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NADPHnet: a novel strategy to predict compounds for regulation of NADPH metabolism via network-based methods

Fei Pan1, Cheng-nuo Wang1, Zhuo-hang Yu1, Zeng-rui Wu1, Ze Wang1, Shang Lou1, Wei-hua Li1, Gui-xia Liu1, Ting Li1, Yu-zheng Zhao1, Yun Tang1
1 Shanghai Frontiers Science Center of Optogenetic Techniques for Cell Metabolism, Shanghai Key Laboratory of New Drug Design, School of Pharmacy, East China University of Science and Technology, Shanghai 200237, China
Correspondence to: Ting Li: tingli@ecust.edu.cn, Yun Tang: ytang234@ecust.edu.cn,
DOI: 10.1038/s41401-024-01324-6
Received: 18 January 2024
Accepted: 26 May 2024
Advance online: 20 June 2024

Abstract

Identification of compounds to modulate NADPH metabolism is crucial for understanding complex diseases and developing effective therapies. However, the complex nature of NADPH metabolism poses challenges in achieving this goal. In this study, we proposed a novel strategy named NADPHnet to predict key proteins and drug-target interactions related to NADPH metabolism via network-based methods. Different from traditional approaches only focusing on one single protein, NADPHnet could screen compounds to modulate NADPH metabolism from a comprehensive view. Specifically, NADPHnet identified key proteins involved in regulation of NADPH metabolism using network-based methods, and characterized the impact of natural products on NADPH metabolism using a combined score, NADPH-Score. NADPHnet demonstrated a broader applicability domain and improved accuracy in the external validation set. This approach was further employed along with molecular docking to identify 27 compounds from a natural product library, 6 of which exhibited concentration-dependent changes of cellular NADPH level within 100 μM, with Oxyberberine showing promising effects even at 10 μM. Mechanistic and pathological analyses of Oxyberberine suggest potential novel mechanisms to affect diabetes and cancer. Overall, NADPHnet offers a promising method for prediction of NADPH metabolism modulation and advances drug discovery for complex diseases.
Keywords: NADPH metabolism; network-based inference; natural product; computational prediction

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