Many isoforms of fast muscle troponin T from chicken legs

Troponin T from fast muscle of chicken legs was found to be composed of about 40 kinds of isoforms by two-dimensional polyacrylamide gel electrophoresis in conjunction with immunoblotting tests with an antiserum to chicken breast muscle troponin T. Almost all of the isoforms were found in the myofibril preparation and troponin preparation from the leg muscle, and they showed complex-forming ability with troponin I and troponin C. These isoforms existed in most of the fast muscle except pectoralis and posterior latissimus dorsi muscles, and they changed in composition during development. The breast muscle troponin T also showed different types of isoforms in the period soon after hatching. Since proteolysis was completely inhibited during two-dimensional gel electrophoresis and since the many isoforms were observed consistently in various muscles of chicken leg, they are most probably products of mRNAs generated by differential gene splicing.     

The amino acid sequence of troponin I from rabbit skeletal muscle.

The complete amino acid sequence of rabbit skeletal muscle troponin I was determined by the isolation of the cyanogen bromide fragments and the tryptic methionine-containing peptides. Troponin I contains 179 amino acid residues and has a molecular weight of 20864. Its N-terminus is acetylated. Detailed evidence on which the sequence is based has been deposited as Supplementary Publication SUP 50055 (23 pages) at the British Library (Lending Division), Boston Spa, Wetherby, West Yorkshire LS23 7QB, U.K., from whom copies may be obtained on the terms given in Biochem. J. (1975) 145, 5.     

A 26K fragment of troponin T from rabbit skeletal muscle

A 26K fragment of troponin T, which was produced by endogenous proteases in rabbit skeletal muscle, was isolated by SE-Sephadex column chromatography. This fragment sensitized both superprecipitation and ATPase of actomyosin to calcium ions, to the same extent as troponin T. There was no difference in affinity for tropomyosin between this fragment and troponin T as examined by affinity chromatography. Amino acid analysis showed that this fragment consisted of residues Ala-46-Lys-259 of troponin T. The N-terminal 45 residues of troponin T, therefore, are not essential for the physiological action of troponin T. It was also observed that Ca2+-activated neutral protease digested troponin T into the 26K fragment in the native thin filament, while the protease digested troponin T in a different way in the reconstituted thin filament.     

Developmentally regulated troponin C mRNAs of chicken skeletal muscle.

Fast and slow/cardiac troponin C (TnC) are the two different isoforms of TnC. Expression of these isoforms is developmentally regulated in vertebrate skeletal muscle. Therefore, in our studies, the pattern of their expression was analyzed by determining the steady-state levels of both TnC mRNAs. It was also examined if mRNAs for both isoforms of TnC were efficiently translated during chicken skeletal muscle development. We have used different methods to determine the steady-state levels of TnC mRNAs. First, probes specific for the fast and slow TnC mRNAs were developed using a 390 base pair (bp) and a 255 bp long fragment, of the full-length chicken fast and slow TnC cDNA clones, respectively. Our analyses using RNA-blot technique showed that fast TnC mRNA was the predominant isoform in embryonic chicken skeletal muscle. Following hatching, a significant amount of slow TnC mRNA began to accumulate in the skeletal (pectoralis) muscle. At 43 weeks posthatching, the slow TnC mRNA was nearly as abundant as the fast isoform. Furthermore, a majority of both slow and fast TnC mRNAs was found to be translationally active. A second method allowed a more reliable measure of the relative abundance of slow and fast TnC mRNAs in chicken skeletal muscle. We used a common highly conserved 18-nucleotide-long sequence towards the 5'-end of these mRNAs to perform primer extension analysis of both mRNAs in a single reaction. The result of these analyses confirmed the predominance of fast TnC mRNA in the embryonic skeletal muscle, while significant accumulation of slow TnC mRNA was observed in chicken breast (pectoralis) muscle following hatching. In addition to primer extension analysis, polymerase chain reaction was used to amplify the fast and slow TnC mRNAs from cardiac and skeletal muscle. Analysis of the amplified products demonstrated the presence of significant amounts of slow TnC mRNA in the adult skeletal muscle.     

