Endogenous IFN-γ facilitates Pneumocystis infection and downregulates carbohydrate receptors in CD4+ T cell-depleted mice.

IFN-γ plays a critical role in host defense against intracellular pathogens. IFN-γ is produced in the bronchoalveolar lavage fluid of mice infected with Pneumocystis, but the role of IFN-γ in host defense against Pneumocystis remains controversial. It has been previously reported that although exogenous IFN-γ has beneficial effects on eradication of Pneumocystis, endogenous IFN-γ has a negative impact on innate immunity in immunocompromised hosts. Surprisingly, CD4+ T cell-depleted IFN-γ deficient (GKO) mice exhibit resistance to Pneumocystis. Alveolar macrophages (AM) from GKO mice exhibit higher expression of macrophage mannose receptor (MMR) and Dectin-1. Concomitantly, they exhibited greater ability to phagocytize Pneumocystis, and this activity was suppressed by inhibitors of these receptors. Incubation with IFN-γ resulted in a reduction in both the expression of these receptors on AM and their Pneumocystis-phagocytic activity. These results indicate that endogenous IFN-γ facilitates Pneumocystis to escape from host innate immunity by attenuating the phagocytic activity of AM via downregulation of MMR and Dectin-1.

State-of-the-Art Cancer Immunotherapies.

Cancer immunotherapy is a type of cancer therapy utilizing the immune system to fight against tumors [...].

Genetic deficiencies of both IL-4 receptor alpha chain and IL-10 trigger early onset of severe colitis in mice.

Inflammatory bowel diseases are associated with dysregulated inflammatory immune responses in the gastrointestinal tract. We found that deficiencies of both IL-4 receptor alpha chain (IL-4Rα) and IL-10 in BALB/c mice (IL-4Rα × IL-10 KO mice) highly induced spontaneous rectal prolapse and diarrhea. These mice also exhibited severe colitis in their cecum and colon and marked elevation of serum proinflammatory cytokines including TNFα and IFNγ. These pathologies were transmittable with their cecal contents containing Helicobacter spp. Their mesenteric LN cells produced TNFα and IFNγ in response to soluble H. hepaticus antigens and high titers of H. hepaticus-specific serum IgG were also detected. These results suggested the important function of IL-4Rα signaling in controlling the intestinal inflammation and the susceptibility to intestinal microbes including H. hepaticus. Therefore, these IL-4Rα × IL-10 KO mice potentially provide the significant murine model for clarifying the causes and control of spontaneous colitis and intestinal inflammation.

The Intracellular Domain of Amyloid Precursor Protein is a Potential Therapeutic Target in Alzheimer's Disease.

Amyloid-ß (Aß) is widely believed to cause Alzheimer's disease (AD), as it is the major constituent of the amyloid plaques observed in the brains of people with AD (the so-called amyloid hypothesis). Based on this hypothesis, therapies utilizing immune responses against Aß have been performed and have succeeded in effectively removing amyloid plaques, but have shown no evidence of improvements in survival and/or cognitive function. Thus, it may be necessary to think about this problem from a different viewpoint. γ-Secretase was initially identified as an enzyme that cleaves amyloid precursor protein (APP) and produces Aß. Although the primary function of γ-secretase has not been fully clarified, this enzyme is well known to play a central regulatory role in Notch signaling. After the shedding of the Notch ectodomain by metalloproteases, γ-secretase releases the intracellular domain (ICD) of Notch, which immediately translocates to the nucleus to modify the expression of certain genes. Recently, many type 1 transmembrane proteins have also been reported as substrates for γ-secretase. Interestingly, several of these substrates may share a γ-secretase-regulated signaling mechanism similar to that of Notch. Indeed, we have demonstrated that the ICD of APP (AICD) induces dynamic changes in gene expression and neuron-specific apoptosis, suggesting that APP also has a signaling mechanism that is closely linked with AD. In this review, we first summarize the evidence that γ-secretase-regulated mechanisms similar to Notch signaling may play wide-ranging roles in signaling events involving type 1 transmembrane proteins, including APP. We also focus on the possibility that APP signaling is involved in the onset and progression of AD. Based on these ideas, we hypothesize that APP signaling, especially AICD, may be an attractive therapeutic target in AD.

γ-Secretase-regulated signaling typified by Notch signaling in the immune system.

