Tropomyosin: a new asymmetric protein component of the muscle fibril

Affinity and structure of complexes of tropomyosin and caldesmon domains

The interaction of caldesmon domains with tropomyosin has been studied using x-ray crystallography and an optical biosensor. Only whole caldesmon and the carboxyl-terminal domain of caldesmon (CaD-4, chicken gizzard residues 597-756) bound to tropomyosin with greater than millimolar affinity at 100 and 150 microM salt. Under these conditions the affinities of whole caldesmon and CaD-4 were both in the micromolar range. Data from the x-ray studies showed that whole caldesmon bound to tropomyosin in several places, with the region of tightest interaction being at tropomyosin residues 70-100 and/or 230-260. Studies with CaD-4 revealed that this region corresponded to the strong binding site seen with whole caldesmon. Weaker association of other regions of caldesmon to tropomyosin residues 180-210 and 5-50 was also observed. The results suggest that the carboxyl-terminus of caldesmon binds tightly to tropomyosin and that other regions of caldesmon may interact with tropomyosin tightly only when they are held close to tropomyosin by the carboxyl-terminal domain. Four models are presented to show the possible interactions of caldesmon with tropomyosin.

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(1)2 with cell constants of a=b=105.6 angstrom, c=506.9 angstrom. The crystals gave rise to reflections the intensities of which were characteristically determined by the transform of alpha-helical coiled-coil. Thus in the region of 10-5.5 angstrom resolut 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 A along the c*-axis, whereas along the a*-b*-plane reflections were limited to 6.6 angstrom. Data analysis is under way on a data set from a PtCl4 derivative.

Location of smooth-muscle myosin and tropomyosin binding sites in the C-terminal 288 residues of human caldesmon

We have produced nine recombinant fragments, H1 to H9, from a human cDNA that codes for the C-terminal 288 residues of caldesmon. The fragment H1, encompassing the 288 residues, is equivalent to domains 3 and 4 of caldesmon (amino acids 506-793 in human, 476-737 in the chicken gizzard sequence). It has been shown [Huber, Redwood, Avent, Tanner and Marston (1993) J. Muscle Res. Cell Motil. 14, 385-391] to bind to actin, Ca(2+)-calmodulin, tropomyosin and myosin. The fragments, H2 to H9, differ in length between 60 and 176 residues and cover the whole of domains 3 and 4 with many of the fragments overlapping. We have characterized the myosin and tropomyosin binding of these fragments. The binding of both tropomyosin and myosin is highly dependent on salt concentration, indicating the ionic nature of these interactions. The location of the myosin binding is an extended region encompassing the junction of domains 3/4 and domain 4a (residues 622-714, human; 566-657, chicken gizzard). Tropomyosin binds in a smaller region within domain 4a of caldesmon (residues 663-714, human; 606-657 chicken gizzard). We confirmed predictions based on sequence similarities of a tropomyosin binding site in domain 3 of caldesmon; however, this site bound to skeletal-muscle tropomyosin and had little affinity for the smooth-muscle tropomyosin isoform. None of the protein fragments H2-H9 retained the affinity of the parent fragment H1 for either myosin or tropomyosin. This indicates the need for several interaction sites scattered over an extended region to attain higher affinity. The regions interacting with caldesmon in both tropomyosin and myosin are coiled-coil structures. This is probably the reason for their shared interaction sites on caldesmon and their similar natures of binding.

Characterisation of fast, slow and cardiac muscle tropomyosins from salmonid fish

Tropomyosin (TM) has been isolated from the cardiac muscle, and fast and slow trunk (myotomal) muscles of the mature salmonid fish Atlantic salmon (Salmo salar) and rainbow trout (Salmo gairdneri). When examined electrophoretically, isoforms of TM were detected which were specific, and exclusive, to each type of muscle. Cardiac and fast muscles contained single and distinct isoforms, while slow muscle contained two distinct isoforms, closely related in terms of apparent M(r), and pI. There was no detectable difference between the same TM type from either salmon or trout. On a variety of gel systems, the cardiac and slow isoforms migrated in close proximity to each other and to rabbit alpha-TM. The fast isoform comigrated with rabbit beta-TM. In developing salmon fry, a more acidic (unphosphorylated) variant of TM was present in addition to, and of similar M(r) to, the fast adult isoform. This TM declined in steady-state level during maturation and was virtually undetected in adult muscle. All of the isolated TMs contained little or no covalently bound phosphate and were blocked at the N-terminus. The amino acids released by carboxypeptidase A, when ordered to give maximal similarity to other muscle TMs, were consistent with the following sequences: fast (LDNALNDMTSI) and cardiac (LDHALNDMTSL). The C-terminal region of the slow TM contained His but was heterogeneous. In viscosity measurements, performed as a function of increasing protein concentration, at low ionic strength (t = 5 degrees C, pH 7.00), fast TM exhibited the highest relative viscosity values. Lower and equivalent levels of polymerisation occurred with the cardiac and slow TMs. Polymerisation of all three isoforms was temperature-dependent, with cardiac TM being least sensitive and fast TM being most sensitive. Determination of the complete coding sequence of adult fast TM confirmed the findings of the carboxypeptidase analysis, but the remainder of the sequence more closely resembled alpha-type TMs than beta-type TMs. Overall, salmon fast TM contains 20 (mostly conservative) substitutions compared to rabbit striated muscle alpha-TM and 40 (mostly conservative) substitutions compared to rabbit striated muscle beta-TM. This demonstrates that electrophoretic mobility is not, in all instances, a suitable method to assess the isomorphic nature of striated muscle TMs.

