A normalized subtracted gene expression library was generated from freshly isolated mouse dendritic cells (DC) of all subtypes, then used to construct cDNA microarrays. The gene expression profiles of the three splenic conventional DC (cDC) subsets were compared by microarray hybridization and two genes encoding signal regulatory protein β (Sirpβ1 and Sirpβ4) molecules were identified as differentially expressed in CD8− cDC. Genomic sequence analysis revealed a third Sirpβ member localized in the same gene cluster. These Sirpβ genes encode cell surface molecules containing extracellular Ig domains and short intracytoplasmic domains that have a charged amino acid in the transmembrane region which can potentially interact with ITAM-bearing molecules to mediate signaling. Indeed, we demonstrated interactions between Sirpβ1 and β2 with the ITAM-bearing signaling molecule Dap12. Real-time PCR analysis showed that all three Sirpβ genes were expressed by CD8− cDC, but not by CD8+ cDC or plasmacytoid pre-DC. The related Sirpα gene showed a similar expression profile on cDC subtypes but was also expressed by plasmacytoid pre-DC. The differential expression of Sirpα and Sirpβ1 molecules on DC was confirmed by staining with mAbs, including a new mAb recognizing Sirpβ1. Cross-linking of Sirpβ1 on DC resulted in a reduction in phagocytosis of Leishmania major parasites, but did not affect phagocytosis of latex beads, perhaps indicating that the regulation of phagocytosis by Sirpβ1 is a ligand-dependent interaction. Thus, we postulate that the differential expression of these molecules may confer the ability to regulate the phagocytosis of particular ligands to CD8− cDC.
CD37 is a leukocyte-specific protein belonging to the tetraspanin superfamily. Previously thought to be predominantly a B cell molecule, CD37 is shown in this study to regulate T cell proliferation. CD37-deficient (CD37−/−) T cells were notably hyperproliferative in MLR, in response to Con A, or CD3-TCR engagement particularly in the absence of CD28 costimulation. Hyperproliferation was not due to differences in memory to naive T cell ratios in CD37−/− mice, apoptosis, or TCR down-modulation. Division cycle analyses revealed CD37−/− T cells to enter first division earlier than wild-type T cells. Importantly, proliferation of CD37−/− T cells was preceded by enhanced early IL-2 production. We hypothesized CD37 to be involved in TCR signaling and this was supported by the observation that CD4/CD8-associated p56Lck kinase activity was increased in CD37−/− T cells. Remarkably, CD37 cross-linking on human T cells transduced signals that led to complete inhibition of CD3-induced proliferation. In the presence of CD28 costimulation, CD37 engagement still significantly reduced proliferation. Taken together, these results demonstrate a regulatory role for CD37 in T cell proliferation by influencing early events of TCR signaling.
Signaling by the serine and threonine kinase Akt (also known as protein kinase B), a pathway that is common to all eukaryotic cells, is central to cell survival, proliferation, and gene induction. We sought to elucidate the mechanisms underlying regulation of the kinase activity of Akt in the immune system. We found that the four-transmembrane protein CD37 was essential for B cell survival and long-lived protective immunity. CD37-deficient (Cd37(-/-)) mice had reduced numbers of immunoglobulin G (IgG)-secreting plasma cells in lymphoid organs compared to those in wild-type mice, which we attributed to increased apoptosis of plasma cells in the germinal centers of the spleen, areas in which B cells proliferate and are selected. CD37 was required for the survival of IgG-secreting plasma cells in response to binding of vascular cell adhesion molecule 1 to the α(4)β(1) integrin. Impaired α(4)β(1) integrin-dependent Akt signaling in Cd37(-/-) IgG-secreting plasma cells was the underlying cause responsible for impaired cell survival. CD37 was required for the mobility and clustering of α(4)β(1) integrins in the plasma membrane, thus regulating the membrane distribution of α(4)β(1) integrin necessary for activation of the Akt survival pathway in the immune system.
