SLy1 regulates T‐cell proliferation during Listeria monocytogenes infection in a Foxo1‐dependent manner

Infection of mice with Listeria monocytogenes results in a strong T‐cell response that is critical for an efficient defense. Here, we demonstrate that the adapter protein SLy1 (SH3‐domain protein expressed in Lymphocytes 1) is essential for the generation of a fully functional T‐cell response. The lack of SLy1 leads to reduced survival rates of infected mice. The increased susceptibility of SLy1 knock‐out (KO) mice was caused by reduced proliferation of differentiated T cells. Ex vivo analyses of isolated SLy1 KO T cells displayed a dysregulation of Forkhead box protein O1 shuttling after TCR signaling, which resulted in an increased expression of cell cycle inhibiting genes, and therefore, reduced expansion of the T‐cell population. Forkhead box protein O1 shuttles to the cytoplasm after phosphorylation in a protein complex including 14‐3‐3 proteins. Interestingly, we observed a similar regulation for the adapter protein SLy1, where TCR stimulation results in SLy1 phosphorylation and SLy1 export to the cytoplasm. Moreover, immunoprecipitation analyses revealed a binding of SLy1 to 14‐3‐3 proteins. Altogether, this study describes SLy1 as an immunoregulatory protein, which is involved in the generation of adaptive immune responses during L. monocytogenes infection, and provides a model of how SLy1 regulates T‐cell proliferation.     

Swiprosin‐1/EFhd2 limits germinal center responses and humoral type 2 immunity

Activated B cells are selected for in germinal centers by regulation of their apoptosis. The Ca²⁺‐binding cytoskeletal adaptor protein Swiprosin‐1/EFhd2 (EFhd2) can promote apoptosis in activated B cells. We therefore hypothesized that EFhd2 might limit humoral immunity by repressing both the germinal center reaction and the expected enhancement of immune responses in the absence of EFhd2. Here, we established EFhd2^?/? mice on a C57BL/6 background, which revealed normal B‐ and T‐cell development, basal Ab levels, and T‐cell independent type 1, and T‐cell independent type 2 responses. However, T cell‐dependent immunization with sheep red blood cells and infection with the helminth Nippostrongylus brasiliensis (N.b) increased production of antibodies of multiple isotypes, as well as germinal center formation in EFhd2^?/? mice. In addition, serum IgE levels and numbers of IgE⁺ plasma cells were strongly increased in EFhd2^?/? mice, both after primary as well as after secondary N.b infection. Finally, mixed bone marrow chimeras unraveled an EFhd2‐dependent B cell‐intrinsic contribution to increased IgE plasma cell numbers in N.b‐infected mice. Hence, we established a role for EFhd2 as a negative regulator of germinal center‐dependent humoral type 2 immunity, with implications for the generation of IgE.     

Expression of activation‐induced cytidine deaminase enhances the clearance of pneumococcal pneumonia: evidence of a subpopulation of protective anti‐pneumococcal B1a cells

We describe a protective early acquired immune response to pneumococcal pneumonia that is mediated by a subset of B1a cells. Mice deficient in B1 cells (xid), or activation‐induced cytidine deaminase (AID^?/?), or invariant natural killer T (iNKT) cells (Jα18^?/?), or interleukin‐13 (IL‐13^?/?) had impaired early clearance of pneumococci in the lung, compared with wild‐type mice. In contrast, AID^?/? mice adoptively transferred with AID^+/+ B1a cells, significantly cleared bacteria from the lungs as early as 3 days post infection. We show that this early bacterial clearance corresponds to an allergic contact sensitivity‐like cutaneous response, probably due to a subpopulation of initiating B1a cells. In the pneumonia model, these B1a cells were found to secrete higher affinity antigen‐specific IgM. In addition, as in contact sensitivity, iNKT cells were required for the anti‐pneumococcal B1a cell initiating response, probably through early production of IL‐13, given that IL‐13^?/? mice also failed to clear infection. Our study is the first to demonstrate the importance of AID in generating an appropriate B1a cell response to pathogenic bacteria. Given the antibody affinity and pneumonia resistance data, natural IgM produced by conventional B1a cells are not responsible for pneumonia clearance compared with the AID‐dependent subset.     

