Water-soluble phosphorescent ruthenium complex with a fluorescent coumarin unit for ratiometric sensing of oxygen levels in living cells.

Dual emission was applied to a molecular probe for the ratiometric sensing of oxygen concentration in a living system. We prepared ruthenium complexes possessing a coumarin unit (Ru-Cou), in which the (3)MLCT phosphorescence of the ruthenium complex was efficiently quenched by molecular oxygen, whereas the coumarin unit emitted constant fluorescence independent of the oxygen concentration. The oxygen status could be determined precisely from the ratio of phosphorescence to fluorescence.

Hypoxic X-irradiation as an external stimulus for conformational change of oligodeoxynucleotides that possess disulfide bond and regulation of DNAzyme function.

We achieved a conformational change of oligodeoxynucleotides and the regulation of DNAzyme function by means of a radiolytic strand exchange reaction of disulfide bond. We designed a system in which the DNAzyme function of RNA cleavage was suppressed by the hybridization of an inhibitor strand that possessed disulfide bond with an active DNAzyme. Hypoxic X-irradiation led to the recovery of RNA cleavage because the strand exchange reaction at the disulfide bond in inhibitor strand resulted in a release of inhibitor strand.

Probing DNA mismatched and bulged structures by using 19F NMR spectroscopy and oligodeoxynucleotides with an 19F-labeled nucleobase.

In this study, DNA local structures with bulged bases and mismatched base pairs as well as ordinary full-matched base pairs by using (19)F NMR spectroscopy with (19)F-labeled oligodeoxynucleotides (ODNs) were monitored. The chemical shift change in the (19) F NMR spectra allowed discrimination of the DNA structures. Two types of ODNs possessing the bis(trifluoromethyl)benzene unit (F-unit) at specified uridines were prepared and hybridized with their complementary or noncomplementary strands to form matched, mismatched, or bulged duplexes.

Electron transport through 5-substituted pyrimidines in DNA: electron affinities of uracil and cytosine derivatives differently affect the apparent efficiencies.

We investigated excess electron transport (EET) in DNA containing cytosine derivatives. By arranging the derivatives according to their electron affinities, the apparent EET efficiency was successfully regulated. Unexpectedly, however, providing gradients of electron affinity by inserting 5-fluorocytosine did not always enhance EET.

Enzyme-catalyzed conversion of chemical structures on the surface of gold nanorods.

For developing metal nanoparticles of which surface chemical structures could be altered by enzymes in the cells, functional linkers caged by coumaric acids have been synthesized. Synthesized gold nanorod (GNR) conjugates possessing coumaric acid precursors underwent (porcine liver) esterase-catalyzed hydrolysis on their surface to afford GNRs coated with amino-functionalized polyethylene glycol and fluorescent coumarins as reporter molecules for monitoring the conversion. The chemical structural conversion on the GNR surfaces was successfully observed inside cells by fluorescence microscopy when GNR conjugates were incubated with tumor cells.

Stepwise regulation of hole transport in DNA by control of triplex formation.

A functionality for regulating hole transport efficiency is a prerequisite for the utilization of DNA duplexes as nanodevices. Herein, we report the regulation of hole transport in anthraquinone-tethered DNA with dual triplex forming sites. Long-range photooxidation experiments showed that hole transport was effectively suppressed by the formation of triplex at low temperature, while it was recovered by dissociation to the duplex at higher temperature.

Chemical ligation of oligodeoxynucleotides by X-irradiation and its application to regulation of G-quadruplex formation.

We demonstrated radiolytic ligation of oligodeoxynucleotides (ODNs) possessing disulfide bond and its application to regulation of DNA quadruplex formation. G-rich hexamer ODNs had poor ability to form quadruplex, while X-irradiation of the ODNs induced interstrand exchange reaction at disulfide bond to form ligated 12 mer ODNs, leading to the ready formation of quadruplex due to the entropic effect. Since complexation of the ligated ODNs with hemin in the presence of K(+) showed strong soret band absorption and also catalyzed the H(2)O(2)-mediated oxidation of luminol, it appears that the quadruplex formed from ligated ODNs showed a function similar to native DNA quadruplex.

