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1H n.m.r. studies of a neurotoxin and a cardiotoxin from Naja mossambica mossambica : Amide proton resonances
Vol. 76, No. 4, 1977
H n.m.r.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
STUDIES OF A NEUROTOXIN AND A CARDIOTOXIN sambica:
FROM Naja mossambica
AMIDE PROTON RESONANCES
Jiirgen Lauterwein, Kurt Wiithrich, Hugues Schweitz*, Jean-Pierre Michel Lazdunskif Institut fiir Molekularbiologie und Biophysik, Technische Hochschule, CH-8093 Ziirich, Switzerland, and *Faculte Universitd de Nice, Part Valrose, F-06034 Nice, France Received
April
mos-
Vincent* and Eidgendssische des Sciences,
25,1977
SUMMARY: Proton n.m.r. spectra at 360 MHz of neurotoxin II and cardiotoxin V II 4 from the venom of Naja mossambica mossambica are reported. From the n.m.r. spectra the solution conformations of the two proteins seem to be quite closely related. However, the exchange rates of the n.m.r. observable labile protons with deuterium of the solvent were markedly different, showing that the molecular structure of the cardiotoxin must be more flexible than that of the neurotoxin and suggesting that the different functional properties of the two toxins might be related to the different molecular dynamics.
Snake neurotoxins
and cardiotoxins
homologies
(l-5)
chain
60 - 62
with
half-cystine
. Short
positions,
groups
in cardiotoxins
differences
in
to a protein
receptor Cardiotoxin
to trigger K+-ATPase
(5). study
mossambica the
structural
other
amino
In spite
acid
bridges.
level
of the neurotoxin
and blocks
mossambica,
which for
and cardiotoxin
was undertaken
the different
V
to obtain
functional
at the same found
there
of toxins.
that
Neurotoxin
trans-
structure, the Na+,
inactivates
4 from
resonance the snake -
additional
properties
binds
acetylcholine
magnetic II
to be com-
are pronounced
receptor
in the membrane 1 reports a H nuclear
II
are
homologies
rearrangement paper
The eight
are placed
to a lipid-type
structural
of one polypeptide
residues
two types
binds
extensive
consist
disulfide
of these
of the
apparently
The present
basis
four
at the post-synaptic
a structural
with
and neurotoxins
the mode of action
mission
(6).
seven
of toxins.
proteins
and cardiotoxins including
acids,
and in addition
mon to both
(n.m.r.)
neurotoxins
amino
residues
are parent
insights of
into
the two pro-
teins. II MATERIALS AND METHODS: Neurotoxin II and cardiotoxin V 4 from the venom of Naja mossambica mossambica were prepared as described previously (5,7). For the n.m.r. measurements, 0.002-M solutions of the proteins in D20 at pD.v4.5 and which contained also 0.1-M NaCl, were prepared. pD values are the pH PD -7.0, meter readings without correction for isotope effects. High resolution proton n.m.r. spectra were obtained on a Bruker HX-360 spectrometer. Chemical shifts are in parts per million (ppm) relative to internal sodium 3-trimethylsilyl propionate (TSP).
Copyright All rights
0 1977 by Academic of reproduction in any
Press. Inc. form reserved.
1071 ISSN
0006-291
X
Vol. 76, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
cardiotoxin
I
I
I
I
IO
I
8
I
1
I
6
I
I
4
1
I
2
0
PPM Fig.
1
-3 H n.m.r. spectra at 360 MHz of 2.10 -M solutions of two toxins from Ne in D20, which also contained 0.1 M NaCl, T = 25v. The neurotoxin solution had pD = 4.8, the cardiotoxin solution pD = 4.1. Both spectra were recorded within 15 min after the proteins had been dissolved in D201
RESULTS: Fig. cardiotoxin dition
recorded to the
aromatic from
1 shows the
7 to
10
ly exchanging
immediately
resonances
protons
360 MHz 'Ii
between
after
dissolving
of the aliphatic
protons
6 and 8 ppm (B),
these
ppm, numerous labile
spectra
n.m.r.
protons
quite
well
resolved
in the protein.
1072
of
the
neurotoxin
the proteins between spectra lines
in D20.