Flexibility of actin filaments derived from thermal fluctuations. Effect of bound nucleotide, phalloidin, and muscle regulatory proteins

Single actin filaments undergoing brownian movement in two dimensions were observed at 20 degrees C in fluorescence optical video microscopy. The persistence length (Lp) was derived from the analysis of either the cosine correlation function or the average transverse fluctuations of a series of recorded shapes of filaments assembled from rhodamine-action. Phalloidin-stabilized filaments had a persistence length of 18 +/- 1 micron, in agreement with recent observations. In the absence of phalloidin, rhodamine-labeled filaments could be observed under a variety of solution conditions once diluted in free unlabeled G-actin at the appropriate critical concentration. Such nonstabilized F-ADP-actin filaments had the same Lp of 9 +/- 0.5 microns, whether they had been assembled from ATP-G-actin or from ADP-G-actin, and independently of the tightly bound divalent metal ion. In the presence of BeF3-, which mimics the gamma-phosphate of ATP, F-ADP-BeF3-actin was appreciably more rigid, with Lp = 13.5 microns. Hence, newly formed F-ADP-Pi-actin filaments are more rigid than "old" F-ADP-actin filaments, a fact which has implications in actin-based motility processes. In the presence of skeletal tropomyosin and troponin, filaments were rigid (Lp = 20 +/- 1 micron) in the off state (-Ca2+), and flexible (Lp = 12 microns) in the on state (+Ca2+), consistent with the steric blocking model. In agreement with x-ray diffraction data, no appreciable difference was recorded between the off and on states using smooth muscle tropomyosin and caldesmon (Lp = 20 +/- 1 micron). In conclusion, this method allows accurate measurement of small (< or = 15%) changes in mechanical properties of actin filaments in correlation with their biological functions.

Transient kinetic analysis of rhodamine phalloidin binding to actin filaments

We have characterized the binding of rhodamine phalloidin to actin filaments and actin filaments saturated with either myosin subfragment-1 or tropomyosin in 50 mM KCl, 1 mM MgCl2 buffer at pH 7.0. Direct transient kinetic measurements of rhodamine phalloidin binding to actin filaments indicate an association rate constant of 2.8 x 10(4) M-1 s-1 and a dissociation rate constant of 4.8 x 10(-4) s-1. The ratio of the rate constants yields a dissociation equilibrium constant of 17 nM. From equilibrium measurements, the apparent affinity of rhodamine phalloidin for actin filaments is 116 nM. The difference between the affinities determined by equilibrium and kinetic experiments is attributed to the depolymerization of filaments at low actin concentrations in the equilibrium samples. The binding stoichiometry is one rhodamine phalloidin molecule per actin subunit. When myosin subfragment-1 and tropomyosin are bound to actin filaments, the rate constants for rhodamine phalloidin binding are the same as for actin alone and in agreement with the binding affinities measured in equilibrium experiments. Presumably these proteins stabilize the filaments. Neither substitution of CaCl2 for MgCl2 nor the inclusion of 20 mM phosphate altered the rate or equilibrium constants.

cAMP and bFGF negatively regulate tropomyosin expression in rat cultured astroblasts

We have examined the expression of tropomyosin (TM) messenger RNAs (mRNAs) and protein isoforms in primary cultures of rat astroblasts during morphological changes. Three messenger RNA bands of 2.5, 1.8 and 1.2 kilobase pairs (kb) were detected by Northern blot. Using an antibody cross-reacting with all tropomyosin isoforms, we found that rat cerebellar neonatal astroblasts expressed three tropomyosin protein isoforms termed TM-As1, TM-As2 and TM-As3 (As for Astroblast) with respective molecular masses of 38,000, 33,000 and 31,000. Treatment of cells with agents which promote or mimick the action of cyclic AMP, or with growth factors, is known to induce astroblast morphological alteration from flat, polygonal epitheloid cells into star-shaped, process-bearing cells. In the presence of dibutyryl cAMP (dBcAMP), forskolin or basic fibroblast growth factor (bFGF), these morphological changes were found to be associated with dramatic decreases of the three mRNA transcripts and also of the three protein isoforms. This decrease was reversed upon removal of the drugs. The pattern of the tropomyosin protein isoforms in cultured astroblasts showed that TM-Asl, the most immunoreactive isoform recovered in the cytoskeletal insoluble cell fraction, had a developmental profile similar to that of F-actin. Therefore this isoform, which belongs to the high-molecular-mass family of proteins known to interact strongly with F-actin, could specifically be involved in the regulation/control of F-actin stability and thus be associated with the plasticity of astroblasts.

A new crystal form of tropomyosin

Tropomyosin crystals with a new morphology have been obtained from lobster tail muscle tropomyosin from which 11 residues at the carboxyl-terminus have been proteolytically removed to avoid head-to-tail polymerization. In contrast to the conventional Bailey crystal form in which the elongated tropomyosin molecules form a mesh, in the present crystals the molecules are packed side-to-side with the long axes parallel to the c-axis of the crystal. The unit cell is tetragonal with a = b = 109 A, c = 509 A, and the symmetry is either P4(1)2(1)2 or P4(3)2(1)2, with 4(1)(4(3)) helical axes parallel to the c-axis. This suggests that a group of molecules surrounding a local 4(1)(4(3)) axis is regarded as the building unit of the crystal. It is likely that the unit cell contains eight molecules with one molecule per asymmetric unit.

Diffuse x-ray scattering from tropomyosin crystals

Diffuse scattering analyses are emerging as a technique to extract additional dynamic information from x-ray diffraction data. In fact, when examined carefully, most protein crystals show significant diffuse scattering in addition to the usual Bragg diffraction. This diffuse scattering contains information about the disorder in the crystal that cannot be obtained from the Bragg diffraction data. Diffraction from tropomyosin crystals shows characteristic diffuse scattering streaks that are directly related to motion of the molecules. The structure of tropomyosin to 15 A resolution shows that the limited molecular contacts between molecules allow large conformational fluctuations of up to 8 A amplitude. Models for the three-dimensional motion of tropomyosin have been tested by comparing their predicted diffuse scattering patterns with the experimental data. From the parameters of the successful simulations, we were able to determine the amplitudes, directions, and distances over which the atomic displacements are correlated.

