Determination of the native subunit pattern of gizzard tropomyosin using antibodies specific to each subunit

The gizzard tropomyosin molecule is composed of two subunits at 1:1 molar ratio. Possible composites of the tropomyosin molecule are two kinds of homodimer (one for each subunit), a heterodimer of two subunits, or a mixture of heterodimer and homodimer(s). We tried to evaluate the native subunit composition of gizzard tropomyosin by cross-linking experiments and immunological methods using specific antibodies to each subunit. For the cross-linking experiment we used dimethyl suberimidate, an amino group-specific cross-linker, in the presence of dithiothreitol to avoid artificial oxidative intersubunit cross-linking. When gizzard tropomyosin was cross-linked, it generated several products which might correspond to dimers formed by intersubunit cross-linkage. When the reaction was carried out for a long time, non-cross-linked subunits completely disappeared and two or three major cross-linked products arose. All of these cross-linked products were recognized by both of the specific antibodies to each subunit. These results indicated that the predominant part, if not all, of gizzard tropomyosin is present as heterodimer.     

Changes in tropomyosin subunit pattern in chronic electrically stimulated rabbit fast muscles.

The tropomyosin subunit ratio of rabbit fast muscle (α:β = 80:20) changes to that characteristic of skeletal slow muscles (α:β = 55:45) on continuous (10 Hz) stimulation for 3 weeks. The altered myosin light chain pattern and histochemical ATPase stain also show clear changes of fast → slow transformation. However, the rate of changes in the light chain patterns of myosin are slower than those of tropomyosin subunits. These results do not support the previous finding (Amphlett et al., Nature $\text{257}$, 602, 1975) that the tropomyosin subunit pattern remains unaltered during transformation of skeletal muscles and the conclusion that the genetic expression of tropomyosin is regulated under separate control from other myofibrillar proteins. Rather, our results suggest that the polymorphic patterns of all myofibrillar proteins in skeletal muscles undergo changes in a temporal manner during skeletal muscle transformation.     

Ca-binding and Ca-sensitizing functions of cardiac native tropomyosin, troponin, and tropomyosin

Procedures are described by which troponin and tropomyosin can be isolated from cardiac muscle rapidly, with minimal damage by oxidation. Cardiac relaxing proteins inhibit actomyosin ATPase activity in the presence of ethyleneglycoltetraacetic acid (EGTA), and permit graded stimulation by Ca²⁺. This stimulation is independent of preexisting inhibition, and greater than that obtained with skeletal proteins. Characteristics of Scatchard plots for Ca²⁺ binding suggest that troponin contains one class of sites which interact at high fractional occupancy. Interaction appears to be enhanced by tropomyosin. Mean values for the estimated maximum affinity and capacity of six canine cardiac troponin preparations were: 4.92·10⁶ M⁻¹, and 21.58·10⁻⁶ moles·g⁻¹. Values for skeletal troponin were not significantly different. Native tropomyosin bound about half as much Ca²⁺ per g, with maximum affinity the same as troponin. Pure tropomyosin bound no Ca²⁺. Cardiac and skeletal proteins differ in that the former are much more labile, and more readily influenced by ions and drugs.     

Factors determining the subunit composition of tropomyosin in mammalian skeletal muscle.

Adult rat fast-twitch skeletal muscle such as extensor digitorum longus contains alpha- and beta-tropomyosin subunits, as is the case in the corresponding muscles of rabbit. Adult rat soleus muscle contains beta-, gamma- and delta-tropomyosins, but no significant amounts of alpha-tropomyosin. Evidence for the presence of phosphorylated forms of at least three of the four tropomyosin subunit isoforms was obtained, particularly in developing muscle. Immediately after birth alpha- and beta-tropomyosins were the major components of skeletal muscle, in both fast-twitch and slow-twitch muscles. Differentiation into slow-twitch skeletal muscles was accompanied by a fall in the amount of alpha-tropomyosin subunit and its replacement with gamma- and delta-subunits. After denervation and during regeneration after injury, the tropomyosin composition of slow-twitch skeletal muscle changed to that associated with fast-twitch muscle. Thyroidectomy slowed down the changes in tropomyosin composition resulting from the denervation of soleus muscle. The results suggest that the 'ground state' of tropomyosin-gene expression in the skeletal muscle gives rise to alpha- and beta-tropomyosin subunits. Innervation by a 'slow-twitch' nerve is essential for the expression of the genes controlling gamma- and delta-subunits. There appears to be reciprocal relationship between expression of the gene controlling the synthesis of alpha-tropomyosin and those controlling the synthesis of gamma- and delta-tropomyosin subunits.     

