Nonpolymerizable Tropomyosin Research Articles

A specific C-terminal deletion in tropomyosin results in a stronger head-to-tail interaction and increased polymerization.

Tropomyosin is a 284 residue dimeric coiled-coil protein that interacts in a head-to-tail manner to form linear filaments at low ionic strengths. Polymerization is related to tropomyosin's ability to bind actin, and both properties depend on intact N- and C-termini as well as alpha-amino acetylation of the N-terminus of the muscle protein. Nalpha-acetylation can be mimicked by an N-terminal Ala-Ser fusion in recombinant tropomyosin (ASTm) produced in Escherichia coli. Here we show that a recombinant tropomyosin fragment, corresponding to the protein's first 260 residues plus an Ala-Ser fusion [ASTm(1-260)], polymerizes to a much greater extent than the corresponding full-length recombinant protein, despite the absence of the C-terminal 24 amino acids. This polymerization is sensitive to ionic strength and is greatly reduced by the removal of the N-terminal Ala-Ser fusion [nfTm(1-260)]. CD studies show that nonpolymerizable tropomyosin fragments, which terminate at position 260 [Tm(167-260) and Tm(143-260)], as well as Tm(220-284), are able to interact with ASTm(1-142), a nonpolymerizable N-terminal fragment, and that the head-to-tail interactions observed for these fragment pairs are accompanied by a significant degree of folding of the C-terminal tropomyosin fragment. These results suggest that the new C-terminus, created by the deletion, polymerizes in a manner similar to the full-length protein. Head-to-tail binding for fragments terminating at position 260 may be explained by the presence of a greater concentration of negatively charged residues, while, at the same time, maintaining a conserved pattern of charged and hydrophobic residues found in polymerizable tropomyosins from a variety of sources.

Production and crystallization of lobster muscle tropomyosin expressed in Sf9 cells

A new form of muscle tropomyosin crystal has been obtained, by employing new strategies in protein preparation and crystallization. Non-polymerizable tropomyosin was prepared by removing 11 amino acids at the C-terminus. The truncated tropomyosin was expressed in Sf9 insect cells by use of the baculovirus-based expression system, to obtain highly homogeneous protein preparations. By routinely monitoring homogeneity by mass spectrometry, we found that the homogeneity played a key role in obtaining good crystals. The crystal quality was also dependent on isoforms; the crystals raised from a slow muscle-specific isoform diffracted to a higher resolution, compared with a fast muscle-specific counterpart. For crystallization, a high concentration of organic solvent was used as the precipitant; in the presence of 35% DMSO, tetragonal crystals were formed, which belong to space group P4 3(1)2 12 with cell constants of a = b = 105.6 A ̊ , c = 506.9 A ̊ . The crystals gave rise to reflections the intensities of which were characteristically determined by the transform of α-helical coiled-coil. Thus in the region of 10-5.5 Å resolution along the c ∗- axis , the reflections were weak. For accurate measurement of these reflection intensities, beam-line ID2 in ESRF Grenoble was advantageous owing to the high brilliance and a low background. There the crystals diffracted to beyond 3.0 Å along the c ∗- axis , whereas along the a ∗–b ∗- plane reflections were limited to 6.6 Å. Data analysis is under way on a data set from a PtCl 4 derivative.

Effects of the amino-terminal regions of tropomyosin and troponin T on thin filament assembly.

Bacterially expressed alpha-tropomyosin lacks the amino-terminal acetylation present in muscle tropomyosin and binds poorly to actin (Hitchcock-DeGregori, S. E., and Heald, R. W. (1987) J. Biol. Chem. 262, 9730-9735). Using a linear lattice model, we determined the affinity (Ko) of unacetylated tropomyosin or troponin-unacetylated tropomyosin for an isolated site on the actin filament and the fold increase in affinity (y) when binding is to an adjacent site. The absence of tropomyosin acetylation decreased Ko 2 orders of magnitude in the absence of troponin. Tropomyosin acetylation also enhanced troponin-tropomyosin binding to actin, not by increasing cooperativity (y), but rather by increasing Ko. These results suggest that the amino-terminal region of tropomyosin is a crucial actin binding site. Troponin promoted unacetylated tropomyosin binding to actin, increasing Ko more than 1,000-fold. Troponin70-259, which lacks the troponin T peptide (1-69) spanning the overlap between adjacent tropomyosins, behaved similarly to intact troponin. Cooperative interactions between adjacent troponin-tropomyosin complexes remained strong despite the use of a nonpolymerizable tropomyosin and a troponin unable to bridge neighboring tropomyosins physically. The Ko for troponin70-259-unacetylated tropomyosin was 500-fold greater than for troponin159-259-unacetylated tropomyosin, indicating that troponin T residues 70-158 are critical for anchoring troponin-tropomyosin to F-actin. The mechanism of cooperative thin filament assembly is discussed.

