Peptides Derived from the Tight Junction Protein CLDN1 Disrupt the Skin Barrier and Promote Responsiveness to an Epicutaneous Vaccine

Peptides Derived from the Tight Junction Protein CLDN1 Disrupt the Skin Barrier and Promote Responsiveness to an Epicutaneous Vaccine

Keratinocytes express many pattern recognition receptors that enhance the skin’s adaptive immune response to epicutaneous antigens. We have shown that these pattern recognition receptors are expressed below tight junctions (TJ), strongly implicating TJ disruption as a critical step in antigen respon...

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Bibliographic Details
Published in:Journal of investigative dermatology Vol. 140; no. 2; pp. 361 - 369.e3
Main Authors: Brewer, Matthew G., Anderson, Elizabeth A., Pandya, Radha P., De Benedetto, Anna, Yoshida, Takeshi, Hilimire, Thomas A., Martinez-Sobrido, Luis, Beck, Lisa A., Miller, Benjamin L.
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-02-2020
Subjects:
TER
TEWL
IM
TJDP
TJ
PHFK
HA
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Summary:Keratinocytes express many pattern recognition receptors that enhance the skin’s adaptive immune response to epicutaneous antigens. We have shown that these pattern recognition receptors are expressed below tight junctions (TJ), strongly implicating TJ disruption as a critical step in antigen responsiveness. To disrupt TJs, we designed peptides inspired by the first extracellular loop of the TJ transmembrane protein CLDN1. These peptides transiently disrupted TJs in the human lung epithelial cell line 16HBE and delayed TJ formation in primary human keratinocytes. Building on these observations, we tested whether vaccinating mice with an epicutaneous influenza patch containing TJ-disrupting peptides was an effective strategy to elicit an immunogenic response. Application of a TJ-disrupting peptide patch resulted in barrier disruption as measured by increased transepithelial water loss. We observed a significant increase in antigen-specific antibodies when we applied patches with TJ-disrupting peptide plus antigen (influenza hemagglutinin) in either a patch-prime or a patch-boost model. Collectively, these observations demonstrate that our designed peptides perturb TJs in human lung as well as human and murine skin epithelium, enabling epicutaneous vaccine delivery. We anticipate that this approach could obviate currently used needle-based vaccination methods that require administration by health care workers and biohazard waste removal.
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ISSN:0022-202X
1523-1747
DOI:10.1016/j.jid.2019.06.145