Published online before print May 10, 2001, doi: 10.1161/hh1001.091640
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© 2001 American Heart Association, Inc.
Integrative Physiology |
Phosphorylation of Troponin I by Protein Kinase A Accelerates Relaxation and Crossbridge Cycle Kinetics in Mouse Ventricular Muscle
From the Centre for Cardiovascular Biology and Medicine (J.C.K., D.T.McC., J.L., S.P.), King’s College London, St Thomas’ Campus, London, UK; Harvard School of Public Health (J.M.L.), Cardiovascular Biology Laboratory, Boston, Mass; Department of Physiology and Biophysics (A.F.M., R.J.S.), University of Illinois at Chicago, Chicago, Ill.
Correspondence to Jonathan C. Kentish, MA, PhD, Centre for Cardiovascular Biology & Medicine, King’s College London, The Rayne Institute, St. Thomas’ Hospital, London SE1 7EH UK. E-mail jon.kentish{at}kcl.ac.uk
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Abstract |
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Abstract—Phosphorylation of cardiac myofibrils by cAMP-dependent protein kinase (PKA) can increase the intrinsic rate of myofibrillar relaxation, which may contribute to the shortening of the cardiac twitch during ß-adrenoceptor stimulation. However, it is not known whether the acceleration of myofibrillar relaxation is due to phosphorylation of troponin I (TnI) or of myosin binding protein-C (MyBP-C). To distinguish between these possibilities, we used transgenic mice that overexpress the nonphosphorylatable, slow skeletal isoform of TnI in the myocardium and do not express the normal, phosphorylatable cardiac TnI. The intrinsic rate of relaxation of myofibrils from wild-type and transgenic mice was measured using flash photolysis of diazo-2 to rapidly decrease the [Ca2+] within skinned muscles from the mouse ventricles. Incubation with PKA nearly doubled the intrinsic rate of myofibrillar relaxation in muscles from wild-type mice (relaxation half-time fell from
150 to 90 ms at 22°C) but had no effect on
the relaxation rate of muscles from the transgenic mice. In parallel
studies with intact muscles, we assessed crossbridge kinetics
indirectly by determining
fmin
(the frequency for minimum dynamic stiffness) during tetanic
contractions. Stimulation of ß-adrenoceptors with isoproterenol
increased
fmin
from 1.9 to 3.1 Hz in muscles from wild-type mice but had no effect on
fmin in
muscles from transgenic mice. We conclude that the acceleration of
myofibrillar relaxation rate by PKA is due to
phosphorylation of TnI, rather than MyBP-C, and that
this may be due, at least in part, to faster crossbridge cycle
kinetics.
Key Words: protein kinase A • phosphorylation • relaxation • troponin I • myosin binding protein-C
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Introduction |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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Stimulation of ß1-adrenoceptors in the myocardium during sympathetic stimulation not only increases contractile force but also accelerates myocardial relaxation (positive lusitropy). This increase of relaxation rate is important for proper pump function, because it allows adequate time for diastolic filling of the ventricles despite the raised heart rate during sympathetic stimulation. The activation of ß1-adrenoceptors stimulates the cAMP/protein kinase A (PKA) pathway, and the faster relaxation of the myocardial cells is partly due to an enhanced reuptake of Ca2+ into the sarcoplasmic reticulum (SR) as a result of phosphorylation of phospholamban by PKA.1 In addition, PKA phosphorylates the cardiac myofibrils during ß-stimulation.2 3 4 This may lead to an acceleration of the intrinsic rate of myofibrillar relaxation, thereby contributing to the abbreviation of the twitch. Using flash photolysis of the caged chelator of Ca2+, diazo-2, to rapidly decrease Ca2+ concentration inside skinned fibers, Zhang et al5 reported that PKA accelerated relaxation in pig skinned muscles. However, a later study by Johns et al6 found no effect in similar experiments using guinea pig skinned muscles. Recent work with intact mouse muscles has suggested that ß-stimulation can produce an SR-independent, presumably myofibril-mediated, acceleration of relaxation that is seen in isometric but not isotonic contractions.4