Heat-treated smooth muscle tropomyosin

Gizzard smooth muscle tropomyosin, which is close to 100% gamma beta heterodimer in the native state, was heated to about 100 degrees C, at which temperature the chains are dissociated, followed by reassociation by rapid cooling to 0 degree C. This heat-treated tropomyosin was composed of about 58% heterodimer and 42% of the gamma gamma and beta beta homodimers and had a lower viscosity than that of the native protein, indicating a reduced end-to-end polymerization. Close to 100% heterodimer was regenerated if the heat-treated tropomyosin was subjected to slow cooling from 50 degrees C. However, the viscosity remained low and did not return to the value for untreated tropomyosin, suggesting that the 100 degrees C treatment results in irreversible chemical damage to tropomyosin which affects its end-to-end interaction. Therefore, heat treatment of tropomyosin, a procedure widely used in the preparation of smooth muscle and non-muscle tropomyosins, may result in tropomyosin with a different heterodimer/homodimer distribution and different properties from those of the native protein and should be used with caution.

Tropomodulin binding to tropomyosins. Isoform-specific differences in affinity and stoichiometry

Tropomodulin is a human erythrocyte membrane cytoskeletal protein that binds to one end of tropomyosin molecules and inhibits tropomyosin binding to actin filaments [Fowler, V. M. (1990) J. Cell Biol. 111, 471-482]. We have characterized the interaction of erythroid and non-erythroid tropomyosins with tropomodulin by non-denaturing gel electrophoresis and by solid-phase binding assays using 125I-tropomyosin. Non-denaturing gel analysis demonstrates that all tropomodulin molecules are able to bind tropomyosin and that tropomodulin forms complexes with tropomyosin isoforms from erythrocyte, brain, platelet and skeletal muscle tissue. Scatchard analysis of binding data using tropomyosin isoforms from these tissues indicate that tropomodulin binds preferentially to erythrocyte tropomyosin. Specificity is manifested by decreases in the apparent affinity or the saturation binding capacity of tropomodulin for non-erythrocyte tropomyosins. Erythrocyte tropomyosin saturates tropomodulin at approximate stoichiometric ratios of 1:2 and 1:4 tropomyosin/tropomodulin (apparent Kd = 14 nM-1 and 5 nM-1, respectively). Brain tropomyosin saturates tropomodulin at a 1:2 ratio of tropomyosin/tropomodulin, but with a threefold lower affinity than erythrocyte tropomyosin. Platelet tropomyosin saturates tropomodulin at a tropomyosin/tropomodulin ratio of 1:4, but with a sevenfold lower affinity than erythrocyte tropomyosin at the 1:4 ratio. These results correlate with oxidative cross-linking data which indicate that tropomodulin can self-associate to form dimers and tetramers in solution. Since tropomodulin interacts with one of the ends of tropomyosin, varying interactions of tropomyosin isoforms with tropomodulin probably reflect the heterogeneity in N-terminal or C-terminal sequences characteristic of the different tropomyosin isoforms. Isoform-specific interactions of tropomodulin with tropomyosins may represent a novel mechanism for selective regulation of tropomyosin/actin interactions.

Actin mediated regulation of muscle contraction

Striated and smooth muscles have different mechanisms of regulation of contraction which can be the basis for selective pharmacological alteration of the contractility of these muscle types. The progression in our understanding of the tropomyosin-troponin regulatory system of striated muscle from the early 1970s through the early 1990s is described along with key concepts required for understanding this complex system. This review also examines the recent history of the putative contractile regulatory proteins of smooth muscle, caldesmon and calponin. A contrast is made between the actin linked regulatory systems of striated and smooth muscle.

The chicken gene encoding the alpha isoform of tropomyosin of fast-twitch muscle fibers: organization, expression and identification of the major proteins synthesized

The chicken gene alpha fTM encoding the alpha-tropomyosin of fast-twitch muscle fibers (alpha fTM) covers 20 kb and consists of 15 exons. From this gene, three types of mature transcripts (1.3 kb, 2 kb and 2.8 kb) are expressed through the use of alternative promoters, alternatively spliced exons and multiple 3' end processing. Northern analysis and S1 mapping have shown that the 1.3-kb transcript (exons 1a, 2b, 3, 4, 5, 6b, 7, 8, 9a-9b) is expressed in fast-twitch skeletal muscles and that 2-kb transcripts are expressed in smooth muscle (exons 1a, 2a, 3, 4, 5, 6b, 7, 8, 9d) and in fibroblasts (exons 1a, 2b, 3, 4, 5, 6a or 6b, 7, 8, 9d). These 2-kb transcripts encode distinct proteins which we have identified by two-dimensional (2D) gel electrophoresis. The 2.8-kb transcript which has not been so far characterized in birds is expressed in brain (exons 1b, 3, 4, 5, 6b, 7, 8, 9c-9d). This transcript has been characterized by a cDNA polymerase chain reaction assay and by S1 nuclease mapping. It produces a major TM isoform of chick brain which we have identified by 2D gels.

Ca2+ and activation mechanisms in skeletal muscle

It has been known for a number of years that calcium ions play a crucial role in excitation-contraction (e-c) coupling (Sandow, 1952). The majority of the calcium required for this process is derived, at least in vertebrate striated muscle fibres, from discrete intracellular stores located at sites within the cell: the terminal cysternae (tc)/junctional SR of the sarcoplasmic reticulum (SR) (Fig. 1 a). These storage sites not only form a compartment that is distinct from the sarcoplasm of the fibre, but they are also closely associated with the contractile elements, the myofibrils. The SR release sites are activated following the spread of electrical activity (Huxley and Taylor, 1958) along the transverse (T) tubular system (Eisenberg and Gage, 1967; Adrian et al. 1969a, b; Peachey, 1973) from the surface membrane (Bm).

