Improving Downstream Process Related Manufacturability Based on Protein Engineering—A Feasibility Study

Florian Capito; Ting Hin Wong; Christine Faust; Kilian Brand; Werner Dittrich; Mark Sommerfeld; Garima Tiwari; Thomas Langer

doi:10.1002/elsc.202400019

Engineering in Life Sciences (Sep 2024)

Improving Downstream Process Related Manufacturability Based on Protein Engineering—A Feasibility Study

Florian Capito,
Ting Hin Wong,
Christine Faust,
Kilian Brand,
Werner Dittrich,
Mark Sommerfeld,
Garima Tiwari,
Thomas Langer

Affiliations

Florian Capito: Sanofi‐Aventis Deutschland GmbH, CMC Microbial Platform Downstream Process Development Industriepark Höchst Frankfurt am Main Germany
Ting Hin Wong: Sanofi‐Aventis Deutschland GmbH, CMC Microbial Platform Downstream Process Development Industriepark Höchst Frankfurt am Main Germany
Christine Faust: Sanofi‐Aventis Deutschland GmbH, Large Molecule Research Industriepark Höchst Frankfurt am Main Germany
Kilian Brand: Sanofi‐Aventis Deutschland GmbH, CMC Microbial Platform Downstream Process Development Industriepark Höchst Frankfurt am Main Germany
Werner Dittrich: Sanofi‐Aventis Deutschland GmbH, Large Molecule Research Industriepark Höchst Frankfurt am Main Germany
Mark Sommerfeld: Sanofi‐Aventis Deutschland GmbH, Large Molecule Research Industriepark Höchst Frankfurt am Main Germany
Garima Tiwari: Sanofi‐Aventis Deutschland GmbH, Large Molecule Research Industriepark Höchst Frankfurt am Main Germany
Thomas Langer: Sanofi‐Aventis Deutschland GmbH, Large Molecule Research Industriepark Höchst Frankfurt am Main Germany

DOI: https://doi.org/10.1002/elsc.202400019
Journal volume & issue: Vol. 24, no. 9
pp. n/a – n/a

Abstract

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ABSTRACT While bioactivity and a favorable safety profile for biotherapeutics is of utmost importance, manufacturability is also worth of consideration to ease the manufacturing process. Manufacturability in the scientific literature is mostly related to stability of formulated drug substances, with limited focus on downstream process‐related manufacturability, that is, how easily can a protein be purified. Process‐related impurities or biological impurities like viruses and host cell proteins (HCP) are present in the harvest which have mostly acid isoelectric points and need to be removed to ensure patient safety. Therefore, during molecule design, the surface charge of the target molecule should preferably differ sufficiently from the surface charge of the impurities to enable an efficient purification strategy. In this feasibility study, we evaluated the possibility of improving manufacturability by adapting the surface charge of the target protein. We generated several variants of a GLP1‐receptor‐agonist‐Fc‐domain‐FGF21‐fusion protein and demonstrated proof of concept exemplarily for an anion exchange chromatography step which then can be operated at high pH values with maximal product recovery allowing removal of HCP and viruses. Altering the surface charge distribution of biotherapeutic proteins can thus be useful allowing for an efficient manufacturing process for removing HCP and viruses, thereby reducing manufacturing costs.

Published in Engineering in Life Sciences

ISSN: 1618-0240 (Print); 1618-2863 (Online)
Publisher: Wiley-VCH
Country of publisher: Germany
LCC subjects: Technology: Chemical technology: Biotechnology
Website: https://onlinelibrary.wiley.com/journal/16182863

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