Selective Methylation of Nucleosides via an In Situ Generated Methyl Oxonium.

A very mild and efficient procedure has been developed for the preparation of N-methylated uridine, pseudouridine, guanosine and inosine derivatives. This process was compatible with free hydroxyls within the ribose and did not require precautions on the protection or deprotection of other functionalities. The key to this extremely mild methylation without protection relied on the in situ generated methyl oxonium from the Wittig reagent and methanol. A putative mechanism for the selective methylation was also proposed.

Photo-Facilitated Detection and Sequencing of 5-Formylcytidine RNA.

5-Formylcytidine (f5 C) is one of the epigenetic nucleotides in tRNA. Despite the evident importance of f5 C in gene expression regulation, little is known about its exact amount and position. To capture this information, we developed a modification-specific functionalization with a semi-stabilized ylide. The chemical labelling exhibited a high selectivity towards f5 C and allowed distinction from similar 5-formyluridine. We realized a detection strategy based on the fluorescence signal of the cyclization product 4,5-pyridin-2-amine-cytidine paC, which exhibited a high quantum yield. The results clearly identified f5 C with a limit of detection at 0.58 nM. This method altered the hydrogen bonding activities of f5 C and modulated its reverse transcription signature in its sequencing profile. We showed that f5 C can be detected from tRNA segments with a single-base resolution. Taken together, this approach is a sensitive, antibody-free, and applicable detection and sequencing method for f5 C-containing RNA.

A Light-Controllable Chemical Modulation of m6 A RNA Methylation.

Bioactive small molecules with photo-removable protecting groups have provided spatial and temporal control of corresponding biological effects. We present the design, synthesis, computational and experimental evaluation of the first photo-activatable small-molecule methyltransferase agonist. By blocking the functional N-H group on MPCH with a photo-removable ortho-nitrobenzyl moiety, we have developed a promising photo-caged compound that had completely concealed its biological activity. Short UV light exposure of cells treated with that caged molecule in a few minutes resulted in a considerable hypermethylation of m6 A modification in transcriptome RNAs, implicating a rapid release of the parent active compound. This study validates for the first time the photo-activatable small organic molecular concept in the field of RNA epigenetic research, which represents a novel tool in spatiotemporal and cellular modulation approaches.

A NaI/H2O2-Mediated Sulfenylation and Selenylation of Unprotected Uracil and Its Derivatives.

An efficient iodide-catalyzed/hydrogen peroxide mediated sulfenylation and selenylation of unprotected uracil and its derivatives with simple thiols and diselenides was established. This coupling tolerates a broad variety of functional groups to provide diverse 5-sulfur/selenium-substituted uracil derivatives in good to excellent yields (up to 93%).

Iodide/H2O2 Catalyzed Intramolecular Oxidative Amination for the Synthesis of 3,2'-Pyrrolidinyl Spirooxindoles.

An ammonium iodide/hydrogen peroxide-mediated intramolecular oxidative amination of 3-aminoalkyl-2-oxindoles was achieved, affording the corresponding 3,2'-pyrrolidinyl spirooxindoles and their 6- or 7-membered analogous in moderate to high yields. This metal-free procedure features very mild reaction conditions, non-toxicity and easily handled hydrogen peroxide as a clean oxidant.

Ruthenium-Catalyzed Decarboxylative C-H Alkenylation in Aqueous Media: Synthesis of Tetrahydropyridoindoles.

We disclose herein a Ru(II)-catalyzed decarboxylative and oxidative coupling of N-substituted indolyl carboxylic acids with broad substrate scope in an aqueous solution. This method provides a sustainable and efficient access to synthesize various indole-fused cyclohexanyl acetic acids under mild conditions.