The thermal denaturation of nonpolymerizable αα‐tropomyosin and its segments as a function of ionic strength

Nonpolymerizable tropomyosin (NPTm) is found to unfold thermally at high ionic strength almost exactly as the parent protein, but it does not aggregate at low ionic strength. Thus, NPTm can be used as a tropomyosin surrogate whose coiled-coil structural stability can be probed by varying the ionic strength. Studies of NPTm by CD show that increasing ionic strength stabilizes the coiled-coil structure. CD spectra over a wide range of helix content, obtained by varying either temperature or ionic strength, show an isodichroic point at 203 nm, suggesting a local, residue-level, two-state model. At given temperature, such a local helix in equilibrium random equilibrium suggests ln [phi h/(1-phi h)] = A1 + A2In, wherein phi h is the fraction helix, and A1, A2, and n are constants. In the low ionic strength region, theoretical limiting laws for ionic strength mediated charge-charge, dipole-dipole, and apolar-apolar (salting out) interactions give, respectively, n = 0.5, 1.0, and 1.0. Our experimental values for 40 degrees C, where the data span a wide range of helix content, show n = 1.0, suggesting that ionic strength stabilizes either by reducing dipole-dipole repulsions or by enhancing hydrophobic interactions, both probably interhelix in nature. Two segments of tropomyosin, 11Tm127 and 142Tm281, neither of which aggregate at low ionic strength, give results similar to those for NPTm, i.e., n = 0.96 and 0.84, respectively.

Removal of Tropomyosin Overlap Modifies Cooperative Binding of Myosin S-1 to Reconstituted Thin Filaments of Rabbit Striated Muscle

Cooperative binding of myosin S-1.ADP to regulated F-actin was previously reported and has been interpreted by a two-state model in which an important source of cooperativity is nearest neighbor interactions between the 7-actin.tropomyosin (TM).troponin units (functional units) (Hill, T.L., Eisenberg, E., and Greene, L. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 3186-3190). It has been postulated that the head-to-tail overlap between adjacent TM molecules is the structural basis of the nearest neighbor interactions. We tested the hypothesis by examining S-1.ADP binding to reconstituted regulated F-actin containing either intact TM or nonpolymerizable TM from which the COOH-terminal 11 residues were removed. In the absence of Ca2+, substitution of nonpolymerizable TM for TM reduced significantly the slope of the steeply rising phase of the sigmoidal S-1.ADP binding curve. Nevertheless, considerable residual cooperativity remained. Analysis of the data using the two-state model of Hill et al. suggests that removal of TM overlap abolishes nearest neighbor interactions, while the concerted change of the state of 7 actins in a functional unit can account for the residual cooperativity.

Effects of deletion of tropomyosin overlap on regulated actomyosin subfragment 1 ATPase

