Yusaku Hontani scite author profile

Multiphoton fluorescence microscopy is a powerful technique for deep-tissue observation of living cells. In particular, three-photon microscopy is highly beneficial for deep-tissue imaging because of the long excitation wavelength and the high nonlinear confinement in living tissues. Because of the large spectral separation of fluorophores of different color, multicolor three-photon imaging typically requires multiple excitation wavelengths. Here, we report a new three-photon excitation scheme: excitation to a higher-energy electronic excited state instead of the conventional excitation to the lowest-energy excited state, enabling multicolor three-photon fluorescence imaging with deep-tissue penetration in the living mouse brain using single-wavelength excitation. We further demonstrate that our excitation method results in ≥10-fold signal enhancement for some of the common red fluorescent molecules. The multicolor imaging capability and the possibility of enhanced three-photon excitation cross section will open new opportunities for life science applications of three-photon microscopy.

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Reaction dynamics of the chimeric channelrhodopsin C1C2

Hontani

Marazzi

Stehfest

et al. 2017

Sci Rep

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Channelrhodopsin (ChR) is a key protein of the optogenetic toolkit. C1C2, a functional chimeric protein of Chlamydomonas reinhardtii ChR1 and ChR2, is the only ChR whose crystal structure has been solved, and thus uniquely suitable for structure-based analysis. We report C1C2 photoreaction dynamics with ultrafast transient absorption and multi-pulse spectroscopy combined with target analysis and structure-based hybrid quantum mechanics/molecular mechanics calculations. Two relaxation pathways exist on the excited (S1) state through two conical intersections CI1 and CI2, that are reached via clockwise and counter-clockwise rotations: (i) the C13=C14 isomerization path with 450 fs via CI1 and (ii) a relaxation path to the initial ground state with 2.0 ps and 11 ps via CI2, depending on the hydrogen-bonding network, hence indicating active-site structural heterogeneity. The presence of the additional conical intersection CI2 rationalizes the relatively low quantum yield of photoisomerization (30 ± 3%), reported here. Furthermore, we show the photoreaction dynamics from picoseconds to seconds, characterizing the complete photocycle of C1C2.

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The photochemistry of sodium ion pump rhodopsin observed by watermarked femto- to submillisecond stimulated Raman spectroscopy

Hontani

Inoue

Kloz

et al. 2016

Phys. Chem. Chem. Phys.

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Krokinobacter rhodopsin 2 (KR2) is a recently discovered light-driven Na(+) pump that holds significant promise for application as a neural silencer in optogenetics. KR2 transports Na(+) (in NaCl solution) or H(+) (in larger cation solution, e.g. in CsCl) during its photocycle. Here, we investigate the photochemistry of KR2 with the recently developed watermarked, baseline-free femto- to submillisecond transient stimulated Raman spectroscopy (TSRS), which enables us to investigate retinal chromophore dynamics in real time with high spectral resolution over a large time range. We propose a new photocycle from femtoseconds to submilliseconds: J (formed in ∼200 fs) → K (∼3 ps) → K/L1 (∼20 ps) → K/L2 (∼30 ns) → L/M (∼20 μs). KR2 binds a Na(+) ion that is not transported on the extracellular side, of which the function is unclear. We demonstrate with TSRS that for the D102N mutant in NaCl (with Na(+) unbound, Na(+) transport) and for WT KR2 in CsCl (with Na(+) unbound, H(+) transport), the extracellular Na(+) binding significantly influences the intermediate K/L/M state equilibrium on the photocycle, while the identity of the transported ion, Na(+) or H(+), does not affect the photocycle. Our findings will contribute to further elucidation of the molecular mechanisms of KR2.

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The terminal phycobilisome emitter, L _CM : A light-harvesting pigment with a phytochrome chromophore

Tang

Ding

Höppner

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Photosynthesis relies on energy transfer from light-harvesting complexes to reaction centers. Phycobilisomes, the light-harvesting antennas in cyanobacteria and red algae, attach to the membrane via the multidomain core-membrane linker, L CM . The chromophore domain of L CM forms a bottleneck for funneling the harvested energy either productively to reaction centers or, in case of light overload, to quenchers like orange carotenoid protein (OCP) that prevent photodamage. The crystal structure of the solubly modified chromophore domain from Nostoc sp. PCC7120 was resolved at 2.2 Å. Although its protein fold is similar to the protein folds of phycobiliproteins, the phycocyanobilin (PCB) chromophore adopts ZZZssa geometry, which is unknown among phycobiliproteins but characteristic for sensory photoreceptors (phytochromes and cyanobacteriochromes). However, chromophore photoisomerization is inhibited in L CM by tight packing. The ZZZssa geometry of the chromophore and π-π stacking with a neighboring Trp account for the functionally relevant extreme spectral red shift of L CM . Exciton coupling is excluded by the large distance between two PCBs in a homodimer and by preservation of the spectral features in monomers. The structure also indicates a distinct flexibility that could be involved in quenching. The conclusions from the crystal structure are supported by femtosecond transient absorption spectra in solution.cyanobacteria | phycobilisome | core-membrane linker | photosynthesis | crystal structure T he structural separation of light-harvesting and energy transduction processes allows photosynthetic organisms a flexible adaptation to the diverse light regimes present in terrestrial and aqueous habitats. In cyanobacteria and some phylogenetically related organisms that, together, provide a substantial proportion of global carbon fixation, light is harvested by hundreds of chromophores located in the peripheral antenna, namely, the phycobilisome (PBS). These excitations are then collected and transferred to the energy-transducing photosystems I (PSI) and PSII in the photosynthetic membrane via only two pigments, allophycocyanin B (AP-B) and the core-membrane linker (L CM ) (1-5). AP-B preferentially serves PSI (2); it is structurally similar to the bulk phycobiliproteins of the PBS (6). L CM (denoted as ApcE according to the gene by which it is encoded), preferentially serving PSII (5), is a more complex multidomain protein, with an N-terminal section that binds the phycocyanobilin (PCB) chromophore, and is homologous to phycobiliproteins but carries an additional loop that probably acts as a membrane anchor to PSII (4, 7-10). The Cterminal section consists of two to four repeats (depending on the PBS type) that are homologous to the N-terminal domain (Pfam PF00427) of structural PBS proteins, rod-linkers [Protein Data Bank (PDB) ID codes 3OSJ and 3OHW], and considered to organize the complex PBS core (9). They are probably also the loci for phosphorylation (11).Both AP-B and L CM contain the same PCB chromophores...

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Yusaku Hontani

Multicolor three-photon fluorescence imaging with single-wavelength excitation deep in mouse brain

Reaction dynamics of the chimeric channelrhodopsin C1C2

The photochemistry of sodium ion pump rhodopsin observed by watermarked femto- to submillisecond stimulated Raman spectroscopy

The terminal phycobilisome emitter, L _CM : A light-harvesting pigment with a phytochrome chromophore

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Yusaku Hontani

Multicolor three-photon fluorescence imaging with single-wavelength excitation deep in mouse brain

Reaction dynamics of the chimeric channelrhodopsin C1C2

The photochemistry of sodium ion pump rhodopsin observed by watermarked femto- to submillisecond stimulated Raman spectroscopy

The terminal phycobilisome emitter, L CM : A light-harvesting pigment with a phytochrome chromophore

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The terminal phycobilisome emitter, L _CM : A light-harvesting pigment with a phytochrome chromophore