In ad-
0 and 6 ppm and the contain,
which
The present
and the
in
correspond investigation
the range to
slow-
concen-
Vol. 76, No. 4, 1977
trated
on the
determine
BIOCHEMICAL
spectral
features
of these
the number
of slowly
exchanging
sure
their
rium
of the solvent.
chemical
shifts
spectra
of
formations
of the neurotoxins
range
at least
from
the 1H n.m.r.
minary
observations
change
rates pH.
This
8.0
had also
is
amide
we decided
prepare
protein
overall
be rather
on
be studied
within
The proteins
typical
for
changes
qualitative
at pDor 4.5 and then
even
dissolved
time
that
the
1) of these intervals actual
toxin.
From comparison
labile
protons
proteins
of these
7.02
to 9.89
rived
from
ter
at pD = 4.1 less After
than
course than
with
1 hr
details
(Table
also
As a general
for
first
exchange
to
would
at higher protons
pD could
in H20 and the pH adjusted
were
from I).
these 7.55
complete
to 9.84
The lyo-
ca.
tubes for
protons.
of the of both
The chemical
30 protons
rates
de-
considerably
In the neurotoxin 1 hr.
and from
exchange
labile
hours showed
the cardio-
exchange
were
30 observable than
several
the spectra
the proton
I).
spec-
ppm in neurotoxin
intensities
of less of the
and 4.1
30 labile
Overall,
ca.
during
in the n.m.r.
conditions
(Table
among the
lyophilized.
recorded
after
of the resonance
in neurotoxin
then
neurotoxin
of approximately
a half-time
and in
ml of D20 at 25O, and n.m.r.
the
under
(Table
at
(10-12).
studies
were
obtained
range
cardiotoxin
for
and T = 25O, thirteen
the proton
25O (for
resonances
and T = 25O, eight
to exchange
that
(9),
exchanging
pH measurements
spectra
resonances
the time
in cardiotoxin
pD = 4.8 found
in
with
solutions in 0.4
4.8
the ex-
flexibility
proton
slowly
D20 solutions
were
was found
contained
shifts
0.002-M
the pH
of time.
These
of 15 minutes. pD values
it
the most
con-
45O. Preli-
least
at
4.0 to 8.0
the kinetic
in 01-M NaCl solution
redissolved
(Fig.
pursue
over
observations,
and 25O , where
period
philized tra
to
the molecular
in general
of the molecular
of these
deute-
7 and 10 ppm decrease
protons
the basis
of HCl.
with
amide
to
to mea-
with
maintained
up to
proteins
where
were
were
between
rates
that
in the pH region
observed
to 4.0 by the addition proteins
that
protons
a reasonable
were
1) had shown
was used
two proteins,
exchange
in globular
slow,
temperature,
the proton
at temperatures
and
N.m.r.
in the
protons
solutions
and higher
protons
(Fig.
shown
of pH dependent
exchanging
strategy
to
behavior
protons.
and the cardiotoxin
of the labile
the absence slowly
4.0
labile
and to study
Inspection
lower
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
fas-
solution protons
In cardiotoxin had a half
at
were solutions
time
of
I).
exchange see figure
had been captions
followed
for
2 and 3),
1073
several the
hours
temperature
at pDq4.5 was raised
and to
Vol. 76, No. 4, 1977
Table
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I Chemical shifts,d,and life times with respect to chemical of the slowly exchanging labile protons in neurotoxin II toxin VII4 of Naja InOssambica mossambica. Neurotoxin
r1 T
7.55 7.50 7.62 7.98 a.05 8.28 8.60
hr - 10 hr at 35O and pD = 6.2
10 hr
- 100 hr
7.64 7.94 a.17 a.52 9.09 9.43 9.65
> 100 hr at 35O and pD = 6.2
a For resonances mated resonance
phosphate thus
buffer.
obtained
in both
protein
(2ja
7.21 7.46 7.51 8.58 8.84 a.94 9.02 9.16 9.24 9.44 9.60
(2-3ja (21a
(aa
8.16 a.58 9.89
i2-3ja
corresponding to more than indicated in parentheses.
