Prediction of LncRNA-protein Interactions Using Auto-Encoder, SE-ResNet Models and Transfer Learning.

MicroRNA Pub Date : 2024-04-08 DOI:10.2174/0122115366288068240322064431

Huiwen Jiang, Song Kai

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Abstract

BACKGROUND Long non-coding RNA (lncRNA) plays a crucial role in various biolog-ical processes, and mutations or imbalances of lncRNAs can lead to several diseases, including cancer, Prader-Willi syndrome, autism, Alzheimer's disease, cartilage-hair hypoplasia, and hear-ing loss. Understanding lncRNA-protein interactions (LPIs) is vital for elucidating basic cellular processes, human diseases, viral replication, transcription, and plant pathogen resistance. Despite the development of several LPI calculation methods, predicting LPI remains challenging, with the selection of variables and deep learning structure being the focus of LPI research. METHODS We propose a deep learning framework called AR-LPI, which extracts sequence and secondary structure features of proteins and lncRNAs. The framework utilizes an auto-encoder for feature extraction and employs SE-ResNet for prediction. Additionally, we apply transfer learning to the deep neural network SE-ResNet for predicting small-sample datasets. RESULTS Through comprehensive experimental comparison, we demonstrate that the AR-LPI ar-chitecture performs better in LPI prediction. Specifically, the accuracy of AR-LPI increases by 2.86% to 94.52%, while the F-value of AR-LPI increases by 2.71% to 94.73%. CONCLUSION Our experimental results show that the overall performance of AR-LPI is better than that of other LPI prediction tools.

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利用自动编码器、SE-ResNet 模型和迁移学习预测 LncRNA 与蛋白质的相互作用

背景长非编码 RNA（lncRNA）在各种生物医学过程中发挥着至关重要的作用，lncRNA 的突变或失衡可导致多种疾病，包括癌症、普拉德-威利综合征、自闭症、阿尔茨海默病、软骨-毛发发育不全和听力损失。了解 lncRNA 与蛋白质的相互作用（LPIs）对于阐明基本细胞过程、人类疾病、病毒复制、转录和植物病原体抗性至关重要。尽管开发出了多种LPI计算方法，但预测LPI仍然具有挑战性，变量的选择和深度学习结构是LPI研究的重点。方法我们提出了一种名为AR-LPI的深度学习框架，它可以提取蛋白质和lncRNA的序列和二级结构特征。该框架利用自动编码器进行特征提取，并采用 SE-ResNet 进行预测。此外，我们还将迁移学习应用于深度神经网络 SE-ResNet，以预测小样本数据集。结果通过全面的实验对比，我们证明 AR-LPI 架构在 LPI 预测中表现更佳。具体来说，AR-LPI 的准确率提高了 2.86%，达到 94.52%，F 值提高了 2.71%，达到 94.73%。

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MicroRNA

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Characteristics of HIF-1Α and HSP70 MRNA Expression, Level, and Inter-leukins in Experimental Chronic Generalized Periodontitis. Prediction of LncRNA-protein Interactions Using Auto-Encoder, SE-ResNet Models and Transfer Learning. Role of miRNAs in Brain Development. MicroRNA and Cancer: A Path to Discovery Acknowledgements to Reviewers