Your search keyword '"Fujitsuka M"' showing total 38 results

1. Stacked Thiazole Orange Dyes in DNA Capable of Switching Emissive Behavior in Response to Structural Transitions.

Author

Takada T, Nishida K, Honda Y, Nakano A, Nakamura M, Fan S, Kawai K, Fujitsuka M, and Yamana K

Subjects

Amination, Circular Dichroism, Fluorescent Dyes chemistry, Nucleic Acid Hybridization, Oxidation-Reduction, Spectrometry, Fluorescence, Transition Temperature, Benzothiazoles chemistry, DNA chemistry, Quinolines chemistry

Abstract

Functional nucleic acids with the capability of generating fluorescence in response to hybridization events, microenvironment or structural changes are valuable as structural probes and chemical sensors. We now demonstrate the enzyme-assisted preparation of nucleic acids possessing multiple thiazole orange (TO) dyes and their fluorescent behavior, that show a spectral change from the typical monomer emission to the excimer-type red-shifted emission. We found that the fluorescent response and emission wavelength of the TO dyes were dependent on both the state of the DNA structure (single- or double-stranded DNA) and the arrangement of the TO dyes. We showed that the fluorescent behavior of the TO dyes can be applied for the detection of RNA molecules, suggesting that our approach for preparing the fluorescent nucleic acids functionalized with multiple TO dyes could be useful to design a fluorescence bioimaging and detection technique of biomolecules., (© 2021 Wiley-VCH GmbH.)

Published

2021

2. Rapid Electron Transfer of Stacked Heterodimers of Perylene Diimide Derivatives in a DNA Duplex.

Author

Takada T, Ishino S, Takata A, Nakamura M, Fujitsuka M, Majima T, and Yamana K

Subjects

Base Pairing, Dimerization, Electron Transport, Perylene chemistry, DNA chemistry, Fluorescent Dyes chemistry, Imides chemistry, Perylene analogs & derivatives

Abstract

The preparation of homo- and heterocomplexes composed of the parent perylene diimide (PH) and pyrrolidine-substituted perylene diimide (PN) in DNA and rapid electron transfer in these complexes, which has been analyzed by steady-state fluorescence and femtosecond transient absorption measurements, have been demonstrated. The DNA molecules possessing PH and PN were prepared through a recently developed method that involved the reaction of enzymatically generated abasic sites with the amino groups of the perylene diimide molecules, through which these molecules can be incorporated as base surrogates within the DNA base stack. Melting temperature analysis showed that the PH and PN monomers, and their homo- and heterodimers, contribute to the stabilization of the DNA duplex, and is comparable to that of natural base pairs. Fluorescence measurements showed that PH in a single-stranded oligopyrimidine showed a strong fluorescence, whereas the fluorescence of PH was completely quenched upon pairing with PN (PH/PN) through duplex formation. The transient absorption measurements showed that a rapid electron-transfer reaction in the stacked PH/PN heterodimer occurred on a sub-picosecond timescale, which allowed highly efficient fluorescence quenching. The PH/PN pair, which served as a fluorophore and quencher, were utilized to design molecular beacon probes with a high signal/noise ratio. The PH/PN pair was also capable of forming a stable, stacked dimer structure and induced rapid electron transfer that could serve as a good signal reporter for fluorescent nucleic acid detection., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

3. Sequence-Dependent Photocurrent Generation through Long-Distance Excess-Electron Transfer in DNA.

Author

Lin SH, Fujitsuka M, and Majima T

Subjects

Base Sequence, Electrodes, Electron Transport, Gold chemistry, Oxidation-Reduction, Quantum Theory, DNA chemistry, Electrochemical Techniques

Abstract

Given its well-ordered continuous π stacking of nucleobases, DNA has been considered as a biomaterial for charge transfer in biosensors. For cathodic photocurrent generation resulting from hole transfer in DNA, sensitivity to DNA structure and base-pair stacking has been confirmed. However, such information has not been provided for anodic photocurrent generation resulting from excess-electron transfer in DNA. In the present study, we measured the anodic photocurrent of a DNA-modified Au electrode. Our results demonstrate long-distance excess-electron transfer in DNA, which is dominated by a hopping mechanism, and the photocurrent generation is sequence dependent., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

4. Excess-Electron Transfer in DNA by a Fluctuation-Assisted Hopping Mechanism.

Author

Lin SH, Fujitsuka M, and Majima T

Subjects

Circular Dichroism, Kinetics, Photosensitizing Agents chemistry, Spectrophotometry, Ultraviolet, DNA chemistry, Electrons

Abstract

The dynamics of excess-electron transfer in DNA has attracted the attention of scientists from all kinds of research fields because of its importance in biological processes. To date, several studies on excess-electron transfer in consecutive adenine (A):thymine (T) sequences in donor-DNA-acceptor systems have been published. However, the reported excess-electron transfer rate constants for consecutive T's are in the range of 10(10)-10(11) s(-1) depending on the photosensitizing electron donor, which provides various driving forces for excess-electron injection into DNA. In this study, we employed a strongly electron-donating photosensitizer, a dimer of 3,4-ethylenedioxythiophene (2E), and an electron acceptor, diphenylacetylene (DPA), to synthesize a series of modified DNA oligomers (2-Tn, n = 3-6) in order to investigate the excess-electron transfer dynamics in these donor-DNA-acceptor systems using femtosecond laser flash photolysis. The relation between the free energy change for charge injection and the excess-electron transfer rate among consecutive T's provided an intrinsic excess-electron hopping rate constant of (3.8 ± 1.5) × 10(10) s(-1) in the DNA, which is consistent with the fluctuation frequency of the DNA sugar backbone and bases (3.3 × 10(10) s(-1)). Thus, we discuss the effect of structural fluctuations on the excess-electron hopping in DNA.

