Lanthanide-induced peptide folding: variations in lanthanide affinity and induced peptide conformation.

The present work has demonstrated the utility of the diamagnetic lanthanides lutetium and lanthanum as metal binding probes for a synthetic 13-residue fragment representing calcium binding site 3 of rabbit skeletal troponin C (residues 103-115). The peptide conformation induced by these metals was monitored by the proton magnetic resonance at 270 MHz. The peptide affinity for these rare earths is 50-400 times higher than that for calcium (KLu3+, 1.3 X 10(4) M-1; KLa3+, 1.1 X 10(5) M-1; KCa2+, 3 X 10(2) M-1) which is related to the change in cation charge from 2+ to 3+. The peptide conformation induced by the presence of La3+ generates a different 1H NMR spectrum than the one observed for the lutetium-saturated peptide. Thus, it appears that these metals do not fold the peptide into exactly the same conformation. The resonance shifts observed during the Lu3+ titration are much smaller than those seen in the case of La3+ addition. The fact that lutetium binds less tightly than lanthanum to the peptide may be linked directly or indirectly to the difference in ionic radius between these metals (Lu3+, 0.86 A; La3+, 1.03 A). This may in turn indicate that the peptide primary sequence encodes for some aspects of metal ion specificity. The 1H NMR results also demonstrate that glycine-108 adopts a restricted geometry in the absence of metal such that its two alpha-carbon protons are in different environments which are further affected by the addition of either metal. These observations support the concept that geometric constraints arising from the particular peptide folding pattern near this residue correlate with the highly conserved nature of this site of the EF hand. This position remains occupied by glycine in most EF hand domains with the exception of known distorted calcium binding sites present in intestine calcium binding proteins and S-100.