Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Using treatment with vanadate solutions, we extracted native cardiac troponin I and troponin C (cTnI and cTnC) from skinned fibers of porcine right ventricles. These proteins were replaced by exogenously supplied TnI and TnC isoforms, thereby restoring Ca2+-dependent regulation. Force then depended on the negative logarithm of Ca2+ concentration (pCa) in a sigmoidal manner, the pCa for 50% force development, pCa50, being about 5.5. For reconstitution we used fast-twitch rabbit skeletal muscle TnI and TnC (sTnI and sTnC), bovine cTnI and cTnC or recombinant sTnIs that were altered by site-directed mutagenesis. Incubation with TnI inhibited isometric tension in TnI-extracted fibers in the absence of Ca2+, but restoration of Ca2+ dependence required incubation with both TnI and TnC. Relaxation at low Ca2+ levels and the steepness of the force/pCa relation depended on the concentration of exogenously supplied TnI in the reconstitution solution (range 20-150 "mu"M), while Ca2+ sensitivity, i.e. the pCa50, was dependent on the isoform, and also on the concentration of TnC in the reconstitution solution. At pH 6.7, skinned fibers reconstituted with optimal concentrations of sTnC and sTnI (120 "mu"M and 150 "mu"M, respectively) were more sensitive to Ca2+ than those reconstituted with cTnC and cTnI (difference in pCa50 approx. 0.2 units). Rabbit sTnI was cloned and expressed in Escherichia coli using a high yield expression plasmid. We introduced point mutations into the TnI inhibitory region comprising the sequence of the minimal common TnC/actin binding site (-G104-K-F-K-R-P-P-L-R-R-V-R115-). The four mutants produced by substitution of T for P110, G for P110, G for L111, and G for K105 were chosen, based on previous work with synthetic peptides showing that single amino acid substitution in this region diminished the capacity of these peptides to inhibit acto-S1 ATPase or contraction of skinned fibers. Therefore, all amino acid residues of the inhibitory region are thought to contribute to biological activity of TnI. However, each of the recombinant TnIs could substitute for endogenous TnI. In combination with exogenous TnC, Ca2+ dependence could be restored when gly110sTnI, thr110sTnI or gly111sTnI was used for reconstitution. The mutant gly105sTnI, on the other hand, reduced the ability of skinned fibers to relax at low Ca2+ concentrations and it caused an increase in Ca2+ sensitivity.
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PMID:Recombinant troponin I substitution and calcium responsiveness in skinned cardiac muscle. 892 1

The central helix of troponin C is highly conserved in length and amino acid sequence. In this region, D89 is conserved and specific to TnC. To investigate its significance, three mutations were made in avian fast troponin C: (1) D89 was replaced with A (D89A); (2) the central helix was replaced with a designed alpha-helix (alpha h89A) consisting of 87AEAALKAAMEA97; and (3) A89 of alpha h89A was replaced with D (alpha h89D). D89A and alpha h89A activated the regulated actomyosin ATPase poorly in the presence of Ca2+ (24 +/- 1.0% and 14 +/- 2.0%, respectively, of the wild type maximal activity) whereas alpha h89D had higher activity (113 +/- 3%). Both alpha h89A and D89A had apparently normal interactions with TnI and TnT whereas alpha h89D formed a complex with TnT even in the absence of Ca2+. The central helix was also replaced with a flexible random coil and rigid polyproline linkers in which D89 was Arg or Pro, respectively. Like alpha h89A and D89A, both mutants were defective in activation of the actomyosin ATPase in the presence of Ca2+. Changes in regulatory function of the mutants did not correlate with altered Ca2+ affinity, altered conformational changes upon binding divalent cations, or Ca(2+)-dependent binding to TnI or TnT. The results suggest that D89 is required for Ca(2+)-dependent signal transduction, an event that can be dissociated from Ca(2+)-dependent binding to TnC targets on the thin filament.
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PMID:Structural and functional significance of aspartic acid 89 of the troponin C central helix in Ca2+ signaling. 895 5

