NK1.1+ CD4+ CD8- thymocytes with specific lymphokine secretion

Mouse CD8+ CD122+ T cells with intermediate TCR increasing with age provide a source of early IFN-gamma production

Although CD8+ IL-2Rbeta (CD122)+ T cells with intermediate TCR reportedly develop extrathymically, their functions still remain largely unknown. In the present study, we characterized the function of CD8+ CD122+ T cells with intermediate TCR of C57BL/6 mice. The proportion of CD8+ CD122+ T cells in splenocytes gradually increased with age, whereas CD8+ IL-2Rbeta-negative or -low (CD122-) T cells conversely decreased. The IFN-gamma production from splenocytes stimulated with immobilized anti-CD3 Ab in vitro increased with age, whereas the IL-4 production decreased. When sorted CD8+ CD122+ T cells were stimulated in vitro by the anti-CD3 Ab, they promptly produced a much larger amount of IFN-gamma than did CD8+ CD122- T cells or CD4+ T cells, whereas only CD4+ T cells produced IL-4. The depletion of CD8+ CD122+ T cells from whole splenocytes greatly decreased the CD3-stimulated IFN-gamma production and increased the IL-4 production, whereas the addition of sorted CD8+ CD122+ T cells to CD8+ CD122+ T cell-depleted splenocytes restored the IFN-gamma production and partially decreased IL-4 production. It is of interest that CD8+ CD122+ T cells stimulated CD4+ T cells to produce IFN-gamma. The CD3-stimulated IFN-gamma production from each T cell subset was augmented by macrophages. Furthermore, CD3-stimulated CD8+ CD122+ T cells produced an even greater amount of IFN-gamma than did liver NK1.1+ T cells and also showed antitumor cytotoxicity. These results show that CD8+ CD122+ T cells may thus be an important source of early IFN-gamma production and are suggested to be involved in the immunological changes with aging.

The mouse tumor cell lines EL4 and RMA display mosaic expression of NK-related and certain other surface molecules and appear to have a common origin

As a potential means for facilitating studies of NK cell-related molecules, we examined the expression of these molecules on a range of mouse tumor cell lines. Of the lines we initially examined, only EL4 and RMA expressed such molecules, both lines expressing several members of the Ly49 and NKRP1 families. Unexpectedly, several of the NK-related molecules, together with certain other molecules including CD2, CD3, CD4, CD32, and CD44, were often expressed in a mosaic manner, even on freshly derived clones, indicating frequent switching in expression. In each case examined, switching was controlled at the mRNA level, with expression of CD3zeta determining expression of the entire CD3-TCR complex. Each of the variable molecules was expressed independently, with the exception that CD3 was restricted to cells that also expressed CD2. Treatment with drugs that affect DNA methylation and histone acetylation could augment the expression of at least some of the variable molecules. The striking phenotypic similarity between EL4 and RMA led us to examine the state of their TCRbeta genes. Both lines had identical rearrangements on both chromosomes, indicating that RMA is in fact a subline of EL4. Overall, these findings suggest that EL4 is an NK-T cell tumor that may have retained a genetic mechanism that permits the variable expression of a restricted group of molecules involved in recognition and signaling.

CD1d structure and regulation on human thymocytes, peripheral blood T cells, B cells and monocytes

Human T cells expressing CD161 and an invariant T-cell receptor (TCR) alpha-chain (Valpha24invt T cells) specifically recognize CD1d and appear to have immunoregulatory functions. However, the physiological target cells for this T-cell population, and whether alterations in CD1d expression contribute to the regulation of Valpha24invt T-cell responses, remain to be determined. A series of antibodies were generated to assess CD1d expression, structure and regulation on human lymphoid and myeloid cells. CD1d was expressed at high levels by human cortical thymocytes and immunoprecipitation analyses showed it to be a 48 000-MW glycosylated protein. However, after solubilization, the majority of the thymocyte CD1d protein, but not CD1d expressed by transfected cells, lost reactivity with monoclonal antibodies (mAbs) against native CD1d, indicating that it was alternatively processed. Moreover, thymocytes were not recognized by CD1d-reactive Valpha24invt T-cell clones. Medullary thymocytes and resting peripheral blood T cells were CD1d-, but low-level CD1d expression was induced on activated T cells. CD1d was expressed by B cells in peripheral blood and lymph node mantle zones, but germinal centres were CD1d-. Resting monocytes were CD1d+ but, in contrast to CD1a, b and c, their surface expression of CD1d was not up-regulated by granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-4 (IL-4) activation. These results demonstrate constitutive CD1d expression by human professional antigen-presenting cells and that post-translational processing of CD1d may contribute to regulation of the activity of CD1d-specific T cells.

Analysis of human V alpha 24+ CD4+ NKT cells activated by alpha-glycosylceramide-pulsed monocyte-derived dendritic cells

Human V alpha 24+ NKT cells with an invariant TCR (V alpha 24-J alpha Q) have been shown to be specifically activated by synthetic glycolipids such as alpha-galactosylceramide and alpha-glucosylceramide in a CD1d-restricted and V alpha 24 TCR-mediated manner. We recently characterized V alpha 24+ CD4- CD8- double negative (DN) NKT cells using alpha-galactosylceramide-pulsed monocyte-derived dendritic cells. Here, we compare V alpha 24+ CD4+ NKT cells with human V alpha 24+ DN NKT cells from the same donor using alpha-galactosylceramide-pulsed monocyte-derived dendritic cells. Human V alpha 24+ CD4+ NKT cells were phenotypically and functionally similar to the human V alpha 24+ DN NKT cells characterized previously. Both of them use V alpha 24-J alpha Q-V beta 11 TCR and express CD161 (NKR-P1A), but not the other NK receptors tested so far. They also produce cytokines such as IL-4 and IFN-gamma, and, in regard to IL-4 production, V alpha 24+ CD4+ NKT cells produce more IL-4 than V alpha 24+ DN NKT cells. The cells exhibit marked cytotoxic activity against the U937 tumor cell line, but not against the NK target cell line, K562. Although at least some of the factors responsible for the stimulation of V alpha 24+ NKT cells have been clarified, little is known regarding the killing phase of these cells. Here we show that the cytotoxic activity of V alpha 24+ NKT cells against U937 cells is mediated mainly through the perforin pathway and that ICAM-1/LFA-1 as well as CD44/hyaluronic acid interactions are important for the effector phase of V alpha 24+ NKT cell-mediated cytotoxicity against U937 cells.

Evidence for human CD4+ T cells in the CD1-restricted repertoire: derivation of mycobacteria-reactive T cells from leprosy lesions

Both the CD4-CD8- (double negative) and CD4-CD8+ T cell lineages have been shown to contain T cells which recognize microbial lipid and glycolipid Ags in the context of human CD1 molecules. To determine whether T cells expressing the CD4 coreceptor could recognize Ag in the context of CD1, we derived CD4+ T cell lines from the lesions of leprosy patients. We identified three CD4+ Mycobacterium leprae-reactive, CD1-restricted T cell lines: two CD1b restricted and one CD1c restricted. These T cell lines recognize mycobacterial Ags, one of which has not been previously described for CD1-restricted T cells. The response of CD4+ CD1-restricted T cells, unlike MHC class II-restricted T cells, was not inhibited by anti-CD4 mAb, suggesting that the CD4 coreceptor does not impact positive or negative selection of CD1-restricted T cells. The CD4+ CD1-restricted T cell lines produced IFN-gamma and GM-CSF, the Th1 pattern of cytokines required for cell-mediated immunity against intracellular pathogens, but no detectable IL-4. The existence of CD4+ CD1-restricted T cells that produce a Th1 cytokine pattern suggests a contributory role in immunity to mycobacterial infection.