The role of the overlap region at the ends of tropomyosin molecules in the properties of regulated thin filaments has been investigated by substituting nonpolymerizable tropomyosin for tropomyosin in a reconstituted troponin-tropomyosin-actomyosin subfragment 1 ATPase assay system. A previous study [Heeley, Golosinka & Smillie (1987) J. Biol. Chem. 262, 9971-9978] has shown that at an ionic strength of 70 mM, troponin will induce full binding of nonpolymerizable tropomyosin to F-actin both in the presence and absence of calcium. At a myosin subfragment 1-to-actin ratio of 2:1 ([actin] = 4 microM) and an ionic strength of 50 mM, comparable levels of ATPase inhibition were observed with increasing levels of tropomyosin or the truncated derivative in the presence of troponin (-Ca2+). Large differences were noted, however, in the activation by Ca2+. Significantly lower ATPase activities were observed with nonpolymerizable tropomyosin and troponin (+Ca2+) over a range of subfragment 1-to-actin ratios from 0.25 to 2.5. The concentration of subfragment 1 required to generate ATPase activities exceeding those seen with actomyosin subfragment 1 alone under these conditions was 3-4-fold greater when nonpolymerizable tropomyosin was used. Similar effects were seen at the much lower ionic strength of 13 mM and are consistent with the reduced ATPase activity with nonpolymerizable tropomyosin observed previously [Walsh, Trueblood, Evans & Weber (1985) J. Mol. Biol. 182, 265-269] at low ionic strength and a subfragment 1-to-actin ratio of 1:100. Little cooperativity in activity as a function of subfragment 1 concentration with either intact tropomyosin or its truncated derivative was observed under the present conditions. Further studies are directed towards an understanding of these effects in terms of the two-state binding model for the attachment of myosin heads to regulated thin filaments.

Fluorescence titration and fluorescence stopped-flow studies of skeletal muscle troponin-nonpolymerizable tropomyosin complex.

The midpoint pCa value of the fluorescence titration curve of the complex of 2-[4'-iodoacetamido)anilino)-naphthalene-6-sulfonic acid-labeled troponin (IAANS-Tn) and nonpolymerizable tropomyosin (NPTm) was much larger than that for the complex of Tn containing dansylaziridine-labeled troponin C (DANZ-TnC) and NPTm. The midpoint was pCa 8.25 for the former protein and 6.80 for the latter protein in 0.1 M KCl, 50 mM Na-cacodylate-HCl (pH 7.0); and pCa 7.90 for the former protein and 6.70 for the latter protein in the presence of 3 mM MgCl2 in the same solvent system. The time course of the fluorescence intensity change of the protein complex subsequent to rapid decrease of free Ca2+ concentration of the solution was measured with a stopped-flow spectrophotometer: The process was exponential and its rate constant was 9.9 s-1 for IAANS-Tn-NPTm at pCa 8.95 and 26.6 s-1 for Tn(DANZ-TnC)-NPTm at pCa 8.99 in the absence of MgCl2 in the same solvent system as in the fluorescence titration experiment. IAANS binds to Cys-133 of TnI and DANZ to Met-25 in the low affinity Ca2+-binding sites of TnC. These results suggest that IAANS bound to Cys-133 of TnI does not directly detect the Ca2+-binding to the low affinity Ca2+-binding site of TnC, but does detect the conformational change of the Tn-NPTm complex induced by the Ca2+-binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Electric birefringence studies of rabbit skeletal tropomyosin.

AbstractThe electric birefringence of rabbit skeletal tropomyosin and its nonpolymerizable derivative was studied as a function of protein concentration, pulse length, and electric field strength. Analyses of the zero field birefringence decay curves show that nonpolymerizable tropomyosin, which has had on average six C‐terminal residues removed, and tropomyosin are both well approximated by rigid cylinders in solution at low salt concentrations at 20°C. The measured relaxation times for the monomers of polymerizable and nonpolymerizable tropomyosin are 1.5 ± 0.4 μs and 1.30 ± 0.2 μs, respectively, in good agreement with the values calculated from the known dimensions. For tropomyosin the electrical pulse induces the formation of linear dimers. Orientation occurs primarily by a permanent dipole mechanism. Permanent and induced dipole moments were calculated from reversing field experiments and from the saturation of the birefringence. Removal of the six C‐terminal residues decreases the measured permanent dipole moment by 9.5%, from 6300 to 5700 Debyes, which is in good agreement with the 7% decrease calculated for permanent dipole contributions arising from the peptide dipoles and from the asymmetric distribution of the formal charges. This change is due primarily to the removal of Asp 280.

The effects of troponin T fragments T1 and T2 on the binding of nonpolymerizable tropomyosin to F-actin in the presence and absence of troponin I and troponin C.

