Identification of Binding Sites for Bepridil and Trifluoperazine on Cardiac Troponin C*

Quinn Kleerekoper, Wen Liu, Daeock Choi, and John A. PutkeyDagger

From the Department of Biochemistry and Molecular Biology, University of Texas Medical School, Houston, Texas 77030

    ABSTRACT
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Abstract
Introduction
Procedures
Results
Discussion
References

The solution structure of cardiac troponin C (cTnC) (Sia, S., Li, M. X., Spyracopoulos, L., Gagne, S. M., Liu, W., Putkey, J. A. & Sykes, B. D. (1997) J. Biol. Chem. 272, 18216-18221) challenges existing structure/function models for this critical regulatory protein. For example, it is clear that the closed conformation of the regulatory N-terminal domain in Ca2+-bound cardiac troponin C (cTnC) presents a much different binding surface for Ca2+-sensitizing compounds than previously thought. We report here the use of Met methyl groups as site-specific structural markers to identify drug binding sites for trifluoperazine and bepridil on cTnC. Drug dependent changes in the NMR heteronuclear single-quantum coherence spectra of [methyl-13C]Met-labeled cTnC indicate that bepridil and trifluoperazine bind to similar sites but only in the presence of Ca2+. There are 3-4 drug binding sites in the N- and C-terminal domains of intact cTnC that exhibit fast exchange on the NMR time scale. Use of a novel spin-labeled phenothiazine and detection of isotope-filtered nuclear Overhauser effects allowed identification of drug binding sites in the shallow hydrophobic cup in the C-terminal domain and on two hydrophobic surfaces on the N-terminal regulatory domain. The data presented here, coupled with our previous study using covalent blocking groups, support a model in which the Ca2+-sensitizing binding site includes Met-45 in helix B of site I, and Met-60 and -80 in helices B and C of the regulatory site II. This subregion in cTnC makes a likely target against which to design new and selective Ca2+-sensitizing compounds.

    INTRODUCTION
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Abstract
Introduction
Procedures
Results
Discussion
References

The ability to sensitize cardiac muscle to Ca2+ would have promising therapeutic potential for the treatment for Ca2+ desensitization that is associated with congestive heart failure due to acute myocardial infarction and associated ischemia (1). Ideally, the mechanism of sensitization would not involve altering Ca2+ transients in myocardial cells that are already metabolically challenged. Regulatory proteins located on the thin filament of cardiac muscle are logical targets for such therapeutic compounds since they respond to cellular Ca2+ levels but are not involved in modulation of Ca2+ transients.

Cardiac troponin C (cTnC)1 is the EF-hand Ca2+ binding receptor on the thin filament of slow skeletal and cardiac striated muscle. Cardiac muscle contraction is initiated when Ca2+ binds to the N-terminal regulatory metal binding site II in cTnC. Muscle relaxation occurs upon release of Ca2+ from this regulatory site. This central role for cTnC makes it an attractive target for putative Ca2+-sensitizing compounds designed to modify the Ca2+ dependence of cardiac muscle contraction. Indeed, precedents have been established for both desensitization and sensitization of cardiac muscle to Ca2+ via mechanisms that involve cTnC. Phosphorylation of Ser-22 and -23 cardiac troponin I (cTnI), which is constitutively associated with cTnC in the troponin complex, leads to a decrease in the Ca2+ sensitivity of cardiac muscle fibers and myofibrils (2) and to a decrease in the affinity of site II in cTnC (3). In contrast, a variety of small hydrophobic compounds including the calmodulin antagonists bepridil (4-6), trifluoperazine (TFP) (7), and calmidazolium (7-9) have the opposite effect of increasing the Ca2+ sensitivity of cardiac muscle preparations. Bepridil has been shown to increase the affinity of cTnC for Ca2+ by decreasing the Ca2+ off-rate (5, 6). Such reports have led to a search for new generations of Ca2+-sensitizing compounds with greater specificity for cTnC (1).