Assuming that phosphorylation does increase the relaxation rate of cardiac myofibrils, how might this be produced? It is known that phosphorylation of troponin I (TnI) by PKA decreases myofibrillar Ca2+ sensitivity2 3 5 6 7 8 and increases the rate at which Ca2+ dissociates from TnC,9 which could lead to faster relaxation by increasing the rate of thin filament deactivation. Alternatively, there is some evidence that phosphorylation by PKA can directly accelerate some steps in the crossbridge cycle. For example, the maximum velocity of shortening in skinned cells or muscles was increased by PKA in some studies,3 10 11 although not in others.12 Under isometric conditions, myofibrillar ATPase activity was either increased11 or unchanged13 by PKA. More consistent results under near-isometric conditions have been obtained with perturbation analysis, which showed that the frequency of minimum dynamic stiffness of muscles (fmin) during sinusoidal length perturbations was increased during ß-stimulation.14 15 16 17 This increase in fmin is likely to reflect an acceleration of strain-dependent transitions in the crossbridge cycle. If the increase in crossbridge kinetics were related to a faster rate of crossbridge detachment, it would produce a faster relaxation of the myofibrils. However, it is still not clear whether the positive lusitropic effect of phosphorylation is due to a direct action on the rate of Ca2+ loss from TnC or on the rate of crossbridge detachment during relaxation.
Another uncertainty is that we do not know which myofibrillar protein mediates the effect of PKA on relaxation rate. As stated above, PKA phosphorylates TnI and increases the rate of Ca2+ loss from TnC. In addition, PKA phosphorylates the N-terminal motif of the thick-filament protein myosin binding protein-C (MyBP-C).2 3 4 8 18 19 20 21 This may abolish a restraining influence of MyBP-C on the flexibility of the myosin head.21 Consistent with this, electron microscopy of isolated thick filaments has shown that phosphorylation of MyBP-C causes the crossbridges to move away from the thick-filament backbone.18 This action may increase the rates of crossbridge attachment and detachment from actin, thereby accelerating relaxation.19 Because both TnI and MyBP-C are phosphorylated concurrently by PKA, it has so far proved impossible to establish the relative roles of phosphorylation of TnI and MyBP-C in the acceleration of myofibrillar relaxation. In the present study, we resolved this difficulty by using transgenic mice in which the normal cardiac form of TnI (cTnI) is replaced by the slow skeletal form of TnI (ssTnI).3 ssTnI, which is normally expressed in the heart only during fetal and early postnatal life, lacks an N-terminal sequence of 32 to 33 amino acids compared with cTnI. In cTnI, this N-terminal sequence contains the two serine residues (23 and 24 in the mouse) that can be phosphorylated by PKA. Thus, MyBP-C is the only phosphorylatable target for PKA in ssTnI transgenic mice. The aims of this study were (1) to establish whether phosphorylation accelerates the intrinsic relaxation rate of wild-type mouse myofibrils; (2) if so, to use the transgenic mice to determine whether the effect is due to phosphorylation of TnI or of MyBP-C; and (3) to see whether differential effects of phosphorylation on relaxation of wild-type and transgenic mouse myofibrils are associated with differences in crossbridge cycle kinetics under near-isometric conditions, as assessed by measurement of fmin.
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Materials and Methods |
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Briefly, heterozygous ssTnI transgenic (TG) mice were produced from CD-1 mice by inserting a vector containing the mouse ssTnI transgene under the control of the cardiac-specific
-myosin
heavy chain promoter.3
Genotyping (using specific PCR primers) and phenotyping (using SDS-PAGE
of isolated myofibrils) were done only after the experiments so that
the experimenter did not know which type of mouse was being used. The
results were the same using either wild-type (WT) CD-1 mice or
nontransgenic littermates of transgenic mice, so we pooled the results
from these two groups. For skinned-muscle experiments, mice (30 to 40 g) were killed by cervical dislocation in accordance with UK Home Office guidelines (section 1). Suitable papillary muscles or trabeculae (diameters: WT, 136±12 µm, n=6; TG, 129±10 µm, n=5) from the right ventricles were skinned with 1% Triton X-100 and attached to a force transducer.22 For rapid-relaxation experiments, the photolysis solution contained 0.25 mol/L diazo-2 and varied [Ca2+] to produce forces of 40% to 80% of maximum force. When force had stabilized, a xenon flashlamp focused on the muscle was triggered to photolyze diazo-2. Results shown are those in which muscles relaxed to 0% to 15% of maximum force. Initially, relaxation trajectories were assessed by calculation of the RT50 (time taken for force to fall by 50% over the 10-second recording period). Subsequently, further analysis was carried out by fitting the relaxation to a double-exponential decay: force at time (t)=axe–k1xt+bxe–k2xt+c. This was done to assess which of the two exponential components of the relaxation trajectory contributed to the observed changes in RT50. Phosphorylation was carried out by incubating the muscles with 500 U mL-1 PKA (porcine catalytic subunit, Sigma)5 in relaxing solution for 30 minutes at 22°C.
