Xingmao Liu

Temperature shift as a process optimization step for the production of pro-urokinase by a recombinant Chinese hamster ovary cell line in high-density perfusion culture

Based on the effects of temperature shift on the cell cycle, apoptosis and metabolism of a recombinant Chinese hamster ovary (rCHO) cell line (CL-11G) producing pro-urokinase (pro-UK) in batch cultures, the potential of temperature shift as a tool in the optimization of the perfusion culture of CL-11G cells for the production of pro-UK was examined. The proportion of CL-11G cells in the G0/G1 phase in static cultures increased from 56.4% to 82.8% following a temperature shift from 37 degrees C to 31 degrees C. Conversely, the proportion of CL-11G cells in the S phase decreased from 34.8% to 11.6%. The specific growth rate of CL-11G cells reflected the effect of temperature on the cell cycle and decreased from 0.024 h(-1) at 37 degrees C to 0.006 h(-1) at 31 degrees C. Continuous exposure to the non-permissive temperature of 31 degrees C led to a marginal increase in apoptosis. The specific pro-UK productivity of CL-11G cells increased by 74% at 34 degrees C compared with controls at 37 degrees C in batch cultures. CL-11G cells immobilized with Cytopore 1 in a 5-l bioreactor initiated at 37 degrees C and temperature shifted to 34 degrees C exhibited an average 17% increase in viable cell density and an average 47% increase in pro-UK production. These results demonstrated that temperature shift offers the prospect of enhancing the productivity of pro-UK in high-density perfusion culture.

A high-yield and scaleable adenovirus vector production process based on high density perfusion culture of HEK 293 cells as suspended aggregates

Cells of the human embryonic kidney cell line (HEK 293) were grown as suspended aggregates in stirred vessels and infected with a recombinant adenovirus vector (Ad-TH-GFP). Regular spherical aggregates with the mean diameter less than 300 microm and a viable cell density greater than 5 x 10(6) cells x ml(-1) were readily achieved after 9 day culture in spinner flasks. The HEK 293 cells growing as suspended aggregates could be efficiently infected by Ad-TH-GFP at an MOI of 10 with a prolonging infection time up to 144 hour post-infection (hpi). The time profile of Ad-TH-GFP production was strongly corresponding to the infection process with a virus concentration peak occurred consistently at 144 h after infection. And the infected aggregates essentially maintained spherical in shape, the portion of dissociated cells from the infected aggregates was less than 5% at 144 hpi. Perfusion culture of HEK 293 cells grown as suspended aggregates in a 7.5 L stirred tank bioreactor and infected with Ad-TH-GFP at a density higher than 1 x 10(7) cells x ml(-1) resulted in a similar Ad-TH-GFP production kinetics, but a much higher virus yield approximately at 5.7 x 10(11) GTU ml(-1) at 144 hpi to that of the infected spinner flask cultures. These results demonstrate the feasibility for using suspended cell aggregates as an immobilization system to facilitate perfusion in stirred tank bioreactors, and improve volumetric productivities by eliminating the cell density effect.

Ex vivo expansion of human umbilical cord blood hematopoietic progenitor cells in a novel three-dimensional culture system

A novel three-dimensional culture system for the ex vivo expansion of human umbilical cord blood (CB) hematopietic progenitor cells (HPCs) was developed by growing CB mononuclear cells on highly porous CultiSpher G microspheres coated with human bone marrow stromal cells in stirred flasks in the presence of supplemented cytokines. After 12 days, the number of total viable cells, colony-forming units in culture (CFU-C) and CD34+ cells present in the cultures reflected average increases of 7.7, 23.3 and 9.6-fold, respectively, and marked hematopoietic islands were formed on the surface of CultiSpher G.

Effects of Hydrodynamics on Aggregates Formation, Growth and Metabolism of HEK 293 Cells in Suspension Culture

By using the size distribution of cell aggregates, viable cell density, cell viability, specific consumption rate of glucose (q(glc)), specific production rate of lactate (q(lac)) and lactate transform rate (Y(lac/glc)) as the evaluation indexes, the effects of hydrodynamic on aggregates formation, growth and metabolism of HEK293 cells in suspension culture were examined in 250mL spinner-flasks by setting the agitation rates at 25, 50, 75 and 100r/min, respectively. It was found that agitation plays an important role in HEK293 cell aggregates formation and cell aggregates size distribution. After 7d cultivation in spinner-flasks operated at 50r/min and 75r/min, the average diameter of HEK293 cell aggregates was 201 microm and 175 microm, respectively, with the fraction of aggregates larger than 225 microm less than 10%. The cell viability was kept above 90% with the metabolic indexes, including q(glc), q(lac) and Y(lac/glc) kept constant. These results demonstrated that hydrodynamic derived from the proper agitation play a decisive role in controlling the formation and size distribution of HEK293 cell aggregates, and provided sufficient mass transfer to support the normal growth and metabolism of HEK293 cells in suspended aggregates.

In vitro Cytolysis of B-lymphoma Cells Mediated by an Anti-CD3/Anti-CD20 Bispecific Single-chain Antibody

After having successfully constructed and expressed the gene of the anti-CD3/anti-CD20 bispecific single-chain antibody (bscCD3 x CD20), here we analyzed its in vitro bioactivity of mediating the lysis of Ramous human B-lymphoma cells in the presence of T-enriched human peripheral blood lymphocytes (PBL). Obvious opoptosis characters were observed by Annexin V/PI(AV/PI) stained and scanning electron microscope. As evaluated by non-radioactive cytotoxity assay, the bscCD3 x CD20 showed potent bioactivity of mediating human B-lymphoma cells lysis in the presence of T-enriched human PBL. The potency of cytotoxicity depended on the ratios of effect cells to target cells (E:T) used. Further, the antibody showed a dose and time-dependent effect on mediating Ramous cells lysis. The specific lysis reached about 87.3% at an antibody concentration of 5microg/mL and E:T used at 10:1. Clear changes in apoptogenes expression profiles were detected by apoptosis gene array after Ramous cells were treated with the antibody and PBL. Among the upregulated apoptogenes, ATM and P53 showed an increase of 187 times and 15 times respectively, which suggested that ATM-p53 pathway may be the main apoptosis way of Ramous cells induced by T cells in the presence of the bscCD3 x CD20.