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- Isometric force redevelopment of skinned muscle fibers from ...Isometric force redevelopment of skinned muscle fibers from rabbit activated with and without Ca2+
Biophysical Journal, Volume 67, Issue 5, 1 November 1994, Pages 1994-2001
P.B. Chase, D.A. Martyn and J.D. Hannon
AbstractFiber isometric tension redevelopment rate (kTR) was measured during submaximal and maximal activations in glycerinated fibers from rabbit psoas muscle. In fibers either containing endogenous skeletal troponin C (sTnC) or reconstituted with either purified cardiac troponin C (cTnC) or sTnC, graded activation was achieved by varying [Ca2+]. Some fibers were first partially, then fully, reconstituted with a modified form of cTnC (aTnC) that enables active force generation and shortening in the absence of Ca2+. kTR was derived from the half-time of tension redevelopment. In control fibers with endogenous sTnC, kTR increased nonlinearly with [Ca2+], and maximal kTR was 15.3 +/- 3.6 s-1 (mean +/- SD; n = 26 determinations on 25 fibers) at pCa 4.0. During submaximal activations by Ca2+, kTR in cTnC reconstituted fibers was approximately threefold faster than control, despite the lower (60%) maximum Ca(2+)-activated force after reconstitution. To obtain submaximal force with aTnC, eight fibers were treated to fully extract endogenous sTnC, then reconstituted with a mixture of a TnC and cTnC (aTnC:cTnC molar ratio 1:8.5). A second extraction selectively removed cTnC. In such fibers containing aTnC only, neither force nor kTR was affected by changes in [Ca2+]. Force was 22 +/- 7% of maximum control (mean +/- SD; n = 15) at pCa 9.2 vs. 24 +/- 8% (mean +/- SD; n = 8) at pCa 4.0, whereas kTR was 98 +/- 14% of maximum control (mean +/- SD; n = 15) at pCa 9.2 vs. 96 +/- 15% (mean +/- SD; n = 8) at pCa 4.0.(ABSTRACT TRUNCATED AT 250 WORDS)
Abstract | PDF (886 kb) - Influence of Length on Force and Activation-Dependent Change...Influence of Length on Force and Activation-Dependent Changes in Troponin C Structure in Skinned Cardiac and Fast Skeletal Muscle
Biophysical Journal, Volume 80, Issue 6, 1 June 2001, Pages 2798-2808
Donald A. Martyn and A.M. Gordon
AbstractLinear dichroism of 5′ tetramethyl-rhodamine (5′ATR) was measured to monitor the effect of sarcomere length (SL) on troponin C (TnC) structure during Ca activation in single glycerinated rabbit psoas fibers and skinned right ventricular trabeculae from rats. Endogenous TnC was extracted, and the preparations were reconstituted with TnC fluorescently labeled with 5′ATR. In skinned psoas fibers reconstituted with sTnC labeled at Cys 98 with 5′ATR, dichroism was maximal during relaxation (pCa 9.2) and was minimal at pCa 4.0. In skinned cardiac trabeculae reconstituted with a mono-cysteine mutant cTnC (cTnC(C84)), dichroism of the 5′ATR probe attached to Cys 84 increased during Ca activation of force. Force and dichroism-[Ca] relations were fit with the Hill equation to determine the pCa and slope (). Increasing SL increased the Ca sensitivity of force in both skinned psoas fibers and trabeculae. However, in skinned psoas fibers, neither SL changes or force inhibition had an effect on the Ca sensitivity of dichroism. In contrast, increasing SL increased the Ca sensitivity of both force and dichroism in skinned trabeculae. Furthermore, inhibition of force caused decreased Ca sensitivity of dichroism, decreased dichroism at saturating [Ca], and loss of the influence of SL in cardiac muscle. The data indicate that in skeletal fibers SL-dependent shifts in the Ca sensitivity of force are not caused by corresponding changes in Ca binding to TnC and that strong cross-bridge binding has little effect on TnC structure at any SL or level of activation. On the other hand, in cardiac muscle, both force and activation-dependent changes in cTnC structure were influenced by SL. Additionally, the effect of SL on cardiac muscle activation was itself dependent on active, cycling cross-bridges.
Abstract | Full Text | PDF (217 kb) - Cardiac Length Dependence of Force and Force Redevelopment K...Cardiac Length Dependence of Force and Force Redevelopment Kinetics with Altered Cross-Bridge Cycling
Biophysical Journal, Volume 87, Issue 3, 1 September 2004, Pages 1784-1794
Bishow B. Adhikari, Michael Regnier, Anthony J. Rivera, Kareen L. Kreutziger and Donald A. Martyn
AbstractWe examined the influence of cross-bridge cycling kinetics on the length dependence of steady-state force and the rate of force redevelopment () during Ca-activation at sarcomere lengths (SL) of 2.0 and 2.3m in skinned rat cardiac trabeculae. Cross-bridge kinetics were altered by either replacing ATP with 2-deoxy-ATP (dATP) or by reducing [ATP]. At each SL dATP increased maximal force () and Ca-sensitivity of force (pCa) and reduced the cooperativity () of force-pCa relations, whereas reducing [ATP] to 0.5mM (low ATP) increased pCa and without changing . The difference in pCa between SL 2.0 and 2.3m (ΔpCa) was comparable between ATP and dATP, but reduced with low ATP. Maximal was elevated by dATP and reduced by low ATP. Ca-sensivity of increased with both dATP and low ATP and was unaffected by altered SL under all conditions. Significantly, at equivalent levels of submaximal force was faster at short SL or increased lattice spacing. These data demonstrate that the SL dependence of force depends on cross-bridge kinetics and that the increase of force upon SL extension occurs without increasing the rate of transitions between nonforce and force-generating cross-bridge states, suggesting SL or lattice spacing may modulate preforce cross-bridge transitions.
Abstract | Full Text | PDF (252 kb) - …more
Copyright © 2006 The Biophysical Society. All rights reserved.
