Mouse NK1.1+ T cells: a new family of T cells

The NK1.1 antigen defines a subset of T cells that produce high fiters of cytokines and express a restricted reperloire of T-cell receptors. Here, Alain Vicari and Albert Zloterik discuss the charteristics of NK1.1 T cells that distinguish them from the mainstream CD4 helper or CDS cytotoxic families of T cells. It appears that NK1.1 T cells may play major roles in the regulation of some immune responses.     

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-γ 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 Vβ8 usage by CD62L^low NK1.1⁻ CD4⁺ T cells was ∼ 5 % higher than that by CD62L^high CD4⁺ T cells in wild-type mice in keeping with the estimated proportion of NK1.1⁻ NK T cells in the CD62L^low population. CD62L^low CD4⁺ T cells from β2-m−/− mice, which lack NK T cells, showed no increase in Vβ8 usage. When activated by anti-CD3 or L-CD1, CD62L^low NK1.1⁻ CD4⁺ T cells from conventional but not β2-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.     

Activation of CD1d-independent NK1.1+ T cells in the large intestine by Lactobacilli

Among digestive organs, the liver and the large intestine are abundant in T cells expressing NK1.1. NK1.1+ T cells in the liver are mostly CD1d-dependent whereas those in the large intestine are CD1d-independent. In this study, we investigated the effects of Lactobacilli on NK1.1+ T cells in the digestive organs of mice. C57BL/6 mice were orally given a dietary supplement prepared from mixed cultures of eight strains of Lactobacilli. Oral administration of Lactobacilli to mice resulted in the selective expansion of NK1.1+ T cells in the large intestine. These colon NK1.1+ T cells activated by Lactobacilli were found to express IFN-gamma mRNA. The level of IFN-gamma in the serum was also elevated by the administration of Lactobacilli. Our results suggest that Lactobacilli selectively activate CD1d-independent NK1.1+ T cells in the large intestine to produce IFN-gamma and therefore modulate Th1 immune responses.     

Alefacept selectively promotes NK cell-mediated deletion of CD45R0+ human T cells

Modulation of the immune response using immunoglobulin fusion proteins has shown great promise for clinical immunotherapy of autoimmune diseases. Alefacept is an immunoglobulin fusion protein composed of the first extracellular domain of human LFA-3 fused to the hinge, C(H)2 and C(H)3 domains of human IgG(1). Alefacept has previously been reported to inhibit T cell proliferation. Here, we analyzed the effects of alefacept on lymphocytes in vitro and characterized the role of autologous NK cells in its mechanism of action. Alefacept, but not a C(H)2 binding mutant of Alefacept, inhibited CD3-induced T cell proliferation only in the presence of live NK cells, consistent with an important role for FcgammaR engagement. Alefacept caused preferential depletion of CD69+CD45R0+CD25+ T cell subsets. Cytotoxicity assays revealed that alefacept, but not the C(H)2 binding mutant, induced NK cell-mediated death of activated T cells and sorting into CD45R0+ and CD45RA+ subpopulations showed that lymphocyte deletion occurred preferentially in the CD45R0+ subset. Activated CD45R0+ cells expressed higher levels of CD2 than CD45R0- cells, providing a possible explanation for the selective targeting of this subset. Our results suggest that selective targeting of CD45R0+ T cells by NK cells represents a potential therapeutic mechanism of action of alefacept.     

Signalling through NK1.1 triggers NK cells to die but induces NK T cells to produce interleukin-4.

In vivo inoculation of specific antibody is an accepted protocol for elimination of specific cell populations. Except for anti-CD3 and anti-CD4, it is not known if the depleted cells are eliminated by signalling through the target molecule or through a more non-specific mechanism. C57BL/6 mice were inoculated with anti-natural killer (NK1.1) monoclonal antibody (mAb). Thereafter spleen cells were harvested, stained for both surface and intracellular markers, and analysed by flow cytometry. As early as 2 hr post inoculation, NK cells were signalled to become apoptotic while signalling through the NK1.1 molecule activated NK1.1+ T-cell receptor (TCR)+ (NK T) cells to increase in number, and produce interleukin-4 (IL-4). Anti NK1.1 mAb was less efficient at signalling apoptosis in NK cells when NK T-cell deficient [beta 2-microglobulin beta 2m-deficient] mice were used compared with wild type mice. Efficient apoptotic signalling was restored when beta 2m-deficient mice were reconstituted with NK T cells. NK-specific antibody best signals the apoptotic process in susceptible NK cells when resistant NK T cells are present, activated, and secrete IL-4.     