Using a nonpolymerizable form of tropomyosin (NPTM) we have investigated the interactions between the T1 (residues 1-158) and T2 (residues 159-259) regions of troponin T and the other components of the thin filament at 50 mM KCl +/- Ca2+. Under these conditions the binding of NPTM to F-actin is fully restored by whole troponin (+/- Ca2+), and in each case, retains a residual degree of cooperativity as demonstrated by Scatchard and Hill plots. Fragment T2 alone had a small inductive effect on the interaction of NPTM with F-actin. In the presence of troponin I, this interaction is increased to a level which exceeds that observed with either component alone. The effects of T2 and troponin I are moderately (-Ca2+) and markedly (+Ca2+) reduced by troponin C. While fragment T1 alone did not promote induction, it accentuated the effects of T2 and troponin I. Since T1 does not interact with T2 or troponin I but does interact weakly with the NH2 terminus of tropomyosin and can be expected to bind weakly at the residual interaction site(s) at the COOH terminus of NPTM, the observed effects of T1 have been ascribed to the linking of neighboring NPTM molecules at their ends.

Induction of nonpolymerizable tropomyosin binding to F-actin by troponin and its components.

Nonpolymerizable tropomyosin, in which 11 residues have been quantitatively cleaved from the COOH terminus of muscle tropomyosin (TM) by enzymic digestion, does not bind to F-actin. Binding is restored in the presence of troponin (Tn) and absence of Ca2+. The binding is stronger than for intact TM alone and shows residual cooperativity. In the presence of Ca2+, the binding is at least 10-fold weaker and cooperativity is not observed. Tn-T alone is more effective than Tn-I alone in inducing nonpolymerizable TM binding. Tn-T plus Tn-I induce binding as effectively as whole Tn (without Ca2+). In the absence of Ca2+, Tn-T + Tn-C and Tn-I + Tn-C are more effective in promoting binding than in the presence of Ca2+. These observations emphasize the importance of the head to tail overlap region of TM in the cooperative interactions of the thin filament assembly. The effects of Ca2+ are largely understandable in terms of its known effects on the strength of interactions between Tn-I and TM + actin and between Tn-T and TM. The residual cooperativity observed in nonpolymerizable TM binding in the presence of Tn (without Ca2+) may indicate that the T1 fragment region (residues 1-158) of Tn-T spans the head to tail overlap gap between the neighboring nonpolymerizable TM molecules. Alternatively, or in addition, the cooperativity may arise from conformational changes transmitted through actin from one nonpolymerizable TM-Tn binding site to others.

The effect of cytochalasin and glutaraldehyde on F-actin filaments containing muscle and non-muscle tropomyosin.

F-actin filaments are disrupted by the action of cytochalasin and glutaraldehyde. Muscle tropomyosin which is able to polymerize can protect F-actin against fragmentation caused by these two agents. This protective effect does not occur with nonpolymerizable, brain or carboxy-peptidase A-treated skeletal muscle tropomyosins. The protection of F-actin against the action of cytochalasin and glutaraldehyde takes place under conditions where the F-actin filaments are saturated with tropomyosin, that is, at a molar ratio of tropomyosin to actin of 1:7. It is suggested that nonpolymerizable tropomyosin lacks the protective ability because its binding to F-actin is considerably weaker than the polymerizable tropomyosin and does not saturate all of the binding sites on F-actin.

Structural interpretation of the two-site binding of troponin on the muscle thin filament

Conditions are described for the quantitative removal of amino acid residues 274 to 284 from rabbit muscle α-tropomyosin with carboxypeptidase A. The product, non-polymerizable tropomyosin, has a much reduced affinity for the tropomyosinbinding fragment CB1 (residues 1 to 151) of troponin-T. Iodination of α-tropomyosin and non-polymerizable tropomyosin by 125I and lactoperoxidase was carried out in the presence and absence of CB1. Following tryptic digestion and peptide mapping, the radioactivities of the labeled tyrosine peptides were compared. In the presence of CB1, tyrosine residues 261 and 267 were iodinated only to the extent of 30 to 40% as compared with the same tyrosine residues in the absence of CB1, All other tyrosine residues (60, 162, 214 and 221) were iodinated to a similar level in the absence or presence of CB1. With non-polymerizable tropomyosin, the presence of CB1 had a much reduced effect on the level of labeling of the tyrosine residues. We conclude that the highly helical region of troponin-T (residues 71 to 151) binds close to or at the COOH-terminal end of the tropomyosin molecule. Taken together with other considerations and recent observations, the results can be interpreted in terms of the two-site model for troponin attachment to the thin filament. A calcium-insensitive site would involve interaction of the highly helical CB2 region of troponin-T (residues 71 to 151) and the COOH-terminal region of tropomyosin (residues 258 to 284) and perhaps the NH 2-terminal overlap region (residues 1 to 9). A calcium-sensitive site would involve the interaction of troponin-T in the neighborhood of cysteine 190 of tropomyosin in F-actin-tropomyosin assemblies both directly and indirectly through the association of its COOH and NH 2-terminal regions with the troponin-I and C components.