Signaling pathways involved in the T‐cell‐mediated immunity against Epstein‐Barr virus: Lessons from genetic diseases

Primary immunodeficiencies (PIDs) provide researchers with unique models to understand in vivo immune responses in general and immunity to infections in particular. In humans, impaired immune control of Epstein‐Barr virus (EBV) infection is associated with the occurrence of several different immunopathologic conditions; these include non‐malignant and malignant B‐cell lymphoproliferative disorders, hemophagocytic lymphohistiocytosis (HLH), a severe inflammatory condition, and a chronic acute EBV infection of T cells. Studies of PIDs associated with a predisposition to develop severe, chronic EBV infections have led to the identification of key components of immunity to EBV – notably the central role of T‐cell expansion and its regulation in the pathophysiology of EBV‐associated diseases. On one hand, the defective expansion of EBV‐specific CD8 T cells results from mutations in genes involved in T‐cell activation (such as RASGRP1, MAGT1, and ITK), DNA metabolism (CTPS1) or co‐stimulatory pathways (CD70, CD27, and TNFSFR9 (also known as CD137/4‐1BB)) leads to impaired elimination of proliferating EBV‐infected B cells and the occurrence of lymphoma. On the other hand, protracted T‐cell expansion and activation after the defective killing of EBV‐infected B cells is caused by genetic defects in the components of the lytic granule exocytosis pathway or in the small adapter protein SH2D1A (also known as SAP), a key activator of T‐ and NK cell‐cytotoxicity. In this setting, the persistence of EBV‐infected cells results in HLH, a condition characterized by unleashed T‐cell and macrophage activation. Moreover, genetic defects causing selective vulnerability to EBV infection have highlighted the role of co‐receptor molecules (CD27, CD137, and SLAM‐R) selectively involved in immune responses against infected B cells via specific T‐B cell interactions.     

IL‐1‐dependent,IL‐1R1‐independent resistance to gastrointestinal nematodes

IL‐1 null mice are unable to expel the intestinal nematode Trichuris muris; whereas WT littermates exhibit sterile immunity. Intriguingly the essential signalling components IL‐1R1 and IL‐1R accessory protein (AcP) are dispensable for expulsion of this parasite. IL‐1 is thus critical for CD4⁺ Th2‐mediated immunity to T. muris; however, this action is independent of the established IL‐1 signalling receptor. We also present data demonstrating that both IL‐1α and IL‐1β induce measurable effects on T. muris primed cells isolated from IL‐1R1 or IL‐1R AcP null mice. MLN cells from these mice restimulated with parasite antigen proliferated at a greater rate and produced more cytokines in response to exogenous IL‐1. This ability to respond to IL‐1 was restricted to these parasite‐primed cells and importantly was not evident in cells from naïve gene null mice. These in vitro data are consistent with the observed ability of mice with compromised IL‐1 signalling to expel the parasite, bolstering the premise that an alternative IL‐1 signalling mechanism is accessible in the context of an intestinal helminth‐driven Th2 immune response.     

IL‐10 production in murine IgM+CD138hi cells is driven by Blimp‐1 and downregulated in class‐switched cells

In contrast to antibody‐induced inflammatory responses, some B‐cell subpopulations suppress inflammation through the production of interleukin (IL)‐10. However, the mechanisms underlying Il10 gene expression during B‐cell development is elusive. Here, we identify IgM⁺B220^loCD138^hi cells responsible for marked IL‐10 production in the bone marrow and spleen of mice. These murine IL‐10‐producing cells predominantly secrete IgM and have unique characteristics of long‐lived plasma cells in spite of high expression of surface IgM. We found that IL‐10 production is strongly correlated with the expression level of Prdm1 (encoding the Blimp‐1 protein), an essential regulator of plasma cell development. Furthermore, overexpression of Prdm1 induces Il10 expression in naïve B cells. Immunoglobulin class‐switching recombination events resulted in the downregulation of both Il10 and Prdm1 expression in differentiating B cells. Thus, the prolonged elevation of Blimp‐1 expression during the formation of IgM⁺CD138^hi cells without class‐switching elicits IL‐10 production. Adoptive transfer of Il10‐deficient B cells into B‐cell‐deficient mice demonstrated that IgM⁺CD138^hi cell‐derived IL‐10 supports the survival of class‐switched plasma cells and their antibody production in response to antigen challenge. These findings reveal an important role for IL‐10 secretion by IgM⁺CD138^hi cells in the complete and efficient humoral response.     