Biophysical Journal, Volume 90, Issue 8, 2867-2876, 15 April 2006
doi:10.1529/biophysj.105.076950
Muscles and Contractility
Troponin T Modulates Sarcomere Length-Dependent Recruitment of Cross-Bridges in Cardiac Muscle
Murali Chandra
, 
, Matthew L. Tschirgi, Indika Rajapakse and Kenneth B. Campbell
Address reprint requests to Murali Chandra, Dept. of VCAPP, 205 Wegner Hall, Washington State University, Pullman, WA 99164-6520. Tel.: 509-335-7561; Fax: 509-335-4650.Abstract
The heterogenic nature of troponin T (TnT) isoforms in fast skeletal and cardiac muscle suggests important functional differences. Dynamic features of rat cardiac TnT (cTnT) and rat fast skeletal TnT (fsTnT) reconstituted cardiac muscle preparations were captured by fitting the force response of small amplitude (0.5%) muscle length changes to the recruitment-distortion model. The recruitment of force-bearing cross-bridges (XBs) by increases in muscle length was favored by cTnT. The recruitment magnitude was ∼1.5 times greater for cTnT- than for fsTnT-reconstituted muscle fibers. The speed of length-mediated XB recruitment (b) in cTnT-reconstituted muscle fiber was 0.50–0.57 times as fast as fsTnT-reconstituted muscle fibers (3.05 vs. 5.32s−1 at sarcomere length, SL, of 1.9μm and 4.16 vs. 8.36s−1 at SL of 2.2μm). Due to slowing of b in cTnT-reconstituted muscle fibers, the frequency of minimum stiffness (fmin) was shifted to lower frequencies of muscle length changes (at SL of 1.9μm, 0.64Hz, and 1.16Hz for cTnT- and fsTnT-reconstituted muscle fibers, respectively; at SL of 2.2μm, 0.79Hz, and 1.11Hz for cTnT- and fsTnT-reconstituted muscle fibers, respectively). Our model simulation of the data implicates TnT as a participant in the process by which SL- and XB-regulatory unit cooperative interactions activate thin filaments. Our data suggest that the amino-acid sequence differences in cTnT may confer a heart-specific regulatory role. cTnT may participate in tuning the heart muscle by decreasing the speed of XB recruitment so that the heart beats at a rate commensurate with fmin.Introduction
Troponin T (TnT) is essential for the Ca2+-regulated acto-myosin interactions that generate force in striated muscle 1,2. TnT not only bridges between the Ca2+ receptor, troponin C (TnC), and force-bearing cross-bridges (XBs) but also regulates XBs 3,4 by virtue of its unique interaction with tropomyosin (Tm) and other thin-filament regulatory proteins. There are major amino-acid sequence differences between cardiac TnT (cTnT) and fast skeletal muscle TnT (fsTnT) 5, many of which are in regions that are important for establishing the size of the regulated functional unit (Tm1-Tn1-actin7) in the thin filament 6, for modulating kinetic rates of transition between on- and off-states of Tm-Tn 7, and for regulating the rate of XB binding to actin 6. These observations suggest an important heart-specific functional role for cTnT in Ca2+ activation of thin filaments and force generation in cardiac muscle.
In addition to Ca2+ activation of thin filaments, changes in sarcomere length (SL) also regulate force in both cardiac and skeletal muscle through length-dependent activation. A greater effect of length-dependent activation in cardiac muscle compared to fast skeletal muscle has been linked to special features of cardiac thin filaments 1,8. Although various mechanisms have been proposed for length-dependent activation 9,10,11,12, the molecular mechanism by which increased SL recruits more XBs in cardiac muscle is not well understood. Previous studies have shown that cardiac troponin I (cTnI) 11 and cTnT 13 may be involved in length-dependent activation of cardiac myofilaments, possibly related to the pivotal role cTnT plays in bridging cTnI and cTnC to the Tm-actin filament.
The dual role of TnT in thin-filament activation by Ca2+ and changes in SL may be expressed in one or more of three myofilament kinetic steps:
1. Ca2+ binding to the thin-filament regulatory unit (Tm-Tn).
2. Regulatory unit (RU) switching between on- and off-states.
3. XB cycling between attached and detached states.
2. Regulatory unit (RU) switching between on- and off-states.
3. XB cycling between attached and detached states.
Because of the interactions of thin-filament kinetics with both Ca2+ binding kinetics and XB cycling kinetics, a RU-induced effect on thin-filament kinetics propagates to affect the other kinetic steps 14,15,16. Changes in RU composition, as occurs with different TnT isoforms, will affect the dynamics of XB recruitment from both Ca2+ activation and SL changes. In cardiac muscle, a cTnT effect on the rate of RU on-/off-transitions could occur either through a direct cTnT-induced effect on Tm-Tm overlapping ends or through direct or indirect effects of cTnT on the actin filament. Furthermore, XBs themselves affect the balance between RU on- and off-states through cooperative activation. This suggests that some aspect of RU-related cooperativity modulates the recruitment of XBs and, therefore, length-dependent activation. We believe that such RU-related mechanisms are likely to be different in cardiac muscle than in fast skeletal muscle, due in part to differences in the primary structure of cTnT.
Accordingly, in this study, we tested the hypothesis that cTnT plays a role in the process by which SL and XB-RU interactions activate cardiac thin filaments. To better determine the effect of specific alterations of cTnT on muscle mechanodynamics, we have used a new mathematical model of myofilament mechanodynamics 14,15,16. Our data fit well with a model in which cTnT is important for modulating the magnitude of XB recruitment in cardiac muscle. Our results also show that cTnT may participate in tuning the heart muscle by decreasing the speed of XB recruitment so that it is ideal for the heart to beat at a rate commensurate with the frequency of minimum stiffness, fmin.
Materials and methods
PCR cloning of full-length rat fsTnT DNA
A full-length cDNA clone for adult rat fsTnT (class IA α-1) was isolated from adult rat skeletal muscle first-strand cDNA (OriGene Technologies, Rockville, MD). For PCR amplification, we used two oligonucleotide primers whose nucleotide sequences were based on the previously published rat fsTnT sequence α-1 (rat fsTnT class IA α-1, Expasy/Swissprot accession No. P09739).
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PCR cloning of full-length rat cTnC DNA
A full-length rat cTnC DNA clone was isolated from rat heart muscle first-strand cDNA (OriGene). We used two oligonucleotide primers whose nucleotide sequences were based on the previously published mouse cTnC sequence (Expasy/Swissprot accession No. P19123).
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PCR cloning of full-length rat cTnI DNA
A full-length rat cTnI DNA clone was isolated from rat heart muscle first-strand cDNA (OriGene). We used two oligonucleotide primers whose nucleotide sequences were based on the previously published 17 mouse cTnI sequence (Expasy/Swissprot accession No. P48787).
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PCR-amplified DNA fragments were gel-purified, digested with appropriate restriction enzymes and subcloned into the Nde I-BamH I site of the pSBETa expression vector (Roche, Pleasantan, CA). DNA clones containing proper inserts were sequenced. Adult rat cTnT cDNA clone was a gift from Dr. J.J. Lin (University of Iowa).
