David N. Radin

Efficient Plant-Based Production of Chicken Interleukin-12 Yields a Strong Immunostimulatory Cytokine

Interleukin-12 (IL-12), an important immunomodulator for cell-mediated immunity, shows significant potential as a vaccine adjuvant and anticancer therapeutic in mammals. Therapeutic strategies to develop mammalian IL-12 as a vaccine adjuvant/immunomodulator for promoting cellular immunity and establishing a Th1-biased immune response further support the potential value of ChIL-12. Transgenic plants show promise as scalable bioproduction platforms for challenging biopharmaceutical proteins. We have expressed, characterized, and purified biologically active ChIL-12 in plants using a rapid Agrobacterium-mediated tobacco plant-based transient expression system. To ensure the stoichiometric expression and assembly of p35 and p40, we expressed a single-chain version of chicken IL-12 (ChIL-12). A histidine 6x tag was used for identity and purification of ChIL-12(His) protein. Our results demonstrated precise cleavage of the endogenous chicken p40 signal peptide in plants as well as addition of N-linked glycans. Biological activity was confirmed in vitro by interferon-gamma secretion of ChIL-12-treated chicken splenocytes. In addition, splenocytes treated with ChIL-12 expressed with or without the His tag demonstrated comparable ChIFN-gamma induction. These studies indicate that plant-based platforms for bioproduction of complex pharmaceutical proteins produce functional ChIL-12 and provide key advantages in safety, scale, and cost-effective platform for veterinary vaccine and therapeutic applications.

Quality Assessment of Recombinant Proteins Produced in Plants

Plant-based expression technologies for recombinant proteins have begun to receive acceptance for pharmaceuticals and other commercial markets. Protein products derived from plants offer safer, more cost-effective, and less capital-intensive alternatives to traditional manufacturing systems using microbial fermentation or animal cell culture bioreactors. Moreover, plants are now known to be capable of expressing bioactive proteins from a diverse array of species including animals and humans. Methods development to assess the quality and performance of proteins manufactured in plants are essential to support the QA/QC demands as plant-produced protein products transition to the commercial marketplace. Within the pharmaceutical arena, process validation and acceptance criteria for biological products must comply with the Food and Drug Administration (FDA) and ICH Q6B guidelines in order to initiate the regulatory approval process. Detailed product specifications will also need to be developed and validated for plant-made proteins for the bioenergy, food, chemical synthesis, or research reagent markets.We have, therefore, developed assessment methods for important qualitative and quantitative parameters of the products and the manufacturing methods utilized in plant-based production systems. In this chapter, we describe a number of procedures to validate product identity and characteristics including mass analyses, antibody cross-reactivity, N-terminal sequencing, and bioactivity. We also address methods for routine assessment of yield, recovery, and purity. The methods presented are those developed for the synthesis and recovery of the avian cytokine, chicken interleukin-12 (ChIL-12), produced in the leaves of Nicotiana benthamiana. The ChIL-12 protein used as a model for this chapter includes a C-terminal histidine epitope (HIS-tag) and, thus, these methods may be directly applicable to other HIS-tagged proteins produced in plants. However, the overall strategy presented using the ChIL-12(HIS) example should provide the basis of standard procedures for assessing the quality of other plant-based protein products and manufacturing systems.

High-throughput imaging method for direct assessment of GM1 ganglioside levels in mammalian cells.

GM1-gangliosidosis is an inherited autosomal recessive disorder caused by mutations in the gene GLB1, which encodes acid β-galactosidase (β-gal). The lack of activity in this lysosomal enzyme leads to accumulation of GM1 gangliosides (GM1) in cells. We have developed a high-content-imaging method to assess GM1 levels in fibroblasts that can be used to evaluate substrate reduction in treated GLB1−/− cells [1]. This assay allows fluorescent quantification in a multi-well system which generates unbiased and statistically significant data. Fluorescently labeled Cholera Toxin B subunit (CTXB), which specifically binds to GM1 gangliosides, was used to detect in situ GM1 levels in a fixed monolayer of fibroblasts. This sensitive, rapid, and inexpensive method facilitates in vitro drug screening in a format that allows a high number of replicates using low working volumes.