The role of intrahepatic CD8+ T cell trapping and NK1.1+ cells in liver-mediated immune regulation

The liver was previously suggested as a site of lymphocyte clearance. Liver-associated lymphocytes that express NK1.1 marker (NKT LAL) play a role in immune modulation. Aim: To determine the role of the liver and of NKT LAL in determining the CD4+/CD8+ balance during tolerance induction. Methods: Colitis was induced in C57 mice by intracolonic instillation of trinitrobenzenesulfonic acid (TNBS). Immune tolerance was induced via five oral feedings of colitis-extracted proteins (CEP) from TNBS-colitis colonic wall, starting on the day of colitis induction (group A). Control mice were fed with BSA (group B). To determine the role of NKT cells in immune modulation, NK1.1 depletion was performed in nonfed (group C) and fed (group D) mice. To further evaluate the role of NKT cells in this model, mice in group E were tolerized following NKT depletion. To determine the effect of NKT depletion in a tolerized environment, tolerized mice in group F were NKT depleted following tolerance induction. Peripheral and intrahepatic NK1.1+ and CD4+/CD8+ T cells were determined in all groups. Colitis was assessed by standard clinical and histologic scores. Serum cytokines levels were measured by ELISA. Results: Oral tolerance induction led to a marked alleviation of colitis as manifested by a significant improvement of the clinical, macroscopic, and microscopic scores of colitis (group A vs. group B). NK1.1+ depletion without tolerance induction had a favorable effect on colitis (C). Depletion of NKT LAL prevented the ability to induce tolerance (group D). However, induction of tolerance following NK1.1+ depletion, and NK1.1+ depletion following tolerance induction led to a marked improvement of colitis (groups E and F). Tolerance induction led to a significant increase in NKT LAL numbers. The peripheral CD4+/CD8+ ratio increased up to 3-fold in tolerized vs. non-tolerized mice. A similar increase was observed in NKT-depleted healthy mice in groups C, E, and F (P < 0.005). In contrast, NK1.1+ depletion in the presence of antigen in the bowel led to a reverse effect with a significant decrease in the peripheral CD4+/CD8+ ratio. An opposite effect was observed in the intrahepatic CD4+/CD8+. The peripheral/intrahepatic CD4+/CD8+ ratio increased significantly in tolerized and in healthy mice (A, D, E, F, P < 0.005). In contrast, NK1.1+ depleted fed mice in group C manifested a marked decrease in the peripheral/intrahepatic CD4+/CD8+ ratio. Induction of tolerance led to a marked increase in the IL-10/interferon gamma (IFNgamma) and IL-4/IFNgamma ratios. Conclusions: In the experimental colitis model, the liver is an important site for CD8+ accumulation during tolerance induction in a process that is independent of NK1.1+ cells. NK1.1+ cells play a dual role in the pro/anti-inflammatory balance. In the presence of antigen, these lymphocytes may be accountable for keeping an anti-inflammatory lymphocyte balance. However, in the absence of antigen, they may induce a pro-inflammatory shift.     

Thymus-dependent modulation of Ly49 inhibitory receptor expression on NK1.1+gamma/delta T cells

Major histocompatibility complex (MHC) class I-specific inhibitory receptors are expressed not only on natural killer (NK) cells but also on some subsets of T cells. We here show Ly49 expression on gamma/delta T cells in the thymus and liver of beta2-microglobulin-deficient (beta2m-/-) and C57BL/6 (beta2m+/+) mice. Ly49C/I or Ly49A receptor was expressed on NK1.1+gamma/delta T cells but not on NK1.1-gamma/delta T cells. The numbers of NK1.1+gamma/delta T cells were significantly smaller in beta2m+/+ mice than in beta2m-/- mice with the same H-2b genetic background. Among NK1.1+gamma/delta T cells, the proportions of Ly49C/I+ cells but not of Ly49A+ cells, were decreased in beta2m+/+ mice, suggesting that cognate interaction between Ly49C/I and H-2Kb is involved in the reduction of the number of Ly49C/I+ gamma/delta T cells in beta2m+/+ mice. The frequency of Ly49C/I+ cells in NK1.1+gamma/delta T cells was lower in both lethally irradiated beta2m+/+ mice transplanted with bone marrow (BM) from beta2m-/- mice and lethally irradiated beta2m-/- mice transplanted with BM from beta2m+/+ mice than those in adult thymectomized BM-transplanted chimera mice. These results suggest that reduction of Ly49C/I+ NK1.1+gamma/delta T cells in beta2m+/+ mice is at least partly due to the down-modulation by MHC class I molecules on BM-derived haematopoietic cells or radioresistant cells in the thymus.     