B‐1‐cell subpopulations contribute differently to gut immunity

In mice, B‐1 (B1a/B1b) cells are mainly located in the peritoneal cavity. B‐1 cells are well known for their role in the early stages of Ab‐mediated immune responses against pathogenic invasion as well as for the production of natural IgM antibodies. Although such B cells have been claimed to give rise to intestinal plasma cells producing IgA, a clear role of B‐1 cells in IgA production in the gut‐associated tissues is still not defined. Here, we employed the transgenic L2 mouse model characterized by the lack of B‐2 cells and presence of B‐1 cells as major B‐cell subpopulation. The oligoclonality of the Ab repertoire in this mouse allowed us to take typical B1a cell VH sequences as indicators of the presence of IgM‐producing B‐1a cells in Peyer's patches as well as in lamina propria. However, amongst the IgAVH sequences recovered from the same tissues, none of the sequences showed B1a‐cell specificity. Interestingly, all IgAVH sequences derived from the lamina propria of L2 mice displayed extensive numbers of nucleotide exchanges, indicating somatic hypermutation, and affinity maturation. This suggests that the contribution of natural unmutated IgA by B‐1a cells to intestinal immunity is negligible.     

Reduced notch activity is associated with an impaired marginal zone B cell development and function in Sly1 mutant mice

MZ B cells represent a distinct lineage of naive B lymphocytes, apart from FO B cells and peritoneal B1 cells, and mediate humoral immune responses against blood-borne type 2 T-independent antigens. Regulation of MZ B cell development involves the Notch receptor signaling, the intensity of B cell receptor signals, and cell compartmentalization by adhesion and chemokine receptors. Our previous work showed that gene-targeted mice expressing a truncated form of the putative signaling adapter protein SLy1 exhibit reduced numbers of a splenic B cell population enriched in MZ B cells. Here, we demonstrate that Sly1(d/d) mice exhibit a partial, but selective, block in the transition from pre-MZ to mature MZ B cells. Development of both T1 and T2 precursor subsets and FO B cells was normal in Sly1(d/d) mice. Consistent with the loss of MZ B cells, the production of antigen-specific IgM antibodies following immunization with pneumococcal polysaccharides was severely impaired in Sly1(d/d) mice. Importantly, expression of the Notch signaling mediator RBP-J and the Notch target genes Hes-1 and Hes-5 was markedly reduced in MZ but not FO B cells of Sly1(d/d) mice. In contrast, B cell receptor signaling, expression and function of LFA-1 and alpha4-integrins, and expression of chemokine receptors appeared intact in Sly1(d/d) cells. Collectively, these results provide strong evidence that SLy1 is important for the generation and function of MZ B cells and suggest a novel link between SLy1 and the activity of the Notch pathway in the development of MZ B cells.     

NF‐κB2/p100 deficiency impairs immune responses to T‐cell‐independent type 2 antigens