Ruthenium complexes with hydrophobic ligands that are key factors for the optical imaging of physiological hypoxia.

The phosphorescence emission of ruthenium complexes was applied to the optical imaging of physiological hypoxia. We prepared three complexes with hydrophobic substituents on the phenanthroline ligand and characterized their emission, which was quenched by molecular oxygen. Among the complexes synthesized in this study, a pyrene chromophore-linked ruthenium complex, Ru-Py, exhibited optimal properties for the imaging of hypoxia; the prolonged lifetime of the triplet excited state of the ruthenium chromophore, which was induced by efficient energy distribution and transfer from the pyrene unit, provided the highest sensitivity towards molecular oxygen.

Aggregate formation and radiolytic degradation of amphiphilic DNA block copolymer possessing disulfide bond.

We have designed a novel aggregate of DNA block copolymer (DBC) that is sensitive to hypoxic X-irradiation. The DBC consists of tetrahydropyrane-protected 2-hydroxyethyl methacrylate as a hydrophobic unit and oligodeoxynucleotides as a hydrophilic unit, which are linked to a radiation-sensitive disulfide bond. The DBC self-assembled efficiently to form aggregates that encapsulated small molecules such as nile red and pyrene.

Radiolytic reduction characteristics of drug-encapsulating DNA aggregates possessing disulfide bond.

Radiation-responsive aggregates consisting of artificial DNA were demonstrated. We prepared DNA amphiphiles (DAMs) consisting of oligodeoxynucleotides (ODNs) as the hydrophilic part and an alkyl chain as the hydrophobic part, which were linked by a radiation-sensitive disulfide bond. DAMs assembled to form nanosized aggregates in aqueous solution that encapsulated hydrophobic dyes and drugs.

Synthesis and one-electron reduction characteristics of radiation-activated prodrugs possessing two 5-fluorodeoxyuridine units.

Two molecules of an antitumor agent, 5-fluorodeoxyuridine (5-FdUrd), were connected by a 2-oxoalkyl linker (Oxo-linker) at the N(3) position to obtain radiation-activated prodrugs, FdUrd(2) A and FdUrd(2) B. The prodrugs in this study released 5-FdUrd via one-electron reduction initiated by hypoxic X-irradiation. The release of 5-FdUrd from FdUrd(2) A and FdUrd(2) B proceeded more efficiently than that of previous prodrug, Oxo-FdUrd, which possessed one molecule of 5-FdUrd.

Synthesis and photooxidation of oligodeoxynucleotides containing 5-dimethylaminocytosine as an efficient hole-trapping site in the positive-charge transfer through DNA duplexes.

We have designed and synthesized DNA duplexes containing 5-dimethylaminocytosine ((DMA)C) to investigate the effects of C(5)-substituted cytosine bases on the transfer and trapping of positive charge (holes) in DNA duplexes. Fluorescence quenching experiments revealed that a (DMA)C base is more readily one-electron oxidized into a radical cation intermediate as compared with other natural nucleobases. Upon photoirradiation of the duplexes containing (DMA)C, the photosensitizer-injected hole migrated through the DNA bases and was trapped efficiently at the (DMA)C sites, where an enhanced oxidative strand cleavage occurred by hot piperidine treatment.

Reductive activation of 5-fluorodeoxyuridine prodrug possessing azide methyl group by hypoxic X-irradiation.

We prepared a 5-fluorodeoxyuridine (5-FdUrd) derivative possessing azide methyl group (N(3)-FdUrd) as a novel radiation-activated prodrug. The parent antitumor agent, 5-FdUrd, was released efficiently from N(3)-FdUrd by hypoxic X-irradiation. On the other hand, the activation of N(3)-FdUrd was suppressed upon X-irradiation under aerobic conditions.

