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Analysis of mixtures of ionic compounds using Fast Atom Bombardment and a triple analyzer mass spectrometer
International Journal ofhfass Elsevier Scientific Publishing
Analysis
of Mixtures
Analyzer
Mass
K.B.
Tomer,
of
Crow,
Center
Lincoln,
NE
Ionic
Compounds
Using
Fast
Atom
Bombardment
and a Triple
Spectrometer
F.W.
Midwest
375
Spectrometry and Ton Physics, 46 (1983) 375-378 Company, Amsterdam - Printed in The Netherlands
and M.L.
for
Gross
Mass
Spectrometry,
University
Nebraska,
of
68588
ABSTRACT The combination of fast atom bombardment (FAB) and mass spectrometry/mass spectrometry (MS/MS) has been applied to the analysis of cyclic peptides and anionic surfactants. INTRODUCTION The
recently
itself
to
be
applicable
zwitterionic spectra
combination
chemical
spectra MS/MS
are can
can
simple
serve
from
CYCLIC
been
of
as a separation ions
some
peptides
for
by be
the
metal
however,
the
analysis other
combination using
3) for
recent
FAB.
in cases
and
a
with
and
removed
component
The of amino
are:
MS/MS; where
isolates
additional
2)
a
the
FAB
of
the
which
are
MS-I
the
1)
structural
(ref.3).
of our
anionic
and mass
or
also
for
peptides
produced
reversal
results and
is
information;
each
easily
by charge
present
of cyclic
stage
the
often,
parallel
activation
structural
are
is
shown
ionic
general,
advantages
can
and
devoid
in
offered
matrix
polar,
deprotonated,
(ref.21
cyclic
by collisional
negative we
distinct
advantages
glycerol
In
has
solvent.
developed
and
(FAB)
of
There
(MS/MS)
offers
linear
the
can be produced paper
(ref.1).
analysis
a protonated,
be produced
information analysis
spectrometry
the mobilizing
The
4)
In this
and
has
as
mixtures;
the
vaporization of
bambardment
fragmentation.
from
and
such
noise
atom
spectrometry
materials.
spectrum"
fast
largely
of the two techniques
acid-containing "mass
arising
advance
compounds
of
limited
spectrometry/mass
instrumentation
the
mass
and
background
Mass
by
the
consisting
simple, molecule
extensive
technique for
compounds
are
cationized
polar
announced
application
of FAB and MS/MS
to
compounds.
PEPTIDES
Underivatized mass
spectra
ions
which
peptides
are
of derivatized can
result
OOZO-7381/83/0000-0000/$03.00
difficult
cyclic in
peptides
incorrect Q
to
analyze are often
sequencing.
1983 Elsevier Scientific
by
mass
plagued Since
spectrometry. with
rearrangement
collision
Publishing Company
The induced
376 decomposition than the
(CID}
rearrangements, analysis
of
and sequencing
spectra
are
we have
applied
underivatized
typically
dominated
the
cyclic
combined
peptides
by simple
techniques
to
cleavages
both
molecular
weight
analysis
of
cyclic
obtain
information.
An example I@B98 *e ,e_ GB _ IB_ ,e_ lb no_ ,e_ B
of
our
results
can
be illustrated
by the
the
1 obo
560 Fig.
rather
FAD and MS/MS to
of
1. FAB Mass Spectrum
Fig.
of
2. CID Spectrum
Protonated
Ion of Cyclo-(Leu-Pro-Gly)4;
Molecular
Cyclo-(Leu-Pro-Gly)4
of the
peak b=MH-Leu-gly;
peak
a=MH-Leu;
peak
c=MH-Leu-gly-pro;
gly-Pro-gly;
peak
d=MH-Leu-
peak e=MH-(Pro-Gly-Leu)2;
peak f =MH-(Pro-Gly-Leu)2-Leu MH-(Pro-Gly-Leu)2-Leu MH-(Pro-Gly-Leu)
; peak g=
gly;
3; peak
peak h=
i=MH-(Pro-
Gly-Leu)3-Leu
cl
Y
NH-CH-COI
N +li
Y
I Leu
GUY
I
I
Pro-leu-Gly-Pro-Leu-Gly-Pro
Scheme 1.
Loss of
dodecapeptide, observed m/z Leu-,
at
Gly
-
1069
and
Pro
(see to then
co -01
Gly
I
Pro-Lsu-Gly-Pro-Leu-Gly-Pro
refers
to
loss
cyclo-(Leu-Pro-Gly)4. m/z
535 corresponding Gly,
0 HN
:H-C&CO+
CO-Gly
Fig. loss occur.
of An
1). of
COCH2NH, for intense
The first two The
y
I Y”
protonated
major
Pro-Gly-Leu CID spectrum
example.
fragment
sequences. of
the
molecular ion
is
ion
is
observed
at
Sequential protonated
loss molecular
of
377 ion
2)
(Fig.
shows
complete
successive
amjno
spectrum.