by the addition
pH measurement
7.02 7.51 7.60 7.67 7.77 7.85 7.% a.21 a.31 a.39 8.86 9.25 9.38
7.96 a.87 9.41 9.84
with intensities intensities are
35O and the pD changed
6 (ppm)
1.44 7.89 8.65 a.72 8.87 a.95 Q-OS 9.09 9.33 9.53
at 35O and pD = 6.2
T
Cardiotoxin
G(pprn)
0.1 hr - 1 hr at 25O and pD = 4.8 (neurotoxin) or pD = 4.1 (cardiotoxin)
0.1
II
exchange, and cardio-
of 0.01
in the n.m.r. solutions.
ml of 2-M deuterated tubes
The time
1074
one proton,
showed
course
that
of the
esti-
neutral pD = 6.2 was resonance
in-
P
Vol. 76, No. 4, 1977
BIOCHEMICAL
lo Fig.
2
Fig.
at pD = 6.2
3 for
exchange
PPM
and
cardiotoxin.
is
with
DISCUSSION: the neurotoxin
of 100 labile
= 35' the
faster
deuterium
In all,
T
Again
appreciably
2 and 3 are presented
der
8
Amide proton exchange in a D20 solution of neut;otoxin II. The sample of Fig. 1 had been kept at pD ; 4.8 and T = 25 for 5.5 hrs. The temperature was then raised to 35 and the pH changed to 6.2 by the addition of a trace of deuterated 2-M neutral phosphate buffer. The spectra were recorded at the following time intervals after the addition of the phosphate buffer: A. 16 min, B. 17 hrs, C. 73 hrs, D. 454 hrs.
tensities change
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
is
shown in Fig.
two figures
in Table
protons
cardiotoxin per
neurotoxin
show that
Life
times
from experiments
and in the proton
with
of the
respect type
exto
of Figs.
I.
the polypeptide
and the
clearly
in cardiotoxin.
of D20 estimated
2 for
backbone
and the
used in the present
molecule.
The majority 1075
amino
acid
study of these
side
contain protons,
chains
of
of the ori.e.
Vol. 76, No. 4, 1977
lo
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
6
8
PPM
Fig.
3 Amide proton exchange in Fig. 1 had been kept at ture was then raised to Fig. 2. The spectra were vals after the addition C. 3.6 hrs, D. 53 hrs.
a D20 solution of zardiotoxin. The sample of pD = 4.1 and T = 25 for 3 hrs. The tempera3S" and the pH changed to 6.2 as described in then recorded at the following time interof the phosphate buffer: A. 10 min, B. 32 min,
those
of the
backbone
chain
protons,
D20 solutions teins in
would
the spectra
solvent
accessible
exchange
too rapidly
of the proteins therefore of Fig.
suggest
(8,9). that
amide
groups
to be observed General
experience
essentially
1 to 3 come from backbone
1076
in
all
and the bulk the n.m.r.
of the side spectra
of
with
peptides
and pro-
the labile
protons
observed
located
in inte-
amide
groups
Vol. 76, No. 4, 1977
rior
parts
(8-12).
BIOCHEMICAL
of the molecule
This
multiplet
is
further
(a-12),
a suitable
and hence
not
corroborated
structures
cussed
AND BIOPHYSICAL
method
accessible
by the chemical
of the resonance
studies
readily
RESEARCH COMMUNICATIONS
lines.
of the exchange
to investigate
shifts
(Table
As was previously
kinetics
the
to the solvent
of interior
rigidity
I)
and the
extensively amide
of the protein
dis-
protons
are
conformation
in
structures
of
solution. specific
More
resonance
homologous sheets ber
neurotoxins
containing
of slowly
number neurotoxin
exchanging
crystal
compatible
with
that
milar
to the
sults
of an earlier
side
crystal
mainly
of the
ticular
interest
protons
observable
neurotoxin
the spatial amide
neurotoxin. lecules
exchange
In other to occur
In conclusion
in
these
different
modes of
ty of the
spatial
possible that
it
changes
mechanistic is
a priori
are induced
(Table
I),
of cardiotoxin (13-15).