Nucleotide sequences of rat fsTnT, rat cTnC, and rat cTnI
The nucleotide sequence from our rat fsTnT (Genbank Accession No. bankit718582 DQ062204) clone matched perfectly with the previously published sequence. To amplify the full-length rat cTnC and rat cTnI clones from the first-strand cDNA, mouse cTnC and mouse cTnI nucleotide sequences were used as templates, respectively. When compared with the nucleotide sequence derived from an annotated rat genomic sequence (NCBI accession No. XM-214266), there were three nucleotide differences in our rat cTnC clone (Genbank Accession No. bankit718648 DQ062205). However, the amino-acid sequences from our rat cTnC clone were found to be identical to the amino-acid sequence derived from an annotated rat genomic sequence. Similarly, we also found four nucleotide changes compared to the published rat cTnI sequence 18, with no changes in amino-acid sequence (Genbank Accession No. bankit719338 DQ062462).
Expression and purification of recombinant proteins
Recombinant rat fsTnT, rat cTnT, rat cTnC, and rat cTnI (all in pSBETa plasmid DNA) were expressed in BL21 DE3 cells (Novagen, Madison, WI). For all protein preparations, cells from 4 liters were then spun down and sonicated in 50mM Tris (pH 8.0 at 4°C), 6M urea, 5mM EDTA, 0.2mM PMSF, 5mM benzamidine-HCl, 10μM leupeptin, 1μM pepstatin, 5μM Bestatin, 2μM E64, and 1mM DTT. The insoluble fraction was separated by centrifugation. Rat fsTnT was purified as follows: The supernatant from rat fsTnT culture preparation was used for ammonium sulfate fractionations. The pellet from the 45% ammonium sulfate cut was dissolved in 50mM Tris (pH 8.0 at 4°C), 6M urea, 1mM EDTA, 0.2mM PMSF, 4mM benzamidine-HCl, and 1mM DTT, and then purified by chromatography on a DEAE-fast sepharose (Pharmacia, Basking Ridge, NJ) column. Rat fsTnT was eluted with a 0–0.3M NaCl gradient. Rat cTnT was purified as follows: The pellet from the 70% ammonium sulfate cut was dissolved in 50mM Tris (pH 8.0 at 4°C), 6M urea, 1mM EDTA, 0.2mM PMSF, 4mM benzamidine-HCl, and 1mM DTT, and then purified by chromatography on a DEAE-fast sepharose. Rat cTnT was eluted with a gradient of 0–0.3M NaCl. Impure fractions were dialyzed against 50mM Na acetate (pH 5.3 at 4°C), 6M urea, 1mM EDTA, 0.2mM PMSF, 4mM benzamidine-HCl, and 1mM DTT and chromatographed on a SP-Sepharose (Pharmacia) column. Rat cTnT was eluted with a gradient of 0–1M NaCl. Rat cTnI was purified as described previously 17. Rat cTnC was purified as described previously 19. All pure protein fractions were extensively dialyzed against deionized water containing 15mM β-mercaptoethanol, lyophilized and stored at −80°C.
Reconstitution of recombinant rat TnT isoforms into detergent-skinned rat cardiac muscle fiber bundles
Left ventricular papillary muscle fiber bundles from rat hearts were isolated and dissected, as described previously 13,14. Detergent skinning of muscle fibers were performed overnight at 4°C in the relaxing solution (HR, pCa 9.0) containing 50mM BES (pH 7.0), 30.83mM K Propionate, 10mM NaN3, 20mM EGTA, 6.29mM MgCl2, 6.09mM ATP, 20mM BDM, 1mM DTT, 0.1% Triton X-100, and a cocktail of protease inhibitors (4μM Benzamidine-HCl, 5μM Bestatin, 2μM E-64, 10μM Leupeptin, 1μM Pepstatin, and 200μM PMSF). Exchange of rat muscle endogenous troponin complex with rat recombinant troponin complex containing either cTnT-cTnI-cTnC or fsTnT-cTnI-cTnC was based on the method described previously 20, which was modified as follows: The extraction solution containing a mixture of cTnT/fsTnT and cTnI was prepared as cTnT/fsTnT (0.7mg/ml, w/v) and cTnI (0.7mg/ml, w/v), which were initially dissolved in 50mM Tris-HCl (pH 8.0), 6M urea, 1.0M KCl, 10mM DTT, and a cocktail of protease inhibitors. High salt and urea were removed by successive dialysis against the following buffers: 50mM Tris-HCl (pH 8.0 at 4°C), 4M urea, 0.7M KCl, 1mM DTT, 4mM benzamidine-HCl and 0.4mM PMSF and 0.01% NaN3, followed by 50mM Tris-HCl (pH 8.0 at 4°C), 2M urea, 0.5M KCl, 1mM DTT, 4mM benzamidine-HCl, and 0.4mM PMSF and 0.01% NaN3 and then finally against the extraction buffer containing 50mM BES (pH 7.0 at 20°C), 180mM KCl, 10mM BDM, 5mM EGTA, 6.27mM MgCl2, 1.0mM DTT, 4mM benzamidine-HCl, 0.2mM PMSF, and 0.01% NaN3. After final dialysis, 5mM MgATP2- and fresh protease inhibitors were added to the supernatant containing cTnT-cTnI or fsTnT-cTnI. Any undissolved protein was removed by spinning in a microfuge at maximum speed for 15min. Detergent-skinned muscle fiber bundles were treated with the extraction solution containing cTnT-cTnI or fsTnT-cTnI for ∼3–4h at room temperature with gentle constant stirring. Muscle fiber bundles were then washed twice with extraction buffer for 15min. Ca2+-activated maximal tension was measured in pCa 4.3 to determine the residual tension. cTnT-cTnI or fsTnT-cTnI treated muscle fiber bundles were reconstituted overnight (4°C) with cTnC (3mg/ml) prepared in the relaxation buffer on ice. The composition of relaxation buffer was 50mM BES, 51.14mM K propionate, 5.83mM Na2ATP, 6.87mM MgCl2, 10mM EGTA, 5mM NaN3, 1mM DTT, 10mM phosphenol pyruvate, 50μM Leupeptin, 1μM Pepstatin, 200μM PMSF, 10μM oligomycin, and 20μM A2P5 (ionic strength ∼180mM). After reconstitution, Ca2+-activated tension and ATPase activity were measured in solutions containing different amounts of free (Ca2+) as described previously 13,14.
