Structural Flexibility of the Monomeric Red Fluorescent Protein DsRed

The monomeric red fluorescent protein DsRed (mDsRed) is widely used as an optical probe for multicolor applications in flow cytometry or fluorescence microscopy. Understanding the structure and dynamics of mDsRed provides fundamental information for its practical applications. The mDsRed crystal structure has been reported, but the structural dynamics have not been fully elucidated. Herein, the crystal structure of mDsRed was determined at 2.9 angstrom resolution, and the molecular flexibility was analyzed. mDsRed contains a solvent-accessible hole between the beta 7-strand and beta 9-alpha 10 loop, which is connected to the chromophore. A partial disorder was present in the electron density map of the tyrosine-ring group of the mDsRed chromophore, indicating a flexible conformation of the chromophore. The refined mDsRed chromophore displayed a cis-conformation with a nonplanar configuration between the tyrosine and imidazoline rings of the chromophore. Temperature factor analysis indicated that the beta-barrel fold of mDsRed is rigid, while the loops at the top and bottom of the beta-barrel are relatively flexible. The beta-barrel surface of mDsRed was closer to the native conformation compared with the previously reported Zn-bound state of mDsRed. These structural findings extend our understanding of the molecular flexibility of mDsRed.