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Native tropomyosin: Effect on the interaction of actin with heavy meromyosin and subfragment-1
Vol. 40, No. 1, 1970
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
NATIVE TROPOMYOSIN: EFFECT ON THE INTERACTION OF ACTIN WITH HEAVY MEROMYOSIN AND SUBFRAGMENTWan Eisenberg and W. Wayne Kielley Physiology, Laboratory of Biochemistry, National Institutes of Health, Bethesda,
Section on Cellular and Lung Institute,
National Heart Md. 20014
Received May 18, 1970 native tropomyosin markedly inhibits the SUMMARY. In the absence of Cai', acto-subfragment-l ATPase as well as the acto-heavy meromyosin ATPase despite the fact that subfragment-1, in contrast to heavy meromyosin, has only a single site for ATP. Double reciprocal plots of acto-heavy meromyosin ATPase vs. actin concentration both in the presence and absence of native tropomyosin, show that the native tropomyosin has little effect on the acto-HMM-ATPase but acts mainly by affecting the binding of actin to the HMM-ATP complex. It vivo
by release
binds the
is now generally of Caf+
to native actin
occurs
which muscle
native
tropomyosin
myosin
ATPase
with
strength,
but
the
actin
absence
in the
made it
of actin
the
native
in the
of native
allows
contraction actin-myosin tropomyosin
absence
of actomyosin
absence
or perhaps
both.
because
with
meromyosin
actin
heavy
concentration
of Cai+,
native
is
one of the tropomyosin
the
the
of Ca++, and the
tropomyosin,
in the
acto-
Ca++
and the
blocks
50
very
of
reciprocal
and therefore turnover
at
actin
low ionic
binding
of the
in vivo of
acto-
plots
In a recent
that
binding
the
to
the
rate (6).
is
difficult
double
proposed the
is
rate
state
independently authors
tropomyosin
precipitated
@MM) linear
(4)
native
turnover
question
can be obtained
can be determined
contraction,
whether
This
it
HMM-ATP complex
(Vmax)
clear
to myosin-ATP,
actomyosin
to the
ATP complex of muscle
studies
complex
vs.
in vitro,
-in
Ca++
in turn
hand,
by the
superprecipitation
whereas
binding
approach
ATPase
Analogously
which
other
inhibited
triggered This
such a way that
, on the
is
is
(1,2).
filament, in
of Caf+
both
reticulum
actin
interact
of muscle
(2,5).
the
myosin-ATP
the
to
(1,2).
inhibits
None of these reducing
along
contraction
activity,
has no effect
contraction
sarcoplasmic
absence
causes
relaxes
that
the
filaments
In the
(2,3,4).
and the
from
tropomyosin
and myosin
interaction
accepted
of of
acto-HMMmodel
in the to myosin-ATP
Vol. 40, No. 1, 1970
rather
than
BIOCHEMICAL
the
turnover
reciprocal
plot
reported
preliminary
rather
than
also
with
results
present
study
investigated
demonstrated
with
HMM which, site
technique
for
of the
actomyosin-ATP
acto-HMM, which
complex
however,
suggest
that
(7).
Szentkiralyi
Using
the
and Oplatka
tropomyosin
affects
Vmax
using
HMM and
Ka(8).
In the have
rate
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
whether
We find
and HMM suggesting of native
native
tropomyosin
any effect
that
the
on the
a further
tropomyosin tryptic
that
tropomyosin
the
native
binding rate
of
of the
actin
product
on HMM., has only affects
on HMM are not find
can be
digestion
sites
We further
turnover
question
of native
two ATP sites
on the
this
two ATP binding
tropomyosin. is
effect
(S-l),
to the
ATP (9,lO).
investigated
the
subfragment-
in contrast
effect
we have
that
the
major
S-l
for
effect
to HMM-ATP, with
acto-HMM-ATP
a single
both
required
of
the of
little
if
complex.