The fragmentation
proton&ion
on
the
Another was
by
patterns
the
application of
easily
can from of
the
the
major
due
peaks
in
based
cleavage
acylium
ion
FAB MS/MS to
cyclic
spectrum
assigned
on the
to peptide
acyl 1). which
The of
the
sequencing
(ref.4),
(ref.5). basis
an
(scheme
Toxin
to
on initial
form
terminus
carbonum
EI mass
definitively
the
explained
bond
Helminthosporium
using
and
comprise
-N-C=0
Ions
information.
be readily
with
initiated
analysis
sequence
CO losses)
nitrogen
incorrectly
was
acid
(and/or
then
of
the
sequenced
sequence
is
example
provided
losses prolyl
Fragmentation
ion. is
acid
amino
the
correct
FAB/MS/MS
results. Thus, to
the
application
provide
1 ittle
molecular
or
no
more cyclic ANIONIC
weight
interference
peptides
and
from
to
relatively
phosphates
Fig.
FAB/MS/MS to
test
the
analysis
straightforward
rearrangement
the
genera?ity
of
cyclic
sequencing processes.
of
these
peptides information
We are
and
,
.
3A.
.
simple phosphonates,
.
Negative
.
.
sb‘.
Ion
anionic are
organic difficult
of
compounds to
-
CID Spectrum
n/2
acid.
with
investigating
results.
the
analyze
rdo M-H Anion
of
such due
as to
su 1fonates, problems
1.30 Benzenephosphonic
acid.
Fig.
appears
COMPOUNDS
Some
.
of
36.
Charge
Reversal
51
Spectrum
of the
M-l Anion of Benzenephosphonic
in
378 removing
them from
(ref.6)
have
utilized
field
sulfonated
surfactants
FAB/MS/MS,
we have
the
combination
information CID
(see
Figure
m/z These
ions
the
is the
indicate
negative
ion
Similar
anion
of
reversal m/z
the
MS/MS to ion
anionic
and charge
analyze
reversal
et.
al.
a group
spectra.
surfactants
of
Utilizing
and found
that
CID provide
structural
acid.
The negative
bemzenephosphonic
shows
only
ions
spectrum
(Fig.
51 and
presence
the
provides
of
39.
the
information
due
An m/z aromatic
to
loss
3B) shows 39 ion
of the
is
ring.
the
carbon
with
m-benzenedisulfanic
major
also
Thus,
about
H and HP03-
skeleton
ion
at
observed. the
charge
missing
in
CID spectrum.
results
have
benzenephosphorous
acid
from
of
the
analysis
M-H at
with
Weber,
mode alone.
the
signals
spectrum
CID
GC analysis.
negative
any
some simple
The .charge
other
show
either
for
combined
not
ion
from
of
3A).
77 with
reversal
negative
example
spectrum
did
investigated
of
them
desorption
but
unavailable
A typical ion
and derivatizing
water
two types
been
observed
verifying
negative
the ion
complementary
nature
acid
of
the
and
information
spectra.
ACKNOWLEDGEMENT This
work
was
Science
National
supported
Foundation
by
the
Regional
Midwest
Center
Instrumentation
for
Mass
Spectrometry,
Faci 1 ity
(Grant
a
#CHE
78-18572). REFERENCES 1 2
3 4 5 6
and J.-C. Rousten, C.R. Acad. SC. Paris, Ser 8, 283, a) F.M. Devienne, 397-399 (1976); b) M. Barb,er. R.S. Bordeli, R.D. Sedgwick, and A.N. Tyler, J. Chem. Sot., Chem. Commun., (1981) 325. R.G. Cooks, and G.L. Glish, Chem. and Eng. News, (1981) .54, (48) 40-52. J.H. Bowie, and T. Blumenthal, J. Am. Chem. Sot., (1975) 97, 2959-2962. M.L. Gross, D. McCrery, F. Crow, K-B. Tamer, M.R. Pope, L.M. Ciufetti, H-W. Knoche. J.M. Daly, and L.D. Dwnkle, Tetrahedron Letters, submitted. G.D. Staffeld, M-S. Anderson, D. J. Weber, and R.P. J.M. Glish, C.C. Swceley, Scheffer. Tetrahedron Letters, 38, (1982) 45. CRheFber, K. tcvsen, G.J. Louter, A.J. Nenk Boerboom, and J. Haverkantp, Anal. -9
54
(1982)
1458-1466.