Notch signaling mediates the fates of numerous cells not only in the nervous system but also in the immune system. Notch signaling contributes to the generation and maintenance of hematopoietic stem cells, lymphocyte development, and several immune responses. The molecular mechanism of Notch signaling is unique: ligands bind to the extracellular domain of Notch and trigger sequential proteolytic cleavages. Finally, γ-secretase releases the intracellular domain (ICD) of Notch (NICD) from the cell membrane, and NICD translocates to the nucleus. In the nucleus, NICD binds to transcription factors and modifies the expression of certain genes. Thus,γ-secretase controls Notch signaling. Recently, many type 1 transmembrane proteins have been reported to be substrates for γ-secretase, and their ICDs are released from the cell membrane to the cytoplasm. It has also been reported that ICDs of several of these substrates also translocate to the nucleus. These phenomena closely resemble that of Notch signaling. Therefore, the common enzyme -secretase controls the proteolysis and turnover of possible signaling molecules, which has led to the hypothesis that mechanisms similar to Notch signaling contribute widely to γ-secretase-regulated signaling pathways. Indeed, we have shown that the ICD of amyloid precursor protein (APP) alters gene expression and induces neuron-specific apoptosis. These observations suggest the existence of APP signaling that is controlled by γ-secretase. It is also likely that γ-secretase-regulated signaling pathways, besides Notch signaling, play an essential role in the immune system. In fact, CD44, which is involved in hematopoiesis and lymphocyte homing, seems to have a γ-secretase-regulated signaling mechanism. In this review, we focus not only on Notch signaling but also on other γ-secretase-regulated signaling pathways in the immune system.

γ-Secretase-regulated mechanisms similar to notch signaling may play a role in signaling events, including APP signaling, which leads to Alzheimer's disease.

Although γ-secretase was first identified as a protease that cleaves amyloid precursor protein (APP) within the transmembrane domain, thus producing Aß peptides that are thought to be pathogenic in Alzheimer's disease (AD), its physiological functions have not been fully elucidated. In the canonical Notch signaling pathway, intramembrane cleavage by γ-secretase serves to release an intracellular domain of Notch that shows activity in the nucleus through binding to transcription factors. Many type 1 transmembrane proteins, including Notch, Delta, and APP, have recently been shown to be substrates for γ-secretase, and their intracellular domains are released from the cell membrane following cleavage by γ-secretase. The common enzyme γ-secretase modulates proteolysis and the turnover of possible signaling molecules, which has led to the attractive hypothesis that mechanisms similar to Notch signaling contribute widely to proteolysis-regulated signaling pathways. APP is also likely to have a signaling mechanism, although the physiological functions of APP have not been elucidated. Indeed, we have shown that the intracellular domain of APP alters gene expression and induces neuron-specific apoptosis. These results suggest that APP signaling responds to the onset of AD. Here, we review the possibility of γ-secretase-regulated signaling, including APP signaling, which leads to AD.

The amyloid precursor protein intracellular domain alters gene expression and induces neuron-specific apoptosis.

Although amyloid precursor protein (APP) plays a central role in Alzheimer's disease, the physiological functions of this protein have yet to be fully elucidated. As previously reported, we established an embryonic carcinoma P19 cell line expressing the intracellular domain of APP (AICD). While neurons were differentiated from these cell lines with retinoic acid treatment, expression of AICD induced neuron-specific apoptosis. As the first step to identify the genes involved in this process, we evaluated AICD-induced changes in gene expression through cell death. The levels of expression of 41,256 transcripts were monitored by DNA microarray analysis. The expression of 277 genes showed up-regulation by more than 10-fold in the presence of AICD. Conversely, the expression of 341 genes showed down-regulation to less than one-tenth of the original level. Reverse transcription-polymerase chain reaction of 17 selected genes showed excellent agreement with the microarray results. These results suggest that AICD induces dynamic changes in gene expression, which may be closely correlated with AICD-induced neuron-specific apoptosis.

γ-Secretase-regulated signaling pathways, such as notch signaling, mediate the differentiation of hematopoietic stem cells, development of the immune system, and peripheral immune responses.

