Structural analysis of random transgene integration in CHO manufacturing cell lines by targeted sequencing.

Genetically modified CHO cell lines are traditionally used for the production of biopharmaceuticals. However, an in-depth molecular understanding of the mechanism and exact position of transgene integration into the genome of pharmaceutical manufacturing cell lines is still scarce. Next-generation sequencing (NGS) holds great promise for strongly facilitating the understanding of CHO cell factories, as it has matured to a powerful and affordable technology for cellular genotype analysis. Targeted Locus Amplification (TLA) combined with NGS allows for robust detection of genomic positions of transgene integration and structural genomic changes occurring upon stable integration of expression vectors. TLA was applied to generate comparative genomic fingerprints of several CHO production cell lines expressing different monoclonal antibodies. Moreover, high producers resulting from an additional round of transfection of an existing cell line (supertransfection) were analyzed to investigate the integrity and the number of integration sites. Our analyses enabled detailed genetic characterization of the integration regions with respect to the number of integrates and structural changes of the host cell's genome. Single integration sites per clone with concatenated transgene copies could be detected and were in some cases found to be associated with genomic rearrangements, deletions or translocations. Supertransfection resulted in an increase in titer associated with an additional integration site per clone. Based on the TLA fingerprints, CHO cell lines originating from the same mother clone could clearly be distinguished. Interestingly, two CHO cell lines originating from the same mother clone were shown to differ genetically and phenotypically despite their identical TLA fingerprints. Taken together, TLA provides an accurate genetic characterization with respect to transgene integration sites compared with conventional methods and represents a valuable tool for a comprehensive evaluation of CHO production clones early in cell line development.

Visualisation of intracellular production bottlenecks in suspension-adapted CHO cells producing complex biopharmaceuticals using fluorescence microscopy.

With the advance of complex biological formats such as bispecific antibodies or fusion proteins, mammalian expression systems often show low performance. Described determining factors may be accumulation or haltering of heterologous proteins within the different cellular compartments disturbing transport or secretion. In case of the investigated bispecific antibody (bsAb)-producing Chinese hamster ovary (CHO) cell line neither impaired transcription nor decreased translation processes were identified and thus satisfactorily explained its low production capacity. Hence, we established a streamlined confocal microscopy-based methodology for CHO production cells investigating the distribution of the recombinant protein within the respective organelles of the secretory pathway and visualised the structure of the endoplasmic reticulum (ER) to be affected pinpointing towards an intra-ER bottleneck putatively hampering or limiting efficient secretion. The ER displayed not only a heavily altered morphology in comparison to a high immunoglobulin G (IgG)-producing cell line with a possibly inflated or overloaded structure, but the recombinant protein was also completely absent in the Golgi apparatus. Notably, the results obtained using an automated microscopy approach suggest the possible application of this methodology in cell line development and engineering.

A single-step FACS sorting strategy in conjunction with fluorescent vital dye imaging efficiently assures clonality of biopharmaceutical production cell lines.

The development of biopharmaceutical production cell lines typically starts with generation of heterogeneous populations of cells, from which then single cell clones are established. Several regulatory guidelines require that production cell lines are clonal, and the actual demonstration of clonality has been increasingly demanded by regulatory authorities over the last years. Here, the authors describe the relative contribution of flow cytometry mediated deposition of single cells in multiwell plates and subsequent imaging to assurance of clonality in a state of the art approach to single cell generation. Within the flow cytometry step, two unit operations are evaluated separately, doublet discrimination during event selection for deposition and droplet deposition accuracy. The imaging procedure is evaluated for the accuracy of detection of non-clonal populations. By employing mixing experiments of cell populations, the authors demonstrate that doublet discrimination is highly efficient, and that an appropriately set up flow cytometry system already can generate >99.5% true single cell clones. The efficiency of the described imaging process depends on several factors, reaching an optimal detection rate of non-clonal wells of about 99.8%. Our results demonstrate that one well characterized cloning step generate biopharmaceutical production cell lines with a probability of clonality of >99.99%.

Use of flow-cytometric analysis to optimize cell banking strategies for production of biopharmaceuticals from mammalian cells.

Production of biopharmaceuticals from mammalian cells requires generation of master, working and post-production cell banks of high quality under GMP conditions. An optimal cryopreservation strategy is needed for each new production cell line, particularly with regard to establishing production processes that are completely devoid of serum or even any animal components and to ensuring robust thaw performance for reliable production. Here, we describe a novel strategy employing flow-cytometric (FC) analysis of Annexin V-stained cells for high-throughput characterization of cell banks. Our data show that this method enables predictive evaluation of a cryopreservation strategy as early as 6h after thawing of cells. Furthermore, a broad study is presented characterizing various factors that may influence the quality of serum-free production cell banks from NSO and CHO cell lines. These results demonstrate how FC-based analysis can be used for development of future state-of-the-art cryopreservation strategies.