Considering
words, "open
should rates
action
also
related.
is
forms"
comparative
(l-51,
a greater
from which studies
structures
related
of neurotoxin
implications more likely
are
of this for
by the different
the structure
type
homologies it
is
not
in the
unexpected
On the other
hand, than
for
cardiotoxin
can take
place
(g-12).
that
to the different
flexibili-
hypothesis, molecule
it
Without
the
pursuing
may be pointed that
conformational
receptor
sites,
in mo-
seem to indicate
medium in or near
1077
of lato be that
and cardiotoxin.
a flexible
numbers
indicate
probability thus
acid
of par-
in cardiotoxin
NH-exchange
would
on membranes
faster
is
it
slowly
the extensive
considerably
amino
which
and cardiotoxin.
data
with
be closely
si-
(15),
identical
and cardiotoxin
are
there
(5,6),
n.m.r.
coincides
is
by the re-
sufficiently
the present
is
seem to
solution
of the
of neurotoxin
exchange
in
was known.
essentially
shifts
the
bonds
neurotoxin
structure
features
of
data
supported
properties
two proteins
chemical
of neurotoxin
structures
proton
structural
in the
conformation
functional
in
nuclei
the X-ray
the
of the resonances
the n.m.r.
also
of non-labile
before
structure
conformation is
with
hydrogen
of a homologous
features
different
(81,
the num-
closely
of most
conclusion
investigation
similar
sequences
that
This
appeared
since
backbone
that
sheet
shifts
to compare
amino
B-pleated assignment
polypeptide
of B-pleated
I: coincides
chemical
suggested
for
acid
antiparallel
structure.
determined
striking
quite
the observed
in D20 solution
the molecular
is
in Table
Since
on spectral
with
It
regions
in intramolecular
n.m.r.
On the one hand,
bonds.
extended
involved
and which
In view
include
by the X-ray
protons
the neurotoxin
chains
bile
in the
amide
indicated
listed
conformation.
imply
was based
which
protons
bonds
I. to backbone
also
the
(13,141,
are
25 to 30 hydrogen
of hydrogen
Table
assignments
out which
Vol. 76, No. 4, 1977
might function
be amenable relations
BIOCHEMICAL
to experimental in these
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
observation
in
future
studies
of structure-
toxins.
ACKNOWLEDGEMENTS: Financial support by the Schweizerischer ject 3.1510.73) and by the Centre National de la Recherche gratefully acknowledged.
Nationalfonds Scientifique
(prois
REFERENCES: 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Lee, C.Y. (1972) Annu.Rev.Pharmacol. 12, 265-286. Yang, C.C. (1974) Toxicon 3, l-43. Louw, A.I. (19741 Biochem.Biophys.Res.Commun. E, 1022-1029. Gregoire, J. and Rochat, H., Eur.J.Biochem., submitted for publication. Vincent, J.P., Schweitz, Y., Chicheportiche, R., Fosset, M., Balerna, M., Lenoir, M.C. and Lazdunski, M. (1976) Biochemistry Is, 1371-1375. Rang, H.P. (1975) Q,Rev.Biophys. I, 283-399. Chicheportiche, R., Vincent, J.P., Kopeyan, C., Schweitz, H. and Lazdunski, M. (1975) Biochemistry 14, 2081-2091. Wiithrich, K., NMR in Biological Research: Peptides and Proteins, North Holland, Amsterdam 1976. Englander, S.W., Downer, N.W. and Teitelbaum, H. (1972) Annu.Rev.Biochemistry g, 903-924. Hvidt, A. and Nielsen, S.O. (1966) Advan.Protein Chem. 2, 287-386. Masson, A. and Wiithrich, K. (1973) FEBS Lett. 31, 114-118. Wagner, G. (1977) Ph.D. Thesis, Eidgendssische Technische Hochschule Ziirich, Switzerland. Low, B.W., Preston, H.S., Sato, A., Rosen, L.S., Searl, J.E., Rudko, A-D. and Richardson, J.S. (1976) Proc.Natl.Acad.Sci. USA 73, 2991-2994. Tsernoglou, D. and Petsko, G.A. (1976) FEBS Lett. "";i-4. Arseniev, A.S., Balashova, T.A., Utkin, Y.N., Tsetlin, V.I., Bystrov, V.F., Ivanov, V.T. and Ovchinnikov, Y.A. (1976) Eur.J.Biochem. -71, 595-606.
