Phenotypic characterization of CD8(+)NKT cells

We describe a novel CD8(+)NKT cell population expressing TCRalpha /beta or TCRgamma /delta. These CD8(+)NKT cells were prominent in the liver, and except for the thymus, virtually absent in other lymphoid organs. CD8(+)NKT cells expressed activation markers and comprised a high proportion of Ly49(+) cells. The development of the majority of CD8(+)NKT cells expressing TCRalpha /beta, but not TCRgamma /delta, depended on classical MHC class I. No CD8(+)NKT cells were detectable in young athymic mice, whereas the cells expressing TCRgamma /delta, but not TCRalpha /beta, appeared randomly in aged athymic mice. CD8(+)NK1(+) TCRalpha /beta cells showed polyclonal TCRVbeta usage and were virtually devoid of TCRValpha14. CD8(+)NK1(+) TCRgamma /delta cells predominantly expressed TCRVgamma1, 2 and 4, and Vdelta4, 5, 6 and 7. CD8(+)NKT cells, in particular those expressing TCRgamma /delta, were a major population in early life. IFN-gamma, but not IL-4, was induced in CD8(+)NKT cells by in vitro stimulation, independent of the TCRalpha /beta or TCRgamma /delta lineage. Hence, these cells represent a unique, though heterogeneous T cell population that shares markers with, but is distinct from, both conventional NKT cells and conventional CD8(+) T cells, and that may play a role in immune regulation.     

Positive selection of NKT cells by CD1(+), CD11c(+) non-lymphoid cells residing in the extrathymic organs

Previously, we found that NK1.1(+), TCRalpha beta(+) natural killer T (NKT) cells develop in cytokine-supplemented suspension cultures of fetal liver established from normal, but not from beta2 microglobulin-deficient [beta2m(- / -)] mice, and that recombination-deficient SCID fetal liver can reconstiute NKT cell development in beta2m(- / -) fetal liver cultures. We found here that cells of SCID adult liver, bone marrow, spleen and thymus were able to reconstitute NKT cell development in the former culture system with efficiency comparable to normal thymic cells. The reconstitution of NKT cells was also seen in the bone marrow chimeras that had been administered a combination of beta2m(- / -) and Rag-2(- / -) bone marrow cells. Development of NKT cells was hampered by depletion of CD11c(+) or CD11b(+) cells, but not by removal of B220(+) or Gr-1(+) cells from cultures of normal fetal liver cells. Furthermore CD11c(+), CD11b(+) and / or CD11c(+) CD11b(-) cells (both populations were CD1-dull positive) enriched from Rag-2-deficient fetal livers and pulsed with alpha-galactosylceramide, a possible antigen for NKT cells, were shown to reconstitute the NKT cell development in beta2m(- / -) fetal liver cultures. Collectively, our findings suggest that non-lymphoid cells, presumably CD11c(+), CD11b(+) and / or CD11c(+), CD11b(-) dendritic cells, are involved in the mechanism of positive selection of NKT cells in the thymus and extrathymic organs.     

Adhesion mediated by LFA-1 is required for efficient IL-12-induced NK and NKT cell cytotoxicity

Interleukin 12 (IL-12)-activated NK1.1+TCRalpha beta+ (NKT2) and NK1.1+TCRalpha beta- (NK) cells exhibit cytotoxic activity against a wide variety of tumor cells in the absence of prior sensitization. Here we demonstrate that the integrin adhesion receptor LFA-1 (CD11a/CD18) regulates the cytotoxic activity of IL-12-activated NKT and NK cells against YAC-1 and EL-4 tumor cells. Differentiation in vivo and the expression of the cytolytic effector molecules perforin and Fas-L were comparable in both IL-12-activated NKT and NK cells from LFA-1-/ - and LFA-1+/+ mice. However, LFA-1-/-IL-12-activated NKT and NK cells showed impaired conjugate formation with target cells. These results provide the first genetic evidence for a role for an adhesion receptor in killing by IL-12-activated NK cells.     

