Department of Molecular and Cellular Physiology, Stanford Institute for Neuro-Innovation and Translational Neurosciences, Stanford University School of Medicine, Stanford, CA 94305-5345, USA.
Proc Natl Acad Sci U S A. 2011 Sep 13;108(37):15432-7. doi: 10.1073/pnas.1112667108. Epub 2011 Aug 30.
Autism and autism spectrum disorder (ASD) typically arise from a mixture of environmental influences and multiple genetic alterations. In some rare cases, such as Timothy syndrome (TS), a specific mutation in a single gene can be sufficient to generate autism or ASD in most patients, potentially offering insights into the etiology of autism in general. Both variants of TS (the milder TS1 and the more severe TS2) arise from missense mutations in alternatively spliced exons that cause the same G406R replacement in the Ca(V)1.2 L-type calcium channel. We generated a TS2-like mouse but found that heterozygous (and homozygous) animals were not viable. However, heterozygous TS2 mice that were allowed to keep an inverted neomycin cassette (TS2-neo) survived through adulthood. We attribute the survival to lowering of expression of the G406R L-type channel via transcriptional interference, blunting deleterious effects of mutant L-type channel overactivity, and addressed potential effects of altered gene dosage by studying Ca(V)1.2 knockout heterozygotes. Here we present a thorough behavioral phenotyping of the TS2-neo mouse, capitalizing on this unique opportunity to use the TS mutation to model ASD in mice. Along with normal general health, activity, and anxiety level, TS2-neo mice showed markedly restricted, repetitive, and perseverative behavior, altered social behavior, altered ultrasonic vocalization, and enhanced tone-cued and contextual memory following fear conditioning. Our results suggest that when TS mutant channels are expressed at levels low enough to avoid fatality, they are sufficient to cause multiple, distinct behavioral abnormalities, in line with the core aspects of ASD.
自闭症和自闭症谱系障碍(ASD)通常源于环境影响和多种基因突变的混合作用。在某些罕见情况下,如 Timothy 综合征(TS),单一基因的特定突变就足以在大多数患者中引发自闭症或 ASD,这可能为自闭症的病因提供了一般的见解。两种 TS 变体(较轻的 TS1 和更严重的 TS2)都源于可变剪接外显子中的错义突变,导致 Ca(V)1.2 L 型钙通道中的相同 G406R 取代。我们产生了一种类似于 TS2 的小鼠,但发现杂合子(和纯合子)动物不能存活。然而,允许保留倒置新霉素盒(TS2-neo)的杂合子 TS2 小鼠可以存活到成年。我们将这种存活归因于通过转录干扰降低 G406R L 型通道的表达,减轻突变 L 型通道过度活跃的有害影响,并通过研究 Ca(V)1.2 敲除杂合子来解决基因剂量改变的潜在影响。在这里,我们对 TS2-neo 小鼠进行了全面的行为表型分析,利用这种独特的机会,利用 TS 突变在小鼠中模拟 ASD。除了正常的一般健康、活动和焦虑水平外,TS2-neo 小鼠还表现出明显的受限、重复和坚持性行为、改变的社交行为、改变的超声发声以及在恐惧条件反射后增强的音调提示和上下文记忆。我们的结果表明,当 TS 突变通道的表达水平低到足以避免致命性时,它们足以引起多种不同的行为异常,与 ASD 的核心方面一致。