Abstract
The accommodation of Mg2+ in the N-terminal domain of calmodulin was followed through amide 1H and 15N chemical shifts and line widths in heteronuclear single-quantum coherence spectroscopy NMR spectra. Mg2+ binds sequentially to the two Ca2+-binding loops in this domain, with affinities such that nearly half of the loops would be occupied by Mg2+ in resting eukaryotic cells. Mg2+ binding seems to occur without ligation to the residue in the 12th loop position, previously proven largely responsible for the major rearrangements induced by binding of the larger Ca2+. Consequently, smaller Mg2+-induced structural changes are indicated throughout the protein. The two Ca2+-binding loops have different Mg2+ binding characteristics. Ligands in the N-terminal loop I are better positioned for cation binding, resulting in higher affinity and slower binding kinetics compared with the C-terminal loop II (koff = 380 +/- 40 s-1 compared with approximately 10,000 s-1 at 25 degreesC). The Mg2+-saturated loop II undergoes conformational exchange on the 100-microseconds time scale. Available data suggest that this exchange occurs between a conformation providing a ligand geometry optimized for Mg2+ binding and a conformation more similar to that of the empty loop.
Highlights
The accommodation of Mg2؉ in the N-terminal domain of calmodulin was followed through amide 1H and 15N chemical shifts and line widths in heteronuclear singlequantum coherence spectroscopy NMR spectra
Ligands in the N-terminal loop I are better positioned for cation binding, resulting in higher affinity and slower binding kinetics compared with the C-terminal loop II
Available data suggest that this exchange occurs between a conformation providing a ligand geometry optimized for Mg2؉ binding and a conformation more similar to that of the empty loop
Summary
Anders Malmendal‡, Johan Evenas, Eva Thulin, Garry P. The Mg2ϩ dissociation constants of CaM are in the millimolar range [24, 25], and Mg2ϩ has generally been assumed to bind to the same sites as Ca2ϩ [25, 26] but to induce only small structural rearrangements [24, 26] This was recently verified by Ohki et al using 1H–15N NMR [27]. In parvalbumin and myosin regulatory light chain, the only difference between Mg2ϩ and Ca2ϩ ligation is that the residues in the 12th loop positions serve as monodentate ligands in the Mg2ϩ structures but bidentate in the Ca2ϩ structures.
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