Notch signaling mediates the fates of numerous cells in both invertebrates and vertebrates. In the immune system, Notch signalling contributes to the generation of hematopoietic stem cells (HSCs), the promotion of HSC self-renewal, T lineage commitment, intrathymic T cell development, and peripheral lymphocyte differentiation/activation. The intracellular domain (ICD) of Notch is released from the cell membrane by γ-secretase and translocates to the nucleus to modulate gene expression. Hence, γ-secretase plays a central role in the regulation of Notch signaling. More than five dozen type 1 transmembrane proteins, including amyloid precursor protein, Notch, and Delta, are substrates for γ-secretase and their ICDs are released from the cell membrane. Therefore, it is highly possible that mechanisms similar to Notch signaling may widely contribute to γ-secretase-regulated signaling. Besides Notch, some transmembrane proteins such as CD44 and CSF-1R, which are important for immune responses, have been reported as substrates for γ-secretase. Since the ICDs of these proteins are also released by γ-secretase from the cell membrane and localize to the nucleus, it is thought that these ICDs modulate gene expression. Thus, γ-secretase-regulated signaling, including Notch signaling, may play a wide range of roles in the immune system.

Similar mechanisms regulated by gamma-secretase are involved in both directions of the bi-directional Notch-Delta signaling pathway as well as play a potential role in signaling events involving type 1 transmembrane proteins.

In the canonical Notch signaling pathway, intramembrane cleavage by gamma-secretase serves to release an intracellular domain of Notch that has activity in the nucleus through binding to transcription factors. In addition, we showed that Notch also supplies signals to Delta, a major Notch ligand, to release the intracellular domain of Delta by gamma-secretase from the cell membrane, which then translocates to the nucleus, where it mediates the transcription of specific genes. Therefore, the Notch-Delta signaling pathway is bi-directional and similar mechanisms regulated by gamma-secretase are involved in both directions. Recently, it was demonstrated that many type 1 transmembrane proteins including Notch, Delta and amyloid precursor protein (APP) are substrates for gamma-secretase and release intracellular domains of these proteins from cell membranes. These observations that the common enzyme, gamma-secretase, modulates proteolysis and the turnover of possible signaling molecules have led to the attractive hypothesis that mechanisms similar to the Notch-Delta signaling pathway may widely contribute to gamma-secretase-regulated signaling pathways, including APP signaling which leads to Alzheimer's disease. Here, we review the molecular mechanisms of the Notch-Delta signaling pathway in a bi-directional manner, and discuss the recent progress in understanding the biology of gamma-secretase-regulated signaling with respect to neurodegeneration.

The intracellular domain of amyloid precursor protein induces neuron-specific apoptosis.

Although amyloid precursor protein (APP) has central roles in Alzheimer's disease, the physiological functions of this protein have yet to be fully elucidated. APP homologues show significant sequence conservation in the intracellular domain through evolution, which may reflect the functional importance of the intracellular domain of APP (AICD). To examine this possibility, we established embryonic carcinoma P19 cell lines overexpressing AICD. Although neurons could be differentiated from these cell lines with retinoic acid treatment, overexpression of AICD gave rise to neuron-specific cell death. Furthermore, DNA fragmentation was detected and TUNEL-positive cells were also Tuj1-positive neurons. Taken together, we concluded that AICD can induce neuron-specific apoptosis.

Despite increased CD4+Foxp3+ cells within the infection site, BALB/c IL-4 receptor-deficient mice reveal CD4+Foxp3-negative T cells as a source of IL-10 in Leishmania major susceptibility.

BALB/c IL-4Ralpha(-/-) mice, despite the absence of IL-4/IL-13 signaling and potent Th2 responses, remain highly susceptible to Leishmania major substain LV39 due exclusively to residual levels of IL-10. To address the contribution of CD4(+)CD25(+) T regulatory (Treg) cells to IL-10-mediated susceptibility, we depleted CD4(+)CD25(+) cells in vivo and reconstituted IL-4Ralpha x RAG2 recipients with purified CD4(+)CD25(-) T cells. Although anti-CD25 mAb treatment significantly decreased parasite numbers in IL-4Ralpha(-/-) mice, treatment with anti-IL-10R mAb virtually eliminated L. major parasites in both footpad and dermal infection sites. In addition, IL-4Ralpha x RAG2 mice reconstituted with CD4(+) cells depleted of CD25(+) Treg cells remained highly susceptible to infection. Analysis of L. major-infected BALB/c and IL-4Ralpha(-/-) inflammatory sites revealed that the majority of IL-10 was secreted by the CD4(+)Foxp3(-) population, with a fraction of IL-10 coming from CD4(+)Foxp3(+) Treg cells. All T cell IFN-gamma production was also derived from the CD4(+)Foxp3(-) population. Nevertheless, the IL-4Ralpha(-/-)-infected ear dermis, but not draining lymph nodes, consistently displayed 1.5- to 2-fold greater percentages of CD4(+)CD25(+) and CD4(+)Foxp3(+) Treg cells compared with the BALB/c-infected dermis. Thus, CD4(+)Foxp3(-) T cells are a major source of IL-10 that disrupts IFN-gamma activity in L. major-susceptible BALB/c mice. However, the increase in CD4(+)Foxp3(+) T cells within the IL-4Ralpha(-/-) dermis implies a possible IL-10-independent role for Treg cells within the infection site, and may indicate a novel immune escape mechanism used by L. major parasites in the absence of IL-4/IL-13 signaling.