Sequences of complete cDNAs encoding four variants of chicken skeletal muscle troponin T

cDNAs containing the complete coding sequences of four isoforms of troponin T derived from 1-week-old chick skeletal muscle have been isolated and sequenced. While the 5' and 3' untranslated regions and most of the coding sequence were identical for each, dramatic differences were observed in the NH2-terminal region corresponding to amino acid residues 10-37 of rabbit skeletal troponin T. These sequence differences correspond to the alternatively spliced but not mutually exclusive exons 4 to 8 of the rat skeletal muscle troponin T gene. In addition, we observe a sequence corresponding to an extra exon or exons (between 5 and 6) present in the chicken skeletal muscle gene and not previously detected in the rat skeletal or chicken cardiac genes. This sequence of 63 nucleotides consists of an almost perfect repeat of 30 and 33 nucleotides and has previously been shown to be represented as a protein variant in chicken skeletal muscle. A difference is also present in one cDNA clone corresponding to the alternatively spliced (mutually exclusive) exons 16 and 17 of the rat gene. In the protein, this corresponds to a region implicated in the interaction of troponin T with troponin C, tropomyosin, and perhaps troponin I and F-actin.     

Heterogeneity of contractile proteins. Purification and characterization of two species of troponin T from rabbit fast skeletal muscle

Two species of troponin T have been purified by ion-exchange chromatography from erector spinae, the major fast white muscle of the rabbit back, and from a pool of the fast hindlimb muscles gastrocnemius and plantaris. Designated Tn-T1f and Tn-T2f, they can be resolved by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, with apparent molecular weights of 37,500 and 37,000 respectively. Their amino acid compositions are similar and correlate well with that reported for troponin T from fast muscle (Pearlstone, J. R., Carpenter, M. R., and Smillie, L. B. (1977) J. Biol. Chem. 252, 971-977). Tn-T2f most likely corresponds to the previously studied troponin T; further characterization was undertaken to determine how the newly identified Tn-T1f differs from Tn-T2f. Phosphorylation of alkaline phosphatase-treated troponin demonstrated that Tn-T1f and Tn-T2f are not interconverted by a change in phosphorylation state. Comparison of the CNBr fragments of Tn-T1f and Tn-T2f by SDS-gel electrophoresis and reverse phase high-performance liquid chromatography revealed similar but not identical peptide patterns. The major difference occurs in the amino-terminal CNBr peptides corresponding to CB3. Since both Tn-T1f and Tn-T2f have blocked amino termini, the difference does not result from proteolysis at the amino terminus of one of the proteins. These observations indicate that the two species of troponin T do not result from a known post-translational modification, but rather from differences in the amino acid sequence, suggesting that they arise either from the expression of different genes or a single gene from which different mRNAs are transcribed.     

Developmental changes of cardiac and slow skeletal muscle troponin T expression in chicken cardiac and skeletal muscles

Numerous troponin T (TnT) isoforms are produced by alternative splicing from three genes characteristic of cardiac, fast skeletal, and slow skeletal muscles. Apart from the developmental transition of fast skeletal muscle TnT isoforms, switching of TnT expression during muscle development is poorly understood. In this study, we investigated precisely and comprehensively developmental changes in chicken cardiac and slow skeletal muscle TnT isoforms by two-dimensional gel electrophoresis and immunoblotting with specific antisera. Four major isoforms composed of two each of higher and lower molecular weights were found in cardiac TnT (cTnT). Expression of cTnT changed from high- to low-molecular-weight isoforms during cardiac muscle development. On the other hand, such a transition was not found and only high-molecular-weight isoforms were expressed in the early stages of chicken skeletal muscle development. Two major and three minor isoforms of slow skeletal muscle TnT (sTnT), three of which were newly found in this study, were expressed in chicken skeletal muscles. The major sTnT isoforms were commonly detected throughout development in slow and mixed skeletal muscles, and at developmental stages until hatching-out in fast skeletal muscles. The expression of minor sTnT isoforms varied from muscle to muscle and during development.     

