Construction of transcript regulation mechanism prediction models based on binding motif environment of transcription factor AoXlnR in Aspergillus oryzae.
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引用次数: 0
Abstract
DNA-binding transcription factors (TFs) play a central role in transcriptional regulation mechanisms, mainly through their specific binding to target sites on the genome and regulation of the expression of downstream genes. Therefore, a comprehensive analysis of the function of these TFs will lead to the understanding of various biological mechanisms. However, the functions of TFs in vivo are diverse and complicated, and the identified binding sites on the genome are not necessarily involved in the regulation of downstream gene expression. In this study, we investigated whether DNA structural information around the binding site of TFs can be used to predict the involvement of the binding site in the regulation of the expression of genes located downstream of the binding site. Specifically, we calculated the structural parameters based on the DNA shape around the DNA binding motif located upstream of the gene whose expression is directly regulated by one TF AoXlnR from Aspergillus oryzae, and showed that the presence or absence of expression regulation can be predicted from the sequence information with high accuracy ([Formula: see text]-1.0) by machine learning incorporating these parameters.
DNA 结合型转录因子(TFs)在转录调控机制中发挥着核心作用,主要是通过与基因组上的靶位点特异性结合,调控下游基因的表达。因此,全面分析这些转录因子的功能将有助于了解各种生物学机制。然而,TFs 在体内的功能是多样而复杂的,而且在基因组上确定的结合位点并不一定参与下游基因的表达调控。在本研究中,我们探讨了能否利用 TFs 结合位点周围的 DNA 结构信息来预测结合位点是否参与调控位于结合位点下游的基因的表达。具体来说,我们根据位于基因上游、其表达受一种来自黑曲霉的 TF AoXlnR 直接调控的 DNA 结合位点周围的 DNA 形状计算了结构参数,结果表明,通过机器学习结合这些参数,可以从序列信息预测表达调控的存在与否,准确率很高([公式:见正文]-1.0)。
期刊介绍:
The Journal of Bioinformatics and Computational Biology aims to publish high quality, original research articles, expository tutorial papers and review papers as well as short, critical comments on technical issues associated with the analysis of cellular information.
The research papers will be technical presentations of new assertions, discoveries and tools, intended for a narrower specialist community. The tutorials, reviews and critical commentary will be targeted at a broader readership of biologists who are interested in using computers but are not knowledgeable about scientific computing, and equally, computer scientists who have an interest in biology but are not familiar with current thrusts nor the language of biology. Such carefully chosen tutorials and articles should greatly accelerate the rate of entry of these new creative scientists into the field.