Tension-ATPase relation
For simultaneous measurement of tension and ATPase (20°C), we used a system described by Stienen et al. 21 and de Tombe and Stienen 22. Detergent-skinned muscle fiber was attached to a motor and a force transducer using aluminum clips. Sarcomere length (SL) was measured, as previously described 13,22. After 2–3 cycles of full activation and relaxation, the resting SL was readjusted to 1.9–2.2μm and continuously monitored using a He-Ne laser diffraction system. Using this approach, we found that the resting SL remained stable throughout the experiment. Near-UV light (340mm) was projected through the muscle chamber just below the muscle fiber, then split via a beam splitter (50:50) and detected at 340nm (sensitive to change in NADH) and 400nm (insensitive to NADH). The light intensity at 400nm served as a reference signal. An analog divider and log amplifier produced a signal proportional to the amount of ATP consumed in the muscle chamber solution. ATPase activity of the skinned muscle fiber bundle was measured as follows: ATP regeneration from ADP was coupled to the breakdown of phosphenol pyruvate to pyruvate and ATP catalyzed by pyruvate kinase, which was linked to the synthesis of lactate catalyzed by lactate dehydrogenase. The breakdown of NADH (which is proportional to the amount of ATP consumed), was measured online by UV absorbance at 340nm. Maximum activation buffer (pCa 4.3) contained 31mM potassium propionate, 5.95mM Na2ATP, 6.61mM MgCl2, 10mM EGTA, 10.11mM CaCl2, 50mM BES, pH 7.0, 10mM NaN3, 10μM leupeptin, 1μM pepstatin, 10μM oligomycin, 100μM PMSF, 0.9mM NADH, 10mM phosphenol pyruvate, 4mg/ml pyruvate kinase (500U/mg), 0.24mg/ml lactate dehydrogenase (870U/mg), and 20μM A2P5 and the ionic strength of the buffer was 180mM. The composition of different pCa (−log of free Ca2+-concentration) solution was calculated using the methods described by Fabiato and Fabiato 23.
Dynamic force-length relationship
Dynamic force-length relationship (FLR) was determined at maximal Ca2+ activation (pCa 4.3) as described previously 14. Briefly, this protocol was designed to provide force and muscle-length information at all frequencies between 0.1 and 40Hz. Muscle fiber length, LM, was commanded to change according to a constant amplitude (0.5% of LM) sinusoid of continuously varying frequency (chirp). Two chirps were delivered over two sequential time periods. In the first period of 40s duration, chirp frequencies varied between 0.1 and 4Hz to emphasize low frequency behavior. In the second time period of 5s duration, chirp frequencies varied between 1 and 40Hz to emphasize higher frequency behavior. Measured force changes, ΔF(t), during the FLR protocol were maximally 10% of the Fs baseline. Baseline trends and wander were removed 14 from the ΔF(t) record by fitting a fourth-order polynomial in time to the ΔF(t) signal. The frequency content of the fourth-order polynomial was in a range below the frequency composition of the ΔL(t) signal. Examples of data obtained with this protocol are shown later, in Fig. 6.
Estimating parameters of dynamic FLR
Parameters of the dynamic FLR were derived by fitting a recruitment-distortion model 14 to the measurement of ΔF(t) obtained in the dynamic FLR protocol. The recruitment-distortion model is given by the following differential equations:
 | (1) |
 | (2) |
 | (3) |
In these equations, 
is the model-predicted variation in force in response to measured variation in muscle length, ΔL(t) (through recruitment dynamics; see Eq. (2)), and in response to the first time derivative of muscle length, 
(through distortion dynamics; see Eq. (3)). The value η(t) is the recruitment variable; it describes the incremental addition of XBs acting in parallel to produce force. The value x(t) is the distortion variable; it describes the average distortion of internal stretch with the elastic regions of XBs. Parameter E0 is the slope of the static FLR. Parameter E∞ is instantaneous stiffness, as estimated from the initial force response to a sudden stretch. Parameter b is the rate constant governing recruitment dynamics. Parameter c is the rate constant governing distortion dynamics. This model of cardiac muscle dynamic FLR has undergone extensive validation; the model was shown to fit the data well, leaving very little residual error (R2>0.98), and parameters of the model (E0, b, E∞, c) were estimated with <1% error 14. Fitting of data in the present study was as described previously 14.
Measurement of rate of tension redevelopment (ktr)
The ktr measurements were made at maximal Ca2+ activation (pCa 4.3). A large slack-release protocol 24 was used to disengage force-generating XBs from the thin filaments, which were isometrically activated. The rate constant of tension redevelopment (ktr) was determined by fitting the rise of tension to the following equation: F=Fobs(1−e−ktr.t)+F0, where F is force at time t, Fobs is observed steady-state force, and ktr is the rate constant of tension redevelopment. In all cases, tension redevelopment in cardiac muscle fibers was well fitted with the monoexponential equation (R2>0.97).
Polyacrylamide gel electrophoresis
Protein samples for gel electrophoresis and Western blot analysis were prepared and run on 12.5% SDS-polyacrylamide gels, as previously described 25,26. For Western blot analysis, proteins were transferred onto the PVDF membrane and probed using an anti-mouse primary antibody against either rabbit fsTnT or rat cTnT, as previously described 26.
Data analysis
Data from the normalized pCa-tension measurements were fitted to the Hill equation by using a nonlinear least-square regression procedure to obtain the pCa50 (−log of free Ca2+-concentration required for half-maximal activation) and the Hill coefficient (n). pCa50 and n were determined separately from each muscle fiber experiment and the values averaged. Statistical differences were analyzed by one-way ANOVA, with the criteria for significance set at p<0.05. Data are expressed as mean±SE.
Results
Exchange of rat fsTnT into detergent-skinned rat cardiac muscle fiber bundles
Control untreated, cTnT+cTnI+cTnC and fsTnT+cTnI+cTnC reconstituted muscle fibers were solubilized in the gel-loading buffer 20,25 and separated on 12.5% SDS gels. Western blot analysis was performed with the anti-cTnT antibody (Figure 1A) to demonstrate the removal of endogenous native cTnT in fsTnT+cTnI+cTnC reconstituted muscle fibers. No immunoreactivity is evident in lane 4 corresponding to the endogenous cTnT band, which demonstrated that most of the endogenous cTnT was replaced by fsTnT (Figure 1A). In Figure 1B, Western blot analysis was performed with the anti-fsTnT antibody to demonstrate the incorporation of fsTnT in fsTnT+cTnI+cTnC reconstituted muscle fibers. Lane 3 in Figure 1B shows that the recombinant fsTnT isoform was incorporated into fsTnT+cTnI+cTnC reconstituted muscle fibers.
