A spontaneously blinking fluorescent protein for simple single laser

super-resolution live cell imaging. 2. 3. Yoshiyuki Arai1,2,# ... samples with the aid of photoswitchable fluorescent probes and intricate. 21 microsc...
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Letter

A spontaneously blinking fluorescent protein for simple single laser super-resolution live cell imaging Yoshiyuki Arai, Hiroki Takauchi, Yuhei Ogami, Satsuki Fujiwara, Masahiro Nakano, Tomoki Matsuda, and Takeharu Nagai ACS Chem. Biol., Just Accepted Manuscript • DOI: 10.1021/acschembio.8b00200 • Publication Date (Web): 02 Jul 2018 Downloaded from http://pubs.acs.org on July 3, 2018

Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.

is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

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A spontaneously blinking fluorescent protein for simple single laser

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super-resolution live cell imaging

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Yoshiyuki Arai1,2,#, Hiroki Takauchi2,#, Yuhei Ogami2, Satsuki Fujiwara1, Masahiro

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Nakano1,2 Tomoki Matsuda1,2, and Takeharu Nagai1,2,*

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1

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Mihogaoka, Ibaraki, Osaka 567-0047, Japan

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2

The Institute of Scientific and Industrial Research, Osaka University, 8-1

Department of Biotechnology, Osaka University, 2-1 Yamadaoka, Suita, Osaka,

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565-0871, Japan

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#

These authors contributed equally to this work.

12 13

*Correspondence should be addressed to

14

[email protected]

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Tel: +81-6-6879-8480

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Fax:+81-6-6875-5724

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Abstract

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Super-resolution imaging techniques based on single molecule localization

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microscopy (SMLM) broke the diffraction limit of optical microscopy in living

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samples with the aid of photoswitchable fluorescent probes and intricate

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microscopy systems. Here, we developed a fluorescent protein, SPOON, which

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can be switched-off by excitation light illumination and switched-on by

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thermally-induced dehydration resulting in an apparent spontaneous blinking

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behavior. This unique property of SPOON provides a simple SMLM-based

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super-resolution imaging platform which requires only a single 488 nm laser.

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Introduction

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Super-resolution imaging techniques are now indispensable to explore biological

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structure at nano-meter scales in living cells1. To break the diffraction limit many

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super-resolution methods have been developed. These include stimulated

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emission depletion (STED)2, reversible saturable optical fluorescence transition

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(RESOLFT)3, photoactivation localization microscopy (PALM)4, stochastic

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optical reconstruction microscopy (STORM)5, and structured illumination

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microscopy (SIM)6. Initially, only PALM and STORM required photoswitchable

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fluorescent probes. But now, many other super-resolution techniques use

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photoswitchable fluorescent probes to reduce illumination power density and

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improve biocompatibility7. Genetically encoded photoswitchable fluorescent

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proteins (PSFPs) are especially promising as they can easily be targeted to the

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proteins of interest in living cells8. Among PSFPs, Dreiklang was the first

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reported PSFP which can be repeatedly switched on and off by using three

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different wavelengths of light (360 nm, 405 nm, and 515 nm or 488 nm)9. In

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addition, Dreiklang can switch on spontaneously by thermal relaxation that is

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caused by a dehydration of chromophore9, which enables a simpler single

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molecule localization-based microscopy, called DSSM (decoupled stochastic

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switching microscopy)10. In DSSM, the on-state of Dreiklang is thought to

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transfer to a long-lived dark state by 488 nm irradiation during observation,

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which makes this strategy similar to ground state depletion microscopy followed

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by individual molecule return (GSDIM)11,12. Compared to GSDIM, DSSM enables

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super-resolution imaging at relatively lower power density illumination for

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switching off (0.2 kW cm-2 by 405 nm light, while GSDIM required 3 kW cm-2).

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However, DSSM still requires 405 nm illumination to make Dreiklang adopt the

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fluorescent off state. Recent studies have highlighted the phototoxicity of 405 nm

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irradiation during super-resolution imaging which hampers biocompatiblity13. In

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addition, the requirement for close coordination of two laser lines for

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super-resolution imaging increases system cost, and complexity, which may be

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barriers to adoption among non-experts.

