Early prediction of instability of Chinese hamster ovary cell lines expressing recombinant antibodies and antibody-fusion proteins.

One of the most important criteria for the successful manufacture of a therapeutic protein (e.g., an antibody) is to develop a mammalian cell line that maintains stability of production. Problems with process yield, lack of effective use of costly resources, and a possible delay in obtaining regulatory approval of the product may ensue otherwise. Therefore the stability of expression in a number of Chinese hamster ovary (CHO) derived production cell lines that were isolated using the glutamine synthetase (GS) selection system was investigated by defining a culture as unstable if the titer (which is a measure of productivity) of a cell line expressing an antibody or antibody-fusion protein declined by 20-30% or more as it underwent 55 population doublings. Using this criterion, a significant proportion of the GS-selected CHO production cell lines were observed to be unstable. Reduced antibody titers correlated with the gradual appearance of a secondary, less productive population of cells as detected with flow cytometric analysis of intracellular antibody content. Where tested, it was observed that the secondary population arose spontaneously from the parental population following multiple passages, which suggested inherent clonal instability. Moreover, the frequency of unstable clones decreased significantly if the host cell line from which the candidate production cell lines were derived was apoptotic-resistant. This data suggested that unstable cell lines were more prone to apoptosis, which was confirmed by the fact that unstable cell lines had higher levels of Annexin V and caspase 3 activities. This knowledge has been used to develop screening protocols that identify unstable CHO production cell lines at an early stage of the cell line development process, potentially reducing the cost of biotherapeutic development.

Utilization of site-specific recombination for generating therapeutic protein producing cell lines.

The AttSite Recombinase Technology from Intrexon, Blacksburg, VA, utilizes specific DNA sequences and proprietary recombinase enzymes to catalyze the insertion of a gene of interest at a specific location in the host cell genome. Using this technology, we have developed Chinese Hamster Ovary (CHO) cell lines that have incorporated attB recombination sites at highly transcriptionally active loci or 'hot spots' within the cell genome. Subsequently, these attB site containing host cell lines could then be used for the expression of future Centocor products. Candidate production cell lines would be generated by a simple recombination event. Since the therapeutic gene of interest would preferentially integrate into the pre-selected high-expressing attB site, candidate cell lines would consistently express high levels of the gene of interest. We have been able to demonstrate that the AttSite Recombinase Technology could be a valid approach for the development of high-expressing production cell lines.

Characterization of antibodies to CA 125 that bind preferentially to the cell-associated form of the antigen.

OBJECTIVE: Antibodies to CA 125 have been used to predict relapse of ovarian cancer, but have performed poorly as therapeutic agents. One rationale for this is antibody binding to circulating shed antigen. Our aim in this study was to develop antibodies to human CA 125 that have enhanced selectivity for the cell-associated form of the antigen. METHODS: Monoclonal antibodies were raised to a recombinant fragment of CA 125 that included sequence proximal to the putative membrane attachment site. Antibodies were characterized in terms of their binding site, affinity and selectivity for cell-associated CA 125. RESULTS: In assays using patient-derived CA 125, a subset of high-affinity (KD <5 nM) monoclonal antibodies demonstrated a 10- to greater than 200-fold increase in selectivity for cell-associated CA 125 when compared with controls. Based on mapping of the various monoclonal antibodies obtained, it was determined that shedding of CA 125 most likely occurs in the most C-terminal repeat domain. CONCLUSION: Results from competition analysis using patient-derived shed antigen predict that the antibodies described in this study may have significantly enhanced tumor-targeting properties when compared with existing antibodies to CA 125 in a tumor environment having high concentrations (>10,000 CA 125 units) of shed CA 125.

Generation and characterization of a panel of monoclonal antibodies specific for human fibroblast growth factor receptor 4 (FGFR4).

Fibroblast growth factor receptor 4 (FGFR4) is a member of the FGFR family of receptor tyrosine kinases, and plays important roles in a variety of biological functions such as cell proliferation, differentiation, migration, angiogenesis, tissue repair, and tumorigenesis. The human FGFRs share a high degree of sequence homology between themselves, as well as with their murine homologs. Consequently, it has been suggested that it may be difficult to prepare monoclonal antibodies (MAbs) that are specific for the individual receptor types. In this communication, we report on the development and characterization of a panel of anti-human FGFR4 MAbs that were generated in mice using a rapid immunization protocol. Using a modified rapid immunization at multiple sites (RIMMS) protocol with the soluble extracellular domain of human FGFR4 (FGFR4-ECD), the immunized mice developed high levels of polyclonal IgG to the immunogen within 13 days of the first immunization. The lymph node cells isolated from the immunized animals were then fused with mouse myeloma cells for hybridoma generation. Use of an efficient hybridoma cloning protocol in combination with an ELISA screening procedure allowed for early identification of stable hybridomas secreting antihuman FGFR4 IgG. Several identified MAbs specifically reacted with the FGFR4 protein without binding to the other human isoforms (FGFR1, FGFR2, and FGFR3). As evaluated by BIAcore analysis, most anti-FGFR4 MAbs displayed high affinities (8.6 x 10(8) approximately 3.9 x 10(10) M) to FGFR4. Furthermore, these MAbs were able to bind to FGFR4 expressed on human breast tumor cell lines MDA-MB-361 and MDA-MB-453. Taken together, the results demonstrate that the RIMMS strategy is an effective approach for generating class-switched, high-affinity MAbs in mice to evolutionarily conserved proteins such as human FGFR4. These MAbs may be useful tools for further investigation of the biological functions and pathological roles of human FGFR4.

Functional expression and display of an antibody Fab fragment in Escherichia coli: study of vector designs and culture conditions.

Several different vector designs are currently being used to display and express Fab molecules in Escherichia coli, but their relative efficiency in phage display and protein expression cannot be compared from the published data. We systematically investigated which vector design most effectively displays and expresses Fab molecules in E. coli using, as a model system, a human Fab against tetanus toxoid (tt). Three different vectors were used in this study: pFab1 where the VL-CL and VH-CH1 genes were driven by two promoters in two separate expression cassettes, and pFab2 and pFab3 that both contain one dicistronic expression cassette with two translation initiation sites and either VH-CH1 before VL-CL or VL-CL before VH-CH1, respectively. The display of tt-Fab on the surface of phage and the expression of tt-Fab protein in E. coli were compared for the aforementioned vectors. Our results showed that the pFab3 vector was most effective in Fab display. A 10-fold increase in the expression of secreted Fab was observed in pFab3 when compared with vectors pFab1 and pFab2. Further experiments were conducted using pFab3 to optimize expression levels using different strains of E. coli and various culture conditions. The highest expression of tt-Fab was obtained using the pFab3 vector in host strain JM105 with an induction temperature at 37 degrees C and IPTG concentration of 0.1 mM.