Published

2016

5. Dynamics of Excess-Electron Transfer through Alternating Adenine:Thymine Sequences in DNA.

Author

Lin SH, Fujitsuka M, and Majima T

Subjects

Acetylene chemistry, DNA chemical synthesis, DNA metabolism, DNA Damage, DNA Repair, Electron Transport, Electrons, Nucleotides metabolism, Acetylene analogs & derivatives, Adenine chemistry, DNA chemistry, Nucleotides chemistry, Photosensitizing Agents chemistry, Thiophenes chemistry, Thymine chemistry

Abstract

This paper presents the results of an investigation into the sequence-dependent excess-electron transfer (EET) dynamics in DNA, which plays an important role in DNA damage/repair. There are many published studies on EET in consecutive adenine:thymine (A:T) sequences (Tn), but those in alternating A:T sequences (ATn) remain limited. Here, two series of functionalized DNA oligomers, Tn and ATn, were synthesized with a strongly electron-donating photosensitizer, a trimer of ethylenedioxythiophene (3 E), and an electron acceptor, diphenylacetylene (DPA). Laser flash photolysis experiments showed that the EET rate constant of AT3 is two times lower than that of T3 due to the lack of π-stacking of Ts in AT3. Thus, it was indicated that excess-electron hopping is affected by the interaction between LUMOs of nucleotides., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

6. How Does Guanine-Cytosine Base Pair Affect Excess-Electron Transfer in DNA?

Author

Lin SH, Fujitsuka M, and Majima T

Subjects

Acetylene analogs & derivatives, Acetylene chemistry, Circular Dichroism, Photolysis, Photosensitizing Agents, Protons, Spectrometry, Fluorescence, Thiophenes chemistry, Thymine chemistry, Transition Temperature, Base Pairing, Cytosine chemistry, DNA chemistry, Electron Transport, Electrons, Guanine chemistry

Abstract

Charge transfer and proton transfer in DNA have attracted wide attention due to their relevance in biological processes and so on. Especially, excess-electron transfer (EET) in DNA has strong relation to DNA repair. However, our understanding on EET in DNA still remains limited. Herein, by using a strongly electron-donating photosensitizer, trimer of 3,4-ethylenedioxythiophene (3E), and an electron acceptor, diphenylacetylene (DPA), two series of functionalized DNA oligomers were synthesized for investigation of EET dynamics in DNA. The transient absorption measurements during femtosecond laser flash photolysis showed that guanine:cytosine (G:C) base pair affects EET dynamics in DNA by two possible mechanisms: the excess-electron quenching by proton transfer with the complementary G after formation of C(•-) and the EET hindrance by inserting a G:C base pair as a potential barrier in consecutive thymines (T's). In the present paper, we provided useful information based on the direct kinetic measurements, which allowed us to discuss EET through oligonucleotides for the investigation of DNA damage/repair.

Published

2015

7. Photocurrent generation through charge-transfer processes in noncovalent perylenediimide/DNA complexes.

Author

Takada T, Ido M, Ashida A, Nakamura M, Fujitsuka M, Kawai K, Majima T, and Yamana K

Subjects

Base Pairing, Base Sequence, Binding Sites, Electrochemical Techniques, Electrodes, Electron Transport, Molecular Sequence Data, Perylene chemistry, Photochemical Processes, Coloring Agents chemistry, DNA chemistry, Imides chemistry, Perylene analogs & derivatives

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., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

8. Photocurrent generation enhanced by charge delocalization over stacked perylenediimide chromophores assembled within DNA.

Author

Takada T, Ashida A, Nakamura M, Fujitsuka M, Majima T, and Yamana K

Subjects

Base Sequence, Dimerization, Electricity, Electrons, Models, Molecular, Perylene chemistry, Photochemical Processes, Coloring Agents chemistry, DNA chemistry, Imides chemistry, Perylene analogs & derivatives

Abstract

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.

Published

2014

9. Efficient electron transfer in i-motif DNA with a tetraplex structure.

Author

Choi J, Tanaka A, Cho DW, Fujitsuka M, and Majima T

Subjects

DNA metabolism, Electron Transport, Nucleotide Motifs, Oxidation-Reduction, Spectrum Analysis, DNA chemistry

Abstract

Electron transfer through DNA: The electron-transfer dynamics of i-motif DNA conjugated with pyrene (Py) and anthraquinone (AQ) has been investigated by fluorescence up-conversion and transient absorption spectroscopic methods. Electron transfer (see red arrows) in i-motif DNA is more efficient than in duplex DNA, suggesting that i-motif DNA can be used as electron carrier in nanoelectronic devices., (Copyright © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2013

10. Excess electron transfer dynamics in DNA hairpins conjugated with N,N-dimethylaminopyrene as a photosensitizing electron donor.

Author

Park MJ, Fujitsuka M, Nishitera H, Kawai K, and Majima T

Subjects

Inverted Repeat Sequences, Models, Molecular, Molecular Structure, DNA chemistry, Electrons, Photosensitizing Agents chemistry, Pyrenes chemistry

Abstract

Excess electron transfer dynamics in DNA hairpins was investigated by femtosecond laser flash photolysis of a donor-DNA-acceptor system using N,N-dimethylaminopyrene and diphenylacetylene as an electron donor and acceptor, respectively. It was revealed that the excess electron hopping rate between T's is faster than that of the hole.

