突变体
聚腺苷酸
生物
基因亚型
内含子
细胞生物学
寡核苷酸
体细胞
突变
转录组
损失函数
分子生物学
编码区
信使核糖核酸
基因
等位基因
RNA剪接
遗传学
函数增益
功能(生物学)
转基因
亨廷顿蛋白
疾病
下调和上调
抄写(语言学)
癌症研究
化学
基因敲除
反义RNA
野生型
表型
作者
Robert M. Bragg,Christian Landles,Edward J Smith,Georgina F. Osborne,Ella Mathews,Jeffrey P. Cantle,Gillian P. Bates,Jeffrey B. Carroll
标识
DOI:10.1126/scitranslmed.adv0702
摘要
Huntington’s disease (HD) arises from the toxic gain of function caused by a CAG expansion in the coding region of the huntingtin ( HTT ) gene. HD is increasingly appreciated to emerge from multiple pathogenic processes, including somatic instability in mutant HTT ’s ( mHTT ) CAG repeat tract, which leads to diverse deleterious consequences. These include the alternative processing of HTT pre-mRNA to generate the HTT1a transcript that encodes the very toxic mHTT isoform referred to as HTT1a. We set out to compare the efficacy and safety of allele-selective lowering of mHTT with those of non–allele-selective lowering using antisense oligonucleotides (ASOs) in heterozygous Htt Q111 (Q111) mice. We developed a mutant-specific ASO (MutASO) targeting Htt intron 1 that selectively reduced mutant full-length HTT, as well as HTT1a, in the brains of Q111 mice. Compared with the rescue provided by a panallele-targeting ASO (PanASO) that lowers wild-type HTT and full-length mHTT (sparing HTT1a), the MutASO essentially eliminated aggregate formation and provided marked protection from transcriptional dysregulation in HD knockin mice. Thus, by targeting the ASO to the region upstream of the cryptic polyadenylation sites required to generate the HTT1a transcript, our allele-selective MutASO potently reduced HTT1a transcript and protein levels. Our findings suggest that HTT1a may have a disproportionate impact on aggregate formation and transcriptional dysregulation and that lowering the levels of HTT1a could provide benefit when designing HTT-lowering–based therapeutic strategies for HD.
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