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-dependent variation in the proportion and number of intestinal lymphocyte subsets, especially natural killer T cells, double-positive CD4+ CD8+ cells and B220+ T cells, in mice

The age-dependent variation in the proportion and number of lymphocyte subsets was examined at various extrathymic sites, including the liver, small intestine, colon and appendix in mice. In comparison with young mice (4 weeks of age), the number of total lymphocytes yielded by all tested organs was greater in adult (9 weeks) and old (40 weeks) mice. The major lymphocyte subset that expanded with age was interleukin-2 receptor (IL-2R) beta+ CD3int cells (50% of them expressed NK1.1) in the liver, whereas it was CD3+ IL-2Rbeta- NK1.1- cells at all intraepithelial sites in the intestine. Although NK1.1+ CD3+ cells were present at intraepithelial sites in the intestine, the proportion of this subset was rather low. The ratio of CD4 to CD8 tended to decrease among natural killer T (NKT) cells and T cells at all intraepithelial sites in the intestine with age. A unique population of double-positive CD4+ CD8+ cells in the small intestine increased in old mice. B220+ T cells were found mainly in the appendix and colon, and the proportion of these T cells decreased in old mice. Conventional NKT cells were very few in Jalpha281-/- and CD1d-/- mice in the liver, while NKT cells which existed in the appendix remained unchanged even in these mice. This was because unconventional CD8+ NKT cells were present in the intestine. The present results suggest that despite the fact that both the liver and intraepithelial sites in the intestine carry many extrathymic T cells, the distribution of lymphocyte subsets and their age-associated variation are site-specific.     

Tissue-specific expansion of NKT and CD5+B cells at the onset of autoimmune disease in (NZBxNZW)F1 mice

Natural killer T (NKT) cells and CD5(+)B cells were searched for in various immune organs of autoimmune prone (NZBxNZW)F(1) (NZB/W F(1)) mice. The number of lymphocytes increased in the liver, spleen, and peritoneal cavity after the onset of disease (at the age of 30 weeks) while the number of thymocytes decreased at that time. Prominent changes of lymphocyte subsets were seen in the liver and peritoneal cavity, namely, expansion of IL-2Rbeta(+)TCRalpha beta(int) cells in the liver and of CD5(+)B220(+) cells in the peritoneal cavity. The majority of TCRalpha beta(int) cells in the liver were NK1.1(+), and CD5(+)B cells in the peritoneal cavity were CD1d(+). Proteinuria became prominent in NZB/W F(1) mice with the progression of disease. In parallel with this progression, the proportion of NKT cells decreased slightly in the liver, but their absolute number remained at a high level in this organ. These NKT cells were CD4(+) and used an invariant chain of Valpha14Jalpha281 for TCRalpha. Reflecting the elevation of CD5(+)B cells, autoantibodies against hepatocyte cytoplasmand denatured DNA were detected in sera. Although NKT cells are known to be immunoregulatory cells in some autoimmune mice, the present results raise the possibility that NKT cells as well as CD5(+)B cells might be associated with the onset of autoimmune diseases in NZB/W F(1) mice. Indeed, NKT cells in F(1) mice had a high potential to induce autoimmune-like inflammationwhen alpha-galactosylceramide was administered or when active NKT cells were transferred into young F(1) mice.     

Size of the population of CD4+ natural killer T cells in the liver is maintained without supply by the thymus during adult life

Given that there are few natural killer T (NKT) cells in the liver of athymic nude mice and in neonatally thymectomized mice, it is still controversial whether all NKT cells existing in the liver are supplied by the thymus or if some such cells develop in the liver. To determine whether or not NKT cells are consistently supplied from the thymus during adult life, thymectomy was conducted in mice at the age of 8 weeks. Interestingly, the proportion and number of CD4+ NKT cells increased or remained unchanged in the liver after adult thymectomy and this phenomenon continued for up to 6 months after thymectomy. The administration of alpha-galactosylceramide induced severe cytopenia (due to apoptosis) of CD4+ NKT cells in the liver on day 1, but subsequent expansion of these NKT cells occurred in thymectomized mice similar to the case in normal mice. However, in thymectomized mice given lethal irradiation (9.5 Gy) and subsequent bone marrow transfer, the population of CD4+ NKT cells no longer expanded in the liver, although that of CD8+ NKT cells did. These results suggest that thymic CD4+ NKT cells, or their progenitors, may migrate to the liver at a neonatal stage but are not supplied from the thymus in the adult stage under usual conditions. CD8+ NKT cells can be generated in the liver.     

Anti-CD11a prevents deletion of self-reactive T cells in neonatal C57BR mice.

