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Highlighted Generation of Fluorescence Signals Using Simultaneous Two-Color Irradiation on Dronpa Mutants

Ryoko Ando ^*, Cristina Flors , Hideaki Mizuno ^*, Johan Hofkens  and Atsushi Miyawaki ^*

^* Laboratory for Cell Function and Dynamics, Advanced Technology Development Group, Brain Science Institute, The Institute of Physical and Chemical Research, Hirosawa, Wako-city, Saitama 351-0198, Japan; and Department of Chemistry, Katholieke Universiteit Leuven, 3001 Heverlee, Belgium

Correspondence: Address reprint requests and inquiries to Atsushi Miyawaki, Tel.: 81-48-467-5917; Fax: 81-48-467-5924; E-mail: matsushi{at}brain.riken.jp.

	ABSTRACT

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Dronpa absorbs blue light and emits bright green fluorescence. It can also be converted by strong irradiation at 490 nm to a nonfluorescent state, which can then be switched back to the original emissive state with irradiation at 400 nm. Through semirandom mutagenesis studies, we have developed two mutants of Dronpa that show efficient photoswitching kinetics. Compared to Dronpa, the mutants can be turned off by blue light more efficiently. Thus, excitation with an argon laser line (488 nm) makes the mutants quickly become dark such that no substantial fluorescence signals can be observed. Excitation with a violet laser diode (405 nm) also produces no fluorescence signals. Simultaneous 488- and 405-nm irradiation, however, results in a rapid oscillation between the two states, thereby keeping the emissive state population large enough to produce sufficiently bright fluorescence signals.

Although Dronpa normally absorbs at 503 nm and emits green fluorescence with a high fluorescence quantum yield (_FL = 0.85), strong irradiation at 488 nm can convert this protein to a nonfluorescent state that absorbs at 390 nm (dark state (D)). The protein can then be switched back to the original emissive state (bright state (B)) with minimal irradiation at 405 nm (1–3). The conversion from the B state to the D state requires a large number of photons (_BD= 0.0003), whereas the D-to-B conversion occurs efficiently (_DB = 0.37). The photochromic characteristics of Dronpa provide an unprecedented molecular tool for studying fast protein dynamics at multiple time points in individual cells (1).

cDNA encoding Dronpa was subjected to an error-prone PCR. Escherichia coli cells transformed with plasmids carrying the mutagenized DNA were plated and screened for different photoswitching behavior using a home-made image analyzing system equipped with two xenon lamps (75 W and 300 W) (4). The plates were directly illuminated with intense blue (490 ± 10 nm) or violet (400 ± 7.5 nm) light emitted from the 300-W lamp. Colonies illuminated with weak blue light (490 ± 10 nm) from the 75-W lamp were examined for green fluorescence and imaged using a cooled charge-coupled device camera. Of 1,000 colonies, 6 colonies showing rapid photobleaching upon intense illumination at 490 nm were identified. Interestingly, all of these colonies quickly recovered their fluorescence after the intense 490-nm light was turned off. Sequence analysis of the Dronpa variants in these mutants revealed that each of them carried a mutation of either Val¹⁵⁷ or Met¹⁵⁹. One of the mutant proteins, Dronpa-Met¹⁵⁹Thr, was named Dronpa-2 and further characterized. In parallel, a degenerative primer was designed so that Val¹⁵⁷ and Met¹⁵⁹ would be randomly replaced with other amino acids. Site-directed random mutagenesis of Dronpa generated a new mutant protein, which showed a more efficient spontaneous recovery of fluorescence after bleaching. This mutant, which was named Dronpa-3, carried two mutations: Val¹⁵⁷Ile and Met¹⁵⁹Ala.