The interaction between troponin I (TnI) and troponin T (TnT) remains the least understood binary interaction among the regulatory proteins of vertebrate striated muscle. To identify the specific binding domains of TnI and TnT and to evaluate the interactions of TnT with troponin C and tropomyosin (Tm), we generated an NH2-terminal fragment of human fast skeletal beta TnT (TnT1-201; residues 1-201) using site-directed mutagenesis. The mutant protein failed to bind to rabbit skeletal muscle TnI as judged by HPLC, showed reduced TnC binding and reduced ternary troponin (Tn) complex formation, and exhibited a much reduced Ca2+ sensitivity in the reconstituted regulatory system. It is shown that the amount of Tn complex formed by TnT1-201 rather than the activity of the mutant Tn complex affected this Ca2+ sensitivity. Binding of the mutant to Tm was similar to that of intact TnT. These results support the view that the COOH-terminal segment of TnT is necessary for binding to TnI and TnC and Ca2+ sensitivity in the thin filament, whereas its NH2-terminus strongly binds to Tm. To identify the regions of TnI which bind to muscle TnT, we used four recombinant fragments of fast skeletal muscle TnI containing amino acid residues 1-94 (TnI1-94), 1-120 (TnI1-120), 96-181 (TnI96-181), and 122-181 (TnI122-181) and a synthetic peptide, TnI98-114, containing residues 98-114 corresponding to the inhibitory region. Only TnI1-120 showed weak binding to TnT but not to TnT1-201. These results suggest that (i) a region within the NH2-terminal 120 residues of TnI interacts with TnT and (ii) the COOH-terminal residues 202-258 of TnT contain the interaction site of TnI. Overall, our results also imply that residues 159-201 constitute the smallest region of TnT which contributes to the Ca2+ sensitivity of actoS1 ATPase in a reconstituted regulatory system.
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PMID:Interaction of deletion mutants of troponins I and T: COOH-terminal truncation of troponin T abolishes troponin I binding and reduces Ca2+ sensitivity of the reconstituted regulatory system. 898 92

The regions of troponin I (TnI) responsible for Ca2+-dependent activation and Ca2+ sensitivity of the actin-myosin subfragment 1-tropomyosin ATPase (acto-S1-TM) activity have been determined. A colorimetric ATPase assay at pH 7.8 has been applied to reconstituted skeletal muscle thin filaments at actin:S1:TM ratios of 6:1:2. Several TnI fragments (TnI-(104-115), TnI-(1-116), and TnI-(96-148)) and TnI mutants with single amino acid substitutions within the inhibitory region (residues 104-115) were assayed to determine their roles on the regulatory function of TnI. TnI-(104-115) is sufficient for achieving maximum inhibition of the acto-S1-TM ATPase activity and its importance was clearly shown by the reduced potency of TnI mutants with single amino acid substitutions within this region. However, the function of the inhibitory region is modulated by other regions of TnI as observed by the poor inhibitory activity of TnI-(1-116) and the increased potency of the inhibitory region by TnI-(96-148). The regulatory complex composed of TnI-(96-148) plus troponin T-troponin C complex (TnT.C) displays the same Ca2+ sensitivity (pCa50) as intact troponin (Tn) or TnI plus TnT.C while those regulatory complexes composed of TnT.C plus either TnI-(104-115) or TnI-(1-116) had an increase in their pCa50 values. This indicates that the Ca2+ sensitivity or responsiveness of the thin filament is controlled by TnI residues 96-148. The ability of Tn to activate the acto-S1-TM ATPase activity in the presence of calcium to the level of the acto-S1 rate was mimicked by the regulatory complex composed of TnI-(1-116) plus TnT.C and was not seen with complexes composed with either TnI-(104-115) or TnI-(96-148). This indicates that the N terminus of TnI in conjunction with TnT controls the degree of activation of the ATPase activity. Although the TnI inhibitory region (104-115) is the Ca2+-sensitive switch which changes binding sites from actin-TM to TnC in the presence of calcium, its function is modulated by both the C-terminal and N-terminal regions of TnI. Thus, distinct regions of TnI control different aspects of Tn's biological function.
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PMID:Distinct regions of troponin I regulate Ca2+-dependent activation and Ca2+ sensitivity of the acto-S1-TM ATPase activity of the thin filament. 909 97

