RNA editing by cytosine and adenosine deaminases changes the identity of the edited bases. While cytosines are converted to uracils, adenines are converted to inosines. If coding regions of mRNAs are affected, the coding potential of the RNA can be changed, depending on the codon affected. The recoding potential of nucleotide deaminases has recently gained attention for their ability to correct genetic mutations by either reverting the mutation itself or by manipulating processing steps such as RNA splicing. In contrast to CRISPR-based DNA-editing approaches, RNA editing events are transient in nature, therefore reducing the risk of long-lasting inadvertent side-effects. Moreover, some RNA-based therapeutics are already FDA approved and their use in targeting multiple cells or organs to restore genetic function has already been shown. In this review, we provide an overview on the current status and technical differences of site-directed RNA-editing approaches. We also discuss advantages and challenges of individual approaches.
Adenosine deaminases acting on RNAs convert adenosines (A) to inosines (I) in structured or double- stranded RNAs. In mammals, this process is widespread. In the human transcriptome more than a million different sites have been identified that undergo an ADAR-mediated A to I exchange (1). Inosines have an altered base pairing potential due to the missing amino group when compared to the original adenosine. Consequently, inosines prefer to base pair with guanosines but can also base pair with uracil or adenine (2). This altered base pairing potential not only affects protein decoding at the ribosome but also influences the folding of RNAs and the proteins that can associate with it. Consequently, an A to I exchange can also affect RNA processing and turnover (3, 4). All of these events will interfere with gene expression and therefore, can also affect cellular and organismic physiology. As double-stranded RNAs are a hallmark of viral pathogens RNA-editing not only affects RNA-processing, coding and gene expression but also controls the antiviral response to double-stranded RNAs. Most interestingly, recent advances in our understanding of ADAR enzymes reveal multiple layers of regulation by which ADARs can control antiviral programs. In this review we focus on the recoding of mRNAs where the altered translation products lead to physiological changes. We also address recent advances in our understanding of the multiple layers of antiviral responses and innate immune modulations mediated by ADAR1.
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