Formation of the splenic marginal zone (MZ) depends on the alternative NF‐κB signaling pathway. Recently, we reported that unrestricted activation of this pathway in NF‐κB2/p100‐deficient (p100^?/?) knock‐in mice alters the phenotype of MZ stroma and B cells. Here, we show that lack of the p100 inhibitor resulted in an expansion of both MZ B and peritoneal B‐1 cells. However, these cells failed to generate proliferating blasts in response to T‐cell‐independent type 2 (TI‐2) Ags, correlating with dampened IgM and absent IgG3 responses. This phenotype was in part due to increased activity of the NF‐κB subunit RelB. Moreover, p100^?/?→B6 BM chimeras were more susceptible to infection by encapsulated Streptococcus pneumoniae bacteria, pathogens that induce TI‐2 responses. In contrast to the TI‐2 defect, p100 deficiency did not impair immune responses to the TI‐1 Ag LPS and p100^?/? MZ B cells showed normal Ag transportation into B‐cell follicles. Furthermore, p100^?/? MZ B and B‐1 cells failed to respond to TI‐2 Ags in the presence of WT accessory cells. Thus, NF‐κB2/p100 deficiency caused a predominant B‐cell‐intrinsic TI‐2 defect that could largely be attributed to impaired proliferation of plasmablasts. Importantly, p100 was also necessary for efficient defense against clinically relevant TI‐2 pathogens.     

Human α1‐antitrypsin modifies B‐lymphocyte responses during allograft transplantation

B‐lymphocyte activities are associated with allograft rejection. Interleukin‐10 (IL‐10) ‐expressing B cells, however, exhibit regulatory attributes. Human α1‐antitrypsin (hAAT), a clinically available anti‐inflammatory circulating glycoprotein that rises during acute‐phase responses, promotes semi‐mature dendritic cells and regulatory T (Treg) cells during alloimmune responses. Whether B lymphocytes are also targets of hAAT activity has yet to be determined. Here, we examine whether hAAT modulates B‐cell responses. In culture, hAAT reduced the lipopolysaccharide‐stimulated Ki‐67⁺ B‐cell population, IgM release and surface CD40 levels, but elevated IL‐10‐producing cells 1.5‐fold. In CD40 ligand‐stimulated cultures, hAAT promoted a similar trend; reduction in the Ki‐67⁺ B‐cell population and in surface expression of CD86, CD80 and MHCII. hAAT increased interferon‐γ‐stimulated macrophage B‐cell activating factor (BAFF) secretion, and reduced BAFF‐receptor levels. Draining lymph nodes of transgenic mice that express circulating hAAT (C57BL/6 background) and that received skin allografts exhibited reduced B‐lymphocyte activation compared with wild‐type recipients. BSA‐vaccinated hAAT transgenic mice exhibited 2.9‐fold lower BSA‐specific IgG levels, but 2.3‐fold greater IgM levels, compared with wild‐type mice. Circulating Treg cells were 1.3‐fold greater in transgenic hAAT mice, but lower in B‐cell knockout (BKO) and chimeric hAAT–BKO mice, compared with wild‐type mice. In conclusion, B cells are cellular targets of hAAT. hAAT‐induced Treg cell expansion appears to be B‐cell‐dependent. These changes support the tolerogenic properties of hAAT during immune responses, and suggest that hAAT may be beneficial in pathologies that involve excessive B‐cell responses.     

Lack of transglutaminase 2 diminished T‐cell responses in mice

Transglutaminase 2 (TG2) has been reported to play a role in dendritic cell activation and B‐cell differentiation after immunization. Its presence and role in T cells, however, has not been explored. In the present study, we determined the expression of TG2 on mouse T cells, and evaluated its role by comparing the behaviours of wild‐type and TG2^?/? T cells after activation. In our results, naive T cells minimally expressed TG2, expression of which was increased after activation. T‐cell proliferation, expression of activation markers such as CD69 and CD25, and secretions of interleukin‐2 and interferon‐γ were suppressed in the absence of TG2, presumably due, in part, to diminished nuclear factor‐κB activation. These effects on T cells seemed to be reflected in the in vivo immune response, the contact hypersensitivity reaction elicited by 2,4‐dinitro‐1‐fluorobenzene, with lowered peak responses in the TG2^?/? mice. When splenic T cells from mice immunized with tumour lysate‐loaded wild‐type dendritic cells were re‐challenged ex vivo with the same antigen, the profile of surface markers including CD44, CD62L, and CD127 strongly indicated lesser generation of memory CD8⁺ T cells in TG2^?/? mice. In the TG2^?/? CD8⁺ T cells, moreover, Eomes expression was markedly decreased. These results indicate possible roles of TG2 in CD8⁺ T‐cell activation and CD8⁺ memory T‐cell generation.     