Cutting edge: the Ets1 transcription factor is required for the development of NK T cells in mice

Ets1-deficient mice develop B and T cells but display a severe defect in the development of the NK cell lineage. In this report, we demonstrate that Ets1 is also required for the development of NK1.1+ T (NK T) cells. We observed significantly decreased numbers of NK T cells in the thymus, spleen, and liver of Ets1-deficient mice. These organs also contained markedly decreased levels of the canonical Valpha14-Jalpha281 TCRalpha transcript seen in NK T cells. Unlike wild-type NK T cells, Ets1-deficient thymocytes failed to produce detectable levels of IL-4 following anti-CD3 stimulation. The absence of NK T cells in the Ets1-deficient mice was not associated with defective expression of CD1, an MHC class I molecule required for NK T cell development. We conclude that Ets1 defines a novel transcriptional regulatory pathway that is required for the development of both the NK and NK T cell lineages.

CD4-CD8- T cells bearing invariant Valpha24JalphaQ TCR alpha-chain are decreased in patients with atopic diseases

Atopic disorders are caused by disregulated activation of T helper 2 (Th2) cells that produce IL-4 and IL-5. Because the presence of IL-4 potently augments the differentiation of naive T cells into Th2 cells, it is important to seek the cell population which provides IL-4 for naive T cells. Recently, a unique subpopulation of T cells, natural killer (NK) T cells, has been shown to produce a large amount of IL-4 upon activation, suggesting their regulatory role in initiation of Th2 cell differentiation. To determine whether NK T cells play a regulatory role in human Th2 cell-mediated atopic diseases, we analysed the frequency of invariant Valpha24JalphaQ CD4-CD8- double-negative (DN) T cells, human NK T cells, in patients with atopic asthma and atopic dermatitis. We also studied cytokine production from Valpha24+ Vbeta11+ DN T cells, which comprise most of Valpha24JalphaQ DN T cells. We found that the invariant Valpha24JalphaQ DN T cells were greatly diminished in patients with asthma and atopic dermatitis. On the other hand, there was no significant difference in Valpha24+ CD4+ T cells possessing invariant Valpha24JalphaQ TCR between healthy subjects and atopic patients. We also found that Valpha24+ Vbeta11+ DN T cells from healthy subjects predominantly produced interferon-gamma (IFN-gamma) but not IL-4 upon activation. These results suggest that NK T cells may not be essential for human atopic disease and that the disappearance of NK T cells, most of which produce IFN-gamma, may be involved in the pathogenesis of atopic diseases.

Differential tumor surveillance by natural killer (NK) and NKT cells

Natural tumor surveillance capabilities of the host were investigated in six different mouse tumor models where endogenous interleukin (IL)-12 does or does not dictate the efficiency of the innate immune response. Gene-targeted and lymphocyte subset-depleted mice were used to establish the relative importance of natural killer (NK) and NK1.1(+) T (NKT) cells in protection from tumor initiation and metastasis. In the models examined, CD3(-) NK cells were responsible for tumor rejection and protection from metastasis in models where control of major histocompatibility complex class I-deficient tumors was independent of IL-12. A protective role for NKT cells was only observed when tumor rejection required endogenous IL-12 activity. In particular, T cell receptor Jalpha281 gene-targeted mice confirmed a critical function for NKT cells in protection from spontaneous tumors initiated by the chemical carcinogen, methylcholanthrene. This is the first description of an antitumor function for NKT cells in the absence of exogenously administered potent stimulators such as IL-12 or alpha-galactosylceramide.

Ly49A expression on T cells alters T cell selection

Ly49 receptors are inhibitory receptors expressed on subsets of both NK cells and NK1.1(+) T cells. The function of these receptors on NK cells is believed to be important in maintaining self-tolerance, yet their role on T cells is unclear. In this report we investigated how an Ly49A transgene alters T and NK cell development in an in vivo environment, where a ligand for Ly49A is expressed. Ly49A transgenic mice that co-expressed an MHC ligand for Ly49A, H-2D(d), developed a severe inflammatory disorder that resulted in death within the first weeks of age. T cells expressing forbidden TCR V(beta) chains were found both in the thymus and periphery of transgenic mice, while non-transgenic littermates had successfully deleted these T cell subsets. These data indicate that the expression of Ly49A on T cells could alter T cell selection and allow survival of potentially self-reactive T cells.

Orally administered decoction of Kampo (Japanese herbal) medicine, "Juzen-Taiho-To" modulates cytokine secretion and induces NKT cells in mouse liver

The effects of orally administered decoction of Juzen-Taiho-To (JTT; Si-Quan-Da-Bu-Tang in Chinese) on cytokine production in hepatic lymphocytes were studied in mice. JTT was found to increase interferon gamma (IFN-gamma), as well as interleukin-4 (IL-4), IL-5 and IL-6 secretion from stimulated hepatic lymphocytes, whereas IL-2 secretion was reduced. The number of IFN-gamma- and IL-4-spot forming cells (SFC) were not changed by administration of JTT. These results suggest that modulation of cytokine secretion by JTT might not be due to changes in the number of cytokine secreting cells within liver lymphocytes. CD4/CD8 ratio and alphabeta/gammadelta T cell receptor (TCR) ratio in hepatic lymphocytes were not changed. However, flow cytometric analysis revealed that the population of CD3 positive intermediate cells in NK positive cells (NKT cells) was increased after oral administration of JTT. The population of CD3int IL-2Rbeta+ cells was also increased. The induction of NKT cells by JTT was reduced by injection of 2-chloroadenosine. JTT enhanced transcription of IL-12 mRNA in liver. From these results, it may be concluded that a rise in NKT cell population contributes, at least partially, to the modulating effect of JTT on cytokine production in liver lymphocytes, and macrophages. The production of IL-12 in liver may also contribute to this NKT induction.

Augmentation of Valpha14 NKT cell-mediated cytotoxicity by interleukin 4 in an autocrine mechanism resulting in the development of concanavalin A-induced hepatitis

The administration of concanavalin A (Con A) induces a rapid severe injury of hepatocytes in mice. Although the Con A-induced hepatitis is considered to be an experimental model of human autoimmune hepatitis, the precise cellular and molecular mechanisms that induce hepatocyte injury remain unclear. Here, we demonstrate that Valpha14 NKT cells are required and sufficient for induction of this hepatitis. Moreover, interleukin (IL)-4 produced by Con A-activated Valpha14 NKT cells is found to play a crucial role in disease development by augmenting the cytotoxic activity of Valpha14 NKT cells in an autocrine fashion. Indeed, short-term treatment with IL-4 induces an increase in the expression of granzyme B and Fas ligand (L) in Valpha14 NKT cells. Moreover, Valpha14 NKT cells from either perforin knock-out mice or FasL-mutant gld/gld mice fail to induce hepatitis, and hence perforin-granzyme B and FasL appear to be effector molecules in Con A-induced Valpha14 NKT cell-mediated hepatocyte injury.

Different influence of macrophage migration inhibitory factor (MIF) in signal transduction pathway of various T cell subsets

It has been shown that macrophage migration inhibitory factor (MIF) modulates not only macrophage functions, but also T cell functions. However, detailed analysis of the MIF function on responses of various T cell subpopulations remained to be elucidated. In this report, using a neutralizing anti-MIF monoclonal antibody (mAb) we examined MIF functions on various T cell lineages. It was shown that anti-MIF mAb inhibited antigen-specific responses of both IFN-gamma producing and IL-4 producing T cells. The inhibition appeared to be related to blockade of the signal pathway via T cell receptor (TCR) but not that via IL-2 receptor (IL-2R). However, the anti-MIF mAb showed no inhibitory effect on NK-T cell responses stimulated through TCR. These results suggest that MIF is involved in the signal pathway via TCR in mainstream T cells but not in NK-T cells.

CD56+ T cells in the peripheral blood of uveitis patients

AIMS

Natural killer T (NKT) cells, T lymphocytes expressing both T cell and NK cell markers, are suggested to be involved in autoimmune diseases. To examine the relation between the pathogenesis of uveitis and CD56+ T cells, which are thought to be a type of human NKT cells, we investigated peripheral CD56+ T cells in uveitis patients.

