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Trifluoperazine binding to calmodulin: A shift reagent 43Ca NMR study
Vol. 122, No. 3, 1984
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
August 16, 1984
Pages 1350-l
TRIFLUOPERAZINE
BINDING
Hans
J.
Vogel, Torbjorn
Department
Received
July
5,
TO CALMODULIN:
of
A SHIFT
Thomas Andersson, Drakenberg and Physical Lund,
REAGENT
William H. Sture ForsPn
43CA
NMR
STUDY
Braunlin,
Chemistry 2, University S-220 07 Lund, Sweden
of
Lund
1984
43Ca NMR experiments of Ca2+ binding to calmodulin (CaM) were performed in the presence and absence of the calmodulin antagonist trifluoperazine (TFP). By making use of the shift reagent Dy(PPP)z(a I:2 complex of DyC13 and Na5P3010) we have succeeded in separating the "3Ca resonances of protein-bound Ca2+ and free Ca2+ in the otherwise unresolved spectra. This experimental strate$y has allowed us to demonstrate unequivocally that the affinity of CaM for Ca + is markedly increased in the presence of TFP. Thus Ca'+ is not liberated from the protein upon addition of TFP as had been suggested based on earlier 43Ca NMR experiments (Shimuzu, T., Hatano, M., Nagao, S. and Nozawa, Y. (1982), Biochem. Biophys. Res. Cotnm. 106, 1112-1118).
Calmodulin tein
in
all
(CaM)'
eukaryotic
that
the
activation
lin
takes
place
measurements
ternary
complexes.
the
for
these
substances creases
that
CaM
upon In
ported
'I3
to
that on their
'Abbreviations troponin
of
"...Ca 43 Ca
compete
of these 2+
with
agreed
TnI
and
CaM's
be of with
is set
other
an
free
similar
of
used are: CaM, calmodulin, TFP, W7, N-(6-aminohexyl)-5-chloro-l-naphtalenesulfonamide.
CaM
CaM
by
Ca
binding CaM
that
CaM. 43
such
to
(5-7).
hydrophobic
from
in
binding
by
affinity hydrophobic ions
compounds
the
These
Ca measurements
trifluoperazine,
the
unexpectedly,
metal
Shimizu
as
combining
Not 2+
of
for
direct
such
increased
(2).
enhanced
provided
enzymes
the
surprising
Tetrahymena
apo-CaM
substances,
affinity
or it
is 45ca2+
melittin,
target
to
to
2+
surfaces
rise
the
(10,ll)
Ca of
concerning
that
to
for
Ca2+
pro-
have shown 2+ Ca -calmodu-
by
of
hydrophobic
gives
results seems
binding
hydrophobic
also
TFP
phosphodiesterase the
as
Cd NMR experiments
NMR measurements
conclusions
I,
can
regulator
laboratories
experiments
Several
Ca2+ -induced .
various
affinity
such
demonstrated
binding
view
proteins,
substances
Moreover,
CaM's
(3,4).
TFP,
CaM's
in
enzyme cyclic-AMP 2+ -levels than
dialysis
notion
calcium-binding
Studies
that
model
this
of
(8,9).
(1,Z).
indicated
with
addition
Ca
multifunctional
Equilibrium
drug
reversibly
the
lower
of
antipsychotic
based
of
presence
evidence
the
cells
at
These
in
is
in-
(12).
et
al.
addition
(13) of
authors
TFP..."
suggested which
TnI
we
per-
re-
356
Vol.
122,
No.
formed
on
bovine
cative
of
increased
controversy on the
CaM
of
lished
anionic
shift
elsewhere
the
(17).
resonances
for
resonances
that
MATERIALS
we
AND
introduced
reagents.
The
use
of
of
to
CaM by 43 Ca NMR
details
shift 2+
the
of
reagents
Ca
and
free
Ca
analysis
has 2+
data
this 43 Ca
NMR.
indi-
To
improve based
method
will
allowed
us
without
Ca
as
apparent
experiment
this
43
of
COMMUNICATIONS
our
resolve
a novel
the
complicates
to
TFP
full
RESEARCH
interpreted
order
binding
protein-bound
normally
In
have
The
the
BIOPHYSICAL
we had
(14). the
studies,
AND
eventhough affinity
reinvestigated
earlier
use
(14-16), 2+
Ca
we
our
BIOCHEMICAL
3, 1984
to
the
NMR
be
on pub-
follow
overlap
of
spectra.
METHODS
43Ca NMR spectra were obtained an two different NMR spectrometers, a homebuilt 6 Tesla instrument (16) and a Nicolet 360 WB. The details of the sample preparations and the spectral parameters used for these studies have been presented elsewhere (15,17). Isotopically enriched 43Ca (60 i:) was obtained from Techsnabexport, Moscow, USSR through their Swedish sales agent Matreco AB, Sodertalje, Sweden. Bovine brain and bovine testis CaM were purified as previously described (11). All other chemicals used were of the highest quality commercially available.
