T-cell Receptor Alpha Beta Research Articles

HLA-E-restricted recognition of cytomegalovirus-derived peptides by human CD8+cytolytic T lymphocytes

HLA-E-restricted T cell receptor alphabeta+ CD8+ cytolytic T lymphocytes (CTLs) exist as monoclonal expansions in the peripheral blood of some individuals. Here, we show that they recognize, with high avidity, peptides derived from the UL40 protein of different human cytomegalovirus (CMV) strains. Recognition results in the induction of cytotoxicity, IFN-gamma production and cell proliferation. Autologous cells pulsed with CMV-derived peptides become susceptible to lysis by HLA-E-restricted CTLs and induce their proliferation. The high avidity for CMV-derived peptides may explain how these cells are generated in vivo and suggest their possible role in the host defenses against CMV, a virus that evolved various mechanisms to down-regulate classical HLA class I molecules, thus escaping detection by conventional CTLs.

Immune networks in animal models of inflammatory bowel disease.

The animal models of inflammatory bowel disease provide a framework to define the immunopathogenesis of intestinal inflammation. Studies in these models support the hypothesis that exaggerated immune responses to normal enteric microflora are involved in the initiation and perpetuation of chronic intestinal inflammation. A major pathway involves development of acquired immune responses by the interactions of CD4+ T-cell receptor alphabeta T cells with antigen-presenting cells (dendritic cells). Immunoregulatory cells, including Tr1 cells, Th3 cells, and CD4+ CD25+ T cells and B cells, directly or indirectly affect the T-cell receptor alphabeta T cell-induced immune responses and bridge innate and acquired immunity. The study of these complicated immune networks provides the rationale for the development of new therapeutic interventions in inflammatory bowel disease.

Preferential Expansion of Vγ9-JγP/Vδ2-Jδ3 γδ T Cells in Nasal T-Cell Lymphoma and Chronic Active Epstein-Barr Virus Infection

We recently established an Epstein-Barr virus (EBV)-positive gammadelta T-cell line from a nasal T/natural killer (NK)-cell lymphoma (Nagata H, Konno A, Kimura N, Zhang Y, Kimura M, Demachi A, Sekine T, Yamamoto K, Shimizu N: Characterization of novel natural killer (NK)-cell and gammadelta T-cell lines established from primary lesions of nasal T/NK-cell lymphomas associated with the Epstein-Barr virus. Blood 2001, 97:708-713). Subsequently, we established two novel EBV-positive gammadelta T-cell lines from the peripheral blood of patients with chronic active EBV infection. Analysis of the terminal repeat of EBV showed that the three cell lines consisted of monoclonal populations, and flow cytometry showed that they had a common phenotype of gammadelta T cells: CD3(+) CD4(-) CD8(-) CD16(-) CD19(-) CD56(+) CD57(-) HLA-DR(+) T-cell receptor (TCR) alphabeta(-) TCR gammadelta(+). Analysis for the expression of TCR by flow cytometry showed that all three cell lines were Vgamma9(+)/Vdelta2(+), but negative for VgammaI, Vdelta1, or Vdelta3 TCR. Southern blot analysis for TCR genes showed that the three cell lines had a common rearrangement of Vgamma9-JgammaP and Jdelta3 genes. Polymerase chain reaction and sequence analysis of the junction between Vdelta and Jdelta genes revealed that the Jdelta3 genes were rearranged with the Vdelta2 genes. In contrast, none of the EBV-negative gammadelta T-cell lines, Molt-14, Peer, or Loucy, which were analyzed for controls, had Vgamma9 or Vdelta2 TCR, or a rearrangement of Jdelta3 genes. These results indicated that Vgamma9-JgammaP/Vdelta2-Jdelta3(+) gammadelta T cells were preferentially affected by EBV and expanded in patients with nasal gammadelta T-cell lymphoma and chronic active EBV infection. Jdelta3(+) gammadelta T cells are known to be a very minor population in gammadelta T cells of peripheral blood, whereas Vgamma9-JgammaP/Vdelta2-Jdelta1(+) cells are the major population. The close association of EBV with this particular gammadelta T-cell population may provide a key to the etiology of EBV-positive lymphoproliferative diseases.

