Reciprocal Translocation Observed in End-of-Production Cells of a Commercial CHO-Based Process.

UNLABELLED: During the validation of an additional working cell bank derived from a validated master cell bank to support the commercial production continuum of a recombinant protein, we observed an unexpected chromosomal location of the gene of interest in some end-of-production cells. This event-identified by fluorescence in situ hybridization and multicolour chromosome painting as a reciprocal translocation involving a chromosome region containing the gene of interest with its integral coding and flanking sequences-was unique, occurred probably during or prior to multicolour chromosome painting establishment, and was transmitted to the descending generations. Cells bearing the translocation had a transient and process-independent selective advantage, which did not affect process performance and product quality. However, this first report of a translocation affecting the gene of interest location in Chinese Hamster Ovary cells used for producing a biotherapeutic indicates the importance of the demonstration of the integrity of the gene of interest in end-of-production cells. LAY ABSTRACT: The expression of recombinant therapeutic proteins in mammalian cells depends on the establishment of a cell line with the gene of interest integrated in the host genome and stably expressed over time. Before being used for commercial production, cell lines are submitted to a qualification program in order to ensure their phenotypic and genotypic characteristics and the efficacy and safety of the product. During the production life cycle of a therapeutic protein, additional cells banks have to be validated after exhaustion of the current qualified cell bank in order to support the commercial production continuum of the recombinant protein. It is during the validation of an additional working cell bank derived from a validated master cell bank that we detected a different chromosome bearing the gene of interest in a portion of cells at the end of the upstream production phase. In our case, this event did not affect the process performance, the product quality, or its safety profile, but it highlights the need to characterize the integrity of the gene of interest in end-of-production cells when producing recombinant proteins for human use.

Cell culture medium improvement by rigorous shuffling of components using media blending.

A novel high-throughput methodology for the simultaneous optimization of many cell culture media components is presented. The method is based on the media blending approach which has several advantages as it works with ready-to-use media. In particular it allows precise pH and osmolarity adjustments and eliminates the need of concentrated stock solutions, a frequent source of serious solubility issues. In addition, media blending easily generates a large number of new compositions providing a remarkable screening tool. However, media blending designs usually do not provide information on distinct factors or components that are causing the desired improvements. This paper addresses this last point by considering the concentration of individual medium components to fix the experimental design and for the interpretation of the results. The extended blending strategy was used to reshuffle the 20 amino acids in one round of experiments. A small set of 10 media was specifically designed to generate a large number of mixtures. 192 mixtures were then prepared by media blending and tested on a recombinant CHO cell line expressing a monoclonal antibody. A wide range of performances (titers and viable cell density) was achieved from the different mixtures with top titers significantly above our previous results seen with this cell line. In addition, information about major effects of key amino acids on cell densities and titers could be extracted from the experimental results. This demonstrates that the extended blending approach is a powerful experimental tool which allows systematic and simultaneous reshuffling of multiple medium components.

Efficacy and safety of ABI793, a novel human anti-human CD154 monoclonal antibody, in cynomolgus monkey renal allotransplantation.

BACKGROUND: Anti-CD154 monoclonal antibodies (mAbs) cause long-term graft survival in preclinical allotransplantation experiments. This is the first report on the efficacy and safety of ABI793, a novel human anti-human CD154 mAb, in Cynomolgus renal transplant recipients. METHODS: ABI793 (human immunoglobulin-G1:kappa) was derived from a hybridoma generated after immunization of human immunoglobulin transgenic mice (HuMAb-Mouse, Medarex Inc., Annandale, NJ). Cynomolgus monkey recipients of major histocompatibility complex-mismatched, life-supporting renal allografts were treated repeatedly with intravenous ABI793 for a 3-month period posttransplantation. Graft function was monitored by serum creatinine, and rejection was confirmed histologically. RESULTS: ABI793 binds to human, Cynomolgus and Rhesus monkey CD154; it inhibits dose dependently in vitro CD154:CD40 binding and human mixed lymphocyte reaction. ABI793 is comparable to the mouse anti-human CD154 mAbs 5c8 and 24-31 with respect to affinity, inhibitory capacity, and species specificity; however, ABI793 binds to a different CD154 epitope. With 20 mg/kg of ABI793, five of nine recipients showed substantially prolonged graft survival after cessation of treatment, whereas four of nine recipients were killed because of high serum creatinine while still receiving treatment. ABI793 treatment was associated with episodes of severe acute tubular necrosis (which was unrelated to rejection and responded to fluid and diuretic treatment) and a decrease in platelet numbers. Chronic and acute thromboembolic vascular lesions with hemorrhages were observed in the lung and brain of two allograft recipients. None of these side effects were observed in animals that underwent autotransplantation, thus excluding direct toxicity of ABI793. CONCLUSIONS: ABI793 treatment effectively prevents graft rejection in Cynomolgus monkeys. Evidence for rare thromboembolic events, as also previously observed with different anti-human CD154 mAbs, suggests that thromboembolic complications may be a class effect of anti-CD154 mAbs, unrelated to their epitope specificity.