Fluorescent Platforms for RNA Chemical Biology Research.

Efficient detection and observation of dynamic RNA changes remain a tremendous challenge. However, the continuous development of fluorescence applications in recent years enhances the efficacy of RNA imaging. Here we summarize some of these developments from different aspects. For example, single-molecule fluorescence in situ hybridization (smFISH) can detect low abundance RNA at the subcellular level. A relatively new aptamer, Mango, is widely applied to label and track RNA activities in living cells. Molecular beacons (MBs) are valid for quantifying both endogenous and exogenous mRNA and microRNA (miRNA). Covalent binding enzyme labeling fluorescent group with RNA of interest (ROI) partially overcomes the RNA length limitation associated with oligonucleotide synthesis. Forced intercalation (FIT) probes are resistant to nuclease degradation upon binding to target RNA and are used to visualize mRNA and messenger ribonucleoprotein (mRNP) activities. We also summarize the importance of some fluorescence spectroscopic techniques in exploring the function and movement of RNA. Single-molecule fluorescence resonance energy transfer (smFRET) has been employed to investigate the dynamic changes of biomolecules by covalently linking biotin to RNA, and a focus on dye selection increases FRET efficiency. Furthermore, the applications of fluorescence assays in drug discovery and drug delivery have been discussed. Fluorescence imaging can also combine with RNA nanotechnology to target tumors. The invention of novel antibacterial drugs targeting non-coding RNAs (ncRNAs) is also possible with steady-state fluorescence-monitored ligand-binding assay and the T-box riboswitch fluorescence anisotropy assay. More recently, COVID-19 tests using fluorescent clustered regularly interspaced short palindromic repeat (CRISPR) technology have been demonstrated to be efficient and clinically useful. In summary, fluorescence assays have significant applications in both fundamental and clinical research and will facilitate the process of RNA-targeted new drug discovery, therefore deserving further development and updating.

Fluorescence-Based Binding Characterization of Small Molecule Ligands Targeting CUG RNA Repeats.

Pathogenic CUG and CCUG RNA repeats have been associated with myotonic dystrophy type 1 and 2 (DM1 and DM2), respectively. Identifying small molecules that can bind these RNA repeats is of great significance to develop potential therapeutics to treat these neurodegenerative diseases. Some studies have shown that aminoglycosides and their derivatives could work as potential lead compounds targeting these RNA repeats. In this work, sisomicin, previously known to bind HIV-1 TAR, is investigated as a possible ligand for CUG RNA repeats. We designed a novel fluorescence-labeled RNA sequence of r(CUG)10 to mimic cellular RNA repeats and improve the detecting sensitivity. The interaction of sisomicin with CUG RNA repeats is characterized by the change of fluorescent signal, which is initially minimized by covalently incorporating the fluorescein into the RNA bases and later increased upon ligand binding. The results show that sisomicin can bind and stabilize the folded RNA structure. We demonstrate that this new fluorescence-based binding characterization assay is consistent with the classic UV Tm technique, indicating its feasibility for high-throughput screening of ligand-RNA binding interactions and wide applications to measure the thermodynamic parameters in addition to binding constants and kinetics when probing such interactions.

Synthesis of 6-Aza-2-Hydroxyimino-5-Methylpyrimidine Nucleosides for Antiviral Evaluation.

The syntheses of a series of novel 6-aza-2-hydroxyimino-5-methylpyrimidine and related nucleosides are described. A suitably protected 2-methylthiopyrimidine nucleoside was selected as the precursor for installing a hydroxyimino moiety at the C-2 position. The starting nucleobase 6-aza-5-methyl-2-thiouracil is prepared in two steps from thiosemicarbazone and ethyl pyruvate. This is subjected to coupling with 1-O-acetyl-2,3,5-tri-O-benzoyl-ß-D-ribofuranose under Vorbrüggen glycosylation conditions to provide the corresponding nucleoside in high yield. Activation of the nucleoside to the corresponding 2-methylthio derivative followed by treatment with hydroxylamine hydrochloride in pyridine provides the corresponding 2-hydroxyimino derivative in high yield. Finally, the synthesis of five free modified nucleoside analogs is described. The newly synthesized nucleosides have been evaluated against an RNA viral panel and moderate activity was observed against hepatitis C virus, Zika virus, and human respiratory syncytial virus. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Preparation of 6-aza-5-methyl-2-thiouracil Basic Protocol 2: Preparation of 6-aza-5-methyl-2-thiouridine and 6-aza-5-methyluridine Basic Protocol 3: Preparation of 6-aza-2-hydroxyimino-5-methyluridine Basic Protocol 4: Preparation of 6-aza-2-hydroxyimino-5-methyl-4-thiouridine and 6-aza-2-hydroxyimino-5-methylcytosine.

Synthesis and Purification of N3 -Methylcytidine (m3 C) Modified RNA Oligonucleotides.

This protocol describes a step-by-step chemical synthesis approach to prepare N3 -methylcytidine (m3 C) and its phosphoramidite. The method for synthesizing m3 C starts from commercially available cytidine, and proceeds via N3 -methylation in the presence of MeI, which generates the N3 -methylcytidine (m3 C) nucleoside, followed by the installation of several protecting groups at sites that include the 5'-hydroxyl group (4,4'-dimethoxytrityl protection), the 4-amino group (benzoyl protection), and the 2'-hydroxyl group (tert-butyldimethylsilyl, TBDMS, protection). Standard phosphoramidite chemistry is applied to prepare the final m3 C phosphoramidite for solid-phase synthesis of a series of RNA oligonucleotides. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Synthesis of N3 -methylcytidine (m3 C) and its phosphoramidite Basic Protocol 2: Automated synthesis of m3 C modified RNA oligonucleotides.