Analysis of TCR, pTα, and RAG-1 in T-acute lymphoblastic leukemias improves understanding of early human T-lymphoid lineage commitment

T-acute lymphoblastic leukemias (T-ALLs) derive from human T-lymphoid precursors arrested at various early stages of development. Correlation of phenotype and T-cell receptor (TCR) status with RAG-1 and pT alpha transcription in 114 T-ALLs demonstrated that they largely reflect physiologic T-lymphoid development. Half the TCR alpha beta lineage T-ALLs expressed a pre-TCR, as evidenced by RAG-1, pT alpha, and cTCR beta expression, absence of TCR delta deletion, and a sCD3(-), CD1a(+), CD4/8 double-positive (DP) phenotype, in keeping with a population undergoing beta selection. Most TCR gamma delta T-ALLs were pT alpha, terminal deoxynucleotidyl transferase (TdT), and RAG-1(lo/neg), double-negative/single-positive (DN/SP), and demonstrated only TCR beta DJ rearrangement, whereas 40% were pT alpha, TdT, and RAG-1 positive, DP, and demonstrated TCR beta V(D)J rearrangement, with cTCR beta expression in proportion. As such they may correspond to TCR alpha beta lineage precursors selected by TCR gamma delta expression, to early gamma delta cells recently derived from a pT alpha(+) common alpha beta/gamma delta precursor, or to a lineage-deregulated alpha beta/gamma delta intermediate. Approximately 30% of T-ALLs were sCD3/cTCR beta(-) and corresponded to nonrestricted thymic precursors because they expressed non-T-restricted markers such as CD34, CD13, CD33, and CD56 and were predominantly DN, CD1a, pT alpha, and RAG-1 low/negative, despite immature TCR delta and TCR gamma rearrangements. TCR gene configuration identified progressive T-lymphoid restriction. T-ALLs, therefore, provide homogeneous expansions of minor human lymphoid precursor populations that can aid in the understanding of healthy human T-cell development.

Hepatosplenic alpha beta T-cell lymphoma: a report of an S100-positive case

Hepatosplenic T-cell lymphoma is an uncommon neoplasm characterized by a lymphoid infiltrate within the sinusoids of the liver, spleen, and bone marrow, without significant nodal involvement. The majority of cases express the gammadelta T-cell receptor and are associated with an isochromosome 7q cytogenetic abnormality. Recently, a small number of cases have been reported that express the alphabeta T-cell receptor. Here, we report our findings of a case of an S100-positive hepatosplenic alphabeta T-cell lymphoma in a 20-year-old woman who presented with pancytopenia and hepatosplenomegaly. The case adds to the growing literature of hepatosplenic alphabeta T-cell lymphomas.

Antigen feeding increases frequency and antigen-specific proliferation ability of intraepithelial CD4+ T cells in alphabeta T cell receptor transgenic mice.

To study how intestinal intraepithelial lymphocytes (IEL) are affected by orally ingested antigen, the phenotypes and responses of the IEL in mice expressing a transgenic T cell receptor alphabeta (TCR alphabeta) specific for ovalbumin (OVA) were analyzed after feeding OVA. In the OVA-fed mice, the abundance of alphabeta-IEL as a proportion of the total IEL population increased and the frequency of CD4+ cells increased within the TCR alphabeta+ IEL population. CD4(+) IEL from OVA-fed transgenic mice proliferated in vitro more markedly in response to antigen stimulation than IEL from mice fed the control diet. These results indicate that antigen-specific proliferation of CD4+ IEL was amplified as a result of oral administration of antigen.

Vgamma4(+) T cells promote autoimmune CD8(+) cytolytic T-lymphocyte activation in coxsackievirus B3-induced myocarditis in mice: role for CD4(+) Th1 cells.