METHODS

41 uveitis patients (Behçet's disease (BD), 14; sarcoidosis (SAR), eight; Vogt-Koyanagi-Harada disease (VKH), five; idiopathic uveitis (IU), nine; and others, five) and 19 healthy controls participated in this study. Cell surface antigens of lymphocytes were analysed by use of monoclonal antibodies and flow cytometry.

RESULTS

The proportion of CD56+ T cells in patients with BD was higher than in controls and in patients with SAR, VKH, IU, and others.

CONCLUSION

Increased peripheral CD56+ T cells might be relevant to the pathogenesis of uveitis in BD, and increase of peripheral CD56+ T cells may be one of the laboratory findings to suggest that uveitis originates from BD.

Proportion of CD56+3+ T cells in decidual and peripheral lymphocytes of normal pregnancy and spontaneous abortion with and without history of recurrent abortion

PROBLEM

The present study investigated the proportion of CD56+3+ T cells in maternal peripheral and decidual lymphocytes in normal pregnancy and spontaneous abortion with and without history of recurrent spontaneous abortion (RSA).

METHOD OF STUDY

Maternal peripheral blood and decidua were taken from normal pregnancies and missed abortions with and without RSA. Decidual lymphocytes were prepared from decidual tissue and analyzed by flow cytometry.

RESULTS

In normal pregnancy, the percentages of CD56+3+ T cells in decidual lymphocytes did not differ from those in the peripheral blood. However, the proportion of CD56+3+ T cells in decidual CD3+ T cells increased higher than that in the peripheral CD3+ T cells. The percentages of decidual CD56+3+ T cells in missed abortions with and without RSA were lower than those in normal pregnancies.

CONCLUSION

CD56+3+ T cells may play a role in the maintenance of pregnancy. The phenomenon, where the proportion of CD56+3+ T cells in decidual lymphocytes decreases, may be due to an immunologic event leading to missed abortion.

Heterogeneity of NK1.1+ T Cells in the Bone Marrow: Divergence from the Thymus

NK1.1+ T cells in the mouse thymus and bone marrow were compared because some marrow NK1.1+ T cells have been reported to be extrathymically derived. Almost all NK1.1+ T cells in the thymus were depleted in the CD1−/−, β2m−/−, and Jα281−/− mice as compared with wild-type mice. CD8+NK1.1+ T cells were not clearly detected, even in the wild-type mice. In bone marrow from the wild-type mice, CD8+NK1.1+ T cells were easily detected, about twice as numerous as CD4+NK1.1+ T cells, and were similar in number to CD4−CD8−NK1.1+ T cells. All three marrow NK1.1+ T cell subsets were reduced about 4-fold in CD1−/− mice. No reduction was observed in CD8+NK1.1+ T cells in the bone marrow of Jα281−/− mice, but marrow CD8+NK1.1+ T cells were markedly depleted in β2m−/− mice. All NK1.1+ T cell subsets in the marrow of wild-type mice produced high levels of IFN-γ, IL-4, and IL-10. Although the numbers of marrow CD4−CD8−NK1.1+ T cells in β2m−/− and Jα281−/− mice were similar to those in wild-type mice, these cells had a Th1-like pattern (high IFN-γ, and low IL-4 and IL-10). In conclusion, the large majority of NK1.1+ T cells in the bone marrow are CD1 dependent. Marrow NK1.1+ T cells include CD8+, Vα14-Jα281−, and β2m-independent subsets that are not clearly detected in the thymus.

NKT cells are phenotypically and functionally diverse

NK1.1(+)alpha betaTCR(+) (NKT) cells have several important roles including tumor rejection and prevention of autoimmune disease. Although both CD4(+) and CD4(-)CD8(-) double-negative (DN) subsets of NKT cells have been identified, they are usually described as one population. Here, we show that NKT cells are phenotypically, functionally and developmentally heterogeneous, and that three distinct subsets (CD4(+), DN and CD8(+)) are differentially distributed in a tissue-specific fashion. CD8(+) NKT cells are present in all tissues but the thymus, and are highly enriched for CD8alpha(+)beta(-) cells. These subsets differ in their expression of a range of cell surface molecules (Vbeta8, DX5, CD69, CD45RB, Ly6C) and in their ability to produce IL-4 and IFN-gamma, with splenic NKT cell subsets producing lower levels than thymic NKT cells. Developmentally, most CD4(+) and DN NKT cells are thymus dependent, in contrast to CD8(+) NKT cells, and are also present amongst recent thymic emigrants in spleen and liver. TCR Jalpha281-deficient mice show a dramatic deficiency in thymic NKT cells, whereas a significant NKT cell population (enriched for the DN and CD8(+) subsets) is still present in the periphery. Taken together, this study reveals a far greater level of complexity within the NKT cell population than previously recognized.

Age-Associated Rapid and Stat6-Independent IL-4 Production by NK1−CD4+8− Thymus T Lymphocytes

The source of IL-4 required for priming naive T cells into IL-4-secreting effectors has not been clearly identified. Here we show that upon TCR stimulation, thymus NK1−CD4+8− T cells produced IL-4, the magnitude of which was inversely correlated with age. This IL-4 production response by Th2-prone BALB/c mice was ∼9-fold that of Th1-prone C57BL/10 mice. More than 90% of activated NK1−CD4+8− thymocytes did not use the invariant Vα14-Jα281 chain characteristic of typical CD1-restricted NK1+CD4+ T cells. Stat6-null NK1−CD4+8− thymocytes produced bioactive IL-4, with induction of IL-4 mRNA expression within 1 h of stimulation. Our results support the possibility that TCR repertoire-diverse conventional NK1−CD4+ T cells are a potential IL-4 source for directing naive T cells toward Th2/type 2 CD8+ T cell (Tc2) effector development.

The Src family tyrosine kinase Fyn regulates natural killer T cell development

T lymphocytes express two Src tyrosine kinases, Lck and Fyn. While thymocyte and T cell subsets are largely normal in fyn(-/-) mice, animals lacking Lck have impaired T cell development. Here, it is shown that Fyn is required for the rapid burst of interleukin (IL)-4 and IL-13 synthesis, which occurs promptly after T cell receptor activation. The lack of cytokine induction in fyn mutant mice is due to a block in natural killer (NK) T cell development. Studies using bone marrow chimeras indicate that the defect behaves in a cell-autonomous manner, and the lack of NK T cells is probably not caused by inappropriate microenvironmental cues. Both NK T cells and conventional T cells express similar levels of Lck, implying that Fyn and Lck have distinct roles in regulating NK T cell ontogeny. The fyn mutation defines the first signaling molecule that is selectively required for NK T cell, but not for T lymphocyte or NK cell development.

Natural killer (NK) T cells are significantly decreased in the peripheral blood of patients with rheumatoid arthritis (RA)

The number of NK T cells was measured in relation to the Th1/Th2 imbalance observed in RA. Peripheral blood samples of patients with RA (n = 60) and healthy controls (n = 36) were stained with anti-NK receptor 1A (anti-NKR-P1A), anti-CD56, and anti-CD3 MoAbs, and examined by three-colour flow cytometry. NK T (NKR-P1A+CD3+) cells in the peripheral blood were decreased in RA compared with the controls: 25 +/- 20/microl versus 143 +/- 53/microl (P < 0.0001). CD56+CD3+ cells were also decreased in RA: 60 +/- 46/microl versus 116 +/- 54/microl (P < 0.0001). The decrease was significant when adjusted to the number of total lymphocytes (P < 0.0001) or NK (CD56+CD3-) cells (P < 0.0001), and showed no correlation with age, sex, disease duration, disease activity, functional class, x-ray stage, drug treatment, joint score, grip strength, C-reactive protein, rheumatoid factor or erythrocyte sedimentation rate of the patients. The results show that the levels of NK T cells are depressed in the peripheral blood of patients with RA, suggesting that the measurement of NK T cells in peripheral blood may have clinical importance for a Th1-type autoimmune disease like RA.