Protective role of NK1.1+ cells in experimental Staphylococcus aureus arthritis.

In a model of Staphylococcus aureus-induced septic arthritis in C57Bl/6 mice we investigated the role of natural killer (NK) cells in the development of disease. Depletion of NK1.1+ cells was achieved by repeated injections of the PK136 antibody, whereas control mice received an irrelevant monoclonal antibody, O1C5.B2. Both groups of mice then received injections intravenously with 2 x 107 live S. aureus LS-1 secreting toxic shock syndrome toxin-1 (TSST-1). The mice were evaluated for 16 days with regard to weight, mortality and arthritis. Nine days after bacterial injection, 9/19 mice depleted of NK cells had developed arthritis compared with 1/17 in the control group (P = 0.01). The experiment was repeated twice with the same outcome. NK cell-depleted and control mice displayed the same degree of histopathological signs of arthritis at day 16. Depletion of NK cells did not affect uptake of bacteria by phagocytic cells in vitro, or bacterial clearance in vivo. In NK cell-depleted mice there was a tendency to increased levels of antibodies to TSST-1, whereas total immunoglobulin levels were similar to those in controls. NK cell depletion of non-infected mice did not affect the magnitude of inflammatory response during the T cell-dependent cutaneous DTH reaction to oxazolone, or during granulocyte-mediated inflammation. However, specific antibody responses to oxazolone were greatly increased in depleted animals. In conclusion, our study demonstrates that NK cells protect against arthritis during S. aureus infection. This outcome does not seem to be due to an influence on bacterial clearance, but could be due to an interaction with the host anti-inflammatory mechanisms.     

Surface receptors identify mouse NK1.1+ T cell subsets distinguished by function and T cell receptor type

Natural killer T (NKT) lymphocytes rapidly produce several cytokines, including IL-4 and IFN-gamma, upon activation, and act as regulatory cells at an early interphase of innate and adaptive immune responses. They have been implicated as important elements in diverse immune responses including the regulation of autoimmune disease, the immune response to infections, and the prevention of tumor metastasis. The broad spectrum of their activities suggested that functionally different subsets of NKT cells may exist. We demonstrate two functionally distinct splenic NKT populations identified by the expression of CD49b and CD69, respectively. Each NKT subset was represented by the amplified transgenic NKT cell population in a distinct transgenic mouse line expressing a CD1d-restricted TCR. CD49bhigh CD69- NKT cells, termed NKT1 cells by us, were high producers of IFN-gamma after stimulation, but essentially devoid of IL-4-synthesizing cells. Most NKT1 cells used diverse (non-Valpha14-canonical) TCR. The CD69+ CD49(-/low) NKT cell population, which we term NKT2, produced large quantities of IL-4 and substantial amounts of IFN-gamma upon activation and were dominated by cells using the canonical Valpha14-Jalpha18 T cell receptor. Knowledge of the unique roles of the different NKT cell subsets in specific situations will be essential for our understanding of NKT cell biology.     

CD25 blockade depletes and selectively reprograms regulatory T cells in concert with immunotherapy in cancer patients

Regulatory T cells (T(regs)) are key mediators of immune tolerance and feature prominently in cancer. Depletion of CD25(+) FoxP3(+) T(regs) in vivo may promote T cell cancer immunosurveillance, but no strategy to do so in humans while preserving immunity and preventing autoimmunity has been validated. We evaluated the Food and Drug Administration-approved CD25-blocking monoclonal antibody daclizumab with regard to human T(reg) survival and function. In vitro, daclizumab did not mediate antibody-dependent or complement-mediated cytotoxicity but rather resulted in the down-regulation of FoxP3 selectively among CD25(high) CD45RA(neg) T(regs). Moreover, daclizumab-treated CD45RA(neg) T(regs) lost suppressive function and regained the ability to produce interferon-γ, consistent with reprogramming. To understand the impact of daclizumab on T(regs) in vivo, we performed a clinical trial of daclizumab in combination with an experimental cancer vaccine in patients with metastatic breast cancer. Daclizumab administration led to a marked and prolonged decrease in T(regs) in patients. Robust CD8 and CD4 T cell priming and boosting to all vaccine antigens were observed in the absence of autoimmunity. We conclude that CD25 blockade depletes and selectively reprograms T(regs) in concert with active immune therapy in cancer patients. These results suggest a mechanism to target cancer-associated T(regs) while avoiding autoimmunity.     

