Mascha Greuter

Chemokine CXCL13 is essential for lymph node initiation and is induced by retinoic acid and neuronal stimulation

The location of embryonic lymph node development is determined by the initial clustering of lymphoid tissue–inducer (LTi) cells. Here we demonstrate that both the chemokine CXCL13 and the chemokine CCL21 attracted LTi cells at embryonic days 12.5–14.5 and that initial clustering depended exclusively on CXCL13. Retinoic acid (RA) induced early CXCL13 expression in stromal organizer cells independently of lymphotoxin signaling. Notably, neurons adjacent to the lymph node anlagen expressed enzymes essential for RA synthesis. Furthermore, stimulation of parasymphathetic neural output in adults led to RA receptor (RAR)-dependent induction of CXCL13 in the gut. Therefore, our data show that the initiation of lymph node development is controlled by RA-mediated expression of CXCL13 and suggest that RA may be provided by adjacent neurons.

LTβR Signaling Induces Cytokine Expression and Up-Regulates Lymphangiogenic Factors in Lymph Node Anlagen

The formation of lymph nodes is a complex process crucially controlled through triggering of LTβR on mesenchymal cells by LTα1β2 expressing lymphoid tissue inducer (LTi) cells. This leads to the induction of chemokines to attract more hematopoietic cells and adhesion molecules to retain them. In this study, we show that the extravasation of the first hematopoietic cells at future lymph node locations occurs independently of LTα and that these cells, expressing TNF-related activation-induced cytokine (TRANCE), are the earliest LTi cells. By paracrine signaling the first expression of LTα1β2 is induced. Subsequent LTβR triggering on mesenchymal cells leads to their differentiation to stromal organizers, which now also start to express TRANCE, IL-7, as well as VEGF-C, in addition to the induced adhesion molecules and chemokines. Both TRANCE and IL-7 will further induce the expression of LTα1β2 on newly arrived immature LTi cells, resulting in more LTβR triggering, generating a positive feedback loop. Thus, LTβR triggering by LTi cells during lymph node development creates a local environment to which hematopoietic precursors are attracted and where they locally differentiate into fully mature, LTα1β2 expressing, LTi cells. Furthermore, the same signals may regulate lymphangiogenesis to the lymph node through induction of VEGF-C.

Effective collaboration between marginal metallophilic macrophages and CD8+ dendritic cells in the generation of cytotoxic T cells

The spleen is the lymphoid organ that induces immune responses toward blood-borne pathogens. Specialized macrophages in the splenic marginal zone are strategically positioned to phagocytose pathogens and cell debris, but are not known to play a role in the activation of T-cell responses. Here we demonstrate that splenic marginal metallophilic macrophages (MMM) are essential for cross-presentation of blood-borne antigens by splenic dendritic cells (DCs). Our data demonstrate that antigens targeted to MMM as well as blood-borne adenoviruses are efficiently captured by MMM and exclusively transferred to splenic CD8+ DCs for cross-presentation and for the activation of cytotoxic T lymphocytes. Depletion of macrophages in the marginal zone prevents cytotoxic T-lymphocyte activation by CD8+ DCs after antibody targeting or adenovirus infection. Moreover, we show that tumor antigen targeting to MMM is very effective as antitumor immunotherapy. Our studies point to an important role for splenic MMM in the initial steps of CD8+ T-cell immunity by capturing and concentrating blood-borne antigens and the transfer to cross-presenting DCs which can be used to design vaccination strategies to induce antitumor cytotoxic T-cell immunity.

Lymph Node Stromal Cells Support Dendritic Cell-Induced Gut-Homing of T Cells

T cells are imprinted to express tissue-specific homing receptors upon activation in tissue-draining lymph nodes, resulting in their migration to the site of Ag entry. Expression of gut-homing molecules α4β7 and CCR9 is induced by retinoic acid, a vitamin A metabolite produced by retinal dehydrogenases, which are specifically expressed in dendritic cells as well as stromal cells in mucosa-draining lymph nodes. In this study, we demonstrate that mesenteric lymph node stromal cell-derived retinoic acid can directly induce the expression of gut-homing molecules on proliferating T cells, a process strongly enhanced by bone marrow-derived dendritic cells in vitro. Therefore, cooperation of sessile lymph node stromal cells with mobile dendritic cells warrants the imprinting of tissue specific homing receptors on activated T cells.