Triggering receptor expressed on myeloid cells‐1 (TREM‐1) improves host defence in pneumococcal pneumonia

Streptococcus (S.) pneumoniae is a common Gram‐positive pathogen in community‐acquired pneumonia and sepsis. Triggering receptor expressed on myeloid cells‐1 (TREM‐1) is a receptor on phagocytes known to amplify inflammatory responses. Previous studies showed that TREM‐1 inhibition protects against lethality during experimental Gram‐negative sepsis. We here aimed to investigate the role of TREM‐1 in an experimental model of pneumococcal pneumonia, using TREM‐1/3‐deficient (Trem‐1/3^–/–) and wild‐type (Wt) mice. Additionally ex vivo responsiveness of Trem‐1/3^–/– neutrophils and macrophages was examined. S. pneumoniae infection resulted in a rapid recruitment of TREM‐1‐positive neutrophils into the bronchoalveolar space, while high constitutive TREM‐1 expression on alveolar macrophages remained unchanged. TREM‐1/3 deficiency led to increased lethality, accompanied by enhanced growth of S. pneumoniae at the primary site of infection and increased dissemination to distant organs. Within the first 3–6 h of infection, Trem‐1/3^–/– mice demonstrated a strongly impaired innate immune response in the airways, as reflected by reduced local release of cytokines and chemokines and a delayed influx of neutrophils. Trem‐1/3^–/– alveolar macrophages produced fewer cytokines upon exposure to S. pneumoniae in vitro and were less capable of phagocytosing this pathogen. TREM‐1/3 deficiency did not influence neutrophil responsiveness to S. pneumoniae. These results identify TREM‐1 as a key player in protective innate immunity during pneumococcal pneumonia, most likely by enhancing the early immune response of alveolar macrophages. Copyright © 2014 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Enhanced protective efficacy against Mycobacterium tuberculosis afforded by BCG prime‐DNA boost regimen in an early challenge mouse model is associated with increased splenic interleukin‐2‐producing CD4 T‐cell frequency post‐vaccination

The development of improved vaccines and vaccination strategies against Mycobacterium tuberculosis has been hindered by a limited understanding of the immune correlates of anti‐tuberculosis protective immunity. Simple measurement of interferon‐γ frequency or production per se does not provide adequate prediction of immune protection. In this study, we examined the relationship between T‐cell immune responses and protective efficacy conferred by the heterologous vaccination strategy, bacillus Calmette–Guérin (BCG) prime‐Ag85A DNA boost (B/D), in an early challenge mouse model of pulmonary tuberculosis. The results demonstrated that mice vaccinated with the B/D regimen had a significantly reduced bacillary load compared with BCG‐vaccinated mice, and the reduction in colony‐forming units was associated with decreased pathology and lower levels of inflammatory cytokines in the infected lungs. Further analysis of immunogenicity showed that the superior protection afforded by the B/D regimen was associated with significantly increased frequency of splenic interleukin‐2 (IL‐2) ‐producing CD4 T cells and increased IL‐2 production when measured as integrated mean fluorescence intensity post‐vaccination as well. These data suggest that measurement of elevated frequency of IL‐2‐producing CD4 T cells or IL‐2 production in the spleens of vaccinated mice can predict vaccine efficacy, at least in the B/D strategy, and add to the accumulating body of evidence suggesting that BCG prime‐boost strategies may be a useful approach to the control of M. tuberclosis infection.     

