Methodology for optimal in vitro cell expansion in tissue engineering.

Expansion of the cell population in vitro has become an essential step in the process of tissue engineering and also the systematic optimization of culture conditions is now a fundamental problem that needs to be addressed. Herein, we provide a rational methodology for searching culture conditions that optimize the acquisition of large quantities of cells following a sequential expansion process. In particular, the analysis of both seeding density and passage length was considered crucial, and their correct selection should be taken as a requisite to establish culture conditions for monolayer systems. This methodology also introduces additional considerations concerning the running cost of the expansion process. The selection of culture conditions will be a compromise between optimal cell expansion and acceptable running cost. This compromise will normally translate into an increase of passage length further away from the optimal value dictated by the growth kinetic of the cells. Finally, the importance of incorporating functional assays to validate the phenotypical and functional characteristics of the expanded cells has been highlighted. The optimization approach presented will contribute to the development of feasible large scale expansion of cells required by the tissue engineering industry.

Glycosylation of an immunoglobulin produced from a murine hybridoma cell line: the effect of culture mode and the anti-apoptotic gene, bcl-2.

The impact of bcl-2 over-expression on the glycosylation pattern of an antibody produced by a bcl-2 transfected hybridoma cell line (TB/C3.bcl-2) was investigated in suspension batch, continuous and high cell density culture (Flat hollow fibre, Tecnomouse system). In all culture modes bcl-2 over-expression resulted in higher cell viability. Analysis of the glycans from the IgG of batch cultures showed that >95% of the structures were neutral core fucosylated asialo biantennary oligosaccharides with variable terminal galactosylation (G0f, G1f and G2f) consistent with previous analysis of glycans from the conserved site at Asn-297 of the IgG protein. The galactosylation index (GI) was determined as an indicator of the glycan profile (=(G2 + 0.5* G1)/(G0 + G1 + G2)). GI values in control cultures were comparable to bcl-2 cultures during exponential growth (0.53) but declined toward the end of the culture when there was a loss in cell viability. Low dilution rates in chemostat culture were associated with reduced galactosylation of the IgG glycans in both cell lines. However, at the higher dilution rates the GI for IgG was consistently higher in the TB/C3.bcl-2 cultures. In the hollow fibre bioreactor the galactosylation of the IgG glycans was considerably lower than in suspension batch or continuous cultures with GI values averaging 0.38. Similar low galactosylation values have been found previously for high density cell cultures and these are consistent with the low values obtained when the dissolved oxygen level is maintained at a low value (10%) in controlled suspension cultures of hybridomas.

Suppression of apoptosis in perfusion culture of Myeloma NS0 cells enhances cell growth but reduces antibody productivity.

A spin filter perfusion systems was used to achieve a high cell density culture for two NS0 cell lines in 2 litres bioreactors. One cell line is transfected with the bcl-2 gene (NS0 Bcl-2) encodes the 'anti-apoptotic' human Bcl-2 protein and the other cell line (NS0 Control) with a blank vector. The runs started as batch cultures for two days and were perfused with fresh medium at 0.5 volumes per day (day(-1)) for 4 days, increasing gradually to 2 day(-1) at day 7. The increase of the viable cell density of Bcl-2 cell line was far greater than the control cell line, although they were perfused with the same amount of medium. At the end of the period of each perfusion rate, the viable cell densities of Bcl-2 culture were 30%, 120%, 160% and 220% higher than its control cell line corresponding values. Overall, there was a roughly 9 fold increase in viable cell density from the inoculum for the control culture, but almost a 30 fold increase for the Bcl-2 culture. The mode of cell death in the control culture was initially predominantly by necrosis (viability higher than 80%), but apoptotic cell death became more significant after day 8 of the culture. Cell death in the Bcl-2 culture was almost entirely by necrosis, although it remained at a very low level (less than 5%) to the termination time. The cell cycle distributions for both cell lines were very much similar indicating they have a similar doubling time and G1 to S progression rate. Interestingly, the Bcl-2 cultures exhibited reduced antibody specific production rate with increasing viable cell number and time. The volumetric production rate was, however, similar in both cultures. Bcl-2 as an anti-death protein allowed cells to survive and thus divide to higher cell densities without the need for additional nutrients. Most of the cellular energy in a producer cell line is used for biomass production rather than for antibody production, as was the case with the control cell line.

Measuring the heterogeneity of protein loading in PLG microspheres using flow cytometry.