For the intact-muscle experiments, muscles were mounted
between a servomotor and a force transducer in a flow-through bath and
superfused with Krebs solution (1 mmol/L
Ca2+, 24°C). Fused tetani were produced by
stimulating the muscles at 10 Hz in 1 µmol/L ryanodine and 30
µmol/L cyclopiazonic acid (to inhibit the SR) plus
12 mmol/L Ca2+ and 1 µmol/L BAY-K
8644 (to increase Ca2+ influx). During the
tetanus, muscle-length oscillations of 0.6% peak-peak
were applied, and the dynamic stiffness was calculated from the
resulting force excursions.
All data are expressed as mean±SEM. Differences were analyzed using Student’s paired or unpaired t tests, as appropriate, with P<0.05 being regarded as statistically significant.
An expanded Materials and Methods section can be found in an online data supplement available at http://www.circresaha.org.
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Results |
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Effects of Phosphorylation on Myofibrillar Ca2+ Sensitivity
Western blot analysis has shown that overexpression of ssTnI in the adult mouse heart leads to a lack of expression of the cTnI gene.3 This was verified in the present study by the absence of cTnI in SDS gels from the TG mice (Figure 1A
). The ssTnI band is not visible in the gel of TG
myofibrils because ssTnI comigrates with myosin light chain-1. The lack
of phosphorylatable TnI in myofibrils from TG mice was further
demonstrated by autoradiograms of myofibrils after
incubation with PKA and 32P-ATP
(Figure 1B): both TnI and MyBP-C were
phosphorylated in myofibrils from WT mice, whereas only
MyBP-C was phosphorylated in myofibrils from TG mice.
Western blot analysis has shown that ssTnI completely replaces
cTnI.3 This was confirmed in
the present study by the fact that the maximum
Ca2+ activated force of skinned
muscles from TG mice (16.0±0.6 mN ·
mm-2) was the same as in muscles from WT
mice (15.8±0.8 mN · mm-2). The
only difference in the steady-state properties was that skinned muscles
from TG mice had a higher Ca2+ sensitivity
than WT muscles under control conditions
(Figure 2). The [Ca2+] required
for 50% activation
([Ca2+]50) was
0.74±0.11 µmol/L (n=5) in TG myofibrils compared with 1.52±0.12
µmol/L (n=6) for WT myofibrils, corresponding to a difference of 0.31
pCa units
(P<0.05).
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, before PKA; 
and 
, after PKA. Force is expressed relative to the maximum force before PKA. Lines are least-squares fits to the Hill equation. Data are mean±SEM; n=6 (WT) and n=5 (TG).
As shown in
Figure 2A
, phosphorylation of the WT
Triton-skinned muscles with PKA increased the
[Ca2+]50 to
2.15±0.19 µmol/L (n=6), which corresponds to a decrease in
Ca2+ sensitivity of 0.15±0.02 pCa units
(P<0.001, paired
t test). In contrast,
incubation of the TG muscles in PKA did not alter the
Ca2+ sensitivity
(Figure 2B): the
[Ca2+]50 rose only
to 0.86±0.07 µmol/L (n=5), a change in pCa50
of 0.05±0.03 pCa units. This shift was not significantly different
from zero and was exactly the same as in time-matched controls
incubated without PKA (0.05±0.03, n=4). The lack of change in the
Ca2+ sensitivity of myofibrils in TG
muscles, despite the phosphorylation of MyBP-C under
these conditions
(Figure 1B), confirms previous
work3 and demonstrates that
the fall in Ca2+ sensitivity in WT mice
results from phosphorylation of cTnI rather than of
MyBP-C. In neither type of mouse muscles was the maximum
Ca2+-activated force altered
significantly by incubation with PKA
(Figure 2).