T cells expressing the Vgamma4 T-cell receptor (TCR) promote myocarditis in coxsackievirus B3 (CVB3)-infected BALB/c mice. CD1, a major histocompatibility complex (MHC) class I-like molecule, is required for activation of Vgamma4(+) cells. Once activated, Vgamma4(+) cells initiate myocarditis through gamma interferon (IFN-gamma)-mediated induction of CD4(+) T helper type 1 (Th1) cells in the infected animal. These CD4(+) Th1 cells are required for activation of an autoimmune CD8(+) alphabeta TCR(+) effector, which is the predominant pathogenic agent in this model of CVB3-induced myocarditis. Activated Vgamma4(+) cells can adoptively transfer myocarditis into BALB/c mice infected with a nonmyocarditic variant of CVB3 (H310A1) but cannot transfer myocarditis into either uninfected or CD1(-/-) recipients, demonstrating the need for both infection and CD1 expression for Vgamma4(+) cell function. In contrast, CD8(+) alphabeta TCR(+) cells transfer myocarditis into either infected CD1(-/-) or uninfected recipients, showing that once activated, the CD8(+) alphabeta TCR(+) effectors function independently of both virus and CD1. Vgamma4(+) cells given to mice lacking CD4(+) T cells minimally activate the CD8(+) alphabeta TCR(+) cells. These studies show that Vgamma4(+) cells determine CVB3 pathogenicity by their ability to influence both the CD4(+) and CD8(+) adaptive immune response. Vgamma4(+) cells enhance CD4(+) Th1 (IFN-gamma(+)) cell activation through IFN-gamma- and CD1-dependent mechanisms. CD4(+) Th1 cells promote activation of the autoimmune CD8(+) alphabeta TCR(+) effectors.

Role of CD4+ and CD8+ T cells in the rejection of concordant pancreas xenografts.

We studied the ability of CD4 and CD8 T cells to induce rejection of pancreas xenografts in a concordant combination using rat pancreas xenografts as donors and chemically induced diabetic mice as recipients. Lewis rat (2 to 3 weeks old) pancreas xenografts were transplanted into streptozotocin (STZ)-induced diabetic mice. Lymphocyte proliferation and cytokine production were analyzed in vitro. All pancreas xenografts were assessed by functional (blood glucose) and histopathologic examinations. Lewis rat pancreas grafts were rejected within 10 to 13 days, with mononuclear cell infiltrate and tissue necrosis in STZ-induced diabetic mice. A predominant T cell receptor alphabeta -CD4 cell (on day 4) and T cell receptor alphabeta -CD8 cell (on day 8) infiltrate and IgM deposition were found in the pancreas xenografts after transplantation. Anti-CD4 (GK1.5), but not anti-CD8 (YTS169.4), monoclonal antibodies resulted in a prolonged survival of Lewis rat pancreas xenografts. Lewis pancreas xenografts were permanently accepted by CD4 knockout mice but not by CD8 knockout mice. The pancreas xenografts were acutely rejected with a mean survival time of 15.3 days in B cell-deficient mice (microMT/microMT). Transfer of CD4 but not CD8 spleen cells from naïve C57BL/6 mice into Rag2 mice led to acute rejection of transplanted pancreas xenografts. However, activated CD8 spleen cells elicited rejection of Lewis rat pancreas xenografts in SZT-induced diabetic mice. The current results show that CD4 T cells are necessary and sufficient for mediating the rejection of Lewis rat pancreas xenografts in STZ-induced diabetic mice. However, CD8 cells, when activated, can also induce acute rejection of concordant pancreas xenografts.

NK1.1+ cell depletion in vivo fails to prevent protection against infection with the murine nematode parasite Trichuris muris.

Protection against the murine nematode parasite Trichuris muris has been shown to involve interleukin 4 (IL-4). NK1.1+ T cell receptor alphabeta+ cells, designated Natural Killer T (NKT) cells, produce a large amount of IL-4 in response to anti-CD3 stimulation and numerous pieces of evidence suggest that NKT cells provide the initial source of IL-4 for T helper 2 (Th2) priming. These observations allow the hypothesis that NKT cells produce a large amount of IL-4 in response to T. muris infection and augment Th2 responses and IL-4 production, thus achieving protection against T. muris. To investigate the involvement of NKT cells in protection against T. muris infection, NK1.1+ cell-depleted B10.BR mice were prepared by anti-NK1.1 monoclonal antibody injection. Efficient expulsion of T. muris worms occurred in NK1.1+ cell-depleted infected mice, and the expulsion kinetics of T. muris worms, the levels of IL-4 production by mesenteric lymph node cells, and the kinetics of the specific IgG1 and IgG2a responses to T. muris were similar to those in mouse IgG-treated or non-treated control B10.BR mice. These observations suggest that NK1.1+ cells and NKT cells are not involved in the induction of Th2 responses and protective immunity to T. muris infection.

