Literature DB >> 27721240

Targeting CAG repeat RNAs reduces Huntington's disease phenotype independently of huntingtin levels.

Laura Rué, Mónica Bañez-Coronel, Jordi Creus-Muncunill, Albert Giralt, Rafael Alcalá-Vida, Gartze Mentxaka, Birgit Kagerbauer, M Teresa Zomeño-Abellán, Zeus Aranda, Veronica Venturi, Esther Pérez-Navarro, Xavier Estivill, Eulàlia Martí.   

Abstract

Huntington's disease (HD) is a polyglutamine disorder caused by a CAG expansion in the Huntingtin (HTT) gene exon 1. This expansion encodes a mutant protein whose abnormal function is traditionally associated with HD pathogenesis; however, recent evidence has also linked HD pathogenesis to RNA stable hairpins formed by the mutant HTT expansion. Here, we have shown that a locked nucleic acid-modified antisense oligonucleotide complementary to the CAG repeat (LNA-CTG) preferentially binds to mutant HTT without affecting HTT mRNA or protein levels. LNA-CTGs produced rapid and sustained improvement of motor deficits in an R6/2 mouse HD model that was paralleled by persistent binding of LNA-CTG to the expanded HTT exon 1 transgene. Motor improvement was accompanied by a pronounced recovery in the levels of several striatal neuronal markers severely impaired in R6/2 mice. Furthermore, in R6/2 mice, LNA-CTG blocked several pathogenic mechanisms caused by expanded CAG RNA, including small RNA toxicity and decreased Rn45s expression levels. These results suggest that LNA-CTGs promote neuroprotection by blocking the detrimental activity of CAG repeats within HTT mRNA. The present data emphasize the relevance of expanded CAG RNA to HD pathogenesis, indicate that inhibition of HTT expression is not required to reverse motor deficits, and further suggest a therapeutic potential for LNA-CTG in polyglutamine disorders.

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Year:  2016        PMID: 27721240      PMCID: PMC5096913          DOI: 10.1172/JCI83185

Source DB:  PubMed          Journal:  J Clin Invest        ISSN: 0021-9738            Impact factor:   14.808


  56 in total

1.  Interference by huntingtin and atrophin-1 with cbp-mediated transcription leading to cellular toxicity.

Authors:  F C Nucifora ; M Sasaki; M F Peters; H Huang; J K Cooper; M Yamada; H Takahashi; S Tsuji; J Troncoso; V L Dawson; T M Dawson; C A Ross
Journal:  Science       Date:  2001-03-23       Impact factor: 47.728

2.  Disruption of striatal glutamatergic transmission induced by mutant huntingtin involves remodeling of both postsynaptic density and NMDA receptor signaling.

Authors:  Jesús F Torres-Peraza; Albert Giralt; Juan M García-Martínez; Edurne Pedrosa; Josep M Canals; Jordi Alberch
Journal:  Neurobiol Dis       Date:  2007-10-23       Impact factor: 5.996

3.  RNA interference improves motor and neuropathological abnormalities in a Huntington's disease mouse model.

Authors:  Scott Q Harper; Patrick D Staber; Xiaohua He; Steven L Eliason; Inês H Martins; Qinwen Mao; Linda Yang; Robert M Kotin; Henry L Paulson; Beverly L Davidson
Journal:  Proc Natl Acad Sci U S A       Date:  2005-04-05       Impact factor: 11.205

4.  Brain region- and age-dependent dysregulation of p62 and NBR1 in a mouse model of Huntington's disease.

Authors:  Laura Rué; Graciela López-Soop; Ellen Gelpi; Marta Martínez-Vicente; Jordi Alberch; Esther Pérez-Navarro
Journal:  Neurobiol Dis       Date:  2013-01-04       Impact factor: 5.996

5.  Decreased expression of striatal signaling genes in a mouse model of Huntington's disease.

Authors:  R Luthi-Carter; A Strand; N L Peters; S M Solano; Z R Hollingsworth; A S Menon; A S Frey; B S Spektor; E B Penney; G Schilling; C A Ross; D R Borchelt; S J Tapscott; A B Young; J H Cha; J M Olson
Journal:  Hum Mol Genet       Date:  2000-05-22       Impact factor: 6.150

6.  Biochemical characterization of circulating Met-enkephalins in canine endotoxin shock.

Authors:  J D Watson; J G Varley; S J Tomlin; S Medbak; L H Rees; C J Hinds
Journal:  J Endocrinol       Date:  1986-11       Impact factor: 4.286

7.  Paradoxical delay in the onset of disease caused by super-long CAG repeat expansions in R6/2 mice.

Authors:  A Jennifer Morton; Dervila Glynn; Wendy Leavens; Zhiguang Zheng; Richard L M Faull; Jeremy N Skepper; James M Wight
Journal:  Neurobiol Dis       Date:  2008-12-11       Impact factor: 5.996

8.  Therapeutic silencing of mutant huntingtin with siRNA attenuates striatal and cortical neuropathology and behavioral deficits.

