Deep Learning-based Identification of DNA-N4 Methylcytosine Modification Sites

Xiaolong Wu
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Abstract

DNA modification is closely related to the expression genetics of many organisms, therefore, the prediction of DNA modification sites is particularly important. In this paper, we use deep learning techniques to identify and predict DNA N4-methylcytosine modification sites, and the main work is as follows. Feature encoding using k-spacer nucleic acids to encode a 41 bp long DNA sequence as a (41×9) dimensional vector. Recognition prediction based on multi-headed attention mechanism and GRU neural network. Firstly, the encoded data are extracted and downscaled; secondly, the importance distribution of 4mc loci and each nucleotide in the sequence are further extracted adaptively using the multi-headed attention mechanism; then the GRU network is used to capture the long dependencies in the whole importance distribution; finally, a new prediction model of 4mc loci is constructed using two fully connected layers, and its recognition accuracy is significantly improved compared with other basic machine learning models. The recognition accuracy is improved compared with other basic machine learning models.
基于深度学习的DNA-N4甲基胞嘧啶修饰位点鉴定
DNA修饰与许多生物体的表达遗传学密切相关,因此,DNA修饰位点的预测就显得尤为重要。本文利用深度学习技术对DNA n4 -甲基胞嘧啶修饰位点进行识别和预测,主要工作如下:特征编码使用k间隔核酸编码41 bp长的DNA序列作为(41×9)维向量。基于多头注意机制和GRU神经网络的识别预测。首先对编码后的数据进行提取和降尺度处理;其次,利用多头注意机制进一步自适应提取4mc位点和序列中每个核苷酸的重要性分布;然后利用GRU网络捕获整个重要分布中的长依赖关系;最后,利用两个完全连接层构建了一个新的4mc位点预测模型,与其他基本机器学习模型相比,其识别精度显著提高。与其他基本机器学习模型相比,该模型的识别精度得到了提高。
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