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To overcome this problem, we developed an improved PSFP that has a

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fast blinking behavior due to thermalswitching ON, and rapid photoswitching

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OFF with the same 488 nm excitation light needed for fluorescent emission. This

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enables simple super-resolution imaging using single wavelength laser

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illumination.

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Results and Discussion

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Development of SPOON

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To develop a fast photoswitching mutant of Dreiklang, we performed extensive

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random mutagenesis using the Dreiklang gene as a template by error-prone

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PCR and DNA shuffling14. We transformed bacteria with the mutant cDNA library

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and screened ~50,000 colonies for fast switching mutants of Dreiklang.

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Ultimately, we obtained a mutant carrying five substitutions: I47V, T59S, M153T,

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S208G, and M233T (Supplementary Figure 1). This mutant exhibited an

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absorption spectrum almost identical to Dreiklang during on and off states

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(Supplementary Figure 2). The absorption spectrum in the thermal equilibrium

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state (switched on) showed two peaks at 411 nm and 510 nm, and an emission

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peak at 527 nm. (Figure 1, panel a, and Table 1). The absorption peaks are

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responsible

for

photoswitching

off

and

excitation,

respectively.

Upon

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photoswitching to the off state by 438 nm irradiation, a new absorption peak at

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around 339 nm appeared which is responsible for photoswitching on (Figure 1,

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panel b, and Supplementary Figure 3). Fluorescence quantum yield (QY) of

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the mutant and Dreiklang were 0.50 and 0.44, respectively, with a molar

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extinction coefficient at 510 nm of 54,000 M-1cm-1 and 81,000 M-1cm-1 in the

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mutant and Dreiklang respectively (Table 1), suggesting that the brightness of

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mutant was slightly lower than Dreiklang itself. We named this Dreiklang mutant

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as SPOON, SPOntaneous switching ON fluorescent protein.

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Characteristics of SPOON

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The photoswitching kinetics of SPOON using purified protein (Supplementary

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Text) embedded in a 15% (w/v) polyacrylamide gel was examined.

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Fluorescence signals during photoswitching off were recorded upon 410 nm

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irradiation in the presence of excitation light (510 nm). The time constant of

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photoswitching off for SPOON was five times faster than that of Dreiklang

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(SPOON; 0.77 s vs Dreiklang; 3.97 s) (Figure 2, panel a, and Table 1). The

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speed of photoswitching on in SPOON was slightly faster than that of Dreiklang

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(4.84 s and 5.93 s, respectively) (Supplementary Figure 4). The time constant

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of thermalswitching on for SPOON was approximately 2.5 times faster than that

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of Dreiklang (~144.9 s and ~332.8 s, respectively) (Figure 2, panel b).

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Photoswitching fatigue resistance of SPOON was 1.7 times longer than that of

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Dreiklang (Supplementary Figure 5). Next, we tested the oligomeric states,

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maturation time, and pH stability of SPOON. Although SPOON and Dreiklang

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showed a dimeric tendency in gel filtration chromatography (Supplementary

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Figure

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monomerization (Supplementary Figure 7) consistent with prior reports9. The

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chromophore of SPOON showed an almost identical pKa value to Dreiklang

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(Supplementary Figure 8), with a maturation time constant of 1.86±0.15 hours

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(n=3, mean±s.e.m.) at 37°C (Supplementary Text, and Supplementary Figure

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9), which was 1.4 times faster than that of Dreiklang (2.63±0.09 hours, n=3,

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mean±s.e.m.). Although the brightness of SPOON is slightly lower than that of

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Dreiklang according to its molar extinction coefficient and fluorescence quantum

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yield (Table 1), photon numbers and localization uncertainty were almost

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identical to Dreiklang (Supplementary Figure 10).

