Bioreactor processes based on disposable materials for the production of recombinant proteins from mammalian cells

Mathieu Benjamin Stettler
EPFL, 2007
Thèse EPFL

Résumé

The objective of industrial cell culture technology is to produce high value-added therapeutic proteins that are well suited for the treatment of infectious diseases, cancer, and autoimmune diseases. Nowadays, an important focus is the reduction of the time and costs from the discovery of the candidate molecule to the full-scale production. Relying on enabling technologies is critical for meeting this objective. Simultaneously, novel technologies are expected to increase the clinical and commercial success rates. In recent years, new concepts based on innovative disposable materials emerged and appeared to be promising alternatives to standard bioprocessing equipment. This thesis work was focused on the use of such disposable compounds in mammalian cell culture applications, particularly for the containment of the cells, and was aimed at demonstrating their benefit in terms of cost-effectiveness, ease-of-use and flexibility. First, a novel disposable packed cell volume tube was shown to be ideal for the quick and reliable assessment of biomasses. A characterization and validation of the measurement system demonstrated that it could replace time-consuming and less accurate cell counting methods. Then, to determine the appropriate growth conditions for cells in culture, small-scale single-use tubes were orbitally agitated with conventional lab shakers. This approach was found to be well-suited for multi-parameter optimization strategies. A systematic characterization of the liquid mass transfer in shake tubes proved that sufficient oxygen was available even at cell densities beyond 1 ×107 cells mL-1. Non-invasive optical methods were used to assess the dissolved oxygen variations in various orbital shake vessels, from the milliliter to the multi-liter scale. This simple and yet powerful cultivation principle, orbital shaking, was scaled-up to pilot and production scales. To match the requirements in terms of oxygen transfer at larger scales, a given airflow was provided to replace the gas in the headspace. When required, the airflow was enriched with oxygen. At scales above 20 L, sterile disposable cell cultivation bags were used to contain the cells. Combining orbital shake technology and disposable cell culture bags with a cylindrical shape was promising, both in terms of efficiency and ease-of-use. Prototype shake bioreactors of 200 L and 1'500 L were designed, constructed and operated with maximal cell densities up to 5-7 ×106 cells mL-1 in batch cultivations of CHO cells. The benefits in terms of time and cost savings were even more obvious when novel shake bioreactors were compared with standard stirred-tank bioreactors. This was shown in a realistic optimization, scale-up and production sequence. Most importantly, this work established that orbital shake technology, unlike other disposable cell cultivation systems, can be used for a wide range of operating scales, from only a few milliliters for optimization purposes up to production scale.

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https://infoscience.epfl.ch/record/111604?ln=fr

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Mathieu Benjamin Stettler
EPFL, 2007
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/111604?ln=fr

À propos de ce résultat

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Concepts associés

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Publications associées (61)

