- Email: [email protected]
Conformational effect on the fragmentations of peptide derivatives in field desorption mass spectrometry
Vol.
146,
No.
July
31,
1987
2, 1987
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
907-911
CONFORMATIONAL EFFECT ON THE FRAGMENTATIONS OF PEPTIDE DERIVATIVES IN FIELD DESORPTIONMASS SPECTROMFTRY Hideaki Eiji
Tsunematsu*t, Shizuko Hachiyama", Ryuichi Isobe**, Ishida*, Mayumi Kakoi", and Magobei Yamamoto"
#Faculty of Pharmaceutical Sciences, Fukuoka University, Nanakuma, Jonan-ku, Fukuoka, 814-01, Japan **Center of Advanced Instrumental Analysis, Faculty of Pharmaceutical Sciences, Kyushu University 62, Maidashi, Higaohi-ku, Fukuoka, 812, Japan Received June 24, 1987
Fragmentations of N-benzyloxycarbonyl-protected tri-peptide ethyl esters containing proline at the P2 site were compared with those of the corresponding peptide derivatives containin no proline in field desorption mass spectrometry. The fragment ion [M-107] F due to a loss of the benzyloxy group from a molecular ion was observed in the field desorption mass spectra for the peptides containing no proline , while it was not found in the peptides containing proline at all. These results suggest that the conformational difference of the peptide derivatives attributable to the existence of proline has an effect upon fragmentations in the field desorption ionizing process. 'G1987 Academic press, 1°C.
It
is well-known
useful
that
Field
method for determining
because it
has a soft
Desorption molecular
ionizing
that
FD mass spectrometry
sequence of small peptides which organic
field
during
molecules
induced surface
(1,2).
is useful Thereare
can be converted
the FD process,
of organic
show the molecular
complex alone as the peak of highest
reported
ions
weights
process for thermolabile
compounds and the FD mass spectra cation
(FD) mass spectrometry
for example,
reactions
relative
compounds,
and nonvolatile ion or molecularintensity.
for determining several
to ions,
It was the amino acid
proposed mechanisms by ion clusters
resonance electron
and thermal
is a
decomposition
or fragment tunneling,
(3-7).
bo whom all correspondence should be addressed. Abbreviations: GPA, p-guanidino-L-phenylalanine; 2, benzyloxycarbonyl; OEt, ethyl ester; FD, Field Desorption; EI, Electron Impact; e.h.c., emitter heating current. 0006-291X/87 $1.50 907
All
Copyright (b 1987 rights qf reproduction
by Academic Press, Inc. in at1.v ,fbrm reserved.
Vol.
146,
No.
2, 1987
BIOCHEMICAL
We have synthesized ethyl
esters
the GPA specific
for
to study the subsite
of the synthetic
we noticed
the peptides
that
containing
analogs
esters
of tri-peptide
viously steric tions
of molecular
fragmentations
the existence
that
this
in peptides it
and analyzed
of N-Z-protected
tri-peptide difference
of Pro at the P2 site
the
them in
that
this
by any other
that
in the fragmenta-
paper we describe
esters
dis-
pre-
also seems possible
ones participate In this
from
was attributable
became clear
it
In addition,
the
group
synthesized fact
which has not been explained
ions in FD process.
with
by FD mass spectro-
were much different
no Pro. We therefore
than electrostatic
depend on the conformational
substrates
As a result,
proposed mechanisms (7). other
of the peptides
of the benzyloxycarbonyl
to ascertain
by FD mass spectrometry.
factors
peptide
of Pro at the P2 site
covery was a new finding
tri-peptide
enzymes. When we confirmed
Pro at the P2 site
those for the peptides
detail
COMMUNICATIONS
(GPA) or arginine
interactions
the fragmentations
containing
to the existence
RESEARCH
p-guanidino-L-phenylalanine
enzyme (8) and trypsin-like
chemicalstructures metry,
BIOPHYSICAL
the N-benzyloxycarbonyl(Z)-protected
(OEt) containing
(Arg) at the P, site
AND
that
the
in FD mass spectrometry
of the peptide
derivatives
due to
in peptides.