N-terminal amino acid sequences of three functionally different troponin T isoforms from rabbit fast skeletal muscle

The different isoforms of fast skeletal muscle troponin T (TnT) are generated by alternative splicing of several 5' exons in the fast TnT gene. In rabbit skeletal muscle this process results in three major fast TnT species, TnT1f, TnT2f and TnT3f, that differ in a region of 30 to 40 amino acid residues near the N terminus. Differential expression of these three isoforms modulates the activation of the thin filament by calcium. To establish a basis for further structure-function studies, we have sequenced the N-terminal region of these proteins. TnT2f is the fast TnT sequenced by Pearlstone et al. The larger species TnT1f contains six additional amino acid residues identical in sequence and position to those encoded by exon 4 in the rat fast skeletal muscle TnT gene. TnT3f also contains that sequence but lacks 17 amino acid residues spanning the region encoded by exons 6 and 7 of the rat gene. These three TnTs appear to be generated by discrete alternative splicing pathways, each differing by a single event. Comparison of these TnT sequences with those from chicken fast skeletal muscle and bovine heart shows that the splicing pattern resulting in the excision of exon 4 is evolutionarily conserved and leads to a more calcium-sensitive thin filament.     

Divalent cation binding properties of slow skeletal muscle troponin in comparison with those of cardiac and fast skeletal muscle troponins

1. New methods of preparing troponins from slow skeletal and cardiac muscle of the chicken have been developed. The electrophoretic mobilities of slow skeletal muscle troponin subunits were different from those of the corresponding fast skeletal muscle subunits. 2. A new method for determining the amount of divalent cations bound to troponin was developed. The principle of the method is to immobilize troponin by conjugating it with Sepharose 4B resin, thus making it readily sedimentable. 3. The numbers of Sr and Ca ions bound to slow muscle troponin at concentrations sufficient to produce maximum contraction were 1.73 and 1.36 mol per mol, respectively, being nearly equal to those of cardiac troponin but half of those of fast muscle troponin. 4. The concentrations of Sr and Ca ions giving half-maximal ion binding to slow muscle troponin (K50%) were 5.5 X 10(-6) M and 4.6 X 10(-7) M, respectively. 5. K50% for Sr of cardiac troponin was significantly higher than that of slow muscle troponin. Although K50% for Sr of cardiac troponin was the same as that of fast muscle troponin, cardiac troponin bound more Sr ions than fast muscle troponin at lower Sr ion concentrations. The mechanism underlying the high sensitivity of cardiac muscle contraction to Sr ions is discussed in comparison with that of slow muscle.     

Isolation and some properties of troponin T kinase from rabbit skeletal muscle.

A method for isolation of troponin T kinase (ATP-protein phosphotransferase, EC 2.7.1.37) from rabbit skeletal muscles in proposed. The method gives a 7000-10 000-fold purification and results in an enzyme with specific activity of 400-800-nmol x min-1 x mg-1 of protein. The molecular weight of tropin T kinase as determined by gel filtration exceeds 500 000. Electrophoresis in polyacrylamide gel in the presence of sodium dodecyl sulphate revealed that isolated preparations of the enzyme consisted of at least three distinct proteins with apparent mol.wt. of 50 000, 46 000 and 31 000. The enzyme phosphorylates isolated troponin T at a rate which exceeds the phosphorylation rates of casein, phosvitin, histones, phosphorylase b and protamine 5-30-fold. Within the whole troponin complex, only troponin T is phosphorylated by the enzyme. The enzyme phosphorylates only the N-terminal serine residue of troponin T, i.e. the site that is normally phosphorylated in the whole troponin complex isolated from rabbit skeletal muscles.     

