IFPTML mapping of nanoparticle antibacterial activity vs. pathogen metabolic networks

AbstractUncertainty in the structure and parameters of networks is ubiquitous across computational biology. In constraint-based reconstruction and analysis of metabolic networks, this uncertainty is present both during the reconstruction of networks and in simulations performed with them. Here, we present Medusa, a Python package for the generation and analysis of ensembles of genome-scale metabolic network reconstructions. Medusa builds on the COBRApy package for constraint-based reconstruction and analysis by compressing a set of models into a compact ensemble object, providing functions for the generation of ensembles using experimental data, and extending constraint-based analyses to ensemble scale. We demonstrate how Medusa can be used to generate ensembles, perform ensemble simulations, and how machine learning can be used in conjunction with Medusa to guide the curation of genome-scale metabolic network reconstructions. Medusa is available under the permissive MIT license from the Python Packaging Index (https://pypi.org/) and from github (https://github.com/gregmedlock/Medusa/), and comprehensive documentation is available at https://medusa.readthedocs.io/en/latest/.

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Modeling Antibacterial Activity with Machine Learning and Fusion of Chemical Structure Information with Microorganism Metabolic Networks

Journal of Chemical Information and Modeling ◽

10.1021/acs.jcim.9b00034 ◽

2019 ◽

Vol 59 (3) ◽

pp. 1109-1120 ◽

Cited By ~ 11

Author(s):

Deyani Nocedo-Mena ◽

Carlos Cornelio ◽

María del Rayo Camacho-Corona ◽

Elvira Garza-González ◽

Noemi Waksman de Torres ◽

...

Keyword(s):

Machine Learning ◽

Antibacterial Activity ◽

Chemical Structure ◽

Metabolic Networks ◽

Structure Information

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Impacts of yeast metabolic network structure on enzyme evolution

Genome Biology ◽

10.1186/gb-2007-8-8-407 ◽

2007 ◽

Vol 8 (8) ◽

pp. 407 ◽

Cited By ~ 16

Author(s):

Chenqi Lu ◽

Ze Zhang ◽

Lindsey Leach ◽

MJ Kearsey ◽

ZW Luo

Keyword(s):

Metabolic Network ◽

Network Structure ◽

Enzyme Evolution

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SCOUR: a stepwise machine learning framework for predicting metabolite-dependent regulatory interactions

BMC Bioinformatics ◽

10.1186/s12859-021-04281-7 ◽

2021 ◽

Vol 22 (1) ◽

Author(s):

Justin Y. Lee ◽

Britney Nguyen ◽

Carlos Orosco ◽

Mark P. Styczynski

Keyword(s):

Machine Learning ◽

Metabolic Networks ◽

Sampling Frequency ◽

Low Noise ◽

Training Data ◽

High Noise ◽

Regulatory Interactions ◽

Learning Framework ◽

Metabolic Systems ◽

Noise Data

Abstract Background The topology of metabolic networks is both well-studied and remarkably well-conserved across many species. The regulation of these networks, however, is much more poorly characterized, though it is known to be divergent across organisms—two characteristics that make it difficult to model metabolic networks accurately. While many computational methods have been built to unravel transcriptional regulation, there have been few approaches developed for systems-scale analysis and study of metabolic regulation. Here, we present a stepwise machine learning framework that applies established algorithms to identify regulatory interactions in metabolic systems based on metabolic data: stepwise classification of unknown regulation, or SCOUR. Results We evaluated our framework on both noiseless and noisy data, using several models of varying sizes and topologies to show that our approach is generalizable. We found that, when testing on data under the most realistic conditions (low sampling frequency and high noise), SCOUR could identify reaction fluxes controlled only by the concentration of a single metabolite (its primary substrate) with high accuracy. The positive predictive value (PPV) for identifying reactions controlled by the concentration of two metabolites ranged from 32 to 88% for noiseless data, 9.2 to 49% for either low sampling frequency/low noise or high sampling frequency/high noise data, and 6.6–27% for low sampling frequency/high noise data, with results typically sufficiently high for lab validation to be a practical endeavor. While the PPVs for reactions controlled by three metabolites were lower, they were still in most cases significantly better than random classification. Conclusions SCOUR uses a novel approach to synthetically generate the training data needed to identify regulators of reaction fluxes in a given metabolic system, enabling metabolomics and fluxomics data to be leveraged for regulatory structure inference. By identifying and triaging the most likely candidate regulatory interactions, SCOUR can drastically reduce the amount of time needed to identify and experimentally validate metabolic regulatory interactions. As high-throughput experimental methods for testing these interactions are further developed, SCOUR will provide critical impact in the development of predictive metabolic models in new organisms and pathways.

