An electrostatically coupled polypeptide affinity multimodal chromatography medium for the purification of antibodies and their separation efficiency.

Yuxuan CHENG; Liuyang WANG; Kaixuan JIANG; Songping ZHANG; Hongbo YAN; Jian LUO

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An electrostatically coupled polypeptide affinity multimodal chromatography medium for the purification of antibodies and their separation efficiency.

Author: Yuxuan CHENG ¹ ; Liuyang WANG ² ; Kaixuan JIANG ² ; Songping ZHANG ² ; Hongbo YAN ¹ ; Jian LUO ²
Author Information

1. College of Bioscience and Engineering, Hebei University of Economics and Business, Shijiazhuang 050061, Hebei, China.
2. State Key Laboratory of Biopharmaceutical Preparation and Delivery, Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, China.
Publication Type:Journal Article
Keywords: antibodies; polypeptide affinity chromatography; polypeptide ligand; separation and purification; space arm
MeSH: Chromatography, Affinity/methods*; Static Electricity; Humans; Sepharose/analogs & derivatives*; Peptides/chemistry*; Adsorption; Antibodies/isolation & purification*
From: Chinese Journal of Biotechnology 2025;41(8):3262-3274
CountryChina
Language:Chinese
Abstract: As the need for antibody production rises, there is an urgent need to lower the costs and enhance the efficiency of the separation process. Currently, the chromatographic media used for antibody separation and purification often focus on individual properties of antibodies, such as affinity, hydrophobicity, and charge, leading to issues like low purification efficiency or inadequate adsorption capacity. To address this, an electrostatically coupled polypeptide affinity medium (FD7-3, 5-diaminobenzoic acid n-sepharose, FD7-DA-Sepharose) was developed for rapid purification of antibodies from cell culture supernatant. This medium utilized 3, 5-diaminobenzoic acid as a spacer to attach the heptapeptide-affinity ligand (FYEILHD, FD7) to agarose microspheres. Antibodies could be adsorbed through charge interactions with the carboxyl functional group of the FD7-DA-Sepharose spacer, while FD7 enhanced electrostatic coupling and affinity adsorption through synergistic effects, significantly increasing the adsorption capacity while maintaining the affinity and specificity. The influences of pH and ionic strength on adsorption capacity were investigated with human immunoglobulin as a model protein. The static adsorption capacity (Q_m) of FD7-DA-Sepharose in the solution of pH 6.0 reached 67.73 mg/mL, representing a 52.68% increase compared with that (44.36 mg/mL) of the commercial Protein A affinity medium. Furthermore, the elution conditions for FD7-DA- Sepharose were mild (20 mmol/L PB, 0.5 mol/L NaCl, pH 6.0), in contrast to the harsh acidic elution (pH 2.7-3.6) typically associated with Protein A, which can damage antibody integrity. The FD7-DA-Sepharose medium was then employed to purify antibodies from cell culture supernatant, achieving the yield of 94.8% and the purity of 98.4%. The secondary structure of the purified antibody was determined by circular dichroism spectroscopy. The results demonstrated that FD7-DA-Sepharose enabled efficient purification of antibodies from cell culture supernatant, which provided a cost-effective solution (approximately one-third the price of commercial Protein A affinity medium) with gentle elution conditions that preserve the natural conformation of antibodies. This approach paves a novel, economical, and efficient way for the separation and purification of antibodies from cell culture supernatant.