IL-33 receptor ST2 deficiency attenuates renal ischaemia-reperfusion injury in euglycaemic, but not streptozotocin-induced hyperglycaemic mice.

AIM: Kidney hypoxia can predispose to the development of acute and chronic renal failure in diabetes. Ischaemia-reperfusion injury (IRI) causes inflammation, and diabetes is known to exacerbate this inflammatory response in the kidney, whereas alarmin IL-33 could act as an innate immune mediator during kidney IRI. Thus, the present study examined the impact of genetic IL-33 receptor ST2 deficiency (ST2-/-) on renal IRI in euglycaemic and hyperglycaemic mice. METHODS: Hyperglycaemia was induced with streptozotocin (STZ) in adult male C57BL/6JRj wild-type (WT) mice and ST2-/- mice. Unilateral renal IRI was achieved 3months after STZ treatment by left kidney nephrectomy (non-ischaemic control kidney) and clamping of the right renal artery for 32min in STZ- and vehicle-treated animals. At 24h after reperfusion, renal function and injury were determined by levels of plasma creatinine, blood urea nitrogen (BUN) and histological tubule scores. Also, in a complementary pilot clinical study, soluble ST2 concentrations were compared in diabetics and non-diabetics. RESULTS: Urinary albumin was significantly increased in STZ-induced hyperglycaemic mice, regardless of genotypic background. At 24h post-ischaemia, plasma creatinine, BUN and tubular injury were significantly reduced in ST2-/- mice compared with vehicle-treated WT mice, but this protective effect was lost in the STZ-induced hyperglycaemic ST2-/- animals. Plasma concentrations of soluble ST2 were significantly greater in type 2 diabetes patients vs non-diabetics. CONCLUSION: Our data suggest that the IL-33/ST2 pathway exerts differential effects depending on the glucose environment, opening-up new avenues for future research on alarmins and diabetes in ischaemia-related diseases.

Identification of invariant natural killer T cells in porcine peripheral blood.

The pig is a relevant preclinical model for numerous pathologies used to validate therapeutic strategies for translation to human. Although invariant natural killer T (iNKT) lymphocytes are a component of innate immunity implicated in many pathological processes, little is known on their characterization in swine. By addressing this issue using mouse α-galactosylceramide-loaded CD1d tetramers (α-GC-CD1dTT), which are commonly used to track iNKT cells, we were able to unequivocally identify CD3(+)α-GC-CD1dTT(+) cells in porcine peripheral blood, hereafter referred to as swine iNKT cells. These lymphocytes are enriched in CD4(-)CD8(+) and CD4(-)CD8(-) cells, harbor an activated-memory phenotype (SLA-DR(+)CD45RA(-)), express the intracellular promyelocytic-leukemia-zinc-finger (PLZF) transcription factor and are significantly enriched in IFN-γ-producing cells after in vitro activation in comparison with conventional T cells. Importantly, in presence of IL-2 and IL-15, the iNKT cell ligand α-GC induces selective expansion of CD3(+)α-GC-CD1dTT(+) cells, confirming the reactivity of swine iNKT cells against α-GC. When associated with α-GC, IL-33, an alarmin of IL-1 family recently described to target iNKT cells, leads to a greater expansion of CD3(+)α-GC-CD1dTT(+) cells than IL-2 and IL-15. Altogether, our results provide the first phenotypic and functional description of swine iNKT cells allowing to further study the critical role of iNKT cells in porcine models of organ injury.

Freshly isolated Valpha24+ CD4+ invariant natural killer T cells activated by alpha-galactosylceramide-pulsed B cells promote both IgG and IgE production.