Published

2012

11. Hole and excess electron transfer dynamics in DNA.

Author

Fujitsuka M and Majima T

Subjects

Base Sequence, Cold Temperature, Electron Transport, Glass chemistry, Spectrum Analysis, DNA chemistry, Electrons

Abstract

Charge transfer in DNA attracts substantial attention from researchers in a wide group of fields such as bioscience, nanotechnology and physical chemistry. It is well known that both positive and negative charges, which are holes and excess electrons, respectively, contribute to the charge transfer in DNA. In the case of hole transfer in DNA, detailed mechanisms and dynamical parameters have been estimated by means of time-resolved spectroscopic methods and product analysis. On the other hand, detailed dynamics of excess electron transfer have not been established yet, although several aspects have been revealed by the continuous efforts of various research groups. In the present Perspective, studies on the charge transfer dynamics in DNA are summarized.

Published

2012

12. Excess-electron injection and transfer in terthiophene-modified DNA: terthiophene as a photosensitizing electron donor for thymine, cytosine, and adenine.

Author

Park MJ, Fujitsuka M, Kawai K, and Majima T

Subjects

Electron Transport, Electrons, Models, Chemical, Molecular Structure, Adenine chemistry, Cytosine chemistry, DNA chemistry, Photosensitizing Agents chemistry, Thiophenes chemistry, Thymine chemistry

Abstract

Excess-electron transfer (EET) in DNA has attracted wide attention owing to its close relation to DNA repair and nanowires. To clarify the dynamics of EET in DNA, a photosensitizing electron donor that can donate an excess electron to a variety of DNA sequences has to be developed. Herein, a terthiophene (3T) derivative was used as the photosensitizing electron donor. From the dyad systems in which 3T was connected to a single nucleobase, it was revealed that (1) 3T* donates an excess electron efficiently to thymine, cytosine, and adenine, despite adenine being a well-known hole conductor. The free-energy dependence of the electron-transfer rate was explained on the basis of the Marcus theory. From the DNA hairpins, it became clear that (1) 3T* can donate an excess electron not only to the adjacent nucleobase but also to the neighbor one nucleobase further along and so on. From the charge-injection rate, the possibilities of smaller β value and/or charge delocalization were discussed. In addition, EET through consecutive cytosine nucleobases was suggested., (Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2012

13. Generation of singlet oxygen during photosensitized one-electron oxidation of DNA.

Author

Osakada Y, Kawai K, Tachikawa T, Fujitsuka M, Tainaka K, Tero-Kubota S, and Majima T

Subjects

Base Sequence, Electrophoresis, Gel, Two-Dimensional, Molecular Structure, Oxidation-Reduction, Photochemistry, DNA chemistry, Electrons, Singlet Oxygen chemistry

Published

2012

14. pH-induced intramolecular folding dynamics of i-motif DNA.

Author

Choi J, Kim S, Tachikawa T, Fujitsuka M, and Majima T

Subjects

Base Sequence, Diffusion, Fluorescence Resonance Energy Transfer, Fluorescent Dyes chemistry, Hydrogen-Ion Concentration, Nucleic Acid Conformation, Spectrometry, Fluorescence, DNA chemistry

Abstract

Using the combination of fluorescence resonance energy transfer (FRET) and fluorescence correlation spectroscopy (FCS) technique, we investigate the mechanism and dynamics of the pH-induced conformational change of i-motif DNA in the bulk phases and at the single-molecule level. Despite numerous studies on i-motif that is formed from cytosine (C)-rich strand at slightly acidic pH, its detailed conformational dynamics have been rarely reported. Using the FRET technique to provide valuable information on the structure of biomolecules such as a protein and DNA, we clearly show that the partially folded species as well as the single-stranded structure coexist at neutral pH, supporting that the partially folded species may exist substantially in vivo and play an important role in a process of gene expression. By measuring the FCS curves of i-motif, we observed the gradual decrease of the diffusion coefficient of i-motif with increasing pH. The quantitative analysis of FCS curves supports that the gradual decrease of diffusion coefficient (D) associated with the conformational change of i-motif is not only due to the change in the intermolecular interaction between i-motif and solvent accompanied by the increase of pH but also due to the change of the shape of DNA. Furthermore, FCS analysis showed that the intrachain contact formation and dissociation for i-motif are 5-10 times faster than that for the open form. The fast dynamics of i-motif with a compact tetraplex is due to the intrinsic conformational changes at the fluorescent site including the motion of alkyl chain connecting the dye to DNA, whereas the slow intrachain contact formation observed from the open form is due to the DNA motion corresponding to an early stage interaction in the folding process of the unstructured open form.

Published

2011

15. Direct measurement of the dynamics of excess electron transfer through consecutive thymine sequence in DNA.

Author

Park MJ, Fujitsuka M, Kawai K, and Majima T

Subjects

Electron Transport, Kinetics, Photolysis, Thiophenes chemistry, DNA chemistry, DNA metabolism, Thymine chemistry, Thymine metabolism

Abstract

Charge transfer in DNA is an essential process in biological systems because of its close relation to DNA damage and repair. DNA is also an important material used in nanotechnology for wiring and constructing various nanomaterials. Although hole transfer in DNA has been investigated by various researchers and the dynamic properties of this process have been well established, the dynamics of a negative charge, that is, excess electron, in DNA have not been revealed until now. In the present paper, we directly measured the rate of excess electron transfer (EET) through a consecutive thymine (T) sequence in nicked-dumbbell DNAs conjugated with a tetrathiophene derivative (4T) as an electron donor and diphenylacetylene (DPA) as an electron acceptor at both ends. The selective excitation of 4T by a femtosecond laser pulse caused the excess electron injection into DNA, and led to EET in DNA by a consecutive T-hopping mechanism, which eventually formed the DPA radical anion (DPA(•-)). The rate constant for the process of EET through consecutive T was determined to be (4.4 ± 0.3) × 10(10) s(-1) from an analysis of the kinetic traces of the ΔO.D. during the laser flash photolysis. It should be emphasized that the EET rate constant for T-hopping is faster than the rate constants for oxidative hole transfers in DNA (10(4) to 10(10) s(-1) for A- and G-hopping).