MATERIALS AND METHODS All amino acids used in this experiment were L-enantiomers. GPA was synthesized as described previously (9). N-benzyloxycarbonyl-protected tripeptide ethyl esters containing GPA and Arg were prepared by using dicyclohexylcarbodiimide as a coupling reagent. Syntheses of these peptide substrates will be reported in detail elsewhere. The chemical structures of the synthetic peptides were determined with the aid of FD and EI mass spectrometry and elemental analysis. All other chemicals were of analytical or reagent grade. Measurement condition of mass spectrometry The mass spectrometer employed was a JEOL JMS-DX300 double focusing model interfaced to a JEOL JMA-3500 data system (Tokyo,Japan). FD mass spectrometry: Ion source accelerating potential was 3 KV for the field anode and -5 KV for the slotted cathode plate. A dimethyl sulfoxide solution of the sample was applied to the carbon emitter. The emitter heating current (e.h.c.) was mani ulated between 15 and 22 mA, and the optimum e.h.c. for detection of [MtH] P ions was between 19 and 20 mA. In the case of the silicon emitter, the e.h.c. was between 20 and 30 mA, and the optimum e.h.c. for detection of [MtH]+ ions was between 27 and 29 mA. EI mass spectrometry: Ion source accelerating potential was 3 XV, the ionizing voltage was 30 eV and the ionizing current was 300 uA. The spectra were recorded at about 300°C for sample and 25O'C for chamber temperature. 908
Vol.
146,
No.
2, 1987
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
RESULTSAND DISCUSSION Figure
1 shows the FD mass spectra
e.h.c.(A)
and after
protonated
for Z-Gly-Leu-GPA-OEt
optimum e.h.c.(B).
molecular
In the spectrum of Fig.
in that
to this
spectrum,
molecular (Fig.
group.
When the e.h.c.
to about 20 mA, a decrease in the intensity
increase
of the fragment
detectable
were obtained
ion at m/z 447 were observed.
In contrast exhibits
ion at m/z 431 (loss of the benzyloxy
even above optimum e.h.c.(Fig.
when the silicon
for these two peptide
in which a benzylalcohol 91 is benzylcation
emitter
a
2-B). The same results
showed similar
cleavage patterns,
ion at m/z 108 is the base peak and an ion at m/z
(Fig. 3). We therefore
containing
synthesized
tri-peptide
Pro at the P2 site
ethyl
the following esters,
X,W = Ala, Val,
ence of the fragment
ion due to the loss of the benzyloxy
ion.
the peptides
This fragment containing "'
(A)
1
while
it
for
was not in those of the 555 [M + HI+
5
47
2 .E a z .-
the exist-
FD mass spectra
io7
I
some
group from the
1 ,cH~~;~-GI~~;;~;;E:
1 s
Leu, Phe) and investigated
ion was observed in all
no Pro (II),
with
two
and some not (Z-X-Pro-GPA-OEt (I),
Z-X-W-GPA-OEt (II),
molecular
group)
was used. On the other hand, EI mass
derivatives
of analogs of N-Z-protected
analogs
was
of the [M+H]+ and an
the FD mass spectrum for Z-Gly-Pro-GPA-OEt
but the fragment
was barely
kinds
a
ion peak at m/z 539 which is the base peak at optimum e.h.c.
2-A),
spectra
I-A,
ion peak at m/z 555 is the base peak and an ion at m/z
447 is formed by the loss of the benzyloxy raised
at optimum
447[M-107]+ I 0 100
447
(B)
aJ .>
555
:
z -5 cx
108
O
Fig. after
1.
I,..,., I 0
FD mass spectra optimum e.h.c.
100
200
for
300
Z-Gly-Leu-GPA-@Et
500
400
at
(A)
optimum
(m/z) e.h.c.
and
(B)
Vol.
146,
No.
