Efficient and Persistent Splice Switching by Systemically Delivered LNA Oligonucleotides in Mice

Roberts, Jennifer; Palma, Enzo; Sazani, Peter; Ørum, Henrik; Cho, Moo; Kole, Ryszard

doi:10.1016/j.ymthe.2006.05.017

Cited by 96 publications

(95 citation statements)

References 19 publications

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“…Furthermore, the resulting double-stranded structures must not be recognized by RNase H, which degrades RNA in RNA-DNA duplexes (13). These conditions are satisfied in cell culture and in vivo by modified oligomers with various backbones, including 2Ј-Omethoxyethyl phosphorothioate (MOE), locked nucleic acid (LNA), peptide nucleic acid conjugated with four lysines (PNA-4K), and phosphorodiamidate morpholino oligomers (14)(15)(16). However, MOE and LNA SSOs were ineffective at correcting aberrant splicing of IVS2-654 pre-mRNA when delivered ex vivo to cultured erythroid progenitor cells from IVS2-654 murine bone marrow cells (data not shown).…”

Section: Resultsmentioning

confidence: 99%

RNA repair restores hemoglobin expression in IVS2–654 thalassemic mice

Svasti

Suwanmanee

Fucharoen

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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Repair of ␤-globin pre-mRNA rendered defective by a thalassemiacausing splicing mutation, IVS2-654, in intron 2 of the human ␤-globin gene was accomplished in vivo in a mouse model of IVS2-654 thalassemia. This was effected by a systemically delivered splice-switching oligonucleotide (SSO), a morpholino oligomer conjugated to an arginine-rich peptide. The SSO blocked the aberrant splice site in the targeted pre-mRNA and forced the splicing machinery to reselect existing correct splice sites. Repaired ␤-globin mRNA restored significant amounts of hemoglobin in the peripheral blood of the IVS2-654 mouse, improving the number and quality of erythroid cells.oligonucleotides ͉ RNA splicing ͉ thalassemia ͉ therapy ͉ morpholino oligomers O ne of the most common inherited diseases, ␤-thalassemia, is caused by defects in the ␤-globin gene that affect production of ␤-globin, a subunit of hemoglobin (1). Current therapy consists of frequent blood transfusions combined with iron chelation (2). The only cure, bone marrow transplantation, is limited by the scarcity of suitable histocompatible donors (3). Although more than 200 mutations cause the disease, some of the most common ones induce aberrant splicing of ␤-globin pre-mRNA, interfering with proper translation of ␤-globin protein. The IVS2-654 (C Ͼ T) mutation creates an aberrant 5Ј splice site and activates a cryptic 3Ј splice site within intron 2 of the ␤-globin pre-mRNA, leading to retention of the intron fragment in the spliced mRNA even though the correct splice sites remain undamaged and potentially functional ( Fig. 1A) (4). The retained fragment prevents proper translation of ␤-globin, leading to hemoglobin deficiency and ␤-thalassemia. The IVS2-654 mutation is a common cause of thalassemia in Thailand and other countries of Southeast Asia (5). Work in this laboratory showed that splice-switching oligonucleotides (SSOs), which block aberrant splice sites in IVS2-654 and other pre-mRNAs (IVS1-5, IVS1-6, IVS1-110, IVS2-705, and IVS2-745) as well as in the coding sequence (HbE) of the ␤-globin gene, force the splicing machinery to reselect the existing correct splice sites, repairing the splicing pattern of ␤-globin pre-mRNA. This repair, which restores production of correctly spliced ␤-globin mRNA and protein, was accomplished in several in vitro systems and ex vivo in erythroid progenitor cells from thalassemic patients (6)(7)(8)(9)(10)(11)(12). In this study, we investigated the effectiveness in thalassemic splicing correction of a modified morpholino oligomer, SSO 654-P005, in a mouse model of IVS2-654 ␤-thalassemia. Results and DiscussionTo be effective in splicing repair, SSOs must hybridize tightly to the targeted splicing elements, such as aberrant splice sites, and prevent their recognition by the splicing factors. Furthermore, the resulting double-stranded structures must not be recognized by RNase H, which degrades RNA in RNA-DNA duplexes (13). These conditions are satisfied in cell culture and in vivo by modified oligomers with various backbones, includi...

