Preventing Protein Self-Association Through Strategic Covalent Modification

IF 1.8 4区生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY Journal of Peptide Science Pub Date : 2025-03-06 DOI:10.1002/psc.70008

Swetha Chintala, Simon H. Friedman

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Abstract

Protein self-interaction leading to aggregation is a major challenge facing protein pharmaceuticals. It leads to a range of problems, including increases in immunogenicity and loss of activity. In this work, we describe an approach for blocking or antagonizing the quaternary interactions that drive self-association. We applied the approach to glucagon, a therapeutic peptide known for its propensity to form fibrils due to self-interaction. We synthesized a regio-pure common feedstock that allowed easy modification with potential blocking peptides that represented a range of chemical types (anionic, cationic, polar, and nonpolar). From these synthesized materials, we identified two modified glucagons that showed significant stabilization against fibril formation compared with unmodified glucagon. This was confirmed by three complementary biophysical techniques. Both successful modifications introduced excess net charge to glucagon, consistent with overall electrostatic repulsion being at the root of the observed fibrillation resistance. This approach can potentially be applied to other therapeutic proteins that suffer from the problems associated with self-association.

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来源期刊

Journal of Peptide Science 生物-分析化学

CiteScore

3.40

自引率

4.80%

发文量

审稿时长

1.7 months

期刊介绍： The official Journal of the European Peptide Society EPS The Journal of Peptide Science is a cooperative venture of John Wiley & Sons, Ltd and the European Peptide Society, undertaken for the advancement of international peptide science by the publication of original research results and reviews. The Journal of Peptide Science publishes three types of articles: Research Articles, Rapid Communications and Reviews. The scope of the Journal embraces the whole range of peptide chemistry and biology: the isolation, characterisation, synthesis properties (chemical, physical, conformational, pharmacological, endocrine and immunological) and applications of natural peptides; studies of their analogues, including peptidomimetics; peptide antibiotics and other peptide-derived complex natural products; peptide and peptide-related drug design and development; peptide materials and nanomaterials science; combinatorial peptide research; the chemical synthesis of proteins; and methodological advances in all these areas. The spectrum of interests is well illustrated by the published proceedings of the regular international Symposia of the European, American, Japanese, Australian, Chinese and Indian Peptide Societies.