Nowadays, therapeutic monoclonal antibodies (mAbs) are predominantly produced with mammalian cell culture systems such as those using Chinese hamster ovary (CHO) cells. Efforts are underway to reduce the costs of this process to meet the increasing global demand in biopharmaceuticals; meanwhile, cheaper and faster expression systems are being investigated as alternatives. The yeast, Pichia pastoris, has become a substantial workhorse for recombinant protein production. However, the N-linked glycosylation in P. pastoris, namely high mannose glycosylation, is significantly different from that in CHO or other mammalian cells, including human cells. In this study, a SuperMan5 strain of P. pastoris was constructed using Pichia GlycoSwitch® technology to successfully produce a more mammalian-like immunoglobulin G (IgG) fragment crystallizable (Fc), which showcases the potential of P. pastoris as a next-generation mAb production platform. Importantly, in this study, a strong methanol-independent promoter, PUPP, was applied, which only requires glycerol feeding for protein production. Most P. pastoris promoters used for protein expression are derived from genes in the methanol metabolism pathway, creating safety concerns due to the flammable nature of methanol, especially at large scale. Here, a fed-batch SuperMan5 P. pastoris fermentation was carried out in which methanol induction, as well as its affiliated safety risks, were eliminated. Overall, this study provides insights into the development of safe and cost-effective industrial mAb production approaches independent of mammalian cell culture.
Tag: <span>eukaryotic expression</span>
Biopharmaceuticals are predicted to become the main driving force of the pharmaceutical market in the near future. Other than blockbuster products such as erythropoietin, an increasing number of approved recombinant therapeutic proteins are based on antibody technology (e.g., fusion proteins or monoclonal antibodies [MAbs]). In contrast to relatively simple products produced in Escherichia coli bacteria (e.g., insulin), proteins which require complex posttranslational modifications such as glycosylation have to be produced in eukaryotic cells. In this context, production systems have been dominated by mammalian cell culture. Nevertheless, alternative eukaryotic expression technologies based on yeast, insect cells, transgenic animals, or transgenic plants are under development. Plants are a particularly promising alternative to mammalian cell culture because of their excellent safety aspects and estimated cost-efficient upstream/cultivation processes. In addition, plants are well known for their ability to express biologically functional monoclonal antibodies. In comparison to the seed plants most widely used for transgenic protein expression — tobacco, corn, and rice — mosses provide unique, beneficial features…