Fluorescence resonance energy transfer between residues on troponin and tropomyosin in the reconstituted thin filament: modeling the troponin-tropomyosin complex

Troponin (Tn), in association with tropomyosin (Tm), plays a central role in the calcium regulation of striated muscle contraction. Fluorescence resonance energy transfer (FRET) between probes attached to the Tn subunits (TnC, TnI, TnT) and to Tm was measured to study the spatial relationship between Tn and Tm on the thin filament. We generated single-cysteine mutants of rabbit skeletal muscle α-Tm, TnI and the β-TnT 25-kDa fragment. The energy donor was attached to a single-cysteine residue at position 60, 73, 127, 159, 200 or 250 on TnT, at 98 on TnC and at 1, 9, 133 or 181 on TnI, while the energy acceptor was located at 13, 146, 160, 174, 190, 209, 230, 271 or 279 on Tm. FRET analysis showed a distinct Ca²⁺-induced conformational change of the Tm-Tn complex and revealed that TnT60 and TnT73 were closer to Tm13 than Tm279, indicating that the elongated N-terminal region of TnT extends beyond the beginning of the next Tm molecule on the actin filament. Using the atomic coordinates of the crystal structures of Tm and the Tn core domain, we searched for the disposition and orientation of these structures by minimizing the deviations of the calculated FRET efficiencies from the observed FRET efficiencies in order to construct atomic models of the Tn-Tm complex with and without bound Ca²⁺. In the best-fit models, the Tn core domain is located on residues 160-200 of Tm, with the arrowhead-shaped I-T arm tilting toward the C-terminus of Tm. The angle between the Tm axis and the long axis of TnC is ∼ 75° and ∼ 85° with and without bound Ca²⁺, respectively. The models indicate that the long axis of TnC is perpendicular to the thin filament without bound Ca²⁺, and that TnC and the I-T arm tilt toward the filament axis and rotate around the Tm axis by ∼ 20° upon Ca²⁺ binding.     

Ca-Dependent Photocrosslinking of Tropomyosin Residue 146 to Residues 157-163 in the C-Terminal Domain of Troponin I in Reconstituted Skeletal Muscle Thin Filaments

The Ca²⁺-dependent interaction of troponin I (TnI) with actin·tropomyosin (Tm) in muscle thin filaments is a critical step in the regulation of muscle contraction. Previous studies have suggested that, in the absence of Ca²⁺, TnI interacts with Tm and actin in reconstituted muscle thin filaments, maintaining Tm at the outer domain of actin and blocking myosin-actin interaction. To obtain direct evidence for this Tm-TnI interaction, we performed photochemical crosslinking studies using Tm labeled with 4-maleimidobenzophenone at position 146 or 174 (Tm*146 or Tm*174, respectively), reconstituted with actin and troponin [composed of TnI, troponin T (TnT), and troponin C] or with actin and TnI. After near-UV irradiation, SDS gels of the Tm*146-containing thin filament showed three new high-molecular-weight bands determined to be crosslinked products Tm*146-TnI, Tm*146-troponin C, and Tm*146-TnT using fluorescence-labeled TnI, mass spectrometry, and Western blot analysis. While Tm*146-TnI was produced only in the absence of Ca²⁺, the production of other crosslinked species did not show Ca²⁺ dependence. Tm*174 mainly crosslinked to TnT. In the absence of actin, a similar crosslinking pattern was obtained with a much lower yield. A tryptic peptide from Tm*146-TnI with a molecular mass of 2601.2 Da that was not present in the tryptic peptides of Tm*146 or TnI was identified using HPLC and matrix-assisted laser desorption/ionization time-of-flight. This was shown, using absorption and fluorescence spectroscopy, to be the 4-maleimidobenzophenone-labeled peptide from Tm crosslinked to TnI peptide 157-163. These data, which show that a region in the C-terminal domain of TnI interacts with Tm in the absence of Ca²⁺, support the hypothesis that a TnI-Tm interaction maintains Tm at the outer domain of actin and will help efforts to localize troponin in actin·Tm muscle thin filaments.     

