Rapid Optimization of Antibotulinum Toxin Antibody Fragment Production by an Integral Approach Utilizing RC-SELDI Mass Spectrometry and Statistical Design

Abstract

A process for the rapid development and optimization of the fermentation process for an antibotulinum neurotoxin antibody fragment (bt-Fab) production expressed in Escherichia coli was achieved via a high-throughput process proteomics and statistical experimental design. This process, using retentate chromatography-surface enhanced laser desorption/ionization mass spectrometry (RC-SELDI MS), was employed for identifying and quantifying bt-Fab antibody in complex biological samples for the optimization of microbial fermentation conditions. Five variables (type of culture media, glycerol concentration, post-induction temperature, IPTG concentration, and incubation time after induction) were statistically combined using an experimental 2(5)(-1) fractional factorial design and tested for their effects on maximal bt-Fab antibody production. When the effects of individual variables and their interactions were assessed, type of media and post-induction temperature showed statistically significant increase in yield of the fermentation process for the maximal bt-Fab antibody production. This study establishes an integral approach as a valuable tool for the rapid development of manufacturing processes for producing various biological materials. To verify the RC-SELDI MS method, a Fab-specific immuno-affinity HPLC assay developed here was also employed for the quantification of the bt-Fab antibody in crude lysate samples obtained during the fermentation optimization process. Similar results were obtained.