Else Eising, Arianna Vino, Heather L. Mabie, Thomas F. Campbell, Lawrence D. Shriberg, Simon E. Fisher
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Thus, in the present study, we used systematic DNA sequencing methods to investigate idiopathic speech delay, as characterized by delayed speech development in the absence of a motor speech diagnosis (such as CAS), a language/reading disorder, or intellectual disability. We performed genome sequencing in a cohort of 23 children with a rigorous diagnosis of idiopathic speech delay. For roughly half of the sample (ten probands), sufficient DNA was also available for genome sequencing in both parents, allowing discovery of <i>de novo</i> variants. In the thirteen singleton probands, we focused on identifying loss-of-function and likely damaging missense variants in genes intolerant to such mutations. We found that one speech delay proband carried a pathogenic frameshift deletion in <i>SETD1A</i>, a gene previously implicated in a broader variable monogenic syndrome characterized by global developmental problems including delayed speech and/or language development, mild intellectual disability, facial dysmorphisms, and behavioural and psychiatric symptoms. Of note, pathogenic <i>SETD1A</i> variants have been independently reported in children with CAS in two separate studies. In other probands in our speech delay cohort, likely pathogenic missense variants were identified affecting highly conserved amino acids in key functional domains of <i>SPTBN1</i> and <i>ARF3</i>. Overall, this study expands the phenotype spectrum associated with pathogenic <i>SETD1A</i> variants, to also include idiopathic speech delay without CAS or intellectual disability, and suggests additional novel potential candidate genes that may harbour high-penetrance variants that can disrupt speech development.</p>","PeriodicalId":3,"journal":{"name":"ACS Applied Electronic Materials","volume":null,"pages":null},"PeriodicalIF":4.3000,"publicationDate":"2024-03-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Genome Sequencing of Idiopathic Speech Delay\",\"authors\":\"Else Eising, Arianna Vino, Heather L. Mabie, Thomas F. Campbell, Lawrence D. Shriberg, Simon E. Fisher\",\"doi\":\"10.1155/2024/9692863\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Genetic investigations of people with speech and language disorders can provide windows into key aspects of human biology. Most genomic research into impaired speech development has so far focused on childhood apraxia of speech (CAS), a rare neurodevelopmental disorder characterized by difficulties with coordinating rapid fine motor sequences that underlie proficient speech. In 2001, pathogenic variants of <i>FOXP2</i> provided the first molecular genetic accounts of CAS aetiology. Since then, disruptions in several other genes have been implicated in CAS, with a substantial proportion of cases being explained by high-penetrance variants. However, the genetic architecture underlying other speech-related disorders remains less well understood. Thus, in the present study, we used systematic DNA sequencing methods to investigate idiopathic speech delay, as characterized by delayed speech development in the absence of a motor speech diagnosis (such as CAS), a language/reading disorder, or intellectual disability. We performed genome sequencing in a cohort of 23 children with a rigorous diagnosis of idiopathic speech delay. For roughly half of the sample (ten probands), sufficient DNA was also available for genome sequencing in both parents, allowing discovery of <i>de novo</i> variants. In the thirteen singleton probands, we focused on identifying loss-of-function and likely damaging missense variants in genes intolerant to such mutations. We found that one speech delay proband carried a pathogenic frameshift deletion in <i>SETD1A</i>, a gene previously implicated in a broader variable monogenic syndrome characterized by global developmental problems including delayed speech and/or language development, mild intellectual disability, facial dysmorphisms, and behavioural and psychiatric symptoms. Of note, pathogenic <i>SETD1A</i> variants have been independently reported in children with CAS in two separate studies. 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引用次数: 0
摘要
对言语和语言障碍患者进行基因研究,可以了解人类生物学的关键方面。迄今为止,有关语言发育障碍的基因组研究大多集中在儿童语言障碍(CAS)上,这是一种罕见的神经发育障碍,其特点是难以协调作为熟练语言基础的快速精细动作序列。2001 年,FOXP2 的致病变体首次从分子遗传学角度说明了 CAS 的病因。从那时起,其他几个基因的紊乱也与 CAS 有关,其中相当一部分病例可通过高亲和力变异得到解释。然而,人们对其他言语相关疾病的遗传结构仍不甚了解。因此,在本研究中,我们采用了系统的 DNA 测序方法来研究特发性言语发育迟缓,特发性言语发育迟缓的特征是在没有运动性言语诊断(如 CAS)、语言/阅读障碍或智力障碍的情况下出现言语发育迟缓。我们对 23 名严格诊断为特发性语言发育迟缓的儿童进行了基因组测序。在大约一半的样本中(10 名疑似患者),父母双方也有足够的 DNA 用于基因组测序,从而发现了新变异。在这 13 个单胎探明者中,我们重点鉴定了不耐受此类突变的基因中的功能缺失变异和可能具有破坏性的错义变异。我们发现,一名语言发育迟缓的疑似患者携带有 SETD1A 的致病性框移缺失,该基因以前曾与一种更广泛的可变单基因综合征有关,该综合征的特征是全面发育问题,包括语言和/或语言发育迟缓、轻度智力障碍、面部畸形以及行为和精神症状。值得注意的是,在两项不同的研究中,CAS 儿童中的 SETD1A 变异已被独立报道。在我们语言发育迟缓队列中的其他受试者中,也发现了可能致病的错义变异,这些变异影响了 SPTBN1 和 ARF3 关键功能域中的高度保守氨基酸。总之,这项研究扩大了与致病性 SETD1A 变异相关的表型范围,还包括不伴有 CAS 或智力障碍的特发性语言发育迟缓,并提出了更多新的潜在候选基因,这些候选基因可能含有会干扰语言发育的高风险变异。
Genetic investigations of people with speech and language disorders can provide windows into key aspects of human biology. Most genomic research into impaired speech development has so far focused on childhood apraxia of speech (CAS), a rare neurodevelopmental disorder characterized by difficulties with coordinating rapid fine motor sequences that underlie proficient speech. In 2001, pathogenic variants of FOXP2 provided the first molecular genetic accounts of CAS aetiology. Since then, disruptions in several other genes have been implicated in CAS, with a substantial proportion of cases being explained by high-penetrance variants. However, the genetic architecture underlying other speech-related disorders remains less well understood. Thus, in the present study, we used systematic DNA sequencing methods to investigate idiopathic speech delay, as characterized by delayed speech development in the absence of a motor speech diagnosis (such as CAS), a language/reading disorder, or intellectual disability. We performed genome sequencing in a cohort of 23 children with a rigorous diagnosis of idiopathic speech delay. For roughly half of the sample (ten probands), sufficient DNA was also available for genome sequencing in both parents, allowing discovery of de novo variants. In the thirteen singleton probands, we focused on identifying loss-of-function and likely damaging missense variants in genes intolerant to such mutations. We found that one speech delay proband carried a pathogenic frameshift deletion in SETD1A, a gene previously implicated in a broader variable monogenic syndrome characterized by global developmental problems including delayed speech and/or language development, mild intellectual disability, facial dysmorphisms, and behavioural and psychiatric symptoms. Of note, pathogenic SETD1A variants have been independently reported in children with CAS in two separate studies. In other probands in our speech delay cohort, likely pathogenic missense variants were identified affecting highly conserved amino acids in key functional domains of SPTBN1 and ARF3. Overall, this study expands the phenotype spectrum associated with pathogenic SETD1A variants, to also include idiopathic speech delay without CAS or intellectual disability, and suggests additional novel potential candidate genes that may harbour high-penetrance variants that can disrupt speech development.