Beta beta homodimers exist in native rabbit skeletal muscle tropomyosin and increase after denaturation-renaturation.

Native tropomyosin from rabbit skeletal muscle (RSTm) consists mainly of alpha alpha and alpha beta coiled coils (alpha/beta approximately 3-4/1). In some extant studies, no beta beta molecules have been found. In this study, RSTm from several different preparations was disulfide cross-linked, both preparation and cross-linking being done under nondenaturing conditions. The cross-linked product was assayed for the presence of beta beta molecules cross-linked at both C36 and C190 (beta = beta). In such cross-linked RSTm, 3-8% beta = beta is detected by sodium dodecyl sulfate polyacrylamide gel electrophoresis, C4 reversed-phase high-performance liquid chromatography, and a free-solution capillary electrophoresis experiment. This percentage becomes approximately 4-10% beta beta when corrected for incomplete double cross-linking and is independent of protein concentration (0.1-10.0 mg/mL), indicating that the observed beta beta species are not artifacts due to intermolecular cross-linking. Upon denaturation and subsequent renaturation either by heating to 55 degrees C or by incubating at 45 degrees C followed by quenching to room temperature, or by guanidine hydrochloride exposure followed by phased renaturation by dialysis, the fraction of beta beta increases, indicating that the reassociation favors homodimer formation somewhat over random association. This result differs from the random association observed when the sulfhydryl on one of the chains is carboxyamidomethylated (Holtzer, M.E., Breiner, T., & Holtzer, A., 1984, Biopolymers 23, 1811-1833), and from the overwhelming heterodimer preferences reported for tropomyosins from other organisms (Lehrer, S.S., Qian, Y., & Hvidt, S., 1989, Science 246, 926-928; Lehrer, S.S. & Qian, Y., 1990, J. Biol. Chem. 265, 1134-1138).     

Regulation of myosin sliding alongChara actin bundles by native skeletal muscle tropomyosin

Summary Native tropomyosin from rabbit skeletal muscle introduced by intracellular perfusion intoChara cells inhibited the cytoplasmic streaming irrespective of the Ca²⁺ concentration. To find the action site of native tropomyosin inChara, the cytoplasmic streaming was reconstituted by introducing isolated endoplasm into actin donorChara cells from which native endoplasm had been removed. The reconstituted streaming was inhibited by pretreatment of the actin donor cells with native tropomyosin but not by that of the endoplasm, suggesting that the native tropomyosin inhibited the cytoplasmic streaming by binding toChara actin bundles. Staining of the actin bundles with FITC-labeled native tropomyosin also showed that the native tropomyosin could bind to the actin bundles. Streaming reconstituted fromChara actin bundles and skeletal muscle myosin was insensitive to Ca²⁺, but became sensitive on application of the native tropomyosin.Abbrevations APW artificial pond water - ATP adenosine 5-triphosphoric acid - BSA bovine serum albumin - EDTA ethylene diamine tetraacetic acid - EGTA ethyleneglycol-bis-(-aminoethylether) N,N,N,N-tetraacetic acid - FITC fluorescein isothiocyanate - FITC-NTM fluorescein isothiocyanate-labeled native tropomyosin - NTM native tropomyosin     

The role of subunit III in bovine cytochrome c oxidase. Comparison between native, subunit III-depleted and Paracoccus denitrificans enzymes

