Otsuka Hiroki, Sasai Hideo, Nakama Mina, Aoyama Yuka, Abdelkreem Elsayed, Ohnishi Hidenori, Konstantopoulou Vassiliki, Sass Jörn Oliver, Fukao Toshiyuki
Department of Pediatrics, Graduate School of Medicine, Gifu University, Gifu 501‑1194, Japan.
Division of Clinical Genetics, Gifu University Hospital, Gifu 501‑1194, Japan.
Mol Med Rep. 2016 Nov;14(5):4906-4910. doi: 10.3892/mmr.2016.5819. Epub 2016 Oct 10.
Beta-ketothiolase deficiency, also known as mitochondrial acetoacetyl-CoA thiolase (T2) deficiency, is an autosomal recessive disease caused by mutations in the acetyl‑CoA acetyltransferase 1 (ACAT1) gene. A German T2‑deficient patient that developed a severe ketoacidotic episode at the age of 11 months, was revealed to be a compound heterozygote of a previously reported null mutation, c.472A>G (p.N158D) and a novel mutation, c.949G>A (p.D317N), in ACAT1. The c.949G>A mutation was suspected to cause aberrant splicing as it is located within an exonic splicing enhancer sequence (c. 947CTGACGC) that is a potential binding site for serine/arginine‑rich splicing factor 1. A mutation in this sequence, c.951C>T, results in exon 10 skipping. A minigene construct was synthesized that included exon 9‑truncated intron 9‑exon 10‑truncated intron 10‑exon 11, and the splicing of this minigene revealed that the c.949G>A mutant construct caused exon 10 skipping in a proportion of the transcripts. Furthermore, additional substitution of G for C at the first nucleotide of exon 10 (c.941G>C) abolished the effect of the c.949G>A mutation. Transient expression analysis of the c.949G>A mutant cDNA revealed no residual T2 activity in the mutated D317N enzyme. Therefore, c.949G>A (D317N) is a pathogenic missense mutation, and diminishes the effect of an exonic splicing enhancer and causes exon 10 skipping. The present study demonstrates that a missense mutation, or even a synonymous substitution, may disrupt enzyme function by interference with splicing.
β-酮硫解酶缺乏症,也称为线粒体乙酰乙酰辅酶A硫解酶(T2)缺乏症,是一种由乙酰辅酶A乙酰转移酶1(ACAT1)基因突变引起的常染色体隐性疾病。一名11个月大时出现严重酮症酸中毒发作的德国T2缺乏症患者,被发现是ACAT1基因中一个先前报道的无效突变c.472A>G(p.N158D)和一个新突变c.949G>A(p.D317N)的复合杂合子。c.949G>A突变被怀疑导致异常剪接,因为它位于外显子剪接增强子序列(c.947CTGACGC)内,该序列是富含丝氨酸/精氨酸剪接因子1的潜在结合位点。该序列中的一个突变c.951C>T导致外显子10跳跃。合成了一个小基因构建体,其包含外显子9截短的内含子9-外显子10截短的内含子10-外显子11,该小基因的剪接显示c.949G>A突变构建体在一定比例的转录本中导致外显子10跳跃。此外,在外显子10的第一个核苷酸处将G额外替换为C(c.941G>C)消除了c.949G>A突变的影响。对c.949G>A突变cDNA的瞬时表达分析显示,突变的D317N酶中没有残留的T2活性。因此,c.949G>A(D317N)是一个致病性错义突变,并削弱了外显子剪接增强子的作用,导致外显子10跳跃。本研究表明,错义突变甚至同义替换可能通过干扰剪接来破坏酶的功能。