BIOCHEMICAL
2, 1987
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
539
CH2C?-CC-Giy-Pro-Gi’A-CE? (1’4
0,
l
H]’
100-j
.-c
/(B)
Fig. 2. FD mass spectra for Z-Gly-Pro-GPA-OEt at (A) optimum e.h.c. and (B) after optimum e.h.c. peptides
containing
sponding peptides results
Pro (I).
in which GPA at the P, site
suggest that
at the P2 site benzyloxy
The same results
the fragment
in N-Z-protected
tri-peptide
group from the molecular
the peptides
containing
of the other fragment tected
tri-peptide
tional
difference
esters
was displaced
to Arg. These
ion.
esters
due to the loss of the ion at m/z
108
ion was weakly observed in the spectrum
It seems that
may be formed by the fission
the fragmentations
in FD mass spectrometry
of peptide
in the presence of Pro
Though the fragment
Pro (Fig. 2-A), it
ions.
in the corre-
ion was not formed
which was assigned to benzylalcohol for
were obtained
derivatives
of N-Z-pro-
depend upon the conforma-
attributable
to the existence
of
Pro.
100
olL..i’ 100
200
( ml2
)
Fig. 3. EI mass spectra for (A) Z-Gly-Leu-GPA-OEt and (B) Z-Gly-Pro-GPA-OEt 910
Vol. 146, No. 2, 1987
BIOCHEMICAL
The mechanism involved
in the fragmentation
has not yet been clearly this
elucidated.
mechanism the positive
apart
AND BIOPHYSICAL
It
electrostatic
field
and they imply that participate
steric
factors
in the fragmentations
Therefore,
some other
bond occurred
will
for
by this
in the mechanism
ones may
ion in FD process.
mechanism for the fragmentations
in FD mass spectrometry
easily
than electrostatic
of the molecular
that
bond is situated
cannot be explained other
in FD ionizing
recognized
chemical
of this
Our results
(5).
of molecules
is generally
charge localized
from the anode and the fission
RESEARCH COMMUNICATIONS
have to be considered
of the molecular
in order to explain
ion our
results. Model buildings at the P2 site
of the N-Z-protected
show that
the Z-group
of GPA and Arg. The possiblity prevent
the fission
the effect research
that
tri-peptide is brought
the basicity
of the side chains
of the guanidino
At present,
out.
Pro
of N-Z-protected
tri-peptide
to the acidic
work along these lines
group may
To discuss
of the amino acids at the PI site,
about the fragmentations
be required.
containing
so close to the side chains
of C6HFGH20-C bond cannot be ruled .
which the basic amino acids are displaced will
esters
the esters
and neutral
is in progress
in ones in our
laboratory. ACKNOWLEDGMENT
We thank Dr. M. Nakashima (Faculty of Medicine, Kyushu University) many interesting and valuable discussions regarding our research.
for
REFERENCES 1. Winkler, H. V. and Beckey, H. D.(1972) &, 391-398
Biochem. Biophys.
Res. Commun.
2. Asauti-Poku, S., Wood, G. W., and Schmidt Jr., D. E.(l975) Biomed. Mass Spectrom. 2, 121-125 3. Miiller, E. W. (1951) Z. Phys. 131, 136-142 4. Ingraham, M. G. and Gomer, R. J.(1954) J. Chem. Phys. 22, 1279-1280 5. Beckey, H. D (1964) Z. Naturforsch. 19a, 71-83 6. Beckey, H. D. (1977) "Principle of Fmd Ionization and Field Desorption Mass Spectrometry", Pergamon, London, England. 7. Beckey, H. D., Levsen, K., Rollgen, F. W. and Schulten, H. R.(1978) Surf. Sci. 70, 325-362 8. Tsunematsu, H., Mizusaki, K., Makisumi, S., Okamoto, K. and Tsunematsu, Y. (1985) Biochem. Biophys. Res. Commun. 128, 1233-1238 9. Tsunematsu, H., Nishimura, H., Mizusaki, K. and Makisumi, S. (1985) J. Biochem. 97, 617-623 911
146,
No.