RESULTS Upon resonance 2+ of Ca width
titration is
CaM.
the
a spectrum from
composed the
this
this
Note
that
spectra, and
shape
since
this
of
CaM
in
resonance
goes
exchange
(15,16).
observed
and
of
have
absence
brain
and
presence
However, slow
in
the
exchange
conditions 1351
of
are
not
followed
the prevail.
Since
narrow
(18)
presence protein in
signal
the
temperature
no
Addition 43 Ca reso-
the
long
via drug
shift.
the
was
When
1).
overlooked
shown.
testis
slow
with figure
easily
of
the
TFP.
B,
rather
and
from
fitted
proteins.
TFP
3 compares of
presence
is
linewidth
prohibitively
temperature
be panel
chemical
ions
is
resonance
is
indicates
resonance
Figure
increasing
thus
directly
in
required
concentration.
the
curves
broad
(see
resonance
the
line-
spectrum
nonetheless
with in
4 eqv.
the
this
calcium-binding
a titration
wide
almost
narrower
a similar
most
the
that
line
a broad
decrease
both the
can
43Ca2+ of
titration
of
it
with
studies
sites
would
with
that
resonance
a marked
the
binding
protein
A),
Lorentzian
results in
of
panel broad
Hz
Figure 1 shows such 2+ Ca . Although we know
additional
1,
protein-bound
in
CaM
Hz
apparent
for
behaviour
a higher
dence
2 the
the
is
arise
results
TFP
365
range
figure
The strong
figure
of
of
an
of
increased
6 eqv. levels
700-800
a ratio
(15,16).
containing
and
to
one
further
rapidly
component
a narrower
will
drug
two
is
of shift
situation
broad
it
up is
subsaturating
a single
presence
nance.
Hz
only
spectra
concentration
a sample
in
to
chemical
In of
800
NMR
normally
decreases
at
comparison
the
this
for
43Ca2+ Ca
Ca
resonance
simulation ease
From
the
an
;ith
the 2+
the
obtained
of
relative
in
major
data
CaM
in
As
obtained
our
(see
observed
per
of
of
drug
is
these acquisition depen-
added
intermediate no
change
of (10,14).
the to
in
linewidth
fast
Vol.
122,
No.
3, 1984
BIOCHEMICAL
AND
BIOPHYSICAL
PPM
RESEARCH
COMMUNICATIONS
1000
0
-1000
HZ
Simulations using Lorentzian lines for a 43Ca resonance measured .3 MHz for a sample containing 1 mM CaM, 6 mM CaZt, 100 mM NaClOs, pH 7.0. Panel A shows (from top to bottom) the measured spectrum, the simulated spectrum and the two Lorentzian lines (750 and 280 Hz) that were used for the fitting. Panel B shows the fitting of the measured data points to a single Lorentzian resonance of 365 Hz. The measured spectrum was broadened by 25 Hz in both cases by exponential multiplication of the free induction decay.
In this
a final
the
shift
final
concentration
shift
reagent
ions
up
to
experiment reagent
-125
ppm
used
Dy(PPP)g of
which
we
1.2
(a
mM.
can
displace
(17).
As
This
2
w-3.0
sample
I:2
is
from
complex
complex
resonances
of
is
a very
for
free
demonstrated
by
1
I
0
the
1
2
TFP /
3
4
DyC13
I and and
Na5P30,D)
effective or
comparing
added
3
to to
a
anionic
weakly
bound
figures
Ca
2+
4B and
I
0
CaM
figure
4C
I 20
60
60
T:rtlP. ( w
The 43Ca NMR linewidth as a function of the [TFPl/[CaM] ratio for mM CaC12 solution, pH 7.0 containing 0.40 mM bovine brain-CaM (0) a 3.0 mM CaC12 solution, pH 7.0 containing 0.44 mM bovine testis-CaM. The spectra for this figure were obtained at 17.2 MHz. The linewidth of the free Ca2+ resonance (- 12 Hz) is not substracted from those given in this figure.
Figure 4 3 310 The the this
The temperature dependence of the *3Ca NMR linewidth for: (0) a 3. mM CaClp solution at pH 7.0 containing 0.9 mM bovine testis-CaM, (0) a mM CaC12 at pH 7.0 containing 0.4 mM bovine testis-CaM and 1.3 mM TFP. spectra for this figure were obtained at 17.2 MHz. The linewidth of free Ca2+ resonance (- 12 Hz) is not substracted from those given in figure. 1352
Vol.
122,
No.