Studies on the regulatory complex of rabbit skeletal muscle: Contributions of troponin subunits and tropomyosin in the presence and absence of Mg2+ to the acto-S1 ATPase activity

The regulatory roles of the components of the troponin-tropomyosin complex in the presence and absence of Mg²⁺ on the acto-S1 ATPase have been examined. The effect of free Mg²⁺ on the inhibition of the acto-S1 ATPase by rabbit skeletal troponin (Tn) was studied at S1 to actin ratios ranging from 0.17:1 to 2.5:1. These studies were performed using two Mg²⁺ concentrations: 2.5 mM Mg²⁺-2.5 mM ATP, conditions considered to have low free Mg²⁺; and 5.0 mM Mg²⁺-2.5 mM ATP, conditions providing a high free Mg²⁺ concentration of 2.5 mM. In the presence of high free Mg²⁺ (2.5 mM ATP-5.0 mM MgCl₂) the Tn inhibition of acto-S1-TM ATPase increased by approximately 40–50% over a range of S1 to actin ratios of 0.17:1 to 2.5:1. The effect of free Mg²⁺ on increasing quantities of Tn in the absence or presence of tropomyosin was studied independently at two S1 to actin ratios (1:1 and 2:1). In the absence of TM, at 5 mM Mg²⁺ there is an additional 38% (1:1 S1 to actin) or 37% (2:1) decrease in the ATPase activity by Tn compared to 2.5 mM Mg²⁺. Similarly, in the presence of TM and Tn, Mg²⁺ exerts its effect at both S1 to actin ratios. Significantly, the inhibition by the IT complex in the presence of TM is unaffected by free Mg²⁺. Furthermore, ultracentrifugation binding studies using¹⁴C-iodoacetamide-labeled Tn and TM established that the Tn-TM regulatory complex was firmly bound to F-actin at both Mg²⁺ concentrations, indicating that faciliation of binding to F-actin by Mg²⁺ is not responsible for the increased inhibition. Hence, it is concluded from the data that Mg²⁺ binding and by analogy Ca²⁺ binding to the Ca²⁺-Mg²⁺ sites of TnC promotes muscle relaxation by inducing inhibition of the actomyosin ATPase, whereas Ca²⁺ binding to the Ca²⁺-specific sites promotes contraction by potentiating the ATPase. The inhibition of the acto-S1-TM ATPase by TnT has also been further examined. The data indicate that TnT exerts the same level of inhibition upon the ATPase as TnI or Tn. The inhibitory activity requires TM, and occurs to the same extent under conditions where TM alone would have either a potentiating (2:1 S1 to actin) or an inhibitory (1:1 S1 to actin) effect upon the ATPase. In the presence of TM the IT complex is a more effective inhibitor than either TnI, TnT, or Tn. The inhibitory activity of the IT complex is partially released by TnC in the absence of Ca²⁺. These observations, in conjunction with those by Chong, Asselbergs, and Hodges, which showed that the inhibition by TnT is partially released by TnC plus Ca²⁺, indicate that the role of TnT involves more than anchoring Tn to the thin filament.     

Spectroscopic and ITC study of the conformational change upon Ca2+-binding in TnC C-lobe and TnI peptide complex from Akazara scallop striated muscle

Akazara scallop (Chlamys nipponensis akazara) troponin C (TnC) of striated adductor muscle binds only one Ca²⁺ ion at the C-terminal EF-hand motif (Site IV), but it works as the Ca²⁺-dependent regulator in adductor muscle contraction. In addition, the scallop troponin (Tn) has been thought to regulate muscle contraction via activating mechanisms that involve the region spanning from the TnC C-lobe (C-lobe) binding site to the inhibitory region of the TnI, and no alternative binding of the TnI C-terminal region to TnC because of no similarity between second TnC-binding regions of vertebrate and the scallop TnIs. To clarify the Ca²⁺-regulatory mechanism of muscle contraction by scallop Tn, we have analyzed the Ca²⁺-binding properties of the complex of TnC C-lobe and TnI peptide, and their interaction using isothermal titration microcalorimetry, nuclear magnetic resonance, circular dichroism, and gel filtration chromatography. The results showed that single Ca²⁺-binding to the Site IV leads to a structural transition not only in Site IV but also Site III through the structural network in the C-lobe of scallop TnC. We therefore assumed that the effect of Ca²⁺-binding must lead to a change in the interaction mode between the C-lobe of TnC and the TnI peptide. The change should be the first event of the transmission of Ca²⁺ signal to TnI in Tn ternary complex.     