Published

2011

16. Sequence dependence of excess electron transfer in DNA.

Author

Tainaka K, Fujitsuka M, Takada T, Kawai K, and Majima T

Subjects

Acetylene analogs & derivatives, Acetylene chemistry, Base Sequence, Coloring Agents chemistry, DNA chemistry, Electron Transport, Inverted Repeat Sequences, Kinetics, Photosensitizing Agents chemistry, Pyrenes chemistry, Spectrum Analysis, DNA genetics, DNA metabolism

Abstract

DNA-mediated charge transfer has recently received a substantial attention because of its biological relevance in the DNA damage and DNA repair as well as the potential applications to nanoscale electronic devices. In contrast to the numerous mechanistic studies on oxidative hole transfer (HT) through DNA, our understanding of reductive electron transfer process still remains limited. In this article, we demonstrate the results of direct observation of the excess electron transfer (EET) through DNA, which conjugated with aminopyrene ((A)Py) and diphenylacetylene (DPA) as a photosensitizing donor and an acceptor of excess electron, respectively. By inserting dihydrothymine as a spacer between (A)Py and T or C, the yield of electron arrival to DPA was improved. It was indicated that EET through DNA completed within a few or a few tens nanosecond time scale even for EET over 34 Å for both consecutive T and C sequences. The various factors such as mismatch sequence and DNA length on the yield of electron arrival to DPA were examined.

Published

2010

17. "Signal-on" detection of DNA hole transfer at the single molecule level.

Author

Takada T, Takeda Y, Fujitsuka M, and Majima T

Subjects

Base Sequence, Sensitivity and Specificity, DNA chemistry, Fluorescence Resonance Energy Transfer methods, Nucleic Acid Conformation

Abstract

The DNA base stack provides unique features for the efficient long-range charge transfer. For the purpose of investigating the hole transfer process of individual DNA and the optical readout of DNA information at the single molecule level, we performed single-molecule detection of DNA hole transfer (DNA HT) using single-molecule fluorescence spectroscopy. We have established the single-molecule detection of DNA HT at the single molecule level based on the fluorescence generation by combining the oxidative reaction of the quencher molecule through DNA HT and the cancellation of FRET. This "signal-on" detection system makes it possible to detect DNA HT in individual DNA and the base-pair mismatch in the target DNA with high sensitivity and accuracy.

Published

2009

18. Kinetics of charge transfer in DNA containing a mismatch.

Author

Osakada Y, Kawai K, Fujitsuka M, and Majima T

Subjects

Adenine chemistry, Guanine chemistry, Kinetics, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Thymine chemistry, Base Pair Mismatch, DNA chemistry

Abstract

Charge transfer (CT) in DNA offers a unique approach for the detection of a single-base mismatch in a DNA molecule. While the single-base mismatch would significantly affect the CT in DNA, the kinetic basis for the drastic decrease in the CT efficiency through DNA containing mismatches still remains unclear. Recently, we determined the rate constants of the CT through the fully matched DNA, and we can now estimate the CT rate constant for a certain fully matched sequence. We assumed that further elucidating of the kinetics in mismatched sequences can lead to the discrimination of the DNA single-base mismatch based on the kinetics. In this study, we investigated the detailed kinetics of the CT through DNA containing mismatches and tried to discriminate a mismatch sequence based on the kinetics of the CT in DNA containing a mismatch.

Published

2008

19. Charge transfer in DNA assemblies: effects of sticky ends.

Author

Osakada Y, Kawai K, Fujitsuka M, and Majima T

Subjects

Absorption, Base Sequence, Kinetics, Molecular Sequence Data, Spectrum Analysis, DNA chemistry, Energy Transfer

Abstract

Transient absorption measurements of charge transfer (CT) demonstrated that the CT in the DNA assembly constructed by simply mixing DNAs with sticky ends occurs over 200 angstroms selectively to the complementary sticky end sequences.

Published

2008

20. Charge separation in acridine- and phenothiazine-modified DNA.

Author

Kawai K, Osakada Y, Fujitsuka M, and Majima T

Subjects

Base Pairing radiation effects, Ions, Oxidation-Reduction, Photochemistry, Photosensitizing Agents, Spectrometry, Fluorescence, Static Electricity, Acridines chemistry, DNA chemistry, DNA radiation effects, Phenothiazines chemistry

