Major histocompatibility complex class I related molecules control the development of CD4+8- and CD4-8- subsets of natural killer 1.1+ T cell receptor-alpha/beta+ cells in the liver of mice

Normal mouse liver contains prominent subsets of CD4+8- and CD4-8- T cell receptor (TCR)-alpha/beta+ cells with intermediate TCR levels. We show here that these cells express the natural killer (NK)1.1 surface antigen and have a restricted TCRV beta repertoire that is highly skewed to V beta 7 and V beta 8. Surprisingly, both CD4+8- and CD4-8- subsets of NK1.1+TCR-alpha/beta+ cells are absent in the liver of beta 2-microglobulin deficient mice, which do not express major histocompatibility complex (MHC) class I or "class I-like" molecules. Analysis of reciprocal radiation bone marrow chimeras established with beta 2-microglobulin deficient and wild-type mice demonstrates that MHC class I expression on radiosensitive (presumably hematopoietic) cells is required for the development of NK1.1+TCR-alpha/beta+ cells in the liver. In the liver of MHC class II deficient mice, the CD4+8- and CD4-8- subsets of NK1.1+TCR-alpha/beta+ cells develop normally. Collectively our data suggest that NK1.1+TCR-alpha/beta+ cells in liver require interaction with a MHC class I-related ligand on hematopoietic cells for their development. This unusual property of liver T cells is shared by a subset of CD4-8-NK1.1+TCR-alpha/beta+ thymocytes, suggesting a common lineage independent of the mainstream of T cell development.

Selective expansion of activated V delta 4+ cells during experimental infection of mice with Leishmania major

Previous work from this laboratory has revealed that infection of mice with Leishmania major leads to an expansion of gamma delta+ T cells in the spleen. Further examination of the gamma delta+ T cells expanding in infected mice has shown that the majority of these cells in the spleen, lymph nodes, blood and liver expressed the V delta 4 gene segment. Cell cycle analysis, using propidium iodide incorporation, demonstrated that while only 1% of alpha beta+ T cells in the spleen were in either S + G2/M phase, up to 10% of the gamma delta+ T cells were in cycling phase 8 weeks after infection. Comparison of the state of activation of the two populations in different organs after infection, confirmed that gamma delta+ T cells are actively dividing in lymph nodes, liver and blood, but not in the thymus or among intraepithelial lymphocytes. Examination of the expression of different activation markers on the surface of gamma delta+ T cells in the spleen of both normal and chronically infected BALB/c mice by FACS analysis, revealed increased expression of LFA-1, CD25, CD44, 4F2, CD28 and the heat-stable antigen, whereas Thy-1 and CD5 decreased. Collectively, these results suggest an oligoclonal expansion and activation of gamma delta+ T cells in response to L. major infection.

Expression of the CD28 costimulatory molecule on subsets of murine intestinal intraepithelial lymphocytes correlates with lineage and responsiveness

The CD28 antigen has been recently demonstrated to be a costimulatory molecule and is expressed by almost all thymic and peripheral T cell receptor (TcR) alpha beta+ and gamma delta+ cells in the mouse system. We show here that expression of CD28 is heterogeneous among murine intestinal intraepithelial lymphocytes (IEL). Whereas some TcR alpha beta-expressing IEL subsets such as CD4+8- and CD4-8 alpha+ beta+ cells express CD28 at the same levels as their phenotypic counterparts in lymph node, other subsets of TcR alpha beta cells (including CD4-8 alpha+ beta- and CD4+8 alpha+ beta- cells) as well as TcR gamma delta+ IEL fail to express CD28. Parallel experiments using aged BALB/c-nu/nu mice indicated that CD28 expression patterns among IEL are quite similar to those of normal BALB/c mice. Furthermore, forward light scatter analysis showed that CD28- cells are considerably larger than CD28+ cells in the gut, although cycling cells were rare in both subsets. Finally CD28- cells in the gut did not proliferate or produce IL-2 upon stimulation by anti-CD3 monoclonal antibodies (mAb) and phorbol 12-myristate 13-acetate, whereas CD28+ cells in the gut and lymph nodes responded to these stimuli. The response of the CD28+ cells was enhanced by anti-CD28 mAb. These results suggest that CD28- IEL (CD4- 8 alpha+ beta- cells, and some CD4+ 8 alpha+ beta- cells) may follow a different developmental pathway from that of CD28+ IEL in a thymus-independent environment, and that expression of CD28 correlates with responsiveness of the cells to triggering via the TcR-CD3 complex.

