Exon-Specific U1s Correct SPINK<i>5</i>Exon 11 Skipping Caused by a Synonymous Substitution that Affects a Bifunctional Splicing Regulatory Element

Mas, Andrea Dal; Fortugno, Paola; Donadon, Irving; Levati, Lauretta; Castiglia, Daniele; Pagani, Franco

doi:10.1002/humu.22762

Cited by 30 publications

(38 citation statements)

References 40 publications

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“…Normal human primary epidermal keratinocytes (NHEK) were cultured as previously described (Zambruno et al 1995). Keratinocytes were seeded at a concentration of 1-1.5 × 10 4 cells/ cm 2 in serum-free Keratinocyte Growth Medium (KGM, Invitrogen) containing 0.15 mM Ca 2+ , cultured till confluence, and then induced to differentiate by culturing in KGM containing 1.2 mM Ca 2+ for up to 5 d (Dal Mas et al 2015). Cells were maintained at 37°C with 5% CO 2 .…”

Section: Cell Culturesmentioning

confidence: 99%

Microprocessor-dependent processing of splice site overlapping microRNA exons does not result in changes in alternative splicing

Pianigiani

Licastro

Fortugno

et al. 2018

RNA

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MicroRNAs are found throughout the genome and are processed by the microprocessor complex (MPC) from longer precursors. Some precursor miRNAs overlap intron:exon junctions. These plice siteverlapping microRNAs (SO-miRNAs) are mostly located in coding genes. It has been intimated, in the rarer examples of SO-miRNAs in noncoding RNAs, that the competition between the spliceosome and the MPC modulates alternative splicing. However, the effect of this overlap on coding transcripts is unknown. Unexpectedly, we show that neither Drosha silencing nor SF3b1 silencing changed the inclusion ratio of SO-miRNA exons. Two SO-miRNAs, located in genes that code for basal membrane proteins, are known to inhibit proliferation in primary keratinocytes. These SO-miRNAs were up-regulated during differentiation and the host mRNAs were down-regulated, but again there was no change in inclusion ratio of the SO-miRNA exons. Interestingly, Drosha silencing increased nascent RNA density, on chromatin, downstream from SO-miRNA exons. Overall our data suggest a novel mechanism for regulating gene expression in which MPC-dependent cleavage of SO-miRNA exons could cause premature transcriptional termination of coding genes rather than affecting alternative splicing.

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Section: Cell Culturesmentioning

confidence: 99%

Microprocessor-dependent processing of splice site overlapping microRNA exons does not result in changes in alternative splicing

Pianigiani

Licastro

Fortugno

et al. 2018

RNA

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“…However, these U1snRNAs are often tailored on the disease-causing mutation and have the intrinsic risk of off-target effects by recognizing the partially conserved donor splice site 22 in other splicing units. For this reason, we recently developed a second-generation U1snRNAs, named Exon Specific U1snRNAs (ExSpeU1s), that are designed to recognize intronic, often poorly conserved and thus gene-specific, regions downstream of the affected exon, and shown to efficiently rescue exon-skipping in different disease models, 23,24,25,26,27,28 Of great importance, in cellular cultures, a unique ExSpeU1 was able to rescue normal splicing from different type of exon-skipping mutations either at the 5′ss or acceptor splice site (3′ss), or within the exon. 23,29 Although these gene-specificity and activity ExSpeU1 features would significantly extend the applicability of a single therapeutic molecule to panels of mutations and thus cohorts of patients, a key issue when addressing the numerous diseases with heterogeneous mutational patterns (www.hgmd.cf.ac.uk), this effect of ExSpeU1s in vivo has not been investigated yet.…”

Section: Introductionmentioning

confidence: 99%

An Exon-Specific U1snRNA Induces a Robust Factor IX Activity in Mice Expressing Multiple Human FIX Splicing Mutants