Effects of Phosphorylation on
Myofibrillar Relaxation Rate
Rapid relaxation of skinned muscles during activation
by Ca2+
(Figure 3) was produced by flash photolysis of diazo-2, a
"caged" chelator of Ca2+ that exhibits a
near-instantaneous increase in Ca2+ affinity
after photolysis with a flash of near-UV
light.23 This causes the
[Ca2+] surrounding the myofilaments to be
reduced rapidly (in 1 ms) so that the rate of the ensuing relaxation
is limited only by the properties of the myofibrils. In skinned muscles
from WT mice, incubation with PKA had a large effect on relaxation rate
(Figure 3B). After PKA, relaxation was accelerated
dramatically, with the half-time for relaxation
(RT50) falling by 41% from 152±29 to 90±16 ms
(Figure 3C). This increase of relaxation rate was almost
entirely due to a change in the slower rate constant
(k2) of the biexponential relaxation trajectory:
k2 rose by 82% from 4.06±0.33 to 7.40±1.3
s-1 (n=8). The faster rate constant
(k1) rose slightly from 35.7±3.1
s-1 to 44.4±6.3
s-1, but this change was not statistically
significant. The amplitudes of the two exponential components or of the
final force level (a,
b, and
c in Materials and Methods)
were not altered significantly (results not shown).
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Under control conditions, skinned muscles from the TG mice
(Figure 4) had a faster rate of relaxation than WT mice
(RT50 of 70±6 ms, n=9;
P<0.05 versus WT). This was
due to a greater value for k1 (44±4 versus
36±3 s-1 in WT mice;
P<0.05), because
k2 (4.0±1.0 s-1,
n=9) was the same as in the WT muscles. (However, it should be noted
that the initial conditions were different for the two types of muscle,
in that the higher [Ca2+] sensitivity of
TG muscles required that the preflash
[Ca2+] of the diazo-2 solution was lower
than with the WT muscles, to give the same initial level of activation
in the two muscle types). It is clear that, in contrast to the WT
muscles, the TG muscles exhibited no change in the rate of myofibrillar
relaxation after incubation in PKA, with no significant alteration in
RT50 or the relaxation rate constants
(Figure 4) or in the amplitudes of the exponential components
(not shown). Thus, the lack of phosphorylation of TnI
in the TG myofibrils
(Figure 1B) is associated with a lack of effect of PKA on the
myofibrillar relaxation rate.
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Effects of Phosphorylation on
fmin
There is evidence that the intrinsic rate of relaxation
of cardiac myofibrils may be governed by the kinetics of the
crossbridge cycle rather than by the rate at which
Ca2+ is lost from
TnC.22 24 We
therefore examined whether the differential effects of
phosphorylation on the relaxation dynamics of WT and TG
mice were reflected in differential effects on crossbridge kinetics.
This was done under near-isometric conditions (as in the relaxation
experiments) by measuring the oscillation frequency
(fmin)
that produced minimum dynamic stiffness during small sinusoidal length
perturbations in tetanized muscles
(Figure 5A). Intact muscles were used because it was
difficult to obtain clear stiffness minima in skinned muscles; an added
advantage was that intact muscle contains the functional
ß-adrenoceptor pathway. In the WT muscle illustrated in
Figure 5B, fmin was
2 Hz under control conditions. Isoproterenol was subsequently applied
at a concentration (5 µmol/L) that gave a maximal increase of the
isometric twitch in the absence of SR blockers (results not shown).