Differentiation of anti-tumour cytotoxic T lymphocytes from autologous peripheral blood lymphocytes in non-Hodgkin's lymphomas.

We have previously reported that specific anti-tumour cytotoxic T cells (CTL) can be differentiated from tumour-infiltrating lymphocytes (TIL) in non-Hodgkin's lymphoma. We found that the combination of interleukin (IL)-1, IL-2 and IL-12 was very efficient for expansion of CD8+ T-cell receptor (TCR)alphabeta+ T cells and for development of their ability to specifically lyse tumour cells. In this study, we investigated whether anti-tumour T cells could be generated from the peripheral blood of patients using the culture protocol developed for TIL. Autologous T cells and tumour B cells from five patients were included in this study. It was found that polyclonal anti-tumour cytotoxic effector cells were generated when cultured in the presence of IL-1beta, IL-2 and IL-12. Interestingly, tumour cells were lysed by perforin/granzyme-mediated cytolysis and not by CD95-mediated apoptosis. By performing inhibition experiments, it was observed that both CD8+ and CD4+ T cells were responsible for the cytotoxic effect and that they were able to recognize malignant B cells by either a major histocompatibility complex (MHC)-restricted or MHC-non-restricted mechanism. Intriguingly, in addition to interferon-gamma and tumour necrosis factor-alpha, IL-10 was secreted continuously during culture. The source of patient T cells used for the generation of anti-tumour CTL should be based on the results obtained with peripheral blood lymphocytes and TIL.

CD25+ immunoregulatory T-cells of donor origin suppress alloreactivity after BMT.

We have previously identified donor-derived Thy1+ alphabeta T-cell receptor (TCR)+ CD4+ CD8- regulatory T-cells that suppress GVH reactivity induced by donor leukocyte infusion (DLI) after BMT. These cells develop in the recipient thymus and may play a role in the maintenance of donor-host tolerance after allogeneic BMT. In the present study, we sought to further characterize the T-cells responsible for the regulatory cell activity in our model. Lethally irradiated recipient AKR mice (H-2k) received transplants of BM from CD25-deficient (-/-) C57BL/6 mice (H-2b). Recipients of CD25-deficient BM developed more severe GVHD after DLI than did recipients of normal BM, a result that indirectly suggests that CD4+ CD25+ regulatory T-cells are important to the suppression of GVH reactivity after allogeneic BMT. GVHD was accompanied by mortality, body weight loss, and elevated percentages of T-cells from the DLI in the peripheral blood in mice that received CD25-deficient BM compared to mice that received normal BM. Both CD40-CD40L and CD28-B7 costimulatory pathways have been implicated in the generation of CD25+ regulatory T-cells. Therefore, we tested whether deficiency in either of these pathways affected the activity of donor BM-derived regulatory T-cells. The absence of CD40L did not affect the regulatory T-cells (ie, recipient mice were still protected from DLI-induced GVHD). In contrast, use of marrow from CD28-deficient mice resulted in complete loss of suppression of GVH reactivity. Thus, CD28 but not CD40L was critical for the generation and/or activation of immunoregulatory T-cells that suppressed GVHD induced by DLI. Together, the results of these experiments suggest that CD4+ CD25+ regulatory T-cells suppress GVH reactivity after BMT and that CD28 expression is indispensable for the generation of these cells.

Establishment of animal model of antigen-specific T lymphocyte recruitment into nasal mucosa.

DO11.10 transgenic mice, expressing an ovalbumin (OVA)-specific alphabeta T-cell receptor (TCR), have been used as a model of various immune diseases associated with T lymphocytes. Some studies of immunoresponse in lung have involved adoptive transfer of DO11.10 mice. As of yet, however, there have been no studies of the adoptive transfer model in the upper airway. The purpose of this study was to establish an animal model to clarify the recruitment mechanism and the roles of Th2 cells in allergic rhinitis. In accordance with the adoptive transfer system, we generated Th0, Th1 and Th2 cells from DO11.10 mice and transferred them into wild type BALB/c mice. Following nasal OVA challenge to DO11.10 mice or to the BALB/c mice into which antigen-specific Th2 cells had been transferred, the number of local antigen-specific TCR-positive cells accompanying the local eosinophilia had significantly increased. However, nasal OVA challenge to BALB/c mice into which antigen-specific Th0 or Th1 cells were transferred failed to increase the number of local OVA-specific TCR positive cells. These observations suggest that an antigen-specific homing mechanism of Th2 cells may exist in nasal mucosa. Analysis of this model will assist in the development of new therapeutic strategy, which targets Th2 cells in allergic rhinitis.

