Abstract
Background: The optimization of metabolic rates (as linear objective functions) represents the methodical core of flux-balance analysis techniques which have become a standard tool for the study of genome-scale metabolic models. Besides (growth and synthesis) rates, metabolic yields are key parameters for the characterization of biochemical transformation processes, especially in the context of biotechnological applications. However, yields are ratios of rates, and hence the optimization of yields (as nonlinear objective functions) under arbitrary linear constraints is not possible with current flux-balance analysis techniques. Despite the fundamental importance of yields in constraint-based modeling, a comprehensive mathematical framework for yield optimization is still missing.Results: We present a mathematical theory that allows one to systematically compute and analyze yield-optimal solutions of metabolic models under arbitrary linear constraints. In particular, we formulate yield optimization as a linear-fractional program. For practical computations, we transform the linear-fractional yield optimization problem to a (higher-dimensional) linear problem. Its solutions determine the solutions of the original problem and can be used to predict yield-optimal flux distributions in genome-scale metabolic models. For the theoretical analysis, we consider the linear-fractional problem directly. Most importantly, we show that the yield-optimal solution set (like the rate-optimal solution set) is determined by (yield-optimal) elementary flux vectors of the underlying metabolic model. However, yield- and rate-optimal solutions may differ from each other, and hence optimal (biomass or product) yields are not necessarily obtained at solutions with optimal (growth or synthesis) rates. Moreover, we discuss phase planes/production envelopes and yield spaces, in particular, we prove that yield spaces are convex and provide algorithms for their computation. We illustrate our findings by a small example and demonstrate their relevance for metabolic engineering with realistic models of E. coli.Conclusions: We develop a comprehensive mathematical framework for yield optimization in metabolic models. Our theory is particularly useful for the study and rational modification of cell factories designed under given yield and/or rate requirements.
Highlights
Productivity and yield are crucial characteristics of biotechnological production processes based on microbial cell factories (Nielsen and Keasling, 2016; Sanford et al, 2016)
We study yield optimization under arbitrary linear constraints as a linear-fractional program (LFP), as opposed to rate optimization in Flux-balance analysis (FBA) which is studied as an linear program (LP)
We discuss the concepts of phase planes (PPs) and yield spaces (YSs) as important tools for computer-aided strain design and, as another theoretical result, we prove the convexity of YSs
Summary
Productivity and yield are crucial characteristics of biotechnological production processes based on microbial cell factories (Nielsen and Keasling, 2016; Sanford et al, 2016). Yield is a relative measure of the efficiency of (bio)chemical conversions It is the amount of product or biomass formed per amount of substrate consumed. Higher growth yields allow an organism to produce more progenies for the same amount of nutrients, while higher growth rates support faster proliferation, but are often accompanied by reduced biomass yields. The latter growth strategy may be better suited under nutrient excess in order to overgrow any competitors, while the former provides a fitness advantage under nutrient scarcity (Schuster et al, 2008). Despite the fundamental importance of yields in constraint-based modeling, a comprehensive mathematical framework for yield optimization is still missing
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