MATERIALS AND METHODS Myosin and S-l gel G-200
was prepared
were
also
filtration
prepared
to purify
column
was then
RPM and finally tropomyosin
taken
as described
previously
using
Actin
was prepared
S-l
that
used
in all
solutions.
(7,12).
by Adelstein
into
was prepared
exception
tropomyosin
of Kielley
to F-actin
the
described
method
the
as described
polymerized
as described
by the
et al.
, pelleted
solution
twice
previously
rather
ATPase was measured
(7).
was 380 a2/q
Protein
G-200
a Sephadex
The resulting
previously
than
at 25'C,
G-actin at 30,000
(12).
Native
and Mueller
(14) with
2mM dithiothietol pHz7.0
HMM
Sephadex
using
using
concentrations
were
also
coefficient
used
for
The extinction at 278~
(11).
by centrifuqation
by Hartshorne
5mM 2mercaptoethanol
(12).
(13).
as described
as described
previously
and Harrinqton
was a pa-stat
measured
as
native
(14).
RESULTS AND DISCUSSION Table tetraacetic both
with
I shows the acid
effect
(EGTA) on the
and without
native
of ea++ and ethyleneqlycol-bis(aminoethylether) ATPase activity tropomyosin
present.
51
of acto-HMM In the
and acto-S-l absence
of native
BIOCHEMICAL
Vol. 40, No. 1, 1970
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE I Effect
of
Native
Tropomyosin
on Acto-HMM
and Acto-S-l
ATPase Excess EGTA
Protein Acto-HMM Acto-HMM+Native
tropcmyosin
Acto-S-l Acto-S-l+Native
tropomyosin
ATPase
(~mole/mg-min) Excess Ca++
1.48
1.36
0.09
2.26
0.85
0.02
0.16
1.00
For the experiment with HMM all samples contained 1.6mM ATP, 0.8mM There was 0.24 mg/ml HMM in MgC12 I 18mM KCl, and 0.4 mg/ml actin. the sample with excess EGTA and native tropomyosin, and 0.12 mg/ml Native tropomyosin when added equaled HMM in the other samples. 0.5 mg/ml. Samples with excess EGTA contained 5.OmM EGTA and samples with excess Ca++ contained 5.OmM EGTA and 5.2mM CaC12. For the experiments with S-l all samples contained 2mM ATP, 1mM MgC12, 2OmM KC1 0.8 mg/ml actin, and 0.20 mg/ml S-l. Native tropomyosin when added equaled 1.0 mg/ml. Samples with excess EGTA contained 1mM EGTA and samples with excess Caf+ contained 0.5mM CaC12.
tropomyosin
the
acto-H?lM This
or EGTA was present. presence
of native
tropomyosin
effect
by Hartshorne
was also
tropomyosin
increased
activating
ATPase was essentially
both
with the
of native for
in the
absence
occurred
for,
as can be seen,
marked
inhibition
of both
clear
that
previously despite
native been
the We next
fact
Ca++,
that
the
tropomyosin reported that
plot
experiment
cannot
excess
acto-HMM
the the
S-l
with
of acto-HMM be performed
acto-S-l
ATPase of the
EGTA present
the
acto-HMM
and acto-S-l
not
affects
(16)
a single
effect ATPase
but
of native vs.
actin
by adding
52
the
was reported
However
native
Thus
acto-HMM
ATPase,
site
for
was
tropomyosin
ATPases.
affects
it
tropomyosin
native
also
the
acto-S-l
caused it
is as has ATPase
ATP.
tropomyosin concentration.
a constant
native
A similar
of Ca+f
(IS).
Ca++
In the
the
ATPases.
presence
excess
ATPase.
present,
and acto-S-l
effect
only
same whether
Ca++ also
in the
major
has only the
the
actomyosin
by Kominz
investigated
reciprocal
for
tropomyosin
and Mueller of
true
the
amount
on the Clearly of native
double this tropo-
Vol. 40, No. 1, 1970
myosin then
since
the
decrease
ratio
BIOCHEMICAL
fraction
as the
of native
completely with
native
due to therefore
I,
even
was essentially
in the
the
reciprocal
a range
where
the
which
with
to hold
the
of actin
free
the
also over
ATP, the
native
EGTA was a poor
in the
reciprocal
by EGTA i.e.
shown
the
actin
We then constant
Ca++-free
of actin
so
native
concentration
effect
to Mg++.