Analysis
of Mixtures
Analyzer
Mass
K.B.
Tomer,
of
Crow,
Center
Lincoln,
NE
Ionic
Compounds
Using
Fast
Atom
Bombardment
and a Triple
Spectrometer
F.W.
Midwest
375
Spectrometry and Ton Physics, 46 (1983) 375-378 Company, Amsterdam - Printed in The Netherlands
and M.L.
for
Gross
Mass
Spectrometry,
University
Nebraska,
of
68588
ABSTRACT The combination of fast atom bombardment (FAB) and mass spectrometry/mass spectrometry (MS/MS) has been applied to the analysis of cyclic peptides and anionic surfactants. INTRODUCTION The
recently
itself
to
be
applicable
zwitterionic spectra
combination
chemical
spectra MS/MS
are can
can
simple
serve
from
CYCLIC
been
of
as a separation ions
some
peptides
for
by be
the
metal
however,
the
analysis other
combination using
3) for
recent
FAB.
in cases
and
a
with
and
removed
component
The of amino
are:
MS/MS; where
isolates
additional
2)
a
the
FAB
of
the
which
are
MS-I
the
1)
structural
(ref.3).
of our
anionic
and mass
or
also
for
peptides
produced
reversal
results and
is
information;
each
easily
by charge
present
of cyclic
stage
the
often,
parallel
activation
structural
are
is
shown
ionic
general,
advantages
can
and
devoid
in
offered
matrix
polar,
deprotonated,
(ref.21
cyclic
by collisional
negative we
distinct
advantages
glycerol
In
has
solvent.
developed
and
(FAB)
of
There
(MS/MS)
offers
linear
the
can be produced paper
(ref.1).
analysis
a protonated,
be produced
information analysis
spectrometry
the mobilizing
The
4)
In this
and
has
as
mixtures;
the
vaporization of
bambardment
fragmentation.
from
and
such
noise
atom
spectrometry
materials.
spectrum"
fast
largely
of the two techniques
acid-containing "mass
arising
advance
compounds
of
limited
spectrometry/mass
instrumentation
the
mass
and
background
Mass
by
the
consisting
simple, molecule
extensive
technique for
compounds
are
cationized
polar
announced
application
of FAB and MS/MS
to
compounds.
PEPTIDES
Underivatized mass
spectra
ions
which
peptides
are
of derivatized can
result
OOZO-7381/83/0000-0000/$03.00
difficult
cyclic in
peptides
incorrect Q
to
analyze are often
sequencing.
1983 Elsevier Scientific
by
mass
plagued Since
spectrometry. with
rearrangement
collision
Publishing Company
The induced
376 decomposition than the
(CID}
rearrangements, analysis
of
and sequencing
spectra
are
we have
applied
underivatized
typically
dominated
the
cyclic
combined
peptides
by simple
techniques
to
cleavages
both
molecular
weight
analysis
of
cyclic
obtain
information.
An example I@B98 *e ,e_ GB _ IB_ ,e_ lb no_ ,e_ B
of
our
results
can
be illustrated
by the
the
1 obo
560 Fig.
rather
FAD and MS/MS to
of
1. FAB Mass Spectrum
Fig.
of
2. CID Spectrum
Protonated
Ion of Cyclo-(Leu-Pro-Gly)4;
Molecular
Cyclo-(Leu-Pro-Gly)4
of the
peak b=MH-Leu-gly;
peak
a=MH-Leu;
peak
c=MH-Leu-gly-pro;
gly-Pro-gly;
peak
d=MH-Leu-
peak e=MH-(Pro-Gly-Leu)2;
peak f =MH-(Pro-Gly-Leu)2-Leu MH-(Pro-Gly-Leu)2-Leu MH-(Pro-Gly-Leu)
; peak g=
gly;
3; peak
peak h=
i=MH-(Pro-
Gly-Leu)3-Leu
cl
Y
NH-CH-COI
N +li
Y
I Leu
GUY
I
I
Pro-leu-Gly-Pro-Leu-Gly-Pro
Scheme 1.
Loss of
dodecapeptide, observed m/z Leu-,
at
Gly
-
1069
and
Pro
(see to then
co -01
Gly
I
Pro-Lsu-Gly-Pro-Leu-Gly-Pro
refers
to
loss
cyclo-(Leu-Pro-Gly)4. m/z
535 corresponding Gly,
0 HN
:H-C&CO+
CO-Gly
Fig. loss occur.
of An
1). of
COCH2NH, for intense
The first two The
y
I Y”
protonated
major
Pro-Gly-Leu CID spectrum
example.
fragment
sequences. of
the
molecular ion
is
ion
is
observed
at
Sequential protonated
loss molecular
of
377 ion
2)
(Fig.
shows
complete
successive
amjno
spectrum.