Abstract

The formation of the long-lived, charge-separated state in DNA upon visible light irradiation is of particular interest in molecular-scale optoelectronics, sensor design, and other areas of nanotechnology. However, the efficient generation of the charge-separated state is hampered by fast charge recombination within a contact ion pair, which limits the application of DNA for photoelectrochemical sensors and devices. In this study, a series of protonated 9-alkylamino-6-chloro-2-methoxyacridine (Acr+)- and phenothiazine (Ptz)-modified DNAs were synthesized for the further understanding of the mechanism of charge separation in DNA to generate a long-lived, charge-separated state with a high quantum yield (Phi). The Acr+ serves as a photosensitizer to produce a hole on guanine (G), and the G-C base pairs were used as a hole-transporting pathway to separate a hole from Acr* (the one-electron-reduced form of Acr+) to be trapped at Ptz. Since Acr+ oxides only G upon photoexcitation, the A-T base pair can be used as a spacer between Acr+ and the G-C base pair to avoid the formation of a contact ion pair. The charge injection dynamics was investigated by steady-state fluorescence spectra and fluorescence lifetime measurements, and the Phi and the lifetime of the charge-separated state produced upon photoirradiation were assessed by nanosecond laser flash photolysis of the Acr+- and Ptz-modified DNA. A long-lived, charge-separated state was successfully formed upon visible-light irradiation, and the Phi was the highest for the DNA having a single intervening A-T base pair between Acr+ and the G-C base pair. These results clearly demonstrated that the charge separation process in DNA can be refined by putting a redox-inactive intervening base pair as a spacer between a photosensitizer and the nucleobase to be oxidized to slow down the charge recombination rate.

Published

2008

21. Diastereochemically controlled porphyrin dimer formation on a DNA duplex scaffold.

Author

Endo M, Fujitsuka M, and Majima T

Subjects

Circular Dichroism, Dimerization, Models, Molecular, Molecular Structure, Nucleic Acid Denaturation, Porphyrins chemical synthesis, Spectrophotometry, Stereoisomerism, Transition Temperature, DNA chemistry, Porphyrins chemistry

Abstract

DNA-porphyrin conjugates were designed and synthesized for the preparation of the conformationally controlled porphyrin dimer structures constructed on a d(GCGTATACGC)2. Porphyrin derivatives were introduced to the central TATpA sequence where p represents the phosphoramidate for the attachment of the free-base porphyrin (FbP) and zinc-coordinated porphyrin (ZnP), which allows contact of the two porphyrins in the minor groove. The porphyrin dimers were characterized using CD, UV-vis, steady-state, and time-resolved fluorescence spectroscopies, indicating that the porphyrins form face-to-face conformations. Also the co-facial conformation was confirmed by comparison with spectra of the non-self-complementary duplex containing one porphyrin moiety. Introduction of zinc into porphyrin moiety destabilized the duplex formation. Two diastereomers showed different thermal stabilities and affected the conformations of porphyrin dimers. The temperature-dependent assembly and the conformational change of the porphyrin dimer on the duplex DNA were observed in the UV-vis spectra, indicating that the dynamic movement of the porphyrin dimer occurs on the duplex. The results indicate that the porphyrin dimers of DNA-FbP conjugates are overlapped clockwise and are located in the minor groove of the usual B-form DNA backbone. The interaction and conformation of two porphyrin moieties are controlled by the following three factors: (1) temperature change during and after formation of the duplex porphyrins at lower temperature; (2) diastereochemistry of the phosphoramidates where porphyrins are connected via a linker; and (3) zinc ion coordination that destabilizes the interaction of porphyrins as well duplex formation.

Published

2008

22. Photocatalytic cleavage of single TiO2/DNA nanoconjugates.

Author

Tachikawa T, Asanoi Y, Kawai K, Tojo S, Sugimoto A, Fujitsuka M, and Majima T

Subjects

Adenine chemistry, Base Sequence, Catalysis, Catechols chemistry, Cytosine chemistry, DNA chemistry, Models, Chemical, Oxidation-Reduction, Quantum Dots, Reactive Oxygen Species chemistry, Semiconductors, Spectrometry, Fluorescence, Spectrophotometry, Ultraviolet, Titanium chemistry, Catechols radiation effects, DNA radiation effects, DNA Damage, Reactive Oxygen Species radiation effects, Titanium radiation effects, Ultraviolet Rays

Abstract

TiO(2)/DNA nanoconjugates were successfully fabricated by using the catechol moiety as a binding functional group, which was confirmed by steady-state absorption and fluorescence spectroscopies. Upon UV irradiation, the photocatalytic cleavage of the TiO(2)/DNA nanoconjugates was observed at the single-molecule level by using wide-field fluorescence microscopy. The decrease in the number of conjugates, which was estimated from the luminescent spots due to semiconductor quantum dots modified at the DNA strand, was significantly inhibited by a single A/C mismatch in the DNA sequences. This result strongly suggests that the migration of holes, which are injected from the photoexcited TiO(2) into the DNA, through the DNA bases plays an important role in the photocatalytic cleavage of the conjugates. The influences of the photogenerated reactive oxygen species (ROS) on the cleavage efficiency were also examined. According to the experimental results, it was concluded that oxidation of the catechol moiety and/or the DNA damage are key reactions in this process.

Published

2008

23. Mechanism of charge separation in DNA by hole transfer through consecutive adenines.

Author

Kawai K, Osakada Y, Fujitsuka M, and Majima T

Subjects

Kinetics, Molecular Structure, Photolysis, Quantum Theory, Time Factors, Adenine chemistry, Bromouracil chemistry, DNA chemistry, Naphthalimides chemistry, Photosensitizing Agents chemistry

Abstract

To investigate the mechanism of charge separation in DNA with consecutive adenines adjacent to a photosensitizer (Sens), a series of naphthalimide (NI) and 5-bromouracil ((br)U)-modified DNAs were prepared, and the quantum yields of formation of the charge-separated states (Phi) upon photo-excitation of the Sens NI in DNA were measured. The Phi was modulated by the incorporation site of (br)U, which changes the oxidation potential of its complementary A through hydrogen bonding and the hole-transfer rates between adenines. The results were interpreted as charge separation by means of the initial charge transfer between NI in the singlet excited state and the second- and third-nearest adenine to the NI. In addition, the oxidation of the A nearest to NI leads to the rapid charge recombination within a contact ion pair. This suggests that the charge-separation process can be refined to maximize the Phi by putting a redox-inactive spacer base pair between a photosensitizer and an A-T stretch.

