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  • Glycan Profile Analysis of Engineered Trastuzumab with Rationally Added Glycosylation Sequons Presents Significantly Increased Glycan Complexity.

Glycan Profile Analysis of Engineered Trastuzumab with Rationally Added Glycosylation Sequons Presents Significantly Increased Glycan Complexity.

Pharmaceutics (2021-11-28)
Esteban Cruz, Vicki Sifniotis, Zeynep Sumer-Bayraktar, Mouhamad Reslan, Lorna Wilkinson-White, Stuart Cordwell, Veysel Kayser
ZUSAMMENFASSUNG

Protein aggregation constitutes a recurring complication in the manufacture and clinical use of therapeutic monoclonal antibodies (mAb) and mAb derivatives. Antibody aggregates can reduce production yield, cause immunogenic reactions, decrease the shelf-life of the pharmaceutical product and impair the capacity of the antibody monomer to bind to its cognate antigen. A common strategy to tackle protein aggregation involves the identification of surface-exposed aggregation-prone regions (APR) for replacement through protein engineering. It was shown that the insertion of N-glycosylation sequons on amino acids proximal to an aggregation-prone region can increase the physical stability of the protein by shielding the APR, thus preventing self-association of antibody monomers. We recently implemented this approach in the Fab region of full-size adalimumab and demonstrated that the thermodynamic stability of the Fab domain increases upon N-glycosite addition. Previous experimental data reported for this technique have lacked appropriate confirmation of glycan occupancy and structural characterization of the ensuing glycan profile. Herein, we mutated previously identified candidate positions on the Fab domain of Trastuzumab and employed tandem mass spectrometry to confirm attachment and obtain a detailed N-glycosylation profile of the mutants. The Trastuzumab glycomutants displayed a glycan profile with significantly higher structural heterogeneity compared to the HEK Trastuzumab antibody, which contains a single N-glycosylation site per heavy chain located in the CH2 domain of the Fc region. These findings suggest that Fab N-glycosites have higher accessibility to enzymes responsible for glycan maturation. Further, we have studied effects on additional glycosylation on protein stability via accelerated studies by following protein folding and aggregation propensities and observed that additional glycosylation indeed enhances physical stability and prevent protein aggregation. Our findings shed light into mAb glycobiology and potential implications in the application of this technique for the development of "biobetter" antibodies.

MATERIALIEN
Produktnummer
Marke
Produktbeschreibung

Sigma-Aldrich
Natriumchlorid, ACS reagent, ≥99.0%
Sigma-Aldrich
Trypsin aus Schweinepankreas, Proteomics Grade, BioReagent, Dimethylated
Sigma-Aldrich
Kanamycin -Lösung aus Streptomyces kanamyceticus, 50 - 60 mg/mL in 0.9% NaCl, BioReagent, liquid, 0.1 μm filtered, suitable for cell culture
Sigma-Aldrich
Glycin -hydrochlorid, ≥99% (HPLC)
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GenElute HP Plasmid Maxiprep Kit, sufficient for 25 purifications
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GenElute Plasmid Miniprep-Kit, sufficient for 70 purifications
HiTrap® Protein A High Performance, Cytiva 17-0403-01, pack of 1 × 5 mL
Sigma-Aldrich
Fc-gamma RIIB/CD32b human, recombinant, expressed in HEK 293 cells, ≥95% (SDS-PAGE)