Immunoelectron microscopic observations on tropomyosin localization in striated muscle

Tropomyosin localization in striated muscle was studied by means of immunoelectron microscopy. Polyclonal and monoclonal antibodies to tropomyosin were allowed to diffuse into mechanically skinned single fibres dissected from frog semitendinosus muscle. Antibodies produced transverse I-band stripes with the expected periodicity of 38 nm. However, some differences were revealed among the various antibodies. While polyclonal antibodies generally showed 23 stripes, monoclonal antibodies showed an extra 24th stripe immediately adjacent to the Z-line, implying some structural/functional uniqueness of this terminal tropomyosin. Furthermore, the stripes did not always lie parallel to the Z-line. When the Z-line was straight or slightly skewed, the stripes generally were parallel to it. However, when Z-line skew was more severe, the stripes remained perpendicular to the fibre axis, indifferent to the Z-line skew. This may implay that the coupling of tropomyosin to the thin filament is not tight. Finally, the monoclonal antibodies themselves exerted an anomalous effect on the Z-line, apparently extracting or shifting some of its mass.

Zero-length crosslinking procedure with the use of active esters

A two-step zero-length crosslinking procedure for studying protein-protein complexes has been developed. One component of a complex is briefly incubated with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) in the presence of N-hydroxysuccinimide resulting in the conversion of some of the protein carboxyls into succinimidyl esters. The reaction is stopped by addition of beta-mercaptoethanol and other interacting proteins are then added. Crosslinking arises from substitution of lysine epsilon-amino groups of these proteins for the succinimidyl moieties during a 1- to 2-h incubation period. The advantage of this method versus one-step zero-length crosslinking is that only one component of the complex is exposed to the crosslinker, which eliminates complications arising from the formation of crosslinks among several proteins of a multicomponent complex. Furthermore, crosslinks can be formed even in the presence of reagents, such as dithiothreitol and EDTA, that would interfere with direct crosslinking with EDC.

Uncoupling of muscle-specific protein expression in myocyte x myoblast heterokaryons

The inducibility of several rat skeletal muscle proteins was examined in heterokaryons formed by fusing differentiated chick myocytes to undifferentiated rat myoblasts. Chicken and rat proteins were distinguished using species-specific antibodies or by their different migrations in polyacrylamide or agarose gels. Both rat skeletal myosin light chain 1 and rat alpha-tropomyosin were induced in the heterokaryons. In contrast, neither rat acetylcholine receptors nor creatine kinase could be detected. These results suggest that chick myocytes may contain quantities of regulatory factors that are sufficient for the activation of some but not all of these rat muscle-specific proteins within the cellular context of the heterokaryon.

Schistosoma mansoni tropomyosin: cDNA characterization, sequence, expression, and gene product localization

We have defined the polypeptide pattern of 3-hr Schistosoma mansoni schistosomula on nonequilibrium two-dimensional gels (NEPHGE). An acidic group of polypeptides with a molecular weight of about 40 kDa and a pI value of around 5.0 (numbered 48/59/53) were identified as antigens on Western blots probed with chronic human infection sera or vaccinated mouse sera. Polypeptides 48/49/53 from silver-stained NEPHGE gels produced antisera that were specific as demonstrated by Western blot analysis and immunoprecipitations of in vitro translation products. A cDNA clone (clone 1) from a S. mansoni adult worm pBR322 library was isolated by using cDNA probes made from size-fractionated mRNA and defined as encoding polypeptide 49 by hybridization selection of the mRNA which was in vitro translated and immunoprecipitated with specific mouse antiserum. A lambda gt 11 expression clone which contained an insert close to the full length mRNA was isolated from a S. mansoni cercariae library. The complete sequence of the mRNA was determined by sequencing the insert of this clone as well as primer extension of total RNA. The only open reading frame coding for 284 amino acids in the 1316 nucleotide sequence showed a 44.76 to 55.44% homology with the amino acid sequences of 18 different tropomyosins from various species. Computer-predicted secondary structure of schistosome tropomyosin was mainly alpha-helix which was very similar to other tropomyosins. Northern analysis showed the mRNA to be about 1.5 kb in size and detectable at much higher levels in the adult worm stage as compared to the cercariae and the egg stages. Western blot analysis likewise showed that greater amounts of tropomyosin were detected in extracts from adult worm stage as compared to extracts from cercariae and egg stages. Immunocytochemical analysis shows that tropomyosin is strongly associated with the tegument of adult worms. The restriction digestion pattern given by genomic Southern analysis suggests the existence of introns and/or multiple gene copies. Thus polypeptide 49, an immunodominant antigen, represents schistosome tropomyosin.

Binding of adenylosuccinate synthetase to contractile proteins of muscle

The muscle isozyme of adenylosuccinate synthetase (AdSS), an enzyme of the purine nucleotide cycle, has previously been shown to bind to purified F-actin in buffers of low ionic strength and pH (Ogawa et al. Eur. J. Biochem. 85: 331-338, 1978). We have extended these observations by measuring the association of both crude and purified AdSS with the contractile proteins of muscle in buffers of physiological ionic strength and pH. Under these conditions, the enzyme binds to F-actin, actin-tropomyosin complexes, reconstructed thin filaments, and myofibrils but not to myosin. The apparent dissociation constant of 1.2 microM and binding maximum of 2.6 nmol enzyme/mg myofibrils indicate that binding of AdSS to myofibrils can be physiologically significant. The results suggest that AdSS in muscle may be associated with the thin filament of myofibrils.