Interleukin-7 inhibits pre-T-cell differentiation induced by the pre-T-cell receptor signal and the effect is mimicked by hGM-CSF in hGM-CSF receptor transgenic mice.

We have previously reported that human granulocyte-macrophage colony-stimulating factor (hGM-CSF) causes a stage-specific inhibition of T-cell receptor (TCR) alphabeta cell development in the thymus of transgenic mice constitutively expressing the hGM-CSF receptor. Since it has been reported that the addition of interleukin-7 (IL-7) to fetal thymic organ culture (FTOC) has similar effects, we compared the effects of IL-7 and hGM-CSF on TCR(alphabeta) cell development in hGM-CSF receptor transgenic mice. We reconstituted fetal lobes with sorted pre-T, or post pre-T CD4(-)CD8(-) precursor cells. The addition of either IL-7 or hGM-CSF to these cultures suppressed further differentiation of pre-T cells but not post pre-T cells. At the same time, the cell number was increased, suggesting that pre-T-cell proliferation is stimulated by these cytokines. Furthermore, the differentiation of recombination-activating gene-1 (RAG-1)-deficient pre-T cells in response to anti-CD3 antibody stimulation was suppressed by either IL-7 or hGM-CSF, suggesting that these cytokines inhibit the pre-T-cell receptor (pre-TCR) signal. This inhibition is unexpected because the pre-TCR signal and the IL-7 signal have previously been considered to be co-operative. Recent analysis of the downstream events of IL-7 receptor and GM-CSF receptor revealed that they share common signal transduction molecules. Our results show that IL-7 is able to promote pre-T cell proliferation and to suppress differentiation induced by the pre-TCR signal. GM-CSF can mimic these biological activities of IL-7 when the pre-T cells express GM-CSF receptors. Our data suggest that both timing and level of activation of the IL-7 signalling pathway must be precisely regulated to facilitate the differentiation of thymocytes.

The mesenchyme expresses T cell receptor mRNAs: relevance to cell growth control.

The mesenchyme plays a crucial regulatory role in organ formation and maintenance. However, comprehensive molecular characterization of these cells is lacking. We found unexpectedly that primary mesenchyme, as well as mesenchymal cell clones, express T cell receptor (TCR)alphabeta mRNAs, lacking the variable region. Immunological and genetic evidence support the expression of a corresponding TCRbeta protein. Additionally, mRNAs encoding TCR complex components including CD3 and zeta chain are present. A relatively higher expression of the mesenchymal TCRbeta mRNA by cultured mesenchymal cell clones correlates with fast growth, whereas poorly expressing cells are slow growers and are contact inhibited. The clones that express relatively higher amount of the TCR mRNA exhibit an increased capacity to form tumors in nude mice. However, the expression of this mRNA in the mesenchyme is not per se leading to tumorigenesis, as demonstrated by primary mesenchyme that does not form tumors in mice while expressing moderate amounts of the TCR transcripts. The expression of mesencymal TCRbeta was confined to the G2/M phases of the cell cycle in the MBA-13 mesenchymal cell line. This cell cycle dependent expression, considered together with the correlation between growth properties and the level of TCR expression by cell clones, implies association of mesenchymal TCR with cell growth control.

HOX-A10 regulates hematopoietic lineage commitment: evidence for a monocyte-specific transcription factor