6),

semi-native

polyacrylamide

gel

electrophoresis

showed

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Photoswitching upon 488 nm excitation

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Interestingly, we found that continuous illumination by 488 nm light stimulated

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photoswitching-off in both Dreiklang and SPOON (Figure 3, panel a). The

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periodic illumination of 488 nm (100 ms irradiation followed by a 900 ms

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observation interval) causes lower illumination power than the continuous

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illumination and thus enables to alter mean illumination power without changing

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source laser power itself, thermalswitching-on was seen. The residual intensity

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included the background signal and “tug-of-war” between photoswitching-off and

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thermal switching-on. These photoswitching-off and thermalswitching-on events

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were observed repeatedly. Photoswitching-off speed depended on the

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illumination power density. Rate constants of photoswitching-off were obtained

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by exponential decay curve fitting. At higher power density, time constant of

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photoswitching-off appeared to be a double, rather than a single, exponential

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curve, suggesting the existing of two states (Figure 3, panel b). We also

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evaluated

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conventional fluorescence microscopy in living cells expressing Dreiklang or

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SPOON (Supplementary Figure 11). 472 nm illumination (15 mW cm-2)

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induced photoswitching-off, whereas 500 nm irradiation allowed the proteins to

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transit

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photoswitching-off pathway is present in Dreiklang and SPOON that may not

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require the transition from an excited state to a long-lived triplet state described

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for GSDIM since the illumination power density was much smaller than that

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reported11.

the

photoswitching-off

fluorescent-on

state.

and

These

thermalswitching-on

results

suggest

process

that

a

by

novel

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Localization of SPOON in living cells

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To test the performance of SPOON in living cells, we fused it with various

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proteins of interest and expressed these in mammalian cells (Supplementary

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Text). Appropriate localization of C terminal- (α-actin, Golgi body-localizing

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signal, fibrillarin, Cox-VIII, histone H2B, clathrin, and Nup133) and N

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terminal-fused (paxillin, zyxin, vimentin, β-tubulin, tyrosine-protein kinase,

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endoplasmic reticulum, and second-mitochondrial activator of caspase) SPOON

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showed the anticipated expression patterns (Supplementary Figure 12).

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Although both Dreiklang and SPOON were observed as weak dimer in solution

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by HPLC (Supplementary Figure 6), SPOON with fusion partners were

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expressed in the normal localization manner in mammalian cells. Therefore, we

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concluded that SPOON can be expressed as monomer tendency in live cell

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environment.

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Super-resolution imaging by single wavelength laser illumination

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We next investigated if the faster thermalswitching-on property of SPOON

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(Figure 2, panel b), together with the 488 nm triggered photoswitching-off

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(Figure 3, panel a) and the possibility to excite sub-maximally at 488 nm was

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sufficient to allow super-resolution imaging based on a single laser. First, we

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identified a cell expressing Vimentin-SPOON (Figure 4, panel a). The cell was

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continuously irradiated by 488 nm light to induce photoswitching-off and

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fluorescence emission. Under these conditions, the fluorescence of SPOON

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decreased immediately (Figure 4, panel b). After 10 s, single molecules of

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Vimentin-SPOON became sparse enough to detect with center localization. The

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signal from single molecules appeared randomly, sparsely and stably during

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observation (Figure 4, panel c and Supplementary Movie 1). The

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super-resolution image was reconstructed by 2,000 frames with 89,820

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molecules in this area (Figure 4, panel d). Line profile also indicated that the

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resolution of the reconstructed image was beyond the diffraction limit by SPOON

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with SMLM (Figure 4, panel e).

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Performance of SPOON

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Here we report a novel fluorescent protein, SPOON, which exhibits faster

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thermal switching-on and photoswitching-off kinetics than that of the parental

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protein Dreiklang. The photoswitching-off speed of SPOON was five times faster

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than that of Dreiklang. In the on-state absorption spectrum of SPOON, we found

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a large peak at around 405 nm (Table 1 and Supplementary Figure 2) which

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may contribute to the accelerated photoswitching-off speed.

