CXCL10 stabilizes T cell–brain endothelial cell adhesion leading to the induction of cerebral malaria
Elizabeth W. Sorensen, Jeffrey Lian, Aleksandra J. Ozga, Yoshishige Miyabe, Sophina W. Ji, Shannon K. Bromley, Thorsten R. Mempel, Andrew D. Luster
Elizabeth W. Sorensen, Jeffrey Lian, Aleksandra J. Ozga, Yoshishige Miyabe, Sophina W. Ji, Shannon K. Bromley, Thorsten R. Mempel, Andrew D. Luster
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Research Article Immunology Infectious disease

CXCL10 stabilizes T cell–brain endothelial cell adhesion leading to the induction of cerebral malaria

Abstract

Malaria remains one of the world’s most significant human infectious diseases and cerebral malaria (CM) is its most deadly complication. CM pathogenesis remains incompletely understood, hindering the development of therapeutics to prevent this lethal complication. Elevated levels of the chemokine CXCL10 are a biomarker for CM, and CXCL10 and its receptor CXCR3 are required for experimental CM (ECM) in mice, but their role has remained unclear. Using multiphoton intravital microscopy, CXCR3 receptor– and ligand–deficient mice and bone marrow chimeric mice, we demonstrate a key role for endothelial cell–produced CXCL10 in inducing the firm adhesion of T cells and preventing their cell detachment from the brain vasculature. Using a CXCL9 and CXCL10 dual-CXCR3-ligand reporter mouse, we found that CXCL10 was strongly induced in the brain endothelium as early as 4 days after infection, while CXCL9 and CXCL10 expression was found in inflammatory monocytes and monocyte-derived DCs within the blood vasculature on day 8. The induction of both CXCL9 and CXCL10 was completely dependent on IFN-γ receptor signaling. These data demonstrate that IFN-γ–induced, endothelium-derived CXCL10 plays a critical role in mediating the T cell–endothelial cell adhesive events that initiate the inflammatory cascade that injures the endothelium and induces the development of ECM.

Authors

Elizabeth W. Sorensen, Jeffrey Lian, Aleksandra J. Ozga, Yoshishige Miyabe, Sophina W. Ji, Shannon K. Bromley, Thorsten R. Mempel, Andrew D. Luster

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Figure 3

Adoptive transfer of Ag-specific WT and Cxcr3–/– CD8+ T cells.

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Adoptive transfer of Ag-specific WT and Cxcr3–/– CD8+ T cells. (A) Schem...
(A) Schematic of experiment. WT mice were coinjected with a 1:1 mix of naive Actin-TdTomato OT-I T cells and Actin-CFP OT-I Cxcr3–/– T cells. Mice were infected with ovalbumin-expressing Plasmodium berghei ANKA (PbA-OVA) 2 hours after transfer and analyzed 8 or 9 days later by (BH) flow cytometry and (IL) brain multiphoton intravital microscopy (MP-IVM). (B) Percentage of WT OT-I (blue symbols) and Cxcr3–/– OT-I cells (red symbols) among total CD8+ T cells in the spleen on day 8 or 9 post-infection (p.i.). Percentage of endogenous CD8+ T cells (black symbols), WT OT-I, and Cxcr3–/– OT-I cells in the spleen stained for (C) CD25, (D) CD62L, (E) CD69, (F) VLA4, or (G) LFA1. (H) Ratio of WT/Cxcr3–/– OT-I in the spleen, blood, and brain on day 8 or 9 p.i. n ≥ 6 mice/group from 3 independent experiments. On day 8 or 9 p.i., cotransfer recipients were imaged by MP-IVM. Number of (I) WT OT-I (blue symbols) and Cxcr3–/– OT-I (red symbols) per field of view (FOV) in the brain vasculature and parenchyma and (J) new T cell attachment events, (K) new detachment events, and (L) percentage of newly attached T cells that subsequently detached from the brain vasculature were enumerated using Imaris software. n = 12 mice total from 4 independent experiments. The groups were compared using (B) Wilcoxon’s, (CI) Friedman’s, and (J and K) Krukal-Wallis tests with Dunn’s multiple comparison test. Bars and lines represent the median in all plots.