Thymic dependence of invariant V alpha 14+ natural killer-T cell development

Both thymic and extrathymic bone marrow (BM)-derived pathways for the development of CD1 reactive, Valpha14-Jalpha281(+) NK1.1(+) T cells have been suggested. In this report, we sought evidence for extrathymic NK-T cell development using two approaches. First, BM cells from gammac-deficient mice were examined for the presence of Valpha14-Jalpha281 transcripts. Since intrathymic NK-T cell selection is gammac independent, we predicted that gammac(-) BM cells should also harbor these specific TCRalpha chains. Second, Valpha14-Jalpha281 transcripts were analyzed in BM cells from lethally irradiated, thymectomized mice reconstituted with fetal liver hematopoietic precursors. All donor-derived T cell development in these chimeras is by definition extrathymic. In both cases, we failed to detect invariant Valpha14(+) TCRalpha chain transcripts. These experiments call into question the significance of an extrathymic pathway of development for Valpha14(+) NK1.1(+) CD1-reactive T cells.

Identification of a New Type of Invariant Vα14+ T Cells and Responsiveness to a Superantigen, Yersinia pseudotuberculosis- Derived Mitogen

We examined the expression of the H4 T cell activation marker in thymic T cell subpopulations and found that TCR-αβ+ CD4+ thymic T cells are segregated into three subpopulations based upon H4 levels. Thymic T cells with either no or low H4 expression differentiate via the mainstream differentiation pathway in the thymus. H4int thymic T cells, which express a skewed Vβ repertoire of Vβ2, -7, and -8 in their TCRs, show the phenotype of NKT cells: CD44high, Ly6Chigh, NK1.1+, and TCR-αβlow. H4high thymic T cells also show a skewed Vβ repertoire, Vβ2, -7, and -8, and predominantly express an invariant Vα14-Jα281+ α-chain in their TCRs but constitute a distinct population in that they are CD44int, Ly6C−, NK1.1−, and TCR-αβhigh. Thus, invariant Vα14+ thymic T cells consist of ordinary NKT cells and a new type of T cell population. Vβ7+ and Vβ8.1+ invariant Vα14+ thymic T cells are present in DBA/2 mice, which carry mammary tumor virus-7-encoded superantigens, in comparable levels to those in BALB/c mice. Furthermore, Vβ7+ invariant Vα14+ thymic T cells in DBA/2 mice are in the immunologically responsive state, and Yersinia pseudotuberculosis-derived mitogen-induced Vβ7+ invariant Vα14+ thymic T cell blasts from DBA/2 and BALB/c mice exhibited equally enhanced responses upon restimulation with Y. pseudotuberculosis-derived mitogen. Thus, invariant Vα14+ thymic T cells that escape negative selection in DBA/2 mice contain T cells as functionally mature as those in BALB/c mice.

IL-4-Producing γδ T Cells That Express a Very Restricted TCR Repertoire Are Preferentially Localized in Liver and Spleen

IL-4-producing γδ thymocytes in normal mice belong to a distinct subset of γδ T cells characterized by low expression of Thy-1. This γδ thymocyte subset shares a number of phenotypic and functional properties with the NK T cell population. Thy-1dull γδ thymocytes in DBA/2 mice express a restricted repertoire of TCRs that are composed of the Vγ1 gene product mainly associated with the Vδ6.4 chain and exhibit limited junctional sequence diversity. Using mice transgenic for a rearranged Vγ1Jγ4Cγ4 chain and a novel mAb (9D3) specific for the Vδ6.3 and Vδ6.4 murine TCRδ chains, we have analyzed the peripheral localization and functional properties of γδ T cells displaying a similarly restricted TCR repertoire. In transgenic mice, IL-4 production by peripheral γδ T cells was confined to the γδ+9D3+ subset, which contains cells with a TCR repertoire similar to that found in Thy-1dull γδ thymocytes. In normal DBA/2 mice such cells represent close to half of the γδ T cells present in the liver and around 20% of the splenic γδ T cells.

Regulatory Role of Peritoneal NK1.1+αβ T Cells in IL-12 Production During Salmonella Infection

NK1.1+αβ T cells emerge in the peritoneal cavity after an i.p. infection with Salmonella choleraesuis in mice. To elucidate the role of the NK1.1+αβ T cells during murine salmonellosis, mice lacking NK1.1+αβ T cells by disruption of TCRβ (TCRβ−/−), β2m (β2m−/−), or Jα281 (Jα281−/−) gene were i.p. inoculated with S. choleraesuis. The peritoneal exudate T cells in wild type (wt) mice on day 3 after infection produced IL-4 upon TCRαβ stimulation, whereas those in TCRβ−/−, β2m−/−, or Jα281−/− mice showed no IL-4 production upon the stimulation, indicating that NK1.1+αβ T cells are the main source of IL-4 production at the early phase of Salmonella infection. Neutralization of endogenous IL-4 by administration of anti-IL-4 mAb to wt mice reduced the number of Salmonella accompanied by increased IL-12 production by macrophages after Salmonella infection. The IL-12 production by the peritoneal macrophages was significantly augmented in mice lacking NK1.1+αβ T cells after Salmonella infection accompanied by increased serum IFN-γ level. The aberrantly increased IL-12 production in infected TCRβ−/− or Jα281−/− mice was suppressed by adoptive transfer of T cells containing NK1.1+αβ T cells but not by the transfer of T cells depleted of NK1.1+αβ T cells or T cells from Jα281−/− mice. Taken together, it is suggested that NK1.1+αβ T cells eliciting IL-4 have a regulatory function in the IL-12 production by macrophages at the early phase of Salmonella infection.

NKT cell cytokine imbalance in murine diabetes mellitus

A minor subset of murine MHC class I-restricted T cells which express both the alphabeta form of the T cell receptor and a NK lineage marker, termed NKT cells, is capable of secreting significant amounts of Interleukin-4 and Interferon-y upon activation. As such NKT cells may play a role in development of Th1 and Th2 cells during T cell ontogeny or expansion of T cells expressing a dominant cytokine pattern in the effector phase. We have studied the role of NKT cells in a murine model of disease multidose streptozotocin induced diabetes mellitus (MDSDM). In MDSDM thymic and splenic NKT cells are present at normal levels but have greatly reduced capacity to secrete Interleukin-4 upon stimulation with anti-TCR antibody compared to control mice; conversely, Interferon-y secretion is maintained. By analysis of cytokine RNA production we found that treatment of several strains of mice with streptozotocin changes the peripheral helper T cell phenotype elicited after immunization with Keyhole Limpet Hemocyanin from a mixed Th1- and Th2-type cytokine pattern (characterized by IFN-gamma and IL-4 and IL-5 expressions, respectively) to predominately Th1-type. Furthermore, susceptibility to MDSDM is significantly enhanced when NKT cells are selectively eliminated in vivo by administration of depleting anti-CD122 antibody TMbeta-1. In addition, antibody depletion of NKT cells from non-obese diabetic mice significantly accelerates onset of disease. Collectively these data support a model for development of murine diabetes mellitus in which NKT cell cytokine expression influences the development of Th1-type diabetogenic T cells.

Inhibition of concanavalin A-induced hepatic injury of mice by bacterial lipopolysaccharide via the induction of IL-6 and the subsequent reduction of IL-4: the cytokine milieu of concanavalin A hepatitis

BACKGROUND/AIMS

Liver natural killer 1.1 antigen (NK1)+ T cells and IL-4 play a crucial role in concanavalin-A (Con-A)-induced hepatic injury in mice, and a T helper (Th) 2 immune response was thus suggested to be involved. This study was designed to examine the effect of bacterial lipopolysaccharide (LPS), a strong inducer of a Th 1 immune response, on Con-A hepatic injury and also to clarify further the cytokine milieu of Con-A hepatitis.

