高通量转录组测序鉴定胎儿酒精谱系障碍易感性的候选基因修饰因子。
High-throughput transcriptome sequencing identifies candidate genetic modifiers of vulnerability to fetal alcohol spectrum disorders.
作者信息
Garic Ana, Berres Mark E, Smith Susan M
机构信息
Departments of Nutritional Sciences and Animal Sciences, University of Wisconsin-Madison, Madison, Wisconsin.
出版信息
Alcohol Clin Exp Res. 2014 Jul;38(7):1874-82. doi: 10.1111/acer.12457. Epub 2014 Jun 24.
BACKGROUND
Fetal alcohol spectrum disorders (FASD) is a leading cause of neurodevelopmental disability. Genetic factors can modify vulnerability to FASD, but these elements are poorly characterized.
METHODS
We performed high-throughput transcriptional profiling to identify gene candidates that could potentially modify vulnerability to ethanol's (EtOH's) neurotoxicity. We interrogated a unique genetic resource, neuroprogenitor cells from 2 closely related Gallus gallus lines having well-characterized robust or attenuated EtOH responses with respect to intracellular calcium mobilization and CaMKII/β-catenin-dependent apoptosis. Samples were not exposed to EtOH prior to analysis.
RESULTS
We identified 363 differentially expressed genes in neuroprogenitors from these 2 lines. Kyoto Encyclopedia of Genes and Genomes analysis revealed several gene clusters having significantly differential enrichment in gene expression. The largest and most significant cluster comprised ribosomal proteins (38 genes, p = 1.85 × 10(-47) ). Other significantly enriched gene clusters included metabolism (25 genes, p = 0.0098), oxidative phosphorylation (18 genes, p = 1.10 × 10(-11) ), spliceosome (13 genes, p = 7.02 × 10(-8) ), and protein processing in the endoplasmic reticulum (9 genes, p = 0.0011). Inspection of gene ontogeny (GO) terms identified 24 genes involved in the calcium/β-catenin signals that mediate EtOH's neurotoxicity in this model, including β-catenin itself and both calmodulin isoforms.
CONCLUSIONS
Four of the identified pathways with altered transcript abundance mediate the flow of cellular information from RNA to protein. Importantly, ribosome biogenesis also senses nucleolar stress and regulates p53-mediated apoptosis in neural crest. Human ribosomopathies produce craniofacial malformations and 11 known ribosomopathy genes were differentially expressed in this model of neural crest apoptosis. Rapid changes in ribosome expression are consistently observed in EtOH-treated mouse embryo neural folds, a model that is developmentally similar to ours. The recurring identification of ribosome biogenesis suggests it is a candidate modifier of EtOH vulnerability. These results highlight this approach's efficacy to formulate new, mechanistic hypotheses regarding EtOH's developmental damage.
背景
胎儿酒精谱系障碍(FASD)是神经发育障碍的主要原因。遗传因素可改变对FASD的易感性,但这些因素的特征尚不明确。
方法
我们进行了高通量转录谱分析,以确定可能改变对乙醇(EtOH)神经毒性易感性的候选基因。我们研究了一种独特的遗传资源,即来自两个密切相关的原鸡品系的神经祖细胞,这两个品系在细胞内钙动员和CaMKII/β-连环蛋白依赖性凋亡方面具有明确的强烈或减弱的EtOH反应。在分析之前,样本未暴露于EtOH。
结果
我们在这两个品系的神经祖细胞中鉴定出363个差异表达基因。京都基因与基因组百科全书分析显示,几个基因簇在基因表达上有显著的差异富集。最大且最显著的簇包含核糖体蛋白(38个基因,p = 1.85×10⁻⁴⁷)。其他显著富集的基因簇包括代谢(25个基因,p = 0.0098)、氧化磷酸化(18个基因,p = 1.10×10⁻¹¹)、剪接体(13个基因,p = 7.02×10⁻⁸)和内质网中的蛋白质加工(9个基因,p = 0.0011)。对基因本体论(GO)术语的检查确定了24个参与钙/β-连环蛋白信号传导的基因,这些信号在该模型中介导EtOH的神经毒性,包括β-连环蛋白本身和两种钙调蛋白异构体。
结论
所鉴定的四个转录丰度改变的途径介导了从RNA到蛋白质的细胞信息流动。重要的是,核糖体生物发生也能感知核仁应激并调节神经嵴中p53介导的凋亡。人类核糖体病会导致颅面畸形,并且11个已知的核糖体病基因在这个神经嵴凋亡模型中差异表达。在EtOH处理的小鼠胚胎神经褶中始终观察到核糖体表达的快速变化,该模型在发育上与我们的模型相似。核糖体生物发生的反复鉴定表明它是EtOH易感性的候选修饰因子。这些结果突出了这种方法在制定关于EtOH发育损伤的新的机制假说方面的有效性。
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