Functional plasticity of the LACK-reactive Vbeta4-Valpha8 CD4(+) T cells normally producing the early IL-4 instructing Th2 cell development and susceptibility to Leishmania major in BALB / c mice

Early production of IL-4 by LACK-reactive Vbeta4-Valpha8 CD4(+) T cells instructs aberrant Th2 cell development and susceptibility to Leishmania major in BALB / c mice. This was demonstrated using Vbeta4(+)-deficient BALB / c mice as a result of chronic infection with MMTV (SIM), a mouse mammary tumor virus expressing a Vbeta4-specific superantigen. The early IL-4 response was absent in these mice which develop a Th1 response to L. major. Here, we studied the functional plasticity of LACK-reactive Vbeta4-Valpha8 CD4(+) T cells using BALB/ c mice inoculated with L. major shortly after infection with MMTV (SIM), i. e. before deletion of Vbeta4(+) cells. These mice fail to produce the early IL-4 response to L. major and instead exhibit an IFN-gamma response that occurs within LACK-reactive Vbeta4-Valpha8 CD4(+) T cells. Neutralization of IFN-gamma restores the production of IL-4 by these cells. These data suggest that the functional properties of LACK-reactive Vbeta4-Valpha8 CD4(+) T cells are not irreversibly fixed.     

The levels and patterns of cytokines produced by CD4 T lymphocytes of BALB/c mice infected with Leishmania major by inoculation into the ear dermis depend on the infectiousness and size of the inoculum

The production of cytokines by CD4 lymph node T lymphocytes derived from BALB/c mice recently infected in the ear dermis with high (10(6) parasites) or low (10(3) parasites) doses of Leishmania major metacyclic promastigotes (MP) was examined over a 3-week period following inoculation. Results were compared with those obtained when mice were injected with less infectious parasite populations, namely, stationary-phase or log-phase promastigotes (LP). Cells were purified 16 h and 3, 8, and 19 days after inoculation, and the amounts of gamma interferon (IFN-gamma) and interleukin-4 (IL-4) released in response to LACK (Leishmania homolog of receptors for activated C kinase) or total L. major antigens were assessed. We found that LACK-reactive T cells from mice inoculated with a high dose of parasites first produced IFN-gamma and later on IL-4; the level of IFN-gamma produced early by these cells was dependent upon the stage of the promastigotes inoculated, the highest level being reached with cells recovered from mice inoculated with the least infectious parasites, LP; sequential production of IFN-gamma and then of IL-4 also characterized L. major antigen-reactive CD4 T cells, suggesting that the early production of IFN-gamma does not impede the subsequent rise of IL-4 and finally the expansion of the parasites; after low-dose inoculation of MP, cutaneous lesions developed with kinetics similar to that of lesions induced after inoculation of 10(6) LP, but in this case CD4 T lymphocytes did not release IFN-gamma or IL-4 in the presence of LACK and neither cytokine was produced in response to L. major antigens before the onset of lesion signs. These results suggest the existence of a discreet phase in terms of CD4 T-cell reactivity for at least the first 8 days following inoculation, a time period during which parasites are able to grow moderately. In conclusion, the levels and profiles of cytokines produced by Leishmania-specific CD4 T lymphocytes clearly depend on both the stage of differentiation and number of parasites used for inoculation.     

Conditions influencing the efficacy of vaccination with live organisms against Leishmania major infection

Numerous experimental vaccines have been developed with the goal of generating long-term cell-mediated immunity to the obligate intracellular parasite Leishmania major, yet inoculation with live, wild-type L. major remains the only successful vaccine in humans. We examined the expression of immunity at the site of secondary, low-dose challenge in the ear dermis to determine the kinetics of parasite clearance and the early events associated with the protection conferred by vaccination with live L. major organisms in C57BL/6 mice. Particular attention was given to the route of vaccination. We observed that the rapidity, strength, and durability of the memory response following subcutaneous vaccination with live parasites in the footpad are even greater than previously appreciated. Antigen-specific gamma interferon (IFN-gamma)-producing T cells infiltrate the secondary site by 1.5 weeks, and viable parasites are cleared as early as 2.5 weeks following rechallenge, followed by a rapid drop in IFN-gamma(+) CD4(+) cell numbers in the site. In comparison, intradermal vaccination with live parasites in the ear generates immunity that is delayed in effector cell recruitment to the rechallenge site and in the clearance of parasites from the site. This compromised immunity was associated with a rapid recruitment of interleukin-10 (IL-10)-producing CD4(+) T cells to the rechallenge site. Treatment with anti-IL-10-receptor or anti-CD25 antibody enhanced early parasite clearance in ear-vaccinated mice, indicating that chronic infection in the skin generates a population of regulatory cells capable of influencing the level of resistance to reinfection. A delicate balance of effector and regulatory T cells may be required to optimize the potency and durability of vaccines against Leishmaniasis and other intracellular pathogens.     