Cardiac Muscle Activation Blunted by a Mutation to the Regulatory Component,Troponin T

The striated muscle thin filament comprises actin, tropomyosin, and troponin. The Tn complex consists of three subunits, troponin C (TnC), troponin I (TnI), and troponin T (TnT). TnT may serve as a bridge between the Ca²⁺ sensor (TnC) and the actin filament. In the short helix preceding the IT-arm region, H1(T2), there are known dilated cardiomyopathy-linked mutations (among them R205L). Thus we hypothesized that there is an element in this short helix that plays an important role in regulating the muscle contraction, especially in Ca²⁺ activation. We mutated Arg-205 and several other amino acid residues within and near the H1(T2) helix. Utilizing an alanine replacement method to compare the effects of the mutations, the biochemical and mechanical impact on the actomyosin interaction was assessed by solution ATPase activity assay, an in vitro motility assay, and Ca²⁺ binding measurements. Ca²⁺ activation was markedly impaired by a point mutation of the highly conserved basic residue R205A, residing in the short helix H1(T2) of cTnT, whereas the mutations to nearby residues exhibited little effect on function. Interestingly, rigor activation was unchanged between the wild type and R205A TnT. In addition to the reduction in Ca²⁺ sensitivity observed in Ca²⁺ binding to the thin filament, myosin S1-ADP binding to the thin filament was significantly affected by the same mutation, which was also supported by a series of S1 concentration-dependent ATPase assays. These suggest that the R205A mutation alters function through reduction in the nature of cooperative binding of S1.     

Conformational changes induced in troponin I by interaction with troponin T and actin/tropomyosin.

Troponin I (TnI) is the inhibitory component of the striated muscle Ca2+ regulatory protein troponin (Tn). The other two components of Tn are troponin C (TnC), the Ca2+-binding component, and troponin T (TnT), the tropomyosin-binding component. We have used limited chymotryptic digestion to probe the local conformation of TnI in the free state, the binary TnC*TnI complex, the ternary TnC*. TnI*TnT (Tn) complex, and in the reconstituted Tn*tropomyosin*F-actin filament. The digestion of TnI alone or in the TnC*TnI complex produced initially two major fragments via a cleavage of the peptide bond between Phe100 and Asp101 in the so-called inhibitory region. In the ternary Tn complex cleavage occurred at a new site between Leu140 and Lys141. In the absence of Ca2+ this was followed by digestion of the 1-140 fragment at Leu122 and Met116. In the reconstituted thin filament the same fragments as in the case of the ternary complex were produced, but the rate of digestion was slower in the absence than in the presence of Ca2+. These results indicate firstly that in both free TnI and TnI complexed with TnC there is an exposed and flexible site in the inhibitory region. Secondly, TnT affects the conformation of TnI in the inhibitory region and also in the region that contains the 140-141 bond. Thirdly, the 140-141 region of TnI is likely to interact with actin in the reconstituted thin filament when Ca2+ is absent. These findings are discussed in terms of the role of TnI in the mechanism of thin filament regulation, and in light of our previous results [Y. Luo, J.-L. Wu, J. Gergely, T. Tao, Biochemistry 36 (1997) 13449-13454] on the global conformation of TnI.     

Deletion of the first 45 NH2-terminal residues of rabbit skeletal troponin T strengthens binding of troponin to immobilized tropomyosin.