CD1d-restricted invariant natural killer T (iNK T) cells activated by their experimental ligand alpha-galactosylceramide (alpha-GC) can produce both T helper 1 (Th1) and Th2 cytokines and display regulatory functions. Recent studies identified CD4(+) and CD4(-) CD8(-) double-negative (DN) iNK T cells as the two major components of the human population and suggest that they display a Th2 and a Th1 profile, respectively. We compared the Th2-promoting activity of freshly isolated human CD4(+) and DN iNK T cells in terms of their capacity to induce Ig production by autologous B cells. Secretion of IgG and IgE but not IgM was enhanced by the CD4(+) T cell subset (including iNK T cells) but not by its DN counterpart. iNK T cells were directly responsible for this pro-Th2 effect, as demonstrated by the requirement for both alpha-GC stimulation and CD1d presentation, as well as by its disappearance upon iNK T cell depletion. Interaction with iNK T cells led to progressive accumulation of isotype-switched and activated B cells. Myeloid dendritic cells (DC) completely block the induction of Ig production in co-culture. This dominant inhibitory effect of myeloid DC was concomitant with a specific loss of interleukin (IL)-4 production by CD4(+) iNK T but not by conventional T cells. These data support the conclusion that, conversely to the interferon (IFN)-gamma-producing DN human iNK T cell population, interleukin (IL)-4-producing CD4(+) iNK T cells can activate and help B cells to produce both IgG and IgE through a CD1d-dependent mechanism, in keeping with a functional Th1/Th2 dichotomy between these subsets.

Activation of natural killer T cells by alpha-galactosylceramide treatment prevents the onset and recurrence of autoimmune Type 1 diabetes.

Type 1 diabetes (T1D) in non-obese diabetic (NOD) mice may be favored by immune dysregulation leading to the hyporesponsiveness of regulatory T cells and activation of effector T-helper type 1 (Th1) cells. The immunoregulatory activity of natural killer T (NKT) cells is well documented, and both interleukin (IL)-4 and IL-10 secreted by NKT cells have important roles in mediating this activity. NKT cells are less frequent and display deficient IL-4 responses in both NOD mice and individuals at risk for T1D (ref. 8), and this deficiency may lead to T1D (refs. 1,6-9). Thus, given that NKT cells respond to the alpha-galactosylceramide (alpha-GalCer) glycolipid in a CD1d-restricted manner by secretion of Th2 cytokines, we reasoned that activation of NKT cells by alpha-GalCer might prevent the onset and/or recurrence of T1D. Here we show that alpha-GalCer treatment, even when initiated after the onset of insulitis, protects female NOD mice from T1D and prolongs the survival of pancreatic islets transplanted into newly diabetic NOD mice. In addition, when administered after the onset of insulitis, alpha-GalCer and IL-7 displayed synergistic effects, possibly via the ability of IL-7 to render NKT cells fully responsive to alpha-GalCer. Protection from T1D by alpha-GalCer was associated with the suppression of both T- and B-cell autoimmunity to islet beta cells and with a polarized Th2-like response in spleen and pancreas of these mice. These findings raise the possibility that alpha-GalCer treatment might be used therapeutically to prevent the onset and recurrence of human T1D.

Protection against diabetes and improved NK/NKT cell performance in NOD.NK1.1 mice congenic at the NK complex.

The NK1.1 cell surface receptor, which belongs to the NKR-P1 gene cluster, has been bred onto nonobese diabetic (NOD) mice for two purposes. The first was to tag NK and NKT cells for easier experimental identification of those subsets and better analysis of their implication in type 1 diabetes. The second was to produce a congenic strain carrying Idd6, a susceptibility locus that has been repeatedly mapped in the vicinity of the NKR-P1 gene cluster and the NK complex, to explore the impact of this locus upon autoimmune diabetes. NOD.NK1.1 mice express the NK1.1 marker selectively on the surface of their NK and NKT cell subsets. In addition, the mice manifest reduced disease incidence and improved NK and NKT cell performance, as compared with wild-type NOD mice. The association of those two features in the same congenic strain constitutes a strong argument in favor of Idd6 being associated to the NK complex. This could explain at the same time the multiple alterations of innate immunity reported in NOD mice and the fact that disease onset can be readily modified by boosting the innate immune system of the mouse.

