A spectral probe mutant (F29W) of chicken skeletal muscle troponin C (TnC) has been prepared in which Phe-29 has been substituted by Trp. Residue 29 is at the COOH-terminal end of the A helix immediately adjacent to the Ca2+ binding loop of site I (residues 30-41) of the regulatory N domain. Since this protein is naturally devoid of Tyr and Trp, spectral features can be assigned unambiguously to the single Trp. The fluorescent quantum yield at 336 nm is increased almost 3-fold in going from the Ca(2+)-free state to the 4Ca2+ state with no change in the wavelength of maximum emission. Comparisons of the Ca2+ titration curves of the change in far-UV CD and fluorescence emission indicated that the latter was associated only with the binding of 2Ca2+ to the regulatory sites I and II. No change in fluorescence was detected by titration with Mg2+. The Ca(2+)-induced transitions of both the N and C domains were highly cooperative. Addition of Ca2+ also produced a red shift in the UV absorbance spectrum and a reduction in positive ellipticity as monitored by near-UV CD measurements. The fluorescent properties of F29W were applied to an investigation of five double mutants: F29W/V45T, F29W/M46Q, F29W/M48A, F29W/L49T, and F29W/M82Q. Ca2+ titration of their fluorescent emissions indicated in each case an increased Ca2+ affinity of their N domains. The magnitude of these changes and the decreased cooperativity observed between Ca2+ binding sites I and II for some of the mutants are discussed in terms of the environment of the mutated residues in the 2Ca2+ and modeled 4Ca2+ states.(ABSTRACT TRUNCATED AT 250 WORDS)
The interactions of troponin-I (Tn-I) with a variety of fragments spanning the length of the troponin-T (Tn-T) polypeptide chain have been reinvestigated at physiological ionic strength by affinity chromatographic, gel filtration, and circular dichroism methodologies. Strong binding was observed with fragment T2 (residues 159-259) mimicking that observed with whole Tn-T and Tn-I. Partial binding was seen with the shorter cyanogen bromide (CB) fragments of Tn-T in the order CB4 (residues 176-230) greater than CB6 (residues 239-259) or CB5 (residues 152-175). No interaction with Tn-I was observed with fragments (CB2, CB3, T1) encompassing residues 1-158 of Tn-T. Based on the present results and the work of others, the binding region for Tn-I includes residues 159-259 and perhaps extends into the highly helical CB2 region (residues 71-151) of Tn-T. No evidence has been obtained by ourselves or others for the interaction of the CB3 region (1-70) with Tn-I. A significant increase (11.6%) in alpha-helical content was observed when an equimolar amount of fragment T2 (residues 159-259) was mixed with Tn-I, a result similar to that seen with whole Tn-T and Tn-I.
The two globular N and C domains of chicken troponin C (TnC) are connected by an exposed alpha-helix (designated D/E; residues 86-94). Recombinant N (residues 1-90) and C (residues 88-162) domains containing either F29 or W29 and F105 or W105 have been engineered and expressed in Escherichia coli. These termination and initiation sites were chosen to minimize disruption of side-chain interactions between the D/E helix and other residues. W29 and W105 served as useful spectral probes for monitoring Ca(2+)-induced structural transitions of the N and C domains, respectively [Pearlstone et al. (1992) Biochemistry 31, 6545-6553; Trigo-Gonzalez et al. (1992) Biochemistry 31, 7009-7015]. By all criteria tested, the properties of the isolated F29W/N domain (1-90) were identical to those of the N domain in intact F29W. These included fluorescence emission spectra in the absence and presence of Ca2+/Mg2+, far-UV CD spectra, and Ca2+ affinity as monitored by fluorescence and ellipticity at 221 nm. Similar but not identical properties were observed for isolated F105W/C domain (88-162) and intact F105W. A summation of the far-UV CD spectra (+/- Ca2+) of the two domains was virtually superimposable on that of the intact protein. Of the total Ca(2+)-induced ellipticity change at 221 nm, 27% could be assigned to the N domain and 73% to the C domain. The data suggest a significant Ca(2+)-induced transition involving secondary structural elements of the N domain.(ABSTRACT TRUNCATED AT 250 WORDS)