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Functional prediction of environmental variables using metabolic networks

Scientific Reports ◽

10.1038/s41598-021-91486-8 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Adèle Weber Zendrera ◽

Nataliya Sokolovska ◽

Hédi A. Soula

Keyword(s):

Machine Learning ◽

Growth Temperature ◽

Environmental Variables ◽

Metabolic Networks ◽

Machine Learning Techniques ◽

Underlying Structure ◽

Glutathione Biosynthesis ◽

Additional Information ◽

Cold Environments ◽

Novel Approach

AbstractIn this manuscript, we propose a novel approach to assess relationships between environment and metabolic networks. We used a comprehensive dataset of more than 5000 prokaryotic species from which we derived the metabolic networks. We compute the scope from the reconstructed graphs, which is the set of all metabolites and reactions that can potentially be synthesized when provided with external metabolites. We show using machine learning techniques that the scope is an excellent predictor of taxonomic and environmental variables, namely growth temperature, oxygen tolerance, and habitat. In the literature, metabolites and pathways are rarely used to discriminate species. We make use of the scope underlying structure—metabolites and pathways—to construct the predictive models, giving additional information on the important metabolic pathways needed to discriminate the species, which is often absent in other metabolic network properties. For example, in the particular case of growth temperature, glutathione biosynthesis pathways are specific to species growing in cold environments, whereas tungsten metabolism is specific to species in warm environments, as was hinted in current literature. From a machine learning perspective, the scope is able to reduce the dimension of our data, and can thus be considered as an interpretable graph embedding.

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Systematic Investigation of Mouse Models of Parkinson’s Disease by Transcriptome Mapping on a Brain-Specific Genome-Scale Metabolic Network

Molecular Omics ◽

10.1039/d0mo00135j ◽

2021 ◽

Author(s):

Ecehan Abdik ◽

Tunahan Cakir

Keyword(s):

Parkinson’S Disease ◽

Parkinson's Disease ◽

Metabolic Network ◽

Mouse Models ◽

Mus Musculus ◽

Metabolic Networks ◽

Systematic Investigation ◽

Omics Data ◽

Metabolic Alterations ◽

Genome Scale

Genome-scale metabolic networks enable systemic investigation of metabolic alterations caused by diseases by providing interpretation of omics data. Although Mus musculus (mouse) is one of the most commonly used model...

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A Novel ECG Automatic Detection Using LongShort-Term Memory Network and Internet of Things Technology

Journal of Medical Imaging and Health Informatics ◽

10.1166/jmihi.2021.3684 ◽

2021 ◽

Vol 11 (6) ◽

pp. 1592-1598

Author(s):

Xufei Liu

Keyword(s):

Machine Learning ◽

Cardiovascular Diseases ◽

Internet Of Things ◽

Network Structure ◽

Recognition Rate ◽

Classification Model ◽

Data Set ◽

Public Data ◽

Lstm Network ◽

Internet Of Things Technology

The early detection of cardiovascular diseases based on electrocardiogram (ECG) is very important for the timely treatment of cardiovascular patients, which increases the survival rate of patients. ECG is a visual representation that describes changes in cardiac bioelectricity and is the basis for detecting heart health. With the rise of edge machine learning and Internet of Things (IoT) technologies, small machine learning models have received attention. This study proposes an ECG automatic classification method based on Internet of Things technology and LSTM network to achieve early monitoring and early prevention of cardiovascular diseases. Specifically, this paper first proposes a single-layer bidirectional LSTM network structure. Make full use of the timing-dependent features of the sampling points before and after to automatically extract features. The network structure is more lightweight and the calculation complexity is lower. In order to verify the effectiveness of the proposed classification model, the relevant comparison algorithm is used to verify on the MIT-BIH public data set. Secondly, the model is embedded in a wearable device to automatically classify the collected ECG. Finally, when an abnormality is detected, the user is alerted by an alarm. The experimental results show that the proposed model has a simple structure and a high classification and recognition rate, which can meet the needs of wearable devices for monitoring ECG of patients.