The binding of the NH2-terminal region of troponin T (TnT) to the COOH-terminal region of tropomyosin (Tm) and the head-to-tail overlap between Tm molecules is thought to provide a pivotal link between troponin (Tn) and Tm (White, S.P., Cohen, C., and Phillips, G.N., Jr. (1987) Nature 325, 826-828). To further explore the structure-function relationship of the NH2-terminal region of TnT, we studied the binding of a 26,000-dalton TnT fragment (26K-TnT, Ohtsuki, I., Shiraishi, F., Suenaga, N., Miyata, T., and Tanokura, M.J. (1984) J. Biochem. (Tokyo) 95, 1337-1342) which corresponds to residues 46-259 of TnT2f, the major isoform of TnT in rabbit fast twitch muscle, to immobilized alpha-Tm. Both 26K-TnT and TnT2f were retained by the alpha-Tm affinity column in the presence of 150 mM NaCl. However, upon increasing the NaCl concentration 26K-TnT was eluted from the column at a higher ionic strength than was TnT. When applied alone, the binary complex of TnI and TnC (TnC.TnI) was not retained by the alpha-Tm affinity column. When applied subsequently to prebound TnT2f or 26K-TnT, TnI.TnC was retained by the alpha-Tm affinity column and eluted together with TnT2f or 26K-TnT as ternary troponin complexes. Whether Ca2+ was present or not, Tn containing 26K-TnT was eluted at a higher ionic strength than was Tn containing TnT2f, indicating that removal of the first 45 residues of TnT2f strengthens the binding of Tn to Tm. In the presence of Tm, reconstituted Tn containing 26K-TnT conferred Ca2+ sensitivity on actomyosin-S1 MgATPase, and the steepness of the pCa-ATPase relation was unchanged with respect to the actoS1 ATPase regulated by TnT2f. It is concluded that the first 45 residues of TnT2f are not essential for anchoring the troponin complex to the thin filament and do not play a crucial role in the cooperative response of regulated actoS1 ATPase to Ca2+.     

A kinetic model of troponin dissociation in relation to thin filament regulation in striated muscle

The apparent rate of troponin (Tn) dissociation from myofibrils has been used as a method to study thin filament regulation in striated muscle. The rate is dependent upon calcium and strong crossbridges and supports the three-state model for thin filament regulation. The dissociation rate of Tn is extremely low so it is not intuitively clear that such a slow process would probe thin filament regulation. We have investigated this issue by developing a simple kinetic model to explain the Tn dissociation rate measured by labeled Tn exchange in the myofibrils. Tn is composed of three interacting subunits, TnC, TnI and TnT. In our model, TnI’s regulatory domain switches from actin-tropomyosin to TnC followed by TnT dissociation from actin-tropomyosin. This TnI regulatory domain switching is linked to the transition of the thin filament from the blocked state to the closed state. It is calcium dependent and several orders of magnitude faster than TnT dissociation from actin-tropomyosin. By integrating the dimensionless rate equations of this model, we have computed the time course of each of the various components. In our numerical simulations, the rate constant for TnI switching from actin-tropomyosin to TnC was varied from 10 s^?1 to 1000 s^?1 to simulate the low calcium, blocked state to high calcium, closed state. The computed progress curves for labeled Tn exchange into the myofibrils and the derived intensity ratio between the non-overlap and overlap regions well explains the intensity ratio progress curves observed experimentally. These numerical simulations and experimental observations reveal that the apparent rate of Tn dissociation probes the blocked state to closed state equilibrium of the myofibrillar thin filament.     

Structural basis for the regulation of muscle contraction by troponin and tropomyosin

The molecular switching mechanism governing skeletal and cardiac muscle contraction couples the binding of Ca²⁺ on troponin to the movement of tropomyosin on actin filaments. Despite years of investigation, this mechanism remains unclear because it has not yet been possible to directly assess the structural influence of troponin on tropomyosin that causes actin filaments, and hence myosin-crossbridge cycling and contraction, to switch on and off. A C-terminal domain of troponin I is thought to be intimately involved in inducing tropomyosin movement to an inhibitory position that blocks myosin-crossbridge interaction. Release of this regulatory, latching domain from actin after Ca²⁺ binding to TnC (the Ca²⁺ sensor of troponin that relieves inhibition) presumably allows tropomyosin movement away from the inhibitory position on actin, thus initiating contraction. However, the structural interactions of the regulatory domain of TnI (the “inhibitory” subunit of troponin) with tropomyosin and actin that cause tropomyosin movement are unknown, and thus, the regulatory process is not well defined. Here, thin filaments were labeled with an engineered construct representing C-terminal TnI, and then, 3D electron microscopy was used to resolve where troponin is anchored on actin-tropomyosin. Electron microscopy reconstruction showed how TnI binding to both actin and tropomyosin at low Ca²⁺ competes with tropomyosin for a common site on actin and drives tropomyosin movement to a constrained, relaxing position to inhibit myosin-crossbridge association. Thus, the observations reported reveal the structural mechanism responsible for troponin-tropomyosin-mediated steric interference of actin-myosin interaction that regulates muscle contraction.     

