An NMR and spin label study of the effects of binding calcium and troponin I inhibitory peptide to cardiac troponin C

Abstract

The paramagnetic relaxation reagent, 4‐hydroxy‐2,2,6,6‐tetramethylpiperidinyl‐1‐oxy (HyTEMPO), was used to probe the surface exposure of methionine residues of recombinant cardiac troponin C (cTnC) in the absence and presence of Ca²+ at the regulatory site (site II), as well as in the presence of the troponin I inhibitory peptide (cTnIp). Methyl resonances of the 10 Met residues of cTnC were chosen as spectral probes because they are thought to play a role in both formation of the N‐terminal hydrophobic pocket and in the binding of cTnIp. Proton longitudinal relaxation rates (R₁'s) of the [¹³C‐methyl] groups in [¹³C‐methyl]Met‐labeled cTnC(C35S) were determined using a T₁ two‐dimensional heteronuclear single‐ and multiple‐quantum coherence pulse sequence. Solvent‐exposed Met residues exhibit increased relaxation rates from the paramagnetic effect of HyTEMPO. Relaxation rates in 2Ca²+‐loaded and Ca²+‐saturated cTnC, both in the presence and absence of HyTEMPO, permitted the topological mapping of the conformational changes induced by the binding of Ca²+ to site II, the site responsible for triggering muscle contraction. Calcium binding at site II resulted in an increased exposure of Met residues 45 and 81 to the soluble spin label HyTEMPO. This result is consistent with an opening of the hydrophobic pocket in the N‐terminal domain of cTnC upon binding Ca²+ at site II. The binding of the inhibitory peptide cTnlp, corresponding to Asn 129 through Ile 149 of cTnl, to both 2Ca²+‐loaded and Ca²+‐saturated cTnC was shown to protect Met residues 120 and 157 from HyTEMPO as determined by a decrease in their measured R₁ values. These results suggest that in both the 2Ca²+‐loaded and Ca²+‐saturated forms of cTnC, cTnlp binds primarily to the C‐terminal domain of cTnC.