Synthesis of oligonucleotides containing a new azobenzene fragment with efficient photoisomerizability

Synthesis, derivatization and photochemical control of an ortho-functionalized tetrafluorinated azoben---zene-modified siRNA

We report the synthesis of an ortho -functionalized tetrafluorinated azobenzene phosphoramidite for its site-specific incorporation into RNA. The tetrafluorinated azobenzene is embedded within the antisense strand of an siRNA duplex to form an ortho -functionalized tetrafluorinated azobenzene-containing siRNA (F-siRNAzo). The F-siRNAzo is inactivated via trans to cis conversion with green light (530 nm), and reactivated with blue light (470 nm) via cis to trans conversion in cell culture. The long half-life and stability of the tetrafluorinated azobenzene unit allows for reversible control of the F-siRNAzo in cell culture for up 72 hours.

Photoresponsive DNA materials and their applications

Photoresponsive nucleic acids attract growing interest as functional constituents in materials science. Integration of photoisomerizable units into DNA strands provides an ideal handle for the reversible reconfiguration of nucleic acid architectures by light irradiation, triggering changes in the chemical and structural properties of the nanostructures that can be exploited in the development of photoresponsive functional devices such as machines, origami structures and ion channels, as well as environmentally adaptable 'smart' materials including nanoparticle aggregates and hydrogels. Moreover, photoresponsive DNA components allow control over the composition of dynamic supramolecular ensembles that mimic native networks. Beyond this, the modification of nucleic acids with photosensitizer functionality enables these biopolymers to act as scaffolds for spatial organization of electron transfer reactions mimicking natural photosynthesis. This review provides a comprehensive overview of these exciting developments in the design of photoresponsive DNA materials, and showcases a range of applications in catalysis, sensing and drug delivery/release. The key challenges facing the development of the field in the coming years are addressed, and exciting emergent research directions are identified.

Photoinduced deformation of amorphous polyimide enabled by an improved azobenzene isomerization efficiency

A newly designed azo-PI, without pre-stretching or polarized-light irradiation, exhibits reversible bending behaviors under alternate UV and visible light irradiation, providing a facile route to deformable 2D/3D structure actuators.

Synthesis, Derivatization and Photochemical Control of ortho-Functionalized Tetrachlorinated Azobenzene-Modified siRNAs

We report the chemical synthesis and derivatization of an ortho-functionalized tetrachlorinated azobenzene diol. A 4',4-dimethoxytrityl (DMT) phosphoramidite was synthesized for its site-specific incorporation within the sense strand of an siRNA duplex to form ortho-functionalized tetrachlorinated azobenzene-containing siRNAs (Cl-siRNAzos). Compared to a non-halogenated azobenzene, ortho-functionalized tetrachlorinated azobenzenes are capable of red-shifting the π→π* transition from the ultraviolet (UV) portion of the electromagnetic spectrum into the visible range. Within this visible range, the azobenzene molecule can be reliably converted from trans to cis with red light (660 nm), and converted back to trans with violet wavelength light (410 nm) and/or thermal relaxation. We also report the gene-silencing ability of these Cl-siRNAzos in cell culture as well as their reversible control with visible light for up to 24 hours.

Reversible control of RNA interference by siRNAzos

In this study, we report the reversible control of RNA interference using siRNAzos, a class of siRNAs that contain azobenzene.