Knowledge of the structure of cTnC and identification of potential drug binding sites on this protein would help facilitate the design or selection of Ca2+-sensitizing compounds with desired pharmacological effects. Until recently, high resolution structural information was only available for the fast skeletal isoform of TnC (sTnC) (10, 11). Structural models for Ca2+-bound cTnC have been proposed based on the structures of sTnC and calmodulin. Not surprisingly, these models predict an open N-terminal regulatory domain of Ca2+-bound cTnC, with an exposed hydrophobic surface similar to the structure of sTnC and calmodulin. Existing models for drug binding to cTnC propose that these compounds bind to this exposed N-terminal hydrophobic pocket (5, 12, 13). Recently, the NMR solution structures of Ca2+-bound intact cTnC (14), and the apo and Ca2+-saturated N-terminal regulatory fragment (15) were reported. The most striking feature of these structures is that the Ca2+-bound N-terminal regulatory domain is partially closed, resulting in significantly less exposed hydrophobic surface than found in Ca2+-bound sTnC. These structures have significant implications with respect to drug binding sites in cTnC.

The goal of the current study was to generate structural information on the binding of bepridil and TFP to full-length cTnC and to correlate these data with the solution structure of this critical Ca2+-regulatory protein. We chose both drugs based on their known Ca2+-sensitizing affects on cTnC. The data presented here, coupled with our previous study using covalent blocking groups (16), support a model in which bepridil and TFP bind to multiple sites on cTnC, including two hydrophobic surfaces in the N-terminal domain. The Ca2+-sensitizing binding site is predicted to be a hydrophobic patch that includes Met-45 in helix B of site I and Met-60 and -80 in helices B and C of the regulatory site II. This subregion in cTnC makes a likely target against which to design new and selective Ca2+-sensitizing compounds.

    EXPERIMENTAL PROCEDURES
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Abstract
Introduction
Procedures
Results
Discussion
References

Chemicals-- Bepridil, and 4-amino-TEMPO were purchased from Sigma. TFP, 2-(trifluoromethyl)phenothiazine, tetrahydrofuran, and 1,3-dibromopropane were obtained from Aldrich. L-Methionine-methyl-13C, L-phenylalanine (D8), Tris-d11, deuterium oxide, dimethyl sulfoxide-d6, and methanol-d were obtained from Cambridge Isotope Labs.

NMR Sample Preparation-- The bacterial expression of cTnC(A-Cys) (17), its labeling with [methyl-13C]Met (18) and the purification of recombinant cTnC proteins (19) were reported previously. To eliminate the possibility of NOEs being detected between the Phe residues and [methyl-13C]Met residues in the drug-protein complexes, the protein was labeled with L-Phe (D8). The NMR samples varied in protein concentration from 0.2 to 3.5 mM in 20 mM Tris-d11, 200 mM KCl, and D2O at pH 7.0.

NMR Methods-- All spectra were collected at 40 °C using Bruker AMX500 or GN500 NMR spectrometers. HSQC (20) spectra were collected with 1024 complex data points in the t2 domain and 72 increments in t1 at 40 °C. The 1H and 13C spectra widths were 6012 and 600 Hz, respectively. 1H and 13C chemical shifts were reported relative to the HDO signal at 4.563 ppm and the [methyl-13C]Met signal at 14.86 ppm, respectively. All spectra were processed using the FELIX software package (Biosyms Technologies, Inc.). The 1H-13C correlations for [methyl-13C]cTnC(A-Cys) were assigned by comparison to known assignments for cTnC (C35S) (18). NOEs between bepridil and cTnC(A-Cys) were obtained from a 2D NOESY experiment using 13C(omega 1,omega 2)-double-half-filter (21, 22). A mixing time of 310 ms was used for the complex. The 1H spectra widths were 6012 and 5000 Hz, respectively.