Published

2008

24. Single-molecule observation of DNA charge transfer.

Author

Takada T, Fujitsuka M, and Majima T

Subjects

Base Pair Mismatch genetics, Base Sequence, DNA genetics, DNA Probes chemistry, Fluorescent Dyes chemistry, Genes, Reporter, Microscopy, Fluorescence, Molecular Sequence Data, Polymorphism, Single Nucleotide, DNA chemical synthesis, Static Electricity

Abstract

DNA charge transfer highly depends on the electronic interaction between base pairs and reflects the difference in the base composition and sequence. For the purpose of investigating the charge transfer process of individual DNA molecules and the optical readout of DNA information at the single-molecule level, we performed single-molecule observation of the DNA charge transfer process by using single-molecule fluorescence spectroscopy. The DNA charge transfer process, leading to the oxidation of the fluorescent dye, was explored by monitoring the on-off signal of the dye after the charge injection by the excitation of a photosensitizer. The photobleaching efficiency of the dyes by the DNA charge transfer specifically depended on the base sequence and mismatch base pair, demonstrating the discrimination of the individual DNA information. Based on this approach, the optical readout of a single-base mismatch contained in a target DNA was performed at the single-molecule level.

Published

2007

25. Hole transfer in DNA and photosensitized DNA damage: importance of adenine oxidation.

Author

Kawai K, Osakada Y, Fujitsuka M, and Majima T

Subjects

Absorption, Base Sequence, DNA Damage, Lasers, Models, Chemical, Molecular Sequence Data, Naphthalimides pharmacology, Nucleic Acid Conformation, Oxidation-Reduction, Photolysis, Photosensitizing Agents pharmacology, Adenine chemistry, DNA radiation effects, Light, Oxygen metabolism

Abstract

Photosensitized DNA damage reactions were investigated for two well-known DNA-damaging photosensitizers (Sens), naphthalimide (NI) and napthaldiimide (NDI), which have similar photophysical properties but differ in their redox properties. NI and NDI derivatives (NIN, NDIN), which have cationic side chains and electrostatically binding to DNA due to favorable electrostatic interactions between the negatively charged phosphate groups of DNA and cationic groups, and NIP and NDIP, which possess phosphate groups and do not bind to DNA, were synthesized. NIN and NDIN can oxidize A and G via their singlet excited state, and NDIP oxidizes A and G via its triplet excited state, whereas NIP oxidizes only G. A combination of laser flash photolysis kinetic studies and quantitative HPLC analyses of photosensitized DNA damage was performed for several DNA sequences in the presence of Sens. NIN, NDIN, and NDIP, which oxidizes A, caused significant DNA damage upon photoirradiation, and DNA damage yield increased with the length of the consecutive A stretch. In contrast, NIP, which oxidizes only G, caused only moderate damage to DNA and showed no preference for the consecutive A sequences. These results clearly demonstrate the importance of A-oxidation, especially in consecutive A sequences, which triggers the rapid hole transfer between A's.

Published

2007

26. Hole transfer rates in A-form DNA/2'-OMeRNA hybrid.

Author

Kawai K, Osakada Y, Sugimoto A, Fujitsuka M, and Majima T

Subjects

Intercalating Agents, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Nucleic Acid Conformation, Stereoisomerism, DNA chemistry, Nucleic Acid Heteroduplexes chemistry, RNA chemistry

Abstract

The hole transfer rates in the DNA/DNA B-form duplex and DNA/2'-OMeRNA A-form duplex were measured which occurred in the time range of approximately 100 micros. The hole transfer rates in the A-form duplexes were slower and more strongly dependent on the temperature compared to those in the B-form duplexes, suggesting that the A-form is more rigid than the B-form duplex in this time scale.

Published

2007

27. Charge transfer through DNA nanoscaled assembly programmable with DNA building blocks.

Author

Osakada Y, Kawai K, Fujitsuka M, and Majima T

Subjects

Base Sequence, DNA chemistry, Kinetics, Molecular Sequence Data, Temperature, DNA chemical synthesis, Nanostructures

Abstract

DNA nanostructures based on programmable DNA molecular recognition have been developed, but the nanoelectronics of using DNA is still challenging. A more rapid charge-transfer (CT) process through the DNA nanoassembly is required for further development of programmable DNA nanoelectronics. In this article, we present direct absorption measurements of the long-range CT over a 140-A DNA assembly based on a GC repetitive sequence constructed by simply mixing DNA building blocks. We show that a CT through DNA nanoscale assembly is possible and programmable with the designed DNA sequence.

Published

2006

28. Detection of the local structural changes in the dimer interface of BamHI initiated by DNA binding and dissociation using a solvatochromic fluorophore.