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Simple biocompatible super-resolution

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Although the excitation peak wavelength of both Dreiklang and SPOON is

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around 510 nm, these proteins can be excited by 488 nm irradiation. We have

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found that not only 405 nm irradiation, but also 488 nm irradiation leads to

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fluorescent off states. Spontaneous thermalswitching-on also occurs during

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illumination. This ‘tug-of-war’ relationship enables many long-term single

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molecule observations. At higher illumination power density (200 W cm-2 or

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larger), the photoswitching off decay curve was fitted by a double exponential

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function, indicating the existence of two states (Figure 3, panel b). One of the

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components in the photoswitching-off rate is related to the transition from the on

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to the off state. Another may be related to photobleaching. Therefore, upon 488

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nm irradiation, three-state transition models could be considered, D ↔ E → B

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where D is the dark state, E is an emissive state, and B is a bleached state

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(Supplementary Figure 13). Because of the thermal photoswitching-on of

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SPOON (and Dreiklang), most of the initial state before 488 nm illumination

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should be fluorescence on state. By irradiating SPOON with more than 500 W

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cm-2 of 488 nm illumination light, both photoswitching-off and photobleaching

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evets were occur simultaneously (Figure 3, panel b) and then, equilibrium

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between photoswitching-off and thermalswitching-on could be observed that

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apparently indicates the blinking like behavior of localizations. As a result,

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SPOON emits photons in blinking manner apparently with only 488 nm

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illumination. HMSiR, a tetramethyrhodamine derivative, also shows blinking

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under single wavelength excitation15, but as a dye it needs to be conjugated to

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its target protein outside a cell, or organ which may limit biological application.

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However, these kinds of spontaneously blinking fluorophores simplify

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super-resolution imaging compared to other SMLM based super-resolution

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techniques (Supplementary Figure 14). Although SPOON enables simple

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super-resolution imaging, overlap of multiple localizations (i.e. multiple emitters)

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should be considered properly. Several software supports the analysis of such

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multiple emitters (Supplementary Figure 15).

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In DSSM, or GSDIM, Dreiklang should be irradiated by 405 nm (200 W

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cm-2) or intense 488 nm light (3 kW cm-2) to make the on state switch off. Such

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strong UV illumination damages cells13. In this work, because the switching off

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feature of Dreiklang and SPOON could be triggered by 488 nm irradiation,

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SMLM could be performed with only one laser (Figure 4). This improves

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bio-compatibility of super-resolution imaging. However, it is also reported that

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the 488 nm illumination cause to the phototoxic effect for several types of cells13.

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Thus, SPOON variants that enable photoswitching on and excitation at longer

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wavelength need to be developed. Moreover, since SPOON is a decoupled type

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of

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super-resolution techniques such as RESOLFT, PALM, and super-resolution

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optical fluctuation imaging (SOFI).

PSFP,

SPOONs

advantages

should

also

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Methods

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apparent

in

other

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Mutagenesis and cloning. For random mutagenesis, error-prone PCR was

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performed as follows; 0.5 µL of pRSETB-Dreiklang, 1.5 µL of 10 µM forward and

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reverse primer for Dreiklang, 5 µL of dNTP mixture (2.5 mM of dATP, 2.5 mM of

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dGTP, 9 mM of dCTP, and 9 mM of dTTP), 2.5 µL of 8 mM of MnCl2, 0.5−2 µL of

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MgSO4, 5 µL of PCR buffer (Takara Bio Inc.), and ddH2O was mixed to 49.5 µL

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volume. Then, 0.5 µL of rTaq (R001A, Takara Bio Inc.) was added. Subsequently,

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PCR was performed to amplify and introduce the mutations. To increase the size

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of the mutation library, staggered extension process (StEP) was performed,

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following the published protocol14. For non-mutagenic PCR reactions, KOD-Plus

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(Toyobo CO., LTD.) DNA polymerase was used. The products of PCR-amplified

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and

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electrophoresis, followed by DNA isolation using the QIAEX II gel extraction kit

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(Qiagen). The amplified DNA was digested with restriction enzyme (RE)

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endonuclease purchased from New England BioLabs or Takara Bio Inc. Ligation

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was performed by using T4 DNA ligase with 2×Rapid Ligation Buffer (Promega).

