Heme binding to calmodulin, troponin C, and parvalbumin, as a probe of calcium-dependent conformational changes

Heme-CO binds to the active (calcium-bound) form of calmodulin (CaM), but not to the inactive form. Despite a similarity in structure of another calcium-binding protein, skeletal muscle troponin C, both the affinity and the spectral red-shift of the absorption of the heme group are greatly decreased for troponin C relative to calmodulin. Parvalbumin, another calcium-binding protein, shows a twofold greater affinity for heme-CO relative to CaM. Unlike calmodulin and troponin C, the affinity of parvalbumin for heme-CO is even greater in the absence of calcium. The affinity of the tryptic and thrombic fragments of CaM for heme-CO are decreased relative to the entire calmodulin. The binding of heme-CO is specific as demonstrated by the discrimination of the calmodulin, troponin C, and parvalbumin pockets. The interaction of heme-CO with active (calcium-bound) CaM is rapid (ms) as determined by stopped flow measurements. No difference in kinetics was observed for mixing inactive (calcium free) CaM with a solution of [heme-CO plus calcium], indicating that the calcium-binding step and subsequent change in protein conformation are rapid.

Interaction of heme with amphiphilic peptides: use of hemin-CN to probe the interaction of calmodulin with its target peptides

The interaction of heme with several amphiphilic peptides has been studied by absorption and fluorescence spectroscopy. The binding can be followed by the changes in the absorption spectrum of the heme group or by the decrease in the peptide tryptophan fluorescence due to energy transfer to the heme. Despite their small size, ranging from 26 residues for melittin to 14 for mastoporan, a high affinity for heme-CO and hemin-CN (Kd < 100 nM) may be observed. Spectral shifts in the absorption peaks and appreciable geminate recombination after photodissociation of CO from the complex peptide-heme-CO suggest the formation of a heme pocket, as for the natural heme proteins.

APPLICATION

hemin-CN can be used as a probe for the interaction of calmodulin with these target peptides. Amphiphilic peptides such as melittin bind to calmodulin with a high (nM) affinity. While both the peptide and calcium-bound calmodulin bind heme-CO, only the peptide binds hemin-CN. These interactions permit studies of the competition between hemin-CN and calmodulin for binding to the peptide: while hemin-CN quenches the melittin tryptophan fluorescence, addition of calmodulin to the [melittin*hemin-CN] complex displaces the hemin-CN and the melittin tryptophan fluorescence is recovered.