Troponin (Tn), consisting of three subunits, TnT, TnC, and TnI, plays a crucial role in the calcium-dependent regulation of vertebrate striated muscle contraction. In the present study, we have applied limited proteolysis to the Tn complex in order to study domain structures and to detect conformational differences of Tn under different conditions. We found that both TnT and TnI were susceptible to chymotryptic digestion: while TnT was cleaved into TnT-(1-158)-peptide and TnT-(159-259)-peptide irrespective of Ca2+ concentration, the cleavage sites of TnI were dependent on the Ca2+ occupancy of TnC. In addition, we characterized the effects of depletion of the C-terminal part of TnI on acto-S1 ATPase activity. The TnT-(159-259)-peptide-TnC-TnICa-frag complex [TnICa-frag = (TnI-(1-134 and 1-140)-peptide], which was produced in the presence of CaCl2 and MgCl2, retains both the activating and inhibitory capabilities of whole Tn on the acto-S1 ATPase activity, while TnT-(159-259)-peptide-TnC-TnIMg-frag complex [TnIMg-frag = (TnI-(1-116)-peptide], which was obtained in the presence of MgCl2 and EGTA, lost its ability to activate acto-S1 ATPase activity. Our results indicate that residues 117-134 or 117-140 of TnI undergo structural changes upon Ca(2+)-binding to the regulatory sites of TnC and are necessary for the Ca(2+)-dependent inhibitory action of the Tn complex on acto-S1 ATPase activity. We also showed that residues 135-181 or 141-181 of TnI are involved in the interaction of Tn with the tropomyosin-actin filament.
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PMID:Structural and functional domains of the troponin complex revealed by limited digestion. 921 16

In vertebrate skeletal muscle, contraction is initiated by the elevation of the intracellular Ca2+ concentration. The binding of Ca2+ to TnC induces a series of conformational changes which ultimately release the inhibition of the actomyosin ATPase activity by Tnl. In this study we have characterized the dynamic behavior of TnC and Tnl in solution, as well as in reconstituted fibers, using EPR and ST-EPR spectroscopy. Cys98 of TnC and Cys133 of Tnl were specifically labeled with malemide spin label (MSL) and indane dione nitroxide spin label (InVSL). In solution, the labeled TnC and Tnl exhibited fast nanosecond motion. MSL-TnC is sensitive to cation binding to the high affinity sites (tau r increases from 1.5 to 3.7 ns), InVSL-TnC s sensitive to the replacement of Mg2+ by Ca2+ at these sites (tau r increase from 1.7 to 6 ns). Upon reconstitution into fibers, the nanosecond mobility is reduced by interactions with other proteins. TnC and Tnl both exhibited microsecond anisotropic motion in fibers similar to that of the actin monomers within the filament. The microsecond motion of TnC was found to be modulated by the binding of Ca2+ and by cross-bridge attachment, but this was not the case for the global mobility of Tnl.
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PMID:The mobility of troponin C and troponin I in muscle. 947 23

We have generated a series of chicken skeletal muscle troponin C mutants to study the conformation of the regulatory domain in the N-terminal half of the molecule. These mutants each contained a single Trp at position 22 (helix A), 52 (linker of helices B and C), or 90 (central helix). Some of these mutants also contained additional mutations to introduce a single Cys at a desired position. The mutants were characterized by molecular graphics and CD and found to have a minimum of structural perturbations when compared with the native structure. They also retained the ability to regulate myofibrillar ATPase activity. The fluorescence of Trp22 was sensitive to Ca2+ binding only to the regulatory sites, whereas Trp52 and Trp90 responded to Ca2+ binding to both the regulatory and the Ca2+/Mg2+ sites. The tryptophan quantum yield (Q) of all Trp22-containing mutants was very high (0.33) in the absence of bound Ca2+, compared to that of L-tryptophan in aqueous solution (0.14). Q decreased 25% upon binding of Ca2+ to the regulatory sites. The quantum yields of Trp52 and Trp90 in apo mutants were close to 0.14. In the presence of bound Ca2+ at the regulatory sites, the quantum yield of Trp52 decreased 16%, whereas that of Trp90 increased 25%. Results from acrylamide quenching of the fluorescence of the three Trp residues indicated that Trp22 was the least exposed and Trp52 was the most exposed, consistent with other spectral data that Trp22 was in a relatively nonpolar environment and Trp52 was in a highly polar environment. The ability of Trp52 and Trp90 to sense Ca2+ binding to sites located at both domains suggests inter-domain communication in the protein. These single Trp TnC mutants provide specific signals for probing Ca2+-induced conformational changes in the regulatory domain.
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PMID:Tryptophan mutants of troponin C from skeletal muscle--an optical probe of the regulatory domain. 954 79

