Idit Shachar

Macrophage Migration Inhibitory Factor Induces B Cell Survival by Activation of a CD74-CD44 Receptor Complex

Macrophage migration inhibitory factor (MIF) is an upstream activator of innate immunity that regulates subsequent adaptive responses. It was previously shown that in macrophages, MIF binds to a complex of CD74 and CD44, resulting in initiation of a signaling pathway. In the current study, we investigated the role of MIF in B cell survival. We show that in B lymphocytes, MIF initiates a signaling cascade that involves Syk and Akt, leading to NF-κB activation, proliferation, and survival in a CD74- and CD44-dependent manner. Thus, MIF regulates the adaptive immune response by maintaining the mature B cell population.

IL-8 secreted in a macrophage migration-inhibitory factor- and CD74-dependent manner regulates B cell chronic lymphocytic leukemia survival

Chronic lymphocytic leukemia (CLL) is a malignant disease of small mature lymphocytes. Previous studies have shown that CLL B lymphocytes express relatively large amounts of CD74 mRNA relative to normal B cells. In the present study, we analyzed the molecular mechanism regulated by CD74 in B-CLL cells. The results presented here show that activation of cell-surface CD74, expressed at high levels from an early stage of the disease by its natural ligand, macrophage migration-inhibition factor (MIF), initiates a signaling cascade that contributes to tumor progression. This pathway induces NF-κB activation, resulting in the secretion of IL-8 which, in turn, promotes cell survival. Inhibition of this pathway leads to decreased cell survival. These findings could form the basis of unique therapeutic strategies aimed at blocking the CD74-induced, IL-8- dependent survival pathway.

Perivascular clusters of dendritic cells provide critical survival signals to B cells in bone marrow niches

Beyond its established function in hematopoiesis, the bone marrow hosts mature lymphocytes and acts as a secondary lymphoid organ in the initiation of T cell and B cell responses. Here we report the characterization of bone marrow–resident dendritic cells (bmDCs). Multiphoton imaging showed that bmDCs were organized into perivascular clusters that enveloped blood vessels and were seeded with mature B lymphocytes and T lymphocytes. Conditional ablation of bmDCs in these bone marrow immune niches led to the specific loss of mature B cells, a phenotype that could be reversed by overexpression of the antiapoptotic factor Bcl-2 in B cells. The presence of bmDCs promoted the survival of recirculating B cells in the bone marrow through the production of macrophage migration–inhibitory factor. Thus, bmDCs are critical for the maintenance of recirculating B cells in the bone marrow.

Deficiency of caspase recruitment domain family, member 11 (CARD11), causes profound combined immunodeficiency in human subjects

BACKGROUND Profound combined immunodeficiency can present with normal numbers of T and B cells, and therefore the functional defect of the cellular and humoral immune response is often not recognized until the first severe clinical manifestation. Here we report a patient of consanguineous descent presenting at 13 months of age with hypogammaglobulinemia, Pneumocystis jirovecii pneumonia, and a suggestive family history. OBJECTIVE We sought to identify the genetic alteration in a patient with combined immunodeficiency and characterize human caspase recruitment domain family, member 11 (CARD11), deficiency. METHODS Molecular, immunologic, and functional assays were performed. RESULTS The immunologic characterization revealed only subtle changes in the T-cell and natural killer cell compartment, whereas B-cell differentiation, although normal in number, was distinctively blocked at the transitional stage. Genetic evaluation revealed a homozygous deletion of exon 21 in CARD11 as the underlying defect. This deletion abrogated protein expression and activation of the canonical nuclear factor κB (NF-κB) pathway in lymphocytes after antigen receptor or phorbol 12-myristate 13-acetate stimulation, whereas CD40 signaling in B cells was preserved. The abrogated activation of the canonical NF-κB pathway was associated with severely impaired upregulation of inducible T-cell costimulator, OX40, cytokine production, proliferation of T cells, and B cell-activating factor receptor expression on B cells. CONCLUSION Thus in patients with CARD11 deficiency, the combination of impaired activation and especially upregulation of inducible T-cell costimulator on T cells, together with severely disturbed peripheral B-cell differentiation, apparently leads to a defective T-cell/B-cell cooperation and probably germinal center formation and clinically results in severe immunodeficiency. This report discloses the crucial and nonredundant role of canonical NF-κB activation and specifically CARD11 in the antigen-specific immune response in human subjects.

The anti‐inflammatory effects of 1,25‐dihydroxyvitamin D3 on Th2 cells in vivo are due in part to the control of integrin‐mediated T lymphocyte homing

The fat soluble vitamin D3 metabolite 1,25‐dihydroxyvitamin D3 [1,25(OH)2D3], and its nuclear receptor play an important role in regulating immune responses. While 1,25(OH)2D3 is known to inhibit transcription of cytokine genes that are required for Th1 differentiation or are products of differentiated Th1 cells, its role in regulating differentiation of Th2 cells is less clear. In this study, we show that 1,25(OH)2D3 has anti‐inflammatory effects in an in vivo Th2‐dependent asthma model. In addition, we demonstrate that 1,25(OH)2D3 down‐regulates the cytoskeleton rearrangement required for promoting integrin‐mediated adhesion of naive and effector CD4+ T cells. Finally, 1,25(OH)2D3 inhibits chemokine‐induced migration of naive cells and their homing to the lymph nodes. Thus, in addition to its regulation of cytokine transcription, 1,25(OH)2D3 regulates migration of cells and thus controls the skewing of various Th subsets in the secondary lymphoid organs and inhibits Th function at sites of inflammation.