We also
native
tropomyosin
little
below
native
tropomyosin
were noted
of
almost
employed
from
which
actin
as the
low
strength,
at the
the
maximal
effect all
in Figure
of the of these
native factors
1 to perform
our
tropomyosin into
to the
plots
very
lowest
53
in which --
actin.
the
an
Both of ATP
action
of
was still
Figure
a
dissociation (17).
of
Since
is most
accurate
KC1 concentration
consideration,
experiment.
presence
at a KC1 concentration
reciprocal
the
we worked
Mg++,
strength
of Vmax and Ka from
ionic
of HMM to
ionic
determinations
in the
was noted
of excess
may be related low
by Ca++ in
at a two to one ratio
disappeared
at very
experiment.
ATP was hydrolyzed
ratios
by working absence
this
was affected
tropomyosin
by high
in the
for
Furthermore
native
completely
15mM, an effect
tropomyosin
activated
avoided
that
chosen
Ca++-buffer.
seemed to be increased
difficulties
given
as is
used
with
had to be carefully
became markedly
of these
Taking
We
where,
Ca++ concentration
range
complexed
complex.
tropomyosin.
complexed
not
concentrations
to actin
native
were
of actin
tropomyosin
90% inhibited
a constant
actin
low actin
concentration
than
throughout
Mg++ an unusual
ATPase rate
effect
at
if
the
fraction
would
plot.
conditions
excess
but
tropomyosin
actin
tropomyosin
Similarly
the
actin-native
saturated
fraction
native
employed,
to decrease
ATPase was more
Mg++ in excess
the
lowest
was constant
Other
of
at the
an EGTA-Ca ++ buffer
tropomyosin
With
tend
of native
completely
in effect,
that,
were
tropomyosin,
of the
a ratio
acto-HMM
employed
might
dissociation
employed
the
plot,
native
with increased.
to actin
with
tropomyosin
saturated
concentration
tropomyosin
partial
in Table
of actin
actin
saturated
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
at
where
observed. we chose
the
1 shows
double
conditions reciprocal
Vol. 40, No. 1, 1970
BIOCHEMICAL AND BIOPHYSICAL
0
-10
IO I /ACTIN
RESEARCH COMMUNKATIONS
20
(mg /ml )-’
FIGURE 1 Double reciprocal plots of acto-HMM-ATPase vs. actin concentration with and without native tropomyosin. All samples contained 1.6mM ATP, 0.8mM MgC12, 19mM KCl, 5mM EGTA, 2mM CaC12. (0) Native tropomyosin added at a concentration equal to 1.25 times the actin concentration, HMM concentration varied from 0.14-0.27 mg/ml. (0) No native tropomyosin added. HMM concentration varied from 0.06-O-12 mg/ml. As described previously for this type of plot (6), in all cases the ATPase of the HMM in the absence of actin was subtracted from the measured ATPase rate to give the acto-HMM ATPase rate, the reciprocal of which is plotted on the ordinate.
plots
of
absence
acto-HMM of native
tropomyosin
only
are
change a
yielded may
plots
small
in the change
essentially
native
i.e.
the
This
is
ATPase because
partial linear
of
and the
native
intercept ordinate
high, tropomysoin rate
the
at the highest
under
tropomyosin
point
this
small
the
plot Repeat
change
(Ka),
observed plot
at
is,
anything,
above
its
is probably concentration
a but
experiments
reciprocal
condition
native
to cause
on the if
and
As can be
appears
(Vmax).
tropomyosin
54
presence
where
reciprocal
Even the
native
in the
acto-HMM-ATPase.
