Chemo-Enzymatic Synthesis of Position-Specifically Modified RNA for Biophysical Studies including Light Control and NMR Spectroscopy.

The investigation of non-coding RNAs requires RNAs containing modifications at every possible position within the oligonucleotide. Here, we present the chemo-enzymatic RNA synthesis containing photoactivatable or 13 C,15 N-labelled nucleosides. All four ribonucleotides containing ortho-nitrophenylethyl (NPE) photocages, photoswitchable azobenzene C-nucleotides and 13 C,15 N-labelled nucleotides were incorporated position-specifically in high yields. We applied this approach for the synthesis of light-inducible 2'dG-sensing riboswitch variants and detected ligand-induced structural reorganization upon irradiation by NMR spectroscopy. This chemo-enzymatic method opens the possibility to incorporate a wide range of modifications at any desired position of RNAs of any lengths beyond the limits of solid-phase synthesis.

Light Regulation of DNA Minicircle Dimerization by Utilizing Azobenzene C-Nucleosides.

Although DNA has the ability to form almost every desired shape, the usability of DNA nanostructures can be limited due to the lack of functionality. To functionalize nanoscale structures, light-responsive moieties like photoswitchable azobenzenes can be introduced into DNA. Upon UV irradiation, the isomerization of the azobenzene moiety causes destabilization of the neighboring base pairs leading to decreased binding ability. The linker strategy of the azobenzene to the DNA alters the performance of the switching behavior significantly. We hereby report the utilization of four different azobenzene C-nucleosides and compare their features in a nanoarchitecture model with the help of gel-electrophoresis and atomic force microscope-imaging.

Azobenzene C-Nucleosides for Photocontrolled Hybridization of DNA at Room Temperature.

Herein, we report the reversible light-regulated destabilization of DNA duplexes by using azobenzene C-nucleoside photoswitches. The incorporation of two different azobenzene residues into DNA and their photoswitching properties are described. These new residues demonstrate a photoinduced destabilization effect comparable to the widely applied D-threoninol-linked azobenzene switch, which is currently the benchmark. The photoswitches presented herein show excellent photoswitching efficiencies in DNA duplexes - even at room temperature - which are superior to commonly used azobenzene-based nucleic acid photoswitches. In addition, these photoswitching residues exhibit high thermal stability and excellent fatigue resistance, thus rendering them one of the most efficient candidates for the regulation of duplex stability with light.

In Search of an Efficient Photoswitch for Functional RNA: Design Principles from a Microscopic Analysis of Azobenzene-linker-RNA Dynamics with Different Linkers.

The design of optimal photoswitches to regulate nucleic acid functionality is a considerable challenge. Azobenzene switches that are covalently bound to the nucleic acid backbone are a paradigm example that has been studied using different types of linker species connecting the chromophore to the backbone. To support experimental efforts to construct optimal azobenzene-linker-RNA combinations, we introduce here a systematic approach for theoretical analysis, which provides criteria for the local embedding of the chromophore via a chosen linker. Using a local reference frame adapted to the chromophore, quantitative measures are provided for (i) the propensity of stacking in competition with a drift toward the minor or major groove, (ii) the tendency to disrupt the native hydrogen bond network, (iii) the structural flexibility of the chromophore-linker combination, and (iv) the correlations with the presence of a base in the opposite strand. Large differences in structural stability between the trans and cis forms of the azobenzene chromophore, according to these criteria, indicate good functionality and lead to significant differences in melting temperatures. In particular, a recently synthesized deoxyribose linker proves optimal within the set of azobenzene-linker-RNA combinations considered.

Reversible photoswitching of RNA hybridization at room temperature with an azobenzene C-nucleoside.

Photoregulation of RNA remains a challenging task as the introduction of a photoswitch entails changes in the shape and the stability of the duplex that strongly depend on the chosen linker strategy. Herein, the influence of a novel nucleosidic linker moiety on the photoregulation efficiency of azobenzene is investigated. To this purpose, two azobenzene C-nucleosides were stereoselectively synthesized, characterized, and incorporated into RNA oligonucleotides. Spectroscopic characterization revealed a reversible and fast switching process, even at 20 °C, and a high thermal stability of the respective cis isomers. The photoregulation efficiency of RNA duplexes upon trans-to-cis isomerization was investigated by using melting point studies and compared with the known D-threoninol-based azobenzene system, revealing a photoswitching amplitude of the new residues exceeding 90 % even at room temperature. Structural changes in the duplexes upon photoisomerization were investigated by using MM/MD calculations. The excellent photoswitching performance at room temperature and the high thermal stability make these new azobenzene residues promising candidates for in-vivo and nanoarchitecture photoregulation applications of RNA.