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cDNA sequencing was performed by dye-terminator cycle sequencing using the

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BigDye Terminator v3.1 Cycle Sequencing Kit (Life Technologies) and a

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sequencer (Applied Biosystems). Plasmids were purified by standard alkali

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methods as described elsewhere. All DNA oligonucleotides used for this study

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were purchased from Hokkaido System Science and all products were used by

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following the provider’s recommended protocols. All other chemicals were

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research grade. Oligonucleotides used in this study are listed in Supplementary

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Table 1.

restriction

enzyme-digested

DNA

were

purified

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Screening of fast photoswitching SPOON. PCR products obtained by

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error-prone and StEP were ligated into the bacterial expression vector pRSETB

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(Invitrogen) using BamHI and EcoRI restriction enzyme sites. The ligation

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products were transformed to E. coli (JM109 (DE3)) and homogenously spread

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on 95-mm agar plates using sterilized glass beads. E. coli were incubated for 16

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h at 37°C up to optimal emission of fluorescence from each colony. The

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Dreiklang mutants expressed in bacterial colonies were switched off with 438/24

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nm LED light and switched on with Mercury (Hg) lamps using band-pass

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emission filter (360/30 nm, Omega Optical. Inc) under simultaneous excitation

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with 512/25 nm LED light in a home-made uniform illumination system16. The

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emission signals passed through a 535/26 nm band-pass filter (Semrock). The

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time-course of fluorescence intensity was recorded until it reached a plateau

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with ~50−200 ms camera exposure time. The image sequence was analyzed

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using ImageJ software. From each plate, 4 or 5 colonies showing faster

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switching behavior than Dreiklang were picked. For the second screening step,

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we used an inverted microscopy (TE2000E, Nikon) with a 20×, 0.5 numerical

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aperture (NA) objective lens (Nikon), and an LED light source (Spectra X Light

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Engine, Lumencor), and 100W Hg lamps (Mercury Lamphouse Illuminator,

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Nikon). For excitation, cyan LED light (475/28 nm) was used. Photoswitching on

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and off was achieved Hg lamp illumination passing through excitation filters

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(360/20 nm (Omega Optical. Inc) and 410/10 nm (Omega Optical. Inc),

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respectively) under epi-illumination configuration with a dichroic mirror

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(FF520-Di02-25x36, Semrock). Emission signals were filtered with an emission

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filter (FF02-531/22-25, Semrock). Fluorescence images were captured by a

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scientific CMOS camera (ORCA-Flash4.0, Hamamatsu photonics) at 300 ms

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exposure time. This screening procedure was repeated ten times to obtain the

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final fast-switching mutant, i.e. SPOON.

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Protein characterization. Purified proteins of Dreiklang and SPOON in (10 µM

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in 20 mM HEPES, 150 mM NaCl buffer, pH 7.4) were switched off using 438/24

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nm LED light and switched on with Hg lamps using band-pass emission filter

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(360/30 nm, Omega Optical. Inc). The absorption spectrum of the purified

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proteins in the on and off state was measured with a spectrophotometer

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(V-630BIO, JASCO). The fluorescence emission spectrum of the on and off state

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was measured with a fluorescence spectrophotometer (F-7000, Hitachi). Gel

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filtration chromatography was performed as described previously16. The molar

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extinction coefficient was determined by calculating the absorption values of

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Dreiklang and SPOON, and known protein concentration measured by an alkali

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denaturation method17. The absolute fluorescence quantum yield (ψfluorescence) of

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Dreiklang and SPOON was measured on a Quantaurus QY (C11347,

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Hamamatsu Photonics), then the absorption values of Dreiklang and SPOON

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were adjusted to be lower than 0.05. pH titration curves were obtained as

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previously described16 and fitted by the equation described previously18.

