Kinetic models of metabolism that consider alternative steady-state solutions of intracellular fluxes and concentrations

Large-scale kinetic models are used for designing, predicting, and understanding the metabolic responses of living cells. Kinetic models are particularly attractive for the biosynthesis of target molecules in cells as they are typically better than other types of models at capturing the complex cellular biochemistry. Using simpler stoichiometric models as scaffolds, kinetic models are built around a steady-state flux profile and a metabolite concentration vector that are typically determined via optimization. However, as the underlying optimization problem is underdetermined, even after incorporating available experimental omics data, one cannot uniquely determine the operational configuration in terms of metabolic fluxes and metabolite concentrations. As a result, some reactions can operate in either the forward or reverse direction while still agreeing with the observed physiology. Here, we analyze how the underlying uncertainty in intracellular fluxes and concentrations affects predictions of constructed kinetic models and their design in metabolic engineering and systems biology studies. To this end, we integrated the omics data of optimally grown Escherichia coli into a stoichiometric model and constructed populations of non-linear large-scale kinetic models of alternative steady-state solutions consistent with the physiology of the E. coli aerobic metabolism. We performed metabolic control analysis (MCA) on these models, highlighting that MCA-based metabolic engineering decisions are strongly affected by the selected steady state and appear to be more sensitive to concentration values rather than flux values. To incorporate this into future studies, we propose a workflow for moving towards more reliable and robust predictions that are consistent with all alternative steady-state solutions. This workflow can be applied to all kinetic models to improve the consistency and accuracy of their predictions. Additionally, we show that, irrespective of the alternative steady-state solution, increased activity of phosphofructokinase and decreased ATP maintenance requirements would improve cellular growth of optimally grown E. coli.

A Study of Dynamic Responses of E. coli Metabolism Upon Large Perturbations Using Large-Scale Kinetic Models

Georgios Fengos, Vassily Hatzimanikatis, Ljubisa Miskovic, Milenko Tokic

In recent years, constraint-based approaches have been widely used for analyzing cellular metabolism. These approaches use stoichiometric models for the characterization of the intracellular fluxes at steady state. Nonetheless, the stoichiometric models lack information about metabolic regulation and enzyme kinetics, and they are not able to capture the dynamic features of metabolic pathways. As a result, there are ongoing efforts to build large-scale and genome-scale kinetic models as they can predict the complex dynamic responses of metabolism to environmental and genetic perturbations. The development of kinetic models is mostly hindered by structural, e.g. unknown kinetic mechanisms, and quantitative, e.g. inconsistencies in the available kinetic data, uncertainties. To overcome these difficulties, we have developed the ORACLE (Optimization and Risk Analysis of Complex Living Entities) framework that uses Monte Carlo sampling techniques to build populations of kinetic models that are consistent with the observations while satisfying the stoichiometric and thermodynamic constraints. ORACLE was initially developed within the context of Metabolic Control Analysis (MCA) to compute control coefficients despite scarce information about kinetic properties of enzymes. Recently, we extended ORACLE capabilities beyond computing control coefficients to construct populations of a large class of nonlinear models of metabolism. In this work, we used the ORACLE framework to build a population of large-scale nonlinear models of aerobically grown wild-type E. coli. We used these models to investigate the dynamic responses of E. coli metabolism to multiple gene deletion knockouts and we compared them with the experiments. We further compared these predictions with the predictions obtained through MCA to assess to what extent the simpler MCA predictions are able to predict the responses of metabolism to large perturbations. These results demonstrate usefulness of large-scale kinetic models for quantitative and qualitative understanding of the global regulation of the cell.

2015

Uncertainty reduction in biochemical kinetic models: Enforcing desired model properties

Vassily Hatzimanikatis, Ljubisa Miskovic, Michaël Roger Germain Moret

A persistent obstacle for constructing kinetic models of metabolism is uncertainty in the kinetic properties of enzymes. Currently, available methods for building kinetic models can cope indirectly with uncertainties by integrating data from different biological levels and origins into models. In this study, we use the recently proposed computational approach iSCHRUNK (in Silico Approach to Characterization and Reduction of Uncertainty in the Kinetic Models), which combines Monte Carlo parameter sampling methods and machine learning techniques, in the context of Bayesian inference. Monte Carlo parameter sampling methods allow us to exploit synergies between different data sources and generate a population of kinetic models that are consistent with the available data and physicochemical laws. The machine learning allows us to data-mine the a priori generated kinetic parameters together with the integrated datasets and derive posterior distributions of kinetic parameters consistent with the observed physiology. In this work, we used iSCHRUNK to address a design question: can we identify which are the kinetic parameters and what are their values that give rise to a desired metabolic behavior? Such information is important for a wide variety of studies ranging from biotechnology to medicine. To illustrate the proposed methodology, we performed Metabolic Control Analysis, computed the flux control coefficients of the xylose uptake (XTR), and identified parameters that ensure a rate improvement of XTR in a glucose-xylose co-utilizing S. cerevisiae strain. Our results indicate that only three kinetic parameters need to be accurately characterized to describe the studied physiology, and ultimately to design and control the desired responses of the metabolism. This framework paves the way for a new generation of methods that will systematically integrate the wealth of available omics data and efficiently extract the information necessary for metabolic engineering and synthetic biology decisions.

2019

Statistical inference in ensemble modeling of cellular metabolism

Marc-Olivier Boldi, Tuure Eelis Hameri, Vassily Hatzimanikatis

Kinetic models of metabolism can be constructed to predict cellular regulation and devise metabolic engineering strategies, and various promising computational workflows have been developed in recent years for this. Due to the uncertainty in the kinetic parameter values required to build kinetic models, these workflows rely on ensemble modeling (EM) principles for sampling and building populations of models describing observed physiologies. Sensitivity coefficients from metabolic control analysis (MCA) of kinetic models can provide important insight about cellular control around a given physiological steady state. However, despite considering populations of kinetic models and their model outputs, current approaches do not provide adequate tools for statistical inference. To derive conclusions from model outputs, such as MCA sensitivity coefficients, it is necessary to rank/compare populations of variables with each other. Currently existing workflows consider confidence intervals (CIs) that are derived independently for each comparable variable. Hence, it is important to derive simultaneous CIs for the variables that we wish to rank/compare. Herein, we used an existing large-scale kinetic model of Escherichia Coli metabolism to present how univariate CIs can lead to incorrect conclusions, and we present a new workflow that applies three different multivariate statistical approaches. We use the Bonferroni and the exact normal methods to build symmetric CIs using the normality assumptions. We then suggest how bootstrapping can compute asymmetric CIs whilst relaxing this normality assumption. We conclude that the Bonferroni and the exact normal methods can provide simple and efficient ways for constructing reliable CIs, with the exact normal method favored over the Bonferroni when the compared variables present dependencies. Bootstrapping, despite its significantly higher computational cost, is recommended when comparing non-normal distributions of variables. Additionally, we show how the Bonferroni method can readily be used to estimate required sample numbers to attain a certain CI size.

2019

Uncertainty reduction in biochemical kinetic models: Enforcing desired model properties

Vassily Hatzimanikatis, Ljubisa Miskovic, Michaël Roger Germain Moret

2019

Statistical inference in ensemble modeling of cellular metabolism

Marc-Olivier Boldi, Tuure Eelis Hameri, Vassily Hatzimanikatis

2019

A Study of Dynamic Responses of E. coli Metabolism Upon Large Perturbations Using Large-Scale Kinetic Models

Georgios Fengos, Vassily Hatzimanikatis, Ljubisa Miskovic, Milenko Tokic

2015