Synthesis of TEMPO-TFP-- N-(3-(4-Amino-TEMPO)propyl)-2-(trifluoromethyl)phenothiazine was synthesized by a two-step procedure. 2-(Trifluoromethyl)phenothiazine (2.67 g, 10 mmol) in tetrahydrofuran (10 ml) was added to a suspension of NaH (0.48 g, 20 mmol) in tetrahydrofuran. The stirred suspension was heated to 50 °C for 1 h then cooled to room temperature. 1,3-Dibromopropane (1.22 ml, 12.0 mmol) in tetrahydrofuran (5 ml) was then added over 10 min. The resulting slurry was stirred at room temperature for 2 h. The reaction mixture was filtered, and the filtrate concentrated in vacuo. The residue was subjected to flash silica gel chromatography (2% ether/hexanes to 50% ether/hexanes). After collection of the high Rf N-allyl compound (1.0 g, 39%), the desired N-(3-bromopropyl)-2-(trifluoromethyl)phenothiazine (0.14 g, 3.6%) was obtained as a viscous oil. 1H NMR (CDCl3) delta  2.25-2.31 (m), 3.52 (t, J = 9.0), 4.11 (t, J = 6.5), 6.90-7.25 (m).

The primary bromide was combined with 4-amino-TEMPO (25 mg, 0.15 mmol) and NaHCO3 (32 mg, 0.30 mmol) in N-methyl-2-pyrrolidinone (2 ml). The mixture was established under nitrogen and heated at 100 °C for 1 h. After cooling to room temperature, the reaction mixture was partitioned between water and diethyl ether. The organic layer was dried over MgSO4 and concentrated in vacuo. The desired product was isolated from the residue by flash silica gel chromatography (5% methanol/chloroform) to provide 35 mg (45%) of a red/brown oil. The fast atom bombardment mass spectrum for this compound of 479.4 (MH+) was consistent with that calculated for the desired product (C25H31F3N3OS, M = 478.6). This product was taken on without further characterization to the hydrobromide salt (HBr in acetic acid) which was obtained as a solid from diethyl ether. An ESR spectrum was collected for the final bromide salt of N-(3-(4-amino-TEMPO) propyl)-2-(trifluoromethyl)phenothiazine.

Drug Solutions-- Stock solutions of each drug were prepared initially before use. Bepridil was prepared in a 80% D2O, 20% methanol-d4 solution and a stock solution of TFP was prepared in D20. TEMPO-TFP was prepared in methanol-d4. The stock solutions of TFP that are light sensitive were stored in the dark. For each drug titration, the sample pH was adjusted when necessary. To reduce the nitroxide radical on the spin-label, TEMPO-TFP, a 2-fold molar excess of ascorbic acid was added to the NMR sample.

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

Drug and Protein Structures-- In previous studies, we assigned the 10 methionyl methyl 1H-13C correlations (18) in recombinant cTnC and used them as general markers to monitor Ca2+ and cTnI binding to cTnC (23-25). The solution structure of cTnC allows these assignments to be used as positional markers for drug binding. Fig. 1 shows the location methionyl methyl carbons in a ribbon rendering of intact cTnC (Fig. 1A), and solvent accessible surfaces in the N-terminal (Fig. 1, B and C) and C-terminal (Fig. 1D) domains. Hydrophobic residues are shown in blue, all other residues are in white, and the methionyl methyl groups are shown in red. Fig. 1E shows the structures of the compounds used in this study. Both bepridil and TFP have a positively charged nitrogen at pH 7.0. The spin-labeled phenothiazine, which we will call TEMPO-TFP, was designed to mimic the primary structural features of TFP including the intact phenothiazine rings and a positively charged amine. Synthesis of this compound is described under "Experimental Procedures."


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Fig. 1.   Solution structure of cTnC and chemical structures of bepridil, TFP, and TEMPO-TFP. Panels A-D show different structural aspects of the solution structure of Ca2+-bound cTnC. Hydrophobic residues are shown in purple, all other polar and charged residues are in white, whereas the Met methyl groups are in red. Panel A shows the positions of all 10 Met methyl groups in a ribbon structure of cTnC. Panels B and C show two different perspectives of solvent accessible surfaces in the N-terminal domain, and panel D shows the solvent accessible surface of the shallow hydrophobic cup in the C-terminal domain. Panels A-D were generated using Insight `95. Accessible surface was calculated using the Connolly algorithm and a 1.4 Å probe. Panel E shows the chemical structures of the compounds used in this study.