The Drosophila melanogaster tropomyosin II gene produces multiple proteins by use of alternative tissue-specific promoters and alternative splicing

The structure of the Drosophila melanogaster tropomyosin II (TmII) gene has been determined by DNA sequencing of cDNA clones and the genomic DNA coding for the gene. Two overlapping transcriptional units produce at least four different tropomyosin isoforms. A combination of developmentally regulated promoters and alternative splicing produces both muscle and cytoskeletal tropomyosin isoforms. One promoter is a muscle-specific promoter and produces three different tropomyosin isoforms by alternative splicing of the last three 3' exons. The second promoter has the characteristics of a housekeeping promoter and produces a cytoskeletal tropomyosin isoform. Several internal exons along with a final 3' exon are alternatively spliced in the cytoskeletal transcript. The intron-exon boundaries of the TmII gene are identical to the intron-exon boundaries of all vertebrate tropomyosin genes reported, but are very different from the intron-exon boundaries of the D. melanogaster tropomyosin I gene. The TmII gene is the only reported tropomyosin gene that has two promoters and a quadruple alternative splice choice for the final exon. Models for the mechanism of D. melanogaster tropomyosin gene evolution are discussed.

Ca2+-calmodulin binding to caldesmon and the caldesmon-actin-tropomyosin complex. Its role in Ca2+ regulation of the activity of synthetic smooth-muscle thin filaments

We measured the concentration of calmodulin required to reverse inhibition by caldesmon of actin-activated myosin MgATPase activity, in a model smooth-muscle thin-filament system, reconstituted in vitro from purified vascular smooth-muscle actin, tropomyosin and caldesmon. At 37 degrees C in buffer containing 120 mM-KCl, 4 microM-Ca2+-calmodulin produced a half-maximal reversal of caldesmon inhibition, but more than 300 microM-Ca2+-calmodulin was necessary at 25 degrees C in buffer containing 60 mM-KCl. The binding affinity (K) of caldesmon for Ca2+-calmodulin was measured by a fluorescence-polarization method: K = 2.7 x 10(6) M-1 at 25 degrees C (60 mM-KCl); K = 1.4 x 10(6) M-1 at 37 degrees C in 70 mM-KCl-containing buffer; K = 0.35 x 10(6) M-1 at 37 degrees C in 120 mM-KCl- containing buffer (pH 7.0). At 37 degrees C/120 mM-KCl, but not at 25 degrees C/60 mM-KCl, Ca2+-calmodulin bound to caldesmon bound to actin-tropomyosin (K = 2.9 x 10(6) M-1). Ca2+ regulation in this system does not depend on a simple competition between Ca2+-calmodulin and actin for binding to caldesmon. Under conditions (37 degrees C/120 mM-KCl) where physiologically realistic concentrations of calmodulin can Ca2+-regulate synthetic thin filaments, Ca2+-calmodulin reverses caldesmon inhibition of actomyosin ATPase by forming a non-inhibited complex of Ca2+-calmodulin-caldesmon-(actin-tropomyosin).

An X-ray diffraction study of alpha-tropomyosin magnesium tactoid

The structure of the needle-shaped aggregate of alpha-tropomyosin formed in the presence of Mg2+ ions (the Mg-tactoid) was studied by X-ray diffraction. Orientated specimens were prepared by magnetic orientation. The meridional reflections corresponding to a Bragg spacing of up to 2.6 nm were recorded and phased by the isomorphous replacement method using p-chloromercuribenzoate bound to the unique cysteine residue of the alpha-chain of tropomyosin. The axial electron density profile thus obtained was compared with the model proposed from electron microscopic investigations. With an adequate phase combination for the observed intensities, the agreement was satisfactory. Comparison with electron micrographs of negatively stained Mg-tactoids suggests that the C-terminus of the molecule has an extended conformation and penetrates into the N-N overlap region. The principal repeat length along the tactoid was 39.0 nm, which was about 5% shorter than the expected periodicity of the tropomyosin molecules with an end-to-end overlap of eight residues, suggesting supercoiling. The equatorial reflections consisted of the diffuse peaks at 1/8 nm-1 and 1/2.3 nm-1. The former indicates, for the first time, the presence of a large structural unit with low crystallinity. The spacing of the latter probably corresponds to the average centre-to-centre distance between neighbouring tropomyosin molecules.

The Drosophila melanogaster tropomyosin II gene produces multiple proteins by use of alternative tissue-specific promoters and alternative splicing

The structure of the Drosophila melanogaster tropomyosin II (TmII) gene has been determined by DNA sequencing of cDNA clones and the genomic DNA coding for the gene. Two overlapping transcriptional units produce at least four different tropomyosin isoforms. A combination of developmentally regulated promoters and alternative splicing produces both muscle and cytoskeletal tropomyosin isoforms. One promoter is a muscle-specific promoter and produces three different tropomyosin isoforms by alternative splicing of the last three 3' exons. The second promoter has the characteristics of a housekeeping promoter and produces a cytoskeletal tropomyosin isoform. Several internal exons along with a final 3' exon are alternatively spliced in the cytoskeletal transcript. The intron-exon boundaries of the TmII gene are identical to the intron-exon boundaries of all vertebrate tropomyosin genes reported, but are very different from the intron-exon boundaries of the D. melanogaster tropomyosin I gene. The TmII gene is the only reported tropomyosin gene that has two promoters and a quadruple alternative splice choice for the final exon. Models for the mechanism of D. melanogaster tropomyosin gene evolution are discussed.

Bulk isolation of the 20,000-Da light chain of smooth muscle myosin: separation of the unphosphorylated and phosphorylated species

The procedure of W. T. Perrie and S. V. Perry (1970, Biochem. J. 119, 31-38) has been improved and extended to allow a convenient large-scale isolation of the 20,000-Da light chain of vertebrate smooth muscle myosin. The method utilizes as source material tropomyosin-free actomyosin or myosin. The relatively pure light chain isolated from this material could be obtained in pure form by a single gel-filtration step. Separation of the unphosphorylated and phosphorylated light chain species was achieved by subsequent chromatography on a DEAE column. The solubility properties of this light chain, relevant to its use in myosin light chain kinase assays, were also established.