Selection of phenotypically distinct NK1.1+ T cells upon antigen expression in the thymus or in the liver.

Unlike the main TCR alphabeta T cell lineage in which deletion occurs at the CD4+ CD8+ double-positive (DP) stage upon TCR engagement by antigen in the thymus, some T cells appear to require such engagement for their selection, either in the thymus or extrathymically. We used a transgenic TCR (tgTCR) model which, as we previously showed, led to selection upon expression of the corresponding antigen H-2Kb (Kb) in the thymus, of tgTCR/CD3(lo) CD4- CD8- double-negative (DN) thymocytes that expressed the NK1.1 marker (NK T cells) (Curnow, S. J., et al., Immunity 1995. 3: 427). We now report that antigen expression on medullary epithelial cells of the thymus failed to select the NK T cells, whereas its expression on thymocytes did, although tgTCR DP thymocyte development was affected under both conditions. Antigen expression on hepatocytes (Alb-Kb mice) did not perturb tgTCR DP thymocyte development. No enrichment in tgTCR NK T cells was detected in the periphery, except for the liver of the Alb-Kb/tgTCR mice. When reconstitution of thymectomized and irradiated H-2k hosts expressing or not Kb was performed with bone marrow from tgTCR H-2k mice, an enrichment in tgTCR+ NK T cells was found in the liver, but not in the spleen, of the hosts which expressed Kb, either selectively on hepatocytes or ubiquitously. Surprisingly, the majority of the hepatic tgTCR+ NK T cells also expressed the CD8 alpha/beta heterodimer. These results indicate that thymus-independent NK T cells with unique phenotypic characteristics can be selected upon antigen encounter in the liver.     

Enhancement of the synthetic ligand-mediated function of liver NK1.1Ag+ T cells in mice by interleukin-12 pretreatment

We previously reported that mouse NK1.1 Ag+ T (NKT) cells activated by interleukin-12 (IL-12) act as anti-tumour/anti-metastatic effectors. However, IL-12 reportedly induces a rapid disappearance of liver NKT cells by activation-induced apoptosis. In the present study, however, we show that injection of IL-12 into mice merely down-regulates the NK1.1 expression of liver NKT cells and Vbeta8+ intermediate T-cell receptor cells and CD1d/alpha-galactosylceramide (alpha-GalCer)-tetramer reactive cells in the liver remained and did not decrease. Furthermore, when IL-12-pretreated (24 hr before) mice were injected with alpha-GalCer, not only serum interferon-gamma but also serum IL-4 concentrations increased several-fold in comparison to the control alpha-GalCer-injected mice. However, IL-12 pretreatment markedly up-regulated serum ALT levels and Fas-ligand expression on NKT cells after alpha-GalCer injection in middle-aged mice only. Consistently, the liver mononuclear cells (MNC) from IL-12-pretreated mice stimulated with alpha-GalCer in vitro produced much greater amounts of interferon-gamma and IL-4, and also showed a more potent cytotoxicity against tumour targets than those from mice pretreated with phosphate-buffered saline. Liver MNC from middle-aged mice, but not from young mice pretreated with IL-12, also showed increased cytotoxicity following in vitro alpha-GalCer stimulation against cultured hepatocytes. Furthermore, IL-12 treatment of middle-aged mice enhanced tumour necrosis factor receptor 1 mRNA expression in liver Vbeta8+ T cells, and in vitro experiments also revealed that IL-12 pretreatment of liver MNC from middle-aged mice enhanced their tumour necrosis factor-alpha production after alpha-GalCer stimulation. Synthetic ligand-mediated functions of NKT cells, including IL-4 production, are thus enhanced by IL-12 pretreatment.     