Poly (DL-lactide co-glycolide) (PLG) microspheres with mean sizes up to 1 microm containing Fluorescein Isothiocyanate labelled Bovine Serum Albumin (FITC-BSA) were prepared by the water-in oil-in water (w/o/w) emulsion solvent evaporation technique. Protein loading and loading efficiency determined by the BCA total protein assay increased with microsphere size as measured by laser diffractometry. Protein loaded microspheres were analysed using flow cytometry (FC) to provide fast and reproducible measurements of the size and protein loading of individual microspheres within a sample thereby quantifying in detail the batch heterogeneity. The FC analysis demonstrated that as the size of individual microspheres within a batch increased, so the protein loading tended to increase. For example, the protein loading of microspheres increased from 2.7 to 8.9 wt.% as the size of microspheres increased from 0.42 to 1.45 microm, respectively. Measurements taken during a subsequent protein release experiment indicated that smaller microspheres within a sample released their protein more quickly than larger sizes. Flow cytometry has been shown to provide detailed information, at the level of individual microspheres, about the heterogeneity in size and protein loading of a microsphere sample and could thus lead to improvement of the release characteristics of microsphere-based delivery systems for biopharmaceuticals.

Characterisation of Tetraploid and Diploid Clones of Spodoptera frugiperda Cell Line.

We have isolated and characterised diploid and tetraploid clones from the normally heterologous Spodoptera frugiperda (Sf-9)cell line by dilution cloning technique. Tetraploid clones were found to have cell sizes in excess of 35% larger than that of the diploid clones. In contrast, the maximum cell numbers achieved in batch cultures of diploid clones were on average 185% higher than the tetraploid cell numbers. Growth rates and metabolic quotients during the exponential phase were similar for both clones. Tetraploid cells infected with wild-type and recombinant green fluorescent protein (GFP) baculovirus, resulted in more polyhedra or GFP product per cell. Importantly, the difference between the clones either completely diminished or reduced to 50% when the yield was assessed in terms of the amount of polyhedra or GFP per mL of medium, respectively. These results indicate that the existing heterogeneity in insect cell populations with respect to ploidy level, are correlated to cell growth and product yield.

Chromosome instability in Spodoptera frugiperda Sf-9 cell line.

Homogeneous cell lines are essential in industry and research if reliable and reproducible data are to be obtained. The Spodoptera frugiperda (Sf-9) cell line routinely used for the production of recombinant proteins was found to be heterogeneous, containing a mixture of diploid and tetraploid cells. Using dilution-cloning techniques, diploid and tetraploid subpopulations were isolated from a Sf-9 parental cell line, and their cytogenetic state was monitored using Vinblastine to arrest cells in mitosis. Flow cytometry was used to obtain a snapshot of the predominant subpopulations present to verify the karyological results. The rate at which clonal populations digress into the heterogeneous state was found to be more rapid for the diploid subpopulation, with the emergence of tetraploid cells after only 11 passages, than for the tetraploid subpopulation, where diploid clones appeared after 18 passages. The chromosomes in both diploid and tetraploid subpopulations as well as the parental cell line were found to spontaneously fragment during growth and expansion processes, giving rise to variable chromosome numbers. DNA analysis of cell lines obtained from laboratories worldwide have shown that the Sf-9 cell line used for the production of many recombinant proteins is cytologically unstable, leading to varying degrees of polyploidal state depending on its culture history and supplier.

Role of vitamins in determining apoptosis and extent of suppression by bcl-2 during hybridoma cell culture.

The identification of cell culture media components that may instigate apoptosis in cell lines used for the production of commercial antibodies and recombinant proteins, is crucial to aid the development of improved media for reduced cell death and to understand the role of nutrient components in cell survival and maintenance. Here we determine the impact of depriving all or individual B-group media vitamins either, D-CaPantothenate (DCaP), choline chloride (CC), riboflavin (Rb), i-inositol, nicotinamide (NAM), pyridoxal hydrochloride (PyrHCl), folic acid (FA), or thiamine hydrochloride (ThHCl) on hybridoma cell growth and viability using fluorescence microscopy techniques. Cultivation in media deprived of all these vitamins prevented cell proliferation from reaching maximum capacity while increasing cell death rate, predominantly via apoptosis. Deletion of either DCaP, CC, or Rb showed that these components were most likely responsible for the development of apoptosis. Exclusion of either i-inositol, NAM or PyrHCl failed to inhibit cell growth and viability, while marginal improvements in viability were noted by ThHCl deprivation and more so by FA exclusion. Over-expression of the anti-apoptotic gene bcl-2 suppressed cell death initiated by all or single vitamin (either DCaP, CC or Rb) deprivation. The involvement of bcl-2 activity, established a close association between small vitamin molecules particularly DCaP, CC or Rb and the biochemical activation of apoptosis.