The Delta intracellular domain mediates TGF-beta/Activin signaling through binding to Smads and has an important bi-directional function in the Notch-Delta signaling pathway.

Delta is a major transmembrane ligand for Notch receptor that mediates numerous cell fate decisions. The Notch signaling pathway has long been thought to be mono-directional, because ligands for Notch were generally believed to be unable to transmit signals into the cells expressing them. However, we showed here that Notch also supplies signals to neighboring mouse neural stem cells (NSCs). To investigate the Notch-Delta signaling pathway in a bi-directional manner, we analyzed functional roles of the intracellular domain of mouse Delta like protein 1 (Dll1IC). In developing mouse NSCs, Dll1IC, which is released from cell membrane by proteolysis, is present in the nucleus. Furthermore, we screened for transcription factors that bind to Dll1IC and demonstrated that Dll1IC binds specifically to transcription factors involved in TGF-beta/Activin signaling--Smad2, Smad3 and Smad4--and enhances Smad-dependent transcription. In addition, the results of the present study indicated that over-expression of Dll1IC in embryonic carcinoma P19 cells induced neurons, and this induction was blocked by SB431542, which is a specific inhibitor of TGF-beta/Activin signaling. These observations strongly suggested that Dll1IC mediates TGF-beta/Activin signaling through binding to Smads and plays an important role for bi-directional Notch-Delta signaling pathway.

The relative contribution of IL-4 receptor signaling and IL-10 to susceptibility to Leishmania major.

The roles of IL-10 and IL-4 receptor signaling were evaluated in a murine model of Leishmania major infection. In previous studies the L. major substrain LV39 caused progressive, nonhealing lesions in BALB/c mice deficient for IL-4R alpha-chain (IL-4R alpha), while substrain IR173 was highly controlled. To explore whether IL-10 is responsible for inducing susceptibility to LV39, wild-type and IL-4R alpha(-/-) mice were treated with anti-IL-10R mAb, and in a genetic approach, the IL-4R alpha(-/-) mice were crossed with BALB/c IL-10(-/-) mice. In contrast to the lack of resistance conferred by IL-4R alpha gene deletion, partial resistance to LV39 was conferred by IL-10 gene deletion or treatment of BALB/c mice with anti-IL-10R mAb. Lesion sizes and LV39 parasite numbers were further and dramatically reduced in both anti-IL-10R-treated IL-4R alpha(-/-) mice and IL-4R alpha x IL-10 double knockouts. Anti-IL-10R mAb treatment further suppressed parasite growth in IL-4R alpha(-/-) mice infected with L. major IR173. Production of IFN-gamma was only increased relative to wild-type or littermate controls in IL-4R alpha(-/-) mice with complementary defects in IL-10. Comparisons of IFN-gamma-treated infected macrophages in vitro indicated that LV39 required 25- to 500-fold greater concentrations of IFN-gamma than IR173-infected macrophages to achieve a similar efficiency of parasite killing. These studies suggest that regardless of parasite substrain, IL-10 is as important as IL-4/IL-13 in promoting susceptibility to L. major and even more so for those substrains that are relatively resistant to IFN-gamma mediated killing.

Significant role of Fas ligand-binding but defective Fas receptor (CD95) in lymph node hyperplasia composed of abnormal double-negative T cells.