A major question in immunology is how DC can display limited amounts of individual peptide-MHC complexes and still induce cross-linking of T-cell receptors to initiate cellular responses. One suggested mechanism is that MHC exists at the cell surface in high avidity multimers, and tetraspanin proteins, known to laterally associate with both MHC classes I and II, promote MHC multimerisation. To validate this theory, we tested the ability of DC deficient in either one of two typical tetraspanin molecules: CD37 or CD151 to present peptide to Ag-specific T cells. Surprisingly, although they exhibited no developmental or maturation defects, DC lacking either CD37 or CD151 expression were hyperstimulatory to T cells. We demonstrate that CD37 and CD151 control DC-mediated T-cell activation by two different mechanisms: CD151 regulates co-stimulation whereas CD37 regulates peptide/MHC presentation. The implications of these results on the model suggesting that tetraspanins promote MHC multimerisation are discussed.Key words: Ag presentation . DC . MHC . Tetraspanin IntroductionAg-specific cellular immune responses are initiated by the presentation of peptides by DC to naive T lymphocytes. Optimal T-cell priming by DC entails three signals: recognition of the specific peptide-MHC by the T-cell receptor, specific molecular interactions between multiple cell surface molecules, which result in co-stimulatory signals, and cytokines produced by DC, which promote T-cell polarization [1].The first signal requires cross-linking of the T-cell receptor, by peptide-MHC [2], and precisely how a DC can display limited amounts of individual peptide-MHC complexes and still induce crosslinking is not completely understood [3]. There is evidence that MHC is not randomly displayed at the DC surface but rather is organised into multi-molecular clusters. MHC class II (MHC-II) clusters have been visualised in microscopic studies [3], and biochemical and crystallographic evidence suggests that MHC-II molecules can interact with one another to form dimers or higher-order multimers [4]. MHC-II can also form multimers with MHC class I (MHC-I) at the cell surface [5]. MHC-II clustering may also occur as a result of incorporation into lipid raft microdomains. The potential importance of rafts in MHC-peptide presentation is illustrated by the poor Ag presentation observed when rafts are disrupted [6].Another mechanism proposed to play a role in MHC clustering is mediated by tetraspanins, a superfamily of four transmembrane molecules with a key role in the molecular organization of cell SHORT COMMUNICATIONÃ These authors contributed equally to this work. [9] demonstrated a biochemical association between the tetraspanins CD82, CD9 and CD81 with MHC-II, CD86, and the MHC-II peptide editor HLA-DM. Tetraspanin-associated MHC-II was distinguished from non-tetraspanin-associated MHC by the CDw78 mAb. These 'CDw781 microdomains' carried a restricted peptide repertoire and were critically important in T-cell activation, as their disruption led to diminished...
Immunoglobulin A (IgA) secretion by plasma cells in the immune system is critical for protecting the host from environmental and microbial infections. However, the molecular mechanisms underlying the generation of IgA+ plasma cells remain poorly understood. Here, we report that the B cell–expressed tetraspanin CD37 inhibits IgA immune responses in vivo. CD37-deficient (CD37−/−) mice exhibit a 15-fold increased level of IgA in serum and significantly elevated numbers of IgA+ plasma cells in spleen, mucosal-associated lymphoid tissue, as well as bone marrow. Analyses of bone marrow chimeric mice revealed that CD37–deficiency on B cells was directly responsible for the increased IgA production. We identified high local interleukin-6 (IL-6) production in germinal centers of CD37−/− mice after immunization. Notably, neutralizing IL-6 in vivo reversed the increased IgA response in CD37−/− mice. To demonstrate the importance of CD37—which can associate with the pattern-recognition receptor dectin-1—in immunity to infection, CD37−/− mice were exposed to Candida albicans. We report that CD37−/− mice are evidently better protected from infection than wild-type (WT) mice, which was accompanied by increased IL-6 levels and C. albicans–specific IgA antibodies. Importantly, adoptive transfer of CD37−/− serum mediated protection in WT mice and the underlying mechanism involved direct neutralization of fungal cells by IgA. Taken together, tetraspanin protein CD37 inhibits IgA responses and regulates the anti-fungal immune response.
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