Hitoshi Kikutani

Class IV semaphorin Sema4A enhances T-cell activation and interacts with Tim-2

Semaphorins are a family of phylogenetically conserved soluble and transmembrane proteins. Although many soluble semaphorins deliver guidance cues to migrating axons during neuronal development, some members are involved in immune responses. For example, CD100 (also known as Sema4D), a class IV transmembrane semaphorin, signals through CD72 to effect nonredundant roles in immune responses in a ligand–receptor system that is distinct from any seen previously in the nervous system. Here we report that the class IV semaphorin Sema4A, which is expressed in dendritic cells and B cells, enhances the in vitro activation and differentiation of T cells and the in vivo generation of antigen-specific T cells. Treating mice with monoclonal antibodies against Sema4A blocks the development of an experimental autoimmune encephalomyelitis that is induced by an antigenic peptide derived from myelin oligodendrocyte glycoprotein. In addition, expression cloning shows that the Sema4A receptor is Tim-2, a member of the family of T-cell immunoglobulin domain and mucin domain (Tim) proteins that is expressed on activated T cells.

Increased T Cell Autoreactivity in the Absence of CD40-CD40 Ligand Interactions: A Role of CD40 in Regulatory T Cell Development

Mutations in the CD40 ligand (CD40L) gene lead to X-linked immunodeficiency with hyper-IgM, which is often associated with autoimmune diseases. To determine the contribution of defective CD40-CD40L interactions to T cell autoreactivity, we reconstituted CD40-CD40L interactions by transferring T cells from CD40-deficient mice to syngenic athymic nude mice and assessed autoimmunity. T cells from CD40-deficient mice triggered autoimmune diseases accompanied with elevations of various autoantibodies, while those from wild-type mice did not. In CD40-deficient mice, the CD25+ CD45RBlow CD4+ subpopulation which regulates T cell autoreactivity was markedly reduced. CD40-deficient APCs failed to induce T regulatory cells 1 producing high levels of an inhibitory cytokine, IL-10 in vitro. Furthermore, autoimmune development was inhibited when T cells from CD40-deficient mice were cotransferred with CD45RBlow CD4+ T cells from wild-type mice or with T regulatory cells 1 induced on CD40-expressing APCs. Collectively, our results indicate that CD40-CD40L interactions contribute to negative regulation of T cell autoreactivity and that defective interactions can lead to autoimmunity.

FARP2 triggers signals for Sema3A-mediated axonal repulsion.

Sema3A, a prototypical semaphorin, acts as a chemorepellent or a chemoattractant for axons by activating a receptor complex comprising neuropilin-1 as the ligand-binding subunit and plexin-A1 as the signal-transducing subunit. How the signals downstream of plexin-A1 are triggered upon Sema3A stimulation, however, is unknown. Here we show that, in the presence of neuropilin-1, the FERM domain–containing guanine nucleotide exchange factor (GEF) FARP2 associates directly with plexin-A1. Sema3A binding to neuropilin-1 induces the dissociation of FARP2 from plexin-A1, resulting in activation of FARP2s Rac GEF activity, Rnd1 recruitment to plexin-A1, and downregulation of R-Ras. Simultaneously, the FERM domain of FARP2 sequesters phosphatidylinositol phosphate kinase type I isoform PIPKIγ661 from talin, thereby inhibiting its kinase activity. These activities are required for Sema3A-mediated repulsion of outgrowing axons and suppression of neuronal adhesion. We therefore conclude that FARP2 is a key molecule involved in the response of neuronal growth cones to class-3 semaphorins.

Semaphorins in interactions between T cells and antigen-presenting cells

Although semaphorins were identified originally as guidance cues for developing neuronal axons, accumulating evidence indicates that several semaphorins are expressed also in the immune system. SEMA4D (CD100), which is expressed constitutively by T cells, enhances the activation of B cells and dendritic cells (DCs) through its cell-surface receptor, CD72. SEMA4A, which is expressed by DCs, is involved in the activation of T cells through interactions with TIM2. So, these semaphorins seem to function in the reciprocal stimulation of T cells and antigen-presenting cells (APCs). Emerging evidence indicates that additional semaphorins and related molecules are involved in T-cell–APC interactions also.

Requirement for the Lymphocyte Semaphorin, CD100, in the Induction of Antigen-Specific T Cells and the Maturation of Dendritic Cells

CD100 belongs to the semaphorin family, several members of which are known to act as repulsive axonal guidance factors during neuronal development. We have previously demonstrated that CD100 plays a crucial role in humoral immunity. In this study, we show that CD100 is also important for cellular immunity through the maturation of dendritic cells (DCs). CD100−/− mice fail to develop experimental autoimmune encephalomyelitis induced by myelin oligodendrocyte glycoprotein peptide, because myelin oligodendrocyte glycoprotein-specific T cells are not generated in the absence of CD100. In vitro studies with T cells from OVA-specific TCR-transgenic mice demonstrate that Ag-specific T cells lacking CD100 fail to differentiate into cells producing either IL-4 or IFN-γ in the presence of APCs and OVA peptide. In addition, DCs from CD100−/− mice display poor allostimulatory capabilities and defects in costimulatory molecule expression and IL-12 production. The addition of exogenous soluble rCD100 restores normal functions in CD100−/− DCs and further enhances functions of normal DCs. Furthermore, treatment of Ag-pulsed DCs with both soluble CD100 and anti-CD40 before immunization significantly enhances their immunogenicity. This treatment elicits improved T cell priming in vivo, enhancing both primary and memory T cell responses. Collectively, these results demonstrate that CD100, which enhances the maturation of DCs, is essential in the activation and differentiation of Ag-specific T cells.