Effect of Bepridil and TFP on cTnC-- Initial experiments involved titration of [methyl-13C]Met-labeled cTnC with bepridil or TFP to assign chemical shifts in the presence of the drugs, and to identify similarities or differences in patterns of chemical shift changes. Unless otherwise indicated, all experiments were performed using recombinant cTnC(A-Cys) (17). This protein has both Cys-35 and -84 converted to Ser to prevent formation of inter- and intramolecular disulfide bonds during NMR analysis that can affect the hydrophobic surfaces and functional characteristics of cTnC. cTnC(A-Cys) is active and was used in determining the solution structure of Ca2+-bound full-length cTnC (14). The methionyl methyl 1H-13C correlations observed for free cTnC(A-Cys) in the presence Ca2+ were essentially identical to those previously reported for cTnC(C35S) (18).

The HSQC spectra in Fig. 2, panel A, shows the effect of bepridil on the methionyl methyl 1H-13C correlations in cTnC(A-Cys) in the absence of Ca2+. The addition of drug in molar excess over protein resulted in small chemical shift changes for all the Met residues. The apparent binding constant for association of bepridil with 3Ca2+-cTnC is approximately 10-20 µM (4, 5). We do not attribute the small chemical shift changes seen in Fig. 2 to high affinity binding of bepridil to specific sites since 1) equilibrium dialysis at lower drug and protein concentrations (200 µM of cTnC(A-Cys)) showed no evidence of bepridil binding in the absence of Ca2+. Equilibrium dialysis in the presence of Ca2+ yielded an apparent binding constant of 20 µM (data not shown); 2) we were unable to detect NOEs between the N-terminal Met methyl groups of cTnC(A-Cys) and protons on the aromatic rings of bepridil in the absence of Ca2+ (see below); and 3) the magnitude of drug-induced chemical shift changes seen in the absence of Ca2+ were minor relative to those observed in the presence of Ca2+ (see below). These data suggest the minor chemical shift changes and line broadening seen for the Mets in the absence of Ca2+ are due to nonspecific weak binding of the drug at mM concentrations used in the NMR experiments.


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Fig. 2.   Titration of apo (panel A) and 2Ca2+-cTnC(A-Cys) (panel B) with bepridil. HSQC spectra of [methyl-13C]Met cTnC (A-Cys) showing the Met methyl 1H-13C correlations at bepridil:protein ratios of 0, 1, and 2 equivalents. The initial peaks without drug are shown in green. The 1H-13C Met methyl correlation for Met-45 shown in the box is at a 4-fold lower contour level.

Fig. 2, panel B, shows that addition of bepridil to the 2Ca2+ form of cTnC(A-Cys), in which the high affinity Ca2+ binding sites III and IV are filled, induced large chemical shift changes for Met-120 and -157. Minor changes in the chemical shifts for N-terminal Met residues are of a magnitude seen in the absence of Ca2+. This suggests that binding of the drug is restricted to the C-terminal domain when Ca2+ is bound only to sites III and IV.


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Fig. 3.   Titration of 3Ca2+-cTnC(A-Cys) with bepridil and TFP. Chemical shift changes for Met residues located in the N-terminal domain (panels A and C) are plotted separately from those in the C-terminal domain (panels B and D). Bepridil was added in 0.5 equivalents to a drug/protein ratio of 4 (panels A and B). TFP was added in 1.0 equivalents to a drug:protein ratio of 6 (panels C and D). All drug additions (blue peaks) are shown only for Met-45 and -157, respectively. The methyl 1H-13C correlation for Met-45 was observed only at a greater than 10-fold lower contour after addition of one equivalent of either drug.

Fig. 3 and Table I show chemical shift changes as the Ca2+-bound cTnC(A-Cys) is titrated with bepridil (Fig. 3, panels A and B) or TFP (panels C and D). Each panel shows the superimposition of spectra obtained at different ratios of drug:protein. The 1H-13C correlations attributed to Met groups located in the N-terminal domain (panels A and C) are shown separately from those in the C-terminal domain (panels B and D). The initial peaks in the absence of drugs are shown in green, whereas red indicates peaks at high concentration of drug. The arrows point in the direction of chemical shift change as the drug was added. The blue peaks correspond to intermediate drug:protein ratios and are shown only for Met-45 and -157, which experience the greatest drug-induced change.