Induction of specific tolerance by hepatic double-negative CD4-8- alpha beta T cells of mice immunized with allogeneic cells via the portal vein in vivo [corrected]

We immunized AKR/n (H-2k) spleen cells in BALB/c (H-2d) mice via the portal vein (pv) and investigated the role of hepatic mononuclear cells (MNC) in the induction of alloantigen-specific immune tolerance. MNC in the liver and spleen of pv-administered mice were demonstrated to abrogate the responses to AKR/n alloantigens in allogeneic MLR. On the contrary, MNC in the liver and spleen of mice administered subcutaneously with the same antigens showed greater responses than those of control mice. The tolerance induced by pv administration was alloantigen-specific and appeared earlier in hepatic MNC than in splenic MNC. Furthermore, hepatic MNC of pv-administered mice had a suppressive effect when these cells were added to allogeneic MLR, in which mitomycin C (MMC)-treated AKR/n splenic MNC were used as stimulator and control BALB/c splenic MNC were used as responder. Splenic MNC of pv-administered mice and hepatic MNC of control mice did not show such suppressive effects. Such suppression was alloantigen-specific, since no suppression was induced when hepatic MNC of pv-administered mice were added to a system using MMC-treated C57BL/6 (H-2b) splenic MNC. The alloantigen-specific suppression induced by hepatic MNC was abrogated by a depletion of TcR-alpha beta + cells but not of CD4+, CD8+, nor B220+ cells from hepatic MNC. These results suggested that alloantigen-specific suppressor cells appeared predominantly in the hepatic MNC of pv-administered mice and displayed the phenotype of TcR-alpha beta +CD4-8- double-negative T cells, although alloantigen-specific tolerance was induced in both hepatic and splenic MNC.

Elevated production of interleukin 6 by hepatic MNC correlates with ICAM-1 expression on the hepatic sinusoidal endothelial cells in autoimmune MRL/lpr mice

MRL/lpr mice, which are a model of SLE and rheumatoid arthritis in humans, develop profound lymphadenopathy resulting from the accumulation of CD3+ 4-8- double-negative (DN) alpha beta T cells in peripheral lymphoid tissues. We previously indicated that these DN alpha beta T cells preferentially proliferate in the liver and migrate to the periphery. In this study, we analyzed whether any kind of cytokine was produced by hepatic mononuclear cells (MNC) in MRL/lpr mice. The evidence obtained indicates that interleukin 6 (IL-6) was vigorously produced by hepatic MNC in diseased MRL/lpr mice under unstimulated conditions. MNC in the spleen of these mice produced small amounts of IL-6, while those in the lymph nodes did not produce any appreciable amounts of IL-6. These activities of hepatic MNC in diseased MRL/lpr mice were almost completely neutralized by anti-mouse IL-6 monoclonal antibody (mAb). On the other hand, immunohistochemical staining of light- and electron-microscopic analyses revealed that the intracellular cell adhesion molecule 1 (ICAM-1) was expressed on the hepatic sinusoidal endothelial cells of diseased MRL/lpr mice. Moreover, ICAM-1 was newly induced in the hepatic sinusoids of control C3H/He mice by an intravenous injection of 50 units of recombinant mouse IL-6. These data suggest that ICAM-1 expressed on the hepatic sinusoidal endothelial cells in MRL/lpr mice is induced by IL-6, which is produced by hepatic MNC, and that such ICAM-1 may be responsible for the saturation of inflammatory cells and the proliferation of lymphocytes in the liver of MRL/lpr mice.