1078
H n.m.r.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
STUDIES OF A NEUROTOXIN AND A CARDIOTOXIN sambica:
FROM Naja mossambica
AMIDE PROTON RESONANCES
Jiirgen Lauterwein, Kurt Wiithrich, Hugues Schweitz*, Jean-Pierre Michel Lazdunskif Institut fiir Molekularbiologie und Biophysik, Technische Hochschule, CH-8093 Ziirich, Switzerland, and *Faculte Universitd de Nice, Part Valrose, F-06034 Nice, France Received
April
mos-
Vincent* and Eidgendssische des Sciences,
25,1977
SUMMARY: Proton n.m.r. spectra at 360 MHz of neurotoxin II and cardiotoxin V II 4 from the venom of Naja mossambica mossambica are reported. From the n.m.r. spectra the solution conformations of the two proteins seem to be quite closely related. However, the exchange rates of the n.m.r. observable labile protons with deuterium of the solvent were markedly different, showing that the molecular structure of the cardiotoxin must be more flexible than that of the neurotoxin and suggesting that the different functional properties of the two toxins might be related to the different molecular dynamics.
Snake neurotoxins
and cardiotoxins
homologies
(l-5)
chain
60 - 62
with
half-cystine
. Short
positions,
groups
in cardiotoxins
differences
in
to a protein
receptor Cardiotoxin
to trigger K+-ATPase
(5). study
mossambica the
structural
other
amino
In spite
acid
bridges.
level
of the neurotoxin
and blocks
mossambica,
which for
and cardiotoxin
was undertaken
the different
V
to obtain
functional
at the same found
there
of toxins.
that
Neurotoxin
trans-
structure, the Na+,
inactivates
4 from
resonance the snake -
additional
properties
binds
acetylcholine
magnetic II
to be com-
are pronounced
receptor
in the membrane 1 reports a H nuclear
II
are
homologies
rearrangement paper
The eight
are placed
to a lipid-type
structural
of one polypeptide
residues
two types
binds
extensive
consist
disulfide
of these
of the
apparently
The present
basis
four
at the post-synaptic
a structural
with
and neurotoxins
the mode of action
mission
(6).
seven
of toxins.
proteins
and cardiotoxins including
acids,
and in addition
mon to both
(n.m.r.)
neurotoxins
amino
residues
are parent
insights of
into
the two pro-
teins. II MATERIALS AND METHODS: Neurotoxin II and cardiotoxin V 4 from the venom of Naja mossambica mossambica were prepared as described previously (5,7). For the n.m.r. measurements, 0.002-M solutions of the proteins in D20 at pD.v4.5 and which contained also 0.1-M NaCl, were prepared. pD values are the pH PD -7.0, meter readings without correction for isotope effects. High resolution proton n.m.r. spectra were obtained on a Bruker HX-360 spectrometer. Chemical shifts are in parts per million (ppm) relative to internal sodium 3-trimethylsilyl propionate (TSP).
Copyright All rights
0 1977 by Academic of reproduction in any
Press. Inc. form reserved.
1071 ISSN
0006-291
X
Vol. 76, No. 4, 1977
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
cardiotoxin
I
I
I
I
IO
I
8
I
1
I
6
I
I
4
1
I
2
0
PPM Fig.
1
-3 H n.m.r. spectra at 360 MHz of 2.10 -M solutions of two toxins from Ne in D20, which also contained 0.1 M NaCl, T = 25v. The neurotoxin solution had pD = 4.8, the cardiotoxin solution pD = 4.1. Both spectra were recorded within 15 min after the proteins had been dissolved in D201
RESULTS: Fig. cardiotoxin dition
recorded to the
aromatic from
1 shows the
7 to
10
ly exchanging
immediately
resonances
protons
360 MHz 'Ii
between
after
dissolving
of the aliphatic
protons
6 and 8 ppm (B),
these
ppm, numerous labile
spectra
n.m.r.
protons
quite
well
resolved
in the protein.
1072
of
the
neurotoxin
the proteins between spectra lines
in D20.