The functional differences between two mutations of the Fas (CD95) locus, Faslpr (lpr) and Faslprcg (lprcg), were investigated using bone marrow (BM) transplantation on the C3H mouse background. Both lpr/lpr and lprcg/lprcg BM transferred caused lymph node (LN) hyperplasia in lpr/+ and lprcg/+ recipients, although it was clearly smaller than that in lpr/lpr and lprcg/lprcg recipients of lpr/lpr and lprcg/lprcg BM. In addition, both BM induced significantly larger LN hyperplasia in lprcg/+ than lpr/+ recipients. Appearance of CD4- CD8-[double negative (DN)] T cells in the periphery is the most consistent phenotype of Fas mutations. Importantly, the proportion of DN T cells was higher in larger LN hyperplasia in the order of lpr/+, lprcg/+ and lpr/lpr or lprcg/lprcg recipients. On the other hand, both lpr/lpr and lprcg/lprcg BM transferred into wild-type (+/+) mice caused marked LN atrophy. The former, but not the latter, induced wasting syndrome. Faslg1d (gld)-homozygous lpr/lpr BM transferred into +/+ mice elicited LN hyperplasia of the same extent as that in lpr/lpr mice transferred with lpr/lpr BM, but not wasting syndrome. Taken together with the fact that DN T cells massively express Fas ligand (FasL), this study implied that FasL overexpressed on DN cells may be involved in the accumulation of DN T cells in LN, LN atrophy and wasting syndrome, and that lprcg Fas, which can bind to Fas ligand but not transduce apoptosis signal into cells, may modulate these pathological conditions by interfering with the binding of FasL to Fas.

Human bronchial epithelium expresses interleukin-9 receptors and releases neutrophil chemotactic factor.

Growing evidence obtained from human genomic analysis and antigen-challenged transgenic mice suggests that interleukin-9 (IL-9) is a candidate factor in immunoglobulin E (IgE) production and thus is thought to be associated with bronchial inflammation and bronchial hyperresponsiveness (BHR). To evaluate the expression of the IL-9 receptor and its effect on the IL-9 human bronchial cell line BEAS-2B cells, reverse transcriptase-polymerase chain reaction (RT-PCR), immunohistochemical investigation, and chemotaxis assay were performed. The components of the IL-9 receptor, consisting of IL-9 receptor alpha (CD129) and IL-2 receptory ((1)132), were expressed on BEAS-2B cells as determined by RT-PCR and flow cytometry. BEAS-2B cells exposed to IL-9 released neutrophil chemotactic activity (NCA) in a time- and dose-dependent manner, and the presence of granulocyte colony-stimulating factor (G-CSF) was also detected. This factor is primarily involved in NCA for the measurement of cytokines and in the inhibition assay of neutrophil chemotaxis. These findings suggest that bronchial epithelial cells may express IL-9 receptors, and that IL-9 may induce airway inflammation through the release of G-CSF from bronchial epithelial cells.

The different process of class switching and somatic hypermutation; a novel analysis by CD27(-) naive B cells.

The relationship between class switch recombination (CSR) and somatic hypermutation has been unclear. By using human CD27(-) naive B cells, we investigated the somatic hypermutation and producibility of immunoglobulins (Igs) that occur after CSR. Although neither adult CD27(-) nor cord blood B cells, which showed the unmutated Ig V-region genes, produced IgG, IgM, or IgA in response to conventional stimuli, they produced IgG and IgM but not IgA in the presence of Staphylococcus aureus Cowan strain (SAC) + interleukin-2 (IL-2) + IL-10 + anti-CD40 mAb + CD32 transfectants (CD40/CD32T). The naive B cells also produced IgE when combined with IL-4 + CD40/CD32T. In parallel with IgG production, the expression of mature gamma1 and gamma 2 transcripts was induced from naive B cells by the stimuli. The CD27 expression on human naive B cells was induced remarkably by CD40 signaling or B-cell receptor engagement, but somatic hypermutation could not be induced. The proliferation and differentiation into plasma cells were induced from naive B cells, whereas most of the plasma cells displayed very low levels of mutations in Ig V-region genes. CD27(-) naive B cells expressed activation-induced cytidine deaminase messenger RNA by the stimuli later than CD27(+) memory B cells. Our results demonstrate that CSR, but not noticeable somatic hypermutation, can be induced from CD27(-) naive B cells upon B-cell receptor engagement and CD40 signaling in cooperation with cytokines, suggesting that CSR and somatic hypermutation processes can occur independently, and the antibodies produced in this in vitro system are low-affinity antibodies.