Age-associated increase of CD5+ B cells in the liver of autoimmune (NZB x NZW) F1 mice

The liver has been demonstrated to be a major site for extrathymic differentiation of T cells. In this study, an identification of CD5+ B cells, which are responsible for the onset of autoimmune disease by virtue of autoantibody production, was performed in autoimmune (NZB x NZW) F1 mice. An age-associated increase of CD5+ B cells was demonstrated in the liver of these mice. Although CD5+ B cells (i.e., CD5+IgM+ and CD5+B220+) constituted a minor population of hepatic mononuclear cells (MNC) (< 5%) when mice were young (8 weeks), a large population of CD5+ B cells (10 to 30% of whole MNC) was identified in the liver of mice aged 25 to 30 weeks after the onset of disease. Such age-dependent increase of CD5+ B cells was not observed in any other strains including NZB, NZW, C3H/He and BALB/c mice. The phenotype of hepatic CD5+ B cells was the same as that of CD5+ B cells in the peritoneal cavity and spleen, showing dull-CD5, bright-IgM and dull-B220. High levels of CD5+ B cells were observed in the peritoneal cavity and liver, but not in the spleen nor in any other lymphoid organs in mice aged 30 weeks. Radioimmunoassay of autoantibodies in the 5-day culture supernatants demonstrated that hepatic MNC were unable to produce any amounts of IgM- and IgG-autoantibodies against double-stranded DNA and single-stranded DNA, despite the increased proportion of CD5+ B cells. On the other hand, peritoneal exudate cells produced only IgM-, but not IgG-, autoantibodies, whereas splenic cells were able to produce both IgM- and IgG-autoantibodies.(ABSTRACT TRUNCATED AT 250 WORDS)

Ontogeny and development of extrathymic T cells in mouse liver

We previously demonstrated that the liver may be a major site of extrathymic T-cell differentiation in mice. In the present study, the ontogeny and subsequent development of such T cells in the liver and other organs were investigated. This study was possible because these T cells have T-cell receptors (TcR) of intermediate intensity (i.e. intermediate TcR cells) and constitutively express a high level of interleukin-2 receptor beta chain (IL-2R beta). Therefore the two-colour staining for CD3 (or alpha beta TcR) and IL-2R beta identifies even a small proportion of intermediate TcR cells. The total numbers of mononuclear cells obtained from the liver, thymus and spleen varied from foetal to adult life. Especially in the liver, many haematopoietic cells were present in the parenchymal space at the foetal stage. There were no lymphocytes in the sinusoidal lumen at this period. In contrast, lymphocytes appeared in the hepatic sinusoids after birth and increased with ageing. Phenotypic analysis revealed that intermediate TcR cells appeared in the liver and spleen on Day 4 after birth. Bright TcR cells of thymic origin were also present in the peripheral organs on Day 4. Thereafter, intermediate TcR cells increased in the liver, whereas bright TcR cells increased in the periphery as a function of age. Similarly, thymectomized and congenitally athymic mice had mainly intermediate TcR cells in the liver and, to some extent, periphery. It is concluded that intermediate TcR cells, possibly of extrathymic origin, are generated only after birth and expand with ageing.

Lymphotoxin activates hepatic T cells and simultaneously induces profound thymic atrophy

We have recently demonstrated that the liver may be a major site of extrathymic T-cell differentiation. This hepatic pathway was shown to be activated in mice injected with heat-killed bacteria. It is conceivable that the resulting activation of macrophages or lymphocytes, and the production of cytokines may be responsible for a subsequent activation of hepatic T cells. In this context, we investigated the possibility of whether certain cytokines may activate hepatic T cells. It was demonstrated that the administration of lymphotoxin [tumour necrosis factor-beta (TNF-beta)] more than doubled the number of hepatic mononuclear cells (MNC) yielded 3-5 days after the treatment. More strikingly, such treatment induced profound thymic atrophy and resulted in a decrease of more than 95% in the number of thymocytes. Spontaneous proliferation in an in vitro culture of hepatic MNC from treated mice increased, and inversely such activity of thymocytes decreased. The increased number of hepatic MNC was mainly due to an increase in intermediate alpha beta T-cell receptor (TcR) cells, which are extrathymic T cells uniquely seen in the liver. On the other hand, the thymic atrophy was caused by the prompt apoptotic death of dull alpha beta TcR cells with double-positive (DP) CD4+ CD8+ phenotype. These results indicate that lymphotoxin may be one of the factors that activates extrathymic T cells in the liver and at the same time inhibits intrathymic T-cell differentiation.