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Photoswitching of Dreiklang and SPOON was performed by using purified

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proteins (10 µM in 20 mM HEPES, 150 mM NaCl buffer, pH 7.4), or the proteins

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expressed in E.coli (JM109 (DE3)) and HeLa cells. The time constant of

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photoswitching was measured using purified proteins embedded in 15% (w/v)

290

polyacrylamide at the final concentration and squeezed with clear cover slips to

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ensure the thickness of layer was ~2 µm. We used an identical microscopy setup

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(inverted microscope, TE2000E) described above for imaging. In the presence

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of simultaneous excitation illumination using LED light (475/28 nm, 18 mW cm-2),

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the samples were irradiated with near-UV light (410/10 nm, 162 mW cm-2) to

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switch the proteins from the fluorescent state to the non-fluorescent state, and

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UV light (360/20 nm, 8.8 mW cm-2) was irradiated to switch the proteins back to

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the fluorescent state. The time constants (τ) for switching on and off were

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determined by fitting functions using single exponential growth or decay curve,

299

respectively.

300 301

Photoswitching by 488 nm irradiation. Photoswitching off upon 488 nm

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irradiation was measured by using Dreiklang or SPOON expressing E.coli.

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Measurement was done by epi-fluorescence microscopy described in single

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molecule localization microscopy section. Samples were irradiated by

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continuous 488 nm irradiation and then periodically irradiated at 100 ms with 900

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ms interval controlled by a mechanical shutter system (SH05, Thorlabs). Images

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were taken every second. Illumination and exposure timing was controlled by

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LabVIEW program with a data acquisition device (NI USB-6259). Data were

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analyzed in Python.

310 311

Super-resolution imaging. We used a home-built setup of objective lens epi

312

fluorescence microscopy under inverted microscope (Ti-E, Nikon, Japan) with

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100×, 1.49 NA oil-immersion objective lens (Nikon), Di01-R405/488/561/635

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(Semrock) and FF01-525/45 (Semrock) as dichroic mirror, and emission filter,

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respectively. Images were collected over an approximately 15×15 µm2 area with

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a scientific complementary metal-oxide-semiconductor (sCMOS) camera,

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ORCA-Flash4.0 (Hamamatsu Photonics). HeLa cells expressing SPOON fused

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with vimentin were irradiated with 488 nm (1 kW cm-2) for 60 seconds with a

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frame rate of 50 Hz (20 ms). For image reconstruction, 10 to 60 seconds imaging

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data were used and processed with the ImageJ plugin ThunderSTORM19.

321 322

Supporting information

323

Additional text, figures, table, and video. This material is available free of charge

324

via the Internet at http://pubs.acs.org

325 326

Accession code. The SPOON nucleotide sequence has been deposited in

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GenBank under the accession code LC320161.

328 329

Acknowledgements

330

We thank D. Matthew for his critical reading of this manuscript. This work was

331

supported by a Grant-in-aid for Scientific Research on Innovative Areas, 'Spying

332

minority in biological phenomena (No. 3306)', from the Ministry of Education,

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Culture, Sports, Science and Technology, Japan (MEXT) (No. 23115003) (T.N.)

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and CREST (T.N.).

335 336

Author contributions

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T.N. conceived the project. H.T., Y.A., Y.O., and S.F. constructed and

338

characterized SPOON, Y.A. set up the microscopy, H.T. and Y.A. performed

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imaging. T.N. Y.A., M.N., T.M., and H.T. discussed and commented on the results,

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and wrote the manuscript.

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COMPETING INTEREST STATEMENT

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The authors declare the following competing financial interest(s): patent (to T.N.,

344

Y.A., H.T., and M.N.)

