DeeplyEssential: a deep neural network for predicting essential genes in microbes

Hasan, Abid; Lonardi, Stefano

doi:10.1186/s12859-020-03688-y

Cited by 20 publications

(19 citation statements)

References 46 publications

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“…Based on the availability of labeled data of essential genes, researchers have employed supervised machine learning strategies [6][7][8] as well as deep learning-based strategies to predict essential genes [24,25]. The key advantage of these strategies lies in the fact that these models are capable of capturing the inherent patterns of a large array of biologically relevant 'features' that are distinctive and reflect the heterogeneous properties of essential genes.…”

Section: Introductionmentioning

confidence: 99%

“…Supervised machine learning classifiers such as logistic regression [ 26 , 27 ], support vector machine [ 28 – 31 ], random forest [ 32 ], decision tree [ 26 ], ensemble [ 26 ] and probabilistic Bayesian-based methods [ 26 , 27 , 33 ] and instance-based learning methods such as K Nearest neighbor (K-NN) and Weighted KNN (WKNN) [ 34 ] have been used for gene essentiality prediction. Deep Learning strategies based on multilayer perceptron networks have also been used for essential gene prediction [ 24 , 35 ]. In these studies, researchers have mostly opted for simpler optimization methods for parameter tuning, such as the grid search technique, where the entire parameter space is explored in all possible combinations.…”

Section: Introductionmentioning

confidence: 99%

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Essential gene prediction using limited gene essentiality information–An integrative semi-supervised machine learning strategy

2020

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Essential gene prediction helps to find minimal genes indispensable for the survival of any organism. Machine learning (ML) algorithms have been useful for the prediction of gene essentiality. However, currently available ML pipelines perform poorly for organisms with limited experimental data. The objective is the development of a new ML pipeline to help in the annotation of essential genes of less explored disease-causing organisms for which minimal experimental data is available. The proposed strategy combines unsupervised feature selection technique, dimension reduction using the Kamada-Kawai algorithm, and semi-supervised ML algorithm employing Laplacian Support Vector Machine (LapSVM) for prediction of essential and non-essential genes from genome-scale metabolic networks using very limited labeled dataset. A novel scoring technique, Semi-Supervised Model Selection Score, equivalent to area under the ROC curve (auROC), has been proposed for the selection of the best model when supervised performance metrics calculation is difficult due to lack of data. The unsupervised feature selection followed by dimension reduction helped to observe a distinct circular pattern in the clustering of essential and non-essential genes. LapSVM then created a curve that dissected this circle for the classification and prediction of essential genes with high accuracy (auROC > 0.85) even with 1% labeled data for model training. After successful validation of this ML pipeline on both Eukaryotes and Prokaryotes that show high accuracy even when the labeled dataset is very limited, this strategy is used for the prediction of essential genes of organisms with inadequate experimentally known data, such as Leishmania sp. Using a graph-based semi-supervised machine learning scheme, a novel integrative approach has been proposed for essential gene prediction that shows universality in application to both Prokaryotes and Eukaryotes with limited labeled data. The essential genes predicted using the pipeline provide an important lead for the prediction of gene essentiality and identification of novel therapeutic targets for antibiotic and vaccine development against disease-causing parasites.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Essential gene prediction using limited gene essentiality information–An integrative semi-supervised machine learning strategy

2020

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“…After the workshop, ten original research papers [1][2][3][4][5][6][7][8][9][10] were accepted for publication in the CNB-MAC 2019 partner journals: BMC Bioinformatics and BMC Genomics. In the following we provide a brief summary of these selected papers.…”

Section: Research Papers Presented At Cnb-mac 2019mentioning

confidence: 99%

“…The identification of essential genes in bacteria not only allows life scientists to determine the set of genes that are critical for the survival of an organism, it can also provide targets for antimicrobial/antibiotic drugs and the creation of self-sustaining artificial genomes. DeeplyEssential [6] leverages a deep neural network architecture for the identification of bacterial essential genes exclusively from the primary DNA sequence, thus maximizing the practicality of the tool.…”

Section: Research Papers Presented At Cnb-mac 2019mentioning

confidence: 99%

“…Byung-Jun Yoon, Xiaoning Qian, Tamer Kahveci, and Ranadip Pal. The workshop featured original research papers [1][2][3][4][5][6][7][8][9][10], a highlight presentation of a recently published journal paper [11], and poster presentations [12,13], which were selected by the workshop chairs based on the reviews performed by the technical committee members. Reports from previous CNB-MAC workshops are available at [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

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Selected Research Articles from the 2019 International Workshop on Computational Network Biology: Modeling, Analysis, and Control (CNB-MAC)

et al. 2020

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Recent advances in the characterization of essential genes and development of a database of essential genes

Liang,

Luo,

Lin

et al. 2024

iMeta

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Over the past few decades, there has been a significant interest in the study of essential genes, which are crucial for the survival of an organism under specific environmental conditions and thus have practical applications in the fields of synthetic biology and medicine. An increasing amount of experimental data on essential genes has been obtained with the continuous development of technological methods. Meanwhile, various computational prediction methods, related databases and web servers have emerged accordingly. To facilitate the study of essential genes, we have established a database of essential genes (DEG), which has become popular with continuous updates to facilitate essential gene feature analysis and prediction, drug and vaccine development, as well as artificial genome design and construction. In this article, we summarized the studies of essential genes, overviewed the relevant databases, and discussed their practical applications. Furthermore, we provided an overview of the main applications of DEG and conducted comprehensive analyses based on its latest version. However, it should be noted that the essential gene is a dynamic concept instead of a binary one, which presents both opportunities and challenges for their future development.

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DeeplyEssential: a deep neural network for predicting essential genes in microbes

Cited by 20 publications

References 46 publications

Essential gene prediction using limited gene essentiality information–An integrative semi-supervised machine learning strategy

Essential gene prediction using limited gene essentiality information–An integrative semi-supervised machine learning strategy

Selected Research Articles from the 2019 International Workshop on Computational Network Biology: Modeling, Analysis, and Control (CNB-MAC)

Recent advances in the characterization of essential genes and development of a database of essential genes

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