The recombinant Dronpa-2 and Dronpa-3 proteins were expressed in E. coli and purified. The oligomerization states of these two mutants were examined using analytical equilibrium ultracentrifugation analysis; their molecular masses were determined to be 28 kDa (data not shown), which confirmed that they were monomers. Recombinant Dronpa, Dronpa-2, and Dronpa-3 were each placed in a droplet of mineral oil on a coverslip (Fig. 1). The time courses of the fluorescence intensities were monitored simultaneously from the three droplets using a 490DF20 excitation filter overlaid with a 0.5% transmittance neutral density (ND) filter, a 505DRLPXR dichroic mirror, and a 535DF25 emission filter. The droplets were continuously illuminated through a 50% transmittance ND filter at 490 nm (490DF20; 0.40 W/cm²) and 400 nm (400DF15; 0.14 W/cm²) to induce photobleaching and photoactivation during the intervals at the beginning and the end of the experiment, respectively. With the intense illumination at 490 nm, the fastest decrease in the fluorescence intensity was observed for Dronpa-2, whereas the slowest decrease was observed for Dronpa. In another experiment, using less intense 490-nm light resulted in more detailed decay curves for the three samples. In comparison to the quantum yield for the B-to-D conversion of Dronpa (3 x 10^–4) (1), the values (_BD) for Dronpa-2 and Dronpa-3 were calculated to be larger at 4.7 x 10^–2 and 5.3 x 10^–3, respectively. Note that Dronpa-2 and Dronpa-3 quickly returned to their emissive states even in the dark, which contrasts with the stable dark state of Dronpa. Because of the apparent thermal instability of their dark states, the quantum yields for the D-to-B conversion by 400-nm light could not be measured for Dronpa-2 and Dronpa-3. These mutants, however, appeared to be photoactivated as efficiently as Dronpa.

View larger version (28K): [in this window] [in a new window]   FIGURE 1  Photochromic behaviors of Dronpa, Dronpa-2, and Dronpa-3. (A) Time courses of green fluorescence intensities of Dronpa (black), Dronpa-2 (red), and Dronpa-3 (blue) in droplets of mineral oil. Green fluorescence was monitored with a 490DF20 excitation filter overlaid with an ND filter, a 505DRLPXR dichroic mirror, and a 535DF25 emission filter. During the marked intervals (blue and violet bars), the droplets were continuously illuminated through an ND filter at 490 nm (490DF20) or 400 nm (400DF15) to induce photobleaching or photoactivation, respectively. (B) The same time courses as shown in (A) between 0 and 40 s on an expanded time scale. (C) Arrows above the first three panels indicate positions on the time scale in (B), whereas those above the last two panels indicate positions on the time scale in (A). Interference filters were obtained from Omega Optical (Brattleboro, VT).

View larger version (16K): [in this window] [in a new window]   FIGURE 2  Normalized excitation and emission spectra of Dronpa-2 (A) and Dronpa-3 (B). Protein samples were photoactivated using 400-nm light before measurements.

View larger version (27K): [in this window] [in a new window]   FIGURE 3  Fluorescent images of HeLa cells expressing mitochondrially targeted (left) and plasma-membrane-targeted (right) Dronpa-3. Dronpa-3 was fused with the 12 N-terminal amino acids of the cytochrome c oxidase subunit IV presequence and the 22 N-terminal amino acids of the nonreceptor tyrosine kinase Lyn, respectively (8). 488 nm, images with a 488-nm laser scan; 405 nm, images with a 405-nm laser scan; 488 nm + 405 nm, images with a 488-nm and 405-nm laser scan. Scale bars, 10 µm. Cells were visualized using a confocal microscope equipped with a 60x objective lens (Plan Apo, NA = 1.40), a laser diode (405 nm), and an argon ion laser (488 nm) (Fluoview FV500, Olympus, Tokyo, Japan). Kalman averaging of four scans was performed on each scanning line.

	ACKNOWLEDGEMENTS

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This work was partly supported by grants from the Molecular Ensemble Development Research, the Special Coordination Fund for the promotion of the Ministry of Education, Culture, Sports, Science, and Technology, the Japanese Government, the New Energy and Industrial Technology Development Organization, and the Human Frontier Science Program.

Submitted on February 5, 2007; accepted for publication March 12, 2007.

	REFERENCES

TOP ABSTRACT ACKNOWLEDGEMENTS REFERENCES

 
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4. Sawano, A., and A. Miyawaki. 2000. Directed evolution of green fluorescent protein by a new versatile PCR strategy for site-directed and semi-random mutagenesis. Nucleic Acids Res. 28:e78.[Abstract/Free Full Text]

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This Article Abstract Full Text (PDF) All Versions of this Article: biophysj.107.105882v1 92/12/L97    most recent Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Ando, R. Articles by Miyawaki, A. Search for Related Content PubMed PubMed Citation Articles by Ando, R. Articles by Miyawaki, A.