Figure 1
Western blot analysis of rat cardiac muscle fiber bundles reconstituted with recombinant rat cTnT and rat fsTnT proteins. (A) Anti-human cTnT antibody was used to probe for rat cardiac TnT. Lane 1, purified recombinant rat cTnT; lane 2, control untreated muscle fibers; lane 3, cTnT+cTnI+cTnC reconstituted muscle fibers; and lane 4, fsTnT+cTnI+cTnC reconstituted muscle fibers. No immunoreactivity is evident in lane 4 corresponding to the native cTnT. (B) Anti-rabbit fast skeletal TnT antibody was used to probe for the presence of rat fsTnT in reconstituted muscle fibers. Lane 1, purified recombinant rat fsTnT; lane 2, cTnT+cTnI+cTnC reconstituted muscle fibers; and lane 3, fsTnT+cTnI+cTnC reconstituted muscle fibers.Effect of fsTnT on Ca2+ activation in cardiac muscle fibers
The SL dependencies of Ca2+-activated maximal tension and ATPase activity were measured in control untreated and reconstituted muscle fibers at pCa 4.3. At short SL of 1.9μm (Figure 2A), Ca2+-activated maximal tension (in mN/mm2) was 38±1, 36±2, and 23±2 for control untreated, cTnT+cTnI+cTnC reconstituted, and fsTnT+cTnI+cTnC reconstituted muscle fibers, respectively. At short SL, Ca2+-activated maximal ATPase activity (in pmol/mm3/s) was 220±8, 202±10, and 174±7 for control untreated, cTnT+cTnI+cTnC reconstituted, and fsTnT+cTnI+cTnC reconstituted muscle fibers, respectively (Figure 2B). At long SL of 2.2μm, Ca2+-activated maximal tension (in mN/mm2) was 53±1, 55±1, and 38±2 for control untreated, cTnT+cTnI+cTnC reconstituted, and fsTnT+cTnI+cTnC reconstituted muscle fibers, respectively (Figure 3A). At long SL, Ca2+-activated maximal ATPase activity (in pmol/mm3/s) was 222±6, 215±7, and 144±7 for control untreated, cTnT+cTnI+cTnC reconstituted and fsTnT+cTnI+cTnC reconstituted muscle fibers, respectively (Figure 3B). Thus, both Ca2+-activated maximal tension and ATPase activity (Figure 2 and Figure 3) in cTnT+cTnI+cTnC reconstituted muscle fibers were not significantly different from those of control untreated muscle fibers at both short and long SL. On the other hand, both Ca2+-activated maximal tension and maximal ATPase activity (Figure 2 and Figure 3) were significantly depressed in fsTnT+cTnI+cTnC reconstituted muscle fibers at both short and long SL. When a second reconstitution of fsTnT+cTnI+cTnC reconstituted fibers was done to replace fsTnT with cTnT (restoring the cTnT+cTnI+cTnC construct), the depression in Ca2+-activated tension, and ATPase activity were released (data not shown). These observations demonstrated that the depression of tension and ATPase activity were due to the impact of fsTnT on cardiac myofilaments and not related to the reconstitution procedure.
Figure 2
Ca2+-activated maximal tension and ATPase activity in detergent-skinned rat cardiac muscle fiber bundles reconstituted with recombinant rat cTnT and fsTnT. After reconstitution, Ca2+-activated maximal tension and ATPase activity 21,22 were measured in activation buffer at pCa 4.3. Control untreated muscle fibers (control), cTnT+cTnI+cTnC reconstituted muscle fibers (cTnT), and fsTnT+cTnI+cTnC reconstituted muscle fibers (fsTnT). (A) Effect on Ca2+-activated maximal tension at SL of 1.9μm. (B) Effect on Ca2+-activated maximal ATPase activity at SL of 1.9μm. Residual Ca2+-activated tension (pCa 4.3) measured after treatment with either cTnT+cTnI or fsTnT+cTnI was minimal (∼1.0mN/mm2). Number of determinations is at least 10 for each. The asterisk symbol (*) indicates a result significantly different from control (P<0.001).
Figure 3
Ca2+-activated maximal tension and ATPase activity in detergent-skinned rat cardiac muscle fiber bundles reconstituted with recombinant rat cTnT and fsTnT. After reconstitution, Ca2+-activated maximal tension and ATPase activity 21,22 were measured in activation buffer at pCa 4.3. Control untreated muscle fibers (control), cTnT+cTnI+cTnC reconstituted muscle fibers (cTnT), and fsTnT+cTnI+cTnC reconstituted muscle fibers (fsTnT). (A) Effect on Ca2+-activated maximal tension at SL of 2.2μm. (B) Effect on Ca2+-activated maximal tension and ATPase activity at SL of 2.2μm. Residual Ca2+-activated tension (pCa 4.3) measured after treatment with either cTnT+cTnI or fsTnT+cTnI was minimal (∼1.0mN/mm2). Number of determinations is at least 10 for each. The asterisk symbol (*) indicates a result significantly different from control (P<0.001).Furthermore, the steepness of pCa-tension relationships in cTnT+cTnI+cTnC and fsTnT+cTnI+cTnC reconstituted muscle fibers were similar to those of control untreated muscle fibers (Fig. 4 and Table 1). Similar results were observed with pCa-ATPase relations (data not shown). A lack of full complement of Tn would have likely resulted in significant changes in the Hill coefficient value (n), myofilament Ca2+ sensitivity (pCa50), and Ca2+-activated maximal tension 27. These observations demonstrated that both cTnT and fsTnT reconstitution was complete. Data shown in Fig. 4 and Table 1 also demonstrate that the fsTnT isoform did not affect cardiac myofilament Ca2+ sensitivity and cooperativity. Two independent previous studies have shown that modifications of cTnT affect Ca2+-activated maximal tension and ATPase activity in cardiac muscle. For example, our own work demonstrated previously that a modification of the N-terminal region of rat cTnT depressed maximal activation in cardiac myofilaments without affecting n- and pCa50 values 25. Similarly, Communal et al. 28 showed that the deletion of the N-terminus of rat cTnT depressed force and ATPase activity, with no effect on n- and pCa50 values.