This stimulation of ß-adrenoceptors caused
fmin to
increase to 3 Hz in the muscle shown. In 17 WT muscles, isoproterenol
increased
fmin by
63% from 1.91±0.17 Hz to 3.12±0.22 Hz
(Figure 5C). This suggests that ß-adrenoceptor stimulation
accelerates crossbridge kinetics in mouse heart muscle. The apparent
effects of isoproterenol on the maximum amplitude of dynamic stiffness
in
Figure 5B were not typical of other muscles. Isoproterenol
had no significant effects on the magnitudes of isometric tetanic
stress
(Figure 5D), as seen
previously,25 or of dynamic
stiffness
(Figure 5E; stiffness measured at 10 Hz, the highest
oscillation frequency used in these
experiments).
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The basal level of TnI phosphorylation under
control conditions is undetectable in TG
myocytes3 but is 10% to 20%
of maximum in WT myocytes (see online date supplement for details).
Given that phosphorylation increased
fmin in
WT mice, we might therefore expect that
fmin
under control conditions would be smaller in TG muscles than in WT
muscles. In fact,
fmin in
the TG muscles (1.75±0.16 Hz, n=8,
Figure 5C) was lower than in WT mice, but the difference was
not statistically significant. The isometric tetanic stress and the
stiffness at 10 Hz were also similar to those in WT mice
(Figures 5D and 5E). However, a major difference between the
two types of mice was apparent with the effects of isoproterenol on
fmin. In
the example TG muscle shown
(Figure 5B), the addition of isoproterenol in fact decreased
fmin,
although on average in the TG muscles,
fmin was
not altered significantly
(Figure 5C). This was not due to a general lack of
responsiveness to ß-adrenoceptor stimulation, because the twitch
amplitude was still increased by isoproterenol (not shown). These
results indicate that activation of PKA speeds crossbridge kinetics in
WT but not in TG mice. This suggests that the faster crossbridge
kinetics are associated with phosphorylation of TnI
rather than of MyBP-C.
Recently, it was reported that
phosphorylation of the cardiac MyBP-C motif,
incorporated into skinned skeletal fibers, increased maximum force
production without altering muscle stiffness (a measure of the
number of attached
crossbridges).26 However,
although we also found no effect of ß-adrenoceptor stimulation on the
dynamic stiffness of TG muscles (measured at 10 Hz,
Figure 5E), we did not see any change in the tetanic force
of TG muscles during ß-stimulation
(Figure 5D).
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Discussion |
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Phosphorylation Effects in WT Mice
It is well established that PKA phosphorylates cardiac myofibrils, both in isolated myofibrils and in intact cells during ß-adrenoceptor stimulation.2 3 4 5 6 7 8 9 10 11 12 13 18 19 20 21 26 However, it is less clear whether this action is beneficial for cardiac function. The resulting decrease in myofibrillar Ca2+ sensitivity, which is now known to be due to phosphorylation of TnI,2 3 8 appears counterproductive, because it would tend to offset the positive inotropic action resulting from the enhanced [Ca2+]i transient during ß-adrenoceptor stimulation.1 A beneficial effect would however result if phosphorylation acted to increase the intrinsic rate of myofibrillar relaxation. Previous work, using flash photolysis of pig or guinea pig skinned cardiac muscles in air at
12°C, has produced contradictory results, that
phosphorylation by PKA
does5 or does
not6 increase the
myofibrillar relaxation rate. Our results, using skinned muscles in
solution at 22°C, show that phosphorylation does
increase the intrinsic relaxation rate of mouse cardiac myofibrils
(Figure 3). It remains to be determined whether these
divergent results from diazo-2 experiments are due to differences in
species or in methodology. The faster relaxation resulting from
phosphorylation of the myofibrils is likely to
contribute to the beneficial effect of twitch abbreviation during
ß1-adrenoceptor stimulation, although the
magnitude of the contribution by the myofibrils, relative to the SR,
may depend on the load placed on the
muscle.4
It is difficult to say precisely how
phosphorylation accelerates myofibrillar relaxation,
because the factors that determine relaxation rate are poorly
understood. Relaxation is a complex process, involving
Ca2+ removal from TnC, thin-filament
deactivation, crossbridge dissociation, and loss of cooperativity in
the thin filament, particularly the activating effect of strongly bound
crossbridges (for review, see Gordon et
al24 ). In addition, even in
muscles held isometric, there is likely to be some internal shortening
of the muscle during activation and a corresponding internal
relengthening (ie, sarcomere relengthening) during relaxation; this
will influence the rate of decay of force. All these processes may
occur simultaneously, so it is difficult to define their
individual contributions to the relaxation process, let alone to state
how phosphorylation accelerates relaxation. However, it
is likely that the faster relaxation after
phosphorylation
(Figure 3) does not result directly from the faster loss of
Ca2+ from
TnC,9 because even before
phosphorylation, the loss of
[Ca2+] is probably too rapid to limit
relaxation.22 24
Further support for this view is given by the results from the TG
muscles. These muscles had an enhanced Ca2+
sensitivity compared with WT mice, which if anything should reflect a
slower dissociation of Ca2+ from TnC.