                              
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Table I
Drug-induced changes in chemical shifts of methyl 1H and 13C resonances in Ca2+-saturated cTnC(A-Cys)
The chemical changes are derived from titration of Ca2+-saturated cTnC(A-cys) with either bepridil or TFP. The accuracy of the measurements are ±0.01 for 1H and ±0.1 for 13C.

The data show that 1H chemical shift changes are observed for all groups except Met-137, which suggests binding sites in both the N- and C-terminal domains. The drug binding sites for both bepridil and TFP exhibit fast exchange characteristics relative to the chemical shift time scale as evidenced by single cross peaks in the HSQC spectra at a given drug:protein ratio, and the fact that these changes are seen for all affected Mets at drug to protein ratios below 1:1. Met-45 shows the greatest drug-induced change at increasing bepridil or TFP concentrations. The resonance for Met-45 broadens significantly at intermediate levels of drug, requiring a greater than 10-fold lower contour level to observe this peak, but then sharpens somewhat at saturating drug levels. This is indicative of intermediate exchange taking place for the methyl group of Met-45 between the free and drug-bound states of cTnC(A-Cys), possibly due to a localized slow conformational transition.

Fig. 4 plots 1H chemical shift changes as a function of added bepridil for Met-45, -47, -120, and -157, which experience the greatest overall change. Drug-induced changes reach 90-100% of maximal at a drug to protein ratio of 3:1. Table I shows that 1H chemical shifts for the other Met residues reach a plateau at a bepridil:protein ratio of 3.5:1, and there is no significant difference in the 13C chemical shifts at bepridil:protein ratios of greater than 3:1. This suggests that 3-4 mol of bepridil bind per mol of protein. Additional drug molecules may bind but without altering the Met methyl groups. Binding of TFP to cTnC appears more complex. Although the major changes are seen upon the addition of 3 equivalents of TFP, additional but smaller changes in the 1H chemical shifts are induced upon the addition of 4 and 6 equivalents of TFP. Nevertheless, it is clear that both bepridil and TFP induce similar patterns in chemical shift changes and that the majority of these changes are achieved at a drug to protein ratio of 3.


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Fig. 4.   Percent of maximal bepridil-induced change in 1H chemical shift of select Met. Chemical shift changes for Met-45 and -47 (panel A) and Met-120 and -157 (panel B) are expressed as a percent of the maximal change observed after addition of 4 mol of bepridil per mol of protein. Raw chemical shift data is taken from Table I.

Effect of TEMPO-TFP on Met Methyl Chemical Shifts-- A number of the Mets reside in close proximity to the Phe residues in the protein and could be affected by local ring current fields. Thus, the chemical shifts changes seen in Fig. 3 and Table I could be attributed to either direct ring current effects from TFP and bepridil or from a secondary effect resulting from drug-induced protein conformational changes that alter the positions of the Met methyl groups relative to Phe side chains. The latter mechanism would be more likely for Met residues such as Met-81 and -157, which are within ~3.4 Å of the Phe ring, rather than Met-45 and -60 which are no closer than ~6.5 Å from the nearest Phe ring.

To distinguish between direct and indirect effects of the drugs, we chose two lines of experiments. The first involved the use of a spin-labeled phenothiazine (TEMPO-TFP in Fig. 1E), the second uses 13C-filtered NOESY NMR experiment to identify NOEs between drug and cTnC. The paramagnetic effect of spin labels on chemical shift line widths is a low resolution technique that can measure distances from between 10 and 15 Å (26). We have used spin labels successfully in measuring solvent exposure of Met methyl groups as well as determining central helix flexibility in cTnC when free or bound to cTnI (23, 24). If the Met methyl groups participate in the formation of the drug binding sites, then TEMPO-TFP will result in line broadening of the 1H-13C correlations for those Mets. Thus, TEMPO-TFP is used here simply to identify which Met side chains are in the drug binding sites.