July
31,
1987
2, 1987
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
907-911
CONFORMATIONAL EFFECT ON THE FRAGMENTATIONS OF PEPTIDE DERIVATIVES IN FIELD DESORPTIONMASS SPECTROMFTRY Hideaki Eiji
Tsunematsu*t, Shizuko Hachiyama", Ryuichi Isobe**, Ishida*, Mayumi Kakoi", and Magobei Yamamoto"
#Faculty of Pharmaceutical Sciences, Fukuoka University, Nanakuma, Jonan-ku, Fukuoka, 814-01, Japan **Center of Advanced Instrumental Analysis, Faculty of Pharmaceutical Sciences, Kyushu University 62, Maidashi, Higaohi-ku, Fukuoka, 812, Japan Received June 24, 1987
Fragmentations of N-benzyloxycarbonyl-protected tri-peptide ethyl esters containing proline at the P2 site were compared with those of the corresponding peptide derivatives containin no proline in field desorption mass spectrometry. The fragment ion [M-107] F due to a loss of the benzyloxy group from a molecular ion was observed in the field desorption mass spectra for the peptides containing no proline , while it was not found in the peptides containing proline at all. These results suggest that the conformational difference of the peptide derivatives attributable to the existence of proline has an effect upon fragmentations in the field desorption ionizing process. 'G1987 Academic press, 1°C.
It
is well-known
useful
that
Field
method for determining
because it
has a soft
Desorption molecular
ionizing
that
FD mass spectrometry
sequence of small peptides which organic
field
during
molecules
induced surface
(1,2).
is useful Thereare
can be converted
the FD process,
of organic
show the molecular
complex alone as the peak of highest
reported
ions
weights
process for thermolabile
compounds and the FD mass spectra cation
(FD) mass spectrometry
for example,
reactions
relative
compounds,
and nonvolatile ion or molecularintensity.
for determining several
to ions,
It was the amino acid
proposed mechanisms by ion clusters
resonance electron
and thermal
is a
decomposition
or fragment tunneling,
(3-7).
bo whom all correspondence should be addressed. Abbreviations: GPA, p-guanidino-L-phenylalanine; 2, benzyloxycarbonyl; OEt, ethyl ester; FD, Field Desorption; EI, Electron Impact; e.h.c., emitter heating current. 0006-291X/87 $1.50 907
All
Copyright (b 1987 rights qf reproduction
by Academic Press, Inc. in at1.v ,fbrm reserved.
Vol.
146,
No.
2, 1987
BIOCHEMICAL
We have synthesized ethyl
esters
the GPA specific
for
to study the subsite
of the synthetic
we noticed
the peptides
that
containing
analogs
esters
of tri-peptide
viously steric tions
of molecular
fragmentations
the existence
that
this
in peptides it
and analyzed
of N-Z-protected
tri-peptide difference
of Pro at the P2 site
the
them in
that
this
by any other
that
in the fragmenta-
paper we describe
esters
dis-
pre-
also seems possible
ones participate In this
from
was attributable
became clear
it
In addition,
the
group
synthesized fact
which has not been explained
ions in FD process.
with
by FD mass spectro-
were much different
no Pro. We therefore
than electrostatic
depend on the conformational
substrates
As a result,
proposed mechanisms (7). other
of the peptides
of the benzyloxycarbonyl
to ascertain
by FD mass spectrometry.
factors
peptide
of Pro at the P2 site
covery was a new finding
tri-peptide
enzymes. When we confirmed
Pro at the P2 site
those for the peptides
detail
COMMUNICATIONS
(GPA) or arginine
interactions
the fragmentations
containing
to the existence
RESEARCH
p-guanidino-L-phenylalanine
enzyme (8) and trypsin-like
chemicalstructures metry,
BIOPHYSICAL
the N-benzyloxycarbonyl(Z)-protected
(OEt) containing
(Arg) at the P, site
AND
that
the
in FD mass spectrometry
of the peptide
derivatives
due to
in peptides.