During the early prediabetic period in NOD mice,the pathogenic CD8(+) T-cell population comprises multiple antigenic specificities

In the NOD mouse model of type 1 diabetes, major histocompatibilitycomplex (MHC) class I-restricted CD8(+) T cells are essential for disease development. However, the extent of diversity of their antigenic specificities during early pathogenesis remains unclear. An insulin-derived peptide was recently identified as the epitope for the NOD-derived diabetogenic T-cell clone G9C8. To explore the possibility that the early pathogenic CD8(+) T-cell population comprises additional antigenic specificities, we employed the T-cell clones AI4 and NY8.3, both of which are pathogenic and represent specificities present in early insulitic lesions. The clones responded to distinct fractions of chromatographically separated class I MHC-bound peptides purified from NOD-derived NIT-1 beta cells, and neither clone recognized the insulin-derived peptide. NIT-1 cells represent an unlimited peptide source that will allow for the future isolation and sequencing of the novel multiple epitopes targeted early in the autoimmune response by pathogenic CD8(+) T cells.     

Central memory CD4 cells are an early indicator of immune reconstitution in HIV/AIDS patients with anti-retroviral treatment

The number of central memory cells among the CD4+ T cells and the of activation of CD8+ T cells is believed to be a better indicator of immune restoration in patients on antiretroviral therapy (ART) than the absolute numbers of CD4(+) and CD8+ T cells alone. In the current study, we investigated the changes in the CD4(+) T cell subsets and their association with immune reconstitution and immune activation at early stages of ART. A prospective study was performed in 21 asymptomatic treatment-naive HIV-infected patients with CD4(+) T cells less than 350 cells/μl. Blood samples were evaluated at base line, and at 2, 4, 8 and 12 weeks' post antiretroviral therapy (ART). A biphasic increase of CD4(+) T cells, central memory CD4 cells (CD4 CM) and CD4 na?ve cells were observed after ART, with a rapid increase before week 4. Change in CD4 CM at week 4 positively correlated with the change in CD4(+) T cells at weeks 12 post ART, and negatively correlated with the change in CD8(+)CD38(+) T cells at weeks 12 post ART. We conclude that CD4 CM cells are a major contributor to early immune reconstitution in treatment-naive HIV-infected patients with delayed ART, and might be an early indicator for immune reconstitution.     

A kinetic analysis of the in vitro sensitization of murine peritoneal mast cells with monoclonal IgE anti-DNP antibody.

Incubation of murine peritoneal cells with monoclonal IgE anti-DNP antibody in vitro led to sensitization of mast cells, measured as release of 5-HT upon challenge with DNP-HSA antigen. Sensitization was maximal at 0.3-3.0 micrograms/ml of IgE anti-DNP and declined above and below this concentration range. In kinetic studies, the time-course of sensitization was clearly divisible into an early slow phase of approximately 4 hr, followed by a more rapid linear phase from 4 to 48 hr. The early slow phase was more pronounced at lower concentrations of IgE anti-DNP (within the range 0.05-5.0 micrograms/ml). The degree of sensitization obtained after incubation of peritoneal cells with IgE anti-DNP for fixed periods (2, 4 and 8 hr) was markedly increased when the cells were washed and recultured in IgE-free medium, thus demonstrating that sensitization proceeds subsequent to an early stage of binding of IgE to receptors. Sensitization with IgE anti-DNP was blocked by addition of excess rat myeloma IgE, but only to a marked extent (greater than 50%) when the blocking immunoglobulin was added during the first 2 hr, thus providing further evidence that the major part of binding of the IgE antibody took place during this early stage, that is, prior to the phase of greatest sensitization. These findings indicate a period of delay between binding of IgE to receptors and functional sensitization, measured as mediator release in response to antigen.     