Non-polymerizable tropomyosin: Preparation, some properties and F-actin binding

Summary Conditions are described for the nearly quantitative removal of residues 274–284 from the COOH-terminus of rabbit cardiac tropomyosin. The product is monomeric (Mr = 64,000) even at low ionic strength. The circular dichroism melting profile is only marginally different from the intact protein. The failure of the non-polymerizable tropomyosin to bind to F-actin, even at elevated MgCl2 concentrations, illustrates the importance of the head-to-tail interaction of tropomyosin molecules in their cooperative binding to the thin filament structure.

Properties of non-polymerizable tropomyosin obtained by carboxypeptidase A digestion.

Tropomyosin digested with carboxypeptidase A [EC 3.4.12.2] (CTM) shows a lower viscosity than the undigested protein in solution. From the relation between the viscosity decrease and the amount of amino acids liberated from the carboxyl terminus during this digestion, it is inferred that loss of the tri-peptide-Thr-Ser-Ile from the C-terminus is responsible for the decrease in viscosity. The secondary structure of -TM was not affected by the digestion according to circular dichroic measurements. The viscosity of CTM did not increase in methanol-water mixtures, whereas that of tropomyosin increased markedly. These results indicate that polymerizability was lost upon the removal of a small peptide from the C-terminus without change in the secondary structure. A decrease in the viscosity of tropomyosin solutions was observed on the addition of CTM, indicating that CTM interacts with intact tropomyosin. The dependence of the viscosity decrease on the amount of CTM showed that CTM binds tropomyosin in a one-to-one ratio as a result of end-to-end interaction. Since paracrystals having a 400 A repeated band structure could be grown in the presence of Mg ions at neutral pH, side-by-side interactions in CTM molecules remain intact, even though polymerizability is lost. The disc gel electrophoretic pattern showed that troponin could bind to CTM, but no increase in viscosity due to the complex was observed in solution. That is, the C-terminal part of tropomyosin is not required for the formation of the complex. The amount of CTM bound to F-actin was less than half of that bound to undigested tropomyosin, and could be reduced to one-tenth by a washing procedure. In the presence of troponin, however, the amount recovered to the level of tropomyosin normally bound to F-actin. Therefore, it is concluded that troponin is bound in the middle of the tropomyosin molecule and strengthens the binding of tropomyosin to F-actin.

Non-polymerizable Tropomyosin and Control of the Superprecipitation of Actomyosin

Non-polymerizable tropomyosin was prepared by the digestion of several C-terminal residues of tropomyosin with carboxypeptidase A [EC 3.4.12.2]. The intrinsic viscosity and molecular weight of the non-polymerizable tropomyosin were almost the same as those of untreated tropomyosin. Like untreated tropomyosin, the non-polymerizable tropomyosin in combination with troponin repressed the superprecipitation of actomyosin in the absence of calcium, while this repression was released by addition of calcium. However, the curve representing the superprecipitation rate as a function of pCa was less steep than that found with actomyosin containing untreated tropomyosin: in the former case, the rate increased to a plateau over about 2 pCa units, while in the latter case, it did so over about 1 pCa unit. These experimental results provide evidence that the "co-operation" in the regulation mechanism of skeletal muscle contraction, which is indicated by the steep curve of the contraction versus pCa relation, is mediated by tropomyosin-tropomyosin interaction along the thin filament.