Age-dependent increase of extrathymic T cells in the liver and their appearance in the periphery of older mice

The liver is a major site of generation of extrathymic T cells with unique properties (e.g., expressing intermediate TCR and containing self-reactive clones). We investigated herein whether the levels of extrathymic alpha beta T cells varied in various organs as a function of age. A systematic examination of the number of mononuclear cells in various organs of BALB/c mice revealed that the number of hepatic MNC increased with age whereas the number of thymocytes decreased. These changes were more striking in mice fed under conventional conditions than under specific pathogen-free condition. The age-dependent changes in the number of mononuclear cells in the spleen and lymph nodes were minimal. Although the total proportion of alpha beta T cells in each organ remained constant, the staining patterns of TCR-alpha beta as shown by immunofluorescence profiles varied. The most prominent change was that intermediate TCR-alpha beta cells, which constituted a small population in the liver of young mice, expanded in the liver of older mice. Intermediate TCR cells appeared even in the periphery of older mice. These findings were confirmed by the appearance of extrathymic T cells with other unique properties, e.g., double-negative CD4-8- phenotype and CD44 expression. In athymic nude mice, only intermediate TCR cells were present in the liver and periphery. An age-dependent increase of intermediate TCR cells was also seen in these mice. Taken together with the result of bromodeoxyuridine-injection experiment, which showed an intensive in vivo proliferation of cells in the hepatic sinusoids, extrathymic T cells may differentiate predominantly in the liver and appeared even to the periphery in older mice.

Age-dependent increase of extrathymic T cells in the liver and their appearance in the periphery of older mice

The liver is a major site of generation of extrathymic T cells with unique properties (e.g., expressing intermediate TCR and containing self-reactive clones). We investigated herein whether the levels of extrathymic alpha beta T cells varied in various organs as a function of age. A systematic examination of the number of mononuclear cells in various organs of BALB/c mice revealed that the number of hepatic MNC increased with age whereas the number of thymocytes decreased. These changes were more striking in mice fed under conventional conditions than under specific pathogen-free condition. The age-dependent changes in the number of mononuclear cells in the spleen and lymph nodes were minimal. Although the total proportion of alpha beta T cells in each organ remained constant, the staining patterns of TCR-alpha beta as shown by immunofluorescence profiles varied. The most prominent change was that intermediate TCR-alpha beta cells, which constituted a small population in the liver of young mice, expanded in the liver of older mice. Intermediate TCR cells appeared even in the periphery of older mice. These findings were confirmed by the appearance of extrathymic T cells with other unique properties, e.g., double-negative CD4-8- phenotype and CD44 expression. In athymic nude mice, only intermediate TCR cells were present in the liver and periphery. An age-dependent increase of intermediate TCR cells was also seen in these mice. Taken together with the result of bromodeoxyuridine-injection experiment, which showed an intensive in vivo proliferation of cells in the hepatic sinusoids, extrathymic T cells may differentiate predominantly in the liver and appeared even to the periphery in older mice.

Activation of extrathymic T cells in the liver and reciprocal inactivation of intrathymic T cells by bacterial stimulation

We recently demonstrated that the liver might be a major site of extrathymic T cell differentiation, including both alpha beta and gamma delta T cells. This extrathymic pathway in the liver, which has a relatively minor role in normal young mice, is activated in mice under bacterial stimulation. In the present study, we investigated how the extrathymic and intrathymic T cell differentiations were mutually related in mice injected intravenously with 10(8) heat-killed Escherichia coli. Three days after stimulation, extrathymic T cells in the liver were observed to be prominently activated in terms of increases in the total number of cells yielded, spontaneous cell proliferation in in vitro culture, and intermediate alpha beta TCR cells. Intermediate alpha beta TCR cells were extrathymic T cells uniquely seen in the liver. However, at the same time intrathymic T cells were profoundly inactivated, showing decreases in the number of thymocytes (more than 90% atrophy), spontaneous cell proliferation, and dull TCR cells with double positive CD4+8+ phenotype. With time, these responses were reversed and normal states were regained. These results suggested that extrathymic and intrathymic T cells are always activated or inactivated in the opposite direction, and that the liver and the thymus are dynamic immune organs. It raises the possibility that the extrathymic T cell differentiation in the liver and the intrathymic T cell differentiation may be reciprocally regulated by certain factors.