Cloning and characterization of a cDNA encoding transformation-sensitive tropomyosin isoform 3 from tumorigenic human fibroblasts

We isolated a cDNA clone from the tumorigenic human fibroblast cell line HuT-14 that contains the entire protein coding region of tropomyosin isoform 3 (Tm3) and 781 base pairs of 5'- and 3'-untranslated sequences. Tm3, despite its apparent smaller molecular weight than Tm1 in two-dimensional gels, has the same peptide length as Tm1 (284 amino acids) and shares 83% homology with Tm1. Tm3 cDNA hybridized to an abundant mRNA of 1.3 kilobases in fetal muscle and cardiac muscle, suggesting that Tm3 is related to an alpha fast-tropomyosin. The first 188 amino acids of Tm3 are identical to those of rat or rabbit skeletal muscle alpha-tropomyosin, and the last 71 amino acids differ from those of rat smooth muscle alpha-tropomyosin by only 1 residue. Tm3 therefore appears to be encoded by the same gene that encodes the fast skeletal muscle alpha-tropomyosin and the smooth muscle alpha-tropomyosin via an alternative RNA-splicing mechanism. In contrast to Tm4 and Tm5, Tm3 has a small gene family, with, at best, only one pseudogene.

Cloning and characterization of a cDNA encoding transformation-sensitive tropomyosin isoform 3 from tumorigenic human fibroblasts

We isolated a cDNA clone from the tumorigenic human fibroblast cell line HuT-14 that contains the entire protein coding region of tropomyosin isoform 3 (Tm3) and 781 base pairs of 5'- and 3'-untranslated sequences. Tm3, despite its apparent smaller molecular weight than Tm1 in two-dimensional gels, has the same peptide length as Tm1 (284 amino acids) and shares 83% homology with Tm1. Tm3 cDNA hybridized to an abundant mRNA of 1.3 kilobases in fetal muscle and cardiac muscle, suggesting that Tm3 is related to an alpha fast-tropomyosin. The first 188 amino acids of Tm3 are identical to those of rat or rabbit skeletal muscle alpha-tropomyosin, and the last 71 amino acids differ from those of rat smooth muscle alpha-tropomyosin by only 1 residue. Tm3 therefore appears to be encoded by the same gene that encodes the fast skeletal muscle alpha-tropomyosin and the smooth muscle alpha-tropomyosin via an alternative RNA-splicing mechanism. In contrast to Tm4 and Tm5, Tm3 has a small gene family, with, at best, only one pseudogene.

Calcium binding and fluorescence measurements of dansylaziridine-labelled troponin C in reconstituted thin filaments

The direct binding of Ca2+ to reconstituted thin filaments containing troponin C and the 5-dimethylaminonaphthalene-1-sulphonylaziridine (DANZ) fluorescent analogue of troponin C (TnCDANZ) was measured (25 degrees C) at three Mg2+ concentrations. Biphasic Scatchard plots were found for all binding curves reflecting the binding of Ca2+ to high- and low-affinity sites of troponin. The binding of Ca2+ to the high-affinity sites had a greater sensitivity to Mg2+ (KMg = 1 x 10(4)M-1) than the low-affinity sites (KMg = 1.2 x 10(3)M-1). The fluorescence change of thin filaments reconstituted with TnCDANZ was titrated with Ca2+ in the same solutions used for binding assays. The Ca2+-dependent fluorescence change had nearly the same sensitivity to Mg2+ (KMg = 9.4 x 10(2)M-1) as did Ca2+ binding to the low-affinity sites. The Ca2+ concentration at the midpoint of the fluorescence change was about 0.3 log units less than at the midpoint for Ca2+ binding to the low-affinity sites. A similar relationship between the fluorescence change and Ca2+ binding to the low-affinity sites of isolated TnCDANZ was measured (4 degrees C). From these results the binding of Ca2+ to either low-affinity site is concluded to produce the fluorescence change. In comparison with the low-affinity sites of isolated troponin and troponin-tropomyosin complex, the low-affinity sites of reconstituted thin filaments were consistently lower in Ca2+ affinity.

Structural changes accompanying phosphorylation of tarantula muscle myosin filaments

Electron microscopy has been used to study the structural changes that occur in the myosin filaments of tarantula striated muscle when they are phosphorylated. Myosin filaments in muscle homogenates maintained in relaxing conditions (ATP, EGTA) are found to have nonphosphorylated regulatory light chains as shown by urea/glycerol gel electrophoresis and [32P]phosphate autoradiography. Negative staining reveals an ordered, helical arrangement of crossbridges in these filaments, in which the heads from axially neighboring myosin molecules appear to interact with each other. When the free Ca2+ concentration in a homogenate is raised to 10(-4) M, or when a Ca2+-insensitive myosin light chain kinase is added at low Ca2+ (10(-8) M), the regulatory light chains of myosin become rapidly phosphorylated. Phosphorylation is accompanied by potentiation of the actin activation of the myosin Mg-ATPase activity and by loss of order of the helical crossbridge arrangement characteristic of the relaxed filament. We suggest that in the relaxed state, when the regulatory light chains are not phosphorylated, the myosin heads are held down on the filament backbone by head-head interactions or by interactions of the heads with the filament backbone. Phosphorylation of the light chains may alter these interactions so that the crossbridges become more loosely associated with the filament backbone giving rise to the observed changes and facilitating crossbridge interaction with actin.

Evidence for interaction between smooth muscle tropomyosin and caldesmon

The viscosity of chicken gizzard smooth muscle tropomyosin is enhanced 4.7-fold in the absence of salt and 1.43-fold in 0.1 M salt by the presence of stoichiometric amounts of gizzard caldesmon, indicating that the two proteins interact under these conditions. Since the thin filament regulation of smooth muscle contraction by caldesmon requires the presence of tropomyosin, these results suggest that the direct interaction between tropomyosin and caldesmon on the thin filament plays a role in this regulation.