In ad-
0 and 6 ppm and the contain,
which
The present
and the
in
correspond investigation
the range to
slow-
concen-
Vol. 76, No. 4, 1977
trated
on the
determine
BIOCHEMICAL
spectral
features
of these
the number
of slowly
exchanging
sure
their
rium
of the solvent.
chemical
shifts
spectra
of
formations
of the neurotoxins
range
at least
from
the 1H n.m.r.
minary
observations
change
rates pH.
This
8.0
had also
is
amide
we decided
prepare
protein
overall
be rather
on
be studied
within
The proteins
typical
for
changes
qualitative
at pDor 4.5 and then
even
dissolved
time
that
the
1) of these intervals actual
toxin.
From comparison
labile
protons
proteins
of these
7.02
to 9.89
rived
from
ter
at pD = 4.1 less After
than
course than
with
1 hr
details
(Table
also
As a general
for
first
exchange
to
would
at higher protons
pD could
in H20 and the pH adjusted
were
from I).
these 7.55
complete
to 9.84
The lyo-
ca.
tubes for
protons.
of the of both
The chemical
30 protons
rates
de-
considerably
In the neurotoxin 1 hr.
and from
exchange
labile
hours showed
the cardio-
exchange
were
30 observable than
several
the spectra
the proton
I).
spec-
ppm in neurotoxin
intensities
of less of the
and 4.1
30 labile
Overall,
ca.
during
in the n.m.r.
conditions
(Table
among the
lyophilized.
recorded
after
of the resonance
in neurotoxin
then
neurotoxin
of approximately
a half-time
and in
ml of D20 at 25O, and n.m.r.
the
under
(Table
at
(10-12).
studies
were
obtained
range
cardiotoxin
for
and T = 25O, thirteen
the proton
25O (for
resonances
and T = 25O, eight
to exchange
that
(9),
exchanging
pH measurements
spectra
resonances
the time
in cardiotoxin
pD = 4.8 found
in
with
solutions in 0.4
4.8
the ex-
flexibility
proton
slowly
D20 solutions
were
was found
contained
shifts
0.002-M
the pH
of time.
These
of 15 minutes. pD values
it
the most
con-
45O. Preli-
least
at
4.0 to 8.0
the kinetic
in 01-M NaCl solution
redissolved
(Fig.
pursue
over
observations,
and 25O , where
period
philized tra
to
the molecular
in general
of the molecular
of these
deute-
7 and 10 ppm decrease
protons
the basis
of HCl.
with
amide
to
to mea-
with
maintained
up to
proteins
where
were
were
between
rates
that
in the pH region
observed
to 4.0 by the addition proteins
that
protons
a reasonable
were
1) had shown
was used
two proteins,
exchange
in globular
slow,
temperature,
the proton
at temperatures
and
N.m.r.
in the
protons
solutions
and higher
protons
(Fig.
shown
of pH dependent
exchanging
strategy
to
behavior
protons.
and the cardiotoxin
of the labile
the absence slowly
4.0
labile
and to study
Inspection
lower
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
fas-
solution protons
In cardiotoxin had a half
at
were solutions
time
of
I).
exchange see figure
had been captions
followed
for
2 and 3),
1073
several the
hours
temperature
at pDq4.5 was raised
and to
Vol. 76, No. 4, 1977
Table
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I Chemical shifts,d,and life times with respect to chemical of the slowly exchanging labile protons in neurotoxin II toxin VII4 of Naja InOssambica mossambica. Neurotoxin
r1 T
7.55 7.50 7.62 7.98 a.05 8.28 8.60
hr - 10 hr at 35O and pD = 6.2
10 hr
- 100 hr
7.64 7.94 a.17 a.52 9.09 9.43 9.65
> 100 hr at 35O and pD = 6.2
a For resonances mated resonance
phosphate thus
buffer.
obtained
in both
protein
(2ja
7.21 7.46 7.51 8.58 8.84 a.94 9.02 9.16 9.24 9.44 9.60
(2-3ja (21a
(aa
8.16 a.58 9.89
i2-3ja
corresponding to more than indicated in parentheses.
