研究者業績

高門 輝

タカカド アキラ  (Akira TAKAKADO)

基本情報

所属
学習院大学 理学部 助教
学位
博士(理学)(京都大学)

J-GLOBAL ID
201801003442865970
researchmap会員ID
B000290405

経歴

 1

学歴

 3

論文

 8
  • Akira Takakado, Koichi Iwata
    Chemical Communications 58(73) 10198-10201 2022年  筆頭著者責任著者
    DNA sequence-dependent thymine dimerization was evaluated using steady-state and transient absorption measurements, which may indicate UV-induced DNA self-repair.
  • Suhyang Kim, Yusuke Nakasone, Akira Takakado, Yoichi Yamazaki, Hironari Kamikubo, Masahide Terazima
    2021年6月2日  
    Photoactive yellow protein (PYP) from Halorhodospira halophila is one of typical light sensor proteins. Although its photoreaction has been extensively studied, no downstream partner protein has been identified to date. In this study, the intermolecular interaction dynamics observed between PYP from Rhodobacter capsulatus (Rc-PYP) and a possible downstream protein, PYP-binding protein (PBP), were studied. It was found that UV light-induced a long-lived product (pUV*), which interacts with PBP to form a stable hetero-hexamer (Complex-Ⅱ). The reaction scheme for this interaction was revealed using transient absorption and transient grating methods. Time-resolved diffusion detection showed that a hetero-trimer (Complex-Ⅰ) is formed transiently, which produced Complex-II via a second-order reaction. Any other intermediates, including those from pBL do not interact with PBP. The reaction scheme and kinetics are determined. Interestingly, long-lived Complex-II dissociates upon excitation with blue light. These results demonstrate that Rc-PYP is a photochromic and new type of UV sensor, of which signaling process is similar to that of other light sensor proteins in the visible light region. The photochromic heterogeneous intermolecular interactions formed between PYP and PBP can be used as a novel and useful tool in optogenetics.
  • Suhyang Kim, Yusuke Nakasone, Akira Takakado, Yoichi Yamazaki, Hironari Kamikubo, Masahide Terazima
    Physical Chemistry Chemical Physics 23(33) 17813-17825 2021年  査読有り
    Photoactive yellow protein (PYP) is one of the typical light sensor proteins. The interaction between PYP and its downstream partner protein PBP (PYP-binding protein) is discovered for the first time and the reaction dynamics are studied.
  • Suhyang Kim, Yusuke Nakasone, Akira Takakado, Yoichi Yamazaki, Hironari Kamikubo, Masahide Terazima
    Biochemistry 59(51) 4810-4821 2020年12月29日  査読有り
    PYPs (photoactive yellow proteins) are blue light sensor proteins found in more than 100 species. Compared with the extensive and intensive studies of the reactions of PYP from Halorhodospira halophila (Hh-PYP), studies of the reactions of other PYPs are scarce. Here, the photoreaction of PYP from Rhodobacter capsulatus (Rc-PYP) was studied in detail using ultraviolet-visible absorption and transient grating methods. Rc-PYP exhibits two absorption peaks at 375 and 438 nm. By using the transient absorption and the temperature-dependent absorption spectrum, the absorption spectra of two forms, pUV and pBL, were determined. Upon photoexcitation of pBL, two intermediates are observed before returning back to the dark state, with a time constant of 1.2 ms, which is 3 orders of magnitude faster than the dark recovery of Hh-PYP. Upon photoexcitation of pUV, two intermediates are observed to produce a long-lived final product, although one of the processes is spectrally silent. The diffusion coefficients decreased transiently for both pBL and pUV reactions, suggesting a relatively large conformational change during the reactions. It is particularly interesting to observe that the blue light irradiation of the long-lived product of pUV returns the product to the dark state. This result suggests different opposing responses of the biological function due to photoexcitation by ultraviolet and blue lights.
  • Naoki Noto, Keigo Takahashi, Shion Goryo, Akira Takakado, Koichi Iwata, Takashi Koike, Munetaka Akita
    The Journal of organic chemistry 85(20) 13220-13227 2020年10月16日  査読有り