Radiolytic reduction characteristics of artificial oligodeoxynucleotides possessing 2-oxoalkyl group or disulfide bonds.

A number of advances have been made in the development of modified oligodeoxynucleotides (ODNs), and chemical or physical properties of which are controlled by external stimuli. These intelligent ODNs are promising for the next generation of gene diagnostics and therapy. This paper focuses on the molecular design of artificial ODNs that are activated by X-irradiation and their applications to regulation of hybridization properties, conformation change, radiation-activated DNAzyme, and decoy molecules.

αvβ3-Integrin-targeting lanthanide complex: synthesis and evaluation as a tumor-homing luminescent probe.

The application of lanthanide complexes in the time-resolved fluorescence imaging of living cells has emerged in the last few decades, providing high-contrast images of cells through detection of the delayed emission. In the present study, we synthesized novel trivalent lanthanide complexes containing the cyclic peptide c(RGDfK) to visualize the α(v)β(3)-integrin-expressing tumor cells. Conjugation of c(RGDfK) with the macrocyclic bipyridine ligand had little effect on the fluorescence properties of the complex, indicating that the coordinated lanthanide ion was well isolated from the peptide.

Anthraquinone-sensitized photooxidation of 5-methylcytosine in DNA leading to piperidine-induced efficient strand cleavage.

One-electron photooxidations of 5-methyl-2'-deoxycytidine (d(m)C) and 5-trideuteriomethyl-2'-deoxycytidine ([D(3)]d(m)C) by sensitization with anthraquinone (AQ) derivatives were investigated. Photoirradiation of an aerated aqueous solution containing d(m)C and anthraquinone 2-sulfonate (AQS) afforded 5-formyl-2'-deoxycytidine (d(f)C) and 5-hydroxymethyl-2'-deoxycytidine (d(hm)C) in good yield through an initial one-electron oxidation process. The deuterium isotope effect on the AQS-sensitized photooxidation of d(m)C suggests that the rate-determining step in the photosensitized oxidation of d(m)C involves internal transfer of the C5-hydrogen atom of a d(m)C-tetroxide intermediate to produce d(f)C and d(hm)C.

(13)C-labeled indolequinone-DTPA-Gd conjugate for NMR probing cytochrome:P450 reductase-mediated one-electron reduction.

We designed and synthesized a new class of (13)C-labeled NMR probe, (13)C-IQ-Gd, to monitor one-electron reductions by cytochrome:P450 (CYP450) reductase under hypoxic conditions. (13)C-IQ-Gd consisted of a Gd(3+)-diethylene triamine pentaacetic acid (DTPA) complex unit and an indolequinone ((13)C-IQ) unit bearing a (13)C-labeled methoxy group. The (13)C NMR signal of (13)C-IQ-Gd was suppressed because of the intramolecular paramagnetic effect of Gd(3+), whereas enzymatic reduction mediated by CYP450 reductase under hypoxic conditions yielded an intensed (13)C NMR signal due to enzymatic activation of the IQ unit followed by release of the DTPA-Gd unit from (13)C-IQ-Gd.

Radiolytic cyclization of stem-and-loop structured oligodeoxynucleotide with neighboring arrangement of α,ω-bis-disulfides.

Upon X-ray irradiation of hypoxic aqueous solution, modified oligodeoxynucleotides (ODNs) bearing a pair of disulfides at both ends of the strand that forms a stem-and-loop structure with a neighboring arrangement of α,ω-bis-disulfides underwent efficient cyclization via an intramolecular exchange reaction at the disulfide moieties with a multiple turnover process. Mechanistic studies revealed that hydrogen atoms generated in the radiolysis of water are key active species initiating a chain reaction to produce cyclic ODN disulfides, in which addition of hydrogen atom results in dissociation of the original disulfide bond to generate a thiyl radical intermediate as the chain carrier for the succeeding disulfide exchange into cyclization. The properties were also assessed for the resultant cyclic ODN disulfide that has several favorable features for use in the transcriptional decoy strategy.