Figure 4
Normalized pCa-tension relationship in detergent-skinned rat cardiac muscle fiber bundles reconstituted with recombinant rat cTnT and fsTnT. (A) pCa-tension relations at SL of 1.9μm. Control untreated muscle fibers (○), cTnT+cTnI+cTnC reconstituted muscle fibers (●), and fsTnT+cTnI+cTnC reconstituted muscle fibers (▴). (B) pCa-tensions relation at SL of 2.2μm. Control untreated muscle fibers (○), cTnT+cTnI+cTnC reconstituted muscle fibers (●), and fsTnT+cTnI+cTnC reconstituted muscle fibers (▴). pCa50 and Hill coefficient values (n) are listed in Table 1. Standard error bars are smaller than symbols in some cases. Number of determinations is at least 10 for each.| Table 1 Normalized pCa-tension relationship in control untreated, cTnT+cTnI+cTnC, and fsTnT+cTnI+cTnC reconstituted cardiac muscle fiber bundles at short (1.9μm) and long (2.2μm) SL |
| Control | cTnT+cTnI+cTnC | fsTnT+cTnI+cTnC | |||
|---|---|---|---|---|---|
| SL 1.9μm | |||||
| pCa50 | 5.50±0.03 | 5.49±0.02 | 5.45±0.02 | ||
| n | 4.3±0.2 | 4.8±0.2 | 4.2±0.2 | ||
| SL 2.2μm | |||||
| pCa50 | 5.61±0.03 | 5.63±0.02 | 5.63±0.02 | ||
| n | 4.2±0.2 | 4.3±0.2 | 4.4±0.2 | ||
| Values are means±SE. Data from the normalized pCa-tension measurements were fitted to the Hill equation by using a nonlinear least-square regression procedure to derive pCa50 and the Hill coefficient (n) values. pCa50 and n were determined separately from each muscle fiber experiment and the values averaged. Number of determinations is at least 10 for each. |
Effect of fsTnT on the relationship between steady-state isometric tension and ATPase activity
We determined the relationship between steady-state isometric tension and the rate of ATP hydrolysis in muscle fibers reconstituted with cTnT+cTnI+cTnC and fsTnT+cTnI+cTnC. Tension-ATPase relationships were linear (Fig. 5). At long SL (Figure 5B), the slopes of the tension-ATPase relationship (tension cost) of cTnT+cTnI+cTnC and fsTnT+cTnI+cTnC reconstituted muscle fibers were not significantly different from those of control untreated muscle fibers (Table 2). The slope of steady-state isometric tension and the rate of ATP hydrolysis has been proposed as a measure of the rate of XB detachment 23. Therefore, our data suggest that the rate of XB detachment in cardiac myofilaments was not altered by the presence of fsTnT at long SL. In contrast, there was a 38% increase in the slope of tension-ATPase relationship in fsTnT+cTnI+cTnC reconstituted muscle fibers at short SL (Figure 5A and Table 2), indicating that there was an increase in the rate of XB detachment rate at short SL.
Figure 5
Relationship between steady-state isometric tension and ATPase activity in detergent-skinned rat cardiac muscle fiber bundles reconstituted with recombinant rat cTnT and fsTnT. Steady-state isometric tension and ATPase were measured simultaneously as described before 21,22. Equal variance across the sample was confirmed, which permitted us to bin the data as follows. Tension and ATPase data were pooled in 10% wide steady-state bands and the average values for each band were calculated. Averaged data were fitted using a linear regression analysis. Departure from linearity was found to be nonsignificant in all cases. (A) Tension-ATPase relations at SL of 1.9μm. Mean slope values from linear fits of at least 10 muscles are listed in Table 2. Control untreated muscle fibers (○), R2=0.97; cTnT+cTnI+cTnC reconstituted muscle fibers (●), R2=0.97; and fsTnT+cTnI+cTnC reconstituted muscle fibers (▴), R2=0.96. (B) Tension-ATPase relations at SL of 2.2μm. Control untreated muscle fibers (○), R2=0.99; cTnT+cTnI+cTnC reconstituted muscle fibers (●), R2=0.98; and fsTnT+cTnI+cTnC reconstituted muscle fibers (▴), R2=0.99.| Table 2 Effect of activating Ca2+ on the slope of tension-ATPase relationship (tension cost) and XB distortion rate constant (c) at SL of 1.9 and 2.2μm in control untreated, cTnT+cTnI+cTnC, and fsTnT+cTnI+cTnC reconstituted cardiac muscle fiber bundles |
| Control | cTnT+cTnI+cTnC | fsTnT+cTnI+cTnC | |||
|---|---|---|---|---|---|
| SL 1.9μm | |||||
| Tension cost | 6.26±0.24 | 6.05±0.22 | 8.38±0.49† | ||
| c (s−1) | 52.75±4.56 | 53.37±4.28 | 94.93±6.76† | ||
| SL 2.2μm | |||||
| Tension cost | 4.47±0.10 | 4.04±0.15 | 4.09±0.18 | ||
| c (s−1) | 40.4±0.2 | 31.21±0.4* | 35.53±0.3* | ||
| Values are means±SE. Tension and ATPase activities were measured simultaneously at different Ca2+ activations as described previously 13,21,22. Tension cost (in pmol/mN/mm/s) is determined from the slopes of tension-ATPase relationships (Fig. 5). The rate constant of XB distortion (c) was determined at maximal Ca2+ activation (pCa 4.3) as described previously 14. Number of determinations is at least 10 for each. |
| * p<0.01. † p<0.001. |
Effect of TnT isoform on the rate of tension redevelopment (ktr)
SL-dependent effects on maximal ktr values in reconstituted muscle fibers were measured at pCa 4.3. fsTnT significantly increased ktr values in reconstituted cardiac muscle fibers at both short and long SL (Table 3). At short SL, the ktr for fsTnT+cTnI+cTnC reconstituted muscle fiber was 37% higher than in cTnT+cTnI+cTnC reconstituted muscle fibers. Similarly, at long SL, the ktr for fsTnT+cTnI+cTnC reconstituted muscle fiber was 32% higher than in cTnT+cTnI+cTnC reconstituted muscle fibers. Furthermore, the maximum ktr values at short SL were significantly higher than those at long SL for all three groups of muscle fibers tested (Table 3). The ktr values increased by 38% from long to short SL in control untreated, by 29% for cTnT+cTnI+cTnC, and by 34% for fsTnT+cTnI+cTnC reconstituted muscle fibers. In contrast to our observations, studies on rat slow-twitch and rabbit fast-twitch skeletal muscle fibers demonstrated that ktr values at short SL were significantly lower than those measured at longer SL 29. This difference may be related to the differences in the fiber types used in our study. Some support for our study comes from a recent study in which the SL-dependent effect on ktr was measured in rat cardiac trabeculae preparations 30. During submaximal activation 30, ktr values measured at short SL were significantly faster than those measured at long SL. However, they observed a small but statistically insignificant increase in ktr values during maximal Ca2+ activation at short SL 30.