In order to obtain information on the role of subunit III in the function and aggregation state of cytochrome c oxidase, the kinetics of ferrocytochrome c oxidation by the bovine cytochrome c oxidase depleted of its subunit III were studied and compared with those of the oxidase isolated from P. denitrificans which contains only two subunits. The aggregation state of both enzymes dispersed in dodecyl maltoside was also compared. The two-subunit oxidase from P. denitrificans gave linear Eadie-Hofstee plots and the enzyme resulted to be monomeric (Mr = 82 000) both, in gel filtration and sucrose gradient centrifugation studies. The bovine heart subunit III depleted enzyme, under conditions when the P. denitrificans cytochrome c oxidase was in the form of monomers, was found to be dimeric by sucrose gradient centrifugation analysis. At lower enzyme concentrations monomers were, however, detected by gel filtration. Depletion of subunit III was accompanied by the loss of small polypeptides (VIa, VIb and VIIa) and of almost all phospholipid (1-2 molecules were left per molecule of enzyme). The electron-transfer activity of the subunit III-depleted enzyme showed a monophasic Eadie-Hofstee plot, which upon addition of phospholipids became non-linear, similar to that of the control bovine cytochrome c oxidase. One of the roles of subunit III may be that of stabilising the dimers of cytochrome c oxidase. Lack of this subunit and loss of phospholipid is accompanied by a change in the kinetics of electron transfer, which might be the consequence of enzyme monomerisation.     

The binding dynamics of tropomyosin on actin.

We discuss a theoretical model for the cooperative binding dynamics of tropomyosin to actin filaments. Tropomyosin binds to actin by occupying seven consecutive monomers. The model includes a strong attraction between attached tropomyosin molecules. We start with an empty lattice and show that the binding goes through several stages. The first stage represents fast initial binding and leaves many small vacancies between blocks of bound molecules. In the second stage the vacancies annihilate slowly as tropomyosin molecules detach and reattach. Finally, the system approaches equilibrium. Using a grain-growth model and a diffusion-coagulation model we give analytical approximations for the vacancy density in all regimes.     

The regulatory subunit monomer of cAMP-dependent protein kinase retains the salient kinetic properties of the native dimeric subunit

Monomeric regulatory subunit (R) fragments of type II cAMP-dependent protein kinase were compared with the parent dimeric R. The monomeric fragments were generated by either endogenous proteolysis of rabbit muscle R or by trypsin treatment of bovine heart R in the holoenzyme form. During isolation of pure R from rabbit muscle, carboxyl-terminal fragments of Mr = 42,000 (42 K) and Mr = 37,000 by denaturing gels are generated by endogenous proteolysis. Although the autophosphorylation site is retained, the 42 K is not dimeric (as is its native 56 K precursor) but, in contrast to the monomeric 37 K product, actively reassociates with purified catalytic subunit (C). Several lines of evidence indicate a type II R origin of the 42 K. N-terminal sequence analysis of the 42 K shows some homology with known bovine RI, RII, and cGMP-dependent protein kinase sequences. Both cyclic nucleotide-binding sites (two/42 K or 37 K) and the site selectivity of cAMP analogs are retained in the monomeric fragments. When purified bovine heart holoenzyme, which contains a dimeric Mr = 56,000 R (denaturing gel analysis) and two C subunits, is treated with trypsin followed by separation procedures, the product is a fully recovered active enzyme with an unaltered ratio of cAMP binding to catalytic activity. From Mr considerations, the product is a dimer containing one intact C and a proteolyzed R of Mr = 48,000 on denaturing gels. This dimeric enzyme is not significantly different from the parent tetramer in cAMP concentration dependence (Hill constant = 1.63), [3H]cAMP dissociation behavior (both intrasubunit cAMP-binding sites are present), stimulation of [3H]cIMP binding by site-selective cAMP analogs, and synergism between two analogs in kinase activation. The data indicate that 1) proteolytic cleavage of the native R dimer can cause monomerization without appreciably affecting the inhibition of C and 2) essentially all of the cAMP binding cooperativity is an intrasubunit interaction.