The process of thymic maturation permits development of T cells expressing receptors which recognize self-major histocompatibility complex (MHC) determinants, but deletes T cells recognizing self-MHC determinants with high affinity. This selection process is evolutionarily conserved, and presumably serves in part to prevent the release of autoreactive cells. However, the mechanisms involved in the selection process, and the molecules required are incompletely characterized. Lymphocyte function-associated antigen-1 (LFA-1) is an accessory molecule important in T-cell activation, is involved in thymocyte-epithelial cell binding, and contributes to the maturation of CD4-CD8- thymocytes to the CD4+CD8+ stage. In this report we have investigated whether LFA-1 also contributes to the thymic deletion of potentially self-reactive cells. Neonatal C57Br mice were injected with amounts of a monoclonal antibody to LFA-1 that saturated thymic binding sites, then splenocytes were examined for T cells expressing receptors normally deleted in the thymus. The results demonstrate that V beta 17a+ T cells, normally deleted in this strain, can be detected in the spleen following administration of anti-LFA-1, thus supporting the hypothesis that LFA-1 also contributes to negative selection. The potential significance of LFA-1 involvement in multiple thymic maturation events is discussed.     

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.     

T cell receptor-negative thymocytes from SCID mice can be induced to enter the CD4/CD8 differentiation pathway

In order to investigate the role of T cell receptor (TcR) expression in thymocyte maturation, we have analyzed thymocytes from C.B-17/SCID mice, which are unable to productively rearrange their antigen receptor genes and fail to express TcR. Despite this defect, SCID thymocytes are functional as they produce lymphokines and proliferate in response to a variety of stimuli. Phenotypic analysis revealed that thymocyte populations from young adult SCID mice resemble thymocyte populations from normal embryonic mice in that they are large, Thy-1.2+, CD4-, CD8-, TcR- and enriched in CD5lo, IL2R+ and Pgp1+ cells. However, other TcR- populations normally present in adult mice (i.e., CD4-CD8+ cells and CD4+CD8+ cells) are absent from the thymus of TcR- adult SCID mice. To understand the basis of the developmental arrest of TcR- SCID thymocytes at the CD4-CD8- stage of differentiation, we analyzed thymi from the occasional "leaky" SCID mouse which possesses small numbers of TcR+ thymocytes. We found that the presence of TcR+ cells within a SCID thymus was invariably associated with the presence of CD4+ and/or CD8+ SCID thymocytes. Interestingly, however, the CD4+/CD8+ SCID thymocytes were not themselves necessarily TcR+. That is, emergence of SCID thymocytes expressing CD4/CD8 was tightly linked to the presence of TcR+ cells within that SCID thymus, but the SCID thymocytes that expressed CD4/CD8 were not necessarily the same cells that expressed TcR. Finally, we found that the introduction into TcR- SCID mice of normal bone marrow cells that give rise to TcR+ cells within the SCID thymus promoted the differentiation of SCID thymocytes into CD4-CD8+ and CD4+CD8+ TcR- cells. These data indicate that TcR+ cells within the thymic milieu provide critical signals which promote entry of CD4-CD8-TcR- precursor T cells into the CD4/CD8 differentiation pathway. When applied to differentiation of normal thymocytes, these findings may imply a critical role for early appearing CD4-CD8- TcR (gamma/delta)+ cells in initiating normal thymic ontogeny.     

Induction of NK1.1(+) alpha beta TCR(+) T cells by bypassing TCR signals in ZAP-70 deficient mice

The mechanism of development of a unique subset of T cells, thymic NK1.1(+) alpha beta T cells, has been poorly understood. We found that the development of thymic NK1.1(+) alpha beta T cells was defective in mice deficient in ZAP-70. Instead, an accumulation of NK1.1(+) TCR beta(-) NK-like population was detected in the thymus and spleen of the ZAP-70 deficient (ZAP -/-) mouse. In the present report, we examined whether biochemical treatments that replace TCR-mediated positive selection signals could restore the generation of thymic NK1.1(+) alpha beta T cells in ZAP -/- mice using the thymus organ culture. We found that a higher concentration of phorbol ester (PMA) than that required for CD4(+) T cell generation and ionomycin induced the generation of NK1.1(+) alpha beta T cells. Phenotypic analysis of the induced NK1.1(+) alpha beta T cell population suggested that these cells expressed CD8 but not CD4 molecules, which is a different characteristic from ordinary thymic NK1.1(+) alpha beta T cells. These results suggest that differential signaling is required for the generation of mainstream T cells and thymic NK1.1(+) alpha beta T cells.     