Airway hyper-reactivity mediated by B-1 cell immunoglobulin M antibody generating complement C5a at 1 day post-immunization in a murine hapten model of non-atopic asthma

Contact skin immunization of mice with reactive hapten antigen and subsequent airway challenge with the same hapten induces immediate airflow obstruction and subsequent airway hyper‐reactivity (AHR) to methacholine challenge, which is dependent on B cells but not on T cells. This responsiveness to airway challenge with antigen is elicited as early as 1 day postimmunization and can be adoptively transferred to naïve recipients via 1‐day immune cells. Responses are absent in 1‐day immune B‐cell‐deficient JH^?/? mice and B‐1 B‐cell‐deficient xid male mice, as well as in recipients of 1‐day immune cells depleted of cells with the B‐1 cell phenotype (CD19⁺ B220⁺ CD5⁺). As B‐1 cells produce immunoglobulin M (IgM), we sought and found significantly increased numbers of anti‐hapten IgM‐producing cells in the spleen and lymph nodes of 1‐day immune wild‐type mice, but not in xid mice. Then, we passively immunized naive mice with anti‐hapten IgM monoclonal antibody and, following airway hapten challenge of the recipients, we showed both immediate airflow obstruction and AHR. In addition, AHR was absent in complement C5 and C5a receptor‐deficient mice. In summary, this study of the very early elicited phase of a hapten asthma model suggests, for the first time, a role of B‐1 cells in producing IgM to activate complement to rapidly mediate asthma airway reactivity only 1 day after immunization.     

The atypical IκB protein IκBNS is important for Toll‐like receptor‐induced interleukin‐10 production in B cells

Although a major function of B cells is to mediate humoral immunity by producing antigen‐specific antibodies, a specific subset of B cells is important for immune suppression, which is mainly mediated by the secretion of the anti‐inflammatory cytokine interleukin‐10 (IL‐10). However, the mechanism by which IL‐10 is induced in B cells has not been fully elucidated. Here, we report that IκB_NS, an inducible nuclear IκB protein, is important for Toll‐like receptor (TLR)‐mediated IL‐10 production in B cells. Studies using IκB_NS knockout mice revealed that the number of IL‐10‐producing B cells is reduced in IκB_NS^?/? spleens and that the TLR‐mediated induction of cytoplasmic IL‐10‐positive cells and IL‐10 secretion in B cells are impaired in the absence of IκB_NS. The impairment of IL‐10 production by a lack of IκB_NS was not observed in TLR‐triggered macrophages or T‐cell‐receptor‐stimulated CD4⁺ CD25⁺ T cells. In addition, IκB_NS‐deficient B cells showed reduced expression of Prdm1 and Irf4 and failed to generate IL‐10⁺ CD138⁺ plasmablasts. These results suggest that IκB_NS is selectively required for IL‐10 production in B cells responding to TLR signals, so defining an additional role for IκB_NS in the control of the B‐cell‐mediated immune responses.     

Human leucocyte antigen‐Bw4 and Gag‐specific T cell responses are associated with slow disease progression in HIV‐1B‐infected anti‐retroviral therapy‐naive Chinese

In China, the majority of human immunodeficiency virus (HIV) infections are predominately subtype B. It is important to characterize the HIV‐1 subtype B‐specific and its T cell response within the Chinese population, with the aim of identifying protective correlates of immunity to control HIV‐1 infections. In this study, we performed a comprehensive analysis looking into the magnitude/strength of T cell responses directed at the Gag protein of the HIV‐1 subtype B, one of the most conserved HIV‐1 proteins. The study group consisted of anti‐retroviral native and chronic HIV‐1 subtype B‐infected individuals. We used enzyme‐linked immunospot (ELISPOT) assay to quantify the total T cell responses to HIV‐1 Gag at the single peptide level. Twenty‐eight (38%) peptides were recognized in 24 (82·8%) individuals. The p24 was identified as the most frequently recognized subunit protein with the greatest T cell response in the test, which correlated positively with CD4⁺ T cell count and inversely with viral load (VL). At the level of the human leucocyte antigen (HLA) supertypes, we detected the highest levels and a significant correlation with both the CD4⁺ T cell count and the VL with Gag T cell responses in Bw4/Bw4. These findings demonstrate that (i) the HIV‐1B Gag p24‐specific immune responses play an important role in controlling viral replication and slowing clinical progression; and (ii) HLA‐Bw4/Bw4 allele has stronger T cell responses, which is associated with slow clinical progression in Chinese HIV patients.     