The HSQC spectra in Fig. 5, panel A, compares the Met methyl chemical shifts of Ca2+-bound cTnC in the presence and absence of reduced diamagnetic TEMPO-TFP at a probe-to-protein ratio of 0.8. The reduced compound should not affect the chemical shift line width but should alter chemical shift positions if it binds in a manner similar to TFP. Indeed, TEMPO-TFP-induced chemical shift changes comparable in magnitude and nature to those induced by TFP at a similar probe to protein ratio. Fig. 5, panel B, shows the paramagnetic effect of oxidized TEMPO-TFP on Met methyl groups. All 1H-13C correlations are broadened beyond detection at this contour level except that for Met-137. These data demonstrate that: 1) the paramagnetic effect of TEMPO-TFP is due to specific binding since a nonspecific effect of the soluble compound would likely result in broadening of all resonances including Met-137; 2) Met-137, which is on the opposite side of the C-terminal domain relative to the C-terminal hydrophobic surface, is not included in a drug binding site; and 3) all Met methyl groups except Met-137 are within about 10 Å from a bound drug. TEMPO-TFP will prove very useful for subsequent studies of drug binding sites on cTnC when associated with the cTnI or the intact troponin complex.


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Fig. 5.   Effect of TEMPO-TFP on 3Ca2+-TnC(A-Cys). Panel A shows the HSQC spectra of the Met methyl 1H-13C correlations of cTnC(A-Cys) in the absence (green peaks) or presence (red peaks) of 0.8 equivalents of reduced TEMPO-TFP. TEMPO-TFP was reduced with ascorbic acid as described under "Experimental Procedures." Panel B shows methyl 1H-13C correlations in the presence of 0.8 equivalents of oxidized TEMPO-TFP. Only Met-137 is detected in the presence of the oxidized paramagnetic TEMPO-TFP. All spectra are shown at the same contour level.

NOEs between Bepridil and Met Methyl Groups-- Bepridil was chosen for additional experiments designed to identify NOEs between drug and Met residues in 3Ca2+-cTnC. cTnC(A-Cys) was labeled with both [methyl-13C]Met and L-Phe[D8] to eliminate intraprotein NOEs between the Met methyl groups and Phe side chains. Isotope editing allowed the select observation of NOEs between the Met methyl protons attached to 13C and aromatic protons on bepridil. Control 1D spectra confirmed the efficiency of labeling with L-Phe[D8] (data not shown).

Fig. 6 shows the spectra from the 13C-edited 2D NOESY experiment at drug:protein ratios of 1.5:1 (panels A, B, and C) and 3.5:1 (panels D, E, and F). Panels A and D show the 1H dimension of the 2D 1H-13C HSQC, whereas panels B and E show the 1H-13C HSQC that were used to assign and determine the intensity of each resonance at the given drug concentration. NOEs between the aromatic protons in bepridil and protons attached to [methyl-13C]Met are shown in panels C and F. At the lower drug to protein ratio, strong NOEs are observed between the 3,5 aromatic protons on the drug and the methionyl protons of Met-60 and -80. Weaker NOEs are detected between the drug and the other Met residues. Due to resonance overlap with Met-81, the NOE to Met-45 cannot be observed, however at a drug:protein ratio below 1 a NOE to Met-45 was detected. At high drug:protein ratios, NOEs between bepridil and Met-60 and -80 persist, and NOEs between bepridil and other Met residues are strengthened in intensity. The NOE at 1.89 ppm in panel C cannot be clearly assigned to Met-103 or -137 due to resonance overlap. However, we have tentatively assigned this NOE to Met-103 since: 1) panel F shows no apparent NOE to Met-137; 2) TEMPO-TFP has no effect on the chemical shift of Met-137; and 3) neither TFP nor bepridil have a significant effect on the 1H chemical shift of Met-137 (Table I). These filtered NOEs show that all methyl groups except 137 are likely within 5 Å of aromatic rings in bound bepridil molecules and that the hydrophobic surface that includes Met-60 and -80 appears to constitute a preferred binding site at lower concentrations of drug.


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Fig. 6.   Detection of NOEs between bepridil and 3Ca2+ cTnC. Panels A, B, and C shows spectra collected at a drug-to-protein ratio of 1.5:1, whereas the spectra in panels D, E, and F were collected at a drug-to-protein ratio of 3.5:1. The 1H spectra of the HSQC spectra are shown in panels A and D. The corresponding 2D HSQC of the Met methyl 1H-13C correlations is shown in panels B and E. Panels C and F show a subspectrum of a 2D 1H NOESY recorded with a 13C double half-filter showing NOEs between the aromatic region of bepridil and the Met methyl groups. All NMR spectra were recorded at 40 °C using a 3.5 mM sample of cTnC double-labeled with [methyl-13C]Met and Phe(D8). Buffer conditions are given under "Experimental Procedures."

