Single molecule fluorescence imaging of the photoinduced conversion and bleaching behavior of the fluorescent protein Kaede.

Photoconversion and photobleaching behavior of the fluorescent protein Kaede immobilized in polyacrylamide gel matrix at room temperature was studied by single molecule wide-field fluorescence microscopy. Photobleaching kinetics of Kaede molecules upon excitation at 488 nm showed slight heterogeneity, suggesting the presence of different protein conformations and/or the distribution of local environments in the gel matrix. Statistical analysis of intensity trajectories of single molecules revealed four major types of fluorescence dynamics behavior upon short illumination by a violet light pulse (405 nm). In particular, two types of photoswitching behavior were observed: the green-to-red photoconversion (4% of Kaede molecules) and the photoactivation of green fluorescence without emission of red fluorescence (13%). Two other major groups show neither photoconversion nor red emission and demonstrate photoinduced partial deactivation (43%) and partial revival (30%) of green fluorescence. The significantly lower green-to-red conversion ratio as compared with bulk measurements in aqueous solution might be induced by the immobilization of the protein molecules within a polyacrylamide gel. Contrary to Ando et al. (Proc Natl Acad Sci 2002;99:12651-12656), we found a significant increase in green fluorescence emission upon illumination with 405-nm light, which is typical for GFP and related proteins.

Characterization of the photoconversion on reaction of the fluorescent protein Kaede on the single-molecule level.

Fluorescent proteins are now widely used in fluorescence microscopy as genetic tags to any protein of interest. Recently, a new fluorescent protein, Kaede, was introduced, which exhibits an irreversible color shift from green to red fluorescence after photoactivation with lambda = 350-410 nm and, thus, allows for specific cellular tracking of proteins before and after exposure to the illumination light. In this work, the dynamics of this photoconversion reaction of Kaede are studied by fluorescence techniques based on single-molecule spectroscopy. By fluorescence correlation spectroscopy, fast flickering dynamics of the chromophore group were revealed. Although these dynamics on a submillisecond timescale were found to be dependent on pH for the green fluorescent Kaede chromophore, the flickering timescale of the photoconverted red chromophore was constant over a large pH range but varied with intensity of the 488-nm excitation light. These findings suggest a comprehensive reorganization of the chromophore and its close environment caused by the photoconversion reaction. To study the photoconversion in more detail, we introduced a novel experimental arrangement to perform continuous flow experiments on a single-molecule scale in a microfluidic channel. Here, the reaction in the flowing sample was induced by the focused light of a diode laser (lambda = 405 nm). Original and photoconverted Kaede protein were differentiated by subsequent excitation at lambda = 488 nm. By variation of flow rate and intensity of the initiating laser we found a reaction rate of 38.6 s(-1) for the complete photoconversion, which is much slower than the internal dynamics of the chromophores. No fluorescent intermediate states could be revealed.