The control of myocardial contraction with skeletal fast muscle troponin C

The present study describes experiments on the myocardial trabeculae from the right ventricle of Syrian hamsters whose troponin C (TnC) moiety was exchanged with heterologous TnC from fast skeletal muscle of the rabbit. These experiments were designed to help define the role of the various classes of Ca2+-binding sites on TnC in setting the characteristic sensitivities for activations of cardiac and skeletal muscles. Thin trabeculae were skinned and about 75% of their troponin C extracted by chemical treatment. Tension development on activations by Ca2+ and Sr2+ was found to be nearly fully blocked in such TnC extracted preparations. Troponin C contents and the ability to develop tension on activations by Ca2+ and Sr2+ was permanently restored after incubation with 2-6 mg/ml purified TnC from either rabbit fast-twitch skeletal muscle (STnC) or the heart (CTnC, cardiac troponin C). The native (skinned) cardiac muscle is characteristically about 5 times more sensitive to activation by Sr2+ than fast muscle, but the STnC-loaded trabeculae gave response like fast muscle. Attempts were also made to exchange the TnC in psoas (fast-twitch muscle) fibers, but unlike cardiac muscle tension response of the maximally extracted psoas fibers could be restored only with homologous STnC. CTnC was effective in partially extracted fibers, even though the uptake of CTnC was complete in the maximally extracted fibers. The results in this study establish that troponin C subunit is the key in setting the characteristic sensitivity for tension control in the myocardium above that in the skeletal muscle. Since a major difference between skeletal and cardiac TnCs is that one of the trigger sites (site I, residues 28-40 from the N terminus) is modified in CTnC and has reduced affinity for Ca2+ binding, the possibility is raised that this site has a modulatory effect on activation in different tissues and limits the effectiveness of CTnC in skeletal fibers.     

Isolation, expression, and mutation of a rabbit skeletal muscle cDNA clone for troponin I. The role of the NH2 terminus of fast skeletal muscle troponin I in its biological activity.

A cDNA for rabbit fast skeletal muscle troponin I (TnI) was isolated and sequenced. The clone contains a coding sequence predicting a 182-amino-acid protein with a molecular mass of 21,162 daltons. The translated sequence is different from that reported by Wilkinson and Grand (Wilkinson, J. M., and Grand, R. J. A. (1978) Nature 271, 31-35) in that Arg-153, Asp-154, and Leu-155 must be inserted into their original sequence. Amino acid sequencing of adult rabbit TnI confirmed this result. In order to investigate the role of the NH2 terminus of TnI in its biological activity, we have expressed a recombinant deletion mutant (TnId57), which lacks residues 1-57, in a bacterial expression system. Both wild type TnI (WTnI) and TnId57 inhibited acto-S1-ATPase activity and this inhibition could be fully reversed by troponin C (TnC) in the presence of Ca2+. Additionally both WTnI and TnId57 bound to an actin affinity column. Thus, both inhibitory actin binding and Ca(2+)-dependent neutralization by TnC were retained in TnId57. TnC affinity chromatography was used to compare the binding of TnI and TnId57 to TnC. Using this method, two types of interaction between TnC and TnI were observed: 1) one which is metal independent (or structural) and 2) one dependent on Ca2+ or Mg2+ binding to the Ca(2+)-Mg2+ sites of TnC. The same experiments with TnId57 demonstrated that the type 1 interaction was weakened, and type 2 binding was lost. This method also revealed an interaction between TnC and TnI which is dependent upon Ca2+ binding to the Ca(2+)-specific sites of TnC and which is retained in TnId57. Taken together, these results suggest that the NH2 terminus of TnI may constitute a Ca(2+)-Mg(2+)-dependent interaction site between TnC and TnI and play, in part, a structural role in maintaining the stability of the troponin complex while the COOH terminus of TnI contains a Ca(2+)-specific site-dependent interaction site for TnC as well as the previously demonstrated Ca(2+)-sensitive inhibitory and actin binding activities.     