Relationship between cell proliferation, cell-cycle phase, and retroviral vector production in FLYRD18 human packaging cells.

The relatively low concentrations of retroviral vectors produced by most packaging cells requires the optimization and intensification of their production to make a commercially viable product for gene therapy. While a number of reports exist concerning target cell-cycle effects on retroviral vector infection efficiency, no studies have been reported on the effects of packaging cell cycle on vector production. We have studied the effect of proliferation of the human packaging cell line, FLYRD18, on vector production. In addition, the titer levels of vector produced by cells in each phase of the cell cycle were compared. Numerous studies suggested progression of the cells through the cell cycle to be essential for vector production. However, vector release was found not to be predominant in any particular phase of the cell cycle. These findings indicate that packaging cell proliferation is important for optimal virus production and that arrest of the cells in any particular phase of the cell cycle affords no benefits in retroviral vector production. In contrast to previous reports (using other cell lines), we observed no temporary inhibition of cell cycle progression after detachment of cells from their substratum and that virus production occurred immediately after re-plating of the cells. The findings in this report are important for determining the optimal culture conditions for vector production by packaging cells in vitro.

Using the Microcyte flow cytometer to monitor cell number, viability, and apoptosis in mammalian cell culture.

The Microcyte is a novel, portable flow cytometer based on diode laser technology whose use has been established for yeast and bacterial analysis. We present data that demonstrate its suitability for routine mammalian cell counting and viability determination. To extend its range of applications in the field of animal cell culture biotechnology, a test to determine the number of apoptotic cells present has been developed for use with the instrument. Apoptosis was induced in hybridoma cell cultures by treatment with camptothecin. Apoptotic cells were labeled with biotinylated Annexin V and then visualized using a streptavidin-allophycocyanin conjugate. Their numbers were counted, and the cell size of the apoptotic cell population was determined using the Microcyte.

Effects of culture parameters on the production of retroviral vectors by a human packaging cell line.

The use of retroviral vectors for human gene therapy requires the production of large quantities of high titer vector stocks. Maintaining high titers during the prolonged culture of packaging cells will require that critical parameters be controlled. The aim of this study was to determine which culture parameters critically affect the production/decay of retroviral vectors produced by the human packaging cell line FLYRD18/LNC-hB7. The stability of retroviral vectors released by this cell line was found to be temperature dependent (half-life of 6.9, 11.0, and 64.3 h when incubated at 37, 32, and 0 degrees C, respectively). Titers increased up to 10-fold when the packaging cells were cultured at 32 degrees C, compared to 37 degrees C, despite a decrease in cell yield (cell-specific titers were 20-fold higher). Virus titers were also over 10-fold higher when the packaging cells were cultured in a reduced serum concentration (1%) compared to 5%. Retrovirus production at a range of pH levels revealed a significant decrease in virus titer at pH levels below 6.8 and above 7.2, optimum titers being achieved in cultures at pH 7.2. Dissolved oxygen levels in the range 20-80% did not significantly affect titers under the conditions tested. Finally, a packed bed system containing the packaging cells immobilized on porous microcarriers was shown to sustain the production of active retroviral vectors for over 1 month, in relatively large volumes.

Bcl-2 mediated suppression of apoptosis in myeloma NS0 cultures.

