Cancer vaccine characterization: from bench to clinic.

BACKGROUND: The development of safe, effective, and affordable vaccines has become a global effort due to its vast impact on overall world health conditions. A brief overview of vaccine characterization techniques, especially in the area of high-resolution mass spectrometry, is presented. It is highly conceivable that the proper use of advanced technologies such as high-resolution mass spectrometry, along with the appropriate chemical and physical property evaluations, will yield tremendous in-depth scientific understanding for the characterization of vaccines in various stages of vaccine development. This work presents the physicochemical and biological characterization of cancer vaccine Racotumomab/alumina, a murine anti-idiotypic antibody that mimics N-glycolyl-GM3 gangliosides. This antibody has been tested as an anti-idiotypic cancer vaccine, adjuvated in Al(OH)3, in several clinical trials for melanoma, breast, and lung cancer. METHODS: Racotumomab was obtained from ascites fluid, transferred to fermentation in stirred tank at 10 L and followed to a scale up to 41 L. The mass spectrometry was used for the determination of intact molecule, light and heavy chains masses; amino acids sequence analysis, N- and C-terminal, glycosylation and posttranslational modifications. Also we used the DLS for the size distribution and zeta potential analysis. The biological analyses were performed in mice and chickens. RESULTS: We observed differences in glycosylation pattern, charge heterogeneity and structural stability between in vivo-produced and bioreactor-obtained Racotumomab products. Interestingly, these modifications had no significant impact on the immune responses elicited in two different animal models. CONCLUSIONS: We are demonstrated that this approach could potentially be more efficient and effective for supporting vaccine research and development.

Metabolic and proteomic study of NS0 myeloma cell line following the adaptation to protein-free medium.

Proteomics and metabolomics technologies are potentially useful tool for the study of the very complex process of cell adaptation to protein-free medium. In this work, we used the iTRAQ technology to analyze different protein levels in adapted and non-adapted NS0 myeloma cell line. Several proteins with differential expression profile were characterized and quantified. Carbohydrate metabolism, protein synthesis and membrane transport were the principal pathways that change after the adaptation. Changes in lactate production rate with respect to glucose consumption rate were observed according to the changes observed by proteomic.