BIOCHEMICAL
3, 1984
,
1
I
>
50
Figure 4. containing additions
we obtain in
the
43 Ca The
This
downfield
improved
reagent
as
resonance
of the
the
can
is It
be
upon -50
broadened
paramagnetic of
-50
4C
the
-100
not
been
to
is
additional reagent spectrum
of
that of
COMMUNICATIONS
for
figures
exchange
with
amount (17). 4D was
free
of Upon obtained.
1353
obtained pH 7.0 with mM Dy(PPP):-,
the
excess
for a sample the following D) 3 mM TFP.
shift
the
of
Ca over 43Ca2+
addition
4A and
4C.
reagent 2+
protein-bound by
the
PPM
of
an the
affected
comparison
ppm
addition
containing
corresponds
because an shift
figure
after
solutions
ppm has
seen at
experiences
sample
of +I0
resonance
shifted
(16).
at
RESEARCH
VT-7
0
resolution
NMR spectrum
resonance
resonance
T
BIOPHYSICAL
“3Ca NMR spectra (24.3 MHz, 106 transients) 1 M bovine testis CaM, 100 fl NaCIOk, A) 2.0 evq. Ca2+, B) 6 eqv. Ca'+,C) 1.2
much
CaM.
AND
of
.
the
The
shift
upfield
Ca 2+ ions. The latter 2+ Ca bound to the protein
broadening addition
due of
The
most
to
the
3 eqv.
of
noticeable
presence TFP
to change
Vol.
in
122,
the
No.
spectrum
Similar W7,
3, 1984
results that
also
BIOCHEMICAL
is
a considerable
as
those
binds
BIOPHYSICAL
narrowing
shown
to
AND
in
of
figure
calmodulin
in
a Ca
RESEARCH
the
upfield
COMMUNICATIONS
shifted
4 were obtained with 2+ -dependent manner
2.
resonance
another (9)
drug,
(data
not
shown).
DISCUSSION The
results
nance
for
upon
addition
been
suggested
nance the
Ca
for 2+
of
the
the
of (< that
(16).
On
the
Ca'+.
Thus of
linewidths
(16)) off-rate
too
stopped contained ionic in
free
in
figure
43 Ca
other
equilibrium
that
to
flow 100 strength
the
various
sensitive
to
free
those
the
two
measurable or
studies
'H
whereas
(15,19).
The thus strength
virtually
on
at
23'C
the
in
agreement
(2-4,
8,9). Ca
Ca2+
From
have
the
at
NMR
one 2+
con-
exchange
rate
changed,
this
affinity
for
outcome
in
of
a in
figures
This
number
Ca NMR
23'C
the
time-
can
difference
43
using
in
the
not
the
resonances -1 800 set
set -I
further no change
increased with
earlier 700
Ca
2t
of
(ca.
the
an
is
between
temperature
rate
for
had reso-
(19)).
the 4C and is
in
(1000
set
This
Ca
-1 2+
low-affinity sites of CaM, as we have discussed 2+ Ca off-rate for the two high affinity sites 43 by Ca NMR but it can be estimated using
The
mM NaC104
This
There is 2+ Ca with
linewidth
determined
fluorescence
solution.
as the rate
exchange
upfield-shifted 2t a minimum Ca off-rate with
of
exchange
reflecting
are
protein
in
on-rates as
the
the
reso-
intensity
narrowing
decreased
the
in
low
the
fluorescence
ionic
the
2.
markedly
studies
for
for
be
has
NMR results
(11,15,16,19). slow
a very
TFP
in
of
differences
interpreted
these
is
resonance
that
directly
stopped-flow
elsewhere is
that
of
the in
that
decrease
from
Rather,
and
assumption
agreement and
liberated
shown
the
or
a decrease
suggesting
calculate
excellent
not (13).
indicates
From
measured
we can
is
al.
clearly
disappear
protein
addition
be
4 demonstrate not
results 43 the Ca
drug,
the
can
variety
the the of
the
Ca
2+.
figure
does 2+
et
Ca
10 set-'j.
result
Thus
Shimizu
to by
linewidth
clude
4D
TFP.
excess
bound
presence scale
in 2+
Ca
by
substantiated in
depicted
protein-bound
NMR
(19,ll).
our
earlier
good
agreement
indicates in
The
contrast
samples
work for
that
these to
recent
used
for
was the
performed 2-t off-rate Ca
numbers allegations
are
at
figure lower measured
not
extremely
(20).
'A second change is that the relative integrated intensities of the protein-bound and the free resonance alter. This is related to the fas,t that the shift reagent used in this study has an affinity for Ca which approximates that of the two weak2$ites of CaM (17). bound to the protein. Hence it would pull out a fraction of the Ca The increase observed for the protein-bound resonance upon addition of TFP provides thus additional evidence for an increased Ca2+ affinity in the CaM-drug complex. 1354
4
,
Vol.
122,
No,
The lnents
3, 1984
conclusions
performed
this
experimental
tion
of
ion
binding
bound
the
to
23Na+
cations,
ments
such
at
and
from
This
al.
