Co-reporter:Tadao Takada, Mai Takemura, Yuta Kawano, Mitsunobu Nakamura, and Kazushige Yamana
Langmuir 2015 Volume 31(Issue 13) pp:3993-3998
Publication Date(Web):March 25, 2015
DOI:10.1021/la505013u
We describe a simple and convenient method for the preparation of photoresponsive DNA-modified electrodes using primer extension (PEX) reactions. A naphthalimide derivative was used as the photosensitizer that was attached to the C5-position of 2′-deoxyuridine-5′-triphosphate (dUTPNI). It has been found that dUTPNI is a good substrate for the PEX reactions using KOD Dash and Vent (exo-) enzymes in solutions to incorporate naphthalimide (NI) moieties into the DNA sequences. On the electrode surface immobilized with the primer/template DNA, the PEX reactions to incorporate dUTPNI molecules into the DNA sequence were found to efficiently proceed. With this solid-phase method, the DNA monolayers capable of generating photocurrent due to the photoresponsive NI molecule can be constructed. It was shown that the photocurrent generation was significantly suppressed by a single-nucleotide mismatch included in the primer/template DNA, which is applicable for the design of photoelectrochemical sensors to discriminate single-nucleotide sequences.
Co-reporter:Dr. Tadao Takada;Misa Ido;Akane Ashida;Dr. Mitsunobu Nakamura;Dr. Mamoru Fujitsuka;Dr. Kiyohiko Kawai; Tetsuro Majima; Kazushige Yamana
Chemistry - A European Journal 2015 Volume 21( Issue 18) pp:6846-6851
Publication Date(Web):
DOI:10.1002/chem.201406592
Abstract
The charge-transfer process in noncovalent perylenediimide (PDI)/DNA complexes has been investigated by using nanosecond laser flash photolysis (LFP) and photocurrent measurements. The PDI/DNA complexes were prepared by inclusion of cationic PDI molecules into the artificial cavities created inside DNA. The LFP experiments showed that placement of the PDI chromophore at a specific site and included within the base stack of DNA led to the efficient generation of a charge-separated state with a long lifetime by photoexcitation. When two PDI chromophores were separately placed at different positions in DNA, the yield of the charge-separated state with a long lifetime was dependent upon the number of A–T base pairs between the PDIs, which was explained by electron hopping from one PDI to another. Photocurrent generation of the DNA-modified electrodes with the complex was also dependent upon the arrangement of the PDI chromophores. A good correlation was obtained between observed charge separation and photocurrent generation on the PDI/DNA-modified electrodes, which demonstrated the importance of the defined arrangement and assembly of organic chromophores in DNA for efficient charge separation and transfer in multichromophore arrays.
Co-reporter:Tadao Takada ; Akane Ashida ; Mitsunobu Nakamura ; Mamoru Fujitsuka ; Tetsuro Majima ;Kazushige Yamana
Journal of the American Chemical Society 2014 Volume 136(Issue 19) pp:6814-6817
Publication Date(Web):May 1, 2014
DOI:10.1021/ja501535z
We now report the photocurrent generation and charge transfer dynamics of stacked perylenediimide (PDI) molecules within a π-stack array of DNA. The cofacially stacked PDI dimer and trimer were found to strongly enhance the photocurrent generation compared to an isolated PDI monomer. Femtosecond time-resolved transient absorption experiments revealed that the excitation of the stacked PDI dimer and trimer provided the broad transient absorption band, which was attributed to the charge delocalization of a negative charge over the PDI chromophores. The lifetime of the charge delocalization of the PDI dimer and trimer (nearly 1 ns) was much longer than that of the charge separated state of the PDI monomer. A comparison between the photocurrent measurements and time-resolved transient absorption measurements demonstrated that the cofacially stacked structure could possibly lead to the charge delocalization and increase the lifetime of the charge-separated state that is essential to enhancing the photocurrent generation.
Co-reporter:Tadao Takada, Kosato Yamaguchi, Suguru Tsukamoto, Mitsunobu Nakamura and Kazushige Yamana
Analyst 2014 vol. 139(Issue 16) pp:4016-4021
Publication Date(Web):16 Jun 2014
DOI:10.1039/C4AN00493K
Here we study the binding behavior of perylenediimide (PDI) derivatives to a hydrophobic pocket created inside DNA and their photochemical properties capable of designing a light-up fluorescent sensor for short single-stranded DNA or RNA. The perylenediimide derivative with alkoxy groups (PO) suppressing electron transfer quenching was examined. The PO bound randomly to DNA showed negligible fluorescence due to the aggregation-induced quenching, whereas the PO bound to the pocket as a monomeric form showed more than 100-fold fluorescence enhancement. Switching the binding states of the PO corresponded to a change in the fluorescence response for the hybridization event, which allowed us to design a fluorescent sensor of nucleic acids with a nanomolar detection limit.
Co-reporter:Tadao Takada, Yumiko Otsuka, Mitsunobu Nakamura and Kazushige Yamana
RSC Advances 2014 vol. 4(Issue 103) pp:59440-59443
Publication Date(Web):10 Nov 2014
DOI:10.1039/C4RA11761A
We now show that a hydrophobic cavity created within the DNA can work as a scaffold to form a charge transfer (CT) complex composed of naphthalenediimide (NDI) and dialkoxynaphthalene (DAN) derivatives. The formation of the CT complex resulted in stabilization of the duplex structure through stacking interaction, which was comparable to the natural base pairs.