Monitoring of duplex and triplex formation by 19F NMR using oligodeoxynucleotides possessing 5-fluorodeoxyuridine unit as 19F signal transmitter.

We prepared oligodeoxynucleotides (ODNs) possessing a 5-fluorodeoxyuridine (5-FU) unit as a 19F-signal transmitter, and characterized their structures including single strand, duplex, and triplex using 19F NMR. The change in chemical shift induced by incorporation of 5-FU into the ODNs and the formation of higher order structures allowed monitoring of structural changes. Data from UV melting experiments and CD spectra were consistent with the spectral changes in the NMR studies.

Monitoring of biological one-electron reduction by (19)F NMR using hypoxia selective activation of an (19)F-labeled indolequinone derivative.

Biological reduction of fluorine-labeled indolequinone derivative (IQ-F) was characterized by (19)F NMR for quantitative molecular understanding. The chemical shift change in (19)F NMR allowed monitoring of the enzymatic reduction of IQ-F. Upon hypoxic treatment of IQ-F with NADPH:cytochrome P450 reductase, IQ-F was activated via catalytic one-electron reduction to release nonafluoro-tert-butyl alcohol (F-OH), while the formation of F-OH was significantly suppressed under aerobic conditions.

Efficient photooxidative strand cleavage at 5-methylcytosine in DNA by sensitization with 9,10-anthraquinone-tethered oligonucleotides.

Photoirradiation and subsequent hot piperidine treatment of the duplex consisting of 5-methylcytosine ((m)C)-containing DNA and 9,10-anthraquinone (AQ)-tethered complementary oligodeoxynucleotide led to selective oxidative strand cleavage at the target (m)C site, whereas no strand cleavage was observed for the duplex containing normal cytosine instead of (m)C. Incorporation of an AQ sensitizer into the interior of a strand induced an enhanced one-electron photooxidation, presumably because of a much larger intersystem crossing efficiency, leading to an efficient strand cleavage at the target (m)C site in DNA. Optimization of the photosensitizer could afford more strand cleavage at (m)C in DNA, thereby allowing for the more sensitive detection of the target (m)C on a sequencing gel.

Photoelectrochemical identification of 5-methylcytosine modification in DNA: combination of photosensitization and enzymatic cleavage.

We present a novel photoelectrochemical approach for discriminating between cytosine and 5-methylcytosine in DNA when used in combination with enzymatic digestion. A photosensitizer-linked DNA duplex bearing 5-methylcytosine or cytosine at a given restriction site of the strand was immobilized on a gold electrode and digested with enzyme, and the photocurrent response was measured. We observed high photocurrent density that was selective for the methylated duplex.

Photoinduced electron transfer reaction in diaminostilbene-tethered DNA duplexes.

DNA duplexes containing diaminostilbene (DAS) as a photoinduced electron donor were synthesized to investigate mechanisms of electron injection into DNA and the succeeding electron transfer in the duplexes. DAS-Capped hairpin DNA showed a high structural stability thereby attains large interaction between DAS and the terminal base pair. DAS-Tethered DNA by a single linker at the end of the duplex was also synthesized and the yields of photoinduced electron transfer through mismatched base pairs were quantified.

Radiolytic one-electron reductive cyclization of oligodeoxynucleotides possessing a disulfide bond.

Radiolytic one-electron reduction of oligodeoxynucleotides (ODNs) possessing a disulfide bond induced strand exchange reaction in a hypoxia selective manner. In this study, we attempted to apply this radiolytic reaction to stem-and-loop structured ODNs. Hypoxic X-irradiation to an aqueous solution of stem-and-loop structured ODNs produced a cyclized DNA in good yield via an intrastrand ligation reaction.