Ca2+ -induced tropomyosin movement in scallop striated muscle thin filaments

Striated muscle contraction in most animals is regulated at least in part by the troponin-tropomyosin (Tn-Tm) switch on the thin (actin-containing) filaments. The only group that has been suggested to lack actin-linked regulation is the mollusks, where contraction is regulated through the myosin heads on the thick filaments. However, molluscan gene sequence data suggest the presence of troponin (Tn) components, consistent with actin-linked regulation, and some biochemical and immunological data also support this idea. The presence of actin-linked (in addition to myosin-linked) regulation in mollusks would simplify our general picture of muscle regulation by extending actin-linked regulation to this phylum as well. We have investigated this question structurally by determining the effect of Ca²⁺ on the position of Tm in native thin filaments from scallop striated adductor muscle. Three-dimensional reconstructions of negatively stained filaments were determined by electron microscopy and single-particle image analysis. At low Ca²⁺, Tm appeared to occupy the “blocking” position, on the outer domain of actin, identified in earlier studies of regulated thin filaments in the low-Ca²⁺ state. In this position, Tm would sterically block myosin binding, switching off filament activity. At high Ca²⁺, Tm appeared to move toward a position on the inner domain, similar to that induced by Ca²⁺ in regulated thin filaments. This Ca²⁺-induced movement of Tm is consistent with the hypothesis that scallop thin filaments are Ca²⁺ regulated.     

Protein kinase A–dependent modulation of Ca2+ sensitivity in cardiac and fast skeletal muscles after reconstitution with cardiac troponin

Protein kinase A (PKA)-dependent phosphorylation of troponin (Tn)I represents a major physiological mechanism during β-adrenergic stimulation in myocardium for the reduction of myofibrillar Ca²⁺ sensitivity via weakening of the interaction with TnC. By taking advantage of thin filament reconstitution, we directly investigated whether or not PKA-dependent phosphorylation of cardiac TnI (cTnI) decreases Ca²⁺ sensitivity in different types of muscle: cardiac (porcine ventricular) and fast skeletal (rabbit psoas) muscles. PKA enhanced phosphorylation of cTnI at Ser23/24 in skinned cardiac muscle and decreased Ca²⁺ sensitivity, of which the effects were confirmed after reconstitution with the cardiac Tn complex (cTn) or the hybrid Tn complex (designated as PCRF; fast skeletal TnT with cTnI and cTnC). Reconstitution of cardiac muscle with the fast skeletal Tn complex (sTn) not only increased Ca²⁺ sensitivity, but also abolished the Ca²⁺-desensitizing effect of PKA, supporting the view that the phosphorylation of cTnI, but not that of other myofibrillar proteins, such as myosin-binding protein C, primarily underlies the PKA-induced Ca²⁺ desensitization in cardiac muscle. Reconstitution of fast skeletal muscle with cTn decreased Ca²⁺ sensitivity, and PKA further decreased Ca²⁺ sensitivity, which was almost completely restored to the original level upon subsequent reconstitution with sTn. The essentially same result was obtained when fast skeletal muscle was reconstituted with PCRF. It is therefore suggested that the PKA-dependent phosphorylation or dephosphorylation of cTnI universally modulates Ca²⁺ sensitivity associated with cTnC in the striated muscle sarcomere, independent of the TnT isoform.     