Estrogen administration activates extrathymic T cell differentiation in the liver

In addition to T cell differentiation in the thymus, we have recently reported that extrathymic T cell differentiation occurs preferentially in the sinusoids of the liver. Although this extrathymic pathway is relatively minor in normal mice, it becomes predominant in mice with autoimmune diseases, athymic mice, and aged mice. In the present study, injection of normal male C3H/He mice, 6-8 wk of age, with 1 mg of estrogen resulted in an increase in mononuclear cells (MNC) yielded from the liver and a drastic decrease in thymocytes approximately 10 d after such injection. This unique modulation was not observed with hydrocortisone injection (5 mg/mouse, i.p.) nor with irradiation (5 Gy/mouse). Rather, these immunosuppressive treatments induced a simultaneous decrease in cell number in both the liver and thymus. A time-kinetics study on the cell number and spontaneous cell proliferation revealed that an increase in spontaneous cell proliferation in the liver preceded the increase in the number of liver MNC, and a decrease in spontaneous cell proliferation in the thymus preceded the decrease in the number of thymocytes. At this time, an enrichment of alpha/beta T cells with intermediate T cell receptors (TCRs), including forbidden T cell oligoclones and V beta 8+ cells, which are characterized as extrathymic alpha/beta T cells with unique properties, took place in the liver. On the other hand, the thymic atrophy induced by estrogen resulted in a prominent decrease in immature double-positive (CD(4+)8+) alpha/beta T cells with dull TCRs. These results indicate that estrogen administration activates an extrathymic pathway of T cell differentiation in the liver and reciprocally inactivates the intrathymic pathway. As extrathymic T cells have unique characteristics such as autoreactivity, the present findings might be intimately related to a female predominance of autoimmune diseases and suggest a possible role of estrogen in this phenomenon.

Details of an isolation method for hepatic lymphocytes in mice

The liver comprises a unique lymphocyte population, i.e., extrathymic alpha beta T cells with TcR of intermediate intensity. In the present study, we attempted to determine what pretreatments were appropriate to isolate hepatic mononuclear cells (MNC) containing such intermediate alpha beta TcR cells in mice. Hepatic MNC were isolated from untreated mice and mice subjected to either bleeding or liver perfusion, and the intermediate alpha beta TcR cells in each preparation were identified. For reasons of simplicity, cell purity and cell yields, hepatic lymphocytes should be obtained from mice subjected to total bleeding. Additional information on extrathymic alpha beta T cells obtained by using the recommended method is also presented.

Expansion of the population of double negative CD4-8- T alpha beta-cells in the liver is a common feature of autoimmune mice

There have been several reports that double negative (DN) CD4-8- T alpha beta-cells might be responsible for the onset of autoimmune diseases in humans and mice. We previously revealed that such DN T alpha beta-cells are generated in the liver of autoimmune MRL-lpr/lpr mice. In the present study, we further characterize the histology of the liver in these mice by light and electron microscopic studies. An intensive accumulation of mononuclear cells in the liver was demonstrated and a significant proportion of these mononuclear lymphocytes was found to intimately interact with Kupffer cells or endothelial cells of the hepatic sinusoids. The majority of such lymphocytes were TcR+CD4-8-Pgp-1+ alpha beta-cells. Identification of DN T alpha beta-cells was then performed in various autoimmune model mice. Interestingly, all autoimmune mice tested (i.e., MRL-lpr/lpr, C3H/HeJ-gld/gld, BXSB, NOD, MRL(-)+/+ and NZB/W F1 mice), showed an increased proportion of DN T alpha beta-cells (greater than 11% among all MNC) in the liver when they became old and diseased. On the other hand, young and old normal mice and young autoimmune mice before the onset of disease did not have such a high proportion of DN T alpha beta-cells (less than 10%) in the liver. Among autoimmune mice, MRL-lpr/lpr and C3H/HeJ-gld/gld mice had lymphadenopathy, which consisted of DN T alpha beta-cells (greater than 25%), after the onset of disease. Autoimmune mice of the other strains had neither lymphadenopathy nor DN T alpha beta-cells in the periphery, even when they were diseased. These results suggest that the expansion of the DN T alpha beta-cell population in the liver is a common feature of autoimmune mice, irrespective of the information of lymphadenopathy.

