Central Nervous System Stromal Cells Control Local CD8(+) T Cell Responses during Virus-Induced Neuroinflammation - PubMed (original) (raw)

Central Nervous System Stromal Cells Control Local CD8(+) T Cell Responses during Virus-Induced Neuroinflammation

Jovana Cupovic et al. Immunity. 2016.

Abstract

Stromal cells generate a complex cellular scaffold that provides specialized microenvironments for lymphocyte activation in secondary lymphoid organs. Here, we assessed whether local activation of stromal cells in the central nervous system (CNS) is mandatory to transfer immune recognition from secondary lymphoid organs into the infected tissue. We report that neurotropic virus infection in mice triggered the establishment of such stromal cell niches in the CNS. CNS stromal cell activation was dominated by a rapid and vigorous production of CC-motif chemokine receptor (CCR) 7 ligands CCL19 and CCL21 by vascular endothelial cells and adjacent fibroblastic reticular cell (FRC)-like cells in the perivascular space. Moreover, CCR7 ligands produced by CNS stromal cells were crucial to support recruitment and local re-activation of antiviral CD8(+) T cells and to protect the host from lethal neuroinflammatory disease, indicating that CNS stromal cells generate confined microenvironments that control protective T cell immunity.

Keywords: Inflammation; encephalitis; stromal cells; virus infection.

Copyright © 2016 Elsevier Inc. All rights reserved.

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Graphical abstract

Figure 1

Figure 1

Viral Replication in the CNS Drives Strong Induction of CCR7 Ligand Expression (A) C57BL/6 (WT) mice were infected i.n. with 5 × 104 pfu MHV A59. Viral titers in cervical lymph nodes (cLN) and the indicated CNS regions were determined at different days post infection. Values indicate mean of log transformed values ± SEM from two independent experiments (n = 6 mice per time point). (B) Distribution of MHV infected cells visualized by staining against MHV-N, Iba-1 and NeuN on paramedian sagittal brain section (day 6 p.i.) (i); high resolution analysis of infected Iba-1+ microglial cells in olfactory bulb (ii), NeuN+ neurons of the anterior olfactory nucleus (iii) and ASPA+ oligodendrocytes of the locus coeruleus (iv); scale bars equal 1 mm (i) and 10 μm (ii–iv); (representative images from two experiments with four mice). (C) Quantitative RT-PCR analysis of genes encoding for inducible and homeostatic chemokines and genes associated with lymphoid organogenesis in cervical lymph nodes (cLN) and olfactory bulb of infected mice (day 6 p.i.) compared to naive controls. Spatial and temporal regulation of (D) Ccl19 and (E) Ccl21 mRNA was analyzed at the indicated time points by quantitative RT-PCR. Values indicate mean ± SEM from two independent experiments (n = 4 mice per time point). See also Figure S1.

Figure 2

Figure 2

Viral Infection Drives Local Activation of CNS Stromal Cells Confocal microscopic analysis of Ccl19 gene expression, CCL21 production, and ICAM1 upregulation MHV-infected olfactory bulbs of _Ccl19_eyfp mice. (A) Olfactory bulbs of infected _Ccl19_eyfp mice stained with the indicated antibodies at day 6 p.i. Sagittal overview of the olfactory bulb. Scale bar represents 200 μm. Boxed areas show magnified meningeal and sub-meningeal regions, scale bar represents 20 μm. (B) Ccl19 gene activity as revealed by EYFP expression on day 6 p.i. Olfactory bulb sections were stained with antibodies against PDPN and CCL21 and counterstained with DAPI. Merged channels are shown in the upper left panel; scale bar represents 200 μm. Boxed areas show magnified meningeal and sub-meningeal regions; scale bar represents 20 μm. (C–F) High-resolution analysis of meningeal and submeningeal areas in virus-infected olfactory bulb tissue using antibodies against the indicated molecules and counterstaining with DAPI; arrows indicate BECs, arrowheads indicate FRC-like cells. (C) Meningeal blood vessel is shown; scale bar represents 30 μm. (D) Submeningeal postcapillary venule is shown; scale bar represents 10 μm. (E) ICAM1 upregulation in meningeal blood vessel from day 6 infected animal with inlet showing a comparable blood vessel from naive control; scale bars represent 30 μm. (F) ICAM1 expression of PDPN+EYFP+ FRC-like perivascular cells; scale bars represent 30 μm. Representative images from three independent experiments (n = 6 mice). See also Figure S2.