of the
concentration
observed
the
intercept
data.
since
both
Ca++ concentration
inhibition
abscissa in the
concentration
at a free
identical
be erroneously
highest
actin
tropomyosin
causes
seen both marked
ATPase vs.
too
in Vmax the true low.
employed,
value
BIOCHEMICAL
Vol. 40, No. 1, 1970
trace
amounts
produced the
enough
reaction
during to
of myokinase
the
the
percent.
major
rate
turnover
of
of native
of the
that
under
to the
HMM-ATP complex.
recently
obtained
a comparable
This
result
fibers
which
on the
unloaded
development that skeletal little
the
velocity
(18). actin
that
It
result
resistance
ACKNOWLEDGEMENTS We would like assistance.
since
with
also
relaxed
to stretch to thank
pH-stat
but with
approach
Hartshorne
has
personal
communication).
on skinned
reduce
studies during
the binding
does markedly
to activated
out,
effect
in the
has
are dissociated
even
a small
concentration
in vivo
in
by a few
be ruled
experiments Casf
as opposed
the
to be a reduction
recent
occur
been produced
although
(D. Hartshorne,
consistent
filaments
in pH to
and therefore
cannot
a similar
the
tropomyosin
NH3 may have with
complex
of contraction is
rise
conditions,
appears
decreasing
and myosin
muscle,
our
Using
may correlate
suggest
enough
acto-HMM-ATP
of actin
a slow
as measured
tropomyosin
native
ATP was hydrolyzed,
reaction
H+ production
of the
in the
ADP to cause
of the
conclude rate
effect
all
course
We thus
on the
after
initial
reduce
and AMP-deaminase
IMP and NH3 from
mixture
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
muscle little
effect
force
which
suggest
relaxation
muscle
of
shows very
(19). Mr.
Louis
Dobkin
for
his
excellent
technical
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.
Weber, A., Herz, R., and Reiss, I., Proc. Royal Sot. Series B., 160, 489 (1964). Ebashi, S. and Endo, M., Prog. in Biophys. and Molecular Biol. l8, 123 (1968). Endo, M., Nonomura, Y., Masaki, T., Ohtsuki, I., and Ebashi, S., J. Biochem. 60, 605 (1966). Fuchs, F. and Briggs, F.N., J. Gen. Physiol. 5l, 655 (1968). Ebashi, S. and Ebashi, F., J. Biochem. 55, 604 (1964). E. and Moos, C., Biochemistry 1, 1486 (1968). Eisenberg, Eisenberg, E., Zobel, C.R., and Moos, C., Biochemistry 1, 3186 (1968). Szentkiralyi, E.M. and Oplatka, A., J. Mol. Biol. 43, 551 (1969). Eisenberg, E., Barouch, W.W., and Moos, C., Federation Proc. B, 536 (1969). Morita, F. and Shimizu, T., Biochim. Biophys. Acta 180, 545 (1969). W.F., Biochim. Biophys. Acta 4l, 401 (1960) Kielley, W.W. and Harrington, Eisenberg, E. and Moos, C., 3. Biol. Chem. 242, 2945 (1967). Adelstein, R., Godfrey, J.E. and Kielley, W.W., Biochem. Biophys. Res. Comm. l2, 34 (1963). Hartshorne, D.J. and Mueller, H., Biochim. Biophys. Acta 175, 301 (1969).
55
Vol. 40, No. 1, 1970
15. 16. 17. 18. 19.
BIOCHEMICAL
D.J. and Mueller, Hartshorne, 647 (1968). Kominz, D-R., Arch. Biochem. Martonosi, A., J. Biol. Chem. Teicholz, L.E. and Podolsky, Hill, D.R., J. Physiol. 199,
AND BIOPHYSICAL
H.,
Biochem.
RESEARCH COMMUNICATIONS
Biophys.
Res.
Comm. 31,
and Biophys. 115, 583 (1966). 237, 2795 (1962). R.J., Biophys. J. lo, 218a (1970). 637 (1968).
