Abstract
Optimal gene expression is central for the development of both bacterial expression systems for heterologous protein production, and microbial cell factories for industrial metabolite production. Our goal is to fulfill industry-level overproduction demands optimally, as measured by the following key performance metrics: titer, productivity rate, and yield (TRY). Here we use a multiscale model incorporating the dynamics of (i) the cell population in the bioreactor, (ii) the substrate uptake and (iii) the interaction between the cell host and expression of the protein of interest. Our model predicts cell growth rate and cell mass distribution between enzymes of interest and host enzymes as a function of substrate uptake and the following main lab-accessible gene expression-related characteristics: promoter strength, gene copy number and ribosome binding site strength. We evaluated the differential roles of gene transcription and translation in shaping TRY trade-offs for a wide range of expression levels and the sensitivity of the TRY space to variations in substrate availability. Our results show that, at low expression levels, gene transcription mainly defined TRY, and gene translation had a limited effect; whereas, at high expression levels, TRY depended on the product of both, in agreement with experiments in the literature.
Highlights
For a wide range of gene expression levels, we evaluate the differential roles of gene transcription and translation in shaping the trade-offs between titer, yield and productivity rate for the three main operational modes of industrial bioreactors
We evaluated them for the production of the protein A in E. coli under the three modes of operation of the bioreactor and for different points covering the expression space
The analysis performed with different conditions of bioreactor operation and several combinations spanning the expression space reveals, as expected, that the cell growth rate decreases as the cell burden induced by higher expression levels of A increases
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Optimal gene expression is central to the development of both bacterial expression systems for production of heterologous proteins and microbial cell factories to produce metabolites of industrial interest. Both applications seek to obtain high levels of products of interest by means of metabolic engineering. The goal is to reach industry-level overproduction demands in an optimal way, as measured using the key performance indices titer, productivity (rate) and yield ( TRY)
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