The influence of Bcl-2 expression on the suppression of apoptosis during the cultivation of an NS0 cell line expressing a chimeric antibody was investigated. Following selection of transfectants in medium containing G418, Western analysis revealed evidence of some up-regulation of endogenous Bcl-2 expression even in the control vector transfectants. Cultivation of the two cell lines in suspension batch cultures clearly demonstrated the enhanced robustness of the bcl-2 vector transfected cells. Suppression of apoptosis resulted in an approximately 20% increase in maximum viable cell number, and a doubling in culture duration compared to the control transfected cells. However, despite the significant affect on viability, Bcl-2 expression did not result in an increase in final antibody titre in comparison with the control cell line. Exposure of cells to various nutrient limited conditions further emphasised the influence of Bcl-2 on cell survival. After 3 days of exposure to serum, glucose, glutamate and asparagine deprivation, the viable cell number and viability were significantly higher in the bcl-2 transfected cell line. When control cells were deprived of all amino acids, there was a complete loss of viability and viable cell number within 3 days. By contrast, the bcl-2 transfected cell line retained greater than 75% of the initial viable cell number and about 70% viability. In response to exposure to 8 mM thymidine (a cytostatic agent) the control cell line underwent complete loss of viability and viable cell number after 6 days. This compared with 18 days for complete loss of viability in the bcl-2 transfected cell line. As under batch culture conditions, there was no difference between the two cell lines in final antibody titre, which indicated that MAb synthesis is limited by nutrient availability during the latter stages of culture in both cases. When fed batch cultures were carried out using a concentrated essential amino acid feed, the bcl-2 cell line exhibited a 60% increase in maximum viable cell number and a 50% increase in culture duration, when compared to the control cell line. Moreover, the bcl-2 cell line exhibited a greater than 40% increase in maximum antibody titre.

Influence of bcl-2 on cell death during the cultivation of a Chinese hamster ovary cell line expressing a chimeric antibody.

The influence of Bcl-2 expression on the robustness of a CHO cell line (22H11) developed for the industrial production of a chimeric antibody was evaluated. Western blot analysis following transfection with the expression vector unexpectedly revealed upregulation of endogenous Bcl-2 expression in the control (Neo) cell line in response to exposure to the selection drug G418. This indicated that geneticin may function by inducing apoptosis in cells not carrying the control plasmid or expressing very low levels of survival genes. Thus, exposure to the drug enriched the culture for a population of cells which expressed enhanced levels of endogenous Bcl-2. In batch cultures, ectopic bcl-2 expression resulted in a 75% increase in maximum viable cell density over control cultures. Moreover, the rate of decrease in viability in the Bcl-2 cultures was significantly lower than that in the control cultures. After 18 days, the Bcl-2 viability was around 90%, compared to 20% in the control cultures. Evaluation of the mechanism of cell death revealed very few cells with classical apoptotic morphology. Around 10% were clearly necrotic, but the majority of dead cells were seen as chromatin free but otherwise relatively intact structures. Because of the relatively low rate of cell death in both cell lines, few cells were observed in the transitional, easily identifiable early stages of apoptosis. However, DNA gel electrophoresis revealed a clear ladder-pattern, but only in the control cultures, thus confirming high levels of apoptotic death. Antibody concentrations during both sets of cultures were very similar, both during the growth and death phases, with a maximum titer of around 40 microgram/ml. Analysis of Bcl-2 expression by flow cytometry revealed that the cultures contained two populations of cells: a large population which expressed high levels of Bcl-2 and a relatively smaller low-expressing population. During the course of the batch, the smaller, low-expressing population declined in frequency, suggesting that these cells were more sensitive to cell death. In addition, the mean level of Bcl-2 expression in the overexpressing population also declined significantly, presumably reflecting the exhaustion of precursors for protein synthesis following nutrient depletion. Importantly, when cells were taken from day 40 of the significantly extended Bcl-2 batch cultures, they immediately proliferated, confirming that they had retained their replicative potential. Cultivation of the cells in basal medium lacking (individually) serum, all amino acids, glutamate/asparagine, and, finally, glucose, resulted in relatively lower viable cell numbers and viability in the control cell line compared to the Bcl-2 cell line. Exposure of cells to ammonia toxicity also revealed the relative robustness of the bcl-2 transfected cells. When growth was arrested by treatment with 4 mM thymidine, Bcl-2 overexpressing cells exhibit a viability of over 80% after 5 days in culture, compared to only 40% in the control cell line. However, under growth-arrested conditions, there was no major difference in antibody titer between the two cell lines.

Relationship between cell size, cell cycle and specific recombinant protein productivity.

Centrifugal elutriation was used to produce cell cycle enrichedfractions of four commercially relevant recombinant cell lines,chosen to allow for variation in properties due to construct,expression system and parent cell type, from normally growingheterogeneous batch cultures. As these fractions had identicalculture histories and had not been subjected to any insult orstress which was likely to have adversely affected cellularmetabolism, they were ideal for further study of cellularproperties. Specific productivity, cell size and cell cyclestate of replicate elutriated fractions were measured for eachcell line. Results showed that cell size was the major cellulardeterminant of productivity for all cell lines examined. Productformation was not restricted to any particular cell cycle phaseand in all cases, production occurred irrespective of cell cyclephase. Specific productivity was lowest when the majority ofcells in the fraction were G(1), intermediate when themajority of cells in the fraction were S phase and greater whenthe majority of cells in the fraction were in G(2)/M. However, the evidence suggests that size is the major cellulardeterminant of productivity; the apparent relationship betweencell cycle and productivity is secondary and can simply beascribed to the increasing size of cells as they progress thoughthe cell cycle. Thus, in addition to cell density and viabilitycell size is the cellular parameter which should be incorporatednot only into mathematical models of recombinant mammalian cellproduction processes but also into process monitoring andcontrol strategies.