Co-reporter:Tadao Takada, Takaaki Tochi, Mitsunobu Nakamura, Kazushige Yamana
Bioorganic & Medicinal Chemistry Letters 2014 Volume 24(Issue 12) pp:2661-2663
Publication Date(Web):15 June 2014
DOI:10.1016/j.bmcl.2014.04.062
DNA molecules possessing multiple ferrocene (Fc) molecules as a redox active probe were prepared by the primer extension (PEX) reaction using a 2′-deoxyuridine-5′-triphosphate derivative in which Fc was connected to the C5-position of the uridine by a diethylene glycol linker. Gold nanoparticles (AuNP) covered with DNA possessing the Fc molecules were prepared by the PEX reaction on the surface. The AuNP–FcDNA conjugates exhibit a detectable electrochemical signal due to the Fc molecules. Possible application of the PEX reaction on AuNP is demonstrated for the detection of a single nucleotide mutation in the target DNA.
Co-reporter:Tadao Takada, Akane Ashida, Mitsunobu Nakamura, Kazushige Yamana
Bioorganic & Medicinal Chemistry 2013 Volume 21(Issue 19) pp:6011-6014
Publication Date(Web):1 October 2013
DOI:10.1016/j.bmc.2013.07.040
Small ligand molecules, which can recognize thermodynamically unstable site within DNA, such as mismatch base pair, abasic site, and single-bulge, have attracted much attention because of their potential diagnostics and biological applications. In this paper, we describe the binding of cationic perylenediimide (cPDI) molecules to thymine-containing mismatch base pair in DNA and the formation of cPDI dimer at the mismatch site. The cPDI dimer exhibits a characteristic excimer emission at 650 nm. For T/T mismatch containing DNA, the switching behavior from the PDI dimer (650 nm) to the monomer (550 nm) emission in specific response to Hg2+ ion was observed.
Co-reporter:Tadao Takada, Yuta Kawano, Akane Ashida, Mitsunobu Nakamura, Kiyohiko Kawai, Tetsuro Majima, Kazushige Yamana
Tetrahedron Letters 2013 Volume 54(Issue 35) pp:4796-4799
Publication Date(Web):28 August 2013
DOI:10.1016/j.tetlet.2013.06.140
DNA oligonucleotides possessing naphthalimide (NI) at the C5 position of deoxyuridine through an ethynyl-containing linker have been synthesized. Based on time-resolved laser flash photolysis, we showed that the photo-induced charge transfer occurs between NI at the C-5 position and the guanine base of DNA with almost same efficiency (1.8%) when compared to the terminal NI-modified DNA (2.3%). Photoelectrochemical experiments showed that DNA with NI immobilized on the gold electrode generated the photocurrent (28 ± 2 nA/cm2). These results revealed that the NI chromophore located in the extrahelical position could work as a good photosensitizer to induce the charge transfer in DNA.
Co-reporter:Tadao Takada, Yuta Kawano, Mitsunobu Nakamura, Kazushige Yamana
Tetrahedron Letters 2012 Volume 53(Issue 1) pp:78-81
Publication Date(Web):4 January 2012
DOI:10.1016/j.tetlet.2011.10.150
DNA oligomers possessing a 2-nitrobenzyl (NB) protected thiol group have been prepared. The photo-remove of the NB to generate a free thiol group in DNA has been analyzed by using reverse-phase HPLC and denaturing gel electrophoresis. The photo-triggered generation of the thiol function in DNA was applicable in the light-initiated ligation of thiol-modified DNA oligomers and Au–DNA conjugation.
Co-reporter:Dr. Tadao Takada;Yumiko Otsuka;Dr. Mitsunobu Nakamura ;Dr. Kazushige Yamana
Chemistry - A European Journal 2012 Volume 18( Issue 30) pp:9300-9304
Publication Date(Web):
DOI:10.1002/chem.201201469
Abstract
DNA is a unique yet useful material to organize nanoscale molecular arrays along the helix axis. In this study, we demonstrate a useful approach for creating molecular arrays inside a double helical DNA. Our approach is based on a host–guest system. Introducing abasic sites into DNA afforded a hydrophobic cavity that serves as a host. A planar aromatic molecule (cationic perylenediimide, PDI) was used as the guest molecule. In an aqueous solution, the PDI molecules tend to aggregate with themselves due to the strong hydrophobicity. In the presence of DNA with the cavity, the binding of the PDI was found to site-specifically occur in the hydrophobic cavity. The unique assembly and arrangement for more than two PDI molecules was achieved by controlling the sizes and positions of the cavities. Our approach would provide a simple and convenient way to construct one-dimensional aromatic arrays in DNA.
Co-reporter:Tadao Takada, Chie Tanaka, Mitsunobu Nakamura, Kazushige Yamana
Bioorganic & Medicinal Chemistry Letters 2010 Volume 20(Issue 3) pp:994-996
Publication Date(Web):1 February 2010
DOI:10.1016/j.bmcl.2009.12.052
The DNA base stack provides unique features for the efficient long-range charge transfer. For the purpose of investigating excess electron transfer process through DNA, we developed a new method for fluorescence analysis of excess electron transfer based on reductive cleavage of a disulfide bond and a thiol-specific fluorescent probe. Excess electron transfer was detected by monitoring the fluorescence of emissive pyrene monomer generated by the reaction of pyrene maleimides with the cleaved disulfide bond (thiols). Mechanism of reductive cleavage of disulfides through excess electron transfer and subsequent reaction with the fluorescent probes were discussed. This facile and sensitive detection by fluorescence method can be applied for mechanistic study of excess electron transfer.A new method for fluorescence analysis of excess electron transfer through DNA based on reductive cleavage of a disulfide bond and a thiol-specific fluorescent probe is described.
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