| Table 3 Effect of activating Ca2+ on rate constants of tension redevelopment (ktr) and XB recruitment (b) at SL of 1.9 and 2.2μm in control untreated, cTnT+cTnI+cTnC, and fsTnT+cTnI+cTnC reconstituted cardiac muscle fiber bundles |
| Control | cTnT+cTnI+cTnC | fsTnT+cTnI+cTnC | |||
|---|---|---|---|---|---|
| SL 1.9μm | |||||
| ktr (s−1) | 8.82±0.31 | 7.87±0.47 | 10.78±0.51* | ||
| b (s−1) | 2.24±0.22 | 3.05±0.52 | 5.32±0.58* | ||
| SL 2.2μm | |||||
| ktr (s−1) | 6.39±0.18 | 6.10±0.14 | 8.04±0.33* | ||
| b (s−1) | 4.67±0.27 | 4.16±0.25 | 8.36±0.38* | ||
| Values are means±SE. The rate constant of monoexponential tension redevelopment (ktr) was determined as described previously 13,24. The rate constant of XB recruitment (b) was determined as described previously 14. The values b and ktr were measured at maximal Ca2+ activation (pCa 4.3). Number of determinations is at least 10 for each. |
| * p<0.01. |
Effect of TnT on XB recruitment and distortion dynamics
Results from the double-chirp, dynamic FLR protocol for muscle fibers reconstituted with cTnT+cTnI+cTnC and fsTnT+cTnI+cTnC are shown in Figure 6AC, respectively. In both examples, the force amplitude first declined to a minimum (see arrows in Fig. 6) and then rose as the frequency of muscle length perturbation increased. Standard errors of the parameter estimates (E0, b, E∞, c) were generally <1% of the estimated parameter value. Both the magnitude and the speed of length-mediated XB recruitment were strongly affected by the isoform of TnT. E0 (XB recruitment magnitude) was ∼1.5 times greater for cTnT+cTnI+cTnC than for fsTnT+cTnI+cTnC reconstituted muscle fibers (82 vs. 56mN/mm2 per μm at short SL and 186 vs. 126mN/mm2 per μm at long SL). Thus, the length-induced increase in E0 was favored in muscle fibers reconstituted with cTnT over those fibers reconstituted with fsTnT. The value b in cTnT+cTnI+cTnC reconstituted muscle fiber was only 0.57–0.50 times as fast as that in fsTnT+cTnI+cTnC reconstituted muscle fibers (3.05 vs. 5.32s−1 at short SL and 4.16 vs. 8.36s−1 at long SL).
Figure 6
Frequency dependency of force response to controlled sinusoidal oscillations in detergent-skinned rat cardiac muscle fiber bundles reconstituted with recombinant rat cTnT and fsTnT. Model-predicted force from the recruitment-distortion model 14 accurately reproduced force measurements for both example tracings shown in panels A and C. Measured force is shown by light shaded trace and the model-predicted force is shown by black trace. The minimal force amplitude response is shown by the arrow in both panels A and C. (A) Force recordings from the double-chirp sinusoidal muscle length change protocol in the cTnT+cTnI+cTnC reconstituted muscle fibers at SL of 2.2μm. (B) Two chirps were delivered over two sequential time periods: in one period of 40-s duration, chirp frequencies varied between 0.1 and 4Hz to emphasize low frequency behavior and in a second time period of 5-s duration, chirp frequencies varied between 1 and 40Hz to emphasize higher frequency behavior 14. Identical chirps were delivered to both muscle fibers shown in panels A and C. (A) Force recordings from the double-chirp sinusoidal muscle length change protocol in the fsTnT+cTnI+cTnC reconstituted muscle fibers at SL of 2.2μm. There was a small divergence between model prediction and force measurement at high frequencies. Our attempt in modifying the recruitment-distortion model to account for the small high frequency effect, led to no change in the values of model-estimated parameters. The frequency of minimal stiffness, fmin, is 0.79Hz for cTnT-cTnI-cTnC reconstituted fibers (A) and 1.11Hz for fsTnT+cTnI+cTnC reconstituted fibers (C).Both the infinite frequency (E∞) and Ca2+-activated steady-state tension (Fss) measure the number of parallel XBs 15. At long SL, E∞ for cTnT+cTnI+cTnC reconstituted fibers was 827mN/mm2/μm, whereas for fsTnT+cTnI+cTnC fibers, E∞ was 558mN/mm2 per μm. Thus, the ratio, E∞/Fss, was not different between cTnT and fsTnT reconstituted muscle fibers indicating that fsTnT had no effect on force per XB. The E∞/Fss ratio also remained unaffected at short SL (data not shown). Therefore, the depression in maximal tension and ATPase activity in fsTnT+cTnI+cTnC reconstituted muscle fibers was likely be due to a decrease in the number of XBs. Whether the stabilization of cardiac thin filaments in the submaximally activated state involves altered fsTnT-Tm 25 or fsTnT-TnI interactions remains to be explored. At short SL, the value c of muscle fibers reconstituted with cTnT+cTnI+cTnC was much lower than that for fibers reconstituted with fsTnT+cTnI+cTnC (53.4 vs. 94.9s−1). However at long SL, c of fibers reconstituted with cTnT+cTnI+cTnC was not different than that for fibers reconstituted with fsTnT+cTnI+cTnC (31.2 vs. 35.5s−1).
TnT-induced changes in the recruitment-distortion model parameters
Just as b was slower in muscle fibers reconstituted with cTnT+cTnI+cTnC than those reconstituted with fsTnT+cTnI+cTnC, ktr was also slower at both short and long SL (Table 3). Directional similarity in the estimated values of b and ktr suggests that TnT modulates b. At short SL, ktr was faster and b was slower for all three groups of muscle fibers tested in this study. The mechanism of recruiting XBs in ktr experiments differs significantly from those in the dynamic FLR measured using small changes in muscle length. The value ktr is an approximation of a single rate constant for force redevelopment for a given SL under the experimental condition where most XBs have been mechanically broken. On the other hand, b was estimated by fitting small changes in force around a steady-state force with small changes in muscle length. The XB recruitment rate constant embraces the entire myofilament system, which includes the thin-filament overlap, length-dependent XB attachment, and amplification of XB attachment by cooperativity 14. The question of how various XB recruitment mechanisms interact and how they are affected by different SLs remains open. Although the directionality of changes in ktr versus b and c versus tension cost were similar, the magnitude of changes in both ktr and c were higher in fsTnT reconstituted muscle fibers at short SL (Table 3).
Discussion
We have documented a new functional role for cTnT in cardiac thin filaments. Our study demonstrates that cardiac muscle fibers reconstituted with cTnT+cTnI+cTnC differ from those reconstituted with fsTnT+cTnI+cTnC in the magnitude and the speed of dynamic length-mediated recruitment of XBs. There are many mechanisms for recruitment of XBs into the force-bearing state in cardiac muscle. Most obviously, Ca2+ activation is an important XB recruitment mechanism. Just as important is the SL of muscle at any given Ca2+ in recruiting XBs. In this study, we use an incremental measure of length-mediated XB recruitment with our assessment of E0 and b from the dynamic FLR. XB recruitment from the noncycling pool into the cycling pool (force generating XBs) is aided by the transition of RU from the nonpermissive to the permissive states 31. Ca2+ bound to RU is obligatory for transition of RU from the nonpermissive to permissive states. However, Ca2+ binding only initiates the process, and the amount of subsequent nonpermissive to permissive RU transition that occurs depends on both SL and cooperative interactions between XB and RU states. Our data implicates TnT as a participant in the mechanism by which both SL and XB-RU cooperative interactions aid in recruiting cycling XBs during thin-filament activation.