Improved cell line development by a high throughput affinity capture surface display technique to select for high secretors.

A novel process is described which permits rapid and objective selection of rare cells from a heterogeneous population based on quantity of secreted target protein. The process involves construction of an immobilised affinity surface display matrix that specifically binds secreted target product which is then detected using a fluorescent labelled ligand. Cells with the highest fluorescence can then be sorted using conventional flow cytometric technology. Overall, the whole process can be completed in less than 4 h during which time in the region of five million cells can be analysed. Cells are rapidly selected for in a quantitative manner compared to traditional methods which can take several months and have a reduced probability of finding low abundance high secretors due to practical limitations imposed on the number of cells which can be screened.

Growth and enumeration of the meat spoilage bacterium Brochothrix thermosphacta.

Brochothrix thermosphacta is a common meat spoilage bacterium. The morphology of this bacterium changes from coccobacilli and short rods to chains during growth, which may give a false estimation in numbers using some enumeration techniques. Methods for the quantification of this bacterium have been compared. Turbidimetric readings showed good agreement with cell dry weight indicating that the former provides a good measure of the change in cell mass during growth. The turbidimetric method also correlated well with bacterial numbers determined by plate counts, flow cytometry and manual counts (by microscope) over a limited range of 10(7)-10(9) cells/ml. Flow cytometry and manual counts gave a linear relationship over a wider range of 10(5)-10(9) cells/ml. The sensitivity of analysis, growth rates and lag time attained using these methods were also compared. As a consequence of changes in bacterial cell size during growth, turbidimetry over-estimated the growth rate. The plate count method proved unable to detect the difference between bacteria existing as chains or single cells. The sensitivity of analysis and the calculated growth related parameters were similar for flow cytometry and manual counts. This suggests that flow cytometry is capable of counting individual cells in a chain. Further investigation showed that passage of B. thermosphacta cells through the flow cytometer resulted in the breakage of chains into single cells. The reliability, low error and rapidity of this technique make it attractive for bacterial enumeration, something which has been demonstrated using B. thermosphacta, a bacterium which exhibits complex morphologies.

Automatic image analysis for quantification of apoptosis in animal cell culture by annexin-V affinity assay.

Apoptosis is a form of cell death in which the dying cell plays an active part in its demise. At the morphological level, it is characterised by cell shrinkage rather than the swelling seen in necrotic cell death. In cell culture, apoptosis limits the yield of economically and medically important products, and can result in synthesis of imperfect molecules. Therefore, this process must be identified, monitored and fully understood, so that a means to regulate it can be developed. We have developed a new automatic image analysis assay for detecting apoptosis in animal cell culture on the basis of the annexin-V affinity assay. The results of this assay were compared with data generated by flow cytometry and manual scoring. All three methods were found to correspond well but image analysis like flow cytometry offers operator-independent results, and can be used as a tool for rapid monitoring of viable cell number, apoptosis and necrosis in animal cell culture. Furthermore, reduction in cell size was measured and was found to precede the appearance of phosphatidylserine on the cell surface.

Production of retroviral vectors for gene therapy with the human packaging cell line FLYRD18.

The development of gene therapy is hampered by the difficulty of producing large stocks of retroviral vectors at high titer. This study aimed to improve culture conditions and to intensify the production of retroviruses by FLYRD18, a packaging cell line derived from the HT1080 human fibrosarcoma line. Batch virus production proved to be feasible in unsupplemented basal medium and provided significantly higher titers and productivities than medium supplemented with 10% serum. For longer-term production, however, AIM-V complete serum-free medium and basal medium supplemented with 2% serum gave superior results. Serum supplementation should nevertheless be optimized to take into account the presence of inhibitors of viral production. In monolayer cultures with 0.2 mL/cm(2), the cell concentration was increased up to 2 x 10(6) cells/mL without loss of cell productivity. A semicontinuous production process, which enables the collection of larger amounts of viruses from the same culture, has also been successfully used. Suspension culture processes were prevented by the anchorage dependency of the FLYRD18 cell line. Microcarrier cultures were able to produce viruses but will require further investigation and optimization for their performance to become competitive with monolayer cultures. In the course of this study, more than a 10-fold increase of titer has been achieved.