56
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
NATIVE TROPOMYOSIN: EFFECT ON THE INTERACTION OF ACTIN WITH HEAVY MEROMYOSIN AND SUBFRAGMENTWan Eisenberg and W. Wayne Kielley Physiology, Laboratory of Biochemistry, National Institutes of Health, Bethesda,
Section on Cellular and Lung Institute,
National Heart Md. 20014
Received May 18, 1970 native tropomyosin markedly inhibits the SUMMARY. In the absence of Cai', acto-subfragment-l ATPase as well as the acto-heavy meromyosin ATPase despite the fact that subfragment-1, in contrast to heavy meromyosin, has only a single site for ATP. Double reciprocal plots of acto-heavy meromyosin ATPase vs. actin concentration both in the presence and absence of native tropomyosin, show that the native tropomyosin has little effect on the acto-HMM-ATPase but acts mainly by affecting the binding of actin to the HMM-ATP complex. It vivo
by release
binds the
is now generally of Caf+
to native actin
occurs
which muscle
native
tropomyosin
myosin
ATPase
with
strength,
but
the
actin
absence
in the
made it
of actin
the
native
in the
of native
allows
contraction actin-myosin tropomyosin
absence
of actomyosin
absence
or perhaps
both.
because
with
meromyosin
actin
heavy
concentration
of Cai+,
native
is
one of the tropomyosin
the
the
of Ca++, and the
tropomyosin,
in the
acto-
Ca++
and the
blocks
50
very
of
reciprocal
and therefore turnover
at
actin
low ionic
binding
of the
in vivo of
acto-
plots
In a recent
that
binding
the
to
the
rate (6).
is
difficult
double
proposed the
is
rate
state
independently authors
tropomyosin
precipitated
@MM) linear
(4)
native
turnover
question
can be obtained
can be determined
contraction,
whether
This
it
HMM-ATP complex
(Vmax)
clear
to myosin-ATP,
actomyosin
to the
ATP complex of muscle
studies
complex
vs.
in vitro,
-in
Ca++
in turn
hand,
by the
superprecipitation
whereas
binding
approach
ATPase
Analogously
which
other
inhibited
triggered This
such a way that
, on the
is
is
(1,2).
filament, in
of Caf+
both
reticulum
actin
interact
of muscle
(2,5).
the
myosin-ATP
the
to
(1,2).
inhibits
None of these reducing
along
contraction
activity,
has no effect
contraction
sarcoplasmic
absence
causes
relaxes
that
the
filaments
In the
(2,3,4).
and the
from
tropomyosin
and myosin
interaction
accepted
of of
acto-HMMmodel
in the to myosin-ATP
Vol. 40, No. 1, 1970
rather
than
BIOCHEMICAL
the
turnover
reciprocal
plot
reported
preliminary
rather
than
also
with
results
present
study
investigated
demonstrated
with
HMM which, site
technique
for
of the
actomyosin-ATP
acto-HMM, which
complex
however,
suggest
that
(7).
Szentkiralyi
Using
the
and Oplatka
tropomyosin
affects
Vmax
using
HMM and
Ka(8).
In the have
rate
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
whether
We find
and HMM suggesting of native
native
tropomyosin
any effect
that
the
on the
a further
tropomyosin tryptic
that
tropomyosin
the
native
binding rate
of
of the
actin
product
on HMM., has only affects
on HMM are not find
can be
digestion
sites
We further
turnover
question
of native
two ATP sites
on the
this
two ATP binding
tropomyosin. is
effect
(S-l),
to the
ATP (9,lO).
investigated
the
subfragment-
in contrast
effect
we have
that
the
major
S-l
for
effect
to HMM-ATP, with
acto-HMM-ATP
a single
both
required
of
the of
little
if
complex.
MATERIALS AND METHODS Myosin and S-l gel G-200
was prepared
were
also
filtration
prepared
to purify
column
was then
RPM and finally tropomyosin
taken
as described
previously
using
Actin
was prepared
S-l
that
used
in all
solutions.
