Metabolic states with maximal specific rate carry flux through an elementary flux mode

Wortel, Meike T.; Peters, Hans; Hulshof, Josephus; Teusink, Bas; Bruggeman, Frank J.

doi:10.1111/febs.12722

Cited by 68 publications

(85 citation statements)

References 28 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, non-linear protein costs have also been reported [17], possibly as a result of effects related to protein activity rather than production [18]. Secondly, the concentration of each protein should be precisely tuned [16,19]. This has been found for several enzymes in E. coli, [20,21,17,22], Lactococcus lactis [23][24][25] and Saccharomyces cerevisiae [26].…”

Section: Introductionmentioning

confidence: 99%

How fast‐growing bacteria robustly tune their ribosome concentration to approximate growth‐rate maximization

Bosdriesz¹,

Molenaar²,

Teusink³

et al. 2015

The FEBS Journal

Self Cite

202

274

View full text Add to dashboard Cite

Maximization of growth rate is an important fitness strategy for bacteria. Bacteria can achieve this by expressing proteins at optimal concentrations, such that resources are not wasted. This is exemplified for Escherichia coli by the increase of its ribosomal protein-fraction with growth rate, which precisely matches the increased protein synthesis demand. These findings and others have led to the hypothesis that E. coli aims to maximize its growth rate in environments that support growth. However, what kind of regulatory strategy is required for a robust, optimal adjustment of the ribosome concentration to the prevailing condition is still an open question. In the present study, we analyze the ppGpp-controlled mechanism of ribosome expression used by E. coli and show that this mechanism maintains the ribosomes saturated with its substrates. In this manner, overexpression of the highly abundant ribosomal proteins is prevented, and limited resources can be redirected to the synthesis of other growth-promoting enzymes. It turns out that the kinetic conditions for robust, optimal protein-partitioning, which are required for growth rate maximization across conditions, can be achieved with basic biochemical interactions. We show that inactive ribosomes are the most suitable ‘signal’ for tracking the intracellular nutritional state and for adjusting gene expression accordingly, as small deviations from optimal ribosome concentration cause a huge fractional change in ribosome inactivity. We expect to find this control logic implemented across fast-growing microbial species because growth rate maximization is a common selective pressure, ribosomes are typically highly abundant and thus costly, and the required control can be implemented by a small, simple network.

show abstract

Section: Introductionmentioning

confidence: 99%

How fast‐growing bacteria robustly tune their ribosome concentration to approximate growth‐rate maximization

Bosdriesz¹,

Molenaar²,

Teusink³

et al. 2015

The FEBS Journal

Self Cite

202

274

View full text Add to dashboard Cite

show abstract

“…If one considers a fixed flux through the metabolic pathway, then minimization of the enzyme mass allocated yields a biologically convenient solution. Particularly in the context of maximum growth rate prediction of microbial cells, there are theoretical results that support the existence of such optimal rates defined by a single EFM . More recently, enzyme‐flux cost minimization (EFCM) has been proposed to rationally explain the trade‐offs between growth rate and yield(s) based on the ECM framework …”

Section: Constraint‐based Optimization Methods For Pathway Designmentioning

confidence: 99%

“…Particularly in the context of maximum growth rate prediction of microbial cells, there are theoretical results that support the existence of such optimal rates defined by a single EFM. [70,71] More recently, enzyme-flux cost minimization (EFCM) has been proposed to rationally explain the trade-offs between growth rate and yield(s) based on the ECM framework. [72] Application of ECM has been mostly focused on evaluating alternative metabolic pathways fulfilling known biological functions such as carbon assimilation [20] and efficient carbon conversions.…”

Section: Pathways With Minimum Enzymatic Costmentioning

confidence: 99%

Expanding Metabolic Capabilities Using Novel Pathway Designs: Computational Tools and Case Studies

Saa

Cortés

López

et al. 2019

Biotechnology Journal

View full text Add to dashboard Cite

Design and selection of efficient metabolic pathways is critical for the success of metabolic engineering endeavors. Convenient pathways should not only produce the target metabolite in high yields but also are required to be thermodynamically feasible under production conditions, and to prefer efficient enzymes. To support the design and selection of such pathways, different computational approaches have been proposed for exploring the feasible pathway space under many of the above constraints. In this review, an overview of recent constraint‐based optimization frameworks for metabolic pathway prediction, as well as relevant pathway engineering case studies that highlight the importance of rational metabolic designs is presented. Despite the availability and suitability of in silico design tools for metabolic pathway engineering, scarce—although increasing—application of computational outcomes is found. Finally, challenges and limitations hindering the broad adoption and successful application of these tools in metabolic engineering projects are discussed.

show abstract

“…It has recently been shown (Müller et al 2014, Wortel et al 2014) that maximal steady state specific flux is attained in special type of pathway, called an Elementary Flux Mode (EFM). An EFM is a pathway that has a minimal number of enzymes involved: it allows for a balanced flow of metabolism, but this possibility is void if any one of its enzymes is removed from the pathway.…”

Section: Maximising Specific Flux and The Qorac Frameworkmentioning

confidence: 99%

Stability of an adaptively controlled pathway maximising specific flux under varying conditions

Hulshof

Planquè

2019

Preprint

View full text Add to dashboard Cite

Microbial cells need to adapt to changing environmental conditions to survive. There is an evolutionary advantage to grow fast; this requires high metabolic rates, and an efficient allocation of enzymatic resources. Here we study a general control theory called qORAC, developed previously, which allows cells to adaptively control their enzyme allocations to achieve maximal steady state flux. The control is robust to perturbations in the environment, but those perturbations themselves do not feature in the control. In this paper we focus on the archetypical pathway, the linear chain with reversible Michaelis-Menten kinetics, together with qORAC control. First we assume that the metabolic pathway is in quasi-steady state with respect to enzyme synthesis. Then we show that the map between steady state metabolite and enzyme concentrations is a smooth bijection. Using this information, we finally show that the unique (and hence flux-maximising) steady state of this system is locally stable. We provide further evidence that it may in fact be globally stable.Mathematics Subject Classification (2010) 34H15 · 37N25 · 93D21 · 93D25 · 92C42

show abstract

Metabolic states with maximal specific rate carry flux through an elementary flux mode

Cited by 68 publications

References 28 publications

How fast‐growing bacteria robustly tune their ribosome concentration to approximate growth‐rate maximization

How fast‐growing bacteria robustly tune their ribosome concentration to approximate growth‐rate maximization

Expanding Metabolic Capabilities Using Novel Pathway Designs: Computational Tools and Case Studies

Stability of an adaptively controlled pathway maximising specific flux under varying conditions

Contact Info

Product

Resources

About