Defining the genetic architecture of human developmental language impairment
- 作者:Ning Lia ; Christopher W. Bartletta ; b ; Christopher.Bartlett@nationwidechildrens.org
- 关键词:Language ; Specific language impairment ; Genetic linkage ; Association ; Reading ; Dyslexia
- 刊名:Life Sciences
- 出版年:2012
- 期刊代码:62_00243205
- 类别:imm
- 出版时间:9 April, 2012
- 卷:90
- 期:13-14
- 页码:469-475
- 文件大小:323 K
摘要
Language is a uniquely human trait, which poses limitations on animal models for discovering biological substrates and pathways. Despite this challenge, rapidly developing biotechnology in the field of genomics has made human genetics studies a viable alternative route for defining the molecular neuroscience of human language. This is accomplished by studying families that transmit both normal and disordered language across generations. The language disorder reviewed here is specific language impairment (SLI), a developmental deficiency in language acquisition despite adequate opportunity, normal intelligence, and without any apparent neurological etiology. Here, we describe disease gene discovery paradigms as applied to SLI families and review the progress this field has made. After review the evidence that genetic factors influence SLI, we discuss methods and findings from scans of the human chromosomes, including the main replicated regions on chromosomes 13, 16 and 19 and two identified genes, ATP2C2 and CMIP that appear to account for the language variation on chromosome 16. Additional work has been done on candidate genes, i.e., genes chosen a priori and not through a genome scanning studies, including several studies of CNTNAP2 and some recent work implicating BDNF as a gene x gene interaction partner of genetic variation on chromosome 13 that influences language. These recent developments may allow for better use of post-mortem human brain samples functional studies and animal models for circumscribed language subcomponents. In the future, the identification of genetic variation associated with language phenotypes will provide the molecular pathways to understanding human language.