Elucidation of isoform-dependent pH sensitivity of troponin i by NMR spectroscopy.

Myocardial ischemia is characterized by reduced blood flow to cardiomyocytes, which can lead to acidosis. Acidosis decreases the calcium sensitivity and contractile efficiency of cardiac muscle. By contrast, skeletal and neonatal muscles are much less sensitive to changes in pH. The pH sensitivity of cardiac muscle can be reduced by replacing cardiac troponin I with its skeletal or neonatal counterparts. The isoform-specific response of troponin I is dictated by a single histidine, which is replaced by an alanine in cardiac troponin I. The decreased pH sensitivity may stem from the protonation of this histidine at low pH, which would promote the formation of electrostatic interactions with negatively charged residues on troponin C. In this study, we measured acid dissociation constants of glutamate residues on troponin C and of histidine on skeletal troponin I (His-130). The results indicate that Glu-19 comes in close contact with an ionizable group that has a pK(a) of ∼6.7 when it is in complex with skeletal troponin I but not when it is bound to cardiac troponin I. The pK(a) of Glu-19 is decreased when troponin C is bound to skeletal troponin I and the pK(a) of His-130 is shifted upward. These results strongly suggest that these residues form an electrostatic interaction. Furthermore, we found that skeletal troponin I bound to troponin C tighter at pH 6.1 than at pH 7.5. The data presented here provide insights into the molecular mechanism for the pH sensitivity of different muscle types.

The dilated cardiomyopathy G159D mutation in cardiac troponin C weakens the anchoring interaction with troponin I.

NMR spectroscopy has been employed to elucidate the molecular consequences of the DCM G159D mutation on the structure and dynamics of troponin C, and its interaction with troponin I (TnI). Since the molecular effects of human mutations are often subtle, all NMR experiments were conducted as direct side-by-side comparisons of the wild-type C-domain of troponin C (cCTnC) and the mutant protein, G159D. With the mutation, the affinity toward the anchoring region of cTnI (cTnI 34-71) was reduced ( K D = 3.0 +/- 0.6 microM) compared to that of the wild type ( K D < 1 microM). Overall, the structure and dynamics of the G159D.cTnI 34-71 complex were very similar to those of the cCTnC.cTnI 34-71 complex. There were, however, significant changes in the (1)H, (13)C, and (15)N NMR chemical shifts, especially for the residues in direct contact with cTnI 34-71, and the changes in NOE connectivity patterns between the G159D.cTnI 34-71 and cCTnC.cTnI 34-71 complexes. Thus, the most parsimonious hypothesis is that the development of disease results from the poor anchoring of cTnI to cCTnC, with the resulting increase in the level of acto-myosin inhibition in agreement with physiological data. Another possibility is that long-range electrostatic interactions affect the binding of the inhibitory and switch regions of cTnI (cTnI 128-147 and cTnI 147-163) and/or the cardiac specific N-terminus of cTnI (cTnI 1-29) to the N-domain of cTnC. These important interactions are all spatially close in the X-ray structure of the cardiac TnC core.

Defining the binding site of levosimendan and its analogues in a regulatory cardiac troponin C-troponin I complex.

The interaction of Cardiac Troponin C (cTnC) and Cardiac Troponin I (cTnI) plays a critical role in transmitting the Ca (2+) signal to the other myofilament proteins in the activation of cardiac muscle contraction. As such, the cTnC-cTnI interface is a logical target for cardiotonic agents such as levosimendan that can modulate the Ca (2+) sensitivity of the myofilaments. Evidence indicates that drug candidates may exert their effects by targeting a site formed by binding of the switch region of cTnI to the regulatory N domain of cTnC (cNTnC). In this study, we utilized two-dimensional (1)H- (15)N HSQC NMR spectroscopy to monitor the binding of levosimendan and its analogues, CMDP, AMDP, CI-930, imazodan, and MPDP, to cNTnC.Ca (2+) in complex with two versions of the switch region of cTnI (cTnI 147-163 and cTnI 144-163). Levosimendan, CMDP, AMDP, and CI-930 were found to bind to both cNTnC.Ca (2+).cTnI 147-163 and cNTnC.Ca (2+).cTnI 144-163 complexes. These compounds contain a methyl group that is absent in MPDP or imazodan. Thus, the methyl group is one of the pharmacophores responsible for the action of these pyridazinone drugs on cTnC. Furthermore, the results showed that the cNTnC.Ca (2+).cTnI 144-163 complex presents a higher-affinity binding site for these compounds than the cNTnC.Ca (2+).cTnI 147-163 complex. This is consistent with our observation that the affinity of cTnI 144-163 for cNTnC.Ca (2+) is approximately 10-fold stronger than that of cTnI 147-163, likely a result of electrostatic forces between the N-terminal RRV extension in cTnI 144-163 and the acidic residues in the C and D helices of cNTnC. These results will help in the delineation of the mode of action of levosimendan on the important functional unit of cardiac troponin that constitutes the regulatory domain of cTnC and the switch region of cTnI.