METHODS

LPS were injected into mice before Con-A injection to evaluate the effect on hepatic injury. The effect of the pretreatment with various T1 and Th2 cytokines or anti-cytokine antibodies on Con-A hepatitis was also examined.

RESULTS

LPS in quantities > or = 500 ng/mouse, when injected 24 h before Con-A injection, abrogated the Con-A-induced elevation of transaminases, hepatocyte destruction and serum IL-4 elevation. This LPS inhibitory effect was blocked when the mice were injected with either anti-IL-6 antibody before LPS injection or IL-4 before Con-A injection. IL-6, but neither IL-10 nor IL-12 pretreatment suppressed Con-A-induced IL-4 production and hepatitis. NK1+ T cells produced IL-4 while both NK1+ T cells and NK1- T cells produced IFN-gamma. Not only anti-IL-4 antibody but also the anti-IFN-gamma antibody pretreatment inhibited Con-A hepatitis. However, although the anti-IL4 antibody suppressed IL-4 alone, the anti-IFN-gamma Ab unexpectedly inhibited both IFN-gamma and IL-4 elevation, while IL-4 injection evoked a moderate Con-A hepatitis even in the anti-IFN-gamma antibody-treated mice. Furthermore, the IL-4 mutant mice did not develop Con-A hepatitis.

CONCLUSION

LPS inhibited Con-A hepatitis by inducing IL-6 and thereby inhibited IL-4 synthesis from NK1+ T cells. Although both IL-4 and IFN-gamma were required for the full induction of Con-A hepatic injury, exogenous IL-4 evoked a moderate Con-A hepatitis, even in the absence of IFN-gamma.

Functional and phenotypical characteristics of hepatic NK-like T cells in NK1.1-positive and -negative mouse strains

We previously reported and partially characterized a unique monoclonal antibody (mAb), U5A2-13, which recognizes a T cell subset similar to NK1.1+ T cells, not only in NK1.1-positive mouse strains but also in NK1.1-negative strains. In NK1.1-positive C57BL/6 mice, U5A2-13+ TCRalphabeta+ cells produced abundant IL-4 as well as extremely high levels of IFN-gamma upon CD3 cross-linking, but this did not occur with U5A2-13- TCRalphabeta+ cells. In NK1.1-negative C3H/He mice, U5A2-13+ TCRalphabeta+ cells produced high levels of IL-4 and IFN-gamma upon CD3 cross-linking, but this was not observed with U5A2-13- TCRalphabeta+ cells. To the best of our knowledge, this is the first direct evidence of the presence of NK-like T cells defined phenotypically by U5A2-13 mAb and functionally by IL-4/IFN-gamma production in NK1.1-negative mouse strains. We also demonstrated that U5A2-13- NK1.1+ T cells and U5A2-13+ NK1.1- T cells in C57BL/6 mice could produce both IL-4 and IFN-gamma. In addition, Vbeta8 or Vbeta7 usage by U5A2-13+ NK1.1- T cells was lower than that by U5A2-13+ NK1.1+ T cells, but remained higher than that by U5A2-13- NK1.1- T cells. Based on the present results, U5A2-13 mAb appears to be a valuable tool in the study of NK-like T cells.

Human parathymic lymph node: morphological and functional significance

Parathymic lymph nodes (PTLNs) have been identified in several species, but in humans they have been noted only once before in a study 90 years ago using fetal material. We now report their occurrence in children. Human PTLNs are small but distinctive lymphatic organs located on the surface of the thymus (or sometimes between the upper and lower lobes of the thymus) and covered with the thymic capsule. Histologically, the medullary cords of these lymph nodes were found to be thin, with only small numbers of plasma cells. In addition, they had a well-developed paracortical area rich with high endothelial venules (HEV), but a thin cortex, including only a few undeveloped follicles. Flow cytometric analysis of PTLNs revealed that the ratios of T:B cells (14.6+/-9.3) and of CD4+:CD8+ T cells (4.9+/-1.4) in PTLNs were much higher than in other peripheral lymphoid tissues and in peripheral blood. Because of these characteristics of the human PTLNs, we propose that the human PTLNs might influence the functional differentiation of T cells.

Characterization of subpopulations of T-cell receptor intermediate (TCRint) T cells

CD1-autoreactive T cells of two types have been demonstrated among T cells expressing the T-cell receptor (TCR) alphabeta at intermediate levels (TCRint cells). One type constitutes a major fraction of the natural killer (NK)1.1+ TCRint population in C57BL/6 (B6) mice and carries a restricted TCR composed of an alpha-chain with an invariant Valpha14-J281 rearrangement, and a beta-chain using Vbeta8. 2, 7 or 2. The second type utilises a variety of TCR and was derived from CD4+ cells in mice lacking MHC class II. To increase our understanding of the two different CD1-reactive subsets, we have investigated and compared the populations of origin: NK1.1+ and NK1. 1- TCRint subsets from MHC class II-deficient mice and CD4+NK1.1+ T cells from B6 mice. The three TCRint populations shared a phenotype indicating previous activation, and contained low frequencies of cells expressing NK receptors of the Ly49 family. In contrast to control CD4+ cells, the three TCRint subsets produced high amounts of interleukin (IL)-4 and interferon (IFN)-gamma after activation. Importantly, no IL-10 could be detected in either TCRint population, implying a distinct function for these cells, different from those of conventional CD8+ and CD4+ cells, including the typical T-helper 2 (Th2) cell. Analysis of TCR expression indicated that the proportion of cells using the semi-invariant Valpha14/Vbeta8.2-type TCR was lower in NK1.1+ cells from MHC class II-negative mice than in CD4+NK1.1+ B6 cells. Further, usage of the Valpha14-J281 rearrangement was also demonstrated among NK1.1- TCRint cells.

Splenic NK1.1-Negative, TCRαβ Intermediate CD4+ T Cells Exist in Naive NK1.1 Allelic Positive and Negative Mice, with the Capacity to Rapidly Secrete Large Amounts of IL-4 and IFN-γ Upon Primary TCR Stimulation

Splenic NK1.1+CD4+ T cells that express intermediate levels of TCRαβ molecules (TCRint) and the DX5 Ag (believed to identify an equivalent population in NK1.1 allelic negative mice) possess the ability to rapidly produce high quantities of immunomodulatory cytokines, notably IL-4 and IFN-γ, upon primary TCR activation in vivo. Indeed, only T cells expressing the NK1.1 Ag appear to be capable of this function. In this study, we demonstrate that splenic NK1.1-negative TCRintCD4+ T cells, identified on the basis of FcγR expression, exist in naive NK1.1 allelic positive (C57BL/6) and negative (C3H/HeN) mice with the capacity to produce large amounts of IL-4 and IFN-γ after only 8 h of primary CD3 stimulation in vitro. Furthermore, a comparison of the amounts of early cytokines produced by FcγR+CD4+TCRint T cells with NK1.1+CD4+ or DX5+CD4+TCRint T cells, simultaneously isolated from C57BL/6 or C3H/HeN mice, revealed strain and population differences. Thus, FcγR defines another subpopulation of splenic CD4+TCRint cells that can rapidly produce large concentrations of immunomodulatory cytokines, suggesting that CD4+TCRint T cells themselves may represent a unique family of immunoregulatory CD4+ T cells whose members include FcγR+CD4+ and NK1.1/DX5+CD4+ T cells.

