Abstract
A large group of biopharmaceuticals is produced in cell lines. The yield of such products can be increased by genetic engineering of the corresponding cell lines. The prediction of promising genetic modifications by mathematical modeling is a valuable tool to facilitate experimental screening. Besides information on the intracellular kinetics and genetic modifications the mathematical model has to account for ubiquitous cell-to-cell variability. In this contribution, we establish a novel model-based methodology for influenza vaccine production in cell lines with overexpressed genes. The manipulation of the expression level of genes coding for host cell factors relevant for virus replication is achieved by lentiviral transduction. Since lentiviral transduction causes increased cell-to-cell variability due to different copy numbers and integration sites of the gene constructs we use a population balance modeling approach to account for this heterogeneity in terms of intracellular viral components and distributed kinetic parameters. The latter are estimated from experimental data of intracellular viral RNA levels and virus titers of infection experiments using cells overexpressing a single host cell gene. For experiments with cells overexpressing multiple host cell genes, only final virus titers were measured and thus, no direct estimation of the parameter distributions was possible. Instead, we evaluate four different computational strategies to infer these from single gene parameter sets. Finally, the best computational strategy is used to predict the most promising candidates for future modifications that show the highest potential for an increased virus yield in a combinatorial study. As expected, there is a trend to higher yields the more modifications are included.
Highlights
Today, a wide range of biopharmaceutical products, e.g. recombinant proteins and viral biopharmaceuticals are produced in cell lines [1]
Population balance model simulations can capture the trend of the experimental virus yield using different single gene overexpression (SGOs)
As a proof of concept, the population balance model is challenged with the obtained distributions and simulated with 7 105 initial target cells and an multiplicity of infection (MOI) of 1 (Fig 2)
Summary
A wide range of biopharmaceutical products, e.g. recombinant proteins and viral biopharmaceuticals are produced in cell lines [1]. Virus-induced changes, related to cell death or to anti-viral signalling, further hamper the process yield To overcome this limitation, one option is to manipulate the expression level of host cell factors (HCFs) relevant for virus replication in order to enhance virus yield. To identify promising HCF candidates costly and time-consuming experimental screening and validation studies are required, as shown recently for poliovirus [2, 3]. This motivates the development of suitable computational tools to predict the impact of genetic modifications in face of the inevitable cellular heterogeneity on the overall product yield. In this study we apply such a methodology to overcome bottlenecks in cell culture-based influenza vaccine production by using genetically modified cell lines
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