Homeobox genes are well known for their crucial role during embryogenesis but have also been found to be critically involved in normal and leukemic hematopoiesis. Because most previous studies focused on the role of aberrant HOX gene expression in leukemogenesis and because HOX-A10 is expressed in human CD34(+) precursor cells, this study investigated whether HOX-A10 also plays a pivotal role in normal hematopoietic-lineage determination. The effect of enforced expression of this transcription factor on hematopoietic differentiation of highly purified human cord-blood progenitors was examined by using in vitro assays. In fetal thymic organ cultures, a dramatic reduction in cells expressing high levels of HOX-A10 was observed, along with absence of thymocytes positive for CD3(+) T-cell receptor alphabeta. Furthermore, in MS-5 stromal cell cultures, there was a 7-fold reduction in the number of natural killer cells and a 9-fold reduction in the number of B cells, thus showing a profound defect in differentiation toward the lymphoid lineage in HOX-A10-transduced progenitors. In contrast, the number of CD14(+) monocytic cells in the stromal cell culture was 6-fold higher, suggesting an enhanced differentiation toward the myeloid differentiation pathway of HOX-A10-transduced progenitors. However, there was a slight reduction in the number of CD15(+) granulocytic cells, which were blocked in their final maturation. These data show that HOX-A10 can act as an important key regulator of lineage determination in human hematopoietic progenitor cells.

A broad T-cell repertoire diversity and an efficient thymic function indicate a favorable long-term immune reconstitution after cord blood stem cell transplantation

Cord blood (CB) is used increasingly as a source of hematopoietic stem cells because of a lower risk of acute and chronic graft-versus-host disease (GVHD). However, there is some concern regarding the ability to adequately reconstitute host immune response due to the immaturity and naivety of CB T cells. This study was designed to evaluate T-cell reconstitution using combined approaches of phenotyping, analysis of alphabeta T-cell receptor (TCR) diversity, and assessment of ex vivo thymic function by measuring TCR rearrangement excision circles (TRECs). Ten patients who underwent CB transplantation for high-risk hematologic disorders were compared to a reference group of 19 age- and GVHD-matched patients who underwent transplantation with non-T cell-depleted bone marrow from an HLA-identical sibling donor. TREC values correlated with the relative number of naive T cells and with TCR repertoire polyclonality. During the first year after transplantation, TCR repertoires were highly abnormal and TREC values low in both groups. Notably, 2 years after transplantation onward TREC values as well as TCR diversity were higher in CB recipients than in recipients of bone marrow transplants. These data indicate an efficient thymic regeneration pathway from CB lymphoid progenitors despite the low number of cells infused compared to bone marrow, arguing for a complete clinical immune recovery after CB transplantation.

Lymphocyte development in neonatal and adult c-Kit-deficient (c-KitW/W) mice.

Hematopoietic stem cells and lymphocyte progenitors express the receptor tyrosine kinase c-Kit. In fetal and neonatal life, c-Kit plays a redundant role in T, and no apparant role in B cell development. In neonatal mice deficient for both c-Kit and the common gamma chain (gammac), a component of the interleukin-7 (IL-7) receptor, the thymus is alymphoid, and therefore lacks T cell receptor (TCR) beta, gamma, and delta rearrangements. Thus, a critical role for c-Kit in T cell development around birth is well established. More recently, it has become possible to examine the impact of c-Kit deficiency under conditions of steady state lymphopoiesis in adult life. Such analysis has been made possible by the identification of a viable adult c-Kit-deficient (c-KitW/W) variant, termed the Vickid mouse. The Vickid mouse arose by outcrossing c-KitW-bearing mice of the WB strain, in which lack of c-Kit is lethal, to a mixed genetic background. In adult Vickid mice, mainstream alphabeta TCR+ thymocyte development, and B cell development in the bone marrow are severely c-Kit-dependent with progressive age. Analysis of other pathways of developing T cells, i.e. CD4-CD8- (double neagative [DN]) alphabeta TCR+ and DN gammadelta TCR+ thymocytes revealed that the development of both lineages is also severely affected by lack of c-Kit. However, numbers of gammadelta TCR+ T cells decline before numbers of alphabeta TCR+ T cells in the thymus. In contrast to T and B cell development, generation of NK cells is not affected in adult c-KitW/W mice.

Cellular and molecular pathophysiology of cutaneous drug reactions.

