Your search keyword '"England W"' showing total 3 results

1. Exploiting Endogenous Enzymes for Cancer-Cell Selective Metabolic Labeling of RNA in Vivo.

Author

Beasley S, Vandewalle A, Singha M, Nguyen K, England W, Tarapore E, Dai N, Corrêa IR Jr, Atwood SX, and Spitale RC

Subjects

Nucleosides metabolism, Neoplasms, RNA metabolism

Abstract

Tissues and organs are composed of many diverse cell types, making cell-specific gene expression profiling a major challenge. Herein we report that endogenous enzymes, unique to a cell of interest, can be utilized to enable cell-specific metabolic labeling of RNA. We demonstrate that appropriately designed "caged" nucleosides can be rendered active by serving as a substrate for cancer-cell specific enzymes to enable RNA metabolic labeling, only in cancer cells. We envision that the ease and high stringency of our approach will enable expression analysis of tumor cells in complex environments.

Published

2022

2. Expanding the Scope of RNA Metabolic Labeling with Vinyl Nucleosides and Inverse Electron-Demand Diels-Alder Chemistry.

Author

Kubota M, Nainar S, Parker SM, England W, Furche F, and Spitale RC

Subjects

Cycloaddition Reaction, HEK293 Cells, Heterocyclic Compounds, 1-Ring chemistry, Humans, Kinetics, Microscopy, Confocal methods, Microscopy, Fluorescence methods, Nucleosides chemical synthesis, Quantum Theory, RNA chemistry, Vinyl Compounds chemical synthesis, Nucleosides metabolism, RNA metabolism, Vinyl Compounds metabolism

Abstract

Optimized and stringent chemical methods to profile nascent RNA expression are still in demand. Herein, we expand the toolkit for metabolic labeling of RNA through application of inverse electron demand Diels-Alder (IEDDA) chemistry. Structural examination of metabolic enzymes guided the design and synthesis of vinyl-modified nucleosides, which we systematically tested for their ability to be installed through cellular machinery. Further, we tested these nucleosides against a panel of tetrazines to identify those which are able to react with a terminal alkene, but are stable enough for selective conjugation. The selected pairings then facilitated RNA functionalization with biotin and fluorophores. We found that this chemistry not only is amenable to preserving RNA integrity but also endows the ability to both tag and image RNA in cells. These key findings represent a significant advancement in methods to profile the nascent transcriptome using chemical approaches.

Published

2019

3. Assaying RNA structure with LASER-Seq.

Author

Zinshteyn B, Chan D, England W, Feng C, Green R, and Spitale RC

Subjects

Adenosine chemistry, Binding Sites genetics, Guanosine chemistry, Ligands, Multiprotein Complexes genetics, Mutation, RNA chemistry, Ribosomes chemistry, Ribosomes genetics, Solvents chemistry, High-Throughput Nucleotide Sequencing, Multiprotein Complexes chemistry, Nucleic Acid Conformation, RNA genetics

Abstract

Chemical probing methods are crucial to our understanding of the structure and function of RNA molecules. The majority of chemical methods used to probe RNA structure report on Watson-Crick pairing, but tertiary structure parameters such as solvent accessibility can provide an additional layer of structural information, particularly in RNA-protein complexes. Herein we report the development of Light Activated Structural Examination of RNA by high-throughput sequencing, or LASER-Seq, for measuring RNA structure in cells with deep sequencing. LASER relies on a light-generated nicotinoyl nitrenium ion to form covalent adducts with the C8 position of adenosine and guanosine. Reactivity is governed by the accessibility of C8 to the light-generated probe. We compare structure probing by RT-stop and mutational profiling (MaP), demonstrating that LASER can be integrated with both platforms for RNA structure analyses. We find that LASER reactivity correlates with solvent accessibility across the entire ribosome, and that LASER can be used to rapidly survey for ligand binding sites in an unbiased fashion. LASER has a particular advantage in this last application, as it readily modifies paired nucleotides, enabling the identification of binding sites and conformational changes in highly structured RNA.

Published

2019