IL-18 enhances IL-4 production by ligand-activated NKT lymphocytes: a pro-Th2 effect of IL-18 exerted through NKT cells.

NKT cells are a remarkably versatile population whose functional capacities are determined by cytokines present in their microenvironment. In this study, we provide evidence for a new immunoregulatory effect of the proinflammatory cytokine IL-18 on NKT cells. We found that IL-18, mainly known for its involvement in NK cell activation and in Th 1 immune responses, substantially enhanced IL-4 production as well as the percentage of IL-4(+) cells among NKT lymphocytes activated by their specific ligand alpha-galactosylceramide (alpha-GalCer). The effect of IL-18 on IL-4 production by activated NKT cells took place both in vivo and in vitro and was not affected by IL-12 which increased IFN-gamma secretion in the same conditions. We show that NKT cells are the main targets for IL-18-induced IL-4 production since it occurred neither in NKT-deficient mice nor after stimulation of Th2 lymphocytes. Finally, we provide evidence that the IL-4 promptly generated by NKT cells in response to IL-18 plus alpha-galactosylceramide in vivo can effectively contribute to the adaptive Th2 immune response by up-regulating the early activation marker CD69 on B cells. Our data support the notion that, in contrast to the exclusive IFN-gamma inducer IL-12, IL-18 acts in a more subtle manner as a costimulatory factor in both pro-Th1 and pro-Th2 responses depending on the nature of the stimulation and the target cells.

NKT lymphocyte ontogeny and function are impaired in low antibody-producer Biozzi mice: gene mapping in the interval-specific congenic strains raised for immunomodulatory genes.

NKT cells are CD4(+) or CD4(-)CD8(-) CD1d-restricted lymphocytes, characterized by the property to rapidly produce IL-4 and IFN-gamma in response to TCR ligation. This IL-4 burst is lacking in autoimmunity-prone SJL and NOD strains of mice, which suggests an immunoregulatory role for NKT cells. The NKT cell status was thus investigated in the genetically selected high (H) and low (L) antibody-producer mice. The results show that (i) the frequency of cells expressing the NKT cell markers is 3- to 4-fold lower in thymus and spleen from L than H mice, (ii) L mice spleen cells did not produce IL-4 following injection of anti-TCR alpha beta antibody, and (iii) L mice thymus and spleen cells failed to produce IL-4 after in vitro stimulation by anti-TCR alpha beta antibody or alpha-galactosylceramide, a newly described NKT cell ligand. These parameters were investigated in six interval-specific congenic strains raised for the quantitative trait loci which contain the immunomodulatory genes responsible for the high/low antibody production phenotypes. IL-4 production recovery occurred only in the congenic strain in which the H origin chromosome 4 segment was introgressed on the L background. This finding was not due to increased NKT cell frequency but appeared dependent of antigen-presenting cells in co-culture experiments. This result strongly suggests the presence of gene(s) modulating NKT function on chromosome 4, close to several genes predisposing to autoimmunity.

A subset of NKT cells that lacks the NK1.1 marker, expresses CD1d molecules, and autopresents the alpha-galactosylceramide antigen.

In the present report, we characterize a novel T cell subset that shares with the NKT cell lineage both CD1d-restriction and high reactivity in vivo and in vitro to the alpha-galactosylceramide (alpha-GalCer) glycolipid. These cells preferentially use the canonical Valpha14-Jalpha281 TCR-alpha-chain and Vbeta8 TCR-beta segments, and are stimulated by alpha-GalCer in a CD1d-dependent fashion. However, in contrast to classical NKT cells, they lack the NK1.1 marker and express high surface levels of CD1d molecules. In addition, this NK1.1(-) CD1d(high) T subset, further referred to as CD1d(high) NKT cells, can be distinguished by its unique functional features. Although NK1.1(+) NKT cells require exogenous CD1d-presenting cells to make them responsive to alpha-GalCer, CD1d(high) NKT cells can engage their own surface CD1d in an autocrine and/or paracrine manner. Furthermore, in response to alpha-GalCer, CD1d(high) NKT cells produce high amounts of IL-4 and moderate amounts of IFN-gamma, a cytokine profile more consistent with a Th2-like phenotype rather than the Th0-like phenotype typical of NK1.1(+) NKT cells. Our work reveals a far greater level of complexity within the NKT cell population than previously recognized and provides the first evidence for T cells that can be activated upon TCR ligation by CD1d-restricted recognition of their ligand in the absence of conventional APCs.