Effect of C-C chemokine receptor 2 (CCR2) knockout on type-2 (schistosomal antigen-elicited) pulmonary granuloma formation: analysis of cellular recruitment and cytokine responses

Monocyte chemotactic protein (MCP)-1 is postulated to play a role in cellular recruitment during inflammatory reactions. C-C chemokine receptor 2 (CCR2) is considered the major G-protein coupled receptor for MCP-1/JE. We reported that mice with knockout of the CCR2 gene display partially impaired type-1 granuloma formation. The present study similarly examined the effect of CCR2 deficiency on synchronously developing type-2 (Th2) cytokine-mediated lung granulomas elicited by embolization of beads coated with Ags of Schistosoma mansoni eggs. Systemically, blood monocytes were reduced by about half throughout the 8-day study period. At the local level, granuloma size and macrophage content were impaired during the early growth phase (days 1 to 2). By day 4, granuloma sizes were similar to controls. In granulomatous lungs, CCR2 knockout increased mRNA for CCR2 agonists, MCP-1, MCP-3, and MCP-5, but reduced IL-4 and IFNgamma mRNA. The latter was possibly related to decreased CD4+ T cell recruitment. Regionally, draining lymph nodes showed panlymphoid hyperplasia with impaired production of IFNgamma, IL-2, and IL-4, but not IL-5, IL-10, or IL-13. Analysis of procollagen gene expression indicated transient impairment of procollagen III transcripts on day 4 of granuloma formation. These findings indicate that agonists of CCR2 contribute to multiple facets of type-2 hypersensitivity granulomatous inflammation.

Expression of CD1d2 on Thymocytes Is Not Sufficient for the Development of NK T Cells in CD1d1-Deficient Mice

CD1 is an MHC class I-like molecule that has been conserved throughout mammalian evolution. Unlike MHC class I molecules, CD1 can present unique nonprotein antigens to T cells. The murine CD1 locus contains two highly homologous genes, CD1d1 and CD1d2. CD1d1 is essential for the development of a major subset of NK T cells that promptly secrete IL-4 following activation. However, the function of CD1d2 has not yet been demonstrated. In the present study, we examined the expression of CD1d2 in CD1d1-deficient (CD1d1°) mice with the anti-CD1 Ab 3H3. Unlike CD1d1, which is expressed by all lymphocytes, CD1d2 can be detected only on the surface of thymocytes. To determine whether CD1d2 can select a unique subset of NK T cells, we compared the remnant population of NK T cells in CD1d1° and CD1d1, CD1d2-double deficient (CD1d1°CD1d2°) mice. No significant difference in the number of NK T cells and cytokine secretion capacity can be detected between CD1d1° and CD1d1°CD1d2° mice, indicating that CD1d2 cannot substitute for CD1d1 in NK T cell development. The inability of CD1d2 to select NK T cells is not due to the structural constraints of CD1d2 since CD1d2-transfected cells can be recognized by both NK T cell hybridomas and freshly isolated NK T cells. Given the structural similarities, it is possible that the low levels of surface expression and limited tissue distribution of CD1d2 may prevent it from functioning in the selection and expansion of NK T cells.

Bone marrow NK1.1(-) and NK1.1(+) T cells reciprocally regulate acute graft versus host disease

Sorted CD4(+) and CD8(+) T cells from the peripheral blood or bone marrow of donor C57BL/6 (H-2(b)) mice were tested for their capacity to induce graft-versus-host disease (GVHD) by injecting the cells, along with stringently T cell-depleted donor marrow cells, into lethally irradiated BALB/c (H-2(d)) host mice. The peripheral blood T cells were at least 30 times more potent than the marrow T cells in inducing lethal GVHD. As NK1.1(+) T cells represented <1% of all T cells in the blood and approximately 30% of T cells in the marrow, the capacity of sorted marrow NK1.1(-) CD4(+) and CD8(+) T cells to induce GVHD was tested. The latter cells had markedly increased potency, and adding back marrow NK1.1(+) T cells suppressed GVHD. The marrow NK1.1(+) T cells secreted high levels of both interferon gamma (IFN-gamma) and interleukin 4 (IL-4), and the NK1.1(-) T cells secreted high levels of IFN-gamma with little IL-4. Marrow NK1.1(+) T cells obtained from IL-4(-/-) rather than wild-type C57BL/6 donors not only failed to prevent GVHD but actually increased its severity. Together, these results demonstrate that GVHD is reciprocally regulated by the NK1.1(-) and NK1.1(+) T cell subsets via their differential production of cytokines.

Differentiation of human single-positive fetal thymocytes in vitro into IL-4- and/or IFN-gamma-producing CD4+ and CD8+ T cells

In this study we have investigated the capacity of human fetal thymocytes to differentiate in vitro into subsets of T cells with polarized Th1 or Th2 cytokine profiles. Stimulation of freshly isolated human fetal thymocytes with anti-CD3 mAb, cross-linked onto CD32,CD58,CD80-expressing mouse fibroblasts and subsequent culture in the presence of exogenous rIL-2 for 6 days, induced the production of both IL-4 and IFN-gamma, which was mainly produced by CD4+ single-positive (SP) and CD8+ SP cells respectively. Addition of rIL-4 during priming augmented IL-4 production in cultures of human fetal thymocytes, which was mainly due to an increased production of IL-4 by CD8SP cells. In contrast, addition of IL-4 to the cultures only slightly enhanced IL-4 production and had little effect on frequencies of IL-4-producing CD4SP cells. Both CD4SP and CD8SP cells produced IL-5, IL-10 and IL-13 at comparable levels, following priming in the presence of rIL-4. Priming in the presence of rIL-12 strongly enhanced the production of IFN-gamma in both CD4SP and CD8SP cells. No correlation between expression of CD27, CD30 and CD60, and a particular cytokine profile of differentiated thymocytes could be demonstrated. Together, these results demonstrate the full capacity of fetal human thymocytes to differentiate into cytokine-producing T cells in a priming milieu with appropriate stimulatory molecules and exogenous cytokines. In addition, CD4SP thymocytes rapidly differentiate into polarized Th2 cells following stimulation in vitro in the absence of exogenous rIL-4.

Cutting Edge: LFA-1 Is Required for Liver NK1.1+TCRαβ+ Cell Development: Evidence That Liver NK1.1+TCRαβ+ Cells Originate from Multiple Pathways

Using mice deficient for LFA-1, CD44, and ICAM-1, we examined the role of these adhesion molecules in NK1.1+TCRαβ+ (NKT) cell development. Although no defect in NKT cell development was observed in CD44−/− and ICAM-1−/− mice, a dramatic reduction of liver NKT cells was observed in LFA-1−/− mice. Normal numbers of NKT cells were present in other lymphoid organs in LFA-1−/− mice. When LFA-1−/− splenocytes were injected i.v. into wild-type mice, the frequency of NKT cells among donor-derived cells in the recipient liver was normal. In contrast, when LFA-1−/− bone marrow (BM) cells were injected i.v. into irradiated wild-type mice, the frequency of liver NKT cells was significantly lower than that of mice injected with wild-type BM cells. Collectively, these data indicate that LFA-1 is required for the development of liver NKT cells, rather than the migration to and/or subsequent establishment of mature NKT cells in the liver.

MHC Class II-Dependent NK1.1+ γδ T Cells Are Induced in Mice by Salmonella Infection

We observed the emergence of a novel population of γδ T cells expressing NK1.1 Ag in the peritoneal cavity of mice infected with Salmonella choleraesuis. The NK1.1+γδ T cells accounted for approximately 20% of all γδ T cells emerging in the peritoneal cavity of C57BL/6 mice and expressed preferentially rearranged Vγ4-Jγ1 and Vδ6.3-Dδ1-Dδ2-Jδ1 genes with N diversity. The γδ T cells proliferated vigorously in response to PHA-treated spleen cells and produced IFN-γ in the culture supernatant. However, spleen cells from Aβb-deficient mice were unable to stimulate the γδ T cells. Furthermore, the NK1.1+γδ T cells were stimulated not only by Chinese hamster ovary (CHO) cells expressing wild-type IAb but also by those expressing IAb/Eα52-68 or IAb/pigeon cytochrome c-derived analogue peptide complex. These proliferation activities were inhibited by mAb specific for IAb chain. Consistent with these findings, the emergence of NK1.1+γδ T cells was reduced in the peritoneal cavity of Aβb-deficient mice after Salmonella infection, whereas NK1.1+γδ T cells were rather abundant in the peritoneal cavity of Salmonella-infected β2m-deficient mice. Moreover, the NK1.1+γδ T cells were easily identified in the thymus of β2m-deficient but not Aβb-deficient mice. Our results indicated that MHC class II expression is essential for development and activation of NK1.1+γδ T cells in the thymus and the periphery.