However, the TG mice showed a faster, not slower, relaxation compared
with the WT mice.
We and others have provided evidence that the kinetics of
the crossbridge cycle may be a major determinant of the intrinsic rate
of myofibrillar
relaxation.22 24
Consistent with this, the present results suggest that the
faster relaxation caused by phosphorylation of
myofibrils in the WT skinned muscles is associated with faster
crossbridge kinetics, as assessed by measurements of
fmin in
intact muscles
(Figure 5C). During the maintained tetanus, thin-filament
activation and cooperative mechanisms should be constant, so the
increase in
fmin
will reflect a true acceleration of the underlying crossbridge
kinetics, unrelated to activation effects. Although in the past
fmin has
been regarded as a measure of crossbridge cycling rate, it is more
likely to be a composite, indirect measure of the forward and backward
transitions between zero-force (detached and weakly bound) and
force-generating (strongly bound) crossbridge
states.27 (The overall
crossbridge cycling rate can be determined from measurements of
myofibrillar ATPase activity, but this has produced divergent results,
with an increase11 or no
change13 after
phosphorylation with PKA). The present results
indicate that
fmin,
and therefore crossbridge kinetics, are increased in intact mouse
muscles during ß-stimulation, as has been found in the hearts of
other mammalian
species.14 15 16 17
At present, we cannot be sure of the relationship (if any) between
fmin and
the biexponential relaxation trajectory typically seen in diazo-2
experiments
(Figures 3 and 4).6 22
However, a commonality between
fmin and
the slower rate constant (k2) of relaxation is
suggested by the finding that both
fmin and
k2 showed no difference between WT and TG
muscles and that in WT mice both
fmin and
k2 were increased (by 60% to 80%) by
phosphorylation with PKA. In contrast,
k1 was greater in TG than in WT mice and was not
altered by phosphorylation. One possible explanation
for our results is that both
fmin and
k2 are influenced by the rate of forward
detachment of crossbridges and that phosphorylation
enhances this detachment rate. An alteration in the strain dependency
of crossbridge transitions13
might cause these increases in
fmin and
k2 without necessarily altering the isometric
ATPase activity. The idea that an acceleration of crossbridge kinetics
may be responsible for the increases in
fmin and
relaxation rate is supported by the finding that these increases were
both due to phosphorylation of TnI by PKA (see below).
Whether there is an additional contribution from accelerated kinetics
of thin-filament deactivation or of other cooperative mechanisms
remains to be determined.
Phosphorylation Effects in TG
Mice
A major aim of the present study was to use TG mice
that overexpressed nonphosphorylatable ssTnI to elucidate the relative
roles of phosphorylation of TnI and MyBP-C to the
positive lusitropic effects of PKA. Fortunately for our purposes, the
overexpression of ssTnI results in a lack of expression of the normal
cTnI, as shown by Western
blots3 and SDS-PAGE gels of
myofibrils
(Figure 1). Thus, in the TG myofibrils only MyBP-C is
phosphorylated by PKA
(Figure 1B). Similarly, in intact myocytes from TG mouse
hearts, ß-adrenoceptor stimulation leads to
phosphorylation of MyBP-C but not
TnI.3
Under control conditions, the muscles from TG mice were
different in two respects from WT mouse muscles. First, as seen
previously,3 28 29
TG muscles expressing ssTnI had a higher
Ca2+ sensitivity than WT muscles
(Figure 2). This illustrates that the isoform of TnI is a
major determinant of Ca2+ sensitivity and
helps to explain why neonatal myofibrils, which express ssTnI rather
than cTnI, have a higher Ca2+ sensitivity
than adult myofibrils.30 The
second difference was that the relaxation rate of TG muscles
(Figure 4) was faster than that of the WT muscles
(Figure 3). This unexpected finding could indicate that the
isoform of TnI also determines the dynamics of myofibrillar relaxation.