Fas/Fas ligand interactions promote activation-induced cell death of NK T lymphocytes.

NKT cells are a versatile population whose immunoregulatory functions are modulated by their microenvironment. We demonstrate herein that in addition to their IFN-gamma production, NKT lymphocytes stimulated with IL-12 plus IL-18 in vitro underwent activation in terms of CD69 expression, blast transformation, and proliferation. Yet they were unable to survive in culture because, once activated, they were rapidly eliminated by apoptosis, even in the presence of their survival factor IL-7. This process was preceded by up-regulation of Fas (CD95) and Fas ligand expression in response to IL-12 plus IL-18 and was blocked by zVAD, a large spectrum caspase inhibitor, as well as by anti-Fas ligand mAb, suggesting the involvement of the Fas pathway. In accordance with this idea, NKT cells from Fas-deficient C57BL/6-lpr/lpr mice did not die in these conditions, although they shared the same features of cell activation as their wild-type counterpart. Activation-induced cell death occurred also after TCR engagement in vivo, since NKT cells became apoptotic after injection of their cognate ligand, alpha-galactosylceramide, in wild-type, but not in Fas-deficient, mice. Taken together, our data provide the first evidence for a new Fas-dependent mechanism allowing the elimination of TCR-dependent or -independent activated NKT cells, which are potentially dangerous to the organism.

CD11c+ eosinophils in the murine thymus: developmental regulation and recruitment upon MHC class I-restricted thymocyte deletion.

Eosinophils are bone marrow-derived cells released into the circulation during hypersensitivity reactions and parasitic infections. Under normal conditions most eosinophils are tissue bound, where their physiologic role is unclear. During in situ analysis of the thymic microenvironment for CD11c+ dendritic cell subpopulations (APC critical in the process of thymic negative selection) a discrete population of CD11b/CD11c double-positive cells concentrated in the cortico-medullary region of young mice was detected. Thymic CD11c+ cells were isolated, and the CD11b+ subpopulation (CD44high, class IIlow, CD11cint) was identified as mature eosinophils based on: scatter characteristics, major basic protein mRNA expression, and eosinophilic granules. They are hypodense, release high levels of superoxide anion, and express CD25, CD69, and mRNA for IL-4 and IL-13, but not GM-CSF or IL-5, suggesting a distinct state of activation. Thymic eosinophils are preferentially recruited during the neonatal period; absolute numbers increased 10-fold between 7-14 days to reach parity with dendritic cells before diminishing. In a model of acute negative selection, eosinophil numbers were increased 2-fold 6 h after cognate peptide injection into MHC class I-restricted female H-Y TCR transgenic mice. In both peptide-treated female and negatively selecting male H-Y TCR mice, clusters of apoptotic bodies were associated with eosinophils throughout the thymus. Our data demonstrate a temporal and spatial association between eosinophil recruitment and class I-restricted selection in the thymus, suggesting an immunomodulatory role for eosinophils under nonpathological conditions.

A distinct IL-18-induced pathway to fully activate NK T lymphocytes independently from TCR engagement.