Spontaneous peripheral T-cell responses to the IA-2beta (phogrin) autoantigen in young nonobese diabetic mice

Phogrin (IA-2beta), a major autoantigen in type 1 diabetes in man is recognized by peripheral T cells in the nonobese diabetic (NOD) mouse. CD4(+) T-cell clones derived from immunized NOD animals elicit islet destruction in a disease transfer model. Spontaneous proliferative responses to the protein and derived peptide epitopes were detected in peripheral lymph node cells (LNC) of unprimed NOD mice but not BALB/c controls as early as 4 weeks of age at a time point when insulitis in NOD animals is minimal. Responses to irradiated NOD islet cells but not irradiated NOD spleen cells were observed for both male and female NOD animals. Insulin, phogrin and phogrin-peptide 7 (aa 755-777) but not phogrin-peptide 2 (aa 640-659) or tetanus toxin peptide were recognized as antigens. Islet cell-reactive and phogrin peptide 7-specific CD4(+) T-cell lines were generated from splenocytes of unprimed 4-week-old NOD females and shown to secrete Th1-type cytokines. The results show that the phogrin molecule is targeted early in the course of disease in NOD animals at a time when circulating autoantibodies are absent and insulitis is minimal.     

Mast cell-derived neurotrophin 4 mediates allergen-induced airway hyperinnervation in early life

Asthma often progresses from early episodes of insults. How early-life events connect to long-term airway dysfunction remains poorly understood. We demonstrated previously that increased neurotrophin 4 (NT4) levels following early-life allergen exposure cause persistent changes in airway smooth muscle (ASM) innervation and airway hyper-reactivity (AHR) in mice. Herein, we identify pulmonary mast cells as a key source of aberrant NT4 expression following early insults. NT4 is selectively expressed by ASM and mast cells in mice, nonhuman primates, and humans. We show in mice that mast cell-derived NT4 is dispensable for ASM innervation during development. However, upon insults, mast cells expand in number and degranulate to release NT4 and thus become the major source of NT4 under pathological condition. Adoptive transfer of wild-type mast cells, but not NT4^−/− mast cells restores ASM hyperinnervation and AHR in Kit^W-sh/W-sh mice following early-life insults. Notably, an infant nonhuman primate model of asthma also exhibits ASM hyperinnervation associated with the expansion and degranulation of mast cells. Together, these findings identify an essential role of mast cells in mediating ASM hyperinnervation following early-life insults by producing NT4. This role may be evolutionarily conserved in linking early insults to long-term airway dysfunction.     

CD4-T-lymphocyte interactions with pneumolysin and pneumococci suggest a crucial protective role in the host response to pneumococcal infection

Previously, we had shown that T cells accumulated in peribronchiolar and perivascular areas of lungs soon after intranasal infection with Streptococcus pneumoniae. We have now presented new evidence, using major histocompatibility class II-deficient mice, that CD4 cells are important for early protective immunity. In addition, we have also shown that a population of human CD4 cells migrates towards pneumococci and that in vivo-passaged pneumococci are substantially more potent at inducing migration than in vitro-grown bacteria. This migratory process is unique to a specific population of CD4 cells, is highly reproducible, and is independent of prior CD4 cell activation, and yet the migratory process results in a significant proportion of CD4 cells becoming activated. The production of pneumolysin is a key facet in the induction of migration of CD4 cells by in vivo bacteria, as pneumolysin-deficient bacteria do not induce migration, but the data also show that pneumolysin alone is not sufficient to explain the enhanced migration. Increased CD25 expression occurs during migration, and a higher percentage of cells in the migrated population express gamma interferon or interleukin 4 (IL-4) than in the population that did not migrate. There is evidence that the activation of IL-4 expression occurs during migration.     

Role of NK Cells in Early Host Response to Chlamydial Genital Infection

The cell-mediated immune response has been documented to be the major protective immune mechanism in mice infected genitally with the agent of mouse pneumonitis (MoPn), a biovar of Chlamydia trachomatis. Moreover, there is strong evidence to indicate that gamma interferon (IFN-γ) is a major effector mechanism of the cell-mediated immune response. Previous studies from this laboratory have also reported that the dominant cell population in the genital tract is the CD4 Th1 population. When experiments were performed by the enzyme-linked immunospot assay, high numbers of cells producing IFN-γ were found in the genital tract, concomitant with resolution of the infection; however, in addition, an increase in IFN-γ-producing cells which were CD4⁻ was seen early in the infection. Since natural killer (NK) cells produce IFN-γ and have been found to participate in the early responses in other infections, we hypothesized that NK cells are responsible for early IFN-γ production in the murine chlamydial model. NK cells were quantified by the standard YAC-1 cytotoxicity assay and were found to appear in the genital tract as early as 12 h after intravaginal infection with MoPn. The cells were confirmed to be NK cells by abrogation of YAC-1 cell cytotoxicity by treatment in vitro and in vivo with anti-asialo-GM1. The early IFN-γ response could also be depleted by treatment with anti-asialo-GM1, indicating that NK cells were responsible for the production of this cytokine. Of interest was our observation that depletion of NK cells also exacerbated the course of infection in the mice and elicited a Th2 response, as indicated by a marked increase in immunoglobulin G1 antibody. Thus, these data demonstrate that NK cells are not only responsible for the production of IFN-γ early in the course of chlamydial genital tract infection but are also, via IFN-γ, a significant factor in the development of the Th1 CD4 response and in the control of the infection.     