The in vivo development of human T cells from CD34(+) cells in the murine thymic environment

There is increasing evidence that human hematopoietic stem cells can develop into lymphocytes expressing T cell surface markers in the organ culture of murine embryonic thymic lobes. If human T cells with functional maturity are inducible from human stem cells in the mouse, it may be a useful model to investigate human T cell development and the human immune response in vivo. To approach this, we produced a hybrid cluster of murine fetal thymic epithelial cells and human cord blood-derived CD34(+) cells (hu/m cluster) using reaggregate thymic organ culture, and subsequently implanted it under the kidney capsule of NOD/SCID mice. The implanted hu/m cluster grew in volume under the kidney capsule and contained increased numbers of CD4(+)CD8(+)cells as well as CD4 or CD8 single-positive cells with low CD1a expression. These lymphocytes were also shown to possess activity for producing IL-2 and IL-4. Characteristics similar to human T cells also developed in the thymus of newly established mice lacking NK activity from NOD/SCID mice. These results indicate that functionally mature T cells can develop in vivo from human hematopoietic progenitors in the murine environment composed of thymic epithelial cells.     

CD28 controls the development of innate‐like CD8+ T cells by promoting the functional maturation of NKT cells

NK T cells(NKT cells) share functional characteristics and homing properties that are distinct from conventional T cells. In this study, we investigated the contribution of CD28 in the functional development of γδ NKT and αβ NKT cells in mice. We show that CD28 promotes the thymic maturation of promyelocytic leukemia zinc finger⁺ IL‐4⁺ NKT cells and upregulation of LFA‐1 expression on NKT cells. We demonstrate that the developmental defect of γδ NKT cells in CD28‐deficient mice is cell autonomous. Moreover, we show in both wild‐type C57BL/6 mice and in downstream of tyrosine kinase‐1 transgenic mice, a mouse model with increased numbers of γδ NKT cells, that CD28‐mediated regulation of thymic IL‐4⁺ NKT cells promotes the differentiation of eomesodermin⁺ CD44^high innate‐like CD8⁺ T cells. These findings reveal a previously unappreciated mechanism by which CD28 controls NKT‐cell homeostasis and the size of the innate‐like CD8⁺ T‐cell pool.     

Expression and selection of productively rearranged TCR beta VDJ genes are sequentially regulated by CD3 signaling in the development of NK1.1(+) alpha beta T cells

The generation of thymic NK1.1(+)alpha beta T (NKT) cells involves positive selection of cells enriched for V(alpha)14/V(beta)8 TCR by CD1d MHC class I molecules. However, it has not been determined whether positive selection is preceded by pre-TCR-dependent beta selection. Here we studied NKT cell development in CD3 signaling-deficient mice (CD3 zeta/eta(-/-) and/or p56(lck-/-)) and TCR alpha-deficient mice. In contrast to wild-type mice, NK1.1(+) thymocytes in CD3 signaling-deficient mice are approximately 10-fold reduced in number, do not exhibit V(alpha)14-J(alpha)281 rearrangements and fail to express alpha beta TCR at the cell surface. However, they exhibit TCR beta VDJ rearrangements and pre-T alpha mRNA, suggesting that they contain pre-NKT cells. Strikingly, pre-NKT cells of CD3 zeta/Lck double-deficient mice fail to express TCR beta mRNA and protein. Whereas in wild-type NKT cells TCR beta VDJ junctions are selected for productive V(beta)8 and against productive V(beta)5 rearrangements, V(beta)8 and V(beta)5 rearrangements are non-selected in pre-NKT cells of CD3 signaling-deficient mice. Thus, pre-NKT cell development in CD3 signaling-deficient mice is blocked after rearrangement of TCR beta VDJ genes but before expression of TCR beta proteins. Most NKT cells of TCR alpha-deficient mice exhibit cell surface gamma delta TCR. In contrast to pre-NKT cells of CD3 signaling-deficient mice, approximately 25% of NKT cells of TCR alpha-deficient mice exhibit intracellular TCR beta polypeptide chains. Moreover, both V(beta)8 and V(beta)5 families are selected for in-frame VDJ joints in the TCR beta(+) NKT cell subset of TCR alpha-deficient mice. The data suggest that CD3 signals regulate initial TCR beta VDJ gene expression prior to beta selection in developing pre-NKT cells.     

Comparison of intrahepatic lymphocytes from normal and growth hormone transgenic mice with chronic hepatitis and liver cancer.