The fragmentation
proton&ion
on
the
Another was
by
patterns
the
application of
easily
can from of
the
the
major
due
peaks
in
based
cleavage
acylium
ion
FAB MS/MS to
cyclic
spectrum
assigned
on the
to peptide
acyl 1). which
The of
the
sequencing
(ref.4),
(ref.5). basis
an
(scheme
Toxin
to
on initial
form
terminus
carbonum
EI mass
definitively
the
explained
bond
Helminthosporium
using
and
comprise
-N-C=0
Ions
information.
be readily
with
initiated
analysis
sequence
CO losses)
nitrogen
incorrectly
was
acid
(and/or
then
of
the
sequenced
sequence
is
example
provided
losses prolyl
Fragmentation
ion. is
acid
amino
the
correct
FAB/MS/MS
results. Thus, to
the
application
provide
1 ittle
molecular
or
no
more cyclic ANIONIC
weight
interference
peptides
and
from
to
relatively
phosphates
Fig.
FAB/MS/MS to
test
the
analysis
straightforward
rearrangement
the
genera?ity
of
cyclic
sequencing processes.
of
these
peptides information
We are
and
,
.
3A.
.
simple phosphonates,
.
Negative
.
.
sb‘.
Ion
anionic are
organic difficult
of
compounds to
-
CID Spectrum
n/2
acid.
with
investigating
results.
the
analyze
rdo M-H Anion
of
such due
as to
su 1fonates, problems
1.30 Benzenephosphonic
acid.
Fig.
appears
COMPOUNDS
Some
.
of
36.
Charge
Reversal
51
Spectrum
of the
M-l Anion of Benzenephosphonic
in
378 removing
them from
(ref.6)
have
utilized
field
sulfonated
surfactants
FAB/MS/MS,
we have
the
combination
information CID
(see
Figure
m/z These
ions
the
is the
indicate
negative
ion
Similar
anion
of
reversal m/z
the
MS/MS to ion
anionic
and charge
analyze
reversal
et.
al.
a group
spectra.
surfactants
of
Utilizing
and found
that
CID provide
structural
acid.
The negative
bemzenephosphonic
shows
only
ions
spectrum
(Fig.
51 and
presence
the
provides
of
39.
the
information
due
An m/z aromatic
to
loss
3B) shows 39 ion
of the
is
ring.
the
carbon
with
m-benzenedisulfanic
major
also
Thus,
about
H and HP03-
skeleton
ion
at
observed. the
charge
missing
in
CID spectrum.
results
have
benzenephosphorous
acid
from
of
the
analysis
M-H at
with
Weber,
mode alone.
the
signals
spectrum
CID
GC analysis.
negative
any
some simple
The .charge
other
show
either
for
combined
not
ion
from
of
3A).
77 with
reversal
negative
example
spectrum
did
investigated
of
them
desorption
but
unavailable
A typical ion
and derivatizing
water
two types
been
observed
verifying
negative
the ion
complementary
nature
acid
of
the
and
information
spectra.
ACKNOWLEDGEMENT This
work
was
Science
National
supported
Foundation
by
the
Regional
Midwest
Center
Instrumentation
for
Mass
Spectrometry,
Faci 1 ity
(Grant
a
#CHE
78-18572). REFERENCES 1 2
3 4 5 6
and J.-C. Rousten, C.R. Acad. SC. Paris, Ser 8, 283, a) F.M. Devienne, 397-399 (1976); b) M. Barb,er. R.S. Bordeli, R.D. Sedgwick, and A.N. Tyler, J. Chem. Sot., Chem. Commun., (1981) 325. R.G. Cooks, and G.L. Glish, Chem. and Eng. News, (1981) .54, (48) 40-52. J.H. Bowie, and T. Blumenthal, J. Am. Chem. Sot., (1975) 97, 2959-2962. M.L. Gross, D. McCrery, F. Crow, K-B. Tamer, M.R. Pope, L.M. Ciufetti, H-W. Knoche. J.M. Daly, and L.D. Dwnkle, Tetrahedron Letters, submitted. G.D. Staffeld, M-S. Anderson, D. J. Weber, and R.P. J.M. Glish, C.C. Swceley, Scheffer. Tetrahedron Letters, 38, (1982) 45. CRheFber, K. tcvsen, G.J. Louter, A.J. Nenk Boerboom, and J. Haverkantp, Anal. -9
54
(1982)
1458-1466.