Development of Visible-Light-Responsive RNA Scissors Based on a 10-23 DNAzyme.

The 10-23 DNAzyme is an artificially developed functional oligonucleotide that can cleave RNA in a sequence-specific manner. In this study, we designed a new photo-driven DNAzyme incorporating a photoresponsive DNA overhang complementary to the catalytic core region. The photoresponsive overhang region of the DNAzyme included either azobenzene components (Azos) or 2,6-dimethyl-4-(methylthio)azobenzene units (SDM-Azos) each attached to a d-threoninol linker. When the Azos or SDM-Azos were in the trans form, the photoresponsive DNA overhang hybridized with the DNAzyme, and the RNA cleavage activity was suppressed. cis Isomerization of Azos or SDM-Azos, induced by 365 or 400 nm light, respectively, destabilized the duplex between the photoresponsive overhang and the catalytic core, and the DNAzyme recovered RNA cleavage activity. Reversible photoswitching of the DNAzyme activity was achieved by use of specific light irradiation. Further, light-dependent photoswitching of protein expression in the presence of the DNAzyme was demonstrated. Thus, this photo-driven DNAzyme has potential for application as a photocontrolled gene silencing system and a photoactivatable gene expression system.

Dynamics of Inter-DNA Chain Interaction of Photoresponsive DNA.

Photoresponsive DNA modified with azobenzene is an attractive design molecule for efficient photoregulation of DNA hybridization, which may be used for controlling DNA functions. Although the essential step of photocontrolling DNA is the initial isomerization of the azobenzene, the dissociation/association kinetics remain unknown. Here, the time-resolved diffusion method was used to trace the dissociation/association processes of photoresponsive DNA. Although the isomerization of azobenzene occurs in picoseconds, the dissociation of the double-stranded DNA to single-stranded DNA triggered by the trans to cis isomerization takes place ∼10(7) times slower, with a time constant of 670 µs at 200 µM. From the concentration dependence, the dissociation and association rates were determined. Furthermore, the reaction rate from the single- to double-stranded DNA after the cis to trans isomerization was measured to be 3.6 ms at 200 µM. The difference in the melting temperatures of DNA between tethered trans- and cis-azobenzene is explained by the different rate of dissociation of the double-stranded form.

Synthetic gene involving azobenzene-tethered T7 promoter for the photocontrol of gene expression by visible light.

In the present study, we demonstrate photoregulation of gene expression in a cell-free translation system from a T7 promoter containing two azobenzene derivatives at specific positions. As photoswitches, we prepared azobenzene-4'-carboxlyic acid (Azo) and 2,6-dimethylazobenzene-4'-carboxylic acid (DM-Azo), which were isomerized from trans to cis upon irradiation with UV light (λ < 370 nm), and 4-methylthioazobenzene-4'-carboxylic acid (S-Azo) and 2,6-dimethyl-4-(methylthio)azobenzene-4'-carobxylic acid (S-DM-Azo), which were cis-isomerized by irradiation with 400 nm visible light. Expression of green fluorescent protein from a promoter modified with S-Azo or S-DM-Azo could be induced by harmless visible light whereas that from a promoter modified with Azo or DM-Azo was induced only by UV light (340-360 nm). Thus, efficient photoregulation of green fluorescent protein production was achieved in a cell-free translation system with visible light without photodamage.