使用并行独立成分分析揭示精神障碍中的新型基因-脑结构关系。
Novel gene-brain structure relationships in psychotic disorder revealed using parallel independent component analyses.
作者信息
Tandon Neeraj, Nanda Pranav, Padmanabhan Jaya L, Mathew Ian T, Eack Shaun M, Narayanan Balaji, Meda Shashwath A, Bergen Sarah E, Ruaño Gualbert, Windemuth Andreas, Kocherla Mohan, Petryshen Tracey L, Clementz Brett, Sweeney John, Tamminga Carol, Pearlson Godfrey, Keshavan Matcheri S
机构信息
Psychiatry, Harvard Medical School, Beth Israel Deaconess Medical Ctr, Boston, MA, USA; Baylor College of Medicine, Texas Medical Center, Houston, TX, USA.
Psychiatry, Harvard Medical School, Beth Israel Deaconess Medical Ctr, Boston, MA, USA; College of Physicians & Surgeons, Columbia University Medical Center, New York, NY, USA.
出版信息
Schizophr Res. 2017 Apr;182:74-83. doi: 10.1016/j.schres.2016.10.026. Epub 2016 Oct 24.
BACKGROUND
Schizophrenia, schizoaffective disorder, and psychotic bipolar disorder overlap with regard to symptoms, structural and functional brain abnormalities, and genetic risk factors. Neurobiological pathways connecting genes to clinical phenotypes across the spectrum from schizophrenia to psychotic bipolar disorder remain largely unknown.
METHODS
We examined the relationship between structural brain changes and risk alleles across the psychosis spectrum in the multi-site Bipolar-Schizophrenia Network for Intermediate Phenotypes (B-SNIP) cohort. Regional MRI brain volumes were examined in 389 subjects with a psychotic disorder (139 schizophrenia, 90 schizoaffective disorder, and 160 psychotic bipolar disorder) and 123 healthy controls. 451,701 single-nucleotide polymorphisms were screened and processed using parallel independent component analysis (para-ICA) to assess associations between genes and structural brain abnormalities in probands.
RESULTS
482 subjects were included after quality control (364 individuals with psychotic disorder and 118 healthy controls). Para-ICA identified four genetic components including several risk genes already known to contribute to schizophrenia and bipolar disorder and revealed three structural components that showed overlapping relationships with the disease risk genes across the three psychotic disorders. Functional ontologies representing these gene clusters included physiological pathways involved in brain development, synaptic transmission, and ion channel activity.
CONCLUSIONS
Heritable brain structural findings such as reduced cortical thickness and surface area in probands across the psychosis spectrum were associated with somewhat distinct genes related to putative disease pathways implicated in psychotic disorders. This suggests that brain structural alterations might represent discrete psychosis intermediate phenotypes along common neurobiological pathways underlying disease expression across the psychosis spectrum.
背景
精神分裂症、分裂情感性障碍和伴有精神病性症状的双相情感障碍在症状、脑结构和功能异常以及遗传风险因素方面存在重叠。从精神分裂症到伴有精神病性症状的双相情感障碍这一谱系中,连接基因与临床表型的神经生物学途径仍 largely unknown。
方法
我们在多中心双相 - 精神分裂症中间表型网络(B - SNIP)队列中研究了整个精神病谱系中脑结构变化与风险等位基因之间的关系。对389名患有精神病性障碍的受试者(139名精神分裂症患者、90名分裂情感性障碍患者和160名伴有精神病性症状的双相情感障碍患者)和123名健康对照进行了脑部MRI区域体积检查。使用并行独立成分分析(para - ICA)筛选并处理了451,701个单核苷酸多态性,以评估先证者中基因与脑结构异常之间的关联。
结果
经过质量控制后纳入了482名受试者(364名患有精神病性障碍的个体和118名健康对照)。Para - ICA确定了四个遗传成分,包括几个已知与精神分裂症和双相情感障碍有关的风险基因,并揭示了三个结构成分,它们在三种精神病性障碍中与疾病风险基因呈现重叠关系。代表这些基因簇的功能本体包括参与脑发育、突触传递和离子通道活性的生理途径。
结论
在整个精神病谱系的先证者中,诸如皮质厚度和表面积减少等可遗传的脑结构发现与一些与精神病性障碍中假定疾病途径相关的不同基因有关。这表明脑结构改变可能代表了整个精神病谱系中疾病表达潜在的共同神经生物学途径上离散的精神病中间表型。
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