Induction of IFN-gamma-producing CD4+ natural killer T cells by Mycobacterium bovis bacillus Calmette Guérin

The CD4+ natural killer (NK)T cells in the liver are potent IL-4 producers and hence may promote Th2 cell development. Following Mycobacterium bovis bacillus Calmette Guérin (BCG) infection, IL-4-producing CD4+ NKT cells become undetectable in liver mononuclear cells of normal density (interface between 40 and 70% Percoll) by flow cytometry. The present study shows that M. bovis BCG infection changes the density of liver CD4+ NKT cells and shifts cytokine production from IL-4 to IFN-gamma. The number of CD4+ NK1+ TCR alpha/beta(intermediate) cells increased in the low-density fraction (<40% Percoll density gradient) in parallel to the reduction of this cell population in the fraction of normal density. The number of IL-4-producing cells, however, was small and high frequencies of IFN-gamma-secreting cells were identified in the low-density fraction after TCR/CD3 ligation. Accordingly, selected low-density CD4+ NKT cells encompassed high numbers of IFN-gamma producers and minute numbers of IL-4-secreting cells. Induction of low-density CD4+ NKT cells by M. bovis BCG was abrogated by endogenous IL-12 neutralization which also caused increased bacterial growth in the liver. We assume that M. bovis BCG infection changes cytokine secretion by the CD4+ NKT cell population from IL-4 to IFN-gamma through IL-12 induction. Thus, CD4+ NKT cells may contribute to host resistance against intracellular bacteria prior to conventional IFN-gamma-producing Th1 cells.

The homogeneity of the TCRdelta repertoire expressed by the Thy-1dull gammadelta T cell population is due to cellular selection

Thy-1dull gammadelta T cells are an unusual subset of mature TCRgammadelta T cells characterized by their highly restricted TCR repertoire. In DBA/2 mice, they predominantly express the product of the Vgamma1 gene together with that of a member of the Vdelta6 subfamily (the Vdelta6.4 gene) and their junctional sequences show very little diversity. To address the mechanisms underlying the expression of the restricted TCRgammadelta repertoire, we have cloned all Vdelta6 subfamily members present in DBA/2 mice and studied their frequency of expression in Thy-1dull and Thy-1bright gammadelta thymocyte populations. Furthermore, we have also cloned non-functional Vdelta6DdeltaJdelta1 rearrangements present in the Thy-1dull gammadelta T cell population and compared their Vdelta6 gene utilization and their junctional sequences with those expressed by this population. Our results indicate that the restricted TCRdelta repertoire expressed by the Thy-1dull gammadelta thymocytes results from cellular selection, rather than molecular constraints suggesting the existence of a limited set of self-ligands. Finally, phenotypic, functional and TCRgammadelta repertoire analysis of Thy-1dull gammadelta T cells in beta2-microglobulin (beta2m)-deficient mice indicated that these putative ligands are not beta2m-dependent major histocompatibility complex class I or class I-like molecules.

A population of CD62Llow Nk1.1- CD4+ T cells that resembles NK1.1+ CD4+ T cells

In MHC class II-/- C57BL/6 (II-/-) mouse spleen, a small population of CD4+ T cells is present of which NK1.1+ CD4+ (NK) T cells comprise 40 to 45%. We report here that many of the NK1.1- CD4+ T cells derived from II-/- mice are also NK T cells. They produce large amounts of IL-4 in response to anti-CD3 ligation and do so without any requirement for the presence of IL-4 in the priming culture, a property characteristic of NK T cells. Their IFN-gamma production is large and is enhanced by IL-12. In addition, II-/- NK1.1- CD4+ T cells produce IL-4 as a result of culture with L cells expressing murine CD1 (L-CD1). We report that CD49b, a component of integrin VLA-2, is expressed on the majority of both NK1.1+ and NK1.1- NK T cells. NK1.1- NK T cells also exist in wild-type C57BL/6 mice. Evidence supporting this is that Vbeta8 usage by CD62Llow NK1.1- CD4+ T cells was approximately 5% higher than that by CD62Lhigh CD4+ T cells in wild-type mice in keeping with the estimated proportion of NK1.1- NK T cells in the CD62Llow population. CD62Llow CD4+ T cells from beta2-m(-/-) mice, which lack NK T cells, showed no increase in Vbeta8 usage. When activated by anti-CD3 or L-CD1, CD62Llow NK1.1- CD4+ T cells from conventional but not beta2-m(-/-) and CD1-/- mice produce IL-4 in a manner indistinguishable from II-/- NK1.1- CD4+ T cells. NK1.1- NK T cells in normal mouse spleens are approximately as numerous as NK1.1+ NK T cells.

Mature Mainstream TCRαβ+CD4+ Thymocytes Expressing L-Selectin Mediate “Active Tolerance” in the Nonobese Diabetic Mouse

Pathogenic autoreactive T lymphocytes are mediators of spontaneous insulin-dependent diabetes in nonobese diabetic (NOD) mice. This is demonstrated by their capacity to transfer diabetes into syngeneic immunoincompetent recipients. In addition, especially in prediabetic NOD mice, peripheral CD4+ T lymphocytes were identified that are highly effective, in conventional mixing cotransfer experiments, at preventing disease transfer. The present data demonstrate that mature heat-stable Ag−TCRαβ+CD8− thymocytes from prediabetic NOD mice also express this inhibitory capacity. Selection using an L-selectin (CD62L)-specific Ab showed that TCRαβ+CD4+CD62L+ thymocytes, emerging from the mainstream differentiation pathway, concentrate this ability to regulate autoreactive effectors. Compared with mature TCRαβ+CD8− thymocytes, significantly lower numbers of TCRαβ+CD4+CD62L+ were sufficient to achieve an efficient inhibition of disease transfer into NOD-scid recipients. This protective ability was potentiated following in vitro culture in the presence of IL-7. In contrast, TCRαβ+CD62L− thymocytes, highly enriched in class I-restricted NK T cells, were unable to influence diabetes transfer. Identical results were obtained using thymocytes that have been cultured in vitro for 4 days in the presence of IL-7. These results support the active role in NOD mice of a thymus-derived CD4+ subset that controls peripheral pathogenic autoimmune effectors.

Rapid death and regeneration of NKT cells in anti-CD3epsilon- or IL-12-treated mice: a major role for bone marrow in NKT cell homeostasis

Natural killer T (NKT) cells express a T cell receptor (TCR) and markers common to NK cells, including NK1.1. In vivo, NKT cells are triggered by anti-CD3epsilon MAb to rapidly produce large amounts of IL-4 and by IL-12 to reject tumors. We show here that anti-CD3epsilon MAb treatment rapidly depletes the liver (and partially the spleen) of NKT cells and that homeostasis is achieved 1 to 2 days later via NKT cell proliferation that occurs mainly in bone marrow. Similar results were obtained in mice treated with IL-12. Collectively, our data demonstrate that peripheral NKT cells are highly sensitive to activation-induced cell death and that bone marrow plays a major role in restoring NKT cell homeostasis.