Tracking salmonella-specific CD4 T cells in vivo reveals a local mucosal response to a disseminated infection

A novel adoptive transfer system was used to track the fate of naive Salmonella-specific CD4 T cells in vivo. These cells showed signs of activation in the Peyer's patches as early as 3 hr after oral infection. The activated CD4 T cells then produced IL-2 and proliferated in the T cell areas of these tissues before migrating into the B cell-rich follicles. In contrast, Salmonella-specific CD4 T cells were not activated in the spleen and very few of these cells migrated to the liver, despite the presence of bacteria in both organs. These results show that the T cell response to pathogenic Salmonella infection is localized to the gut-associated lymphoid tissue and does not extend efficiently to the major sites of late infection.     

Localisation of specific heparan sulfate proteoglycans during the proliferative phase of brain development.

Early brain development is characterised by the proliferation of neural precursor cells. Several families of signalling molecules such as the fibroblast growth factors (FGFs) and Wnts are known to play important roles in this early phase of brain development. Accumulating evidence demonstrates that signalling of these molecules requires the presence of heparan sulfate chains attached to a proteoglycan core protein (HSPG). However, the specific identity of the HSPG components in the developing brain is unknown. To determine which HSPGs might be involved at this early phase, we analysed the expression of the major cell surface HSPG families in the developing brain at a time of most active proliferation. Syndecan-1 and glypican-4 were the most highly expressed in the developing brain during the time of peak proliferation and localise to ventricular regions of the brain, where the precursor cells are proliferating. Syndecan-4, although less abundant, also localises to cells in the ventricular zone. We have also examined HSPG involvement in brain development using cultures of embryonic neural precursor cells. We find that FGF2 stimulation of proliferation is inhibited in the presence of sodium chlorate, an inhibitor of heparan sulfate synthesis, and is rescued by addition of exogenous heparan sulfate. These data support a requirement for heparan sulfate in FGF signalling for proliferation of brain precursor cells. The expression of these specific HSPGs within the proliferative zone of the brain suggests that they may be involved in regulation of early brain development, such as FGF-stimulated proliferation.     

Studies in listeriosis show the strong symbiosis between the innate cellular system and the T-cell response

Summary: Resistance to infection with Listeria monocytogenes involves a series of cellular interactions, many of which are carried on by cytokines. Macrophages. NK cells and neutrophils participate in early stages of Listeria resistance. The neutrophil is specially important for clearance of the liver phase of listeriosis. Macrophages and NK cells interact by way of IL-12 and TNF, which induce the NK cell to produce IFN-γ. IFN-γ 'S the major macrophage-activating cytokine. The CB-I7 SCID mouse shows these cellular interactions restricting the growth of Listeria , without its elimination. CD4 and/or CDS T cells bring about sterilizing immunity, Macrophages influence the lymphocyte response by way of antigen presentation and also by promoting Th1 differentiation, Thus, elimination of Listeria requires a symbiosis between innate immunity and the T-cell system.     

TLR9 signaling is essential for the innate NK cell response in murine cutaneous leishmaniasis

Mice deficient for the TLR adaptor molecule MyD88 succumb to a local infection with Leishmania (L.) major. However, the TLR(s) that contribute to the control of this intracellular parasite remain to be defined. Here, we show that TLR9 was required for the induction of IL-12 in bone marrow-derived DC by intact L. major parasites or L. major DNA and for the early IFN-gamma expression and cytotoxicity of NK cells following infection with L. major in vivo. During the acute phase of infection TLR9-/- mice exhibited more severe skin lesions and higher parasite burdens than C57BL/6 wild-type controls. Although TLR9 deficiency led to a transient increase of IL-4, IL-13 and arginase 1 mRNA and a reduced expression of iNOS at the site of infection and in the draining lymph nodes, it did not prevent the development of Th1 cells and the ultimate resolution of the infection. We conclude that TLR9 signaling is essential for NK cell activation, but dispensable for a protective T cell response to L. major in vivo.