The regions of troponin I (TnI) responsible for Ca 2؉ dependent activation and Ca 2؉ sensitivity of the actinmyosin 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-(
Ca2+ and human cardiac troponin I (cTnI) peptide binding to human cardiac troponin C (cTnC) have been investigated with the use of 2D [1H,15N] HSQC NMR spectroscopy. The spectral intensity, chemical shift, and line-shape changes were analyzed to obtain the dissociation ( K(D)) and off-rate ( k(off)) constants at 30 degrees C. The results show that sites III and IV exhibit 100-fold higher Ca2+ affinity than site II ( K(D(III,IV)) approximately 0.2 microM, K(D(II)) approximately 20 microM), but site II is partially occupied before sites III and IV are saturated. The addition of the first two equivalents of Ca2+ saturates 90% of sites III and IV and 20% of site II. This suggests that the Ca2+ occupancy of all three sites may contribute to the Ca2+-dependent regulation in muscle contraction. We have determined a k(off) of 5000 s(-1) for site II Ca2+ dissociation at 30 degrees C. Such a rapid off-rate had not been previously measured. Three cTnI peptides, cTnI(34-71), cTnI(128-147), and cTnI(147-163), were titrated to Ca2+-saturated cTnC. In each case, the binding occurs with a 1:1 stoichiometry. The determined K(D) and k(off) values are 1 microM and 5 s(-1) for cTnI(34-71), 78+/-10 microM and 5000 s(-1) for cTnI(128-147), and 150+/-10 microM and 5000 s(-1) for cTnI(147-163), respectively. Thus, the dissociation of Ca2+ from site II and cTnI(128-147) and cTnI(147-163) from cTnC are rapid enough to be involved in the contraction/relaxation cycle of cardiac muscle, while that of cTnI(34-71) from cTnC may be too slow for this process.
In contrast to skeletal muscle, the efficiency of the contractile apparatus of cardiac tissue has long been known to be severely compromised by acid pH as in the ischemia of myocardial infarction and other cardiac my- 2؉ sensitivity of cardiac contractility at low pH (
The actomyosin ATPase inhibitory protein troponin I (TnI) plays a central regulatory role in skeletal and cardiac muscle contraction and relaxation through its calcium-dependent interactions with troponin C (TnC) and actin. Previously we have demonstrated the utility of F29W and F105W mutants of TnC for measurement of binding affinities of inhibitory peptide TnI(96-116) to its regulatory N and structural C domains, both in isolation and in the intact TnC molecule [Pearlstone, J. R. & Smillie, L. B. (1995) Biochemistry 34, 6932-6940]. This approach is now extended to fragment TnI(96-148). Curve-fitting analyses of fluorescence changes induced in the intact TnC mutants and the isolated N and C domains by increasing [TnI(96-148)] have permitted the assignments of K(D) values (designated K(D,N) and K(D,C)) to the interaction of TnI(96-148) with the N and C domains, respectively, of intact TnC. Taken together with the previous data for TnI(96-116) binding, it can be concluded that, within TnI(96-148), residues 96-116 are primarily responsible for binding to C domain of intact TnC and residues 117-148 to its N domain. Inspection of the available mammalian and avian skeletal muscle TnI amino acid sequences reveals a previously unrecognized conserved motif repeated 3-fold, once in the inhibitory peptide region (approximately residues 101-114; designated alpha) and twice more in the region of residues approximately 121-132 (beta) and approximately 135-146 (gamma). The number and distribution of these motifs have important structural implications for the TnI x C complex. In the beta motif of cardiac TnI, as compared with skeletal, several changes in charged amino acids are suggested as candidates responsible for the greater sensitivity of cardiac Ca2+-regulated actomyosin to acidic pH as in ischemia.
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