by the addition
pH measurement
7.02 7.51 7.60 7.67 7.77 7.85 7.% a.21 a.31 a.39 8.86 9.25 9.38
7.96 a.87 9.41 9.84
with intensities intensities are
35O and the pD changed
6 (ppm)
1.44 7.89 8.65 a.72 8.87 a.95 Q-OS 9.09 9.33 9.53
at 35O and pD = 6.2
T
Cardiotoxin
G(pprn)
0.1 hr - 1 hr at 25O and pD = 4.8 (neurotoxin) or pD = 4.1 (cardiotoxin)
0.1
II
exchange, and cardio-
of 0.01
in the n.m.r. solutions.
ml of 2-M deuterated tubes
The time
1074
one proton,
showed
course
that
of the
esti-
neutral pD = 6.2 was resonance
in-
P
Vol. 76, No. 4, 1977
BIOCHEMICAL
lo Fig.
2
Fig.
at pD = 6.2
3 for
exchange
PPM
and
cardiotoxin.
is
with
DISCUSSION: the neurotoxin
of 100 labile
= 35' the
faster
deuterium
In all,
T
Again
appreciably
2 and 3 are presented
der
8
Amide proton exchange in a D20 solution of neut;otoxin II. The sample of Fig. 1 had been kept at pD ; 4.8 and T = 25 for 5.5 hrs. The temperature was then raised to 35 and the pH changed to 6.2 by the addition of a trace of deuterated 2-M neutral phosphate buffer. The spectra were recorded at the following time intervals after the addition of the phosphate buffer: A. 16 min, B. 17 hrs, C. 73 hrs, D. 454 hrs.
tensities change
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
is
shown in Fig.
two figures
in Table
protons
cardiotoxin per
neurotoxin
show that
Life
times
from experiments
and in the proton
with
of the
respect type
exto
of Figs.
I.
the polypeptide
and the
clearly
in cardiotoxin.
of D20 estimated
2 for
backbone
and the
used in the present
molecule.
The majority 1075
amino
acid
study of these
side
contain protons,
chains
of
of the ori.e.
Vol. 76, No. 4, 1977
lo
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
6
8
PPM
Fig.
3 Amide proton exchange in Fig. 1 had been kept at ture was then raised to Fig. 2. The spectra were vals after the addition C. 3.6 hrs, D. 53 hrs.
a D20 solution of zardiotoxin. The sample of pD = 4.1 and T = 25 for 3 hrs. The tempera3S" and the pH changed to 6.2 as described in then recorded at the following time interof the phosphate buffer: A. 10 min, B. 32 min,
those
of the
backbone
chain
protons,
D20 solutions teins in
would
the spectra
solvent
accessible
exchange
too rapidly
of the proteins therefore of Fig.
suggest
(8,9). that
amide
groups
to be observed General
experience
essentially
1 to 3 come from backbone
1076
in
all
and the bulk the n.m.r.
of the side spectra
of
with
peptides
and pro-
the labile
protons
observed
located
in inte-
amide
groups
Vol. 76, No. 4, 1977
rior
parts
(8-12).
BIOCHEMICAL
of the molecule
This
multiplet
is
further
(a-12),
a suitable
and hence
not
corroborated
structures
cussed
AND BIOPHYSICAL
method
accessible
by the chemical
of the resonance
studies
readily
RESEARCH COMMUNICATIONS
lines.
of the exchange
to investigate
shifts
(Table
As was previously
kinetics
the
to the solvent
of interior
rigidity
I)
and the
extensively amide
of the protein
dis-
protons
are
conformation
in
structures
of
solution. specific
More
resonance
homologous sheets ber
neurotoxins
containing
of slowly
number neurotoxin
exchanging
crystal
compatible
with
that
milar
to the
sults
of an earlier
side
crystal
mainly
of the
ticular
interest
protons
observable
neurotoxin
the spatial amide
neurotoxin. lecules
exchange
In other to occur
In conclusion
in
these
different
modes of
ty of the
spatial
possible that
it
changes
mechanistic is
a priori
are induced
(Table
I),
of cardiotoxin (13-15).
