Kinetic analysis of maturation and denaturation of DsRed, a coral-derived red fluorescent protein.

The red fluorescent protein DsRed recently cloned from Discosoma coral, with its significantly red-shifted excitation and emission maxima (558 and 583 nm, respectively), has attracted great interest because of its spectral complementation to other fluorescent proteins, including the green fluorescent protein and its enhanced mutant EGFP. We demonstrated that the much slower DsRed fluorescence development could be described by a three-step kinetic model, in contrast to the fast EGFP maturation, which was fitted by a one-step model. At pH below 5.0 DsRed fluorescence gradually decreased, and the rate and degree of this fluorescence inactivation depended on the pH value. The kinetics of fluorescence inactivation under acidic conditions was fitted by a two-exponential function where the initial inactivation rate was proportional to the fourth power of proton concentration. Subsequent DsRed alkalization resulted in partial fluorescence recovery, and the rate and degree of such recovery depended on the incubation time in the acid. Recovery kinetics had a lag-time and was fitted minimally by three exponential functions. The DsRed absorbance and circular dichroism spectra revealed that the fluorescence loss was accompanied by protein denaturation. We developed a kinetic mechanism for DsRed denaturation that includes consecutive conversion of the initial state of the protein, protonated by four hydrogen ions, to the denatured one through three intermediates. The first intermediate still emits fluorescence, and the last one is subjected to irreversible inactivation. Because of tight DsRed tetramerization we have suggested that obligatory protonation of each monomer results in the fluorescence inactivation of the whole tetramer.

Denaturation and partial renaturation of a tightly tetramerized DsRed protein under mildly acidic conditions.

The red fluorescent protein, DsRed, recently cloned from coral Discosoma sp. has one of the longest fluorescence waves and one of the most complex absorbance spectra among the family of fluorescent proteins. In this work we found that with time DsRed fluorescence decreases under mildly acidic conditions (pH 4.0-4.8) in a pH-dependent manner, and this fluorescence inactivation could be partially recovered by subsequent re-alkalization. The DsRed absorbance and circular dichroism spectra under these conditions revealed that the fluorescence changes were caused by denaturation followed by partial renaturation of the protein. Further, analytical ultracentrifugation determined that native DsRed formed a tight tetramer under various native conditions. Quantitative analysis of the data showed that several distinct states of protein exist during the fluorescence inactivation and recovery, and the inactivation of fluorescence can be caused by protonation of a single ionogenic group in each monomer of DsRed tetramer.