NK T lymphocytes are characterized by their ability to promptly generate IL-4 and IFN-gamma upon TCR engagement. Here, we demonstrate that these cells can also be fully activated in the absence of TCR cross-linking in response to the proinflammatory cytokine IL-18 associated with IL-12. NK T cells stimulated with IL-18 plus IL-12 proliferated, killed Fas+ target cells, and produced high levels of IFN-gamma without IL-4. In these conditions, IFN-gamma production was at least 10-fold higher than that upon TCR cross-linking. Interestingly, a 2-h pretreatment with IL-12 plus IL-18 sufficed to maintain the high IFN-gamma-producing potential during subsequent stimulation with anti-TCR mAbs or with the specific Ag alpha-galactosylceramide. Similar effects were observed in vivo, because splenic CD4+ NK T cells from MHC class II-deficient mice secreted IFN-gamma without further stimulation when removed 2 h after a single injection of IL-12 plus IL-18. In conclusion, our evidence for activation of NK T lymphocytes in response to IL-18 plus IL-12 in the absence of TCR engagement together with the maintenance of preferential IFN-gamma vs IL-4 production upon subsequent exposure to specific Ags is consistent with the active participation of this cell population in innate as well as acquired cellular immune responses.

CD3 antibody-induced IL-10 in renal allograft recipients: an in vivo and in vitro analysis.

BACKGROUND: The first administration of CD3 monoclonal antibodies, such as anti-human CD3 (OKT3), induces a massive release of several cytokines, including tumor necrosis factor alpha (TNF-alpha), interferon (IFN)-gamma, interleukin (IL)-2, IL-3, IL-6, and granulocyte-macrophage colony-stimulating factor. METHODS: Cytokine levels in patient's sera were measured by specific ELISA. In vitro cultures were performed using OKT3-stimulated peripheral blood mononuclear cells and/or whole blood from patients and normal controls. RESULTS: Here we describe that OKT3 administration to human renal allograft recipients also leads to a significant release of IL-10. Contrasting with most OKT3-induced cytokines, such as TNF-alpha whose release is transient, IL-10 levels show a more progressive increase, they peak only by 4-8 hr after the first OKT3 injection and persist longer. Thus, significant IL-10 levels are still detectable at the time of the second and the third OKT3 injection. Administration of corticosteroids, 1 hr before the first OKT3 injection, significantly reduced both TNF-alpha and IL-10 release. Experiments were performed to evaluate the source(s) of IL-10 and its (their) influence on the initial T-cell activation. When stimulated in culture with soluble OKT3, the production of IL-10 was dependent on the cooperation between T lymphocytes and monocytes. It is important that, as assessed through the use of a specific neutralizing antibody, the endogenous IL-10 produced in the co-culture system exerted a negative feed-back on the release of the other pro-inflammatory CD3-induced cytokines, which was reproducible. CONCLUSION: These results are supportive of a major role of IL-10 in the down-modulation of the OKT3-triggered T-cell activation cascade.

IL-7 up-regulates IL-4 production by splenic NK1.1+ and NK1.1- MHC class I-like/CD1-dependent CD4+ T cells.

NK T cells are an unusual subset of T lymphocytes. They express NK1. 1 Ag, are CD1 restricted, and highly skewed toward Vbeta8 for their TCR usage. They express the unique potential to produce large amounts of IL-4 and IFN-gamma immediately upon TCR cross-linking. We previously showed in the thymus that the NK T subset requires IL-7 for its functional maturation. In this study, we analyzed whether IL-7 was capable of regulating the production of IL-4 and IFN-gamma by the discrete NK T subset of CD4+ cells in the periphery. Two hours after injection of IL-7 into mice, or after a 4-h exposure to IL-7 in vitro, IL-4 production by CD4+ cells in response to anti-TCR-alphabeta is markedly increased. In contrast, IFN-gamma production remains essentially unchanged. In beta2-microglobulin- and CD1-deficient mice, which lack NK T cells, IL-7 treatment does not reestablish normal levels of IL-4 by CD4+ T cells. Moreover, we observe that in wild-type mice, the memory phenotype (CD62L-CD44+) CD4+ T cells responsible for IL-4 production are not only NK1.1+ cells, but also NK1.1- cells. This NK1.1-IL-4-producing subset shares three important characteristics with NK T cells: 1) Vbeta8 skewing; 2) CD1 restriction as demonstrated by their absence in CD1-deficient mice and relative overexpression in MHC II null mice; 3) sensitivity to IL-7 in terms of IL-4 production. In conclusion, the present study provides evidence that CD4+MHC class I-like-dependent T cell populations include not only NK1.1+ cells, but also NK1.1- cells, and that these two subsets are biased toward IL-4 production by IL-7.

