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研究生: 鄭吉峰
Cheng, Chi-Feng
論文名稱: 結合化學指紋輔助原子嵌入和自注意力模型進行蛋白質-配體交互作用預測
Combining Molecular Fingerprints and Atomic Embedding with a Self-Attention Model for Protein-Ligand Interaction Prediction
指導教授: 蔡明剛
Tsai, Ming-Kang
口試委員: 蔡明剛
Tsai, Ming-Kang
張鈞智
Chang, Chun-Chih
葉丞豪
Yeh, Chen-Hao
口試日期: 2023/07/14
學位類別: 碩士
Master
系所名稱: 化學系
Department of Chemistry
論文出版年: 2023
畢業學年度: 111
語文別: 中文
論文頁數: 72
中文關鍵詞: 深度學習CPI化學指紋Transformer
英文關鍵詞: Deep learning, CPI, Chemical fingerprint, Transformer
研究方法: 實驗設計法數據分析
DOI URL: http://doi.org/10.6345/NTNU202301683
論文種類: 學術論文
相關次數: 點閱:160下載:3
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  • 在藥物研發中,Compound Protein Interaction是一個關鍵的領域,它關注藥物與蛋白質之間的相互作用,這些作用對於藥物的活性和效果至關重要。傳統上,CPI的研究主要依賴實驗室進行的耗時耗力的試驗,但隨著機器學習的快速發展,它在CPI研究中展現了許多優勢,它可以高效地處理大規模和複雜的生物信息數據,並自動學習特徵和模式,從而加速藥物研發的進程並降低成本。
    本研究旨在改進現有的CPI機器學習模型,以提升其預測能力。原始模型主要採用了Transformer模型的自注意機制來預測CPI反應性,這種機制能夠捕捉分子和蛋白質之間的局部和全局關係。我們認為進一步引入分子的化學指紋可以增加對分子特徵的理解,從而提高模型的性能。為此我們使用了PaDEL工具生成了GPCR資料集中所有分子的化學指紋。
    通過聚類分析,我們對資料集中不同化學指紋的分布情況進行了研究。這有助於我們理解分子的結構和性質之間的相似性和差異性。接著我們將這些化學指紋先後以三種方式引入模型訓練中,試圖從中探明其有效性並找出最適合的引入方法。首先,我們將化學指紋轉換為嵌入向量,以提供更全面的信息。其次,我們嘗試將化學指紋作為附加特徵引入模型,使模型能夠更完整的使用到化學指紋。最後,我們對化學指紋的數值進行TF-IDF的操作來擴展其變異性,以便模型能夠更好地理解分子之間的不同。
    在實驗結果中,我們比較了這三種模型在CPI預測性能上的差異,並分析了它們與先前聚類分析結果之間的關係。我們觀察到引入化學指紋後,模型的預測準確性和穩定性在特定化學指紋得到了改善,並且其與聚類分析結果之間存在一定的關聯性。

    Compound Protein Interaction (CPI) is a critical field in drug development that focuses on the interactions between drugs and proteins. This plays a crucial role in determining the activity and efficacy of drugs. Traditionally, CPI research heavily relied on laborious and time-consuming experimental assays. However, the rapid advancement of machine learning has demonstrated numerous advantages in CPI research, enabling efficient processing of large-scale and complex biological data while automatically learning features and patterns. As a result, it accelerates the drug development process and reduces costs significantly.
    This study aims to improve existing CPI machine learning models to enhance their predictive capabilities. The original model primarily employed the self-attention mechanism of the Transformer model which captures both local and global relationships between molecules and proteins. We believe that further incorporating molecular chemical fingerprints can enhance the understanding of molecular features and improve model performance. To achieve this, we utilized the PaDEL tool to generate chemical fingerprints for all molecules in the GPCR dataset.
    Through cluster analysis, we investigated the distribution patterns of different chemical fingerprints within the dataset. This analysis aided our understanding of the similarities and differences in molecular structures and properties. Subsequently, we introduced these chemical fingerprints into the model training process using three different approaches, aiming to determine their effectiveness and identify the most suitable integration method. Firstly, we transformed the chemical fingerprints into embedding vectors to provide more comprehensive information. Secondly, we attempted to incorporate the chemical fingerprints as additional features to enable the model to fully utilize the information contained in the fingerprints. Lastly, we applied TF-IDF operations to the numerical values of the chemical fingerprints to expand their variations, allowing the model to better understand the differences between molecules.
    In the experimental results, we compared the performance of these three models in CPI prediction and analyzed their relationship with the previous cluster analysis results. We observed that the introduction of chemical fingerprints improved the predictive accuracy and stability of the model, particularly for specific chemical fingerprint types, and exhibited certain correlations with the cluster analysis results.

    表目錄 iv 圖目錄 v 摘要 vii Abstract viii 第一章、 緒論 1 一、 研究動機與目的 1 二、 SMILES分子表達式規範介紹 3 (一)、元素及其電荷數 3 (二)、鍵結 4 (三)、環狀結構 4 (四)、立體結構 4 三、化學指紋介紹 6 (一)、分子表示 6 (二)、特徵提取 6 (三)、特徵編碼 6 (四)、指紋存儲和比對 7 四、 PaDEL介紹 8 五、 深度學習(Deep Learning)介紹 9 (一)、機器學習概述 9 (二)、深度學習概述 9 (三)、深度學習方法介紹 10 六、 Transformer及self-attention簡介 14 第二章、 研究方法 19 一、GPCR資料集 19 (一)、何為GPCR 19 (二)、GLASS資料庫的介紹 19 (三)、GPCR訓練資料集的建構 20 二、 TransformerCPI模型架構 22 (一)、蛋白質序列轉換區塊 22 (二)、配體分子資訊處理區塊 24 (三)、交互作用區塊 25 (四)、活性預測區塊 26 三、 原始模型的優化及測試 28 四、化學指紋的生成 29 (一)、CDK fingerprint 29 (二)、CDK extended fingerprint 29 (三)、Estate fingerprint 30 (四)、CDK graph only fingerprint 30 (五)、MACCS fingerprint 30 (六)、Pubchem fingerprint 30 (七)、Substructure fingerprint 30 (八)、Substructure fingerprint count 30 (九)、Klekota-Roth fingerprint 31 (十)、Klekota-Roth fingerprint count 31 (十一)、2D atom pairs 31 (十二)、2D atom pairs count 31 五、化學指紋嵌入層置入方法 32 (一)、化學指紋嵌入式跨注意力模型 32 (二)、化學指紋線性層跨注意力模型 33 (三)、化學指紋TF-IDF加權跨注意力模型 34 第三章、 研究結果 36 一、原模型訓練測試結果 36 二、化學指紋數值分析 40 (一)、inertia score 41 (二)、silhouette score 43 三、化學指紋加入模型訓練結果 45 (一)、化學指紋嵌入式跨注意力模型 45 (二)、化學指紋線性層跨注意力模型 48 (三)、化學指紋TF-IDF加權跨注意力模型 51 第四章、 結論 54 第五章、 參考文獻 56 第六章、 附錄 61

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