However, the conditions were different for the two types of muscle, in
that preflash [Ca2+] was lower for the TG
muscles, to achieve the same initial level of activation. Further
studies will be required to establish if the disparity in relaxation
rates between WT and TG mice is due to true differences in myofibrillar
properties or merely to differences in preflash
[Ca2+]. One potential problem is that the
elevated relaxation rate of the TG myofibrils under control conditions
could have masked any potential acceleration of relaxation from the
subsequent phosphorylation of MyBP-C. We think this is
unlikely because the faster relaxation of TG myofibrils was in fact due
to a higher value for rate constant k1; the
value of k2, which was the rate constant
increased by phosphorylation in WT mice, was no greater
in TG myofibrils than in WT myofibrils under control conditions (4
s-1,
Figures 3 and 4), and so should not have been
limiting.
At first sight, the faster relaxation of skinned muscles from TG mice is surprising, given that in intact cells and hearts of TG mice relaxation is slower than in WT mice, leading to diastolic dysfunction in vivo.3 One reason for this difference is that the Ca2+ transient decays more slowly in TG myocytes than in WT myocytes,3 for unknown reasons. This, coupled with the higher Ca2+ sensitivity of TG myofibrils, makes it likely that the rate of relaxation in intact TG myocytes is determined only by the slow fall of [Ca2+], rather than by the faster intrinsic relaxation rate of the myofibrils.
A major finding in the present work was that the PKA-induced phosphorylation of both TnI and MyBP-C in skinned muscles from WT mice increased myofibrillar relaxation rate substantially, but that phosphorylation of MyBP-C alone in the TG muscles had no effect on relaxation. Similarly, in the intact muscles ß-stimulation increased fmin in the muscles from WT mice but not in those from TG mice. Thus, the increases in both relaxation rate and fmin are likely to be due to phosphorylation of TnI rather than of MyBP-C. As discussed above, the faster crossbridge kinetics shown by the fmin measurements may be responsible, at least in part, for the increase in relaxation speed of the myofibrils.
Nevertheless, other studies have suggested that
phosphorylation of MyBP-C may influence the contractile
properties of cardiac muscle. Kunst et
al26 diffused the
phosphorylatable motif of cardiac MyBP-C into skinned skeletal fibers
and showed that force and force per attached crossbridge were higher,
and myofibrillar Ca2+ sensitivity lower, if
the motif was phosphorylated. In contrast, Calaghan et
al31 obtained indirect
evidence that phosphorylation of MyBP-C, mimicked by
introduction of myosin S2 into intact cardiomyocytes (to
reduce the endogenous interaction between MyBP-C and myosin
S2), increased myofibrillar Ca2+
sensitivity. Our results indicate that phosphorylation
of MyBP-C alone (in the TG muscles) does not alter the maximum force or
Ca2+ sensitivity of skinned muscles
(Figure 2B)2 3 8
nor the tetanic force or stiffness of intact muscles
(Figure 5D). Clearly, more work is needed to resolve these
discrepancies and to elucidate the functional consequences of MyBP-C
phosphorylation. Because MyBP-C
phosphorylation has been reported to increase the
flexibility or extension of myosin
crossbridges,18 19 21
there may be other effects of MyBP-C phosphorylation
that were not uncovered by the experiments reported in the present
study. Our experiments do not, for example, rule out a potential
permissive effect, in which phosphorylation of MyBP-C
is necessary for the effects of TnI phosphorylation to
be seen.
In summary, by using transgenic mice that lack phosphorylatable TnI in the adult myocardium, we have established that it is phosphorylation of TnI, rather than of MyBP-C, that is responsible for an increase in the intrinsic relaxation rate of cardiac myofibrils. This may be due, at least in part, to an acceleration of crossbridge cycle kinetics. The acceleration of myofibrillar relaxation induced by PKA is likely to contribute to the faster relaxation of the myocardium during ß-adrenoceptor stimulation.