Initiation of Cellular Organization in Lymph Nodes Is Regulated by Non-B Cell-Derived Signals and Is Not Dependent on CXC Chemokine Ligand 13

The molecular and cellular events that initiate the formation of T and B cell areas in developing lymph nodes are poorly understood. In this study we show that formation of the lymphoid architecture in murine neonatal lymph nodes evolves through a series of distinct stages. The initial segregation of T and B cells is regulated in a CXCL13-independent manner, characterized by the localization of B cells in a ring-like pattern in the outer cortex on day 4. However, during this CXCL13-independent phase of lymph node modeling, CXCL13 is expressed and regulated in a lymphotoxin-α1β2 (LTα1β2)-dependent manner. Surprisingly, neonatal B cells are unable to respond to this chemokine and also lack surface LTα1β2 expression. At this time, CD45+CD4+CD3− cells are the predominant LTα1β2-expressing cells and are also capable of responding to CXCL13. From day 4 on, architectural changes become CXCL13 dependent, and B cells become fully CXCL13 responsive, express LTα1β2, and cluster in anatomically distinct follicles. Because the initial induction of CXCL13 is dependent on LTα1β2, a role for CD45+CD4+CD3− cells in inducing chemokine expression in the developing lymph nodes is proposed and, as such, a role in initiation of the shaping of the microenvironment.

Lymph sacs are not required for the initiation of lymph node formation

The lymphatic vasculature drains lymph fluid from the tissue spaces of most organs and returns it to the blood vasculature for recirculation. Before reaching the circulatory system, antigens and pathogens transported by the lymph are trapped by the lymph nodes. As proposed by Florence Sabin more than a century ago and recently validated, the mammalian lymphatic vasculature has a venous origin and is derived from primitive lymph sacs scattered along the embryonic body axis. Also as proposed by Sabin, it has been generally accepted that lymph nodes originate from those embryonic primitive lymph sacs. However, we now demonstrate that the initiation of lymph node development does not require lymph sacs. We show that lymph node formation is initiated normally in E14.5 Prox1-null mouse embryos devoid of lymph sacs and lymphatic vasculature, and in E17.5 Prox1 conditional mutant embryos, which have defective lymph sacs. However, subsequent clustering of hematopoietic cells within these developing lymph nodes is less efficient.

Secretory Leukoprotease Inhibitor in Mucosal Lymph Node Dendritic Cells Regulates the Threshold for Mucosal Tolerance

The notion that the mucosal immune system maintains a tolerogenic response to harmless Ags while continually being challenged with microbial products seems an enigma. The aim of this study was to unravel mechanisms that are involved in regulating the development of tolerance under constant microbial pressure. The tolerogenic response to Ags administered via the nasal mucosa is dependent on the organized lymphoid tissue of the cervical lymph nodes (LN). We show that cervical LN differentially express secretory leukoprotease inhibitor (SLPI) compared with peripheral LN. SLPI was expressed by dendritic cells (DCs) and because SLPI is known to suppress LPS responsiveness, it was hypothesized that its expression in mucosal DCs may be required to regulate cellular activation to microbial products. Indeed, compared with wild-type controls, bone marrow-derived DCs from SLPI−/− mice released more inflammatory cytokines and enhanced T cell proliferation after stimulation with low dose LPS. This increased sensitivity to LPS was accompanied by increased NF-κB p65 activation in SLPI−/− DCs. In vivo, nasal application of OVA with LPS to SLPI−/− mice resulted in enhanced DC activation in the cervical LN reflected by increased costimulatory molecule expression and release of inflammatory cytokines. This led to failure to maintain tolerance to nasal OVA application in the presence of low doses of LPS. We propose that expression of SLPI functions as a rheostat by controlling the level of bacterial stimuli that induce mucosal DC activation. As such, it regulates the quality of the ensuing Ag-specific immune response in the mucosa draining LN.