Author

Nakayama K, Endo M, Fujitsuka M, and Majima T

Subjects

Deoxyribonuclease BamHI metabolism, Dimerization, Fluorescent Dyes, Hydrophobic and Hydrophilic Interactions, Protein Conformation, DNA metabolism, Deoxyribonuclease BamHI chemistry

Abstract

To detect the local structural change in an interface between proteins induced by the substrate binding and dissociation, a solvatochromic fluorescent N(beta)-L-alanyl-5-(N,N-dimethylamino)-naphthalene-1-sulfonamide (DanAla) was introduced into 132 position of the dimer interface in BamHI. Before addition of the substrate, the fluorescence from the normal planer excited state of DanAla moiety was observed as a main emission, and thereby the DanAla in the dimer interface is located in the hydrophobic microenvironment. The incubation with the substrate for 20 min induced the gradual increase in fluorescence intensity around 430 nm. The fact reflects that the polarity is reduced by the slight structural change initiated by the formation of the complex with the substrate. Furthermore, the incubation for more than 20 min caused the slight decrease in fluorescence around 430 nm and an appearance of fluorescence (560 nm) due to twisted intramolecular charge transfer (TICT) excited state. Therefore, the DanAla is exposed to comparative polar environment after the dissociation of the substrate. The fluorescence lifetime as a minor component, which is attributed to the TICT excited state, was reduced by addition of the substrate. The results provide that the hydrophobicity in the dimer interface is increased by the substrate binding. Interestingly, we found that the structure of an initial form is different from that of a refolded form after the dissociation of the substrate using a spectral subtraction technique. We have achieved detection of the changing structure induced by the substrate binding and dissociation using a steady-state and time-resolved fluorescence.

Published

2006

29. Detection of the G-quadruplex-TMPyP4 complex by 2-aminopurine modified human telomeric DNA.

Author

Kimura T, Kawai K, Fujitsuka M, and Majima T

Subjects

Base Sequence, G-Quadruplexes, Humans, Porphyrins chemistry, Spectrometry, Fluorescence, Substrate Specificity, Temperature, 2-Aminopurine chemistry, DNA chemistry, Porphyrins analysis, Telomere chemistry

Abstract

2-Aminopurine (Ap) modified human telomere sequences were used to monitor the specific complex formation of the G-quadruplex and 5,10,15,20-tetrakis(N-methyl-4-pyridyl)porphyrin (TMPyP4).

Published

2006

30. High-yield generation of a long-lived charge-separated state in diphenylacetylene-modified DNA.

Author

Takada T, Kawai K, Fujitsuka M, and Majima T

Subjects

Acetylene chemistry, Base Sequence, DNA chemical synthesis, DNA genetics, Molecular Structure, Photochemistry, Spectrum Analysis, Static Electricity, Acetylene analogs & derivatives, DNA chemistry

Published

2005

31. Four-way-branched DNA-porphyrin conjugates for construction of four double-helix-DNA assembled structures.

Author

Endo M, Shiroyama T, Fujitsuka M, and Majima T

Subjects

Drug Design, Photochemistry, DNA chemistry, Nucleic Acid Conformation, Porphyrins chemistry

Abstract

[reaction: see text] DNA-porphyrin conjugates having four DNA strands were designed and synthesized. Four double helices were assembled using two DNA-porphyrin conjugates and their complementary strands, and the formation of the four double-helix assembled structures with the two DNA-porphyrin units was examined by gel electrophoresis and spectroscopic analysis. The interaction between two porphyrin chromophores in the complex was investigated by measurement of fluorescence lifetimes, and the singlet energy transfer between the two different phorphyrin units (Zn-porphyrin and H2-porphyrin) was observed. These results indicate that multiple and different porphyrin chromophores can be integrated into the DNA structures by programming the sequences of the DNA strands.

Published

2005

32. Contributions of the distance-dependent reorganization energy and proton-transfer to the hole-transfer process in DNA.

Author

Takada T, Kawai K, Fujitsuka M, and Majima T

Subjects

DNA chemical synthesis, DNA radiation effects, Guanine chemistry, Imides chemistry, Intercalating Agents chemistry, Kinetics, Lasers, Naphthalenes chemistry, Phenothiazines chemistry, Protons, Thermodynamics, Ultraviolet Rays, DNA chemistry

Abstract

A kinetic study of the single-step hole transfer in DNA was performed by measuring time-resolved transient absorption. DNA molecules with various sequences were designed and conjugated with naphthalimide (NI) and phenothiazine (PTZ) to investigate the sequence and distance dependence of the single-step hole transfer between guanines (Gs). Hole injection into DNA was accomplished by excitation of the NI site with a 355 nm laser pulse, and the kinetics of the hole-transfer process were investigated by monitoring the transient absorption of the PTZ radical cation (PTZ.+). Kinetic analysis of the time profile of PTZ.+ based on the kinetic model showed that the distance dependence of the hole-transfer process was significantly influenced by the DNA sequence. Results of temperature- and isotope-effect experiments demonstrated that the activation energy increased as the number of bridge bases separating the Gs increased. This is because of the distance-dependent reorganization energy and contribution of the proton-transfer process to the hole transfer in DNA.

Published

2005

33. Selective guanine oxidation by UVB-irradiation in telomeric DNA.

Author

Kawai K, Fujitsuka M, and Majima T

Subjects

DNA chemistry, Oxidation-Reduction, Telomere chemistry, DNA radiation effects, Guanine chemistry, Guanine radiation effects, Telomere radiation effects, Ultraviolet Rays

Abstract

The combination of the transient absorption measurement and DNA damage quantification by HPLC clearly demonstrated the preferential excitation of guanine and its decomposition in quadruplex DNA by UVB-irradiation.

Published

2005

34. Lifetime regulation of the charge-separated state in DNA by modulating the oxidation potential of guanine in DNA through hydrogen bonding.