Mice expressing an ovine growth hormone-mouse metallothionein promoter fusion gene (METoGH mice) develop chronic hepatitis which becomes progressively more severe over time, hepatocellular adenomas, and eventually carcinoma in the oldest animals. T-lymphocyte expression of activation/memory-associated markers was compared between liver and blood lymphocytes isolated from METoGH and non-transgenic mice at 7, 10 and 12 months of age. The percentage of intrahepatic lymphocytes (IHL) which were CD4+ was markedly diminished in METoGH mice at all times. CD4+ and CD8+ IHL in METoGH mice expressed Ly-6A/6D at increased density, and were CD45RBlo at later time-points. Ly-6C+ and NK1.1+ CD4+ cells, which are common in normal mouse liver, were found at decreased frequency in METoGH livers. Further analysis demonstrated that, as a proportion of total T-cell receptor (TCR) alpha beta cells, NK1.1+ TCR alpha beta int CD4+ cell numbers (NKT cells) were diminished in the livers of METoGH mice. Observations made in METoGH mice support the hypothesis that sustained liver inflammation and hepatocellular injury may be linked to liver cancer. Additionally, it is possible that the relative lack of NKT cells may create an environment permissive for the growth of liver tumours.     

Development of rat CD45+ 13-day-old fetal liver cells in SCID mouse fetal thymic organ cultures.

A phenotypic analysis of the lympho-hemopoietic cells which occur in the liver of 13-day-old fetal rats was achieved by flow cytometry in an attempt to further characterize the rat lymphoid progenitor cells. A small fraction of rat 13-day-old fetal liver (r13FL) cells, which weakly expressed the leukocyte common antigen CD45, constituted a homogeneous Thy-1(hi), CD71(-), CD44(+), MHC class I+, CD43(+) cell subpopulation negative for CD45RC, CD3, TCRalphabeta, TCRgammadelta, CD2, CD5, CD4, CD8, CD25, CD28, NKR-P1a and sIg. On the contrary, the CD45(-) cells were a heterogeneous cell subset which expressed Thy-1, CD71 and CD44 at distinct levels. After MACS separation, the CD45(+) r13FL cells, but not the CD45(-) cell subset, in vitro repopulated 14-day-old SCID mouse fetal thymic lobes providing rat T cells, both TCRalphabeta and TCRgammadelta, NK cells, and thymic dendritic cells but not B lymphocytes. Interestingly, NKR-P1a(lo) TCRalphabeta+ or TCRgammadelta+ cells developed in the xenogeneic cultures, and a rare CD4(+)CD8(+) double-positive subpopulation among the TCRgammadelta-expressing cells accumulated in the oldest cultures. These results are discussed from the double perspective of the nature of the precursor cells which colonize the fetal thymus and the relevance of the xenogeneic SCID mouse fetal thymic microenvironment for supporting rat lymphopoiesis.     

Activation of extrathymic T cells in the liver during liver regeneration following partial hepatectomy.

Partial hepatectomy was performed in C57BL/6 mice to investigate whether extrathymic T cells in the liver are activated during liver regeneration. This study is based on the finding that in mice with malignant tumours, extrathymic T cells in the liver are activated and yet the intrathymic pathway is suppressed (i.e. thymic atrophy). Attention was therefore focused on whether a similar phenomenon is induced during benign cell regeneration. Extrathymic T cells were identified using the two-colour immunofluorescence test for CD3 and interleukin-2 receptor beta-chain (IL-2R beta) [or lymphocyte function-associated antigen-1 (LFA-1)] antigens. They were estimated to be intermediate CD3+ [or T-cell receptor (TcR)] cells with high expressions of IL-2R beta and LFA-1. It was demonstrated that the proportion and number of intermediate CD3+ cells increased in the early phase (days 2-4 after partial hepatectomy), and that the thymus was inversely atrophic at the same time. This raised the possibility that extrathymic T cells may also be responsible for regulation of normal cell regeneration.     

Mouse hepatitis viral infection induces an extrathymic differentiation of the specific intrahepatic alpha beta-TCRintermediate LFA-1high T-cell population.