17β-Estradiol Suppresses Cytotoxicity and Proliferative Capacity of Murine Splenic NK1.1^＋ Cells

In order to clarify the effects of 17β-estradiol （E2） on natural killer （NK） cells and the possibly regulatory mechanisms, we obtained highly purified and viable NK cells from C57BL/6J mouse spleen by a magnetic cell sorter （MACS）. These cells were treated with E2 and then their cytotoxicity and proliferative capacity were examined. To further investigate the mechanisms on the effect of E2 on NK cells, expressions of activationassociated markers （CD69, CD122） and inhibitory receptors （CD94, Ly49）, and intracellular cytokine production were analyzed. At last, we performed the cDNA microarray to explore the possible involved genes. We found that E2 could suppress NK cell cytotoxicity and proliferative capacity in vitro. E2 reduced NK cell cytotoxicity and proliferative capacity, which may be through influencing the phenotypes and cytokine expression of NK cells, mainly involving CD94 and IFN-γ. Furthermore, regulation of Stat4, Fyn, Sh2d1a, Eat2, Cd244, Irf1, Runxl, Irf7, Irf5, Esrra and Nr5a1 genes may be related to the cytotoxicity, proliferation and cytokine production of E2-mediated purified NK ceils.     

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 havebeen proposed to play an immune regulatory role by their fastand strong production of cytokines, in particular IL-4. We soughtto determine factors driving the functional differentiationof NK1.1⁺ T cells. Since NK1.1⁺ T cells are exquisitely sensitiveto IL-7 stimulation, we analyzed the development, selectionand IL-4 production of NK1.1⁺ T cells in IL-7 deficient mice(IL-7–/–mice). Besides a sharp reduction of allT cell subsets, NK1.1⁺ T cells develop at normal relative frequenciesin IL-7–/–;mice. They also undergo a normal selectionprocess, as revealed by the biased V_ß TCR repertoireidentical to the one in IL-7+/+ mice. However, NK1.1₊ T cellsfrom IL-7+/+ mice were found to be impaired in IL-4 and IFN-production in in vitro and in vivo models. In addition, IL-7was able to restore IL-4 production by NK1.1⁺ thymocytes fromIL-7–/– mice. Finally, IL-7 but not IL-4 was ableto maintain and increase IL-4 production by NK1.1⁺ thymocytesfrom normal mice. These data suggest that the functional maturationof NK1.1⁺ T cells requires a cytokine-driven differentiationprocess, in which IL-7 plays a major role.     

Effect of coadministration of M-CSF and IFN-alpha on NK1.1+ cells in mice.

The purpose of this study was to evaluate the effect of coadministration of macrophage colony-stimulating factor (M-CSF) and interferon-alpha (IFN-alpha) on NK1.1(+) cells in mice. Administration of M-CSF, but not IFN-alpha, increased the number of NK1.1(+) cells and CD11b(+) cells in spleen and blood. Coadministration of the two agents induced a greater increase in NK1.1(+) cells than did administration of M-CSF alone. Administration of M-CSF or IFN-alpha augmented the clearance activity of Yac-1 cells in lung, and coadministration of these agents further augmented this effect. The combination of M-CSF and IFN-alpha effectively reduced the formation of tumor nodules in lung and liver in an experimental metastasis model using B16 melanoma. The combination of M-CSF and IFN-alpha induced the increase and activation of NK1.1(+) cells more than either agent alone. These effects may contribute to the antimetastatic reaction by NK1.1(+) cells in vivo.     

NK1.1+细胞在实验性自身免疫性重症肌无力疾病发病中的免疫调节作用

目的:探讨NK1.1 细胞在实验性自身免疫性重症肌无力(EAMG)疾病发病中的作用以及其调节机制。方法:腹腔注射抗小鼠NK1.1单克隆抗体(mAb)清除C57BL/6(B6)小鼠体内的NK1.1 细胞,建立NK1.1 细胞缺陷小鼠模型;用AChR CFA免疫小鼠诱发EAMG,通过Lennon等的肌无力评分标准分析各组小鼠之间EAMG的发病情况和病情严重程度;应用ELISA法检测单核细胞(MNC)上清液中IFN-γ、IL-4的分泌和表达;应用放射免疫测定法检测血清中AChRIgG含量;用抗IFN-γmAb中和小鼠体内IFN-γ,观察发病情况及血清中AChRIgG的含量。结果:NK1.1 细胞缺陷的小鼠同正常免疫组小鼠相比,发病率和病情严重程度均明显降低(发病率:36%vs86%,P<0.01);免疫后NK1.1 细胞缺陷组和正常免疫组小鼠相比,发病率和病情严重程度无明显统计差异;NK1.1 细胞缺陷降低IFN-γ的表达,但是IL-4的分泌和表达无统计学意义;NK1.1 细胞缺失降低AChR特异性抗体的产生;中和体内IFN-γ后,EAMG的发病率和病情严重程度均减轻,并且AChR特异性抗体减少。结论:NK1.1 细胞在EAMG发病初期发挥重要作用。在EAMG发病中,NK1.1 细胞可以使AChR特异性T细胞产生IFN-γ,增加AChR特异性抗体产生,从而加重EAMG的发病。     

