Enzymatic synthesis of RNA standards for mapping and quantifying RNA modifications in sequencing analysis

Concise Affinity-Based Purification of Ligated mRNA for Structure-Activity Relationship Studies of Nucleosugar Modification Patterns

Position-specific nucleoside sugar modifications have been shown to improve the translational activity and stability of chemically synthesized mRNA. For pharmaceutical applications of chemically modified mRNAs, a rapid purification methodology is imperative to identify the optimal modification pattern. However, while the chemical synthesis of mRNAs can be accomplished by splint ligation of oligonucleotide fragments, the current purification method for ligated mRNAs based on denaturing polyacrylamide gel electrophoresis tends to be time consuming. In this study, we developed a two-step affinity purification method for rapid sample preparation. In this method, ligated mRNA is captured by oligo dT magnetic beads and streptavidin magnetic beads with 3'-biotinylated oligo DNA, which are complementary to the 3'-poly(A) and 5' terminal sequences of the target mRNA, respectively. Therefore, the target mRNA can be isolated from a complex mixture of splint ligations. Using this method, six sugar-modified mRNAs were simultaneously purified, and the translational activities of these mRNAs were evaluated immediately after purification. The results demonstrate that this methodology is suitable for the rapid preparation of various chemically synthesized mRNAs to identify their optimal modification patterns.

Advantages and challenges associated with bisulfite-assisted nanopore direct RNA sequencing for modifications

Nanopore direct RNA sequencing is a technology that allows sequencing for epitranscriptomic modifications with the possibility of a quantitative assessment. In the present work, pseudouridine (Ψ) was sequenced with the nanopore before and after the pH 7 bisulfite reaction that yields stable ribose adducts at C1' of Ψ. The adducted sites produced greater base call errors in the form of deletion signatures compared to Ψ. Sequencing studies on E. coli rRNA and tmRNA before and after the pH 7 bisulfite reaction demonstrated that using chemically-assisted nanopore sequencing has distinct advantages for minimization of false positives and false negatives in the data. The rRNA from E. coli has 19 known U/C sequence variations that give similar base call signatures as Ψ, and therefore, are false positives when inspecting base call data; however, these sites are refractory to reacting with bisulfite as is easily observed in nanopore data. The E. coli tmRNA has a low occupancy Ψ in a pyrimidine-rich sequence context that is called a U representing a false negative; partial occupancy by Ψ is revealed after the bisulfite reaction. In a final study, 5-methylcytidine (m5C) in RNA can readily be observed after the pH 5 bisulfite reaction in which the parent C deaminates to U and the modified site does not react. This locates m5C when using bisulfite-assisted nanopore direct RNA sequencing, which is otherwise challenging to observe. The advantages and challenges of the overall approach are discussed.