Bundling of myosin subfragment-1-decorated actin filaments

We have reported previously that rabbit skeletal myosin subfragment-1 (S-1) assembles actin filaments into bundles. The rate of this reaction can be estimated roughly from the initial rate (Vo) of the accompanying turbidity increase ("super-opalescence") of the acto-S-1 solution. Vo is a function of the molar ratio (r) of S-1 to actin, with a peak at r = 1/6 to 1/7 and minimum around r = 1. In the present paper we report a different type of opalescence (we call it "hyper-opalescence") of acto-S-1 solutions, which also resulted from bundle formation. Adjacent filaments in the bundles had a distance of approximately 180 A. Hyper-opalescence occurred at r approximately equal to 1 when KCOOCH3 was used instead of KCl. By comparing the effects of ADP, epsilon-ADP, tropomyosin or ionic strength upon the super- and hyper-opalescence, we concluded that the two types of S-1-induced actin bundling had different molecular mechanisms. The hyper-opalescence type of bundling seemed to be induced by S-1, which was not complexed with actin in the manner of conventional rigor binding. The presence of the regulatory light chain did not affect hyper-opalescence (or super-opalescence), since there were no significant differences between papain S-1 and chymotryptic S-1 with respect to these phenomena.

A new crystal form of tropomyosin. Preliminary X-ray diffraction analysis

A new crystalline form of tropomyosin has been produced that diffracts to about 4 A resolution. The crystals are grown at room temperature by slowly lowering the concentration of spermine. This polyamine apparently neutralizes the acidic amino acid side-chains of tropomyosin and allows close side-by-side packing of molecules. The space group is C2, with unit cell dimensions a = 259.7 A, b = 55.3 A, c = 135.6 A, and beta = 97.2 degrees. The tropomyosin molecules appear to be bonded head-to-tail to form straight filaments that run along the crystallographic (332) direction in an arrangement closely related to thin crystalline sheets previously described.

Troponin-T and glyceraldehyde-3-phosphate dehydrogenase share a common antigenic determinant

A 37 kDa protein in extracts of bovine aorta and equine platelets was observed on SDS-polyacrylamide gel electrophoretograms to react with polyclonal and monoclonal antibodies to rabbit skeletal troponin-T (TnT) by immunoblotting. Following purification by precipitation at pH 4.6 and several ion-exchange chromatographic steps, it has been identified as glyceraldehyde-3-phosphate dehydrogenase (G3PD) by amino acid analyses and NH2-terminal sequencing. By ELISA, the anti-troponin-T monoclonal antibody reacted with rabbit skeletal G3PD appreciably but 120-fold less specifically than with TnT. A cyanogen bromide fragment (CB2) of TnT (residues 71-151) reacted with the monoclonal antibody nearly as well as intact TnT. This cross-reactivity between G3PD and TnT can be ascribed to a weak homology in the amino acid sequences of the two proteins between residues 72-80 of TnT and residues 157-165 of G3PD. Other regions of limited sequence similarity in the two proteins are also present. We conclude that the identification of diffuse cytoplasmic indirect immunofluorescent staining observed with a monoclonal anti-TnT antibody in chicken gizzard muscle is probably attributable to cross-reactivity with G3PD.

Characterization of a cDNA defining a gene family encoding TM30p1, a human fibroblast tropomyosin

We have isolated a cDNA that contains the complete coding sequence of a 3.0 X 10(3) base human fibroblast mRNA together with a large part of its 3' untranslated sequence. The deduced protein sequence is very similar if not identical to the sequence of horse platelet tropomyosin, a 247 amino acid protein. In vitro translation of an SP6 transcript of this cDNA reveals that the protein product of the 3.0 X 10(3) base mRNA is TM30p1, one of the five proteins in human fibroblasts that have been shown to possess the physical and chemical characteristics of tropomyosin. This mRNA is encoded by a gene family that consists of a functional gene and multiple RNA-copy pseudogenes. This family of sequences is distinct from the gene family encoding TM30nm, a cytoskeletal tropomyosin very similar in electrophoretic mobility to TM30p1, but which shows significant differences in primary structure.

Relation of streptococcal M protein with human and rabbit tropomyosin: the complete amino acid sequence of human cardiac alpha tropomyosin, a highly conserved contractile protein

Partial sequences of group A streptococcal M proteins exhibit up to 50% sequence identity with segments of rabbit skeletal tropomyosin. It is well recognized that rheumatic fever and rheumatic heart disease in humans are sequelae of group A streptococcal infection. To examine whether the human cardiac tropomyosin would exhibit greater homology with the streptococcal M proteins, we have now determined its complete amino acid sequence. The amino acid sequence of human cardiac tropomyosin was established from sequence analyses of its peptides derived by enzymic and chemical cleavages, and comparison of these sequences to the reported sequence of rabbit skeletal tropomyosin. These studies have revealed that the amino acid sequence of human cardiac alpha tropomyosin is identical to that of the rabbit skeletal alpha tropomyosin, but for a single conservative substitution of Arg/Lys at position 220. This observation increases the significance of the previously observed sequence homology between streptococcal M protein and rabbit skeletal tropomyosin and may have relevance to the pathogenesis of rheumatic fever. Furthermore, these results rank tropomyosin as one of the most highly conserved contractile proteins between vertebrate species reported thus far.

