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Abstract

Site-directed RNA editing is a promising genetic modification technology for therapeutic and pharmaceutical applications. We previously constructed adenosine deaminases acting on RNA (ADAR)-guiding RNAs (AD-gRNAs) that direct A-to-I RNA editing activity of native human ADAR2 into a programmable target site. In this study, we developed the short-chain AD-gRNA (shAD-gRNA) as a potential basic framework for practical RNA-editing oligonucleotides. Based on knowledge of previous AD-gRNA, shAD-gRNAs were designed to have the shortest possible sequence for the induction of editing activity. In vitro, compared to the original AD-gRNA, the shAD-gRNAs showed similar or superior editing induction activity, depending on the target RNA sequence, and had lower off-target editing activity around the target site, which is predicted to be a hotspot for off-target editing. Moreover, shAD-gRNAs achieved target RNA editing with both exogenous and endogenous human ADARs in cultured cells. Our results present shAD-gRNA as a short basic framework that would be applicable to further development for practical RNA-editing oligonucleotides.

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References

Stafforst

and Schneider

. (2012). An RNA-deaminase conjugate selectively repairs point mutations. Angew Chem Int Ed Engl, 51:11166–11169.

Montiel-Gonzalez

, Vallecillo-Viejo

, Yudowski

and Rosenthal

. (2013). Correction of mutations within the cystic fibrosis transmembrane conductance regulator by site-directed RNA editing. Proc Natl Acad Sci USA, 110:18285–18290.

Cox

DBT

, Gootenberg

, Abudayyeh

, Franklin

, Kellner

, Joung

and Zhang

. (2017). RNA editing with CRISPR-Cas13. Science, 358:1019–1027.

Vallecillo-Viejo

, Liscovitch-Brauer

, Montiel-Gonzalez

, Eisenberg

and Rosenthal

. (2018). Abundant off-target edits from site-directed RNA editing can be reduced by nuclear localization of the editing enzyme. RNA Biol, 15:104–114.

Vogel

, Moschref

, Li

, Merkle

, Selvasaravanan

, Li

and Stafforst

. (2018). Efficient and precise editing of endogenous transcripts with SNAP-tagged ADARs. Nat Methods, 15:535–538.

Azad

MTA

, Bhakta

and Tsukahara

. (2017). Site-directed RNA editing by adenosine deaminase acting on RNA for correction of the genetic code in gene therapy. Gene Ther, 24:779–786.

Fukuda

, Umeno

, Nose

, Nishitarumizu

, Noguchi

and Nakagawa.

(2017). Construction of a guide-RNA for site-directed RNA mutagenesis utilising intracellular A-to-I RNA editing. Sci Rep, 7:41478.

Wettengel

, Reautschnig

, Geisler

, Kahle

and Stafforst

. (2017). Harnessing human ADAR2 for RNA repair—recoding a PINK1 mutation rescues mitophagy. Nucleic Acids Res, 45:2797–2808.

Monteleone

, Matthews

, Palumbo

, Thomas

, Zheng

, Chiang

, Fisher

and Beal

. (2019). A bump-hole approach for directed RNA editing. Cell Chem Biol, 26:269–277.

10.

Katrekar

, Chen

, Meluzzi

, Ganesh

, Worlikar

, Shih

, Varghese

and Mali

. (2019). In vivo RNA editing of point mutations via RNA-guided adenosine deaminases. Nat Method, 16:239–242.

11.

, Yi

, Zhu

, Wang

, Cao

, Zhou

, Yuan

, Yu

, Tian

, et al. (2019). Programmable RNA editing by recruiting endogenous ADAR using engineered RNAs. Nat Biotechnol, 37:1059–1069.

12.

Merkle

, Merz

, Reautschnig

, Blaha

, Li

, Vogel

, Wettengel

, Li

and Stafforst

. (2019). Precise RNA editing by recruiting endogenous ADARs with antisense oligonucleotides. Nat Biotechnol, 37:133–138.

13.

Nishikura

. (2016). A-to-I editing of coding and non-coding RNAs by ADARs. Nat Rev Mol Cell Biol, 17:83–96.

14.

Picardi

, Manzari

, Mastropasqua

, Aiello

, D'Erchia

and Pesole.

(2015). Profiling RNA editing in human tissues: towards the inosinome atlas. Sci Rep, 5:14941.

15.

Tan

, Li

, Shanmugam

, Piskol

, Kohler

, Young

, Liu

, Zhang

, Ramaswami

, et al. (2017). Dynamic landscape and regulation of RNA editing in mammals. Nature, 550:249–254.

16.

Crooke

, Witztum

, Bennett

and Baker

. (2018). RNA-targeted therapeutics. Cell Metab, 27:714–739.

17.

Eggington

, Greene T and BL

Bass

. (2011). Predicting sites of ADAR editing in double-stranded RNA. Nat Commun 2:. 319.

18.

Sato

, Watanabe

, Katsuda

, Murata

, Wang

and Uesugi

. (2015). Live-cell imaging of endogenous mRNAs with a small molecule. Angew Chem Int Ed, 54:1855–1858.

19.

Rhee

, Santangelo

, Jo

and Bao.

(2008). Target accessibility and signal specificity in live-cell detection of BMP-4 mRNA using molecular beacons. Nucleic Acids Res, 36:e30.

20.

Rudnick

, Swaminathan

, Sumaroka

, Liebhaber

and Gewirtz

. (2008). Effects of local mRNA structure on posttranscriptional gene silencing. Proc Natl Acad Sci USA, 16:13787–13792.

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Short-Chain Guide RNA for Site-Directed A-to-I RNA Editing

Abstract

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Supplementary Material