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Acknowledgments |
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This work was supported by grants to J.K. from the British Heart Foundation , the Central Research Fund of London University, and the Charitable Foundation for Guy’s and St Thomas’ Hospital, and by NHLBI Grants R 37 HL 22231 and PO1 HL 62426 (Project 1) (to R.J.S.). We are grateful to Emma Pollock and Robert Haworth for help with the gels.
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Footnotes |
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Original received November 30, 2000; resubmission received March 30, 2001; revised resubmission received April 18, 2001; accepted April 18, 2001.
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References |
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 X.-J. Du, T. J. Cole, N. Tenis, X.-M. Gao, F. Kontgen, B. E. Kemp, and J. Heierhorst Impaired Cardiac Contractility Response to Hemodynamic Stress in S100A1-Deficient Mice Mol. Cell. Biol., April 15, 2002; 22(8): 2821 - 2829. [Abstract] [Full Text] [PDF]
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Y. Pi, K. R. Kemnitz, D. Zhang, E. G. Kranias, and J. W. Walker Phosphorylation of Troponin I Controls Cardiac Twitch Dynamics: Evidence From Phosphorylation Site Mutants Expressed on a Troponin I-Null Background in Mice Circ. Res., April 5, 2002; 90(6): 649 - 656. [Abstract] [Full Text] [PDF]
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G. Chu, A. N. Carr, K. B. Young, J.W. Lester, A. Yatani, A. Sanbe, M. C. Colbert, S. M. Schwartz, K. F. Frank, P. D. Lampe, et al. Enhanced myocyte contractility and Ca2+ handling in a calcineurin transgenic model of heart failure Cardiovasc Res, April 1, 2002; 54(1): 105 - 116. [Abstract] [Full Text] [PDF]
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S. P. Harris, C. R. Bartley, T. A. Hacker, K. S. McDonald, P. S. Douglas, M. L. Greaser, P. A. Powers, and R. L. Moss Hypertrophic Cardiomyopathy in Cardiac Myosin Binding Protein-C Knockout Mice Circ. Res., March 22, 2002; 90(5): 594 - 601. [Abstract] [Full Text] [PDF]
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D. E Montgomery, J. C Tardiff, and M. Chandra Cardiac troponin T mutations: correlation between the type of mutation and the nature of myofilament dysfunction in transgenic mice J. Physiol., October 15, 2001; 536(2): 583 - 592. [Abstract] [Full Text] [PDF]
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T. J. Herron, F. S. Korte, and K. S. McDonald Power Output Is Increased After Phosphorylation of Myofibrillar Proteins in Rat Skinned Cardiac Myocytes Circ. Res., December 7, 2001; 89(12): 1184 - 1190. [Abstract] [Full Text] [PDF]
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S. P. Harris, C. R. Bartley, T. A. Hacker, K. S. McDonald, P. S. Douglas, M. L. Greaser, P. A. Powers, and R. L. Moss Hypertrophic Cardiomyopathy in Cardiac Myosin Binding Protein-C Knockout Mice Circ. Res., March 22, 2002; 90(5): 594 - 601. [Abstract] [Full Text] [PDF]
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Y. Pi, K. R. Kemnitz, D. Zhang, E. G. Kranias, and J. W. Walker Phosphorylation of Troponin I Controls Cardiac Twitch Dynamics: Evidence From Phosphorylation Site Mutants Expressed on a Troponin I-Null Background in Mice Circ. Res., April 5, 2002; 90(6): 649 - 656. [Abstract] [Full Text] [PDF]
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B. M. Wolska, G. M. Arteaga, J. R. Pena, G. Nowak, R. M. Phillips, S. Sahai, P. P. de Tombe, A. F. Martin, E. G. Kranias, and R. J. Solaro Expression of Slow Skeletal Troponin I in Hearts of Phospholamban Knockout Mice Alters the Relaxant Effect of {beta}-Adrenergic Stimulation Circ. Res., May 3, 2002; 90(8): 882 - 888. [Abstract] [Full Text] [PDF]
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