Figure 3

Figure 3

Virus Infection-Induced Activation and Chemokine Expression of CNS Stromal Cells Flow cytometric analysis of myelin- and CD45-depleted cells from olfactory bulbs of C57BL/6 mice. (A–C) Fibroblastic and endothelial stromal cells were distinguished using gating on CD45-negative (A) and glial fibrillary acidic protein (GFAP)-negative (B) cells and staining for CD31 and PDPN expression (C); representative dot plot analysis with quadstat values for CD31 and PDPN expression. (D) Expression of fibroblastic stromal markers ICAM1, VCAM1, MHC I, CD140a, CD140b, and CD44 on PDPN+CD31– fibroblastic CNS stromal cells from naive (upper panels) and day 6 infected animals (lower panels). (E) Expression of ICAM1, VCAM1, and MHC I on PDPN–CD31+ endothelial stromal populations from naive (upper panels) and infected animals (lower panels). (F) Intracellular CCL21 production by PDPN+CD31– fibroblastic (left panel) and PDPN–CD31+ endothelial (right panel) stromal cells. Values indicate mean percentage of positive cells ± SEM compared to isotype control staining (gray shaded histograms); representative plots from two independent experiments (n = 4–6 mice per group). See also Figure S3.

Figure 4

Figure 4

High Susceptibility to Neurotropic Viral Infection in _Ccr7_-Deficient Mice (A) Weight loss of _Ccr7_-deficient, plt/plt, and WT mice was recorded during the indicated time period following infection with MHV A59. Values indicate mean percentage of the initial weight ± SEM from two independent experiments (n = 7–10 mice per group). (B) Viral titers in CNS tissues as determined at day 10 after infection. Data indicate means of log transformed values ± SEM from two independent experiments (n = 8 mice per group). (C) Tetramer-binding and IFN-γ production of (D) CD8+ and (E) CD4+ T cells from the whole brain was determined by flow cytometry on day 10 after infection. Representative dot plots analysis with percentage of virus-specific T cell population indicated. Graphs indicate mean percentage ± SEM of the respective virus-specific T cell populations from two independent experiments (n = 8 mice per group). Statistical analysis was performed using the Student’s t test (∗∗p < 0.01; ∗∗∗p < 0.001; n.s. not significant). See also Figure S4.

Figure 5

Figure 5

CCR7-Dependent Activation and Recruitment of Antiviral CD8+ T Cells Protects from Virus-Induced CNS Disease Thy1.2+ WT mice received 106 TCR transgenic Thy 1.1+ Spiky cells labeled with the intracellular dye carboxy-fluorescein succimidyl ester (CFSE) and were subsequently infected i.n. with MHV. CFSE dilution of transferred Thy1.1+ CD8+ T cells from the cLNs (A) and brain tissue (B) was determined by flow cytometry at the indicated time points post infection. Values in histograms indicate percentage of proliferated cells (black line) compared to naive controls (gray histogram); representative data from two independent experiments (n = 5 mice). (C) CCR7 and (D) CD62L expression on Thy1.1+CD8+ T cells from cLNs, blood and the brain was performed at the indicated time points post infection. Values in histograms indicate mean fluorescent intensity (MFI) values of the total Thy1.1+CD8+ T population (black lines) minus MFI of isotype controls (gray shaded lines) ± SEM. Data from two independent experiments (n = 5 mice). Expression of effector cytokines TNF-α and IFN-γ and the degranulation marker Lamp-1 by CNS infiltrating Thy1.1+CD8+ T cells (day 8 p.i.) following in vitro peptide restimulation is shown in representative dot plots (E) and summarized in a bar graph (F) with mean percentage ± SEM pooled from two independent experiments (n = 5 mice). _Ccr7_-deficient mice were adoptively transferred with a total of 107 of CD3+_Ccr7_-proficient, CD3+_Ccr7_-deficient, or 106 of transgenic Spiky cells and infected with MHV. (G) Survival and (H) weight loss of the mice were recorded during the indicated period of time. Values in (H) indicate mean percentage of the initial weight ± SEM pooled from three independent experiments (n = 9 mice per group). See also Figure S5.