Authors:  M DiFiglia; M Sena-Esteves; K Chase; E Sapp; E Pfister; M Sass; J Yoder; P Reeves; R K Pandey; K G Rajeev; M Manoharan; D W Y Sah; P D Zamore; N Aronin
Journal:  Proc Natl Acad Sci U S A       Date:  2007-10-16       Impact factor: 11.205

9.  Sustained effects of nonallele-specific Huntingtin silencing.

Authors:  Valérie Drouet; Valérie Perrin; Raymonde Hassig; Noëlle Dufour; Gwennaelle Auregan; Sandro Alves; Gilles Bonvento; Emmanuel Brouillet; Ruth Luthi-Carter; Philippe Hantraye; Nicole Déglon
Journal:  Ann Neurol       Date:  2009-03       Impact factor: 10.422

Review 10.  Oligonucleotide-based strategies to combat polyglutamine diseases.

Authors:  Agnieszka Fiszer; Wlodzimierz J Krzyzosiak
Journal:  Nucleic Acids Res       Date:  2014-05-21       Impact factor: 16.971
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  29 in total

1.  Huntington's disease brain-derived small RNAs recapitulate associated neuropathology in mice.

Authors:  Jordi Creus-Muncunill; Anna Guisado-Corcoll; Veronica Venturi; Lorena Pantano; Georgia Escaramís; Marta García de Herreros; Maria Solaguren-Beascoa; Ana Gámez-Valero; Cristina Navarrete; Mercè Masana; Franc Llorens; Daniela Diaz-Lucena; Esther Pérez-Navarro; Eulàlia Martí
Journal:  Acta Neuropathol       Date:  2021-02-06       Impact factor: 17.088

Review 2.  Recent Advances in the Treatment of Huntington's Disease: Targeting DNA and RNA.

Authors:  Kathleen M Shannon
Journal:  CNS Drugs       Date:  2020-03       Impact factor: 5.749

3.  Small interfering RNAs based on huntingtin trinucleotide repeats are highly toxic to cancer cells.

Authors:  Andrea E Murmann; Quan Q Gao; William E Putzbach; Monal Patel; Elizabeth T Bartom; Calvin Y Law; Bryan Bridgeman; Siquan Chen; Kaylin M McMahon; C Shad Thaxton; Marcus E Peter
Journal:  EMBO Rep       Date:  2018-02-12       Impact factor: 8.807

Review 4.  Repeat-associated non-AUG (RAN) translation: insights from pathology.

Authors:  Monica Banez-Coronel; Laura P W Ranum
Journal:  Lab Invest       Date:  2019-03-27       Impact factor: 5.662

5.  Comparison of spinocerebellar ataxia type 3 mouse models identifies early gain-of-function, cell-autonomous transcriptional changes in oligodendrocytes.

Authors:  Biswarathan Ramani; Bharat Panwar; Lauren R Moore; Bo Wang; Rogerio Huang; Yuanfang Guan; Henry L Paulson
Journal:  Hum Mol Genet       Date:  2017-09-01       Impact factor: 6.150

Review 6.  Molecular mechanisms underlying nucleotide repeat expansion disorders.

Authors:  Indranil Malik; Chase P Kelley; Eric T Wang; Peter K Todd
Journal:  Nat Rev Mol Cell Biol       Date:  2021-06-17       Impact factor: 113.915

Review 7.  Therapies targeting DNA and RNA in Huntington's disease.

Authors:  Edward J Wild; Sarah J Tabrizi
Journal:  Lancet Neurol       Date:  2017-09-12       Impact factor: 44.182

Review 8.  Gene targeting techniques for Huntington's disease.

Authors:  Eric Fields; Erik Vaughan; Deepika Tripu; Isabelle Lim; Katherine Shrout; Jessica Conway; Nicole Salib; Yubin Lee; Akash Dhamsania; Michael Jacobsen; Ashley Woo; Huijing Xue; Kan Cao
Journal:  Ageing Res Rev       Date:  2021-06-05       Impact factor: 11.788

9.  Trojan triplets: RNA-based pathomechanisms for muscle dysfunction in Huntington's disease.

Authors:  Martin Skov; Robert T Dirksen
Journal:  J Gen Physiol       Date:  2016-12-09       Impact factor: 4.086

Review 10.  Gene suppression approaches to neurodegeneration.

Authors:  Rhia Ghosh; Sarah J Tabrizi
Journal:  Alzheimers Res Ther       Date:  2017-10-05       Impact factor: 6.982
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