Author

Kawai K, Osakada Y, Takada T, Fujitsuka M, and Majima T

Subjects

1-Naphthylamine chemistry, Cytosine chemistry, Hydrogen Bonding, Kinetics, Oligonucleotides chemical synthesis, Oxidation-Reduction, Photochemistry, Photolysis, Cytosine analogs & derivatives, DNA chemistry, Guanine chemistry, Oligonucleotides chemistry

Abstract

A series of naphthalimide (NI)- and 5-bromocytosine ((br)C)-modified oligodeoxynucleotides (ODNs) were prepared, and their lifetimes of the charge-separated states during the photosensitized one-electron oxidation of DNA were measured. Various lifetimes of the charge-separated states were observed depending on the sequence and the incorporation sites of (br)C, and the oxidation potential of G in the (br)C:G base-pair relative to that of G in the C:G base-pair and in the GGG sequence was determined by comparing the lifetimes of the charge-separated states. The change in the cytosine C5 hydrogen to bromine resulted in a 24 mV increase in the oxidation potential of G in the (br)C:G base-pair as compared to that of G in the C:G base-pair, the value of which is comparable to a 58 mV decrease in the oxidation potential of G in the GGG sequence. These results clearly demonstrate that hole transfer in DNA can be controlled through hydrogen bonding by introducing a substituent on the cytosine.

Published

2004

35. Direct observation of hole transfer through double-helical DNA over 100 A.

Author

Takada T, Kawai K, Fujitsuka M, and Majima T

Subjects

Base Sequence, DNA genetics, DNA radiation effects, Electron Transport, Kinetics, Models, Molecular, Naphthalenes chemistry, Nucleic Acid Conformation, Phenothiazines chemistry, Photolysis, Photosensitizing Agents chemistry, Spectrum Analysis, DNA chemistry

Abstract

Mechanism of photo-induced electron transfer and the subsequent hole transfer in DNA has been studied extensively, but so far we are not aware of any reliable report of the observation of the long-distance hole-transfer process. In this article, we demonstrate the results of direct observation for the long-distance hole transfer in double-helical DNA over 100 A with time-resolved transient absorption measurements. DNA conjugated with naphthalimide (NI) and phenothiazine (PTZ) (which worked as electron-acceptor and donor molecules, respectively) at both 5' ends was synthesized to observe the hole-transfer process. Site-selective charge injection into G by means of the adenine-hopping process was accomplished by excitation of NI with a 355-nm laser flash. Transient absorption around 400 nm, which was assigned to the NI radical anion, was observed immediately after the irradiation of a laser flash, indicating that the charge separation between NI and the nearest G occurred. Then, the transient absorption of the PTZ radical cation (PTZ(*+)) at 520 nm was emerged, which was attributed to the hole transfer through DNA to the PTZ site. By monitoring the time profiles of the transient absorption of PTZ(*+) for NI-A(6)-(GA)(n)-PTZ and NI-A(6)-(GT)(n)-PTZ (n = 2, 3, 4, 6, 8, 12) (base sequences correspond to those for DNA modified with NI), the long-distance hole-transfer process from G to PTZ, which occurred in the time scale of microsecond to millisecond, was observed directly. By assuming an average distance of 3.4 A between base-pairs, total distance reaches 100 A for n = 12 sequences. Our results clearly show the direct observation of the long-distance hole transfer over 100 A.

Published

2004

36. Two-color two-laser DNA damaging.

Author

Kawai K, Cai X, Sugimoto A, Tojo S, Fujitsuka M, and Majima T

Subjects

Base Sequence, DNA genetics, Electrons, Guanine chemistry, Imides chemistry, Photochemotherapy, Color, DNA chemistry, DNA radiation effects, DNA Damage radiation effects, Lasers

Published

2004

37. Charge separation in DNA via consecutive adenine hopping.

Author

Takada T, Kawai K, Cai X, Sugimoto A, Fujitsuka M, and Majima T

Subjects

Photolysis, Spectrometry, Fluorescence, Static Electricity, Adenine chemistry, DNA chemistry

Abstract

Charge transfer in DNA is of current interest because of the involvement of charge transfer in oxidative DNA damage and electronic molecular devices. We have investigated the charge separation process via the consecutive adenine (A)-hopping mechanism using laser flash photolysis of DNA conjugated with naphthaldiimide (NDI) as an electron acceptor and phenothiazine (PTZ) as a donor. Upon the 355-nm laser flash excitation of NDI, the charge separation and recombination process between NDI and PTZ was observed. The yields of the charge separation via the consecutive A-hopping were slightly dependent upon the number of A bases between the two chromophores, while the charge recombination rate was strongly dependent upon the distance. The charge-separated state persisted over 300 micros when NDI was separated from PTZ by eight A bases. Furthermore, the rate constant of the A-hopping process was determined to be 2 x 10(10) s(-1) from an analysis of the yield of the charge separation depending on the number of A-hopping steps.

Published

2004

38. Long-lived charge-separated state leading to DNA damage through hole transfer.

Author

Kawai K, Takada T, Nagai T, Cai X, Sugimoto A, Fujitsuka M, and Majima T

Subjects

Chromatography, High Pressure Liquid, DNA drug effects, DNA radiation effects, Imides chemistry, Imides pharmacology, Oligonucleotides chemistry, Oligonucleotides radiation effects, Oxidation-Reduction, Photolysis, Photosensitizing Agents chemistry, Photosensitizing Agents pharmacology, DNA chemistry, DNA Damage

Abstract

The hole transfer causes the long-lived charge-separated state in DNA during the photosensitized one-electron oxidation of DNA. The combination of the transient absorption measurement and DNA damage quantification by HPLC clearly demonstrated that the yield of the DNA damage correlates well with the lifetime of the charge-separated state.

Published

2003