Diverse Fluorescence Resonance Energy Transfer Processes Originating from the Conformational Heterogeneity of the Calcium Indicator Yellow Cameleon YC3.60.

Abstract

By combining time-resolved fluorescence spectroscopy and molecular biology, we have clearly elucidated the fluorescence mechanism of yellow cameleon YC3.60. YC3.60 is one of the most widely used fundamental calcium ion indicator proteins and is a tandem protein consisting of cyan fluorescent protein, calmodulin, and yellow fluorescent protein. Our results show that the conformational heterogeneity of YC3.60 leads to multiple FRET (fluorescence resonance energy transfer) processes occurring in a variety of structures. In the presence of calcium ions, FRET occurs in 75% of all YC3.60 molecules, and the intramolecular FRET faster than 20 ps is dominant among the three different FRET processes. Even in the absence of calcium ions, FRET occurs in 28% of YC3.60, where intra- and intermolecular FRET with a time constant of 160 ps is dominant among the four different FRET processes. YC3.60 with the immature chromophore, which is 25% of the total, would result in lower contrast on imaging. Conformational heterogeneity arises from the specific association of the two fluorescent proteins. It was clearly shown that the association of fluorescent proteins has a significant impact on the fluorescence mechanism. These observations lead to the promotion of research that elucidates the relationship between the higher-order structure and function of proteins.