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Silencing Srsf6 does not modulate incomplete splicing of the huntingtin gene in Huntington’s disease models

Michael Atwood Mason, Casandra Gomez-Paredes, Kirupa Sathasivam, Andreas Neueder, Aikaterini-Smaragdi Papadopoulou, Gillian P. Bates

2020Scientific Reports25 citationsDOIOpen Access PDF

Abstract

Abstract We have previously shown that the incomplete splicing of exon 1 to exon 2 of the HTT gene results in the production of a small polyadenylated transcript ( Httexon1 ) that encodes the highly pathogenic exon 1 HTT protein. There is evidence to suggest that the splicing factor SRSF6 is involved in the mechanism that underlies this aberrant splicing event. Therefore, we set out to test this hypothesis, by manipulating SRSF6 levels in Huntington’s disease models in which an expanded CAG repeat had been knocked in to the endogenous Htt gene. We began by generating mice that were knocked out for Srsf6 , and demonstrated that reduction of SRSF6 to 50% of wild type levels had no effect on incomplete splicing in zQ175 knockin mice. We found that nullizygosity for Srsf6 was embryonic lethal, and therefore, to decrease SRSF6 levels further, we established mouse embryonic fibroblasts (MEFs) from wild type, zQ175, and zQ175:: Srsf6 +/− mice and transfected them with an Srsf6 siRNA. The incomplete splicing of Htt was recapitulated in the MEFs and we demonstrated that ablation of SRSF6 did not modulate the levels of the Httexon1 transcript. We conclude that SRSF6 is not required for the incomplete splicing of HTT in Huntington’s disease.

Topics & Concepts

ExonHuntingtinRNA splicingBiologyAlternative splicingGene silencingExon skippingGeneHuntington's diseasePolyadenylationMinigeneGeneticsMolecular biologyCell biologyGene expressionDiseaseRNAMutantMedicinePathologyGenetic Neurodegenerative DiseasesMuscle Physiology and DisordersMitochondrial Function and Pathology
Silencing Srsf6 does not modulate incomplete splicing of the huntingtin gene in Huntington’s disease models | Litcius