Control Theory Concepts for Modeling Uncertainty in Enzyme Kinetics of Biochemical Networks

Mišković, Ljubiša; Tokic, Milenko; Savoglidis, Georgios; Hatzimanikatis, Vassily

doi:10.1101/618777

Cited by 10 publications

(13 citation statements)

References 59 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Otherwise, we performed the stratified sampling where we imposed the σA distributions obtained from the classification algorithm in Step VII (Fig 7A and 7B). An alternative to sampling σA values would be to sample the enzyme states (27,28).…”

Section: IIImentioning

confidence: 99%

Uncertainty Reduction in Biochemical Kinetic Models: Enforcing Desired Model Properties

Mišković

Béal

Moret

et al. 2018

Preprint

Self Cite

View full text Add to dashboard Cite

Phone: + 41 (0)21 693 98 70 Fax: +41 (0)21 693 98 75 Author SummaryKinetic models are the most promising tool for understanding the complex dynamic behavior of living cells. The primary goal of kinetic models is to capture the properties of the metabolic networks as a whole, and thus we need large-scale models for dependable in silico analyses of metabolism. However, uncertainty in kinetic parameters impedes the development of kinetic models, and uncertainty levels increase with the model size. Tools that will address the issues with parameter uncertainty and that will be able to reduce the uncertainty propagation through the system are therefore needed. In this work, we applied a method called iSCHRUNK that combines parameter sampling and machine learning techniques to characterize the uncertainties and uncover intricate relationships between the parameters of kinetic models and the responses of the metabolic network.The proposed method allowed us to identify a small number of parameters that determine the responses in the network regardless of the values of other parameters. As a consequence, in future studies of metabolism, it will be sufficient to explore a reduced kinetic space, and more comprehensive analyses of large-scale and genome-scale metabolic networks will be computationally tractable.

show abstract

Section: IIImentioning

confidence: 99%

Uncertainty Reduction in Biochemical Kinetic Models: Enforcing Desired Model Properties

Mišković

Béal

Moret

et al. 2018

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…We found that all reaction directionalities within the obtained thermodynamically feasible steady-state flux and metabolite concentration profile were in agreement with the preassigned directionalities from iJN1411 [15] (Additional file 1: Table S1). We used ORACLE [34,[41][42][43][44][45][46][47][48][49][50] to construct a population of 50,000 nonlinear kinetic models around the computed steady-state flux and concentration profile ("Methods"). The constructed models contained the experimental values for 21 Michaelis constants (K m 's) available for the Pseudomonas genus in the Brenda database [81][82][83][84].…”

Section: Kinetic Study Of Wild-type P Putida Physiology Model Responmentioning

confidence: 99%

“…However, as the model complexity increases, the portion of available data of intracellular metabolite concentration and metabolic flux is rapidly decreasing, i.e., uncertainty in the system is increasing [19]. Next, we applied ORA-CLE [34,[41][42][43][44][45][46][47][48][49][50], a computational framework based on Monte Carlo sampling, to construct large-scale kinetic metabolic models of P. putida KT2440. The potential of developed kinetic models for the design of improved production strains of P. putida was demonstrated through two studies: (i) predicting metabolic responses of a wildtype P. putida strain to single-gene knockouts; and (ii) improving the responses of this organism to the stress conditions of increased ATP demand.…”

mentioning

confidence: 99%

Large-scale kinetic metabolic models of Pseudomonas putida KT2440 for consistent design of metabolic engineering strategies

Tokic

Hatzimanikatis

Mišković

2020

Biotechnol Biofuels

Self Cite

View full text Add to dashboard Cite

Background: Pseudomonas putida is a promising candidate for the industrial production of biofuels and biochemicals because of its high tolerance to toxic compounds and its ability to grow on a wide variety of substrates. Engineering this organism for improved performances and predicting metabolic responses upon genetic perturbations requires reliable descriptions of its metabolism in the form of stoichiometric and kinetic models. Results: In this work, we developed kinetic models of P. putida to predict the metabolic phenotypes and design metabolic engineering interventions for the production of biochemicals. The developed kinetic models contain 775 reactions and 245 metabolites. Furthermore, we introduce here a novel set of constraints within thermodynamicsbased flux analysis that allow for considering concentrations of metabolites that exist in several compartments as separate entities. We started by a gap-filling and thermodynamic curation of iJN1411, the genome-scale model of P. putida KT2440. We then systematically reduced the curated iJN1411 model, and we created three core stoichiometric models of different complexity that describe the central carbon metabolism of P. putida. Using the medium complexity core model as a scaffold, we generated populations of large-scale kinetic models for two studies. In the first study, the developed kinetic models successfully captured the experimentally observed metabolic responses to several single-gene knockouts of a wild-type strain of P. putida KT2440 growing on glucose. In the second study, we used the developed models to propose metabolic engineering interventions for improved robustness of this organism to the stress condition of increased ATP demand. Conclusions: The study demonstrates the potential and predictive capabilities of the kinetic models that allow for rational design and optimization of recombinant P. putida strains for improved production of biofuels and biochemicals. The curated genome-scale model of P. putida together with the developed large-scale stoichiometric and kinetic models represents a significant resource for researchers in industry and academia.