CaM its
"excess
as implicit
It
is
our
itrarmally
of
concerning
metal
ion
problems
similar
to
off 2+ Ca
binding those
the
as
to
protein. to
Ca NMR
authors
works
seem
the
binding for method
is
free
and
break
exemplified the
Shimizu
proteinas
35c1 -
tighter
down, by
and
divalent leading
this
to
study,
time-consuming
by
study
such
other
measure-
Unfortunately
proteins
favour
and
ions 2+
to
to
becomes Ca
experi-
in the collecwell
between
monovalent
excess
perform
43
on
for
case
to
COMMUNICATIONS
time-savings rates
when
outlined
based
usually
case
the
RESEARCH
These
exchange
experience
pays level
ratio. obvious
often in
were
method"
the
is
BIOPHYSICAL
(13)
to of
when
decrease,
assumptions
cases
et 2+
This is usually the 39 + K (23). However,
a subsaturating
NMR papers suffer
Ca
AND
because
(13).
fast.
conclusions. in
high
macromolecules
rates
erroneous that
data
(22)
the
a very
Shimizu
strategy
are
exchange
of
at
NMR
ions
(211, the
BIOCHEMICAL
several and
Hatano
other (24)
above.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. IO. 11. 12. 13. 14.
15. 16. 17. 18.
19. 20.
Klee, C.B., and Vanaman, T.C. (1982) Adv. Protein Chem. 28, 214-321. Rasmussen, H. (1983) Ann. Int. Medic. 98, 809-816. Keller, C.H., Olwin. B.B.. LaPorte, D.C.. and Storm. D.R. (1982) Biochemistry-21, 156-162.. Maulet, Y., and Cox, J.A. (1983) Biochemistry 22, 5680-5686. LaPorte, D.C., Wierman, B.M., and Storm, D.R. (1980) Biochemistry 9, 3814-3819. Vogel, H.J., Lindahl, L., and Thulin, E. (1983) FEBS Lett. 157, 24 -246. Krebs, J., Buerkler, J., Guerini, D., Brunner, J., and Carafoli, E (1984) Biochemistry 23, 400-403. Keller, C.H., Olwin, B.B., Heideman, W., and Storm, D.R. (1982) in Calcium and Cell Function (Cheung, W.Y. Ed) Academic Press, New York, 10 3-127. , . Inagaki, M., Tanaka, T., and Hidaka, H. (1983) Pharmacology 27, 125-129. Forsen, S., Thulin, E., Drakenberg, T., Krebs, J., and Seamon, K. (1980) FEBS Lett. 117, 189-194. Thulin, E., Andersson, A., Drakenberg, T., Forsen, S., and Vogel, H.J. (1984) Biochemistry 23, 1862-1870. Andersson, A., Drakenberg, T., Forsen, S., and Thulin, E. (1983) Eur. J. Biochem. 134, 459-465. Shimizu, T., Hatano, M., Nagao, S., and Nozawa, Y. (1982) Biochem. Biophys. Res. Comm. 106, 1112-1118. Thulin, E., Forsen, S., Drakenberg, T., Andersson, T., Seamon, K.B., and Krebs, J. (1980) in Calcium-binding proteins: Structure and Function (Siegel F.L. et al. Eds.), Elsevier, Amsterdam, 243-244. Andersson, T., Drakenberg, T., For&, S., and Thulin, E. (1982) Eur. J. Biochem. 126, 501-505. Drakenberg, T., ForsPn, S., and Lilja, H. (1983) J. Magn. Reson. 53, 412421. Vogel, H.J., and Braunlin, W.H. (1983) J. Magn. Reson. Vogel, H.J., Drakenberg, T., and Forsen, S. (1983) in NMK of newly accessible nuclei (Laszlo, P., Ed.) Vol I, Academic Press, New York, 157-192. Bayley, P., Ahlstriim, P., Martin, R., and Forsen, S. (1984). Biochem. Biophys. Res. Comm. 120, 185-191. Burger, D., Cox, J.A., Comte, M.A., and Stein, E.A. (1984) Biochemistry 23, 1966-1971. 1355
Vol.
21. 22. 23. 24.
122,
No.
3, 1984
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Forsen, S., and Lindman, B. (1981) in Methods of Biochemical Analysis (Glick, D., Ed.), Vol. 27, 284-486. Braunlin, W.H., Drakenberg, T., and For&, S. (1985) in "Current Topics ir Bioenergetics" (Lee, P.C. Ed), (in press). Braunlin, W-H., Vogel, H.J., and Forsen, S. (1984) Eur. J. Biochem. (in press). Shimizu, T., and Hatano. M. (1982) Biochem. Biophys. Res. Comm. 104, 13561362, ibid 104, 720-726, (1983) Inorg. Chem. Acta 80, L37-L39.
