Department of Chemistry and Biochemistry and Center for RNA Biology, The Ohio State University, 484 West 12th Avenue, Columbus, OH, 43210, USA.
Chembiochem. 2018 Jan 18;19(2):142-146. doi: 10.1002/cbic.201700538. Epub 2017 Dec 7.
Spectroscopic methods, which are used to establish RNA structure-function relationships, require strategies for post-synthetic, site-specific incorporation of chemical probes into target RNAs. For RNAs larger than 50 nt, the enzymatic incorporation of a nucleoside or nucleotide monophosphate guanosine analogue (G analogue) at their 5'-end is routinely achieved by T7 RNA polymerase (T7RNAP)-mediated in vitro transcription (IVT) of the appropriate DNA template containing a GTP-initiating class III Φ6.5 promoter. However, when high G analogue:GTP ratios are used to bias G analogue incorporation at the 5'-end, RNA yield is compromised. Here, we show that the use of a T7RNAP P266L mutant in IVT with 10:1 thienoguanosine ( G):GTP increased the percent incorporation and yield of 5'- G-initiated precursor tRNA for a net ≈threefold gain compared to IVT with wild-type T7RNAP. We also demonstrated that a one-pot multienzyme approach, consisting of transcription by T7RNAP P266L and post-transcriptional cleanup by polyphosphatase and an exonuclease, led to essentially near-homogeneous 5'- G-modified transcripts. This approach should be of broad utility in preparing 5'-modified RNAs.
光谱方法用于建立 RNA 的结构-功能关系,需要在合成后将化学探针特异性地掺入目标 RNA 中。对于大于 50nt 的 RNA,通过 T7 RNA 聚合酶(T7RNAP)介导的包含 GTP 起始 III 类 Φ6.5 启动子的适当 DNA 模板的体外转录(IVT),可以常规地将核苷或核苷酸单磷酸鸟苷类似物(G 类似物)掺入其 5' - 末端。然而,当使用高 G 类似物:GTP 比来偏向 5' - 末端的 G 类似物掺入时,RNA 的产量会受到影响。在这里,我们表明在 IVT 中使用 T7RNAP P266L 突变体,并用 10:1 噻鸟嘌呤(G):GTP 取代,与使用野生型 T7RNAP 的 IVT 相比,可提高 5' - G 起始前体 tRNA 的掺入百分比和产量,净增加约三倍。我们还证明,由 T7RNAP P266L 转录和多磷酸酶和外切核酸酶的转录后清理组成的一锅多酶方法,可导致基本上均一的 5' - G 修饰的转录物。该方法在制备 5' - 修饰的 RNA 方面应该具有广泛的用途。