    Organic photoredox catalysis has become a useful tool for the development of metal-free radical reactions. Recently, we have reported that 1,4-bis(diphenylamino)naphthalene N serves as an efficient photoredox catalyst for radical monofluoromethylation with N-tosyl-S-monofluoromethyl-S-phenylsulfoximine 2. In this paper, we report the preparation and photo- and electrochemical properties of (diarylamino)naphthalene derivatives, 1,4-bis(di(p-tert-butylphenyl)amino)naphthalene 1a, 1,5-bis(di(p-tert-butylphenyl)amino)naphthalene 1b, and 1-(di(p-tert-butylphenyl)amino)naphthalene) 1c, as supported by density functional theory (DFT) and time-dependent-DFT calculations. In addition, their performance of photocatalysis has been evaluated by means of methoxy-monofluoromethylation of aromatic alkenes. Laser flash photolysis shows that the fluorescence of 1a in the excited state is efficiently quenched by 2 (quenching rate constant kq = ca. 2 × 109 M-1 s-1). Transient absorption spectroscopic analyses reveal that the excited species of 1a in the presence of 2 starts decreasing in ca. 100 ps, suggesting the occurrence of fast electron-transfer processes. These results lead to the unconventional concept for the catalyst design, that is, long lifetime of the excited state is not always a requisite for efficient photoredox catalysts.
  • Akira Takakado, Yusuke Nakasone, Masahide Terazima
    Biochemistry 57(10) 1603-1610 2018年3月13日  査読有り筆頭著者
    EL222 is a blue light sensor protein, which consists of a light-oxygen-voltage domain as a light sensor and a LuxR-type helix-turn-helix DNA-binding domain. The reaction dynamics of the protein-DNA binding were observed for the first time using the time-resolved transient grating method. The reaction scheme was determined, showing that photoexcited EL222 first binds DNA and the ground state EL222 monomer is subsequently associated with the complex. Rate constants on the millisecond scale were determined for these processes. In addition, binding rates for EL222 with three DNA sequences, with different binding affinities, were measured. Although EL222 binds nonspecific DNA sequences with affinities at least 5-fold lower than the target sequence affinity, the binding rates were almost the same as that for the target DNA. This observation indicates that the specific and nonspecific binding affinities are mainly controlled by differences in the dissociation of DNA binding.
  • Akira Takakado, Yusuke Nakasone, Masahide Terazima
    Physical chemistry chemical physics : PCCP 19(36) 24855-24865 2017年9月20日  査読有り筆頭著者
    EL222 is a blue light sensor protein consisting of a light-oxygen-voltage (LOV) domain (EL-LOV domain) at the N-terminus and a helix-turn-helix DNA-binding domain at the C-terminus. EL222 acts as a light dependent transcriptional factor. The photochemical reactions of EL222 and the light sensing properties of the LOV domain were investigated. Concentration dependent experiments revealed that the EL-LOV domain is in equilibrium between the dimer and the monomer in the dark state, and the main photoreaction is the dimerization reaction between a monomer in the ground state and that in the excited state. The equilibrium constant and the intrinsic rate constants of dimerization were determined. EL222 was found to also exhibit photoinduced dimerization even in the absence of target DNA, although the yield of the reaction was low (∼0.08 compared with that of the EL-LOV domain). This observation suggests that there are inhomogeneous conformations, open and closed types, of EL222 in solution.
  • Akira Takakado, Yusuke Nakasone, Koji Okajima, Satoru Tokutomi, Masahide Terazima
    The journal of physical chemistry. B 121(17) 4414-4421 2017年5月4日  査読有り筆頭著者
    Phototropins (phots) are blue light sensors found in a variety of higher plants and algae. The photochemical reactions of this family of proteins have attracted much attention since their discovery. Phots have two light sensor domains called light-oxygen-voltage 1 (LOV1) and LOV2. After the formation of the characteristic adduct of the LOV domain, a conformational change of the C-terminal region of the LOV2 domain occurs, and characterizing this change is important for understanding biological function, that is, kinase activation. Here, the reaction dynamics of the Jα-helix and the extended region adjacent to the Jα-helix (connector) have been investigated. The conformation of the connector part and the Jα-helix were found to alter significantly in a two-state manner. Furthermore, the conformational change of the kinase domain was also successfully detected as a change in translational diffusion, although the CD intensity due to the kinase domain movement was almost silent. These observations indicate that the tertiary structure of the kinase domain changes. The rate of the kinase domain change is almost the same as that of the change for the LOV2-linker, suggesting that the conformational change of the linker is the rate-determining step for kinase activation.

MISC

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共同研究・競争的資金等の研究課題

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