Eukaryotic mRNA with its 5′-cap is of central importance for the cell. Many studies involving mRNA require reliable preparation and modification of 5′-capped RNAs. Depending on the length of the desired capped RNA, chemical or enzymatic preparation – or a combination of both – can be advantageous. We review state-of-the art methods and give directions for choosing the appropriate approach. We also discuss the preparation and properties of mRNAs with non-natural caps providing novel features such as improved stability or enhanced translational efficiency.
Methyltransferases have proven useful to install functional groups site-specifically in different classes of biomolecules when analogues of their cosubstrate S-adenosyl-l-methionine (AdoMet) are available. Methyltransferases have been used to address different classes of RNA molecules selectively and site-specifically, which is indispensable for biophysical and mechanistic studies as well as labeling in the complex cellular environment. However, the AdoMet analogues are not cell-permeable, thus preventing implementation of this strategy in cells. We present a two-step enzymatic cascade for site-specific mRNA modification starting from stable methionine analogues. Our approach combines the enzymatic synthesis of AdoMet with modification of the 5' cap by a specific RNA methyltransferase in one pot. We demonstrate that a substrate panel including alkene, alkyne, and azido functionalities can be used and further derivatized in different types of click reactions.
Selective modification of nucleobases with photolabile caging groups enables the study and control of processes and interactions of nucleic acids. Numerous positions on nucleobases have been targeted, but all involve formal substitution of a hydrogen atom with a photocaging group. Nature, however, also uses ring‐nitrogen methylation, such as m7G and m1A, to change the electronic structure and properties of RNA and control biomolecular interactions essential for translation and turnover. We report that aryl ketones such as benzophenone and α‐hydroxyalkyl ketone are photolabile caging groups if installed at the N7 position of guanosine or the N1 position of adenosine. Common photocaging groups derived from the ortho‐nitrobenzyl moiety were not suitable. Both chemical and enzymatic methods for site‐specific modification of N7G in nucleosides, dinucleotides, and RNA were developed, thereby opening the door to studying the molecular interactions of m7G and m1A with spatiotemporal control.
Elucidation of biomolecular interactions is of utmost importance in biochemistry. Photo-cross-linking offers the possibility to precisely determine RNA-protein interactions. However, despite the inherent specificity of enzymes, approaches for site-specific introduction of photo-cross-linking moieties into nucleic acids are scarce. Methyltransferases in combination with synthetic analogues of their natural cosubstrate S-adenosyl-l-methionine (AdoMet) allow for the post-synthetic site-specific modification of biomolecules. We report on three novel AdoMet analogues bearing the most widespread photo-cross-linking moieties (aryl azide, diazirine, and benzophenone). We show that these photo-cross-linkers can be enzymatically transferred to the methyltransferase target, that is, the mRNA cap, with high efficiency. Photo-cross-linking of the resulting modified mRNAs with the cap interacting protein eIF4E was successful with aryl azide and diazirine but not benzophenone, reflecting the affinity of the modified 5' caps.
The ability to detect and localize defined RNA strands inside living cells requires probes with high specificity, sensitivity, and signal-to-background ratio. To track low-abundant biomolecules, such as strands of regular mRNA, and distinguish fluorescence signal from the background after bioorthogonal reactions in cells, it is imperative to employ turn-on concepts. Here, we have presented a straightforward enzymatic approach to allow site-specific modification of two different positions on the 5' cap of eukaryotic mRNA with either identical or different small functional groups. The approach relies on two methyltransferases and analogues of their natural co-substrate, and it can be extended to a three-enzyme cascade reaction for their in situ production. Subsequent labeling by using bioorthogonal click reactions provided access to double labeling with identical fluorophores or dual labeling with two different reporter groups, as exemplified by a Cy5 dye, a FRET pair, and a fluorophore/biotin combination. Our dual-labeling strategy addresses the need for increased sensitivity and should improve the signal-to-background ratio after bioorthogonal reactions in cells.
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