Immune semaphorins: a new area of semaphorin research.

The semaphorin family comprises soluble and membrane-bound proteins originally identified as axonal guidance cues that function during neuronal development. Emerging evidence suggests that a subset of semaphorins, called immune semaphorins, function in the immune system. The class IV semaphorins Sema4D/CD100 and Sema4A use CD72 and Tim-2, respectively, as receptors during immune responses; these receptors comprise a set distinct from those used by semaphorins in the nervous system. Sema4D/CD100, which is expressed constitutively by T cells, is involved in the activation of B cells and dendritic cells, whereas Sema4A is preferentially expressed on B cells and dendritic cells, and is involved in the activation of T cells. Additionally, increasing evidence suggests that some other semaphorins, including viral-encoded semaphorins, might also play important roles in the immune system.

Enhanced Immune Responses in Transgenic Mice Expressing a Truncated Form of the Lymphocyte Semaphorin CD100

CD100/Sema4D is a 150-kDa transmembrane protein that belongs to the semaphorin family. Binding of CD100 to CD72 enhances the immune response by turning off the negative signaling effects of CD72. To investigate the physiological functions of CD100 in vivo, we generated transgenic mice expressing a truncated form of CD100. A large amount of the soluble form of CD100 was detected in the sera of mice expressing a truncated form of CD100, although the amount of CD100 was only slightly elevated on the surface of B cells. In the mutant mice the development of conventional B and T cells appeared normal in terms of the surface marker phenotypes, while the number of CD5+ B-1 cells in the peritoneal cavity increased in comparison with wild-type mice. In vitro proliferation and Ig production of B cells in response to CD40 stimulation were considerably enhanced in mice expressing a truncated form of CD100. Additionally, in vivo both Ab responses against T cell-dependent Ags and generation of Ag-specific T cells were enhanced. Furthermore, introduction of the CD100-transgene could restore in vitro B cell responses as well as in vivo Ab production against T cell-dependent Ag in CD100-deficient mice. Collectively, these results not only indicate that CD100 has an important role in the immune system, but also that the soluble form of CD100 released from the cell surface can exert functions in vivo.

Loss of dopaminergic neurons by the induction of inducible nitric oxide synthase and cyclooxygenase-2 via CD40: Relevance to Parkinson's disease

A glial reaction associated with up‐regulation of inflammatory molecules has been suggested to play an important role in dopaminergic neuron loss in Parkinsons disease (PD). Among inflammatory molecules, inducible nitric oxide synthase (iNOS) and cyclooxygenase‐2 (COX‐2) have been focused upon as key factors in the pathogenesis. However, the mechanism of how these molecules are induced in PD brains is not clearly understood. We focused on CD40, which is expressed on neural cells and could be implicated in the neuroinflammation by inducing inflammatory molecules. We showed that both iNOS and COX‐2 were up‐regulated in microglia and astrocytes by CD40 stimulation in association with a low dose of interferon‐γ (IFN‐γ) in vitro. Selective loss of dopaminergic neurons was induced by costimulation with CD40 and IFN‐γ in mesencephalic cultures, which was protected by selective inhibitors of iNOS and/or COX‐2. We also found in CD40‐stimulated astrocytes an increase of a low‐affinity IgE receptor CD23, which is known to induce iNOS expression. Together these data suggest that up‐regulated iNOS and COX‐2 via the CD40 pathway may lead to dopaminergic neuron loss and may participate in the neuroinflammaory pathway of PD.

Roles of the semaphorin family in immune regulation.

The immune system and the nervous system have distinct roles in maintaining physiological homeostasis. These independent systems, however, influence each other while sharing common resources, including the cytokines and members of the immunoglobulin superfamily. Semaphorins are one of these shared molecular families that are biologically active in both systems. Although semaphorins were originally identified as axon guidance factors functioning in the nervous system, recent studies have uncovered additional immunological functions. For example, ligand-receptor systems distinct from those characterized in the nervous system govern class IV semaphorin, CD100/Sema4D and Sema4A activity in immune responses. This review provides an overview of the currently emerging immunoregulatory functions of Immuno-semaphorins.

Semaphorins: a new class of immunoregulatory molecules.

The immune and nervous systems play distinct roles in maintaining physiological homeostasis. Recent data indicates that these systems influence one another and share many proteins and pathways that are essential for their normal function and development. Molecules originally shown to be critical for the development of proper immune responses have recently been found to function in the nervous system. Conversely, neuronal guidance cues can modulate immune functions. Although semaphorins were originally identified as axon guidance factors active during neuronal development, several recent studies have identified indispensable functions for these molecules in the immune system. This review provides an overview of the rapidly emerging functions of semaphorins and their receptors in the immune system.