EPR of spin labeled TnC at Cys98 was used to explore the possible structural coupling between TnC in the thin filament and myosin trapped in the intermediate states of ATPase cycle. Weakly attached myosin heads (trapped by low ionic strength, low temperature and ATP) did not induce structural changes in TnC as compared to relaxed muscle, as spin labeled TnC displayed the same narrow orientational distribution [Li, H.-C., and Fajer, P. G. (1994) Biochemistry 33, 14324]. Ca2+-binding alone resulted in disordering of the labeled domain of TnC. Additional conformational changes of TnC occurred upon the attachment of strongly bound, prepower stroke myosin heads (trapped by AlF4-). These changes were not present in ghost fibers which myosin had been removed, excluding direct effects of AlF4- on the orientation of TnC in muscle fibers. The postpower stroke heads (rigor.ADP/Ca2+ and rigor/Ca2+) induced further changes in the orientational distribution of labeled domain of TnC irrespective of the degree of cooperativity in thin filaments. We thus conclude that troponin C in thin filaments detects structural changes in myosin during force generation, implying that there is a structural coupling between actomyosin and TnC.
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PMID:Structural coupling of troponin C and actomyosin in muscle fibers. 957 46

The regulatory protein troponin (Tn) located on actin filament consists of three subunits: TnT--binds troponin to tropomyosin, TnC--binds divalent calcium ions, and TnI--affects myosin-actin interactions. Tn subunits display several molecular and calcium binding variations. During ontogenetic development of cardiac and skeletal muscles the synthesis of multiple isoforms of Tn subunits was detected. Expression of Tn isoforms and the extent of phosphorylation of both TnT and TnI via protein kinase C or protein kinase A under different pathological situations (e.g. ischemia, congenital heart disease, heart failure) can affect the Ca2+-stimulated contraction function and the myofibrillar ATPase activity of the heart.
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PMID:Isoforms of troponin in normal and diseased myocardium. 1063 75

Troponin I (TnI) is the component of the troponin complex, TnI, TnC, TnT, that is responsible for inhibition of actomyosin ATPase activity. Using the fluorescence of pyrene-labeled tropomyosin (Tm), we probed the interaction of TnI and TnIC with Tm on the reconstituted muscle thin filament. The results indicate that TnI and TnIC(-Ca(2+)) bind specifically and strongly to actin-Tm with a stoichiometry of 1 TnI or 1 TnIC/1 Tm/7 actin, in agreement with previous results. The binding of myosin heads (S1) to actin-Tm at low levels of saturation caused TnI and TnIC to dissociate from actin-Tm. These results are interpreted in terms of the S1-binding state allosteric-cooperative model of the actin-Tm thin filament, closed/open. Thus, TnI and TnIC(-Ca(2+)) bind to the closed state of actin-Tm and their binding is greatly weakened in the S1-induced open state, indicating that they act as allosteric inhibitors. The fluorescence change and the stoichiometry indicate that the TnI-binding site is composed of regions from both actin and Tm probably in the vicinity of Cys 190.
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PMID:Binding of troponin I and the troponin I-troponin C complex to actin-tropomyosin. Dissociation by myosin subfragment 1. 1065 59


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