Liquori Alessandro, Vaché Christel, Baux David, Blanchet Catherine, Hamel Christian, Malcolm Sue, Koenig Michel, Claustres Mireille, Roux Anne-Françoise
Laboratoire de Génétique de Maladies Rares EA 7402, Université de Montpellier, Montpellier, France.
Laboratoire de Génétique Moléculaire, CHRU Montpellier, Montpellier, France.
Hum Mutat. 2016 Feb;37(2):184-93. doi: 10.1002/humu.22926. Epub 2015 Nov 23.
Deep intronic mutations leading to pseudoexon (PE) insertions are underestimated and most of these splicing alterations have been identified by transcript analysis, for instance, the first deep intronic mutation in USH2A, the gene most frequently involved in Usher syndrome type II (USH2). Unfortunately, analyzing USH2A transcripts is challenging and for 1.8%-19% of USH2 individuals carrying a single USH2A recessive mutation, a second mutation is yet to be identified. We have developed and validated a DNA next-generation sequencing approach to identify deep intronic variants in USH2A and evaluated their consequences on splicing. Three distinct novel deep intronic mutations have been identified. All were predicted to affect splicing and resulted in the insertion of PEs, as shown by minigene assays. We present a new and attractive strategy to identify deep intronic mutations, when RNA analyses are not possible. Moreover, the bioinformatics pipeline developed is independent of the gene size, implying the possible application of this approach to any disease-linked gene. Finally, an antisense morpholino oligonucleotide tested in vitro for its ability to restore splicing caused by the c.9959-4159A>G mutation provided high inhibition rates, which are indicative of its potential for molecular therapy.
导致假外显子(PE)插入的内含子深处突变被低估了,并且这些剪接改变大多是通过转录本分析鉴定出来的,例如,USH2A基因中的首个内含子深处突变,该基因是II型Usher综合征(USH2)中最常受累的基因。不幸的是,分析USH2A转录本具有挑战性,对于1.8%-19%携带单个USH2A隐性突变的USH2个体,第二个突变尚未被鉴定出来。我们开发并验证了一种DNA二代测序方法,以鉴定USH2A中的内含子深处变异,并评估它们对剪接的影响。已鉴定出三种不同的新型内含子深处突变。如小基因检测所示,所有这些突变均被预测会影响剪接并导致PE的插入。当无法进行RNA分析时,我们提出了一种新的且有吸引力的策略来鉴定内含子深处突变。此外,所开发的生物信息学流程与基因大小无关,这意味着该方法可能适用于任何与疾病相关的基因。最后,在体外测试的一种反义吗啉代寡核苷酸恢复由c.9959-4159A>G突变引起的剪接的能力提供了高抑制率,这表明其在分子治疗方面的潜力。