Figure 6

Figure 6

Expression of CCR7 Ligands in the CNS Controls CD8+ T Cell Recruitment and Function (A) Intracellular CCL21 production by PDPN+CD31− cells from cLNs and olfactory bulbs of WT (black lines) and plt/plt (red lines) mice either infected with MHV (solid lines) or left naive (dashed lines). Data are representative of two independent experiments (n = 4 mice per group). (B and C) 105 TCR Spiky _Ccr7_-proficient or _Ccr7_-deficient CD8+ T cells were adoptively transferred into plt/plt mice 12 hr before infection. Absolute numbers of _Ccr7_-proficient and _Ccr7_-deficient Spiky transgenic cells in (B) cLNs and (C) brain were recorded on day 4 post infection. Representative contour plots of T cell activation markers CD44 and CD62L expressed by _Ccr7_-proficient (black) and _Ccr7_-deficient (red) Spiky cells compared to LN-derived naive control cells (gray contour). Values in the plots represent percentage of activated cells (i.e., CD44high or CD62Llow, respectively). At day 6 post infection, absolute numbers of _Ccr7_-proficient and _Ccr7_-deficient Spiky transgenic cells in (D) brain and (E) cLNs were determined. Frequencies of brain infiltrating Spiky cells expressing markers of (F) proliferation (Ki67) and (G) apoptosis (active caspase 3) were analyzed using flow cytometry day 6 after the infection. Data represent mean value ± SEM from two independent experiments (n = 5–6 mice per group). (H–J) A mix of 104 of Ly5.1+_Ccr7_-proficient and 104 of Thy1.1+_Ccr7_-deficient Spiky TCR transgenic CD8+ T cells was adoptively transferred into plt/plt mice 12 hr prior to infection. (H) Representative dot plots showing the accumulation of _Ccr7_-proficient or _Ccr7_-deficient Spiky CD8+ T cells in cLNs (left panel) and brain tissue (right panel) of plt/plt mice on 6 day post infection. Values indicate the percentage of the respective CD8+ T cell population. (I) Frequencies of _Ccr7_-proficient and _Ccr7_-deficient TCR transgenic CD8+ T cells in cLNs and CNS of MHV infected plt/plt mice. (J) IFN-γ production by _Ccr7_-proficient and -deficient TCR transgenic CD8+T cells in cLNs and CNS. Data represent mean value ± SEM from two independent experiments (n = 5 mice). Statistical analysis was performed using the Student’s t test (∗∗p < 0.01;∗∗∗p < 0.001; n.s. not significant).

Figure 7

Figure 7

Activated CNS Stromal Cells Guide Antiviral CD8+ T Cells to the CNS Parenchyma (A and B) C57BL/6 (A) and Ccl19 eyfp mice (B) were infected with MHV intranasally and brains were harvested for histological analysis on day 6 post infection. Meningeal and submeningeal areas were inspected for interactions of CD8+ T cells with endothelial cells (arrowheads) and perivascular fibroblasts (arrows). Scale bar represents 10 μm in (A) and 20 μm in (B). (C) _Ccl19_eypf/idtr mice were infected with MHV intranasally, treated with PBS or diphtheria toxin (DT, 1 ng/g body weight) on days 1 and 3 post infection, and brains and cLNs (inlets) were examined by histological analysis on day 8 post infection using the indicated antibodies. Scale bar represents 30 μm. (D and E) Absolute numbers of CD8+ (D) and CD4+ (E) T cells, and viral titers (F) in the brains of DT-treated mice. (G and H) Absolute numbers of CD8+ (G) and CD4+ (H) T cells in cLNs of DT-treated mice. Data are shown as mean ± SEM (n = 4–6 mice per group, pooled from two independent experiments). (I) Positioning of antiviral CD8+ T cells in olfactory bulb tissue in Ccr7 +/+ and Ccr7 −/− mice on day 6 post infection. Scale bar represents 10 μm. (J) Quantification of CD8+ T cell density in meningeal/submeningeal (M/SM) and parenchymal (PAR) areas as determined by histological analysis in the olfactory bulbs of Ccr7 +/+ and Ccr7 −/− mice. Data are shown as mean ± SEM (n = 3–4 mice per group, two independent experiments); statistical analysis was performed by Student’s t test (∗p < 0.05; ∗∗p < 0.01).

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