cDNA clone and expression analysis of rodent fast and slow skeletal muscle troponin I mRNAs

We have characterized the structure and expression of rodent mRNAs encoding the fast and slow skeletal muscle isoforms of the contractile regulatory protein, troponin I (TnIfast and TnIslow). TnIfast and TnIslow cDNA clones were isolated from mouse and rat muscle cDNA clone libraries and were used as isoform-specific probes in Northern blot and in situ hybridization studies. These studies showed that the TnIfast and TnIslow mRNAs are expressed in skeletal muscle, but not cardiac muscle or other tissues, and that they are differentially expressed in individual muscle fibers. Fiber typing on the basis of in situ hybridization analysis of TnI isoform mRNA content showed an excellent correlation with fiber type as assessed by myosin ATPase histochemistry. These results directly demonstrate that the differential expression of skeletal muscle TnI isoforms in the various classes of vertebrate striated muscle cells is based on gene regulatory mechanisms which control the abundances of specific TnI mRNAs in individual muscle cells. Both TnIfast and TnIslow mRNAs are expressed, at comparable levels, in differentiated cultures of rat L6 and mouse C2 muscle cell lines. Thus, although neuronal input has been shown to be an important factor in determining fast versus slow isoform-specific expression in skeletal muscle, both TnIfast and TnIslow genes can be expressed in muscle cells in the absence of nerve. Comparison of the deduced rodent TnI amino acid sequences with previously determined rabbit protein sequences showed that residues with potential fast/slow isoform-specific function are present in several discrete clusters, two of which are located near previously identified actin and troponin C binding sites.     

Energetics of the binding of calcium and troponin I to troponin C from rabbit skeletal muscle.

We determined the free energy of interaction between rabbit skeletal troponin I (TNI) and troponin C (TNC) at 10 degrees and 20 degrees C with fluorescently labeled proteins. The sulfhydryl probe 5-iodoacetamidoeosin (IAE) was attached to cysteine (Cys)-98 of TNC and to Cys-133 of TNI, and each of the labeled proteins was titrated with the other unlabeled protein. The association constant for formation of the complex between labeled TNC (TNC*) and TNI was 6.67 X 10(5) M-1 in 0.3 M KCl, and pH 7.5 at 20 degrees C. In the presence of bound Mg2+, the binding constant increased to 4.58 X 10(7) M-1 and in the presence of excess of Ca2+, the association constant was 5.58 X 10(9) M-1. Very similar association constants were obtained when labeled TNI was titrated with unlabeled TNC. The energetics of Ca2+ binding to TNC* and the complex TNI X TNC* were also determined at 20 degrees C. The two sets of results were used to separately determine the coupling free energy for binding TNI and Mg2+, or Ca2+ to TNC. The results yielded a total coupling free energy of -5.4 kcal. This free energy appeared evenly partitioned into the two species: TNI X TNC(Mg)2 or TNI X TNC(Ca)2, and TNI X TNC(Ca)4. The first two species were each stabilized by -2.6 kcal, with respect to the Ca2+ free TNI X TNC complex, and TNI X TNC(Ca)4 was stabilized by -2.8 kcal, respect to TNI X TNC(Ca)2 or TNI X TNC(Mg)2. The coupling free energy was shown to produce cooperatively complexes formed between TNI and TNC in which the high affinity sites were initially saturated as a function of free Ca2+ to yield TNI X TNC(Ca)4. This saturation occurred in the free Ca2+ concentration range 10(-7) to 10(-5) M. The cooperative strengthening of the linkage between TNI and TNC induced by Ca2+ binding to the Ca2+-specific sites of TNC may have a direct relationship to activation of actomyosin ATPase. The nature of the forces involved in the Ca2+-induced strengthening of the complex is discussed.