Beta(2) integrin deficiency yields unconventional double-negative T cells distinct from mature classical natural killer T cells in mice

β2 Integrins differentially regulate γδ T cell subset thymic development and peripheral maintenance

The γδ T cells reside predominantly at barrier sites and play essential roles in immune protection against infection and cancer. Despite recent advances in the development of γδ T cell immunotherapy, our understanding of the basic biology of these cells, including how their numbers are regulated in vivo, remains poor. This is particularly true for tissue-resident γδ T cells. We have identified the β₂ family of integrins as regulators of γδ T cells. β₂-integrin-deficient mice displayed a striking increase in numbers of IL-17-producing Vγ6Vδ1⁺ γδ T cells in the lungs, uterus, and circulation. Thymic development of this population was normal. However, single-cell RNA sequencing revealed the enrichment of genes associated with T cell survival and proliferation specifically in β₂-integrin-deficient IL-17⁺ cells compared to their wild-type counterparts. Indeed, β₂-integrin-deficient Vγ6⁺ cells from the lungs showed reduced apoptosis ex vivo, suggesting that increased survival contributes to the accumulation of these cells in β₂-integrin-deficient tissues. Furthermore, our data revealed an unexpected role for β₂ integrins in promoting the thymic development of the IFNγ-producing CD27⁺ Vγ4⁺ γδ T cell subset. Together, our data reveal that β₂ integrins are important regulators of γδ T cell homeostasis, inhibiting the survival of IL-17-producing Vγ6Vδ1⁺ cells and promoting the thymic development of the IFNγ-producing Vγ4⁺ subset. Our study introduces unprecedented mechanisms of control for γδ T cell subsets.

Double-negative T resident memory cells of the lung react to influenza virus infection via CD11c(hi) dendritic cells

Immunity to Influenza A virus (IAV) is controlled by conventional TCRαβ(+) CD4(+) and CD8(+) T lymphocytes, which mediate protection or cause immunopathology. Here, we addressed the kinetics, differentiation, and antigen specificity of CD4(-)CD8(-) double-negative (DN) T cells. DNT cells expressed intermediate levels of TCR/CD3 and could be further divided in γδ T cells, CD1d-reactive type I NKT cells, NK1.1(+) NKT-like cells, and NK1.1(-) DNT cells. NK1.1(-) DNT cells had a separate antigen-specific repertoire in the steady-state lung, and expanded rapidly in response to IAV infection, irrespectively of the severity of infection. Up to 10% of DNT cells reacted to viral nucleoprotein. Reinfection experiments with heterosubtypic IAV revealed that viral replication was a major trigger for recruitment. Unlike conventional T cells, the NK1.1(-) DNT cells were in a preactivated state, expressing memory markers CD44, CD11a, CD103, and the cytotoxic effector molecule FasL. DNT cells resided in the lung parenchyma, protected from intravascular labeling with CD45 antibody. The recruitment and maintenance of CCR2(+) CCR5(+) CXCR3(+) NK1.1(-) DNT cells depended on CD11c(hi) dendritic cells (DCs). Functionally, DNT cells controlled the lung DC subset balance, suggesting they might act as immunoregulatory cells. In conclusion, we identify activation of resident memory NK1.1(-) DNT cells as an integral component of the mucosal immune response to IAV infection.

Hematopoietic stem/progenitor cells directly contribute to arteriosclerotic progression via integrin β2