    DISCUSSION
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Abstract
Introduction
Procedures
Results
Discussion
References

The overall goal of the current study was to identify sites on cTnC that can bind cardiotonic compounds and potentially alter the Ca2+ binding affinity of site II. We chose bepridil and TFP as test compounds since previous reports show that they bind to sTnC (4, 5, 27) or sTnC peptides (28-30) and have clear Ca2+-sensitizing effects on muscle preparations (4, 7, 9, 31, 32). It was reasoned that identification of binding sites for these compounds and the unique opportunity to correlate structural drug binding data with the recent high resolution solution structure of cTnC (14, 15) would implicate drug binding sites that contribute to Ca2+ sensitization and provide a foundation for the development of compounds that are specific for cTnC.

In a previous study, MacLachlan et al. (5) reported binding of one bepridil molecule to the N-terminal domain of cTnC. The drug was proposed to make contact with Met-81, and a model for drug binding was presented based on tentative chemical shift assignments and a structure for Ca2+-bound cTnC that was based on the open conformation of sTnC. In contrast to MacLachlan's study, our data differ markedly in both the number and location of bepridil binding sites. Differences in the number of drug binding sites can be attributed to the experimental conditions used in each study. At pH 7.0 used here, bepridil is fairly soluble, whereas at a higher pH used in the previous study, bepridil precipitates at drug:protein ratio of greater than 1:1. Differences in locations of bound bepridil can be attributed to incorrect chemical shift assignments in the previous study. Met-81 was assigned a chemical shift of 2.15 ppm, whereas its correct assignment is 1.38 ppm. Confidence in the location of the drug binding sites reported here is based on the unambiguous assignments of methionyl Met chemical shifts, and the use of heteronuclear NMR to clearly monitor chemical shift changes and for the collection NOE distance constraints.

Bepridil and TFP bind to cTnC only in the presence of Ca2+ with rapid exchange of drug between multiple binding sites in the N- and C-terminal domains. The stoichiometry of binding either drug was roughly the same, and the observed patterns of Met methyl chemical shift changes were remarkably similar for both drugs. This suggests that bepridil and TFP bind similar sites on cTnC. The C-terminal drug binding sites appear to be restricted to the hydrophobic inside surface of a shallow cup formed by the C-domain upon Ca2+ binding to sites III and IV (see Fig. 1D). This surface includes side chains for Met-103, -120, and -157, but not -137. This conclusion is based on: 1) the large chemical shift changes seen for the methyl groups of Met-120 and -157; 2) the paramagnetic effect of the oxidized TEMPO-TFP on the methyl 1H-13C correlations for Met-103, -120, and -157, but not -137; and 3) observed NOEs between bepridil and Met-103, -120, and -157.

Pan and Johnson (33) recently showed that binding of EMD 57033 to cTnC, required the high affinity sites III and IV to be occupied with Ca2+. Thus, the hydrophobic surface in the C-terminal domain of free cTnC appears to present binding sites for calmodulin antagonists TFP and bepridil as well as EMD 57033. A pertinent question is whether binding of these compounds to the C-terminal domain can affect the characteristics of Ca2+ binding to the N-terminal domain. Intradomain communication in cTnC has been reported previously (34). In addition, the Ca2+ binding affinity of site II in cTnC is increased by inactivation of sites III and IV (35), whereas the affinity of sites III and IV in C-terminal fragments of both cTnC (35) and sTnC (36) are increased relative to the intact protein. However, these observations should be interpreted cautiously with respect to an interdomain effect of drugs in the troponin complex. The cTnI inhibitory peptide was shown to shield Met-120 and -157 from solvent (23), and association of cTnC with cTnI causes significant change in the Met chemical shifts of Met-120 and -157 (24, 25). This suggests that association of cTnI may displace compounds bound to the C-terminal domain of cTnC.