Considering
words, "open
should rates
action
also
related.
is
forms"
comparative
(l-51,
a greater
from which studies
structures
related
of neurotoxin
implications more likely
are
of this for
by the different
the structure
type
homologies it
is
not
in the
unexpected
On the other
hand, than
for
cardiotoxin
can take
place
(g-12).
that
to the different
flexibili-
hypothesis, molecule
it
Without
the
pursuing
may be pointed that
conformational
receptor
sites,
in mo-
seem to indicate
medium in or near
1077
of lato be that
and cardiotoxin.
a flexible
numbers
indicate
probability thus
acid
of par-
in cardiotoxin
NH-exchange
would
on membranes
faster
is
it
slowly
the extensive
considerably
amino
which
and cardiotoxin.
data
with
be closely
si-
(15),
identical
and cardiotoxin
are
there
(5,6),
n.m.r.
coincides
is
by the re-
sufficiently
the present
is
seem to
solution
of the
of neurotoxin
exchange
in
was known.
essentially
shifts
the
bonds
neurotoxin
structure
features
of
data
supported
properties
two proteins
chemical
of neurotoxin
structures
proton
structural
in the
conformation
functional
in
nuclei
the X-ray
the
of the resonances
the n.m.r.
also
of non-labile
before
structure
conformation is
with
hydrogen
of a homologous
features
different
(81,
the num-
closely
of most
conclusion
investigation
similar
sequences
that
This
appeared
since
backbone
that
sheet
shifts
to compare
amino
B-pleated assignment
polypeptide
of B-pleated
I: coincides
chemical
suggested
for
acid
antiparallel
structure.
determined
striking
quite
the observed
in D20 solution
the molecular
is
in Table
Since
on spectral
with
It
regions
in intramolecular
n.m.r.
On the one hand,
bonds.
extended
involved
and which
In view
include
by the X-ray
protons
the neurotoxin
chains
bile
in the
amide
indicated
listed
conformation.
imply
was based
which
protons
bonds
I. to backbone
also
the
(13,141,
are
25 to 30 hydrogen
of hydrogen
Table
assignments
out which
Vol. 76, No. 4, 1977
might function
be amenable relations
BIOCHEMICAL
to experimental in these
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
observation
in
future
studies
of structure-
toxins.
ACKNOWLEDGEMENTS: Financial support by the Schweizerischer ject 3.1510.73) and by the Centre National de la Recherche gratefully acknowledged.
Nationalfonds Scientifique
(prois
REFERENCES: 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Lee, C.Y. (1972) Annu.Rev.Pharmacol. 12, 265-286. Yang, C.C. (1974) Toxicon 3, l-43. Louw, A.I. (19741 Biochem.Biophys.Res.Commun. E, 1022-1029. Gregoire, J. and Rochat, H., Eur.J.Biochem., submitted for publication. Vincent, J.P., Schweitz, Y., Chicheportiche, R., Fosset, M., Balerna, M., Lenoir, M.C. and Lazdunski, M. (1976) Biochemistry Is, 1371-1375. Rang, H.P. (1975) Q,Rev.Biophys. I, 283-399. Chicheportiche, R., Vincent, J.P., Kopeyan, C., Schweitz, H. and Lazdunski, M. (1975) Biochemistry 14, 2081-2091. Wiithrich, K., NMR in Biological Research: Peptides and Proteins, North Holland, Amsterdam 1976. Englander, S.W., Downer, N.W. and Teitelbaum, H. (1972) Annu.Rev.Biochemistry g, 903-924. Hvidt, A. and Nielsen, S.O. (1966) Advan.Protein Chem. 2, 287-386. Masson, A. and Wiithrich, K. (1973) FEBS Lett. 31, 114-118. Wagner, G. (1977) Ph.D. Thesis, Eidgendssische Technische Hochschule Ziirich, Switzerland. Low, B.W., Preston, H.S., Sato, A., Rosen, L.S., Searl, J.E., Rudko, A-D. and Richardson, J.S. (1976) Proc.Natl.Acad.Sci. USA 73, 2991-2994. Tsernoglou, D. and Petsko, G.A. (1976) FEBS Lett. "";i-4. Arseniev, A.S., Balashova, T.A., Utkin, Y.N., Tsetlin, V.I., Bystrov, V.F., Ivanov, V.T. and Ovchinnikov, Y.A. (1976) Eur.J.Biochem. -71, 595-606.
1078