1356
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
August 16, 1984
Pages 1350-l
TRIFLUOPERAZINE
BINDING
Hans
J.
Vogel, Torbjorn
Department
Received
July
5,
TO CALMODULIN:
of
A SHIFT
Thomas Andersson, Drakenberg and Physical Lund,
REAGENT
William H. Sture ForsPn
43CA
NMR
STUDY
Braunlin,
Chemistry 2, University S-220 07 Lund, Sweden
of
Lund
1984
43Ca NMR experiments of Ca2+ binding to calmodulin (CaM) were performed in the presence and absence of the calmodulin antagonist trifluoperazine (TFP). By making use of the shift reagent Dy(PPP)z(a I:2 complex of DyC13 and Na5P3010) we have succeeded in separating the "3Ca resonances of protein-bound Ca2+ and free Ca2+ in the otherwise unresolved spectra. This experimental strate$y has allowed us to demonstrate unequivocally that the affinity of CaM for Ca + is markedly increased in the presence of TFP. Thus Ca'+ is not liberated from the protein upon addition of TFP as had been suggested based on earlier 43Ca NMR experiments (Shimuzu, T., Hatano, M., Nagao, S. and Nozawa, Y. (1982), Biochem. Biophys. Res. Cotnm. 106, 1112-1118).
Calmodulin tein
in
all
(CaM)'
eukaryotic
that
the
activation
lin
takes
place
measurements
ternary
complexes.
the
for
these
substances creases
that
CaM
upon In
ported
'I3
to
that on their
'Abbreviations troponin
of
"...Ca 43 Ca
compete
of these 2+
with
agreed
TnI
and
CaM's
be of with
is set
other
an
free
similar
of
used are: CaM, calmodulin, TFP, W7, N-(6-aminohexyl)-5-chloro-l-naphtalenesulfonamide.
CaM
CaM
by
Ca
binding CaM
that
CaM. 43
such
to
(5-7).
hydrophobic
from
in
binding
by
affinity hydrophobic ions
compounds
the
These
Ca measurements
trifluoperazine,
the
unexpectedly,
metal
Shimizu
as
combining
Not 2+
of
for
direct
such
increased
(2).
enhanced
provided
enzymes
the
surprising
Tetrahymena
apo-CaM
substances,
affinity
or it
is 45ca2+
melittin,
target
to
to
2+
surfaces
rise
the
(10,ll)
Ca of
concerning
that
to
for
Ca2+
pro-
have shown 2+ Ca -calmodu-
by
of
hydrophobic
gives
results seems
binding
hydrophobic
also
TFP
phosphodiesterase the
as
Cd NMR experiments
NMR measurements
conclusions
I,
can
regulator
laboratories
experiments
Several
Ca2+ -induced .
various
affinity
such
demonstrated
binding
view
proteins,
substances
Moreover,
CaM's
(3,4).
TFP,
CaM's
in
enzyme cyclic-AMP 2+ -levels than
dialysis
notion
calcium-binding
Studies
that
model
this
of
(8,9).
(1,Z).
indicated
with
addition
Ca
multifunctional
Equilibrium
drug
reversibly
the
lower
of
antipsychotic
based
of
presence
evidence
the
cells
at
These
in
is
in-
(12).
et
al.
addition
(13) of
authors
TFP..."
suggested which
TnI
we
per-
re-
356
Vol.
122,
No.
formed
on
bovine
cative
of
increased
controversy on the
CaM
of
lished
anionic
shift
elsewhere
the
(17).
resonances
for
resonances
that
MATERIALS
we
AND
introduced
reagents.
The
use
of
of
to
CaM by 43 Ca NMR
details
shift 2+
the
of
reagents
Ca
and
free
Ca
analysis
has 2+
data
this 43 Ca
NMR.
indi-
To
improve based
method
will
allowed
us
without
Ca
as
apparent
experiment
this
43
of
COMMUNICATIONS
our
resolve
a novel
the
complicates
to
TFP
full
RESEARCH
interpreted
order
binding
protein-bound
normally
In
have
The
the
BIOPHYSICAL
we had
(14). the
studies,
AND
eventhough affinity
reinvestigated
earlier
use
(14-16), 2+
Ca
we
our
BIOCHEMICAL
3, 1984
to
the
NMR
be
on pub-
follow
overlap
of
spectra.
METHODS
43Ca NMR spectra were obtained an two different NMR spectrometers, a homebuilt 6 Tesla instrument (16) and a Nicolet 360 WB. The details of the sample preparations and the spectral parameters used for these studies have been presented elsewhere (15,17). Isotopically enriched 43Ca (60 i:) was obtained from Techsnabexport, Moscow, USSR through their Swedish sales agent Matreco AB, Sodertalje, Sweden. Bovine brain and bovine testis CaM were purified as previously described (11). All other chemicals used were of the highest quality commercially available.
