Department of Chemistry and Biochemistry and, Center for RNA Biology, The Ohio State University, 774 Biological Sciences Building, 484 West 12th Avenue, Columbus, OH, 43210, USA.
Present address: Biological and Biomedical Sciences Graduate Program, Yale University, New Haven, CT, 06520, USA.
Chembiochem. 2018 Nov 16;19(22):2353-2359. doi: 10.1002/cbic.201800447. Epub 2018 Oct 24.
Chemoenzymatic approaches are important for generating site-specific, chemically modified RNAs, a cornerstone for RNA structure-function correlation studies. T7 RNA polymerase (T7RNAP)-mediated in vitro transcription (IVT) of a DNA template containing the G-initiating class III Φ6.5 promoter is typically used to generate 5'-chemically modified RNAs by including a guanosine analogue (G analogue) initiator in the IVT. However, the yield of 5'-G analogue-initiated RNA is often poor and variable due to the high ratios of G analogue:GTP used in IVT. We recently reported that a T7RNAP P266L mutant afforded an approximately three-fold increase in fluorescent 5'-thienoguanosine-initiated pre-tRNA compared to the wild type T7RNAP. We have further explored the use of T7RNAP P266L to generate 5'-deoxy-5'-azidoguanosine ( G)-initiated RNA and found that the mutant yielded approximately four times more G-initiated pre-tRNA than the wild type in an IVT containing a 10:1 ratio of G:GTP. For accurate quantitation of the 5'- G-initiated RNA fraction, we employed RNase P, an endonuclease that catalyzes the removal of the 5'-leader in pre-tRNAs. Importantly, we show herein how RNase P can be leveraged for assessing 5'-G analogue incorporation in any RNA by rendering the target RNA, upon its binding to a customized external guide sequence RNA, into an unnatural substrate of RNase P. Such an approach in conjunction with T7RNAP P266L-based IVT should aid chemoenzymatic methods that are designed to generate 5'-chemically modified RNAs.
酶化学方法对于产生具有特定化学修饰的 RNA 至关重要,这是 RNA 结构-功能相关性研究的基石。通常使用 T7 RNA 聚合酶(T7RNAP)介导的含有 G 起始 III 类 Φ6.5 启动子的 DNA 模板的体外转录(IVT)来通过在 IVT 中包含鸟苷类似物(G 类似物)引发子来产生 5'-化学修饰的 RNA。然而,由于在 IVT 中使用的 G 类似物:GTP 的高比例,5'-G 类似物引发的 RNA 的产量往往很差且不稳定。我们最近报道,与野生型 T7RNAP 相比,T7RNAP P266L 突变体使荧光 5'-硫代鸟苷引发的预 tRNA 的产量增加了大约三倍。我们进一步探索了使用 T7RNAP P266L 产生 5'-脱氧-5'-叠氮鸟苷(G)引发的 RNA,并发现突变体在含有 10:1 G:GTP 比例的 IVT 中产生的 G 引发的预 tRNA 比野生型多约四倍。为了准确定量 5'-G 引发的 RNA 部分,我们使用了 RNase P,这是一种内切核酸酶,可催化预 tRNA 中 5'-leader 的去除。重要的是,我们在此展示了如何通过将靶 RNA 与定制的外部引导序列 RNA 结合,将其转化为 RNase P 的非天然底物,从而利用 RNase P 来评估任何 RNA 中的 5'-G 类似物掺入。这种方法与基于 T7RNAP P266L 的 IVT 相结合,应该有助于设计用于生成 5'-化学修饰 RNA 的酶化学方法。