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References

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Table 1 Characteristics of SPOON and Dreiklang Parameters

SPOON

Dreiklang

Wavelength of switching off light (nm)

339

339

Wavelength of switching on light (nm)

411

412

Fluorescence excitation peak (nm)

510

510

Fluorescence emission peak (nm)

527

527

Fluorescence quantum yield

0.50

0.44

Extinction coefficient@510 nm (M-1 cm-1)

54,000

81,000

Extinction coefficient@405 nm (M-1 cm-1)

31,000

19,000

Extinction coefficient@360 nm (M-1 cm-1)

24,000

22,000

Time constant of photoswitching off (s)

0.77 (83.3%)

3.97

18 mW cm-2@475 nm, 162 mW cm-2@410 nm

3.43(16.6%)

Time constant of photoswitching on (s)

4.84

5.93

Time constant of spontaneous switching on (s)

144.9

332.8

Time constant of maturation speed (hours)

1.86±0.15

2.63±0.09

18 mW cm-2@475 nm, 8.8 mW cm-2@360 nm

419 420

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Figure 1. Characteristics of SPOON. a) Absorption and emission spectra of

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SPOON. b) Absorption spectra of SPOON in on and off states.

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Figure 2. Comparison of switching characteristics between SPOON and Dreiklang. a) Photoswitching-off kinetics under continuous 475 nm (cyan) and

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410 nm (purple) irradiation of SPOON (red) and Dreiklang (black). For Dreiklang,

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data were fitted by single exponential decay curve, while SPOON data was fitted

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by a double exponential decay curve. b) Thermalswitching-on kinetics of

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SPOON and Dreiklang under continuous 475 nm irradiation.

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430 432

Figure 3. Comparison of photoswitching-off by 488 nm irradiation between SPOON and Dreiklang. a) Photoswitching-off by 488 nm irradiation at 100 W

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cm-2. Timing of 488 nm (cyan) of continuous (solid line) and periodic (dashed

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line) are indicated as bar at the above of graph. b) Rate constants of switching

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off. At higher power density, data were fitted by double exponential curve (black)

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instead of a single one (gray). Error bars indicates standard deviation (n=2−4).

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Figure 4. SMLM with only 488 nm irradiation. a) The first frame image of Vimentin-SPOON. b) Montage images taken every 100 frames after 10 s. Red

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dots indicated the detected molecules by ThunderSTORM software. c) Time

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trajectory of average intensity. Arrow indicates the duration for super-resolution

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image reconstruction shown in d. d) Reconstructed super-resolution image using images obtained after 10 s irradiation. Scale bars is 1 µm. e) Comparison

444

of line profiles where line of interest was indicated in d (yellow line).

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445

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Figure 1 Characteristics of SPOON. a) Absorption and emission spectra of SPOON. b) Absorption spectra of SPOON in on and off states. 49x17mm (300 x 300 DPI)

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Figure 2 Comparison of switching characteristics between SPOON and Dreiklang. a) Photoswitching-off kinetics under continuous 475 nm (cyan) and 410 nm (purple) irradiation of SPOON (red) and Dreiklang (black). For Dreiklang, data were fitted by single exponential decay curve, while SPOON data was fitted by a double exponential decay curve. b) Thermalswitching-on kinetics of SPOON and Dreiklang under continuous 475 nm irradiation. 40x16mm (300 x 300 DPI)

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Figure 3 Comparison of photoswitching-off by 488 nm irradiation between SPOON and Dreiklang. a) Photoswitching-off by 488 nm irradiation at 100 W cm-2. Timing of 488 nm (cyan) of continuous (solid line) and periodic (dashed line) are indicated as bar at the above of graph. b) Rate constants of switching off. At higher power density, data were fitted by double exponential curve (black) instead of a single one (gray). Error bars indicates standard deviation (n=2−4). 36x11mm (300 x 300 DPI)

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Figure 4 SMLM with only 488 nm irradiation. a) The first frame image of Vimentin-SPOON. b) Montage images taken every 100 frames after 10 s. Red dots indicated the detected molecules by ThunderSTORM software. c) Time trajectory of average intensity. Arrow indicates the duration for super-resolution image reconstruction shown in d. d) Reconstructed super-resolution image using images obtained after 10 s irradiation. Scale bars is 1 µm. e) Comparison of line profiles where line of interest was indicated in d (yellow line). 99x101mm (300 x 300 DPI)

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Table of contents graphic 52x39mm (300 x 300 DPI)

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