Photoswitching of DNA Hybridization Using a Molecular Motor

Reversible control over the functionality of biological systems via external triggers may be used in future medicine to reduce the need for invasive procedures. Additionally, externally regulated biomacromolecules are now considered as particularly attractive tools in nanoscience and the design of smart materials, due to their highly programmable nature and complex functionality. Incorporation of photoswitches into biomolecules, such as peptides, antibiotics, and nucleic acids, has generated exciting results in the past few years. Molecular motors offer the potential for new and more precise methods of photoregulation, due to their multistate switching cycle, unidirectionality of rotation, and helicity inversion during the rotational steps. Aided by computational studies, we designed and synthesized a photoswitchable DNA hairpin, in which a molecular motor serves as the bridgehead unit. After it was determined that motor function was not affected by the rigid arms of the linker, solid-phase synthesis was employed to incorporate the motor into an 8-base-pair self-complementary DNA strand. With the photoswitchable bridgehead in place, hairpin formation was unimpaired, while the motor part of this advanced biohybrid system retains excellent photochemical properties. Rotation of the motor generates large changes in structure, and as a consequence the duplex stability of the oligonucleotide could be regulated by UV light irradiation. Additionally, Molecular Dynamics computations were employed to rationalize the observed behavior of the motor–DNA hybrid. The results presented herein establish molecular motors as powerful multistate switches for application in biological environments.

Photoswitching properties of hairpin ODNs with azobenzene derivatives at the loop position

Photoisomerization of an azobenzene moiety modulates the thermodynamic stability of hairpin ODNs by interfering with stacking interation between azobenzene and neighbouring base pair and dihedral angle of the neighbouring base pair.

Photomodulation of PS-modified oligonucleotides containing azobenzene substituent at pre-selected positions in phosphate backbone

A new protocol has been developed for incorporation of a photoisomerizable azobenzene moiety into synthetic stereo-enriched [R(p)] and [S(p)] PS-oligonucleotides. The azobenzene pendant is attached at pre-selected positions in internucleotidic phosphorothioate oligonucleotides of both [R(p)] and [S(p)] diastereomers using a novel reagent, N-iodoacetyl-p-aminoazobenzene, 1. The modified oligomers are purified on HPLC, characterized by LC-MS, and examined for their thermal and photoisomerization properties. The azobenzene moiety imparts greater stability to oligomer duplexes in (E) NN configuration as compared to (Z) configuration. The placement of the azobenzene pendant close to 5'-terminus (n-1) and 3'-terminus of the modified PS-oligos contributes maximum stability to the duplex while a gradual decline in stability occurs with azobenzene moving toward middle of the duplex. Circular Dichroism studies reveal that the chiral environment at the phosphorus center of the PS-oligos does not alter the global conformation of the DNA duplex as such, suggesting conservation of conformation of the modified DNA strands.

Conformational changes of DNA by photoirradiation of DNA-bis(Zn(II)-cyclen)-azobenzene complex

Bis(Zn(II)-cyclen)-azobenzene derivative, which has two Zn(II)-macrocyclic tetraamine complexes connected through azobenzene spacer, has been synthesized as a cross-linking agent fordoublestranded DNA in aqueous solution. The Zn(II)-cyclen derivative selectively binds to A-T base pairs producing complexes between the Zn(II)-cyclen moiety and the imide-deprotonated thymine with breaking A-T base pairs. The azobenzene spacer undergoes cis/trans photoisomerization in the complex between the Zn(II)-cyclen derivative and the DNA duplex. The conformation of the DNA remarkably changed by photoisomerization of the azobenzene linker, when the Zn(II)-cyclen derivative binds to the DNA duplex with an interstrand cross-linking manner

Synthesis of photoswitchable amino acids based on azobenzene chromophores: building blocks with potential for photoresponsive biomaterials

Three novel derivatives of azobenzene substituted amino acids have been synthesized. The compounds may serve as photoswitchable building blocks in the synthesis of bicyclic peptides or peptide strands interconnected with a photoisomerizable group.

Azo cyclization: peptide cyclization via azo bridge formation

A novel method for peptide cyclization in solution: the azo cyclization is presented herein. Ring closure by forming an azo bridge was achieved in situ by connecting the corresponding side chains of para amino phenylalanine (Pap) residues to those of tyrosine or histidine residues present in the corresponding linear precursors. The reaction was performed using an initial diazotization step in acidic media followed by intramolecular azo cyclization in a mild basic media. This new method of cyclization is facile, applicable to various sequences and results in a high yield of pure products and hence is suggested as an additional method for peptide cyclization. Here we report the successful utilization of this method for the synthesis of 10 new cyclic azo peptides, derived from RGD, GnRH, Tuftsin, VIP and SV40 NLS.