Internal pH indicators for biomolecular NMR.

We describe a non-invasive technique for determining pH in biomolecular NMR sample using buffer components (formate, tris, piperazine, and imidazole) as internal pH indicators, whose (1)H NMR chemical shifts are sensitive to pH in a range from 2.5 to 9.8. This method is suitable for a wide range of applications where samples are handled intensively during NMR titrations or in high throughput analysis in structural genomics or metabolomics.

Modulation of cardiac troponin C function by the cardiac-specific N-terminus of troponin I: influence of PKA phosphorylation and involvement in cardiomyopathies.

The cardiac-specific N-terminus of cardiac troponin I (cTnI) is known to modulate the activity of troponin upon phosphorylation with protein kinase A (PKA) by decreasing its Ca(2+) affinity and increasing the relaxation rate of the thin filament. The molecular details of this modulation have not been elaborated to date. We have established that the N-terminus and the switch region of cTnI bind to cNTnC [the N-domain of cardiac troponin C (cTnC)] simultaneously and that the PKA signal is transferred via the cTnI N-terminus modulating the cNTnC affinity toward cTnI(147-163) but not toward Ca(2+). The K(d) of cNTnC for cTnI(147-163) was found to be 600 microM in the presence of cTnI(1-29) and 370 microM in the presence of cTn1(1-29)PP, which can explain the difference in muscle relaxation rates upon the phosphorylation with PKA in experiments with cardiac fibers. In the light of newly found mutations in cNTnC that are associated with cardiomyopathies, the important role played by the cTnI N-terminus in the development of heart disorders emerges. The mutants studied, L29Q (the N-domain of cTnC containing mutation L29Q) and E59D/D75Y (the N-domain of cTnC containing mutation E59D/D75Y), demonstrated unchanged Ca(2+) affinity per se and in complex with the cTnI N-terminus (cTnI(1-29) and cTnI(1-29)PP). The affinity of L29Q and E59D/D75Y toward cTnI(147-163) was significantly perturbed, both alone and in complex with cTnI(1-29) and cTnI(1-29)PP, which is likely to be responsible for the development of malfunctions.

Backbone dynamics of SDF-1alpha determined by NMR: interpretation in the presence of monomer-dimer equilibrium.

SDF-1alpha is a member of the chemokine family implicated in various reactions in the immune system. The interaction of SDF-1alpha with its receptor, CXCR4, is responsible for metastasis of a variety of cancers. SDF-1alpha is also known to play a role in HIV-1 pathogenesis. The structures of SDF-1alpha determined by NMR spectroscopy have been shown to be monomeric while X-ray structures are dimeric. Biochemical data and in vivo studies suggest that dimerization is likely to be important for the function of chemokines. We report here the dynamics of SDF-1alpha determined through measurement of main chain (15)N NMR relaxation data. The data were obtained at several concentrations of SDF-1alpha and used to determine a dimerization constant of approximately 5 mM for a monomer-dimer equilibrium. The dimerization constant was subsequently used to extrapolate values for the relaxation data corresponding to monomeric SDF-1alpha. The experimental relaxation data and the extrapolated data for monomeric SDF-1alpha were analyzed using the model free approach. The model free analysis indicated that SDF-1alpha is rigid on the nano- to picosecond timescale with flexible termini. Several residues involved in the dimer interface display slow micro- to millisecond timescale motions attributable to chemical exchange such as monomer-dimer equilibrium. NMR relaxation measurements are shown to be applicable for studying oligomerization processes such as the dimerization of SDF-1alpha.

Investigations of bivalent antibody binding on fluid-supported phospholipid membranes: the effect of hapten density.

Investigations of ligand-receptor binding between bivalent antibodies and membrane-bound ligands are presented. The purpose of these studies was to explore binding as a function of hapten density in a two-dimensionally fluid environment. A novel microfluidic strategy in conjunction with total internal reflection fluorescence microscopy was designed to achieve this. The method allowed binding curves to be acquired with excellent signal-to-noise ratios while using only minute quantities of protein solution. The specific system investigated was the interaction between anti-DNP antibodies and phospholipid membranes containing DNP-conjugated lipids. Binding curves for ligand densities ranging from 0.1 to 5.0 mol % were obtained. Two individual dissociation constants could be extracted from the data corresponding to the two sequential binding events. The first dissociation constant, K(D1), was 2.46 x 10(-)(5) M, while the second was K(D2) = 1.37 x 10(-)(8) mol/m(2). This corresponded to a positively cooperative binding effect with an entropic difference between the two events of 62.3 +/- 2.7 J/(mol.K). Furthermore, the percentage of monovalently and bivalently bound protein was determined at each ligand density.