Hypersensitivity reactions to drugs can cause a variety of skin diseases like maculopapular, bullous and pustular eruptions. In recent years increasing evidence indicates the important role of T cells in these drug-induced skin diseases. Analysis of such drug-specific T cell clones has revealed that drugs can be recognized by alpha beta-T cell receptors, not only if bound covalently to peptides, but also if the drug binds in a rather labile way to the presenting major histocompatibility complex (MHC)-peptide. This presentation is sufficient to stimulate T cells. In maculopapular exanthema (MPE), histopathological analysis typically shows a dominant T cell infiltration together with a vacuolar interface dermatitis. Immunohistochemical studies demonstrate the presence of cytotoxic CD4+ and to a lesser degree of CD8+ T cells, which contain perforin and granzyme B. They are close to keratinocytes that show signs of cell destruction. Expression of Fas ligand is barely detectable, suggesting that cytotoxic granule exocytosis may be the dominant pathway leading to keratinocyte cell damage. While in MPE, the killing of cells seems to be predominantly mediated by CD4+ T cells, patients with bullous skin disease show a strong CD8+ T cell migration to the epidermis. This is probably due to a preferential presentation of the drug by MHC class I molecules, and a more extensive killing of cells that present drugs on MHC class I molecules. This might lead to bullous skin diseases. In addition to the presence of cytotoxic T cells, drug-specific T cells also orchestrate the inflammatory skin reaction through the release and induction of various cytokines [i.e. interleukin (IL)-5, IL-6, tumor necrosis factor-alpha and interferon-gamma] and chemokines (RANTES, eotaxin or IL-8). The increased expression of these mediators seems to contribute to the generation of tissue and blood eosinophilia, a hallmark of many drug-induced allergic reactions. However, in acute generalized exanthematous pustulosis (a peculiar form of drug allergy), neutrophils represent the predominant cell type within pustules, probably due to their recruitment by IL-8 secreting drug specific T cells and keratinocytes.

Establishment of animal model of antigen-specific T lymphocyte recruitment into nasal mucosa

DO11.10 transgenic mice, expressing an ovalbumin (OVA)-specific alphabeta T-cell receptor (TCR), have been used as a model of various immune diseases associated with T lymphocytes. Some studies of immunoresponse in lung have involved adoptive transfer of DO11.10 mice. As of yet, however, there have been no studies of the adoptive transfer model in the upper airway. The purpose of this study was to establish an animal model to clarify the recruitment mechanism and the roles of Th2 cells in allergic rhinitis. In accordance with the adoptive transfer system, we generated Th0, Th1 and Th2 cells from DO11.10 mice and transferred them into wild type BALB/c mice. Following nasal OVA challenge to DO11.10 mice or to the BALB/c mice into which antigen-specific Th2 cells had been transferred, the number of local antigen-specific TCR-positive cells accompanying the local eosinophilia had significantly increased. However, nasal OVA challenge to BALB/c mice into which antigen-specific Th0 or Th1 cells were transferred failed to increase the number of local OVA-specific TCR positive cells. These observations suggest that an antigen-specific homing mechanism of Th2 cells may exist in nasal mucosa. Analysis of this model will assist in the development of new therapeutic strategy, which targets Th2 cells in allergic rhinitis.

Evolution of T cell receptor (TCR) alpha beta heterodimer assembly with the CD3 complex.

T cell antigen receptors (TCR) are composed of an antigen-recognizing unit, the TCRalpha beta heterodimer, and a signal transduction ensemble, the CD3 complex. Whereas mammals possess three CD3 dimers (delta epsilon, gamma epsilon, and zeta2), birds and amphibians have only two (delta/gamma-epsilon and zeta2). To understand evolutionary changes in TCR/CD3 assembly,a phylogenetic approach was employed to dissect the interaction of TCRalpha beta heterodimers with the CD3 components. While sheep and mouse TCRalpha and TCRbeta chains could replace the corresponding human chains in mutant human T cells to restore surface TCR/CD3 expression and function, chicken TCRalpha, TCRbeta and CD3delta/gamma chains were unable to replace the corresponding human chains in forming a chimeric TCR/CD3 complex. The inability of chicken TCR/CD3 components to replace the human molecules in T cells was found to result from the lack of interaction between chicken TCRalpha beta heterodimers and the human CD3 complex. In contrast, if no CD3 molecules are present (non-T cells), TCRalpha -TCRbeta chain pairing can take place in an apparently non-controlled way. Thus, the TCR-CD3 interactions have changed with the evolutionary divergence of two mammalian CD3gamma and CD3delta genes from a single prototypic chicken delta/gamma gene. Our data suggest that the structures in mammalian TCR.C regions, which distinguish between CD3delta and CD3gamma chains, have evolved with the appearance of two separate CD3delta and CD3gamma functions.