RESULTS Upon resonance 2+ of Ca width
titration is
CaM.
the
a spectrum from
composed the
this
this
Note
that
spectra, and
shape
since
this
of
CaM
in
resonance
goes
exchange
(15,16).
observed
and
of
have
absence
brain
and
presence
However, slow
in
the
exchange
conditions 1351
of
are
not
followed
the prevail.
Since
narrow
(18)
presence protein in
signal
the
temperature
no
Addition 43 Ca reso-
the
long
via drug
shift.
the
was
When
1).
overlooked
shown.
testis
slow
with figure
easily
of
the
TFP.
B,
rather
and
from
fitted
proteins.
TFP
3 compares of
presence
is
linewidth
prohibitively
temperature
be panel
chemical
ions
is
resonance
is
indicates
resonance
Figure
increasing
thus
directly
in
required
concentration.
the
curves
broad
(see
resonance
the
line-
spectrum
nonetheless
with in
4 eqv.
the
this
calcium-binding
a titration
wide
almost
narrower
a similar
most
the
that
line
a broad
decrease
both the
can
43Ca2+ of
titration
of
it
with
studies
sites
would
with
that
resonance
a marked
the
binding
protein
A),
Lorentzian
results in
of
panel broad
Hz
Figure 1 shows such 2+ Ca . Although we know
additional
1,
protein-bound
in
CaM
Hz
apparent
for
behaviour
a higher
dence
2 the
the
is
arise
results
TFP
365
range
figure
The strong
figure
of
of
an
of
increased
6 eqv. levels
700-800
a ratio
(15,16).
containing
and
to
one
further
rapidly
component
a narrower
will
drug
two
is
of shift
situation
broad
it
up is
subsaturating
a single
presence
nance.
Hz
only
spectra
concentration
a sample
in
to
chemical
In of
800
NMR
normally
decreases
at
comparison
the
this
for
43Ca2+ Ca
Ca
resonance
simulation ease
From
the
an
;ith
the 2+
the
obtained
of
relative
in
major
data
CaM
in
As
obtained
our
(see
observed
per
of
of
drug
is
these acquisition depen-
added
intermediate no
change
of (10,14).
the to
in
linewidth
fast
Vol.
122,
No.
3, 1984
BIOCHEMICAL
AND
BIOPHYSICAL
PPM
RESEARCH
COMMUNICATIONS
1000
0
-1000
HZ
Simulations using Lorentzian lines for a 43Ca resonance measured .3 MHz for a sample containing 1 mM CaM, 6 mM CaZt, 100 mM NaClOs, pH 7.0. Panel A shows (from top to bottom) the measured spectrum, the simulated spectrum and the two Lorentzian lines (750 and 280 Hz) that were used for the fitting. Panel B shows the fitting of the measured data points to a single Lorentzian resonance of 365 Hz. The measured spectrum was broadened by 25 Hz in both cases by exponential multiplication of the free induction decay.
In this
a final
the
shift
final
concentration
shift
reagent
ions
up
to
experiment reagent
-125
ppm
used
Dy(PPP)g of
which
we
1.2
(a
mM.
can
displace
(17).
As
This
2
w-3.0
sample
I:2
is
from
complex
complex
resonances
of
is
a very
for
free
demonstrated
by
1
I
0
the
1
2
TFP /
3
4
DyC13
I and and
Na5P30,D)
effective or
comparing
added
3
to to
a
anionic
weakly
bound
figures
Ca
2+
4B and
I
0
CaM
figure
4C
I 20
60
60
T:rtlP. ( w
The 43Ca NMR linewidth as a function of the [TFPl/[CaM] ratio for mM CaC12 solution, pH 7.0 containing 0.40 mM bovine brain-CaM (0) a 3.0 mM CaC12 solution, pH 7.0 containing 0.44 mM bovine testis-CaM. The spectra for this figure were obtained at 17.2 MHz. The linewidth of the free Ca2+ resonance (- 12 Hz) is not substracted from those given in this figure.
Figure 4 3 310 The the this
The temperature dependence of the *3Ca NMR linewidth for: (0) a 3. mM CaClp solution at pH 7.0 containing 0.9 mM bovine testis-CaM, (0) a mM CaC12 at pH 7.0 containing 0.4 mM bovine testis-CaM and 1.3 mM TFP. spectra for this figure were obtained at 17.2 MHz. The linewidth of free Ca2+ resonance (- 12 Hz) is not substracted from those given in figure. 1352
Vol.
122,
No.
BIOCHEMICAL
3, 1984
,
1
I
>
50
Figure 4. containing additions
we obtain in
the
43 Ca The
This
downfield
improved
reagent
as
resonance
of the
the
can
is It
be
upon -50
broadened
paramagnetic of
-50
4C
the
-100
not
been
to
is
additional reagent spectrum
of
that of
COMMUNICATIONS
for
figures
exchange
with
amount (17). 4D was
free
of Upon obtained.