Transcriptional repressor Blimp1 regulates follicular regulatory T‐cell homeostasis and function

The B‐lymphocyte‐induced maturation protein 1 (Blimp1) regulates T‐cell homeostasis and function. Loss of Blimp1 could double the proportion of follicular regulatory T (Tfr) cells. However, the effects that Blimp1 may have on the function of Tfr cells remain unknown. Here we document the function for Blimp1 in Tfr cells in vitro and in vivo. Data presented in this study demonstrate that Tfr cells indirectly inhibit the activation and differentiation of B cells by negatively regulating follicular helper T cells, so lowering the secretion of antibody. Lack of Blimp1 makes the immune suppression function of Tfr cells impaired in vitro. In the in vivo study, adoptive transfer of Tfr cells could reduce immune responses in germinal centres and relieve the muscle weakness symptoms of mice with experimental autoimmune myasthenia gravis. Blimp1 deficiency resulted in reduced suppressive ability of Tfr cells. This study identifies that Tfr cells are potent suppressors of immunity and are controlled by Blimp1.     

DNA immunization in relB-deficient mice discloses a role for dendritic cells in IgM → IgG1 switch in vivo

A single intraspleen inoculation of plasmid DNA coding for an immunoglobulin heavy chain gene initiates immunity and establishes immunologic memory against the antigenic determinants of transgenic immunoglobulins, somatic transgene immunization. During priming mice produce IgM but not IgG1 antibodies. Since IgM → IgG1 class switch occurs spontaneously during the primary immune response to protein antigens we investigated possible mechanisms for failure of spontaneous isotype switch in vivo in this model of immunity. We found that inoculation of plasmid DNA in the form of a chimeric gene coding for granulocyte-macrophage colony-stimulating factor (GM-CSF) was able to drive IgG1 class switch readily after priming. Since GM-CSF activates cells of the dendritic lineage we tested the possibility that dendritic cells (DC) may be involved in regulating IgM → IgG1 switch. To this end we used bone marrow chimeras constructed from mice carrying the null mutation for the relB member of the NF-κB/Rel family as these mice lack bone marrow-derived mature DC. RelB (-/-) mice and (-/-) bone marrow chimeras inoculated with DNA/GM-CSF did not produce IgG1 antibodies during the primary immune response. Since relB (-/-) bone marrow chimeras lack DC of donor origin but possess resident follicular dendritic cells we conclude that Ig class switch in vivo is regulated by the function of interdigitating dendritic cells (IDC). Thus, IDC may contribute to the qualitative aspects of the emerging immune response.     

B and CD4+ T‐cell expression of TLR2 is critical for optimal induction of a T‐cell‐dependent humoral immune response to intact Streptococcus pneumoniae

TLR2^?/? mice immunized with Streptococcus pneumoniae (Pn) elicit normal IgM, but defective CD4⁺ T‐cell‐dependent type 1 IgG isotype production, associated with a largely intact innate immune response. We studied the T‐cell‐dependent phosphorylcholine (PC)‐specific IgG3 versus the T‐cell‐independent IgM response to Pn to determine whether TLR2 signals directly via the adaptive immune system. Pn‐activated TLR2^?/? BMDC have only a modest defect in cytokine secretion, undergo normal maturation, and when transferred into naïve WT mice elicit a normal IgM and IgG3 anti‐PC response, relative to WT BMDC. Pn synergizes with BCR and TCR signaling for DNA synthesis in purified WT B and CD4⁺T cells, respectively, but is defective in cells lacking TLR2. Pn primes TLR2^?/? mice for a normal CD4⁺ T‐cell IFN‐γ recall response. Notably, TLR2^?/? B cells transferred into RAG‐2^?/? mice with WT CD4⁺T cells, or TLR2^?/? CD4⁺T cells transferred into athymic nude mice, each elicit a defective IgG3, in contrast to normal IgM, anti‐PC response relative to WT cells. These data are the first to demonstrate a major role for B‐cell and CD4⁺ T‐cell expression of TLR2 for eliciting an anti‐bacterial humoral immune response.