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Abstract

Mutations within the chromosome 9 open reading frame 72 (c9orf72) gene are associated with both familial amyotrophic lateral sclerosis and frontotemporal dementia. The mutation leads to an expanded GGGGCC hexanucleotide repeat within the first intron of c9orf72 and an expanded CCCCGG repeat within a corresponding antisense transcript. Both the mutant intronic and antisense RNAs have been implicated in disease. We have previously reported that duplex RNAs complementary to the repeats can recognize disease-causing RNA and block detection of nuclear foci formed by the mutant transcripts. Here, we test the hypothesis that inhibition can also be achieved by single-stranded silencing RNAs (ss-siRNAs). ss-siRNAs are single-stranded antisense oligonucleotides (ASOs) that function through RNAi interference (RNAi) to silence gene expression. ss-siRNAs can block the expanded repeats within both intronic RNA and the antisense transcripts. Inhibition is more potent than by analogous duplex RNAs. Our data suggest that the potent effects on foci are caused by a combination of mechanisms including RNAi and direct binding of the ss-siRNA to the target transcripts. These findings reinforce the suggestion that ss-siRNAs combine the favorable properties of duplex RNA and single-stranded ASOs.

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References

Juliano RL. (2016). The delivery of therapeutic oligonucleotides. Nucleic Acids Res, 44:6518–6548.

Nair

, Willoughby

JLS

, Chan

, Charisse

, Alam

, Wang

, Hoekstra

, Kandasamy

, Kel'in

, et al. (2014). Multivalent N-Acetylgalactosamine-conjugated siRNA localizes in hepatocytes and elicits robust RNAi-mediated gene silencing. J Am Chem Soc, 136:16958–16961.

Geary

, Norris

and Bennett

. (2015). Pharmacokinetics, biodistribution and cell uptake of antisense oligonucleotides. Adv Drug Deliv Rev, 87:46–51.

Prakash

, Graham

, Yu

, Carty

, Low

, Chappell

, Schmidt

, Zhao

, Aghajan

, et al. (2014). Targeted delivery of antisense oligonucleotides to hepatocytes using triantennary N-aceyl galactosamine improves potency 10-fold in mice. Nucleic Acids Res, 42:8796–8807.

Lima

, Prakash

, Murray

, Kinberger

, Li

, Chappell

, Li

, Murray

, Gaus

, et al. (2012). Single-stranded siRNAs activate RNAi in animals. Cell, 150:883–894.

Chorn

, Klein-McDowell

, Zhao

, Saunders

, Flanagan

, Willingham

and Lim

. (2012). Single-stranded microRNA mimics. RNA, 18:1796–1804.

, Pendergraff

, Liu

, Kordasiewicz

, Cleveland

, Swayze

, Lima

, Crooke

, Prakash

and Corey

. (2012). Single-stranded RNAs that function through RNAi are potent and allele-selective inhibitors of huntingtin expression. Cell, 150:95–908.

Liu

, Yu

, Aiba

, Pendergraff

, Swayze

, Lima

, Prakash

and Corey

. (2013). ss-siRNAs allele-selectively inhibit ataxin-3 expression: multiple mechanisms for an alternative gene silencing strategy. Nucleic Acids Res, 41:9570–9583.

Matsui

, Prakash

and Corey

. (2013). Transcriptional silencing by promoter-targeted single-stranded RNAs. ACS Chem Biol, 8:122–126.

10.

, Lui

, Yu

, Aiba

, Lee

, Pendergraff

, Boubaker

, Arates

, Lagier-Tourenne

, et al. (2014). Exploring the effect of sequence length and composition on allele-selective inhibition of human huntingtin expression by single-stranded silencing RNAs. Nucleic Acid Ther, 24:199–209.

11.

, Liu

, Narayannair

, Lackey

, Kuchimanchi

, Rajeev

, Manoharan

, Swayze

, Lima

, et al. (2014). Allele-selective inhibition of mutant atrophin-1 expression by duplex and single-stranded RNAs. Biochemistry, 53:4510–4518.

12.

Liu

, Hu

, Hicks

, Prakash

and Corey

. (2015). Modulation of splicing by single-stranded silencing RNAs. Nucleic Acid Ther, 25:113–120.

13.

Pendergraff

, Debacker

and Watts

. (2016). Single-stranded silencing RNAs: hit rate and chemical modification. Nucleic Acid Ther, 26:216–222.

14.

Chang

, Pei

, Guidry

, Zewge

, Parish

, Shere

, DiMuzio

, Zhang

, South

, et al. (2016). Systematic chemical modifications of single stranded siRNAs significantly improved DTNNBI mRNA silencing. Bioorg Med Chem Lett, 26:4513–4517.

15.

Matsui

, Prakash

and Corey

. (2016). Argonaute 2-dependent regulation of gene expression by single-stranded miRNA mimics. Mol Ther, 24:946–955.

16.

DeJesus-Hernandez

, Mackenzie

, Boeve

, Boxer

, Baker

, Rutherford

, Nicholson

, Finch

, Flynn

, et al. (2012). Expanded GGGGCC hexanucleotide repeat in noncoding region of C9ORF72 causes chromosome 9p-linked FTD and ALS. Neuron, 72:245–256.

17.

Renton

, Majounie

, Waite

, Simon-Sanchez

, Rollinson

, Gibbs

, Schymick

, Laaksovirta

, van Swieten

, et al. (2011). A hexanucleotide repeat expansion in C9ORF72 is the cause of chromsome 9p21-linked ALS-FTD. Neuron, 72:257–268.

18.

Gendron

, Bieniek

, Zhang

Y-J

, Jansen-West

, Ash

PEA

, Caulfield

, Daughrity

, Dunmore

, Castanedes-Casey

, et al. (2013). Antisense transcripts of the expanded C9ORF72 hexanucleotide repeat form nuclear RNA foci and undergo repeat associated non-ATG translation in c9FTD/ALS. Acta Neuropathol, 53:839–844.

19.

, Liu

, Liande

, Gagnon

and Corey

. (2015). Targeted recognition of GGGGCC/CCCCGG repeats at the C9orf72 locus by duplex RNA. Chem Biol, 22:1505–1511.

20.

Wang

, Juranek

, Li

, Sheng

, Tuschl

and Patel

. (2008). Structure of an argonaute silencing complex with a seed-containing guide DNA and target RNA duplex. Nature, 456:921–926.

21.

, Liu

and Corey

. (2010). Allele-selectivity by switching to an miRNA-like RNAi mechanism. Chem Biol, 17:1183–1188.

22.

Lennox

and Behlke

. (2016). Cellular localization of long noncoding RNAs affects silencing by RNAi more than by antisense oligonucleotides. Nucleic Acids Res, 44:863–877.

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Recognition of c9orf72 Mutant RNA by Single-Stranded Silencing RNAs

Abstract

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