IGF, CNRS, INSERM, University of Montpellier, Montpellier, France.
LabEx 'Ion Channel Science and Therapeutics', Montpellier, France.
Brain. 2018 Jul 1;141(7):1998-2013. doi: 10.1093/brain/awy145.
Cerebellar atrophy is a key neuroradiological finding usually associated with cerebellar ataxia and cognitive development defect in children. Unlike the adult forms, early onset cerebellar atrophies are classically described as mostly autosomal recessive conditions and the exact contribution of de novo mutations to this phenotype has not been assessed. In contrast, recent studies pinpoint the high prevalence of pathogenic de novo mutations in other developmental disorders such as intellectual disability, autism spectrum disorders and epilepsy. Here, we investigated a cohort of 47 patients with early onset cerebellar atrophy and/or hypoplasia using a custom gene panel as well as whole exome sequencing. De novo mutations were identified in 35% of patients while 27% had mutations inherited in an autosomal recessive manner. Understanding if these de novo events act through a loss or a gain of function effect is critical for treatment considerations. To gain a better insight into the disease mechanisms causing these cerebellar defects, we focused on CACNA1G, a gene not yet associated with the early-onset form. This gene encodes the Cav3.1 subunit of T-type calcium channels highly expressed in Purkinje neurons and deep cerebellar nuclei. We identified four patients with de novo CACNA1G mutations. They all display severe motor and cognitive impairment, cerebellar atrophy as well as variable features such as facial dysmorphisms, digital anomalies, microcephaly and epilepsy. Three subjects share a recurrent c.2881G>A/p.Ala961Thr variant while the fourth patient has the c.4591A>G/p.Met1531Val variant. Both mutations drastically impaired channel inactivation properties with significantly slower kinetics (∼5 times) and negatively shifted potential for half-inactivation (>10 mV). In addition, these two mutations increase neuronal firing in a cerebellar nuclear neuron model and promote a larger window current fully inhibited by TTA-P2, a selective T-type channel blocker. This study highlights the prevalence of de novo mutations in early-onset cerebellar atrophy and demonstrates that A961T and M1531V are gain of function mutations. Moreover, it reveals that aberrant activity of Cav3.1 channels can markedly alter brain development and suggests that this condition could be amenable to treatment.
小脑萎缩是一种关键的神经影像学发现,通常与儿童的小脑性共济失调和认知发育缺陷有关。与成人形式不同,早发性小脑萎缩经典地被描述为主要为常染色体隐性疾病,并且新出现的突变对这种表型的确切贡献尚未评估。相比之下,最近的研究指出,在其他发育障碍(如智力障碍、自闭症谱系障碍和癫痫)中,新出现的致病性突变的高发率。在这里,我们使用定制基因面板和全外显子组测序研究了 47 名早发性小脑萎缩和/或发育不良患者的队列。在 35%的患者中发现了新出现的突变,而 27%的患者则继承了常染色体隐性方式的突变。了解这些新出现的事件是否通过功能丧失或获得效应起作用对于治疗考虑至关重要。为了更好地了解导致这些小脑缺陷的疾病机制,我们专注于 CACNA1G,这是一个尚未与早发性疾病相关的基因。该基因编码 T 型钙通道的 Cav3.1 亚基,在浦肯野神经元和小脑深部核团中高度表达。我们鉴定了 4 名具有新出现 CACNA1G 突变的患者。他们均表现出严重的运动和认知障碍、小脑萎缩以及面部畸形、数字异常、小头症和癫痫等可变特征。三个受试者共享一个反复出现的 c.2881G>A/p.Ala961Thr 变异,而第四个患者具有 c.4591A>G/p.Met1531Val 变异。这两种突变均极大地损害了通道失活特性,具有明显较慢的动力学(约 5 倍)和潜在的半失活电位负移(>10 mV)。此外,这两种突变增加了小脑核神经元模型中的神经元放电,并促进了被选择性 T 型通道阻滞剂 TTA-P2 完全抑制的更大窗口电流。本研究强调了早发性小脑萎缩中新出现的突变的普遍性,并证明 A961T 和 M1531V 是功能获得性突变。此外,它表明 Cav3.1 通道的异常活动可显著改变大脑发育,并表明该病症可能适合治疗。