show abstract

“…Although our emphasis is on finding general design principles, this method can be 705 prepended to any modeling pipeline as a way to accelerate parameter estimation by 706 filtering our bad models and integrating qualitative biochemical knowledge into the 707 modeling process. In fact, the method presented here can be considered the natural 708 continuation of the ensemble modeling approaches developed by Liao's group [13,14] by 709 way of incorporating the attention to thermodynamics and the use of power-law kinetics 710 exemplified by Hatzimanikatis' lab [15,21,29]. What this method adds is the possibility 711 of partitioning the design space into subspaces that can be sampled and tested 712 independently.…”

mentioning

confidence: 99%

“…130 Using easy to measure values to reduce the dimensionality of the parameter space has 131 proven to be a very effective strategy for ensemble modeling [19] that works particularly 132 well with the power-law formalism [20]. Using models based on the power-law formalism 133 or similar approaches such as Metabolic Control Analysis (MCA) offers a series of 134 advantages [21] and does not result in a loss of generality. Once a set of the 135 above-mentioned parameters is obtained, it can always be translated to more traditional 136 biochemical parameters such as Michaelis constants or Hill coefficients [22,23].…”

mentioning

confidence: 99%

Understanding biochemical design principles with ensembles of canonical non-linear models

Bromig

Kremling

Marı́n-Sanguino

2020

Preprint

View full text Add to dashboard Cite

AbstractSystems biology applies concepts from engineering in order to understand biological networks. If such an understanding was complete, biologists would be able to design ad hoc biochemical components tailored for different purposes, which is the goal of synthetic biology. Needless to say that we are far away from creating biological subsystems as intricate and precise as those found in nature, but mathematical models and high throughput techniques have brought us a long way in this direction. One of the difficulties that still needs to be overcome is finding the right values for model parameters and dealing with uncertainty, which is proving to be an extremely difficult task. In this work, we take advantage of ensemble modeling techniques, where a large number of models with different parameter values are formulated and then tested according to some performance criteria. By finding features shared by successful models, the role of different components and the synergies between them can be better understood. We will address some of the difficulties often faced by ensemble modeling approaches, such as the need to sample a space whose size grows exponentially with the number of parameters, and establishing useful selection criteria. Some methods will be shown to reduce the predictions from many models into a set of understandable “design principles” that can guide us to improve or manufacture a biochemical network. Our proposed framework formulates models within standard formalisms in order to integrate information from different sources and minimize the dimension of the parameter space. Additionally, the mathematical properties of the formalism enable a partition of the parameter space into independent subspaces. Each of these subspaces can be paired with a set of criteria that depend exclusively on it, thus allowing a separate sampling/screening in spaces of lower dimension. By applying tests in a strict order where computationally cheaper tests are applied first to each subspace and applying computationally expensive tests to the remaining subset thereafter, the use of resources is optimized and a larger number of models can be examined. This can be compared to a complex database query where the order of the requests can make a huge difference in the processing time. The method will be illustrated by analyzing a classical model of a metabolic pathway with end-product inhibition. Even for such a simple model, the method provides novel insight.Author summaryA method is presented for the discovery of design principles, understood as recurrent solutions to evolutionary problems, in biochemical networks.The method takes advantage of ensemble modeling techniques, where a large number of models with different parameter values are formulated and then tested according to some performance criteria. By finding features shared by successful models, a set of simple rules can be identified that enables us to formulate new models that are known to perform well, a priori. By formulating the models within the framework of Biochemical Systems Theory (BST) we manage to overcome some of the obstacles often faced by ensemble modeling. Further analysis of the selected modeling with standard machine learning techniques enables the formulation of simple rules – design principles – for building good performing networks. We illustrate the method with a well-known case study: the unbranched pathway with end-product inhibition. The method manages to identify the known features of this well-studied pathway while providing additional guidelines on how the pathway kinetics can be tuned to achieve a desired functionality – e.g. demand vs supply control – as well as to identifying important tradeoffs between performance, robustness and and stability.

show abstract

Control Theory Concepts for Modeling Uncertainty in Enzyme Kinetics of Biochemical Networks

Cited by 10 publications

References 59 publications

Uncertainty Reduction in Biochemical Kinetic Models: Enforcing Desired Model Properties

Uncertainty Reduction in Biochemical Kinetic Models: Enforcing Desired Model Properties

Large-scale kinetic metabolic models of Pseudomonas putida KT2440 for consistent design of metabolic engineering strategies

Understanding biochemical design principles with ensembles of canonical non-linear models

Contact Info

Product

Resources

About