Improved titers of retroviral vectors from the human FLYRD18 packaging cell line in serum- and protein-free medium.

The influence of serum on the production of retroviral vectors by the HT1080 human fibrosarcoma-derived packaging cell line FLYRD18 was investigated. A fourfold increase in virus titer was observed under serum-free conditions, as compared with medium supplemented with 10% fetal calf serum. A similar improvement was also seen for bulk transduction efficiency. Serum had a negative and dose-dependent effect on titer without affecting cell growth, virus stability, or infectivity. In contrast to virus from NIH 3T3-derived packaging cells [Hanenberg, H., et al. (1996). Nature Med. 2, 876-882], the FLYRD18-derived virus did not adhere to fibronectin or serum proteins adsorbed at the surface of culture flasks. Electron microscopy supports the conclusion that the effect of serum is at the level of virus production by the cells. Addition of soybean trypsin inhibitor had an inhibitory effect on virus production, while pretreatment of serum with trypsin was found to enhance the retroviral titer. These results suggest that protease inhibitors present in serum may be responsible for the inhibition of virus production. The exact mechanism remains, however, to be determined. As compared with medium supplemented with 10% serum, the combination of increased virus titer and absence of exogenous protein under serum-free conditions resulted in a 300-fold increase in the virus:total protein ratio in the supernatants harvested from the FLYRD18 packaging line. This improvement enhances prospects for further concentration and purification of the virus.

Bcl-2 over-expression reduces growth rate and prolongs G1 phase in continuous chemostat cultures of hybridoma cells.

Recent studies have suggested that Bcl-2 can affect cell cycle re-entry by inhibiting the transition from G0/G1 to S phase. In this study, we have taken a novel route to the study of the relationship between Bcl-2 expression and cell cycle progression. Continuous cultures of pEF (control) and Bcl-2 transfected murine hybridoma cells were operated at a range of dilution rates from 0.8 day-1 down to 0.2 day-1. The specific growth rate of the pEF cell line was the same as the dilution rate down to a value of 0.6 day-1. However, as the dilution rate was reduced stepwise to 0.2 day-1, the growth rate levelled-off at approximately 0.55 day-1 and this coincided with a fall in culture viability. By contrast, the specific growth rate of the Bcl-2 transfected cell line followed the dilution rate down to a value of 0.3 day-1 with high levels of cell survival. At high dilution rates, the cell cycle distributions were very similar for both cell lines. However, the distributions diverged as the dilution rate was reduced and, at a rate of 0.2 day-1, the percentage of G1 cells in the Bcl-2 culture was 80%, compared to only 56% in the pEF cell population. This corresponded with a greater extension in the duration of the G1 phase in the Bcl-2 cells, which was 1.7 days at the lowest dilution rate tested, compared to only 0.6 day for the pEF cell line. The durations of the G2/M and S phases remained constant throughout the culture. The maximum doubling time was 1.2 days in the pEF culture compared to 2.3 days in the Bcl-2 culture. Analysis of amino acids, ammonia and lactate concentrations indicated that the observed effects on cell cycle dynamics were probably not due to differences in the culture environment. It is suggested that the expression of Bcl-2 can effect G1 to S phase transition in continuously cycling cells, but this is only apparent at suboptimal growth rates.

The role of the cell cycle in determining gene expression and productivity in CHO cells.

Understanding the relationships between cell cycle and protein expression is critical to the optimisation of media and environmental conditions for successful commercial operation of animal cell culture processes. Using flow cytometry for the analysis of the early phases of synchronised batch cultures, the dependency of product expression on cell cycle related events has been evaluated in a recombinant CHO cell line. Although the production of recombinant protein is initially found to be cell cycle related, the maximum specific protein productivity is only achieved at a later stage of the exponential phase which also sees a maximum in the intracellular protein concentration. Subsequent work suggests that it is the batch phase/medium composition of cultures which is the major determinant of maximum specific productivity in this cell line. Furthermore the effect of the positive association between S phase and specific productivity is subordinate to the effect of batch phase/medium composition on the specific productivity of batch cultures.