(7,12).
by Adelstein
into
was prepared
exception
tropomyosin
of Kielley
to F-actin
the
described
method
the
as described
polymerized
as described
by the
et al.
, pelleted
solution
twice
previously
rather
ATPase was measured
(7).
was 380 a2/q
Protein
G-200
a Sephadex
The resulting
previously
than
at 25'C,
G-actin at 30,000
(12).
Native
and Mueller
(14) with
2mM dithiothietol pHz7.0
HMM
Sephadex
using
using
concentrations
were
also
coefficient
used
for
The extinction at 278~
(11).
by centrifuqation
by Hartshorne
5mM 2mercaptoethanol
(12).
(13).
as described
as described
previously
and Harrinqton
was a pa-stat
measured
as
native
(14).
RESULTS AND DISCUSSION Table tetraacetic both
with
I shows the acid
effect
(EGTA) on the
and without
native
of ea++ and ethyleneqlycol-bis(aminoethylether) ATPase activity tropomyosin
present.
51
of acto-HMM In the
and acto-S-l absence
of native
BIOCHEMICAL
Vol. 40, No. 1, 1970
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE I Effect
of
Native
Tropomyosin
on Acto-HMM
and Acto-S-l
ATPase Excess EGTA
Protein Acto-HMM Acto-HMM+Native
tropcmyosin
Acto-S-l Acto-S-l+Native
tropomyosin
ATPase
(~mole/mg-min) Excess Ca++
1.48
1.36
0.09
2.26
0.85
0.02
0.16
1.00
For the experiment with HMM all samples contained 1.6mM ATP, 0.8mM There was 0.24 mg/ml HMM in MgC12 I 18mM KCl, and 0.4 mg/ml actin. the sample with excess EGTA and native tropomyosin, and 0.12 mg/ml Native tropomyosin when added equaled HMM in the other samples. 0.5 mg/ml. Samples with excess EGTA contained 5.OmM EGTA and samples with excess Ca++ contained 5.OmM EGTA and 5.2mM CaC12. For the experiments with S-l all samples contained 2mM ATP, 1mM MgC12, 2OmM KC1 0.8 mg/ml actin, and 0.20 mg/ml S-l. Native tropomyosin when added equaled 1.0 mg/ml. Samples with excess EGTA contained 1mM EGTA and samples with excess Caf+ contained 0.5mM CaC12.
tropomyosin
the
acto-H?lM This
or EGTA was present. presence
of native
tropomyosin
effect
by Hartshorne
was also
tropomyosin
increased
activating
ATPase was essentially
both
with the
of native for
in the
absence
occurred
for,
as can be seen,
marked
inhibition
of both
clear
that
previously despite
native been
the We next
fact
Ca++,
that
the
tropomyosin reported that
plot
experiment
cannot
excess
acto-HMM
the the
S-l
with
of acto-HMM be performed
acto-S-l
ATPase of the
EGTA present
the
acto-HMM
and acto-S-l
not
affects
(16)
a single
effect ATPase
but
of native vs.
actin
by adding
52
the
was reported
However
native
Thus
acto-HMM
ATPase,
site
for
was
tropomyosin
ATPases.
affects
it
tropomyosin
native
also
the
acto-S-l
caused it
is as has ATPase
ATP.
tropomyosin concentration.
a constant
native
A similar
of Ca+f
(IS).
Ca++
In the
the
ATPases.
presence
excess
ATPase.
present,
and acto-S-l
effect
only
same whether
Ca++ also
in the
major
has only the
the
actomyosin
by Kominz
investigated
reciprocal
for
tropomyosin
and Mueller of
true
the
amount
on the Clearly of native
double this tropo-
Vol. 40, No. 1, 1970
myosin then
since
the
decrease
ratio
BIOCHEMICAL
fraction
as the
of native
completely with
native
due to therefore
I,
even
was essentially
in the
the
reciprocal
a range
where
the
which
with
to hold
the
of actin
free
the
also over
ATP, the
native
EGTA was a poor
in the
reciprocal
by EGTA i.e.
shown
the
actin
We then constant
Ca++-free
of actin
so
native
concentration
effect
to Mg++.