Mature mainstream TCR alpha beta+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-TCR alpha beta+CD8-thymocytes from prediabetic NOD mice also express this inhibitory capacity. Selection using an L-selectin (CD62L)-specific Ab showed that TCR alpha/beta+CD4+CD62L+ thymocytes, emerging from the mainstream differentiation pathway, concentrate this ability to regulate autoreactive effectors. Compared with mature TCR alpha beta+CD8- thymocytes, significantly lower numbers of TCR alpha beta+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, TCR alpha beta+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.

Inflammation: "a natural experiment" for the systemic pathogenicity of cytokines.

It has previously been demonstrated that the overproduction of interleukin-6 (IL-6) is a key element in the clinical and biological abnormalities encountered in Castleman's disease (CD). The particular case of a male child with a localized form of CD is reported. In this patient, evidence was found of a correlation between systemic manifestations and circulating IL-6, and IL-6 gene overexpression in the germinal centers of hyperplastic lymph nodes. Circulating IL-6 levels were 10- to 100-fold higher than in all CD cases previously documented. This unique biological feature was closely associated with high levels of circulating IL-1 and tumor necrosis factor-alpha (TNF-alpha), which are known for their ability to induce and/or amplify IL-6 production. One month after surgical removal of the pathological lymph node, the clinical and biological abnormalities diminished, while circulating IL-6 levels dropped dramatically eight months later. It is worth noting that after resection, the time-course of the IL-6 decrease closely correlated with that of IL-1 and TNF-alpha. Considering that in various inflammatory diseases IL-1, TNF-alpha and IL-6 may act in a synergistic manner in inducing systemic manifestations, this case report raises new questions as to the nature of the systemic pathogenicity of cytokines in CD.

Requirement of IL-7 for IL-4-producing potential of MHC class I-selected CD4-CD8-TCR alpha beta+ thymocytes.

IL-7 plays an important role in the growth and differentiation of T cells. We have previously reported that IL-7 induces preferential expansion of MHC class I-selected CD4-CD8-TCR alpha beta+ thymocytes which express a skewed V beta repertoire and are potent IL-4 producers. In this report, we provide evidence that IL-1 in combination with granulocyte macrophage colony stimulating factor can also expand this population. Yet, these cells do not share the functional characteristics of those obtained in the presence of IL-7, i.e. cytotoxic activity and high IL-4 production. These functional capacities can be acquired by adding IL-7. In conclusion, our findings demonstrate that the capacity of MHC class I-selected CD4-CD8-TCR alpha beta+ thymocytes to produce IL-4 as well as to kill target cells is IL-7 dependent.

Early quantitative and functional deficiency of NK1+-like thymocytes in the NOD mouse.

An immunoregulatory role has recently been attributed to the discrete subset of major histocompatibility complex class I-restricted NK1+ mature heat-stable antigen- (HSA-) thymocytes expressing an unusual Vbeta8-biased T cell receptor repertoire. NK1+ T cells are the main interleukin (IL)-4 producers upon priming. We have studied the size and the function of this subset in the nonobese diabetic (NOD) mouse, a model of spontaneous T cell-mediated autoimmune insulin-dependent diabetes. This study was complicated by the absence in this strain of the NK1.1 allele, the only one for which an antibody is available. To circumvent this difficulty, the cells, hereafter designated the NK1+-like T subset, were characterized by the use of monoclonal antibodies which showed the Vbeta8 bias in the CD44+ Ly-49+ MEL-14- 3G11- thymocyte subset of non-autoimmune strains and of its absence in class I-deficient (beta2-microglobulin-/-) mice. A clear deficit in the number of NK1+-like cells was evidenced at 3 weeks of age in NOD mice. It was still present at 8 weeks of age in the double-negative CD4-CD8- population. The functional anomaly was even more striking: NOD mouse NK1+-like thymocytes virtually lacked the ability to produce IL-4 at 3 weeks and still showed a very reduced capacity at 8 weeks. NK1+ T cell deficiency was also suggested in the periphery by the reduction of Ly-49A+ cells in the spleen of 3- and 8-week-old NOD mice and the absence of short-term production of IL-4 in vitro by NOD mouse spleen cells 90 min after the administration of anti-CD3 antibody, a response attributed to NK1+ T cells. Taken together, these data demonstrate a very early defect in NK1+-like T cells which could be involved in the genesis of autoimmunity in NOD mice through a deficiency in Th2 cell function.