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Recombinant cell line generation by standard transfection techniques is a time-consuming and labor-intensive process often leading to an unpredictable outcome as transgene integration is a rare, random event. Consequently, the population of cells obtained after standard gene delivery is heterogeneous in terms of specific growth and recombinant protein productivity. Therefore, genetic selection is usually applied to the population for up to 3 weeks to eliminate non-recombinant cells. A large number of the surviving cell lines must be screened to find a few which stably produce the recombinant protein at the desired level. These must be maintained in culture for 2-4 months in the absence of selection to assess the stability of protein production. In contrast, lentiviral vectors (LVs) deliver the recombinant gene to target cells through infection and a controlled integration process, which allows the inserted transgene to become a permanent genetic element of the transduced cell. Moreover, lentiviruses tend to integrate into transcriptionally active sites of the host cell genome. Hence, LV-mediated gene transfer was expected to increase the probability of generating a stable high-producing clone in comparison to the standard methods based on plasmid transfection. Therefore, the objective of this PhD thesis was to improve the efficiency of stable cell line generation with the use of LVs. For this purpose, LVs carrying the enhanced green fluorescent protein (eGFP) gene under the control of either the cytomegalovirus immediate early promoter/enhancer (CMV) or the elongation factor-1 alpha promoter (EF-1α) were generated and used to infect Chinese hamster ovary (CHO) cells. Two days after gene delivery at a multiplicity of infection (MOI) of 2, up to 98% of infected cells were eGFP-positive. Following isolation by fluorescence-activated cell sorting (FACS), CHO cell pools and clonal cell lines were analyzed for the stability of eGFP expression over time. In these studies, the EF-1α promoter was found to yield more stable and homogeneous protein expression compared to the CMV promoter. For comparison, cell pools and cell lines were generated by transfection with the LV transfer plasmid bearing the eGFP gene. The level and stability of eGFP expression was greater in LV-generated pools and cell lines than in those established by transfection. Subsequently, an LV expressing the tumor necrosis factor receptor-Fc (TNFR-Fc) fusion gene and the eGFP gene from a bicistronic mRNA under the control of the EF-1α promoter (LV_EF-TNFR) was generated and used to infect CHO cells. Based on selective FACS gating for high eGFP expression, stable CHO clones showing volumetric productivities of up to 100 mg/L of TNFR-Fc in a non-optimized batch process could be isolated within 2 days of infection at an MOI of 2. The level of expression of the recombinant protein remained constant for 3 months in serum-free suspension culture and in the absence of chemical selective agents. Next, CHO cells were infected at 3 higher MOIs with the LV_EF-TNFR and clonal cell lines with high eGFP-specific fluorescence were recovered by FACS at 2 d post-infection. These cell lines had volumetric TNFR:Fc productivities ranging from 100 to 400 mg/L in 4-day cultures with cell-specific secretion rates up to 100 pg/cell/day. Moreover, recombinant cell lines developed by the LV-based technology could be successfully cultured in bench-scale bioreactors, yielding up to 1.5 g/L of TNFR:Fc under batch mode operation. The increase in integrated TNFR:Fc copy number was found to correlate with the MOI, and resulted in improved protein productivity. However, this relationship was found to be non-linear: cell saturation in terms of protein productivity and integrated transgene copy number was observed at an MOI of 100. In order to determine the shortest time-frame necessary for the production of satisfactory quantities of a recombinant product, the high MOI-infection approach was tested on pools of transduced cells. Without a priori FACS isolation, recombinant pools of CHO cells expressing on average 500 mg/L of TNFR:Fc within 8 days of inoculation at 3 × 105 cells/ml could be obtained. This strategy provided a simple protocol for high titer recombinant protein production, executable within 4 weeks from LV batch preparation to product harvest. Since large-scale production of LVs would be needed for industrialized bioprocesses, a method for LV production in serum-free suspension culture was developed. However, the best titers generated by this system were still approximately 20-fold lower than the yields obtained regularly from the adherent cultures, thus leaving room for further optimization. In conclusion, LV-mediated gene transfer provided an efficient alternative to plasmid transfection for the generation of stable and high-producing recombinant cell lines. Moreover, it proved amenable to large-scale manufacture and could yield several hundred milligrams per liter of the recombinant product without the need for any kind of genetic selection. In addition, using the LV technology described here it seems possible to target the number of copies of the delivered transgene to a specific range which balances favorable growth with good productivity characteristics.

EPFL2010

Chargement

Transient gene expression for rapid protein production

Natalie Muller

Recombinant proteins are important for biomedical research and for the treatment of human disease. Therefore it is necessary to develop reproducible bioprocesses to rapidly produce proteins of adequate quality and quantity. Expression in mammalian cells is preferred if the proteins are to be properly folded and post-translationally modified. For the rapid production of milligram to gram quantities of a protein in mammalian cells, large-scale transient gene expression is an attractive option. The two most important components of this technology are the cell cultivation system and the gene delivery method. For this reason the goal of this thesis was to develop novel cost-efficient cell cultivation systems and gene delivery methods for the large-scale transfection of mammalian cells in chemically defined media free of any animal-derived components including serum. Cultivation of mammalian cells in suspension is essential for large-scale transient gene expression. A superior system for the cultivation of mammalian cells based on the agitation of cells in "square-shaped" glass bottles (square bottles) was developed. It is an inexpensive but efficient means to grow cells to a high density without instrumentation. The growth and viability of cultures of both human embryo kidney (HEK) 293E and Chinese hamster ovary (CHO) DG44 cells in agitated one-liter square bottles exceeded that in spinner flasks, reaching cell densities 1.5 times higher on average. Furthermore, an efficient and reproducible method to transfect cells in agitated square bottles was developed for both HEK 293E and CHO DG44 cells. A novel gene delivery method termed calfection that relies on the addition of DNA and CaCl2 directly to a suspension culture was developed. Calfection has a number of advantages over existing gene delivery methods such as calcium phosphate-DNA coprecipitation in that there are no time-dependent steps. The DNA/CaCl2 solution can be stored for long periods and is filterable. It is suitable for both large-scale transfections in bioreactors and for high-throughput transfections in microtiter plates. One drawback, however, is its dependence on the presence of serum in the culture medium. A second gene delivery method, serum-free transfection with polyethylenimine (polyfection), proved to be highly efficient for the transfection of both HEK 293E and CHO DG44 cells. A reproducible method for polyfection in microtiter plates, 50 ml centrifuge tubes, agitated square and round bottles, spinner flasks, and bioreactors was optimized for these two cell lines. Polyfection proved to be a simple and successful gene transfer method in both instrumented and non-instrumented cultivation systems. Importantly, it could be performed in serum-free chemically defined media. With HEK 293E cells, 80 mg/l of antibody was produced in agitated square bottles and with CHO DG44 cells, more than 2 g of antibody were produced in one week in a 150-liter bioreactor.