Lymph node stromal cells constrain immunity via MHC class II self-antigen presentation

Non-hematopoietic lymph node stromal cells shape immunity by inducing MHC-I-dependent deletion of self-reactive CD8+ T cells and MHC-II-dependent anergy of CD4+ T cells. In this study, we show that MHC-II expression on lymph node stromal cells is additionally required for homeostatic maintenance of regulatory T cells (Tregs) and maintenance of immune quiescence. In the absence of MHC-II expression in lymph node transplants, i.e. on lymph node stromal cells, CD4+ as well as CD8+ T cells became activated, ultimately resulting in transplant rejection. MHC-II self-antigen presentation by lymph node stromal cells allowed the non-proliferative maintenance of antigen-specific Tregs and constrained antigen-specific immunity. Altogether, our results reveal a novel mechanism by which lymph node stromal cells regulate peripheral immunity. DOI: http://dx.doi.org/10.7554/eLife.04433.001

CD200-CD200R signaling suppresses anti-tumor responses independently of CD200 expression on the tumor

Expression of CD200, the gene encoding the ligand for the inhibitory immune receptor CD200R, is an independent prognostic factor for various forms of leukemia predicting worse overall survival of the patients. The enhanced expression of CD200 on the tumors implies that anti-tumor responses can be enhanced by blockage of the CD200–CD200R interaction. Indeed, antibody-mediated blockade of the CD200-CD200R inhibitory axis is currently evaluated in clinical tests to boost immune responses against CD200-expressing tumors. Here, we show that mice lacking CD200, the exclusive ligand for CD200R, are resistant to chemical skin carcinogenesis. Importantly, CD200R controls tumor outgrowth independently of CD200 expression by the tumor cells themselves. Furthermore, Cd200−/− mice do not become tolerant to intranasally administered antigens, suggesting that tumor rejection is normally suppressed through CD200-induced immune tolerance. Decreased tumor outgrowth is accompanied by increased expression of the proinflammatory cytokines interleukin (IL)-1β and IL-6 by the lymph node (LN) dendritic cells. During carcinogenesis, skin-draining LNs of Cd200−/− mice contain increased numbers of IL-17-producing FoxP3+ cells, which preferentially home to the tumors. Thus, the CD200-CD200R axis induces tolerance to external and tumor antigens and influences the T-regulatory/Th17 cell ratio. We demonstrate for the first time that the absence of CD200R signaling inhibits outgrowth of an endogenous tumor irrespective of CD200 expression by the tumor cells. This important paradigm shift leads to a much broader applicability of CD200-blockade in the treatment of tumors.

Blockade of IDO Inhibits Nasal Tolerance Induction

The amino acid tryptophan is essential for the proliferation and survival of cells. Modulation of tryptophan metabolism has been described as an important regulatory mechanism for the control of immune responses. The enzyme IDO degrades the indole moiety of tryptophan, not only depleting tryptophan but also producing immunomodulatory metabolites called kynurenines, which have apoptosis-inducing capabilities. In this study, we show that IDO is more highly expressed in nonplasmacytoid dendritic cells of the nose draining lymph nodes (LNs), which form a unique environment to induce tolerance to inhaled Ags, when compared with other peripheral LNs. Upon blockade of IDO during intranasal OVA administration, Ag-specific immune tolerance was abrogated. Analysis of Ag-specific T cells in the LNs revealed that inhibition of IDO resulted in enhanced survival at 48 h after antigenic stimulation, although this result was not mediated through alterations in apoptosis or cell proliferation. Furthermore, no differences were found in CD4+ T cells expressing FoxP3. Our data suggest that the level of IDO expression in dendritic cells, present in nose draining LNs, allows for the generation of a sufficient number of regulatory T cells to control and balance effector T cells in such a way that immune tolerance is induced, whereas upon IDO blockade, effector T cells will outnumber regulatory T cells, leading to immunity.