XB recruitment magnitude effects in muscle activation have typically been related to so-called length-dependent activation in cardiac muscle. The differential effect of cTnT on the rate constant of XB recruitment (b) and the magnitude of XB recruitment (E0) suggests that cTnT participates importantly in the mechanism of this fundamental cardiac muscle functional property. Most importantly, cTnT slows b in cardiac muscle fibers. The significance of slowing b may be explained by considering the frequency dependence of cardiac muscle stiffness. Frequency-dependent cardiac muscle stiffness, σ(jω), was calculated from the recruitment-distortion model by Fourier transformation of Eqs. (1) to give
 | (4) |
Figure 7
Stiffness magnitude spectra of detergent-skinned rat cardiac muscle fiber bundles reconstituted with recombinant rat cTnT and fsTnT. Dynamic FLR was determined at full activation (pCa 4.3) after muscle fiber bundles were reconstituted with recombinant proteins. Dashed line represents muscle fiber bundles reconstituted with cTnT+cTnI+cTnC and solid lines represent muscle fiber bundles reconstituted with fsTnT+cTnI+cTnC. (A) Dynamic stiffness measurements at SL of 1.9μm. The frequency of minimal stiffness, fmin, is 0.64Hz for cTnT-cTnI-cTnC reconstituted muscle fibers and 1.16Hz for fsTnT+cTnI+cTnC reconstituted muscle fibers. (B) Dynamic stiffness measurements at SL of 2.2μm. The frequency of minimal stiffness, fmin, is 0.79Hz for cTnT-cTnI-cTnC reconstituted muscle fibers and 1.11Hz for fsTnT+cTnI+cTnC reconstituted muscle fibers.When complex stiffness is calculated using the dynamic FLR parameters of the cTnT+cTnI+cTnC reconstituted muscle fibers, fmin is well defined with values of 0.64 and 0.79Hz at short and long SL, respectively (Fig. 7). The minimum in the stiffness magnitude at fmin is clearly identified, i.e., the minimum stiffness magnitude at fmin is much less than that at zero frequency. However, when b is almost doubled to the value it possessed in the fsTnT+cTnI+cTnC reconstituted fiber, fmin is increased by 80% to 1.16Hz at short SL and 40% to 1.11Hz at long SL (Fig. 7). Assuming, as others have 32,33,34, that fmin and minimum frequency stiffness are important features of heart muscle that tunes the dynamics of muscle contraction to heart rate, our results suggest that cTnT is an important protein in achieving that tuning.
The sense in which this tuning may occur is as follows. When muscle shortens, force decreases according to the speed of shortening and the stiffness of the muscle. If the muscle shortens quickly, as during high frequency length change, the high stiffness of the muscle at these high frequencies (→ E∞) causes muscle force to drop to very low values by the end of the shortening period (ΔF→E∞ΔL). If the muscle shortens slowly, as during low frequency length change, the modest stiffness of the muscle at these low frequencies (→ E0) causes muscle force to drop modestly to low values by the end of the shortening period (ΔF→E0ΔL). However, if the muscle shortens at speeds commensurate with fmin, the minimum stiffness at fmin (→ Emin) causes force to drop by an increment (ΔF→EminΔL) that is less than during rapid shortening or slow shortening. Because the amount of work done by the muscle during shortening is determined by the area under the force-length trajectory, the trajectory in which force is maintained highest during shortening is the one in which most work is performed. This will be the trajectory associated with shortening at speeds commensurate with fmin. Because cTnT participates in determining fmin, it participates in setting the requirements for tuned operation of the cardiac system. cTnT exerts this effect on cardiac thin-filament tuning by its effect on the speed of XB recruitment (b).
SL-dependence of rate of tension redevelopment (ktr) and XB detachment rate constant in cardiac muscle
When maximally activated (pCa 4.3), there was a small but significant increase in ktr at short SL, compared to long SL, in all three groups of muscle fibers tested. At short SL, ktr increased by 38%, 29%, and 34% in control, cTnT+cTnI+cTnC, and fsTnT+cTnT+cTnI reconstituted muscle fibers, respectively (Table 3). A recent study by Adhikari et al. 30 demonstrated a small, but statistically insignificant 14% increase in maximal ktr at short SL in detergent-skinned rat cardiac trabeculae preparations. However, in the study of Adhikari et al., measurements made during submaximal activation at short SL showed significantly decreased force and significantly increased ktr. To account for this decreased force and increased ktr at short SL, Adhikari et al. 30 hypothesized that the XB detachment rate constant, g, increased at short SL due to an increased XB radial strain 35,36. In the two-state model, ktr=fapp+gapp and force is proportional to fapp/(fapp+gapp). Therefore, an increase in g may explain why maximal ktr increases and force drops at short SL in cardiac muscle fibers. Interestingly, our data demonstrate that both the tension cost (which is a measure of g) and the XB detachment rate constant (c, which is proportional to g) increase significantly at short SL (Table 2). Note that the model estimated c agrees well with the directionality of the trend in the experimentally obtained value of the tension cost. Although the tension cost and c increased at short SL in both control untreated as well as reconstituted muscle fiber bundles, an increase in the tension cost and c were more pronounced in fsTnT+cTnI+cTnC reconstituted muscle fibers. The mechanism by which changes in SL and TnT isoforms impact XB recruitment is not well understood. The small increase in ktr as shown in this study and Adhikari et al. 30 contrasts with previous data from rat slow-twitch and rabbit fast-twitch skeletal muscle fiber studies, which demonstrated a small but significant decrease in maximal ktr at short SL 29.
The molecular mechanism by which RU impacts XB detachment rate is unknown. TnT interacts strongly with both TnI and Tm, which bind directly to actin to regulate different XB states. Parts of TnT may also interact directly with actin monomers in a functional unit 37,38. Therefore, TnT has the ability to alter XB cycling either directly or indirectly through its effect on TnI, Tm, and actin 39,40. For example, qualitative changes in cardiac RU have been shown to affect length-dependent activation (slow skeletal TnI in the heart, PKA phosphorylation of cTnI, mutations in cTnT), which suggest that altered protein-protein interactions within the thin filament alter length-dependent activation 11,13,41. For example, we recently showed that the tension cost increased at both short and long SL in a mutant cTnT in which the amino-acid residue 160 was deleted 42. Our data show that cTnT differentially modulates XB recruitment compared to the effect of fsTnT and may tune the heart muscle by decreasing the speed of XB recruitment so that the heart beats at a rate commensurate with the frequency of minimum stiffness (fmin). A link between tuning of cardiac muscle by a thin-filament protein and heart rate has significant implications for cardiomyopathy in humans, where mutations in thin-filament proteins are known to be causal.
Acknowledgments
This work was supported by National Institutes of Health grant No. HL-075643 (to M.C.).
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