MATERIALS AND METHODS All amino acids used in this experiment were L-enantiomers. GPA was synthesized as described previously (9). N-benzyloxycarbonyl-protected tripeptide ethyl esters containing GPA and Arg were prepared by using dicyclohexylcarbodiimide as a coupling reagent. Syntheses of these peptide substrates will be reported in detail elsewhere. The chemical structures of the synthetic peptides were determined with the aid of FD and EI mass spectrometry and elemental analysis. All other chemicals were of analytical or reagent grade. Measurement condition of mass spectrometry The mass spectrometer employed was a JEOL JMS-DX300 double focusing model interfaced to a JEOL JMA-3500 data system (Tokyo,Japan). FD mass spectrometry: Ion source accelerating potential was 3 KV for the field anode and -5 KV for the slotted cathode plate. A dimethyl sulfoxide solution of the sample was applied to the carbon emitter. The emitter heating current (e.h.c.) was mani ulated between 15 and 22 mA, and the optimum e.h.c. for detection of [MtH] P ions was between 19 and 20 mA. In the case of the silicon emitter, the e.h.c. was between 20 and 30 mA, and the optimum e.h.c. for detection of [MtH]+ ions was between 27 and 29 mA. EI mass spectrometry: Ion source accelerating potential was 3 XV, the ionizing voltage was 30 eV and the ionizing current was 300 uA. The spectra were recorded at about 300°C for sample and 25O'C for chamber temperature. 908
Vol.
146,
No.
2, 1987
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
RESULTSAND DISCUSSION Figure
1 shows the FD mass spectra
e.h.c.(A)
and after
protonated
for Z-Gly-Leu-GPA-OEt
optimum e.h.c.(B).
molecular
In the spectrum of Fig.
in that
to this
spectrum,
molecular (Fig.
group.
When the e.h.c.
to about 20 mA, a decrease in the intensity
increase
of the fragment
detectable
were obtained
ion at m/z 447 were observed.
In contrast exhibits
ion at m/z 431 (loss of the benzyloxy
even above optimum e.h.c.(Fig.
when the silicon
for these two peptide
in which a benzylalcohol 91 is benzylcation
emitter
a
2-B). The same results
showed similar
cleavage patterns,
ion at m/z 108 is the base peak and an ion at m/z
(Fig. 3). We therefore
containing
synthesized
tri-peptide
Pro at the P2 site
ethyl
the following esters,
X,W = Ala, Val,
ence of the fragment
ion due to the loss of the benzyloxy
ion.
the peptides
This fragment containing "'
(A)
1
while
it
for
was not in those of the 555 [M + HI+
5
47
2 .E a z .-
the exist-
FD mass spectra
io7
I
some
group from the
1 ,cH~~;~-GI~~;;~;;E:
1 s
Leu, Phe) and investigated
ion was observed in all
no Pro (II),
with
two
and some not (Z-X-Pro-GPA-OEt (I),
Z-X-W-GPA-OEt (II),
molecular
group)
was used. On the other hand, EI mass
derivatives
of analogs of N-Z-protected
analogs
was
of the [M+H]+ and an
the FD mass spectrum for Z-Gly-Pro-GPA-OEt
but the fragment
was barely
kinds
a
ion peak at m/z 539 which is the base peak at optimum e.h.c.
2-A),
spectra
I-A,
ion peak at m/z 555 is the base peak and an ion at m/z
447 is formed by the loss of the benzyloxy raised
at optimum
447[M-107]+ I 0 100
447
(B)
aJ .>
555
:
z -5 cx
108
O
Fig. after
1.
I,..,., I 0
FD mass spectra optimum e.h.c.
100
200
for
300
Z-Gly-Leu-GPA-@Et
500
400
at
(A)
optimum
(m/z) e.h.c.
and
(B)
Vol.
146,
No.