Balestra

Scalet

Pagani

et al. 2016

Molecular Therapy - Nucleic Acids

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In cellular models we have demonstrated that a unique U1snRNA targeting an intronic region downstream of a defective exon (Exon-specific U1snRNA, ExSpeU1) can rescue multiple exon-skipping mutations, a relevant cause of genetic disease. Here, we explored in mice the ExSpeU1 U1fix9 toward two model Hemophilia B-causing mutations at the 5′ (c.519A > G) or 3′ (c.392-8T > G) splice sites of F9 exon 5. Hydrodynamic injection of wt-BALB/C mice with plasmids expressing the wt and mutant (hFIX-2G5′ss and hFIX-8G3′ss) splicing-competent human factor IX (hFIX) cassettes resulted in the expression of hFIX transcripts lacking exon 5 in liver, and in low plasma levels of inactive hFIX. Coinjection of U1fix9, but not of U1wt, restored exon inclusion of variants and in the intrinsically weak FIXwt context. This resulted in appreciable circulating hFIX levels (mean ± SD; hFIX-2G5′ss, 1.0 ± 0.5 µg/ml; hFIX-8G3′ss, 1.2 ± 0.3 µg/ml; and hFIXwt, 1.9 ± 0.6 µg/ml), leading to a striking shortening (from ~100 seconds of untreated mice to ~80 seconds) of FIX-dependent coagulation times, indicating a hFIX with normal specific activity. This is the first proof-of-concept in vivo that a unique ExSpeU1 can efficiently rescue gene expression impaired by distinct exon-skipping variants, which extends the applicability of ExSpeU1s to panels of mutations and thus cohort of patients.

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“…On the basis of the frequency and relevance of these nucleotide changes and on their mechanism, we and others have devised a correction approach based on variants of the U1snRNA designed to restore complementarity with the defective 5′ss (compensatory U1snRNAs; Pinotti et al., ) or to target downstream intronic regions (exon‐specific U1snRNAs; ExSpeU1; Alanis et al., ). For different human genetic disorders, in both cellular (Balestra et al., ; Dal Mas et al., ; Glaus, Schmid, Da Costa, Berger, & Neidhardt, ; Scalet et al., ; Schmid et al., ; Tajnik et al., ; van der Woerd et al., ) and animal (Balestra et al., ; Balestra et al., ; Dal Mas, Rogalska, Bussani, & Pagani, ; Donadon et al., ; Rogalska et al., ) models, the engineered U1snRNAs were shown to be effective on variants at 5′ss but also within the exon or at the 3′ss. However, these approaches failed to rescue changes at the highly conserved nucleotides +1G and +2T of the 5′ss (Alanis et al., ; Cavallari et al., ), which are the most represented (Buratti et al., ; Krawczak et al., ) and severe ones, and commonly considered to be virtually null.…”

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confidence: 99%

Disease-causing variants of the conserved +2T of 5′ splice sites can be rescued by engineered U1snRNAs

et al. 2018

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The ability of variants of the spliceosomal U1snRNA to rescue splicing has been proven in several human disease models, but not for nucleotide changes at the conserved GT nucleotide of 5 ′ splice sites (5 ′ ss), frequent and associated with severe phenotypes. Here, we focused on variants at the 5 ′ ss of F9 intron 3, leading to factor IX (FIX) deficiency (hemophilia B). Through minigene expression, we demonstrated that all changes induce complete exon 3 skipping, which explains the associated hemophilia B phenotype. Interestingly, engineered U1snRNAs remarkably increased the proportion of correct transcripts in the presence of the c.277+4A>G (∼60%) and also c.277+2T>C mutation (∼20%). Expression of splicing-competent cDNA constructs indicated that the splicing rescue produces an appreciable increase of secreted FIX protein levels. These data provide the first experimental evidence that even part of variants at the conserved 5 ′ ss +2T nucleotide can be rescued, thus expanding the applicability of this U1snRNA-based approach. K E Y W O R D SExSpeU1, hemophilia B, human disease, RNA splicing, splicing mutations Nucleotide changes affecting the 5 ′ splice site (5 ′ ss) represent approx-

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Exon-Specific U1s Correct SPINK5Exon 11 Skipping Caused by a Synonymous Substitution that Affects a Bifunctional Splicing Regulatory Element

Cited by 30 publications

References 40 publications

Microprocessor-dependent processing of splice site overlapping microRNA exons does not result in changes in alternative splicing

Microprocessor-dependent processing of splice site overlapping microRNA exons does not result in changes in alternative splicing

An Exon-Specific U1snRNA Induces a Robust Factor IX Activity in Mice Expressing Multiple Human FIX Splicing Mutants

Disease-causing variants of the conserved +2T of 5′ splice sites can be rescued by engineered U1snRNAs

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