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DEXOM: Diversity-based enumeration of optimal context-specific metabolic networks

10.1101/2020.07.17.208918 ◽

2020 ◽

Author(s):

Pablo Rodríguez-Mier ◽

Nathalie Poupin ◽

Carlo de Blasio ◽

Laurent Le Cam ◽

Fabien Jourdan

Keyword(s):

Metabolic Network ◽

Metabolic Networks ◽

Relevant Information ◽

Experimental Information ◽

Correct Identification ◽

Good Representation ◽

Metabolic State ◽

Whole Space ◽

Context Specific ◽

Optimal Networks

AbstractThe correct identification of metabolic activity in tissues or cells under different environmental or genetic conditions can be extremely elusive due to mechanisms such as post-transcriptional modification of enzymes or different rates in protein degradation, making difficult to perform predictions on the basis of gene expression alone. Context-specific metabolic network reconstruction can overcome these limitations by leveraging the integration of multi-omics data into genome-scale metabolic networks (GSMN). Using the experimental information, context-specific models are reconstructed by extracting from the GSMN the sub-network most consistent with the data, subject to biochemical constraints. One advantage is that these context-specific models have more predictive power since they are tailored to the specific organism and condition, containing only the reactions predicted to be active in such context. A major limitation of this approach is that the available information does not generally allow for an unambiguous characterization of the corresponding optimal metabolic sub-network, i.e., there are usually many different sub-network that optimally fit the experimental data. This set of optimal networks represent alternative explanations of the possible metabolic state. Ignoring the set of possible solutions reduces the ability to obtain relevant information about the metabolism and may bias the interpretation of the true metabolic state. In this work, we formalize the problem of enumeration of optimal metabolic networks, we implement a set of techniques that can be used to enumerate optimal networks, and we introduce DEXOM, a novel strategy for diversity-based extraction of optimal metabolic networks. Instead of enumerating the whole space of optimal metabolic networks, which can be computationally intractable, DEXOM samples solutions from the set of optimal metabolic sub-networks maximizing diversity in order to obtain a good representation of the possible metabolic state. We evaluate the solution diversity of the different techniques using simulated and real datasets, and we show how this method can be used to improve in-silico gene essentiality predictions in Saccharomyces Cerevisiae using diversity-based metabolic network ensembles. Both the code and the data used for this research are publicly available on GitHub1.

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Artificial Metabolic Networks: enabling neural computation with metabolic networks

10.1101/2022.01.09.475487 ◽

2022 ◽

Author(s):

Leon Faure ◽

Bastien Mollet ◽

Wolfram Liebermeister ◽

Jean-Loup Faulon

Keyword(s):

Machine Learning ◽

Recurrent Neural Networks ◽

Metabolic Networks ◽

Cross Validation ◽

Regression Coefficient ◽

Network Models ◽

Biotechnological Applications ◽

Neural Network Models ◽

Surrogate Constraint ◽

Constraint Based Modeling

Metabolic networks have largely been exploited as mechanistic tools to predict the behavior of microorganisms with a defined genotype in different environments. However, flux predictions by constraint-based modeling approaches are limited in quality unless labor-intensive experiments including the measurement of media intake fluxes, are performed. Using machine learning instead of an optimization of biomass flux - on which most existing constraint-based methods are based - provides ways to improve flux and growth rate predictions. In this paper, we show how Recurrent Neural Networks can surrogate constraint-based modeling and make metabolic networks suitable for backpropagation and consequently be used as an architecture for machine learning. We refer to our hybrid - mechanistic and neural network - models as Artificial Metabolic Networks (AMN). We showcase AMN and illustrate its performance with an experimental dataset of Escherichia coli growth rates in 73 different media compositions. We reach a regression coefficient of R2=0.78 on cross-validation sets. We expect AMNs to provide easier discovery of metabolic insights and prompt new biotechnological applications.

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Finding Minimum Reaction Cuts of Metabolic Networks Under a Boolean Model Using Integer Programming and Feedback Vertex Sets

Computer Engineering ◽

10.4018/978-1-61350-456-7.ch318 ◽

2012 ◽

pp. 774-791

Author(s):

Takeyuki Tamura ◽

Kazuhiro Takemoto ◽

Tatsuya Akutsu

Keyword(s):

Integer Programming ◽

Metabolic Network ◽

Drug Targets ◽

Metabolic Networks ◽

Boolean Model ◽

Pentose Phosphate ◽

Minimum Size ◽

E Coli ◽

Potential Applications ◽

Vertex Set

In this paper, the authors consider the problem of, given a metabolic network, a set of source compounds and a set of target compounds, finding a minimum size reaction cut, where a Boolean model is used as a model of metabolic networks. The problem has potential applications to measurement of structural robustness of metabolic networks and detection of drug targets. They develop an integer programming-based method for this optimization problem. In order to cope with cycles and reversible reactions, they further develop a novel integer programming (IP) formalization method using a feedback vertex set (FVS). When applied to an E. coli metabolic network consisting of Glycolysis/Glyconeogenesis, Citrate cycle and Pentose phosphate pathway obtained from KEGG database, the FVS-based method can find an optimal set of reactions to be inactivated much faster than a naive IP-based method and several times faster than a flux balance-based method. The authors also confirm that our proposed method works even for large networks and discuss the biological meaning of our results.

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