Challenging the workhorse: Comparative analysis of eukaryotic micro‐organisms for expressing monoclonal antibodies

Jiang, Huabei; Horwitz, Andrew A.; Wright, Chapman; Tai, Anna; Znameroski, Elizabeth A.; Tsegaye, Yoseph; Warbington, Hailley; Bower, Benjamin; Alves, Christina; Co, Carl; Jonnalagadda, Kanvasri; Platt, Darren; Walter, Jessica M.; Natarajan, Venkatesh; Ubersax, Jeffrey A.; Cherry, Joel R.; Love, J. Christopher

doi:10.1002/bit.26951

Cited by 29 publications

(23 citation statements)

References 81 publications

(128 reference statements)

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“…Rapidly advancing technologies for genomic engineering of hosts are promoting renewed consideration of microbial hosts for these tasks (Wagner & Alper, ). Selection of an optimal host for pursuing such purposes, however, can be difficult: many organisms may be suitable hosts, and for each organism, several variants typically exist (Jiang et al, ; Matthews et al, ). A framework for the rational evaluation of potential hosts could further promote the adoption of alternative hosts for commercial protein expression.…”

Section: Introductionmentioning

confidence: 99%

Comparative genome‐scale analysis of Pichia pastoris variants informs selection of an optimal base strain

Brady

Whittaker

Tan

et al. 2019

Biotech & Bioengineering

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Komagataella phaffii, also known as Pichia pastoris, is a common host for the production of biologics and enzymes, due to fast growth, high productivity, and advancements in host engineering. Several K. phaffii variants are commonly used as interchangeable base strains, which confounds efforts to improve this host. In this study, genomic and transcriptomic analyses of Y‐11430 (CBS7435), GS115, X‐33, and eight other variants enabled a comparative assessment of the relative fitness of these hosts for recombinant protein expression. Cell wall integrity explained the majority of the variation among strains, impacting transformation efficiency, growth, methanol metabolism, and secretion of heterologous proteins. Y‐11430 exhibited the highest activity of genes involved in methanol utilization, up to two‐fold higher transcription of heterologous genes, and robust growth. With a more permeable cell wall, X‐33 displayed a six‐fold higher transformation efficiency and up to 1.2‐fold higher titers than Y‐11430. X‐33 also shared nearly all mutations, and a defective variant of HIS4, with GS115, precluding robust growth. Transferring two beneficial mutations identified in X‐33 into Y‐11430 resulted in an optimized base strain that provided up to four‐fold higher transformation efficiency and three‐fold higher protein titers, while retaining robust growth. The approach employed here to assess unique banked variants in a species and then transfer key beneficial variants into a base strain should also facilitate rational assessment of a broad set of other recombinant hosts.

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Section: Introductionmentioning

confidence: 99%

Comparative genome‐scale analysis of Pichia pastoris variants informs selection of an optimal base strain

Brady

Whittaker

Tan

et al. 2019

Biotech & Bioengineering

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“…In a recent study, eight wild-type eukaryotic micro-organisms (including yeast, filamentous fungi, and mammalian cells) were evaluated to assess growth rates in industry-relevant media, adaptability for genome editing, and product quality. This study showed that multiple organisms may be suitable for recombinant protein production with appropriate engineering and development and highlighted the advantages of yeast for rapid genome engineering and development cycles (Jiang H. et al, 2019).…”

Section: Yeastmentioning

confidence: 90%

Recent Developments in Bioprocessing of Recombinant Proteins: Expression Hosts and Process Development

Tripathi

Shrivastava

2019

Front. Bioeng. Biotechnol.

340

243

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Infectious diseases, along with cancers, are among the main causes of death among humans worldwide. The production of therapeutic proteins for treating diseases at large scale for millions of individuals is one of the essential needs of mankind. Recent progress in the area of recombinant DNA technologies has paved the way to producing recombinant proteins that can be used as therapeutics, vaccines, and diagnostic reagents. Recombinant proteins for these applications are mainly produced using prokaryotic and eukaryotic expression host systems such as mammalian cells, bacteria, yeast, insect cells, and transgenic plants at laboratory scale as well as in large-scale settings. The development of efficient bioprocessing strategies is crucial for industrial production of recombinant proteins of therapeutic and prophylactic importance. Recently, advances have been made in the various areas of bioprocessing and are being utilized to develop effective processes for producing recombinant proteins. These include the use of high-throughput devices for effective bioprocess optimization and of disposable systems, continuous upstream processing, continuous chromatography, integrated continuous bioprocessing, Quality by Design, and process analytical technologies to achieve quality product with higher yield. This review summarizes recent developments in the bioprocessing of recombinant proteins, including in various expression systems, bioprocess development, and the upstream and downstream processing of recombinant proteins.

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“…These proteins are typically enzymes for industrial purposes (e.g., detergents) but may be adaptable to production of pharmaceutical-grade antibodies, especially for topical use. Some yeast (e.g., Pichia pastoris ) and fungus (e.g., Trichoderma reesei ) have been evaluated for production of antibodies [ 42 , 43 ] that could address the metric ton challenge for antibodies. In addition to a quality expression host, the perspective of regulatory agencies on utilization of existing infrastructure (e.g., 300,000 L fermenters) for manufacturing topical contraceptive antibodies may be crucial in avoiding enormous capital costs.…”

Section: Manufacturing the Human Contraceptive Antibodymentioning

confidence: 99%

Engineering monoclonal antibody-based contraception and multipurpose prevention technologies†

Anderson

Politch

Cone

et al. 2020

Biology of Reproduction

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Abstract Sexually transmitted infections are highly prevalent, and over 40% of pregnancies are unplanned. We are producing new antibody-based multipurpose prevention technology products to address these problems and fill an unmet need in female reproductive health. We used a Nicotiana platform to manufacture monoclonal antibodies against two prevalent sexually transmitted pathogens, HIV-1 and HSV-2, and incorporated them into a vaginal film (MB66) for preclinical and Phase 1 clinical testing. These tests are now complete and indicate that MB66 is effective and safe in women. We are now developing an antisperm monoclonal antibody to add contraceptive efficacy to this product. The antisperm antibody, H6-3C4, originally isolated by Shinzo Isojima from the blood of an infertile woman, recognizes a carbohydrate epitope on CD52g, a glycosylphosphatidylinositol-anchored glycoprotein found in abundance on the surface of human sperm. We engineered the antibody for production in Nicotiana; the new antibody which we call “human contraception antibody,” effectively agglutinates sperm at concentrations >10 μg/ml and maintains activity under a variety of physiological conditions. We are currently seeking regulatory approval for a Phase 1 clinical trial, which will include safety and “proof of principle” efficacy endpoints. Concurrently, we are working with new antibody production platforms to bring the costs down, innovative antibody designs that may produce more effective second-generation antibodies, and delivery systems to provide extended protection.

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Challenging the workhorse: Comparative analysis of eukaryotic micro‐organisms for expressing monoclonal antibodies

Cited by 29 publications

References 81 publications

Comparative genome‐scale analysis of Pichia pastoris variants informs selection of an optimal base strain

Comparative genome‐scale analysis of Pichia pastoris variants informs selection of an optimal base strain

Recent Developments in Bioprocessing of Recombinant Proteins: Expression Hosts and Process Development

Engineering monoclonal antibody-based contraception and multipurpose prevention technologies†

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