Impact of Peptide Structure on Colonic Stability and Tissue Permeability

Most marketed peptide drugs are administered parenterally due to their inherent gastrointestinal (GI) instability and poor permeability across the GI epithelium. Several molecular design techniques, such as cyclisation and D-amino acid (D-AA) substitution, have been proposed to improve oral peptide...

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Bibliographic Details
Published in:Pharmaceutics 2023-07, Vol.15 (7), p.1956
Main Authors: Taherali, Farhan, Chouhan, Nerisha, Wang, Fanjin, Lavielle, Sebastien, Baran, Maryana, McCoubrey, Laura E, Basit, Abdul W, Yadav, Vipul
Format: Article
Language:English
Subjects:
Amino acids
bioavailability of biopharmaceuticals
Biological products
Chemical bonds
Colon
colonic drug delivery
Colorectal cancer
Enzymes
Gastrointestinal diseases
gastrointestinal peptide stability
Hormones
Inflammatory bowel disease
microbiota drug metabolism
oral delivery of biologics and peptides
peptide design and synthesis
Peptides
Permeability
Proteins
Small intestine
Systemic diseases
Type 2 diabetes
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Summary:Most marketed peptide drugs are administered parenterally due to their inherent gastrointestinal (GI) instability and poor permeability across the GI epithelium. Several molecular design techniques, such as cyclisation and D-amino acid (D-AA) substitution, have been proposed to improve oral peptide drug bioavailability. However, very few of these techniques have been translated to the clinic. In addition, little is known about how synthetic peptide design may improve stability and permeability in the colon, a key site for the treatment of inflammatory bowel disease and colorectal cancer. In this study, we investigated the impact of various cyclisation modifications and D-AA substitutions on the enzymatic stability and colonic tissue permeability of native oxytocin and 11 oxytocin-based peptides. Results showed that the disulfide bond cyclisation present in native oxytocin provided an improved stability in a human colon model compared to a linear oxytocin derivative. Chloroacetyl cyclisation increased native oxytocin stability in the colonic model at 1.5 h by 30.0%, whereas thioether and N-terminal acetylated cyclisations offered no additional protection at 1.5 h. The site and number of D-AA substitutions were found to be critical for stability, with three D-AAs at Tyr, Ile and Leu, improving native oxytocin stability at 1.5 h in both linear and cyclic structures by 58.2% and 79.1%, respectively. Substitution of three D-AAs into native cyclic oxytocin significantly increased peptide permeability across rat colonic tissue; this may be because D-AA substitution favourably altered the peptide's secondary structure. This study is the first to show how the strategic design of peptide therapeutics could enable their delivery to the colon via the oral route.
ISSN:1999-4923
1999-4923
DOI:10.3390/pharmaceutics15071956