Recent studies described the association between hematopoietic stem/progenitor cell (HSPC) expansion in the bone marrow (BM), leukocytosis in the peripheral blood, and accelerated atherosclerosis. We hypothesized that circulating HSPC may home to inflamed vessels, where they might contribute to inflammation and neointima formation. We demonstrated that Lin⁻ Sca-1⁺ cKit⁺ (LSK cells) in BM and peripheral blood of LDLr^−/− mice on high fat diet expressed significantly more integrin β₂, which was responsible for LSK cell adhesion and migration toward ICAM-1 in vitro, and homing to injured arteries in vivo, all of which were blocked with an anti-CD18 blocking antibody. When homed LSK cells were isolated from ligated artery and injected to irradiated recipients, they resulted in BM reconstitution. Injection of CD18^+/+ LSK cells to immunodeficient Balb/C Rag2⁻ γC^−/− recipients resulted in more severe inflammation and reinforced neointima formation in the ligated carotid artery, compared to mice injected with PBS and CD18^−/− LSK cells. Hypercholesterolemia stimulated ERK phosphorylation (pERK) in LSK cells of LDLr^−/− mice in vivo. Blockade of pERK reduced ARF1 expression, leading to decreased integrin β₂ function on HSPC. In addition, integrin β₂ function could be regulated via ERK-independent LRP1 pathway. Integrin β₂ expression on HSPC is regulated by hypercholesterolemia, specifically LDL, in pERK-dependent and -independent manners, leading to increased homing and localization of HSPC to injured arteries, which is highly correlated with arteriosclerosis. Stem Cells2015;33:1230–1240

T cell-extrinsic CD18 attenuates antigen-dependent CD4+ T cell activation in vivo

The β2 integrins (CD11/CD18) are heterodimeric leukocyte adhesion molecules expressed on hematopoietic cells. The role of T cell-intrinsic CD18 in trafficking of naive T cells to secondary lymphoid organs and in Ag-dependent T cell activation in vitro and in vivo has been well defined. However, the T cell-extrinsic role for CD18, including on APC, in contributing to T cell activation in vivo is less well understood. We examined the role for T cell-extrinsic CD18 in the activation of wild-type CD4(+) T cells in vivo through the adoptive transfer of DO11.10 Ag-specific CD4(+) T cells into CD18(-/-) mice. We found that T cell-extrinsic CD18 was required for attenuating OVA-induced T cell proliferation in peripheral lymph nodes (PLN). The increased proliferation of wild-type DO11.10 CD4(+) T cells in CD18(-/-) PLN was associated with a higher percentage of APC, and these APC demonstrated an increased activation profile and increased Ag uptake, in particular in F4/80(+) APC. Depletion of F4/80(+) cells both reduced and equalized Ag-dependent T cell proliferation in CD18(-/-) relative to littermate control PLN, demonstrating that these cells play a critical role in the enhanced T cell proliferation in CD18(-/-) mice. Consistently, CD11b blockade, which is expressed on F4/80(+) macrophages, enhanced the proliferation of DO11.10 CD4(+) T cells in CD18(+/-) PLN. Thus, in contrast to the T cell-intrinsic essential role for CD18 in T cell activation, T cell-extrinsic expression of CD18 attenuates Ag-dependent CD4(+) T cell activation in PLN in vivo.

The integrin adhesome: from genes and proteins to human disease

The adhesive interactions of cells with their environment through the integrin family of transmembrane receptors have key roles in regulating multiple aspects of cellular physiology, including cell proliferation, viability, differentiation and migration. Consequently, failure to establish functional cell adhesions, and thus the assembly of associated cytoplasmic scaffolding and signalling networks, can have severe pathological effects. The roles of specific constituents of integrin-mediated adhesions, which are collectively known as the 'integrin adhesome', in diverse pathological states are becoming clear. Indeed, the prominence of mutations in specific adhesome molecules in various human diseases is now appreciated, and experimental as well as in silico approaches provide insights into the molecular mechanisms underlying these pathological conditions.

