A novel alternative for pyrogen detection based on a transgenic cell line.

Pyrogen, often as a contaminant, is a key indicator affecting the safety of almost all parenteral drugs (including biologicals, chemicals, traditional Chinese medicines and medical devices). It has become a goal to completely replace the in vivo rabbit pyrogen test by using the in vitro pyrogen test based on the promoted 'reduction, replacement and refinement' principle, which has been highly considered by regulatory agencies from different countries. We used NF-κB, a central signalling molecule mediating inflammatory responses, as a pyrogenic marker and the monocyte line THP-1 transfected with a luciferase reporter gene regulated by NF-κB as an in vitro model to detect pyrogens by measuring the intensity of a fluorescence signal. Here, we show that this test can quantitatively and sensitively detect endotoxin (lipopolysaccharide from different strains) and nonendotoxin (lipoteichoic acid, zymosan, peptidoglycan, lectin and glucan), has good stability in terms of NF-κB activity and cell phenotypes at 39 cell passages and can be applied to detect pyrogens in biologicals (group A & C meningococcal polysaccharide vaccine; basiliximab; rabies vaccine (Vero cells) for human use, freeze-dried; Japanese encephalitis vaccine (Vero cells), inactivated; insulin aspart injection; human albumin; recombinant human erythropoietin injection (CHO Cell)). The within-laboratory reproducibility of the test in three independent laboratories was 85%, 80% and 80% and the interlaboratory reproducibility among laboratories was 83.3%, 95.6% and 86.7%. The sensitivity (true positive rate) and specificity (true negative rate) of the test were 89.9% and 90.9%, respectively. In summary, the test provides a novel alternative for pyrogen detection.

Development of a robust reporter-based assay for the bioactivity determination of anti-VEGF therapeutic antibodies.

Development of anti-VEGF based biologic agents has been a focus in cancer treatment for the past decades, and several anti-VEGF pharmaceuticals have been already approved for treatment of various medical indications especially in cancer. The first anti-angiogenic agent approved by FDA was bevacizumab (BVZ, trade name Avastin, Genentech/Roche), a humanized anti-VEGF monoclonal antibody. Accurate determination of bioactivity is crucial for the safety and efficacy of therapeutic antibodies. The current method widely used in the lot release and stability test for clinical trial batches of BVZ is anti-proliferation assay using primary human umbilical vein endothelial cells (HUVEC), which is tedious with high assay variations. We describe here the development and preliminary validation of a reporter gene assay (RGA) that is based on an HEK293 cell line stably expressing vascular endothelial growth factor receptor 2 (VEGFR-2), and a luciferase reporter under the control of nuclear factor activated T cell (NFAT) response elements. Our study shows this assay not only to be superior on precision, sensitivity and assay simplicity compared with HUVEC assay, but also applicable to other VEGF-targeted biotherapeutics. These results show for the first time that this new reporter assay, based on the VEGF-VEGFR-NFAT pathway, can be a viable supplement to the HUVEC assay and employed in potency determination of BVZ and other kinds of anti-VEGF antibody-based biotherapeutics.

[Development of a novel reporter gene method for determination of ADCC potency of anti-CD20 monoclonal antibody].

The biological activity of ADCC by anti-CD20 monoclonal antibody was determined by BioGlo™ Luciferase Assay System using Jurkat/NFAT-luc+FcγRIIIa cell line as effector cell and WIL2-S cell line as target cell. The developed method was verified for specificity, precision and accuracy. Anti-CD20 monoclonal antibody showed a dose-response mode by the developed method, and the determination result complied with the following four-parameter equation: y = (A-D)/[1 + (X/C)(B)] + D. The optimized parameters of the method were determined including the antibodies diluted concentration (18,000 ng·mL(-1)), dilution rate (1:5), the ratio of effector cell and target cell (6:1), and induction time (6 h). The values of eight independent tests have passed a statistical test for curve regression analysis, linear or parallelism, which showed the method possessed good specificity. Four different dilute groups of recovery rates sample were determined for 3 times, and the result showed mean relative potencies of (44.39±3.93)%, (72.74±2.78)%, (128.28±7.01)% and (168.19±2.70)% respectively, with a variation coefficient of less than 10%, and the recoveries of (88.78±7.85)%, (96.99±3.70)%, (102.63±5.61)% and (112.12±1.80)% respectively. A novel reporter gene method for determination of biological activity of ADCC by anti-CD20 monoclonal antibody was successfully developed, which showed strong specificity, good reproducibility and high accuracy, and might be used routinely.

[Determination of drug antibody ratio in an antibody-drug conjugate].

This paper reports the determination of the drug antibody ratio in an antibody-drug conjugate with two methods, i.e. LC-MS and UV/VIS, and to provide a reliable method to scientifically evaluate and effectively control the drug antibody ratio. Deglycosylated sample was analyzed with C4 column followed by MS, and the number of conjugated drugs in the antibody was determined by the molecular weight increase due to the addition of different number of drugs to the antibody, and then drug antibody ratio was calculated by weighted average of different number of drugs conjugated to the antibody. Optical density at 252 and 280 nm was measured with UV/VIS, and due to the difference of extinction coefficients between the antibody and the drug, the drug antibody ratio was calculated from linear equation with two unknowns. The drug antibody ratio was 3.21 and 3.25 respectively measured by the two methods, and the results were similar with the two methods. Our study indicated that both methods, LC-MS and UV/VIS, could be applied to the analysis of drug antibody ratio of the antibody drug conjugate.

[Cloning, expression and subcellular localization of a novel human gene-RNF122].

OBJECTIVE: To clone a functionally unknown gene RNF122 and analyze its expression pattern and subcellular localization. METHODS: PCR was used to clone the novel gene-RNF122 from the mixed human tissue cDNA library. Bioinformatics analysis was used to identify structure characteristics of the gene. Northern blot was used to analyze its expression in normal tissues; RT-PCR was employed for its expression in cell lines and tumor tissues. By co-focal microscope, we identified its subcellular localization with organelle markers. RESULTS: A novel human gene-RNF122 was cloned, which was proved to have been expressed in several normal and tumor tissues and many cell lines, and localized in ER and Golgi apparatus. CONCLUSION: RNF122 is a novel gene which encodes a protein that has a classic RING domain. It is widely expressed in several tissues and cell lines. The encoded protein is localized in ER and Golgi apparatus, which indicates that it may play a role in the process of protein degradation.