Photocrosslinking of benzophenone-labeled single cysteine troponin I mutants to other thin filament proteins

The interaction sites of rabbit skeletal troponin I (TnI) with troponin C (TnC), troponin T (TnT), tropomyosin (Tm) and actin were mapped systematically using nine single cysteine residue TnI mutants with mutation sites at positions 6, 48, 64, 89, 104, 121, 133, 155 or 179 (TnI6, TnI48 etc.). Each mutant was labeled with the heterobifunctional photocrosslinker 4-maleimidobenzophenone (BP-Mal), and incorporated into the TnI.TnC binary complex, the TnI.TnC.TnT ternary troponin (Tn) complex, and the Tn.Tm.F-actin synthetic thin filament. Photocrosslinking reactions carried out in the presence and absence of Ca(2+) yielded the following results: (1) BP-TnI6 photocrosslinked primarily to TnC with a small degree of Ca(2+)-dependence in all the complex forms. (2) BP-TnI48, TnI64 and TnI89 photocrosslinked to TnT with no Ca(2+)-dependence. Photocrosslinking to TnC was reduced in the ternary versus the binary complex. BP-TnI89 also photocrosslinked to actin with higher yields in the absence of Ca(2+) than in its presence. (3) BP-TnI104 and TnI133 photocrosslinked to actin with much higher yields in the absence than in the presence of Ca(2+). (4) BP-TnI121 photocrosslinked to TnC with a small degree of Ca(2+)-dependence, and did not photocrosslink to actin. (5) BP-TnI155 and TnI179 photocrosslinked to TnC, TnT and actin, but all with low yields. All the labeled mutants photocrosslinked to TnC with varying degrees of Ca(2+)-dependence, and none to Tm. These results, along with those published allowed us to construct a structural and functional model of TnI in the Tn complex: in the presence of Ca(2+), residues 1-33 of TnI interact with the C-terminal domain hydrophobic cleft of TnC, approximately 48-89 with TnT, approximately 90-113 with TnC's central helix, approximately 114-125 with TnC's N-terminal domain hydrophobic cleft, and approximately 130-150 with TnC's A-helix. In the absence of Ca(2+), residues approximately 114-125 move out of TnC's N-terminal domain hydrophobic cleft and trigger the movements of residues approximately 89-113 and approximately 130-150 away from TnC and towards actin.     

Structural Basis for the Activation of Muscle Contraction by Troponin and Tropomyosin

The molecular regulation of striated muscle contraction couples the binding and dissociation of Ca²⁺ on troponin (Tn) to the movement of tropomyosin on actin filaments. In turn, this process exposes or blocks myosin binding sites on actin, thereby controlling myosin crossbridge dynamics and consequently muscle contraction. Using 3D electron microscopy, we recently provided structural evidence that a C-terminal extension of TnI is anchored on actin at low Ca²⁺ and competes with tropomyosin for a common site to drive tropomyosin to the B-state location, a constrained, relaxing position on actin that inhibits myosin-crossbridge association. Here, we show that release of this constraint at high Ca²⁺ allows a second segment of troponin, probably representing parts of TnT or the troponin core domain, to promote tropomyosin movement on actin to the Ca²⁺-induced C-state location. With tropomyosin stabilized in this position, myosin binding interactions can begin. Tropomyosin appears to oscillate to a higher degree between respective B- and C-state positions on troponin-free filaments than on fully regulated filaments, suggesting that tropomyosin positioning in both states is troponin-dependent. By biasing tropomyosin to either of these two positions, troponin appears to have two distinct structural functions; in relaxed muscles at low Ca²⁺, troponin operates as an inhibitor, while in activated muscles at high Ca²⁺, it acts as a promoter to initiate contraction.     

Troponin Revealed: Uncovering the Structure of the Thin Filament On-Off Switch in Striated Muscle

