Krochmalnek Eric, Accogli Andrea, St-Onge Judith, Addour-Boudrahem Nassima, Prakash Gyan, Kim Sung-Hoon, Brunette-Clement Tristan, Alhajaj Ghadd, Mougharbel Lina, Bruneau Elena, Myers Kenneth A, Dubeau Francois, Karamchandani Jason, Farmer Jean-Pierre, Atkinson Jeffrey, Hall Jeffrey, Chantal Poulin Chantal, Rosenblatt Bernard, Lafond-Lapalme Joel, Weil Alexander, Fallet-Bianco Catherine, Albrecht Steffen, Sonenberg Nahum, Riviere Jean-Baptiste, Dudley Roy W, Srour Myriam
From the Research Institute of the McGill University Health Centre (E.K., J.S.-O., N.A.-B., L.M., E.B., K.A.M., J.L.-L., J.-B.R., R.W.D., M.S.); Integrated Program in Neuroscience (E.K.), McGill University; Department of Specialized Medicine (A.A.), McGill University Health Centre; Department of Human Genetics (A.A., J.-B.R.), Faculty of Medicine; Goodman Cancer Centre (G.P., S.-H.K., N.S.), Department of Biochemistry, McGill University; Department of Pediatric Neurosurgery (T.B.-C., A.W.), Centre Hospitalier Universitaire Sainte-Justine, University of Montreal; Division of Pediatric Neurology (G.A., K.A.M., C.C.P., M.S.), Department of Pediatrics, McGill University, Montreal, Quebec, Canada; Department of Pediatrics (G.A.), Unaizah College of Medicine and Medical Sciences, Qassim University, Saudi Arabia; Department of Neurology and Neurosurgery (K.A.M., F.D., J.H., C.C.P., M.S.), McGill University Health Centre; Department of Pathology (J.K., S.A.), McGill University; Division of Neurosurgery (J.-P.F., J.A., R.W.D.), Department of Pediatric Surgery, McGill University Health Center; McGill University (B.R.); Department of Pathology (C.F.-B.), Centre Hospitalier Universitaire Sainte-Justine, University of Montreal, Quebec, Canada.
Neurol Genet. 2023 Oct 26;9(6):e200103. doi: 10.1212/NXG.0000000000200103. eCollection 2023 Dec.
Somatic and germline pathogenic variants in genes of the mammalian target of rapamycin (mTOR) signaling pathway are a common mechanism underlying a subset of focal malformations of cortical development (FMCDs) referred to as mTORopathies, which include focal cortical dysplasia (FCD) type II, subtypes of polymicrogyria, and hemimegalencephaly. Our objective is to screen resected FMCD specimens with mTORopathy features on histology for causal somatic variants in mTOR pathway genes, describe novel pathogenic variants, and examine the variant distribution in relation to neuroimaging, histopathologic classification, and clinical outcomes.
We performed ultra-deep sequencing using a custom HaloPlex Target Enrichment kit in DNA from 21 resected fresh-frozen histologically confirmed FCD type II, tuberous sclerosis complex, or hemimegalencephaly specimens. We mapped the variant alternative allele frequency (AAF) across the resected brain using targeted ultra-deep sequencing in multiple formalin-fixed paraffin-embedded tissue blocks. We also functionally validated 2 candidate somatic variants and performed targeted RNA sequencing to validate a splicing defect associated with a novel variant.
We identified causal mTOR pathway gene variants in 66.7% (14/21) of patients, of which 13 were somatic with AAF ranging between 0.6% and 12.0%. Moreover, the AAF did not predict balloon cell presence. Favorable seizure outcomes were associated with genetically clear resection borders. Individuals in whom a causal somatic variant was undetected had excellent postsurgical outcomes. In addition, we demonstrate pathogenicity of the novel c.4373_4375dupATG and candidate c.7499T>A variants in vitro. We also identified a novel germline aberrant splice site variant in (c.2802-1G>C).
The AAF of somatic pathogenic variants correlated with the topographic distribution, histopathology, and postsurgical outcomes. Moreover, cortical regions with absent histologic FCD features had negligible or undetectable pathogenic variant loads. By contrast, specimens with frank histologic abnormalities had detectable pathogenic variant loads, which raises important questions as to whether there is a tolerable variant threshold and whether surgical margins should be clean, as performed in tumor resections. In addition, we describe 2 novel pathogenic variants, expanding the mTORopathy genetic spectrum. Although most pathogenic somatic variants are located at mutation hotspots, screening the full-coding gene sequence remains necessary in a subset of patients.
哺乳动物雷帕霉素靶蛋白(mTOR)信号通路基因中的体细胞和生殖系致病变异是一组称为mTOR病的皮质发育局灶性畸形(FMCDs)的常见潜在机制,其中包括II型局灶性皮质发育不良(FCD)、多小脑回亚型和半侧巨脑畸形。我们的目的是对组织学上具有mTOR病特征的切除的FMCD标本进行筛查,以寻找mTOR通路基因中的因果体细胞变异,描述新的致病变异,并研究变异分布与神经影像学、组织病理学分类和临床结果的关系。
我们使用定制的HaloPlex靶向富集试剂盒对21例切除的新鲜冷冻、组织学确诊的II型FCD、结节性硬化症或半侧巨脑畸形标本的DNA进行了超深度测序。我们在多个福尔马林固定石蜡包埋组织块中使用靶向超深度测序绘制了切除脑内变异替代等位基因频率(AAF)图。我们还对2个候选体细胞变异进行了功能验证,并进行了靶向RNA测序以验证与一个新变异相关的剪接缺陷。
我们在66.7%(14/21)的患者中鉴定出因果性mTOR通路基因变异,其中13个是体细胞变异,AAF在0.6%至12.0%之间。此外,AAF不能预测气球样细胞的存在。良好的癫痫发作结果与基因上明确的切除边界相关。未检测到因果体细胞变异的个体术后结果良好。此外,我们在体外证明了新的c.4373_4375dupATG和候选c.7499T>A变异的致病性。我们还在(c.2802-1G>C)中鉴定出一个新的生殖系异常剪接位点变异。
体细胞致病变异的AAF与地形分布、组织病理学和术后结果相关。此外,组织学上无FCD特征的皮质区域的致病变异负荷可忽略不计或无法检测到。相比之下,具有明显组织学异常的标本具有可检测到的致病变异负荷,这就提出了一个重要问题,即是否存在一个可耐受的变异阈值,以及手术切缘是否应该像肿瘤切除那样干净。此外,我们描述了2个新的致病变异,扩展了mTOR病的遗传谱。尽管大多数致病变体细胞变异位于突变热点,但对一部分患者进行完整编码基因序列的筛查仍然是必要的。
