The C-terminal half-fragment (residues 78-148) of scallop testis calmodulin was investigated by 500-MHz two-dimensional proton NMR in order to clarify the structure and the structural change accompanying Ca2+ binding. The sequential resonance assignment to individual amino acid residues was made in part (27 out of 71 residues) by a combination of correlated spectroscopy and nuclear Overhauser effect spectroscopy of a 90% H2O solution. In the Ca2+-bound state, resonances of backbone amide protons of Gly-98, Gly-134, Ile-100, Asn-137, and Val-136 appear at extremely low fields. These findings suggest that amide protons of these residues are hydrogen bonded. In the Ca2+-free state, the amide resonances of Ile-100 and Gly-134 disappear into the crowded normal shift region. This observation indicates that two hydrogen bonds of Ile-100 and Gly-134 are destroyed (or weakened) as Ca2+ ions are removed from two Ca2+-binding sites. Chemical shifts of amide and alpha-protons of residues located in the Ca2+-binding loop of domain III are similar to those of domain IV. These results suggest that the conformations of the two loops are very similar. The present results can be interpreted in terms of a structure predicted by Kretsinger [Kretsinger, R.H. (1980) Ann. N.Y. Acad. Sci. 356, 14].