1353
obtained pH 7.0 with mM Dy(PPP):-,
the
excess
for a sample the following D) 3 mM TFP.
shift
the
of
Ca over 43Ca2+
addition
4A and
4C.
reagent 2+
protein-bound by
the
PPM
of
an the
affected
comparison
ppm
addition
containing
corresponds
because an shift
figure
after
solutions
ppm has
seen at
experiences
sample
of +I0
resonance
shifted
(16).
at
RESEARCH
VT-7
0
resolution
NMR spectrum
resonance
resonance
T
BIOPHYSICAL
“3Ca NMR spectra (24.3 MHz, 106 transients) 1 M bovine testis CaM, 100 fl NaCIOk, A) 2.0 evq. Ca2+, B) 6 eqv. Ca'+,C) 1.2
much
CaM.
AND
of
.
the
The
shift
upfield
Ca 2+ ions. The latter 2+ Ca bound to the protein
broadening addition
due of
The
most
to
the
3 eqv.
of
noticeable
presence TFP
to change
Vol.
in
122,
the
No.
spectrum
Similar W7,
3, 1984
results that
also
BIOCHEMICAL
is
a considerable
as
those
binds
BIOPHYSICAL
narrowing
shown
to
AND
in
of
figure
calmodulin
in
a Ca
RESEARCH
the
upfield
COMMUNICATIONS
shifted
4 were obtained with 2+ -dependent manner
2.
resonance
another (9)
drug,
(data
not
shown).
DISCUSSION The
results
nance
for
upon
addition
been
suggested
nance the
Ca
for 2+
of
the
the
of (< that
(16).
On
the
Ca'+.
Thus of
linewidths
(16)) off-rate
too
stopped contained ionic in
free
in
figure
43 Ca
other
equilibrium
that
to
flow 100 strength
the
various
sensitive
to
free
those
the
two
measurable or
studies
'H
whereas
(15,19).
The thus strength
virtually
on
at
23'C
the
in
agreement
(2-4,
8,9). Ca
Ca2+
From
have
the
at
NMR
one 2+
con-
exchange
rate
changed,
this
affinity
for
outcome
in
of
a in
figures
This
number
Ca NMR
23'C
the
time-
can
difference
43
using
in
the
not
the
resonances -1 800 set
set -I
further no change
increased with
earlier 700
Ca
2t
of
(ca.
the
an
is
between
temperature
rate
for
had reso-
(19)).
the 4C and is
in
(1000
set
This
Ca
-1 2+
low-affinity sites of CaM, as we have discussed 2+ Ca off-rate for the two high affinity sites 43 by Ca NMR but it can be estimated using
The
mM NaC104
This
There is 2+ Ca with
linewidth
determined
fluorescence
solution.
as the rate
exchange
upfield-shifted 2t a minimum Ca off-rate with
of
exchange
reflecting
are
protein
in
on-rates as
the
the
reso-
intensity
narrowing
decreased
the
in
low
the
fluorescence
ionic
the
2.
markedly
studies
for
for
be
has
NMR results
(11,15,16,19). slow
a very
TFP
in
of
differences
interpreted
these
is
resonance
that
directly
stopped-flow
elsewhere is
that
of
the in
that
decrease
from
Rather,
and
assumption
agreement and
liberated
shown
the
or
a decrease
suggesting
calculate
excellent
not (13).
indicates
From
measured
we can
is
al.
clearly
disappear
protein
addition
be
4 demonstrate not
results 43 the Ca
drug,
the
can
variety
the the of
the
Ca
2+.
figure
does 2+
et
Ca
10 set-'j.
result
Thus
Shimizu
to by
linewidth
clude
4D
TFP.
excess
bound
presence scale
in 2+
Ca
by
substantiated in
depicted
protein-bound
NMR
(19,ll).
our
earlier
good
agreement
indicates in
The
contrast
samples
work for
that
these to
recent
used
for
was the
performed 2-t off-rate Ca
numbers allegations
are
at
figure lower measured
not
extremely
(20).
'A second change is that the relative integrated intensities of the protein-bound and the free resonance alter. This is related to the fas,t that the shift reagent used in this study has an affinity for Ca which approximates that of the two weak2$ites of CaM (17). bound to the protein. Hence it would pull out a fraction of the Ca The increase observed for the protein-bound resonance upon addition of TFP provides thus additional evidence for an increased Ca2+ affinity in the CaM-drug complex. 1354
4
,
Vol.
122,
No,
The lnents
3, 1984
conclusions
performed
this
experimental
tion
of
ion
binding
bound
the
to
23Na+
cations,
ments
such
at
and
from
This
al.