Tolerance and latent cellular rejection in long-term liver transplant recipients

Tolerance develops in a proportion of long-term liver transplant recipients but currently cannot be identified before an attempt at withdrawal from immunosuppression therapy. In the present study, we have examined the immunophenotypic characteristics of the cellular infiltrate in portal tracts and lobules as observed in liver biopsy specimens in relation to the outcome of subsequent withdrawal from immunosuppression therapy. Cryostat biopsy specimens from 27 long-term recipients before drug withdrawal, and from 10 patients with recent transplants who were having acute rejection, were analyzed. Immunohistochemical staining was performed for CD3+ (pan T cell), CD8+ (cytotoxic), CD4+ (helper), CD45RO+ (memory), CD45RA+ (naive), CD56+ (natural killer), CD68+ (macrophage), and CD8+ perforin+ cells. Fewer CD8+ and CD3+ cells were present in the lobular areas of biopsy specimens from patients who were successfully withdrawn from immunosuppression therapy (n = 6) compared with biopsy specimens from patients with nontolerant grafts (n = 9; 15 vs. 23 cells/high-power field [hpf] [P < .01] and 16 vs. 26 cells/hpf [P < .03], respectively) or biopsy specimens obtained during acute rejection (15 vs. 31 cells/hpf [P < .01] and 16 vs. 32 cells/hpf [P < .01]). Cell frequencies in the biopsy specimens of nontolerant long-term patients were similar to those found with acute rejection. Immunophenotyping the lobular inflammation within long-term liver allografts assists in identifying those patients in whom drug withdrawal is likely to be unsuccessful and in whom it is postulated a form of inactive, latent cellular rejection exists.

IL-4-Producing NK1.1+ T Cells Are Resistant to Glucocorticoid-Induced Apoptosis: Implications for the Th1/Th2 Balance

To elucidate the mechanisms by which glucocorticoids promote Th2-type responses, we investigated the influence of dexamethasone (DEX) on both cytokine production and viability of NK1.1+ T cells. The in vivo administration of DEX enhanced the IL-4 production of spleen cells and liver mononuclear cells in wild-type mice, but not in β2m-deficient mice. DEX reduced the cellularity of conventional T cells, but not that of NK1.1+ T cells, in both spleen and liver, suggesting an increased proportion of NK1.1+ T cells. Moreover, the proportion of IL-4-producing NK1.1+ T cells increased in the DEX-injected mice. These results suggest that DEX induced IL-4 production through the preferential survival of IL-4-producing NK1.1+ T cells. In investigating the reason for the preferential survival of NK1.1+ T cells, we found that NK1.1+ T cells were resistant to DEX-induced apoptosis and expressed a higher level of intracellular Bcl-2 compared with conventional NK1.1− T cells. In addition, splenic and hepatic NK1.1+ T cells were resistant to radiation-induced apoptosis. Collectively, our findings revealed an important role for NK1.1+ T cells in the regulation of Th1/Th2 balance by glucocorticoids and their possible functions under various apoptotic stimuli.

The regulation of phenotype and function of human liver CD3+/CD56+ lymphocytes, and cells that also co-express CD8 by IL-2, IL-12 and anti-CD3 monoclonal antibody

The regulation of phenotype and function of human liver infiltrating lymphocytes (LIL) by in vitro culture with IL-2, IL-12 and anti-CD3 monoclonal antibodies (mAb) was investigated. The CD3+ LIL which express 50% less CD3 molecules per cell than peripheral blood T lymphocytes, exhibited a 6-fold reduction in proliferation when stimulated through the CD3 complex by anti-CD3 mAb. LIL freshly isolated or cultured in medium did not suppress MLR response, nor were they cytotoxic. However, treatment of the LIL cells with IL-2, IL-12 and anti-CD3 induced these cells to suppress autologous responding cells in MLR (ca. 70%) and to kill autologous or allogeneic cells. Low level cytotoxicity could be induced by cytokines IL-2, IL-12 or anti-CD3 alone. However, the development of optimum MLR suppression and cytotoxicity induction was dependent upon stimulation of the LIL cells through the CD3 complex. The co-expression of CD3 and CD56 on LIL was also up-regulated by anti-CD3 stimulation in the combination of IL-2 and IL-12. Most of the CD3+/CD56+ cells, also expressed CD8. After the magnetic bead separation procedure, the cytotoxic activity was found mainly in the CD3+/CD56+/CD8+ population. These results suggest that CD3+/CD56+/CD8+ cells can be expanded by stimulation through the TCR/CD3 complex in the presence of IL-2 and IL-12, which results in the suppression of autologous responding cells by a cytotoxic mechanism. The proliferative response of the CD3+/CD56+/CD8+ population was enhanced by the induction of CD1 molecules on the stimulating cells, and anti-CD1 mAb were able to block the response in a dose-dependent manner. The CD3+/CD56+/CD8+ cells were examined for cytokine production by flow cytometry. Cytokines IL-4, TNF-alpha, and IFN-gamma were produced by 91.7%, 29.2%, and 27.4% of the cells, respectively.

An alternate pathway for T cell development supported by the bone marrow microenvironment: recapitulation of thymic maturation

In the principal pathway of alpha/beta T cell maturation, T cell precursors from the bone marrow migrate to the thymus and proceed through several well-characterized developmental stages into mature CD4+ and CD8+ T cells. This study demonstrates an alternative pathway in which the bone marrow microenvironment also supports the differentiation of T cell precursors into CD4+ and CD8+ T cells. The marrow pathway recapitulates developmental stages of thymic maturation including a CD4+CD8+ intermediary cell and positive and negative selection, and is strongly inhibited by the presence of mature T cells. The contribution of the marrow pathway in vivo requires further study in mice with normal and deficient thymic or immune function.

Requirement for gammadelta T cells in allergic airway inflammation

The factors that contribute to allergic asthma are unclear but the resulting condition is considered a consequence of a type-2 T helper (TH2) cell response. In a model of pulmonary allergic inflammation, mice that lacked gammadelta T cells had decreases in specific immunoglobulin E (IgE) and IgG1 and pulmonary interleukin-5 (IL-5) release as well as in eosinophil and T cell infiltration compared with wild-type mice. These responses were restored by administration of IL-4 to gammadelta T cell-deficient mice during the primary immunization. Thus, gammadelta T cells are essential for inducing IL-4-dependent IgE and IgG1 responses and for TH2-mediated airway inflammation to peptidic antigens.

IL-4-producing NK T cells are biased towards IFN-gamma production by IL-12. Influence of the microenvironment on the functional capacities of NK T cells

NK T cells are an unusual T lymphocyte subset capable of promptly producing several cytokines after stimulation, in particular IL-4, thus suggesting their influence in Th2 lineage commitment. In this study we demonstrate that, according to the cytokines present in the microenvironment, NK T lymphocytes can preferentially produce either IL-4 or IFN-gamma. In agreement with our previous reports showing that their IL-4-producing capacity is strikingly dependent on IL-7, CD4-CD8-TCRalphabeta+ NK T lymphocytes, obtained after expansion with IL-1 plus granulocyte-macrophage colony-stimulating factor, produced almost undetectable amounts of IL-4 or IFN-gamma in response to TCR/CD3 cross-linking. However, the capacity of these T cells to produce IFN-gamma is strikingly enhanced when IL-12 is added either during their expansion or the anti-CD3 stimulation, while IL-4 secretion is always absent. A similar effect of IL-12 on IFN-gamma production was observed when NK T lymphocytes were obtained after expansion with IL-7. It is noteworthy that whatever cytokines are used for their expansion, IL-12 stimulation, in the absence of TCR/CD3 cross-linking, promotes consistent IFN-gamma secretion by NK T cells without detectable IL-4 production. Experiments in vivo demonstrated a significant upregulation of the capacity of NK T cells to produce IFN-gamma after anti-CD3 mAb injection when mice were previously treated with IL-12. In conclusion, we provide evidence that the functional capacities of NK T cells, which ultimately will determine their physiological roles, are strikingly dependent on the cytokines present in their microenvironment.