IFN-γ Acts on T Cells to Induce NK Cell Mobilization and Accumulation in Target Organs

The mechanism(s) that regulates NK cell mobilization and the significance of this process to NK cell activity are unknown. After Con A-induced hepatitis, NK cells are mobilized from the spleen and bone marrow into the periphery in an IFN-γ-dependent fashion. Intraperitoneal administration of IFN-γ stimulates the mobilization of NK cells into the circulation, but not their cell death or proliferation. Increased number of circulating NK cells was coupled with their accumulation in the peritoneum, liver, and tumor-bearing lung tissue. Furthermore, increased number of NK cells in the lung reduced metastasis of Lewis lung carcinoma cells (3LL cell line) resulting in significantly extended NK-dependent survival. Mobilization of NK cells was specific and required the presence of T cells. Moreover, mobilization and migration of spleen NK cells in response to IFN-γ treatment is dependent on the chemokine receptor CXCR3. Mechanistic insights regarding the role of IFN-γ in the regulation of NK cell mobilization and their accumulation at sites of tumor metastasis may lead to the development of novel immunotherapy for cancer.

Invariant chain, a chain of command

Abstract Invariant chain (Ii) is a type II integral membrane protein, which acts as a chaperone for MHC class II protein expression and facilitates antigen presentation. Recently, an additional role for Ii in the differentiation of immature to mature B cells has been described. These studies showed that Ii acts as a signaling molecule; its cytosolic domain induces B-cell maturation by activation of transcription mediated by the p65 member of the NF-κB family, a process that requires the B-cell-enriched coactivator, TAF II 105. NF-κB activation is mediated by the cytosolic region of Ii, which is liberated from the membrane. The process of intramembrane cleavage followed by nuclear translocation and transcriptional activation is reminiscent of regulated intramembrane cleavage (RIP). In this Review we suggest that the behavior of Ii shows remarkable similarities to the function of proteins processed by RIP and propose that the roles of Ii as a chaperone and as a signaling molecule are intertwined.

Reconstitution of invariant chain function in transgenic mice in vivo by individual p31 and p41 isoforms

MHC class II molecules associate with invariant chain (li) during biosynthesis. If facilitates folding of class II molecules, interferes with their association with peptides, and is involved in their transport. The murine Ii gene encodes two chains, p31 and p41. The role of these isoforms has been studied in vitro only in inappropriate antigen-presenting cells. To circumvent this problem, we have generated invariant chain-deficient mice (delta Ii), which express exclusively the p31 and p41 isoforms. Low level expression of p31 or p41 is not sufficient for rescuing high levels of cell surface class II expression. However, low levels of the typical compact dimer conformation indicative of tight peptide binding are observed. Thus, both isoforms participate in class II folding and assembly. Furthermore, p31 and p41 retrieve the CD4+ T cell population, which is reduced in the (delta Ii) mice. Moreover, the immune response to protein antigen is restored by both isoforms.

Invariant Chain-Induced B Cell Differentiation Requires Intramembrane Proteolytic Release of the Cytosolic Domain

Immature B cells differentiate in the spleen into mature B cells, a process that is essential for their participation in the immune response. Previously, we showed that the MHC class II chaperone, invariant chain (Ii), controls this differentiation to the mature stage. Ii cytosolic domain-induced B cell maturation involves activation of transcription mediated by the NF-kappaB p65/RelA homodimer and requires the B cell enriched coactivator, TAF(II)105. In this study we show that the cytosolic region of Ii is cleaved within the plane of the membrane to generate a cytosolic fragment, which is essential for NF-kappaB activation and B cell differentiation. Our results suggest that Ii functions as a membrane-bound inactive inducer of NF-kappaB transcription that is activated by intramembrane proteolytic cleavage.

Invariant chain induces B cell maturation in a process that is independent of its chaperonic activity

Early stages of B cell development take place in the bone marrow, resulting in formation of immature B cells, which migrate to the spleen for their final differentiation into mature cells. This final maturation step is essential for B cells to become responsive to antigens and to participate in the immune response. Previously, we showed that the MHC class II chaperone, invariant chain (Ii), controls the differentiation of B cells from the immature to the mature stage. In this study, by generating transgenic mice expressing truncated Ii lacking its luminal domain, we could dissect the chaperonin activity of Ii from its role in B cell maturation. We demonstrate in vivo that Ii N-terminal domain is directly involved in the maturation of B cells and is sufficient to promote B cell differentiation.