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Section: Resultsmentioning

confidence: 99%

RNA repair restores hemoglobin expression in IVS2–654 thalassemic mice

Svasti

Suwanmanee

Fucharoen

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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“…In addition, they are nontoxic and nuclease resistant (Wahlestedt et al 2000). LNAs have been reported to be extremely efficient modulators of pre-mRNA splicing (Aartsma-Rus et al 2004b;Roberts et al 2006). Ethylenebridged nucleic acids (ENA) have an ethylene bridge instead of a methylene bridge and have comparable characteristics to LNAs (Morita et al 2002(Morita et al , 2003.…”

Section: Aon Chemistrymentioning

confidence: 99%

“…A mouse model stably expressing the GFP construct has been generated, allowing easy comparison of the biodistribution of different AON analogs (Sazani et al 2002). Using this model, it was discovered that full-length LNAs generate an effect mainly in liver, colon, and small intestine after systemic delivery, thus providing a tool to manipulate splicing in these specific tissues (Roberts et al 2006). Morpholinos have gained attention for DMD exon skipping since this chemistry is taken up at higher levels by the muscle (Sazani et al 2002).…”

Section: Aon Chemistrymentioning

confidence: 99%

Antisense-mediated exon skipping: A versatile tool with therapeutic and research applications

Aartsma‐Rus¹,

Ommen²

2007

RNA

236

177

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Antisense-mediated modulation of splicing is one of the few fields where antisense oligonucleotides (AONs) have been able to live up to their expectations. In this approach, AONs are implemented to restore cryptic splicing, to change levels of alternatively spliced genes, or, in case of Duchenne muscular dystrophy (DMD), to skip an exon in order to restore a disrupted reading frame. The latter allows the generation of internally deleted, but largely functional, dystrophin proteins and would convert a severe DMD into a milder Becker muscular dystrophy phenotype. In fact, exon skipping is currently one of the most promising therapeutic tools for DMD, and a successful first-in-man trial has recently been completed. In this review the applicability of exon skipping for DMD and other diseases is described. For DMD AONs have been designed for numerous exons, which has given us insight into their mode of action, splicing in general, and splicing of the DMD gene in particular. In addition, retrospective analysis resulted in guidelines for AON design for DMD and most likely other genes as well. This knowledge allows us to optimize therapeutic exon skipping, but also opens up a range of other applications for the exon skipping approach.

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“…In this model, quantitative analysis of the reverse transcription-polymerase chain reaction (RT-PCR) data indicated that splice correction levels reached 40% in liver and kidney for the most effective oligonucleotide chemistries (PNAs coupled to four lysines) (Sazani et al, 2002). In another study using EGFP-654 mice, LNA oligomers achieved 85% splice correction in liver, exhibiting high potency and persistence up to 22 days after injection (Roberts et al, 2006). These promising results warrant successful application in vivo for antisense-mediated splice modulation therapy in liver associated metabolic diseases.…”

mentioning

confidence: 85%

“…In the EGFP-654 mouse described above, detailed quantification of splice switching after systemic injection showed best results for liver, colon, and intestine, while other tissues such as heart, lung, and skeletal muscle were less efficiently targeted, and no effect was observed in brain tissue (Sazani et al, 2002;Roberts et al, 2006). Other authors have shown similar results, with differences that may be explained by the different routes of delivery (intravenous or intraperitoneal), oligonucleotide chemistries, dosing regime and experimental model used (Parra et al, 2011).…”

Section: Enzyme Defects With Multisystemic Phenotypesmentioning

confidence: 99%

Antisense Mediated Splicing Modulation For Inherited Metabolic Diseases: Challenges for Delivery

Pérez

Vilageliu

Grinberg

et al. 2014

Nucleic Acid Therapeutics

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In the past few years, research in targeted mutation therapies has experienced significant advances, especially in the field of rare diseases. In particular, the efficacy of antisense therapy for suppression of normal, pathogenic, or cryptic splice sites has been demonstrated in cellular and animal models and has already reached the clinical trials phase for Duchenne muscular dystrophy. In different inherited metabolic diseases, splice switching oligonucleotides (SSOs) have been used with success in patients' cells to force pseudoexon skipping or to block cryptic splice sites, in both cases recovering normal transcript and protein and correcting the enzyme deficiency. However, future in vivo studies require individual approaches for delivery depending on the gene defect involved, given the different patterns of tissue and organ expression. Herein we review the state of the art of antisense therapy targeting RNA splicing in metabolic diseases, grouped according to their expression patterns-multisystemic, hepatic, or in central nervous system (CNS)-and summarize the recent progress achieved in the field of in vivo delivery of oligonucleotides to each organ or system. Successful body-wide distribution of SSOs and preferential distribution in the liver after systemic administration have been reported in murine models for different diseases, while for CNS limited data are available, although promising results with intratechal injections have been achieved.

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Efficient and Persistent Splice Switching by Systemically Delivered LNA Oligonucleotides in Mice

Cited by 96 publications

References 19 publications

RNA repair restores hemoglobin expression in IVS2–654 thalassemic mice

RNA repair restores hemoglobin expression in IVS2–654 thalassemic mice

Antisense-mediated exon skipping: A versatile tool with therapeutic and research applications

Antisense Mediated Splicing Modulation For Inherited Metabolic Diseases: Challenges for Delivery

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