ME-ACP: Multi-view Neural Networks with Ensemble Model for Identification of Anticancer Peptides

Feng, Guanwen; Yao, Hang; Li, Chaoneng; Liu, Ruyi; Huang, Rungen; Fan, Xiaopeng; Ge, Ruiquan; Qi, Guangmiao

doi:10.1101/2021.11.22.469543

Cited by 2 publications

(1 citation statement)

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“…AMPfun ( Chung et al, 2020 ) and xDeep-AcPEP ( Chen J. et al, 2021 ) have Using deep learning methods to predict the multifaceted functionalities of peptides, while Alsanea et al employed ensemble techniques for ACPs prediction ( Alsanea et al, 2022 ). Advanced models like ME-ACP ( Feng et al, 2021 ) and ACP-DA ( Chen X. G. et al, 2021 ) which successfully integrated neural network architectures and data balancing techniques. Equally impressive is the approach taken by Lv et al that married the light gradient booster with deep representation learning algorithms ( Lv et al, 2021a ).…”

Section: Introductionmentioning

confidence: 99%

ACPPfel: Explainable deep ensemble learning for anticancer peptides prediction based on feature optimization

Liu,

Wu,

et al. 2024

Front. Genet.

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Background: Cancer is a significant global health problem that continues to cause a high number of deaths worldwide. Traditional cancer treatments often come with risks that can compromise the functionality of vital organs. As a potential alternative to these conventional therapies, Anticancer peptides (ACPs) have garnered attention for their small size, high specificity, and reduced toxicity, making them as a promising option for cancer treatments.Methods: However, the process of identifying effective ACPs through wet-lab screening experiments is time-consuming and requires a lot of labor. To overcome this challenge, a deep ensemble learning method is constructed to predict anticancer peptides (ACPs) in this study. To evaluate the reliability of the framework, four different datasets are used in this study for training and testing. During the training process of the model, integration of feature selection methods, feature dimensionality reduction measures, and optimization of the deep ensemble model are carried out. Finally, we explored the interpretability of features that affected the final prediction results and built a web server platform to facilitate anticancer peptides prediction, which can be used by all researchers for further studies. This web server can be accessed at http://lmylab.online:5001/.Results: The result of this study achieves an accuracy rate of 98.53% and an AUC (Area under Curve) value of 0.9972 on the ACPfel dataset, it has improvements on other datasets as well.

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