Proximity relationship in the binary complex formed between troponin I and troponin C

We have determined six molecular distances among four sites in the binary complex formed between troponin C (TnC) and troponin I (TnI) by fluorescence resonance energy transfer between donor and acceptor probes that were either an intrinsic fluorophore (Trp158 of TnI) or extrinsic probes attached to the sites. The three extrinsic probes were dansylaziridine (DNZ), N'-(iodoacetyl)-N'-(8-sulfo-1-naphthyl)ethylenediamine (IAEDANS) and 5-(iodoacetamido)eosin (IAE). The four fluorophores provided four donor-acceptor pairs: DNZ----IAE, Trp----IAEDANS, IAEDANS----IAE, and Trp----DNZ. They allowed determinations of separations between specific sites from measurements of energy transfer from (1) Met25 (DNZ) to Cys98 (IAE) in TnC, (2) Trp158 to Cys133 (IAEDANS) in TnI, (3) Cys98 (IAEDANS) of TnC to Cys133(IAE) of TnI, (4) Trp158 of TnI to Cys98(IAEDANS) of TnC, and (6) Met25(DNZ) of TnC to Cys133(IAE) of TnI. Distance (1) in TnC was little affected when the isolated protein was complexed with TnI, whereas distance (2) in TnI increased by 6A (29%) when TnI was incorporated into the binary complex. In the presence of EGTA, the six donor-acceptor separations (R) in the complex were in the range 28 to 57 A based on kappa 2 = 2/3. Mg2+ had only small effects on R, but Ca2+ induced substantial increases or decreases of R in five of the six distances. These changes were not accompanied by significant changes in the axial depolarization of the fluorophores. The results indicate global structural perturbations of regions of the two proteins in the complex by Ca2+ binding to the TnC, and suggest that large-scale movements of domains of troponin subunits may be the initial molecular events that occur in the transmission of the Ca2+ signal in the regulation of contraction by calcium.

Effect of DNAase I on muscle tropomyosin polymerization

DNAase I, an endonuclease which interacts with G-actin, also affects tropomyosin polymerization. With chicken pectoralis or bovine cardiac ventricle tropomyosin, DNAase I both prevents tropomyosin from polymerizing and disrupts already formed tropomysin filaments. DNAase I and filament tropomyosin can also form a precipitable complex. In the electron microscope, the complex is observed as irregularly margined stellate-shaped structures with a maximum size of 9 micron. Isolated DNAase I-tropomyosin stellate complex consists of a 2:1 molar ratio of DNAase I and tropomyosin, suggesting that each tropomyosin subunit can bind DNAase I.

Interaction of tropomyosin and troponin T: a proton nuclear magnetic resonance study

Proton nuclear magnetic resonance (1H NMR) has been used to study the nature of the interaction between tropomyosin (TM) and troponin T (Tn-T). Resonances corresponding to the histidine residues in fragments of both TM and Tn-T can be resolved and assigned in the 1H NMR spectrum. Changes in the pH titration profiles of these resonances when the various fragments are mixed provide probes of the interaction sites between the proteins. Fragment T1 (residues 1-158) of Tn-T appears to interact weakly but specifically with fragments of TM in which the NH2-terminus (residues 1-10) is intact. While fragment CB2 (residues 71-151) of Tn-T interacts weakly (dissociation constant of 0.1-0.2 mM) with NH2-terminal fragments of TM, this appears to be nonspecific since the absence of residues 1-10 and 128-189 of TM does not affect the observed perturbations of the titration profiles of His-79 of CB2. Although a strong interaction between T1 and the COOH-terminal Cy2 fragment (residues 190-284) of TM has been previously demonstrated, no perturbation of His-276 of Cy2 or of His-7, -23, -29, or -36 of T1 was observed in a mixture of T1/Cy2. The pKa of His-276 was also not affected in a mixture of Cy1/Cy2 (where Cy1 is residues 1-189 of TM) but was significantly decreased in the ternary complex T1/Cy1/Cy2. The importance of residues 1-70 of Tn-T in its binding to TM is illustrated by the specificity it confers on the T1/Cy1 interaction and by the absence of His-276 perturbation in the mixture CB2/Cy1/Cy2.

Differences in thermal stability of frog and rabbit alpha alpha- and alpha beta-tropomyosins determined by optical rotatory dispersion

Frog and rabbit alpha alpha- and alpha beta-tropomyosins were purified, and their thermal stabilities determined by use of optical rotatory dispersion. The tropomyosins were found to be virtually completely helical at 5 degrees C. Regions of different thermal stabilities were seen for all tropomyosins. Rabbit and frog alpha alpha-tropomyosin show very similar thermal properties, with main transitions near 47-49 degrees C. The main transition for frog alpha beta-tropomyosin is at 32 degrees C. The results show that the alpha beta-tropomyosins are less stable than the alpha alpha-forms. Only thermal transitions of the alpha beta-forms appear to be correlated with the body temperatures of the animals.

Inhibition of muscle tropomyosin polymerization by DNAse I

Tropomyosin polymerization is inhibited by DNAse I, an endonuclease which also interacts with G-actin. A 1:4 molar ratio of DNAse I to adult chicken pectoralis muscle tropomyosin almost completely prevents the increased viscosity of tropomyosin under polymerizing ionic conditions. While G-actin binding to DNAse I inhibits the DNAse I hydrolysis of DNA, tropomyosin does not affect this enzymatic activity. G-actin-DNAse I interaction is also not altered by tropomyosin.

Adrenal medullary tropomyosins: purification and biochemical characterization

Tropomyosins have been isolated from bovine adrenal medulla. Purified from a heat-stable extract, the adrenal medullary tropomyosins show the same chromatographic patterns as platelet tropomyosin components purified under very similar conditions on ion-exchange (DEAE-Sephacel) and hydroxylapatite columns. When analyzed by polyacrylamide gel electrophoresis, the purified fraction, reduced and denatured, yielded three polypeptides with apparent molecular weights of 38,000, 35,500, and 32,000. The molar ratio of the two major polypeptides (38 kd and 32 kd) was 2:1. The predominant form of 38 kd is different from other nonmuscle tropomyosins previously isolated and with which an apparent molecular weight of 30,000 is normally associated. The three adrenal medullary tropomyosins have similar isoelectric points of about 4.7. When adrenal tropomyosins were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of 8 M urea, each form showed a shift to a higher molecular weight, which is a characteristic of muscle tropomyosin. The 38,000 adrenal medullary tropomyosin exhibits a stronger affinity for F-actin than the other forms. Peptide profiles obtained after limited proteolytic digestion show some similarity between the two predominant tropomyosins of the bovine adrenal medulla and also between these and the alpha and beta forms of bovine skeletal muscle tropomyosin.