EPFL2005

Chargement

Study of transposon-mediated cell pool and cell line generation in CHO cells

Sowmya Balasubramanian

The goal of this thesis was to evaluate the use of artificial transposon systems for the generation of recombinant cell pools and cell lines with Chinese hamster ovary (CHO) cells as the production host. Transposons are naturally occurring genetic elements present in the genome of most organisms. Several transposons of metazoan origin have been engineered to facilitate the integration of one or more recombinant genes (transgenes) into the genome of the host cell. In this thesis, three of the most commonly used transposons, piggyBac (PB), Tol2, and Sleeping Beauty (SB), were used for transgene delivery into CHO-DG44 cells. The transposon systems described here involves co-transfection of the host cells with a helper plasmid for the transient expression of the transposase, and a donor plasmid coding for the transgene and a gene for the selection, both positioned between two transposon repeat sequences that are required for DNA transposition. Through the optimization of various selection parameters we showed that PB-mediated cell pools can be generated with selection duration of as little as 5 days in the presence of puromycin. All three transposon systems, PB, Tol2, and SB, resulted in cell pools with similar volumetric TNFR:Fc productivities that were about 9 times higher than those generated by conventional plasmid transfection. Transposon-mediated cell pools had 10 - 12 transgene integrations per cell. However, we demonstrated that some the integration events occurred via DNA recombination rather than transposition. We also isolated clonal cell lines from cell pools. As expected, the average volumetric TNFR:Fc productivity of transposon-derived cell lines was higher than that of cell lines generated by conventional transfection. In 14-day fed-batch cultures, protein levels up to 900 mg/L and 1.5 g/L were obtained from transposon-mediated cell pools and cell lines, respectively. The stability over time of the volumetric productivity of cell pools was determined by maintaining the cells in culture for 3 months in the absence of selection. In general, the productivity decreased to 50 % its initial level over the first 7 weeks in culture and then remained constant for the following 5 weeks. In contrast, the volumetric protein yield from transposon-mediated cell lines remained constant for up to 4 months in the absence of selection. We also showed that the three transposon systems could be used for cell pool generation with CHO-K1 and CHO-S with similar volumetric productivities as observed with CHO-DG44 cells. Finally, we utilized the PB transposon system for generating cell pools co-expressing up to 4 different transgenes, enhanced green fluorescent protein (EGFP), secreted alkaline phosphatase (SEAP), and the light and heavy chains of an IgG1 monoclonal antibody, by simultaneous transfection of all four transgenes. We showed that PB-mediated cell pools had increased volumetric productivity of each of the proteins compared to those generated by conventional co-transfection. The use of the PB transposon system increased the percentage of cells in the pools that were co-expressing all four proteins as compared to the results with cell pools generated by conventional transfection. In conclusion, the transfection of CHO cells with the PB, Tol2 or SB transposon system is a simple, efficient, and reproducible approach to the generation of cell pools and cell lines for the rapid production of recombinant proteins.

EPFL2015

Chargement

Transient gene expression for rapid protein production

Natalie Muller

EPFL2005

EPFL2010

Study of transposon-mediated cell pool and cell line generation in CHO cells

Sowmya Balasubramanian

EPFL2015