Characterization of huJAM: evidence for involvement in cell-cell contact and tight junction regulation

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Characterization of huJAM: evidence for involvement in cell-cell contact and tight junction regulation

Tony W. Liang¹, Richard A. DeMarco¹, Randy J. Mrsny², Austin Gurney³, Alane Gray³, Jeffery Hooley⁴, Holly L. Aaron⁴, Arthur Huang³, Toni Klassen⁵, Daniel B. Tumas⁶, and Sherman Fong¹

¹ Department of Immunology, ² Department of Pharmacology Research and Development, ³ Department of Molecular Biology, ⁴ Department of Cell Biology and Technology, ⁵ Department of Antibody Technology, and ⁶ Department of Pathology, Genentech, South San Francisco, California 94080

Cell-cell interactions of the mucosal epithelia are important for the maintenance and establishment of epithelial barrierfunction. During events of inflammation, such cell-cell interactionsare often disrupted, resulting in a leaky epithelial barrier,which in turn can lead to various inflammatory and infective dysfunctions.Human junctional adhesion molecule (huJAM), found on the mucosalepithelia and vascular endothelia of many major organ systems,is a membrane glycoprotein which resolves to a doublet band of~40 and ~37 kDa under SDS-PAGE analysis, representing differentiallyglycosylated forms of the same protein. huJAM was localized tothe lateral membrane of Caco-2 cells (a human colonic epithelialcell line) monolayers, in an area basolateral of the epithelialtight junctions (TJ). Through functional and biochemical assays,we show huJAM to be able to homotypically associate and to participatein TJ restitution after trypsin-EDTA disruption. Furthermore,we also observed a migration of huJAM expression toward areasof cell-cell contacts during events of cell adhesion and monolayerformation. These qualities makes huJAM a likely player in theregulation of cell-cell contacts and the subsequent formationofTJs.

epithelial permeability; junctions; immunoglobulin superfamily; adhesion molecule; cell contact

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