Recently, our understanding of the structural basis of troponin-tropomyosin’s Ca²⁺-triggered regulation of striated muscle contraction has advanced greatly, particularly via cryo-electron microscopy data. Compelling atomic models of troponin-tropomyosin-actin were published for both apo- and Ca²⁺-saturated states of the cardiac thin filament. Subsequent electron microscopy and computational analyses have supported and further elaborated the findings. Per cryo-electron microscopy, each troponin is highly extended and contacts both tropomyosin strands, which lie on opposite sides of the actin filament. In the apo-state characteristic of relaxed muscle, troponin and tropomyosin hinder strong myosin-actin binding in several different ways, apparently barricading the actin more substantially than does tropomyosin alone. The troponin core domain, the C-terminal third of TnI, and tropomyosin under the influence of a 64-residue helix of TnT located at the overlap of adjacent tropomyosins are all in positions that would hinder strong myosin binding to actin. In the Ca²⁺-saturated state, the TnI C-terminus dissociates from actin and binds in part to TnC; the core domain pivots significantly; the N-lobe of TnC binds specifically to actin and tropomyosin; and tropomyosin rotates partially away from myosin’s binding site on actin. At the overlap domain, Ca²⁺ causes much less tropomyosin movement, so a more inhibitory orientation persists. In the myosin-saturated state of the thin filament, there is a large additional shift in tropomyosin, with molecular interactions now identified between tropomyosin and both actin and myosin. A new era has arrived for investigation of the thin filament and for functional understandings that increasingly accommodate the recent structural results.     

Role of the fetal and alpha/beta exons in the function of fast skeletal troponin T isoforms: correlation with altered Ca2+ regulation associated with development

In mammalian fast skeletal muscle, constitutive and alternative splicing from a single troponin T (TnT) gene produce multiple developmentally regulated and tissue specific TnT isoforms. Two exons, alpha (exon 16) and beta (exon 17), located near the 3' end of the gene and coding for two different 14 amino acid residue peptides are spliced in a mutually exclusive manner giving rise to the adult TnTalpha and the fetal TnTbeta isoforms. In addition, an acidic peptide coded by a fetal (f) exon located between exons 8 and 9 near the 5' end of the gene, is specifically present in TnTbeta and absent in the adult isoforms. To define the functional role of the f and alpha/beta exons, we constructed combinations of TnT cDNAs from a single human fetal fast skeletal TnTbeta cDNA clone in order to circumvent the problem of N-terminal sequence heterogeneity present in wild-type TnT isoforms, irrespective of the stage of development. Nucleotide sequences of these constructs, viz. TnTalpha, TnTalpha + f, TnTbeta - f and TnTbeta are identical, except for the presence or absence of the alpha or beta and f exons. Our results, using the recombinant TnT isoforms in different functional in vitro assays, show that the presence of the f peptide in the N-terminal T1 region of TnT, has a strong inhibitory effect on binary interactions between TnT and other thin filament proteins, TnI, TnC and Tm. The presence of the f peptide led to reduced Ca2+-dependent ATPase activity in a reconstituted thin filament, whereas the contribution of the alpha and beta peptides in the biological activity of TnT was primarily modulatory. These results indicate that the f peptide confers an inhibitory effect on the biological function of fast skeletal TnT and this can be correlated with changes in the Ca2+ regulation associated with development in fast skeletal muscle.     

Solution structure of the chicken skeletal muscle troponin complex via small-angle neutron and X-ray scattering

Troponin is a Ca2+-sensitive switch that regulates the contraction of vertebrate striated muscle by participating in a series of conformational events within the actin-based thin filament. Troponin is a heterotrimeric complex consisting of a Ca2+-binding subunit (TnC), an inhibitory subunit (TnI), and a tropomyosin-binding subunit (TnT). Ternary troponin complexes have been produced by assembling recombinant chicken skeletal muscle TnC, TnI and the C-terminal portion of TnT known as TnT2. A full set of small-angle neutron scattering data has been collected from TnC-TnI-TnT2 ternary complexes, in which all possible combinations of the subunits have been deuterated, in both the +Ca2+ and -Ca2+ states. Small-angle X-ray scattering data were also collected from the same troponin TnC-TnI-TnT2 complex. Guinier analysis shows that the complex is monomeric in solution and that there is a large change in the radius of gyration of TnI when it goes from the +Ca2+ to the -Ca2+ state. Starting with a model based on the human cardiac troponin crystal structure, a rigid-body Monte Carlo optimization procedure was used to yield models of chicken skeletal muscle troponin, in solution, in the presence and in the absence of regulatory calcium. The optimization was carried out simultaneously against all of the scattering data sets. The optimized models show significant differences when compared to the cardiac troponin crystal structure in the +Ca2+ state and provide a structural model for the switch between +Ca2+ and -Ca2+ states. A key feature is that TnC adopts a dumbbell conformation in both the +Ca2+ and -Ca2+ states. More importantly, the data for the -Ca2+ state suggest a long extension of the troponin IT arm, consisting mainly of TnI. Thus, the troponin complex undergoes a large structural change triggered by Ca2+ binding.     