Adaptive immune response to model antigens is impaired in murine leukocyte-adhesion deficiency-1 revealing elevated activation thresholds in vivo

Absence of β₂ integrins (CD11/CD18) leads to leukocyte-adhesion deficiency-1 (LAD1), a rare primary immunodeficiency syndrome. Although extensive in vitro work has established an essential function of β₂ integrins in adhesive and signaling properties for cells of the innate and adaptive immune system, their respective participation in an altered adaptive immunity in LAD1 patients are complex and only partly understood in vivo. Therefore, we investigated adaptive immune responses towards different T-dependent antigens in a murine LAD1 model of β₂ integrin-deficiency (CD18^−/−). CD18^−/− mice generated only weak IgG responses after immunization with tetanus toxoid (TT). In contrast, robust hapten- and protein-specific immune responses were observed after immunization with highly haptenated antigens such as (4-hydroxy-3-nitrophenyl)₂₁ acetyl chicken γ globulin (NP₂₁-CG), even though regularly structured germinal centers with specificity for the defined antigens/haptens in CD18^−/− mice remained absent. However, a decrease in the hapten/protein ratio lowered the efficacy of immune responses in CD18^−/− mice, whereas a mere reduction of the antigen dose was less crucial. Importantly, haptenation of TT with NP (NP-TT) efficiently restored a robust IgG response also to TT. Our findings may stimulate further studies on a modification of vaccination strategies using highly haptenated antigens in individuals suffering from LAD1.

CD3+CD4-CD8- (double negative) T cells: saviours or villains of the immune response?

Recent studies have shown that T cells are not just the latecomers in inflammation but might also play a key role in the early phase of this response. In this context, a number of T cell subsets including NKT cells, mucosal-associated invariant T cells and γ/δ T cells have been shown, together with classical innate immune cells, to contribute significantly to the development and establishment of acute and chronic inflammatory diseases. In this commentary we will focus our attention on a somewhat neglected class of T cells called CD3(+)CD4(-)CD8(-) double negative T cells and on their role in inflammation and autoimmunity. We will summarize the most recent views on their origin at the thymic and peripheral levels as well as their tissue localization in immune and non-lymphoid organs. We will then outline their potential pathogenic role in autoimmunity as well as their homeostatic role in suppressing excessive immune responses deleterious to the host. Finally, we will discuss the potential therapeutic benefits or disadvantages of targeting CD3(+)CD4(-)CD8(-) double negative T cells for the treatment of autoimmune disease. We hope that this overview will shed some light on the function of these immune cells and attract the interest of investigators aiming at the design of novel therapeutic approaches for the treatment of autoimmune and inflammatory conditions.

Analysis of the inflammatory response in HY-TCR transgenic mice highlights the pathogenic potential of CD4- CD8- T cells

Transgenic mice expressing a rearranged T cell receptor (TCR)-αβ prematurely at the double-negative stage develop an abnormal population of peripheral T cells that lack CD4 and CD8 expression and are hyper-reactive to anti-TCR antibody stimulation. One such example is the HY-TCR transgenic mice. These mice express a TCR transgenic specific for the HY antigen that is expressed in male but not in female mice. As a result, male mice have an abnormal population of HY(+)/CD4(-)8(-) or HY(+)/CD4(-)CD8(low) T cells that are much lower in female mice. In this study, we investigated the potential patho/physiological function of these cells in vivo using a model of delayed-type hypersensitivity (DTH) reaction: the λ-carrageenan-induced paw edema. Interestingly, while both male and female HY-TCR mice develop a classical biphasic inflammatory response to λ-carrageenan, the degree of inflammation in the former was much higher than that in the latter. This was accompanied by a selective expansion of HY(+)/CD4(-)8(-) and HY(+)/CD4(-)CD8(low) T cells in male mice and by a markedly increased production of typical DTH cytokines compared with cells from female mice. These results were specific since analysis of the inflammatory response of HY-TCR transgenic mice subjected to zymosan-induced peritonitis showed no differences between male and female mice. Together, these findings provide novel evidence for the pathological role of self-reactive CD4(-)CD8(-) T cells, previously described in several autoimmune strains and recently identified in patients suffering from autoimmune diseases such as systemic lupus erythematosus.