Mouse hepatitis virus type 3 (MHV3), a coronavirus, is an excellent model for the study of thymic and extrathymic T-cell subpopulation disorders induced during viral hepatitis. It was recently reported that, in addition to the intrathymic T-cell differentiation pathway, an extrathymic differentiation pathway of alpha beta-T-cell receptor (TCR) T lymphocytes exists in the liver, and becomes important under pathological situations such as autoimmune diseases, malignancies or hepatic bacterial infections. In the present study, we compared the phenotypes of resident hepatic, splenic or thymic T-cell subpopulations during the acute viral hepatitis induced by HMV3 in susceptible C57BL/6 mice. The number of liver-resident mononuclear cells (MNC) increased during the viral infection, while cellularity decreased. Single positive (SP) CD4+ cells strongly increased in both the liver and thymus, while double positive (DP) (CD4+ CD8+) cells, present in the liver and thymus of mock-infected mice, decreased in C57BL/6 mice during the viral infection. A shift of alpha beta-TCRintermediate T cells toward alpha beta-TCRhigh was evidenced in the liver and thymus of infected mice, but not in the spleen. The few alpha beta-TCRint double negative (DN) (CD4-CD8-) cells also decreased following viral infection. alpha beta-TCRint or high lymphocytes expressing high levels of leucocyte function antigen-1 (LFA-1) increased in the liver of MHV3-infected mice. In addition, liver-resident T cells expressed strongly the CD44 (Pgp-1) activation marker, suggesting that they were either activated or antigen experienced during the viral infection. No significant change in T-cell subpopulations was detected in the spleen, suggesting that MHV3 infection could induce an early in situ differentiation of resident hepatic T cells rather than a recruitment of lymphocytes from peripheral lymphoid organs.     

Critical role for invariant chain in CD1d-mediated selection and maturation of Vα14-invariant NKT cells

The development and maturation of Vα14 invariant (i)NKT cells in mice requires CD1d-mediated lipid antigen presentation in the thymus and the periphery. Cortical thymocytes mediate positive selection, while professional APCs are involved in thymic negative selection and in terminal maturation of iNKT cells in the periphery. CD1d requires entry in the endosomal pathway to allow antigen acquisition for assembly as lipid/CD1d complexes for display to iNKT cells. This process involves tyrosine-based sorting motifs in the CD1d cytoplasmic tail and invariant chain (Ii) that CD1d associates with in the endoplasmic reticulum. The function of Ii in iNKT cell thymic development and peripheral maturation had not been fully understood. Using mice deficient in Ii and the Ii-processing enzyme cathepsin S (catS), we addressed this question. Ii(-/-) mice but not catS(-/-) mice developed significantly fewer iNKT cells in thymus, that were less mature as measured by CD44 and NK1.1 expression. Ii(-/-) mice but not catS(-/-) mice developed fewer Vβ7(+) cells in their iNKT TCR repertoire than WT counterparts, indicative of a change in endogenous glycolipid antigen/CD1d-mediated iNKT cell selection. Finally, using a Mycobacterium tuberculosis infection model in macrophages, we show that iNKT developed in Ii(-/-) but not catS(-/-) mice have defective effector function. Our data support a role for professional APCs expressing Ii, but no role for catS in the thymic development and peripheral terminal maturation of iNKT cells.     

Regulatory roles of CD1d-restricted NKT cells in the induction of toxic shock-like syndrome in an animal model of fatal ehrlichiosis

CD1d-restricted NKT cells are key players in host defense against various microbial infections. Using a murine model of fatal ehrlichiosis, we investigated the role of CD1d-restricted NKT cells in induction of toxic shock-like syndrome caused by gram-negative, lipopolysaccharide-lacking, monocytotropic Ehrlichia. Our previous studies showed that intraperitoneal infection of wild-type (WT) mice with virulent Ehrlichia (Ixodes ovatus Ehrlichia [IOE]) results in CD8+ T-cell-mediated fatal toxic shock-like syndrome marked by apoptosis of CD4+ T cells, a weak CD4+ Th1 response, overproduction of tumor necrosis factor alpha and interleukin-10, and severe liver injury. Although CD1d-/- mice succumbed to high-dose IOE infection similar to WT mice, they did not develop signs of toxic shock, as shown by elevated bacterial burdens, low serum levels of tumor necrosis factor, normal serum levels of liver enzymes, and the presence of few apoptotic hepatic cells. An absence of NKT cells restored the percentages and absolute numbers of CD4+ and CD8+ T cells and CD11b+ cells in the spleen compared to WT mice and was also associated with decreased expression of Fas on splenic CD4+ lymphocytes and granzyme B in hepatic CD8+ lymphocytes. Furthermore, our data show that NKT cells promote apoptosis of macrophages and up-regulation of the costimulatory molecule CD40 on antigen-presenting cells, including dendritic cells, B cells, and macrophages, which may contribute to the induction of pathogenic T-cell responses. In conclusion, our data suggest that NKT cells mediate Ehrlichia-induced T-cell-mediated toxic shock-like syndrome, most likely via cognate and noncognate interactions with antigen-presenting cells.