We also
native
tropomyosin
little
below
native
tropomyosin
were noted
of
almost
employed
from
which
actin
as the
low
strength,
at the
the
maximal
effect all
in Figure
of the of these
native factors
1 to perform
our
tropomyosin into
to the
plots
very
lowest
53
in which --
actin.
the
an
Both of ATP
action
of
was still
Figure
a
dissociation (17).
of
Since
is most
accurate
KC1 concentration
consideration,
experiment.
presence
at a KC1 concentration
reciprocal
the
we worked
Mg++,
strength
of Vmax and Ka from
ionic
of HMM to
ionic
determinations
in the
was noted
of excess
may be related low
by Ca++ in
at a two to one ratio
disappeared
at very
experiment.
ATP was hydrolyzed
ratios
by working absence
this
was affected
tropomyosin
by high
in the
for
Furthermore
native
completely
15mM, an effect
tropomyosin
activated
avoided
that
chosen
Ca++-buffer.
seemed to be increased
difficulties
given
as is
used
with
had to be carefully
became markedly
of these
Taking
We
where,
Ca++ concentration
range
complexed
complex.
tropomyosin.
complexed
not
concentrations
to actin
native
were
of actin
tropomyosin
90% inhibited
a constant
actin
low actin
concentration
than
throughout
Mg++ an unusual
ATPase rate
effect
at
if
the
fraction
would
plot.
conditions
excess
but
tropomyosin
actin
tropomyosin
Similarly
the
actin-native
saturated
fraction
native
employed,
to decrease
ATPase was more
Mg++ in excess
the
lowest
was constant
Other
of
at the
an EGTA-Ca ++ buffer
tropomyosin
With
tend
of native
completely
in effect,
that,
were
tropomyosin,
of the
a ratio
acto-HMM
employed
might
dissociation
employed
the
plot,
native
with increased.
to actin
with
tropomyosin
saturated
concentration
tropomyosin
partial
in Table
of actin
actin
saturated
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
at
where
observed. we chose
the
1 shows
double
conditions reciprocal
Vol. 40, No. 1, 1970
BIOCHEMICAL AND BIOPHYSICAL
0
-10
IO I /ACTIN
RESEARCH COMMUNKATIONS
20
(mg /ml )-’
FIGURE 1 Double reciprocal plots of acto-HMM-ATPase vs. actin concentration with and without native tropomyosin. All samples contained 1.6mM ATP, 0.8mM MgC12, 19mM KCl, 5mM EGTA, 2mM CaC12. (0) Native tropomyosin added at a concentration equal to 1.25 times the actin concentration, HMM concentration varied from 0.14-0.27 mg/ml. (0) No native tropomyosin added. HMM concentration varied from 0.06-O-12 mg/ml. As described previously for this type of plot (6), in all cases the ATPase of the HMM in the absence of actin was subtracted from the measured ATPase rate to give the acto-HMM ATPase rate, the reciprocal of which is plotted on the ordinate.
plots
of
absence
acto-HMM of native
tropomyosin
only
are
change a
yielded may
plots
small
in the change
essentially
native
i.e.
the
This
is
ATPase because
partial linear
of
and the
native
intercept ordinate
high, tropomysoin rate
the
at the highest
under
tropomyosin
point
this
small
the
plot Repeat
change
(Ka),
observed plot
at
is,
anything,
above
its
is probably concentration
a but
experiments
reciprocal
condition
native
to cause
on the if
and
As can be
appears
(Vmax).
tropomyosin
54
presence
where
reciprocal
Even the
native
in the
acto-HMM-ATPase.
of the
concentration
observed
the
intercept
data.
