Reconstructing Kinetic Models for Dynamical Studies of Metabolism using Generative Adversarial Networks

Choudhury, Subham; Moret, Michael; Salvy, Pierre; Weilandt, Daniel; Hatzimanikatis, Vassily; Mišković, Ljubiša

doi:10.1038/s42256-022-00519-y

Cited by 46 publications

(35 citation statements)

References 52 publications

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“…However, acquiring the parameters of these models with traditional kinetic modeling approaches is computationally expensive and arduous 15,32 . To improve the efficiency of generating kinetic models, we have recently proposed REKINDLE 32 . This unsupervised deep-learning method uses generative adversarial networks (GANs) 52 for this task.…”

Section: Discussionmentioning

confidence: 99%

“…A parameterized kinetic model exhibits highly nonlinear but deterministic responses that depend on the intracellular state determined by the network topology and the integrated data. To capture this nonlinear behavior and determine kinetic parameters, we require function approximators with similar complexity, such as neural networks 32 . In RENAISSANCE, we iteratively optimize the weights of feed-forward neural networks (generators) using NES (Figure 1a) to obtain kinetic parameters leading to biologically relevant kinetic models, meaning that the metabolic responses obtained from these models have experimentally observed dynamics (Methods).…”

Section: Renaissance For Parameterization Of Biologically Relevant Ki...mentioning

confidence: 99%

“…Recent efforts employing new tailor-made parametrization 27 and machine learning [32][33][34] improved the efficiency of constructing near-genome-scale kinetic models. Nevertheless, challenges remain regarding extensive computational time 27 and the need for training data from traditional kinetic modeling approaches [32][33][34] .…”

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Generative machine learning produces kinetic models that accurately characterize intracellular metabolic states

Choudhury

Narayanan

Moret

et al. 2023

Preprint

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Large omics datasets are nowadays routinely generated to provide insights into cellular processes. Nevertheless, making sense of omics data and determining intracellular metabolic states remains challenging. Kinetic models of metabolism are crucial for integrating and consolidating omics data because they explicitly link metabolite concentrations, metabolic fluxes, and enzyme levels. However, the difficulties in determining kinetic parameters that govern cellular physiology prevent the broader adoption of these models by the research community. We present RENAISSANCE (REconstruction of dyNAmIc models through Stratified Sampling using Artificial Neural networks and Concepts of Evolution strategies), a generative machine learning framework for efficiently parameterizing large-scale kinetic models with dynamic properties matching experimental observations. We showcase RENAISSANCE's capabilities through three applications: generation of kinetic models of E. coli metabolism, characterization of intracellular metabolic states, and assimilation and reconciliation of experimental kinetic data. We provide the open-access code to facilitate experimentalists and modelers applying this framework to diverse metabolic systems and integrating a broad range of available data. We anticipate that the proposed framework will be invaluable for researchers who seek to analyze metabolic variations involving changes in metabolite and enzyme levels and enzyme activity in health and biotechnological studies.

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Section: Discussionmentioning

confidence: 99%

Section: Renaissance For Parameterization Of Biologically Relevant Ki...mentioning

confidence: 99%

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Generative machine learning produces kinetic models that accurately characterize intracellular metabolic states

Choudhury

Narayanan

Moret

et al. 2023

Preprint

Self Cite

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“…These kinetic models consist of a system of nonlinear ordinary differential equations (ODEs) characterized by a set of kinetic parameters. To generate such models, we can use traditional kinetic modeling approaches such as MASSPy [17], Ensemble Modeling [19], ORACLE [15], [18], [26], [27], and machine learning empowered methods such as REKINDLE [21] and iSCHRUNK [20] [22].…”

Section: Nomad For Reliable Strain Designsmentioning

confidence: 99%

Rational strain design with minimal phenotype perturbation

Narayanan¹,

Weilandt²,

Mišković

et al. 2022

Preprint

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Increased availability of multi-omics data has facilitated the characterization of metabolic phenotypes of cellular organisms. However, devising genetic interventions that drive cellular organisms toward the desired phenotype remains challenging in terms of time, cost, and resources. Kinetic models, in particular, hold great potential for accelerating this task since they can simulate the metabolic responses to environmental and genetic perturbations. Although the challenges in building kinetic models have been well-documented, there exists no consensus on how to use these models for strain design in a computationally tractable manner. A straightforward approach that exhaustively simulates and evaluates putative designs would be impractical, considering the intensive computational requirements when targeting multiple enzymes. We address this issue by introducing a framework to efficiently scout the space of designs while respecting the physiological requirements of the cell. The framework employs mixed-integer linear programming and nonlinear simulations with large-scale nonlinear kinetic models to devise genetic interventions in a scalable manner while accounting for the network effects of these perturbations. More importantly, the framework ensures the engineered strain's robustness by maintaining its phenotype close to that of the reference strain. We use the framework to improve the production of anthranilate, a precursor for pharmaceutical drugs, in E. coli. The devised strategies include previously experimentally validated targets as well as novel designs suitable for experimental implementation. As an essential part of the future design-build-test-learn cycles, we anticipate that this novel framework will enable high throughput designs and accelerated turnover in biotechnological processes.

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“…Notably, systems biologyinformed AI can be used to select among different reaction kinetic schemes (e.g., mass-balance, S-systems, log-linear/linlog, Michaelis-Menten, generalized Hill, convenience, modular) according to the available mechanistic knowledge, experimental datasets, and desired level of details (Du et al, 2016;Kim et al, 2018). Several approaches combining deep learning with GNNs or GANNs have been recently used to fully parametrize ODE-based genome-scale metabolic models in terms of Michaelis-Menten affinity constants (Choudhury et al, 2022) or enzyme turnover numbers (Li et al, 2021), respectively. Bayesian meta-modeling is another systems biology-based approach that uses different mathematical representations, scales, and levels of granularity from prior models in order to simulate cell activity (Raveh et al, 2021).…”

Section: Model Simulationmentioning

confidence: 99%

How artificial intelligence enables modeling and simulation of biological networks to accelerate drug discovery

DiNuzzo¹

2022

Front. Drug. Discov.

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The pharmaceutical industry suffered a significant decline of innovation in the last few decades, whose simple reason is complex biology. Artificial intelligence (AI) promises to make the entire drug discovery and development process more efficient. Here I consider the potential benefits of using AI to deepen our mechanistic understanding of disease by leveraging data and knowledge for modeling and simulation of genome-scale biological networks. I outline recent developments that are moving the field forward and I identify several overarching challenges for advancing the state of the art towards the successful integration of AI with modeling and simulation in drug discovery.

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Reconstructing Kinetic Models for Dynamical Studies of Metabolism using Generative Adversarial Networks

Cited by 46 publications

References 52 publications

Generative machine learning produces kinetic models that accurately characterize intracellular metabolic states

Generative machine learning produces kinetic models that accurately characterize intracellular metabolic states

Rational strain design with minimal phenotype perturbation

How artificial intelligence enables modeling and simulation of biological networks to accelerate drug discovery

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