NK1.1+ T cells from IL-7-deficient mice have a normal distribution and selection but exhibit impaired cytokine production.

Particular subsets of T cells expressing the NK1.1 antigen have been proposed to play an immune regulatory role by their fast and strong production of cytokines, in particular IL-4. We sought to determine factors driving the functional differentiation of NK1.1+ T cells. Since NK1.1+ T cells are exquisitely sensitive to IL-7 stimulation, we analyzed the development, selection and IL-4 production of NK1.1+ T cells in IL-7-deficient mice (IL-7-/-m mice). Besides a sharp reduction of all T cell subsets, NK1.1+ T cells develop at normal relative frequencies in IL-7-/- mice. They also undergo a normal selection process, as revealed by the biased V beta TCR repertoire identical to the one in IL-7+/+ mice. However, NK1.1+ T cells from IL-7-/- mice were found to be impaired in IL-4 and IFN-gamma production in in vitro and in vivo models. In addition, IL-7 was able to restore IL-4 production by NK1.1+ thymocytes from IL-7-/- mice. Finally, IL-7 but not IL-2 or IL-4 was able to maintain and increase IL-4 production by NK1.1+ thymocytes from normal mice. These data suggest that the functional maturation of NK1.1+ T cells requires a cytokine-driven differentiation process, in which IL-7 plays a major role.

IL-7 reverses NK1+ T cell-defective IL-4 production in the non-obese diabetic mouse.

Converging data suggest an important role for IL-7 in T lymphocyte maturation as illustrated by the severe T lymphopenia observed in IL-7-deficient mice. We recently reported that IL-7 preferentially promotes the in vitro expansion of a discrete MHC class I-dependent lymphocyte subset comprising both CD4+ and CD4-CD8- TCR alpha beta + cells bearing several NK cells markers such NK1.1 and Ly-49. These T cells, designated as NK1+ T cells, have the unique property among thymocytes of producing large amounts of IL-4 upon primary stimulation via the TCR. We have further demonstrated that thymic NK1+ T cells of non-obese diabetic (NOD) mice, a spontaneous model of autoimmune type I diabetes, are markedly deficient in maturation both quantitatively and functionally (IL-4 production). In the present experiments, the addition of exogenous IL-7 completely restored IL-4 production by anti-TCR alpha beta-stimulated mature (HSA-CD8-) thymocytes in NOD mice. A short 2 h preincubation with IL-7 was sufficient to restore both the expression of IL-4 mRNA and IL-4 production capacity. This was related to a direct effect on NK1+ thymocytes since: (i) the effect of IL-7 was restricted to the non-mainstream MEL-14- 3G11- TCR alpha beta + subset which mostly concentrates the IL-4-producing capacity and (ii) IL-7 did not restore IL-4 production in class I-deficient mice which lack the NK1+ T cell subset. Importantly, this activity of IL-7 on NK1+ T cells was also demonstrated in non-autoimmune strains of mice. These results were extended in vivo by showing that the IL-7 treatment significantly increased the anti-CD3 triggered IL-4 production by NK1+ T spleen cells. These findings confirm the role of IL-7 in NK1+ T cell maturation and suggest that the NK1+ T cell defect in NOD mice could be related to insufficient intrathymic IL-7 bioavailability.