BIOCHEMICAL
2, 1987
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
539
CH2C?-CC-Giy-Pro-Gi’A-CE? (1’4
0,
l
H]’
100-j
.-c
/(B)
Fig. 2. FD mass spectra for Z-Gly-Pro-GPA-OEt at (A) optimum e.h.c. and (B) after optimum e.h.c. peptides
containing
sponding peptides results
Pro (I).
in which GPA at the P, site
suggest that
at the P2 site benzyloxy
The same results
the fragment
in N-Z-protected
tri-peptide
group from the molecular
the peptides
containing
of the other fragment tected
tri-peptide
tional
difference
esters
was displaced
to Arg. These
ion.
esters
due to the loss of the ion at m/z
108
ion was weakly observed in the spectrum
It seems that
may be formed by the fission
the fragmentations
in FD mass spectrometry
of peptide
in the presence of Pro
Though the fragment
Pro (Fig. 2-A), it
ions.
in the corre-
ion was not formed
which was assigned to benzylalcohol for
were obtained
derivatives
of N-Z-pro-
depend upon the conforma-
attributable
to the existence
of
Pro.
100
olL..i’ 100
200
( ml2
)
Fig. 3. EI mass spectra for (A) Z-Gly-Leu-GPA-OEt and (B) Z-Gly-Pro-GPA-OEt 910
Vol. 146, No. 2, 1987
BIOCHEMICAL
The mechanism involved
in the fragmentation
has not yet been clearly this
elucidated.
mechanism the positive
apart
AND BIOPHYSICAL
It
electrostatic
field
and they imply that participate
steric
factors
in the fragmentations
Therefore,
some other
bond occurred
will
for
by this
in the mechanism
ones may
ion in FD process.
mechanism for the fragmentations
in FD mass spectrometry
easily
than electrostatic
of the molecular
that
bond is situated
cannot be explained other
in FD ionizing
recognized
chemical
of this
Our results
(5).
of molecules
is generally
charge localized
from the anode and the fission
RESEARCH COMMUNICATIONS
have to be considered
of the molecular
in order to explain
ion our
results. Model buildings at the P2 site
of the N-Z-protected
show that
the Z-group
of GPA and Arg. The possiblity prevent
the fission
the effect research
that
tri-peptide is brought
the basicity
of the side chains
of the guanidino
At present,
out.
Pro
of N-Z-protected
tri-peptide
to the acidic
work along these lines
group may
To discuss
of the amino acids at the PI site,
about the fragmentations
be required.
containing
so close to the side chains
of C6HFGH20-C bond cannot be ruled .
which the basic amino acids are displaced will
esters
the esters
and neutral
is in progress
in ones in our
laboratory. ACKNOWLEDGMENT
We thank Dr. M. Nakashima (Faculty of Medicine, Kyushu University) many interesting and valuable discussions regarding our research.
for
REFERENCES 1. Winkler, H. V. and Beckey, H. D.(1972) &, 391-398
Biochem. Biophys.
Res. Commun.
2. Asauti-Poku, S., Wood, G. W., and Schmidt Jr., D. E.(l975) Biomed. Mass Spectrom. 2, 121-125 3. Miiller, E. W. (1951) Z. Phys. 131, 136-142 4. Ingraham, M. G. and Gomer, R. J.(1954) J. Chem. Phys. 22, 1279-1280 5. Beckey, H. D (1964) Z. Naturforsch. 19a, 71-83 6. Beckey, H. D. (1977) "Principle of Fmd Ionization and Field Desorption Mass Spectrometry", Pergamon, London, England. 7. Beckey, H. D., Levsen, K., Rollgen, F. W. and Schulten, H. R.(1978) Surf. Sci. 70, 325-362 8. Tsunematsu, H., Mizusaki, K., Makisumi, S., Okamoto, K. and Tsunematsu, Y. (1985) Biochem. Biophys. Res. Commun. 128, 1233-1238 9. Tsunematsu, H., Nishimura, H., Mizusaki, K. and Makisumi, S. (1985) J. Biochem. 97, 617-623 911