
sample
allowing
to observe
degree
unambiguous
of N-terminal amenable mixture
residues.
to the
study
containing
of simple
5 nanomoles
Ll965
cs
r
706
578
Gln
mixtures. of both
presented
For example, eledoisin-related
assignment here
is
is
a synthetic peptide
P (2) was subjected
to the Edman degradation.
Ile
NH2
Gly
Leu
Met
Phe
Phe
GUY Leu
ion FAB mass spectrum reproduced
in Figure
and associated
Met
NH2
from structure
related
peptide
Both visible
the
protonated (in
metal
generated
-2 produced
the
salts
same spectrum
I227
the
first
molecular
at -m/z 891 and
by removal
of N-terminal
of the eledoisin-
a pentapeptide
molecular
and 907) at -m/z 579 and 601 respectively
after
The protonated
Edman degradation
2.
structure
obtained
2.
alkali
heptapeptide
proline
are clearly
strategy
a high
-3
907 are due to the
578.
for
the
868
ion at -m/z 869,
weight
the
requires
all
of
2 -
Gln
The positive Edman cycle
peptide
However,
(2) and octa-substance
Pro
original
the
FAB mass spectrometry
although it is not always possible 5 components. The classical Edman degradation of the
sample
determinations.
mixtures,
of purity
four
subtrac-
on a total
a proportion
degradation
attributed
The first
been determined
and FAB mass spectrometry
after
Some success
ion
by oxidation
10 nanomoles.
remained
possibility
the
have therefore
tive
still
AND BIOPHYSICAL
of molecular
ion and the that (Figure
gives 2).
sodium salt
m/z 869, --
891
Vol. 104, No. 4, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
I
MH+ 579
MNa*
Figure
2:
The positive ion FAB mass spectrum of peptides from eledoisin-related peptide and octa-substance after the first Edman cycle.
Subtractive
Edman degradation
fragments,
for
successful
presumably
organic for
example
extraction
peptides
used in this unable
success
of C-terminal sequence using
peptides
C-termini,
subtractive
the
were less
information
carboxypeptidase
in the
noticeable for
substance
example
the
P related
peptides
Edman degradation
was
information.
use of carboxypeptidase
peptide
1228
peptide
are more soluble
was particularly
sequence
problem,
on shorter
and tripeptides,
common to the
Hence the
this
C-terminal obtained
This
C-terminal
mixtures
was
small
hydrophobic
sequence
study.
To overcome
determine
since
containing
to provide
generate
tetrapeptides
solvents.
X-Gly-Leu-Met-NH2
studies
generated P
fragments,
and hence to
was investigated. Y to
to
digest
Some a mixture
Vol. 104, No. 4, 1982
of
BIOCHEMICAL
5 nmol eledoisin-related
variation
of the
enable
the
example,
ion of
peptide
enzyme:substrate
observation
analysis
essentially
AND BIOPHYSICAL
of
of the
unchanged
all
and octa-substance ratio
C-terminal
2 hour digestion
octa-substance
time
However, did not
fragments.
For
sample by FAB showed
P and a small
peptide
P.
and reaction
possible
the eledoisin-related
RESEARCH COMMUNICATIONS
to give
the
amount of digestdigestion
products
-a and -b shown in -4. Phe
LYS
b
C
Six
hour digestion
octa-substance products
fragment
a large
amount of unreacted
no intact
digestion
Gln
study
Phe
it
digestion
would
provide
differing
rates
for
observation
GUY Leu
However no additiona
Met
that
C-terminal
sequencg since
C-terminal
peptide
of
C-terminal
fragments.
all
reduces
the possible
NH2
carboxypeptidase
cleaving
and often
determined,
provides
some
C-terminal
by two amino acid
sequence
limiting
the possible 1229
However,
compositions.
are often
combinations.
the
information,
amino acid
residues
the
bonds do not
sum of the masses of two amino acid
thus
obtained
-5
unlikely
a complete
generally
and hence the
peptide
--I d
appears
mixture
differing
and an
P and a small
peptide.
Phe
digestion
Products
products
octa-substance
I
the
P, 2,
from eledoisin-related
e
allow
digestion
were observed.
Gln
From this
of undigested
However,
octa-substance
eledoisin-related
products Pro
for
carboxypeptidase
revealed
proportion
peptide.
-e was generated
of the
18 hours
digestion
-4
P and eledoisin-related
Analysis
after
indicated
a and e were observed
additional --4
again
a
observed
residues
may be
Vol. 104, No. 4, 1982
It
is
digestion
concluded
that
offers
ation
from peptides.
AND BIOPHYSICAL
the
and subtractive
metry
to small
BIOCHEMICAL
combination
of
Edman degradation
a promising
strategy
carboxypeptidase with
FAB mass spectro-
from obtaining
The combination
sample sizes
RESEARCH COMMUNICATIONS
and extensive
sequence
of techniques purification
inform-
is applicable
of peptides
is
unneccessary. References 1.
Morris, H-R., Williams, J ., 125, 189-201.
2.
Morris,
3.
Barber, M., Bordoli, (1981) Nature, 293,
4.
Williams, Biochem.
5.
Morris, H.R., Panico, M., Barber, M., Bordoli, R.D., and Tyler, A.N., (1981) Biochem. Biophys. 101, 623-631.
6.
Williams, D.H., Bojesen, G., Auffret, (1981) FEBS. Letts., 128, 37-39.
H.R.,
(1980)
D-H., Nature,
and Ambler, 286,
C.V.,
1230
(1971)
Biochem.
447-452.
R-S., Sedgwick, 270-275.
D.H., Bradley, J., in press.
R.P.,
R-D.,
Santikarn,
A.D.,
and Tyler, S.,
A.N.,
and Bojesen,
G.,
R.S., Sedgwick, Res. Comm.,
and Taylor,
L.C.E.,