Drug binding to the N-terminal domain must be considered with respect to the pattern of N-terminal hydrophobic surfaces, distances between Met methyl groups and NOEs between protons in bepridil and the methionyl methyl groups. Fig. 1 shows the N-terminal domain of cTnC to contain discrete hydrophobic surfaces. One surface includes the side chains of Met-47, -81, and -85 (Fig. 1B), whereas the other includes Met-45, -60, and -80 (Fig. 1C). The methyl groups of Met-47 and -60 are 16.7 Å apart and on different surfaces of the N-terminal domain. Thus, it seems unlikely that they could participate in the same drug binding site. Even if bepridil were to induce a separation of helices A and B, to more fully open the N-terminal domain and generate a contiguous hydrophobic surface, the methyl groups of Met-47 and -60 would be separated by about 17 Å. Given these structural constraints and the fact that at least 3 mol of drug bind per mol of protein, it is more likely that the N-terminal domain has multiple drug binding sites. Modeling of bepridil binding to the hydrophobic surface seen in Fig. 1B shows that NOEs could be generated between one aromatic ring in bepridil and Met-47 and between the other aromatic ring and Met-81 and -85. In addition, stabilizing electrostatic interactions could form between bepridil and Glu-19. The other binding site would include the hydrophobic patch seen in Fig. 1C. The methyl group of Met-60 is 5.5 and 7.5 Å from those of Met-45 and -80, respectively, and the methyl groups of Met-45 and -80 are separated by only a 3.5 Å distance. Thus a single drug molecule bound to this site could generate NOEs with the methyl groups of all three Mets.

In a previous study we tested the functional consequence of covalently coupling a 9 amino acid peptide to single Cys residues in cTnC (16). These experiments were designed to mimic the steric blocking effects of noncovalently bound drugs. Our general conclusion was that the N-terminal regulatory domain had discrete hydrophobic surfaces with different functions. One surface, which includes Met-81, is important for activity since blocking groups attached to Cys at position 81 greatly inhibited the activity of cTnC. This surface appears to interact with cTnI since position 81 can be readily cross-linked to cTnI (16) and since the methyl 1H-13C correlation of Met-81 is significantly affected by association of cTnC with cTnI or cTnI peptides (25). In contrast, no significant functional effect was seen when blocking groups were attached to Cys at position 45, and the methyl 1H-13C correlation of Met-45 is not affected by cTnI. Together these data suggest that drugs that are noncovalently bound to the region of Met-81 would either be displaced by cTnI or that the nature of binding would be altered such that cTnC activity is not inhibited. Drug binding to a region that includes Met-45 as well as Met-60 and -80 could persist in the presence of cTnI and not inhibit activity. Drug binding to this site may sensitize cTnC to Ca2+ since Met-60 and -80 are in the helices C and D of the regulatory Ca2+ binding site II. This provides potential structural basis for the bepridil-induced decrease in Ca2+ off rate at site II (5, 6) and an attractive target against which to direct Ca2+-sensitizing compounds.

    ACKNOWLEDGEMENTS

We thank Dr. Ed Nikonowicz for providing the pulse sequences, and Drs. Ed Nikonowicz, Chyau Liang, and Brian Sykes for their helpful discussions.

    FOOTNOTES

* This work was supported in part by Grants (to J. A. P.) from the National Institutes of Health (RO1-HL45724) and the Robert Welch Foundation (AU-1144).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed. Tel.: 713-500-6061; Fax: 713-500-0652; E-mail: jputkey{at}utbmb.med.uth.tmc.edu.

1 The abbreviations used are: cTnC, cardiac troponin C; cTnC(A-Cys), recombinant cTnC(des M1, D2A, C35S, C84S); cTnC(C35S), recombinant cTnC(des M1, D2A, C35S); sTnC, skeletal troponin C; cTnI, cardiac troponin I; HSQC, heteronuclear single-quantum coherence; NOE, nuclear Overhauser effect; NOESY, nuclear Overhauser enhancement spectroscopy; TFP, trifluoperazine; TEMPO-TFP, N-(3-(4-Amino- TEMPO)propyl)-2-(trifluoromethyl)phenothiazine.

    REFERENCES
Top
Abstract
Introduction
Procedures
Results
Discussion
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