CaM its
"excess
as implicit
It
is
our
itrarmally
of
concerning
metal
ion
problems
similar
to
off 2+ Ca
binding those
the
as
to
protein. to
Ca NMR
authors
works
seem
the
binding for method
is
free
and
break
exemplified the
Shimizu
proteinas
35c1 -
tighter
down, by
and
divalent leading
this
to
study,
time-consuming
by
study
such
other
measure-
Unfortunately
proteins
favour
and
ions 2+
to
to
becomes Ca
experi-
in the collecwell
between
monovalent
excess
perform
43
on
for
case
to
COMMUNICATIONS
time-savings rates
when
outlined
based
usually
case
the
RESEARCH
These
exchange
experience
pays level
ratio. obvious
often in
were
method"
the
is
BIOPHYSICAL
(13)
to of
when
decrease,
assumptions
cases
et 2+
This is usually the 39 + K (23). However,
a subsaturating
NMR papers suffer
Ca
AND
because
(13).
fast.
conclusions. in
high
macromolecules
rates
erroneous that
data
(22)
the
a very
Shimizu
strategy
are
exchange
of
at
NMR
ions
(211, the
BIOCHEMICAL
several and
Hatano
other (24)
above.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. IO. 11. 12. 13. 14.
15. 16. 17. 18.
19. 20.
Klee, C.B., and Vanaman, T.C. (1982) Adv. Protein Chem. 28, 214-321. Rasmussen, H. (1983) Ann. Int. Medic. 98, 809-816. Keller, C.H., Olwin. B.B.. LaPorte, D.C.. and Storm. D.R. (1982) Biochemistry-21, 156-162.. Maulet, Y., and Cox, J.A. (1983) Biochemistry 22, 5680-5686. LaPorte, D.C., Wierman, B.M., and Storm, D.R. (1980) Biochemistry 9, 3814-3819. Vogel, H.J., Lindahl, L., and Thulin, E. (1983) FEBS Lett. 157, 24 -246. Krebs, J., Buerkler, J., Guerini, D., Brunner, J., and Carafoli, E (1984) Biochemistry 23, 400-403. Keller, C.H., Olwin, B.B., Heideman, W., and Storm, D.R. (1982) in Calcium and Cell Function (Cheung, W.Y. Ed) Academic Press, New York, 10 3-127. , . Inagaki, M., Tanaka, T., and Hidaka, H. (1983) Pharmacology 27, 125-129. Forsen, S., Thulin, E., Drakenberg, T., Krebs, J., and Seamon, K. (1980) FEBS Lett. 117, 189-194. Thulin, E., Andersson, A., Drakenberg, T., Forsen, S., and Vogel, H.J. (1984) Biochemistry 23, 1862-1870. Andersson, A., Drakenberg, T., Forsen, S., and Thulin, E. (1983) Eur. J. Biochem. 134, 459-465. Shimizu, T., Hatano, M., Nagao, S., and Nozawa, Y. (1982) Biochem. Biophys. Res. Comm. 106, 1112-1118. Thulin, E., Forsen, S., Drakenberg, T., Andersson, T., Seamon, K.B., and Krebs, J. (1980) in Calcium-binding proteins: Structure and Function (Siegel F.L. et al. Eds.), Elsevier, Amsterdam, 243-244. Andersson, T., Drakenberg, T., For&, S., and Thulin, E. (1982) Eur. J. Biochem. 126, 501-505. Drakenberg, T., ForsPn, S., and Lilja, H. (1983) J. Magn. Reson. 53, 412421. Vogel, H.J., and Braunlin, W.H. (1983) J. Magn. Reson. Vogel, H.J., Drakenberg, T., and Forsen, S. (1983) in NMK of newly accessible nuclei (Laszlo, P., Ed.) Vol I, Academic Press, New York, 157-192. Bayley, P., Ahlstriim, P., Martin, R., and Forsen, S. (1984). Biochem. Biophys. Res. Comm. 120, 185-191. Burger, D., Cox, J.A., Comte, M.A., and Stein, E.A. (1984) Biochemistry 23, 1966-1971. 1355
Vol.
21. 22. 23. 24.
122,
No.
3, 1984
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Forsen, S., and Lindman, B. (1981) in Methods of Biochemical Analysis (Glick, D., Ed.), Vol. 27, 284-486. Braunlin, W.H., Drakenberg, T., and For&, S. (1985) in "Current Topics ir Bioenergetics" (Lee, P.C. Ed), (in press). Braunlin, W-H., Vogel, H.J., and Forsen, S. (1984) Eur. J. Biochem. (in press). Shimizu, T., and Hatano. M. (1982) Biochem. Biophys. Res. Comm. 104, 13561362, ibid 104, 720-726, (1983) Inorg. Chem. Acta 80, L37-L39.
1356