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Bioengineering commensal bacteria-derived outer membrane vesicles for delivery of biologics to the gastrointestinal and respiratory tract.

Carvalho, Ana L.; Fonseca, Sonia; Miquel-Clopés, Ariadna; Cross, Kathryn; Kok, Khoon-S.; Wegmann, Udo; Gil-Cardoso, Katherine; Bentley, Eleanor G.; Al Katy, Sanaria H.M.; Coombes, Janine L.; Kipar, Anja; Stentz, Regis; Stewart, James P.; Carding, Simon R.

Authors

Ana L. Carvalho

Sonia Fonseca

Ariadna Miquel-Clopés

Kathryn Cross

Khoon-S. Kok

Udo Wegmann

Katherine Gil-Cardoso

Eleanor G. Bentley

Sanaria H.M. Al Katy

Anja Kipar

Regis Stentz

James P. Stewart

Simon R. Carding



Abstract

Gram-negative bacteria naturally produce and secrete nanosized outer membrane vesicles (OMVs). In the human gastrointestinal tract, OMVs produced by commensal Gram-negative bacteria can mediate interactions amongst host cells (including between epithelial cells and immune cells) and maintain microbial homeostasis. This OMV-mediated pathway for host-microbe interactions could be exploited to deliver biologically active proteins to the body. To test this we engineered the Gram-negative bacterium Bacteroides thetaiotaomicron (Bt), a prominent member of the intestinal microbiota of all animals, to incorporate bacteria-, virus- and human-derived proteins into its OMVs. We then used the engineered Bt OMVs to deliver these proteins to the respiratory and gastrointestinal (GI)-tract to protect against infection, tissue inflammation and injury. Our findings demonstrate the ability to express and package both Salmonella enterica ser. Typhimurium-derived vaccine antigens and influenza A virus (IAV)-derived vaccine antigens within or on the outer membrane of Bt OMVs. These antigens were in a form capable of eliciting antigen-specific immune and antibody responses in both mucosal tissues and systemically. Furthermore, immunisation with OMVs containing the core stalk region of the IAV H5 hemagglutinin from an H5N1 strain induced heterotypic protection in mice to a 10-fold lethal dose of an unrelated subtype (H1N1) of IAV. We also showed that OMVs could express the human therapeutic protein, keratinocyte growth factor-2 (KGF-2), in a stable form that, when delivered orally, reduced disease severity and promoted intestinal epithelial repair and recovery in animals administered colitis-inducing dextran sodium sulfate. Collectively, our data demonstrates the utility and effectiveness of using Bt OMVs as a mucosal biologics and drug delivery platform technology.

Citation

CARVALHO, A.L., FONSECA, S., MIQUEL-CLOPÉS, A., CROSS, K., KOK, K.-S., WEGMANN, U., GIL-CARDOSO, K., BENTLEY, E.G., AL KATY, S.H.M., COOMBES, J.L., KIPAR, A., STENTZ, R., STEWART, J.P. and CARDING, S.R. 2019. Bioengineering commensal bacteria-derived outer membrane vesicles for delivery of biologics to the gastrointestinal and respiratory tract. Journal of extracellular vesicles [online], 8(1), article number 1632100. Available from: https://doi.org/10.1080/20013078.2019.1632100

Journal Article Type Article
Acceptance Date Jun 10, 2019
Online Publication Date Jun 24, 2019
Publication Date Dec 31, 2019
Deposit Date Jul 15, 2024
Publicly Available Date Jul 15, 2024
Journal Journal of extracellular vesicles
Electronic ISSN 2001-3078
Publisher Taylor & Francis Open Access
Peer Reviewed Peer Reviewed
Volume 8
Issue 1
Article Number 1632100
DOI https://doi.org/10.1080/20013078.2019.1632100
Keywords Commensal bacteria; Bacterial microvesicles; Outer membrane vesicles; Mucosal drug delivery; Mucosal vaccines; Therapeutic proteins
Public URL https://rgu-repository.worktribe.com/output/2058419

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