Differential regulation of Ly49 expression on CD4+ and CD4-CD8- (double negative) NK1.1+ T cells

The pan-NK cell marker NK1.1, present in some mouse strains, is also found on a subset of TCRalphabeta+ lymphocytes termed NKT cells. These cells are primarily CD4+ or CD4-CD8- (double negative, DN), and both NKT subpopulations contain cells reactive with the MHC class I-like molecule CD1d. Murine NK cells express clonally distributed inhibitory receptors of the Ly49 family that bind to different alleles of MHC class I molecules and transmit negative signals regulating NK cell function. Ly49 receptors are also found on TCRalphabeta+ NK1.1+ T cells. To investigate the potential role of inhibitory Ly49 markers in the regulation of NKT cells, we have done a thorough analysis of their expression on different NKT populations. The CD4+ and DN NK1.1+ T cell subsets have traditionally been dealt with as one NK1.1+ T cell population, but we found dramatic differences between these two NKT cell subsets. We demonstrate here expression of Ly49 receptors on DN, but not on CD4+, NK1.1+ T cells in spleen and liver. Absence of the specific MHC class I ligand in the host was associated with elevated levels of expression and, to a greater extent than has been found for NK cells, increased the frequencies of Ly49-positive cells within the DN subset, while CD4+ NK1.1+ cells remained negative. In the thymus and bone marrow both NK1.1+ T cell subsets contained high frequencies of Ly49-positive cells. Results from in vitro stimulation of DN NKT cells further suggest that activation and expansion of NKT cell subsets are regulated by the Ly49 receptors.     

Involvement of both donor cytotoxic T lymphocytes and host NK1.1+ T cells in the thymic atrophy of mice suffering from acute graft-versus-host disease.

It has been reported that a dramatic decrease in the number of thymocytes (thymic atrophy) in mice suffering from acute graft-versus-host disease (GVHD) is ascribed to glucocorticoids. In this study, we examined the possibility that cellular immune responses may thus be involved in thymic atrophy. In contrast to chronic GVHD mice, acute GVHD (C57BL/6 X DBA/2) F1 (BDF1) hybrid mice, which were injected intravenously with both spleen and lymph node cells from C57BL/6 mice, showed a dramatic decrease in the number of CD4 CD8 double-positive thymocytes 2 or 3 weeks after the induction of GVHD. A flow cytometric analysis revealed the donor-derived T cells with either CD4 or CD8 molecules to infiltrate the thymus of the mice undergoing acute GVHD for 10 days. In a cytolytic assay, such thymus-containing cells exhibited a cytolytic activity specific to the host cells. In addition, anti-H-2d cytolytic T cells showed a high level of cytolytic activity against BDF1 (H-2bXd) thymocytes, whereas they also showed a low level of cytolytic activity against C57BL/6 (H-2b) thymocytes, thus suggesting that the thymus-infiltrating donor-derived T cells killed the host thymocytes through both anti-H-2d-specific and non-specific mechanisms. Interestingly, a flow cytometric analysis revealed both the percentage and the absolute cell number of host-derived NK1.1+ CD3+ cells to increase in the thymus of mice suffering from acute GVHD for 10 days. In addition, they also showed the cytolytic activity against YAC-1 cells and the mRNA expression of interleukin-12 (IL-12) in the thymus to be also significantly augmented on day 7 after the induction of acute GVHD. Collectively, our results indicate that the cellular immune responses such as donor cytotoxic T lymphocytes and host NK1.1+ T cells are therefore involved in the thymic atrophy of mice suffering from acute GVHD.