Binding of troponin I and the troponin I-troponin C complex to actin-tropomyosin. Dissociation by myosin subfragment 1

Troponin I (TnI) is the component of the troponin complex, TnI, TnC, TnT, that is responsible for inhibition of actomyosin ATPase activity. Using the fluorescence of pyrene-labeled tropomyosin (Tm), we probed the interaction of TnI and TnIC with Tm on the reconstituted muscle thin filament. The results indicate that TnI and TnIC(-Ca(2+)) bind specifically and strongly to actin-Tm with a stoichiometry of 1 TnI or 1 TnIC/1 Tm/7 actin, in agreement with previous results. The binding of myosin heads (S1) to actin-Tm at low levels of saturation caused TnI and TnIC to dissociate from actin-Tm. These results are interpreted in terms of the S1-binding state allosteric-cooperative model of the actin-Tm thin filament, closed/open. Thus, TnI and TnIC(-Ca(2+)) bind to the closed state of actin-Tm and their binding is greatly weakened in the S1-induced open state, indicating that they act as allosteric inhibitors. The fluorescence change and the stoichiometry indicate that the TnI-binding site is composed of regions from both actin and Tm probably in the vicinity of Cys 190.     

Effects of troponin on thermal unfolding of actin-bound tropomyosin

Differential scanning calorimetry (DSC) was used to study the effect of troponin (Tn) and its isolated components on the thermal unfolding of skeletal muscle tropomyosin (Tm) bound to F-actin. It is shown that in the absence of actin the thermal unfolding of Tm is expressed in two well-distinguished thermal transitions with maxima at 42.8 and 53.8°C. Interaction with F-actin affects the character of thermal unfolding of Tm leading to appearance of a new Tm transition with maximum at about 48°C, but it has no influence on the thermal denaturation of F-actin stabilized by aluminum fluoride, which occurs within the temperature region above 70°C. Addition of troponin leads to significant increase in the cooperativity and enthalpy of the thermal transition of the actin-bound Tm. The most pronounced effect of Tn was observed in the absence of calcium. To elucidate how troponin complex affects the properties of Tm, we studied the influence of its isolated components, troponin I (TnI) and troponin T (TnT), on the thermal unfolding of actin-bound Tm. Isolated TnT and TnI do not demonstrate cooperative thermal transitions on heating up to 100°C. However, addition of TnI, and especially of TnT, to the F-actin–Tm complex significantly increased the cooperativity of the thermal unfolding of actin-bound tropomyosin.     

Time-dependent changes in expression of troponin subunit isoforms in unloaded rat soleus muscle

This study focuses on the effects ofmechanical unloading of rat soleus muscle on the isoform patterns ofthe three troponin (Tn) subunits: troponin T (TnT), troponin I (TnI),and troponin C (TnC). Mechanical unloading was achieved by hindlimbunloading (HU) for time periods of 7, 15, and 28 days. Relativeconcentrations of slow and fast TnT, TnI, and TnC isoforms wereassessed by electrophoretic and immunoblot analyses. HU inducedprofound slow-to-fast isoform transitions of all Tn subunits, althoughto different extents and with different time courses. The effectivenessof the isoform transitions was higher for TnT than for TnI and TnC.Indeed, TnI and TnC encompassed minor partial exchanges of slowisoforms with their fast counterparts, whereas the expression patternof fast TnT isoforms (TnTf) was largely increased after HU. Moreover, slow and fast isoforms of the different Tn were not affected in thesame manner by HU. This suggests that the slow and fast counterparts ofthe Tn subunit isoforms are regulated independently in response to HU.The changes in TnTf composition occurred in parallel with previouslydemonstrated transitions within the pattern of the fast myosin heavychains in the same muscles.