Real time quantitative PCR as a method to evaluate xenotropic murine leukemia virus removal during pharmaceutical protein purification.

Chinese hamster ovary cells used for pharmaceutical protein production express noninfectious retrovirus-like particles. To assure the safety of pharmaceutical proteins, validation of the ability of manufacturing processes to clear retrovirus-like particles is required for product registration. Xenotropic murine leukemia virus (X-MuLV) is often used as a model virus for clearance studies. Traditionally, cell-based infectivity assay has been the standard virus quantification method. In this article, a real time quantitative PCR (Q-PCR) method has been developed for X-MuLV detection/quantification. This method provides accurate and reproducible quantification of X-MuLV particle RNA (pRNA) over a linear dynamic range of at least 100,000-fold with a quantification limit of approximately 1.5 pRNA copies microL(-1). It is about 100-fold more sensitive than the cell-based infectivity assay. High concentrations of protein and cellular DNA present in test samples have been demonstrated to have no impact on X-MuLV quantification. The X-MuLV clearance during chromatography and filtration procedures determined by this method is highly comparable with that determined by the cell-based infectivity assay. X-MuLV clearance measured by both methods showed that anion exchange chromatography (QSFF) and DV50 viral filtration are robust retroviral removal steps. In addition, combination of the two methods was able to distinguish the viral removal from inactivation by the Protein A chromatography, and fully recognize the viral clearance capacity of this step. This new method offers significant advantages over cell-based infectivity assays. It could be used to substitute cell-based infectivity assays for process validation of viral removal procedures, but not inactivation steps. Its availability should greatly facilitate and reduce the cost of viral clearance evaluations for new biologic product development.

Evaluation of a quantitative product-enhanced reverse transcriptase assay to monitor retrovirus in mAb cell-culture.

Murine hybridoma cells used in the production of monoclonal antibodies (mAbs) produce endogenous type C retrovirus particles. Regulatory agencies require a demonstration that mAbs intended for human use are free of retrovirus with an adequate margin of safety. This is usually achieved by evaluation studies, performed at small scale, to demonstrate that the manufacturing process is capable of removing or inactivating several different model viruses, including a murine retrovirus. In a previous report, we demonstrated the utility of TaqMan fluorogenic 5'-nuclease product-enhanced reverse transcriptase (TM-PERT) assays for measuring reverse transcriptase (RT) activity in laboratory-scale cell-culture samples and RT removal by laboratory-scale models of processing steps. In this report, we evaluate the specificity, accuracy, range, precision and robustness of TM-PERT for this purpose. We find that this assay detects RT activity contained in xenotropic murine leukemia virus (X-MuLV) and CHO cell type C particles and quantifies particle numbers comparably to other assays (e.g. transmission electron microscopy, viral sequence specific TaqMan). Cell derived DNA polymerases appear to contribute only modestly to the assay background and RT activity in clarified cell culture harvests is contained largely in Type C particles. TM-PERT is linear and precise between 10(7)and 10(13) pU/ml, establishing the assay range. The assay is robust in that test article storage condition and DNA/protein content had little impact on assay performance. Thus, TM-PERT appears to be an acceptable assay to measure type C particles in rodent cell culture samples.