since
both
Ca++ concentration
inhibition
abscissa in the
concentration
at a free
identical
be erroneously
highest
actin
tropomyosin
causes
seen both marked
ATPase vs.
too
in Vmax the true low.
employed,
value
BIOCHEMICAL
Vol. 40, No. 1, 1970
trace
amounts
produced the
enough
reaction
during to
of myokinase
the
the
percent.
major
rate
turnover
of
of native
of the
that
under
to the
HMM-ATP complex.
recently
obtained
a comparable
This
result
fibers
which
on the
unloaded
development that skeletal little
the
velocity
(18). actin
that
It
result
resistance
ACKNOWLEDGEMENTS We would like assistance.
since
with
also
relaxed
to stretch to thank
pH-stat
but with
approach
Hartshorne
has
personal
communication).
on skinned
reduce
studies during
the binding
does markedly
to activated
out,
effect
in the
has
are dissociated
even
a small
concentration
in vivo
in
by a few
be ruled
experiments Casf
as opposed
the
to be a reduction
recent
occur
been produced
although
(D. Hartshorne,
consistent
filaments
in pH to
and therefore
cannot
a similar
the
tropomyosin
NH3 may have with
complex
of contraction is
rise
conditions,
appears
decreasing
and myosin
muscle,
our
Using
may correlate
suggest
enough
acto-HMM-ATP
of actin
a slow
as measured
tropomyosin
native
ATP was hydrolyzed,
reaction
H+ production
of the
in the
ADP to cause
of the
conclude rate
effect
all
course
We thus
on the
after
initial
reduce
and AMP-deaminase
IMP and NH3 from
mixture
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
muscle little
effect
force
which
suggest
relaxation
muscle
of
shows very
(19). Mr.
Louis
Dobkin
for
his
excellent
technical
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.
Weber, A., Herz, R., and Reiss, I., Proc. Royal Sot. Series B., 160, 489 (1964). Ebashi, S. and Endo, M., Prog. in Biophys. and Molecular Biol. l8, 123 (1968). Endo, M., Nonomura, Y., Masaki, T., Ohtsuki, I., and Ebashi, S., J. Biochem. 60, 605 (1966). Fuchs, F. and Briggs, F.N., J. Gen. Physiol. 5l, 655 (1968). Ebashi, S. and Ebashi, F., J. Biochem. 55, 604 (1964). E. and Moos, C., Biochemistry 1, 1486 (1968). Eisenberg, Eisenberg, E., Zobel, C.R., and Moos, C., Biochemistry 1, 3186 (1968). Szentkiralyi, E.M. and Oplatka, A., J. Mol. Biol. 43, 551 (1969). Eisenberg, E., Barouch, W.W., and Moos, C., Federation Proc. B, 536 (1969). Morita, F. and Shimizu, T., Biochim. Biophys. Acta 180, 545 (1969). W.F., Biochim. Biophys. Acta 4l, 401 (1960) Kielley, W.W. and Harrington, Eisenberg, E. and Moos, C., 3. Biol. Chem. 242, 2945 (1967). Adelstein, R., Godfrey, J.E. and Kielley, W.W., Biochem. Biophys. Res. Comm. l2, 34 (1963). Hartshorne, D.J. and Mueller, H., Biochim. Biophys. Acta 175, 301 (1969).
55
Vol. 40, No. 1, 1970
15. 16. 17. 18. 19.
BIOCHEMICAL
D.J. and Mueller, Hartshorne, 647 (1968). Kominz, D-R., Arch. Biochem. Martonosi, A., J. Biol. Chem. Teicholz, L.E. and Podolsky, Hill, D.R., J. Physiol. 199,
AND BIOPHYSICAL
H.,
Biochem.
RESEARCH COMMUNICATIONS
Biophys.
Res.
Comm. 31,
and Biophys. 115, 583 (1966). 237, 2795 (1962). R.J., Biophys. J. lo, 218a (1970). 637 (1968).
56