Expansion of the population of double negative CD4-8- T alpha beta-cells in the liver is a common feature of autoimmune mice

There have been several reports that double negative (DN) CD4-8- T alpha beta-cells might be responsible for the onset of autoimmune diseases in humans and mice. We previously revealed that such DN T alpha beta-cells are generated in the liver of autoimmune MRL-lpr/lpr mice. In the present study, we further characterize the histology of the liver in these mice by light and electron microscopic studies. An intensive accumulation of mononuclear cells in the liver was demonstrated and a significant proportion of these mononuclear lymphocytes was found to intimately interact with Kupffer cells or endothelial cells of the hepatic sinusoids. The majority of such lymphocytes were TcR+CD4-8-Pgp-1+ alpha beta-cells. Identification of DN T alpha beta-cells was then performed in various autoimmune model mice. Interestingly, all autoimmune mice tested (i.e., MRL-lpr/lpr, C3H/HeJ-gld/gld, BXSB, NOD, MRL(-)+/+ and NZB/W F1 mice), showed an increased proportion of DN T alpha beta-cells (greater than 11% among all MNC) in the liver when they became old and diseased. On the other hand, young and old normal mice and young autoimmune mice before the onset of disease did not have such a high proportion of DN T alpha beta-cells (less than 10%) in the liver. Among autoimmune mice, MRL-lpr/lpr and C3H/HeJ-gld/gld mice had lymphadenopathy, which consisted of DN T alpha beta-cells (greater than 25%), after the onset of disease. Autoimmune mice of the other strains had neither lymphadenopathy nor DN T alpha beta-cells in the periphery, even when they were diseased. These results suggest that the expansion of the DN T alpha beta-cell population in the liver is a common feature of autoimmune mice, irrespective of the information of lymphadenopathy.

Reciprocal T cell responses in the liver and thymus of mice injected with syngeneic tumor cells

We investigated the T cell responses in various tissues, especially in the liver and thymus, of mice injected with syngeneic tumors. This study was undertaken since recent evidence indicated that the liver is one of the important immune organs for T cell proliferation. When C3H/He mice were intraperitoneally injected with mitomycin-treated syngeneic MH134 tumors (1 x 10(7)/mouse), a transient increase of liver mononuclear cells (MNC) was induced, showing a peak at Day 4 after injection. Histological study of such liver showed a sinusoidal dilatation and an accumulation of MNC in the sinusoids. The most predominant MNC induced were double negative (CD4-8-) alpha beta T cells and gamma delta T cells. These gamma delta T cells varied, showing unique time-kinetics. Despite a continuous increase of whole liver MNC and alpha beta T cells, the proportion of gamma delta T cells in the liver decreased beginning 4 days after injection. In contrast with the response in the liver, a striking decrease in the cell number of thymocytes was induced after tumor injection, showing a basal level at Day 6. This hypocellularity in the thymus appears to be an inverted response of the lymphocytosis in the liver. At this time, a corresponding decrease in the proportion of double positive (CD4+8+) T cells was always seen in the thymus. Analysis of cell proliferative response showed that the increase of liver MNC after tumor injection was accompanied by augmented proliferation, whereas the decrease of thymocytes was accompanied by depressed proliferation. The present results indicate that there exists a unique, reciprocal response of T lymphocytes between the liver and thymus, and that the presence of tumor appears to stimulate T cell response in the liver but alternatively inactivates such response in the thymus.

Unusual alpha beta-T cells expanded in autoimmune lpr mice are probably a counterpart of normal T cells in the liver

Autoimmune MRL-lpr/lpr (lpr) mice develop severe lymphadenopathy, characterized by the accumulation of alpha beta-T cells with CD4-8- double negative (DN) phenotype, at the onset of disease. We previously demonstrated that the liver is a major site for the proliferation of such DN alpha beta-T cells. Herein, we further demonstrate that a large proportion of alpha beta-T cells in the liver and other organs, except the thymus, of lpr mice have unique properties, such as DN phenotype, relatively dull TCR intensity, a preponderance of V beta 8+ cells, and Pgp-1 expression. Interestingly, alpha beta-T cells in the liver of normal mice were found to consist of T cells with intermediate intensity of TCR (i.e., brighter than thymic dull TCR and lower than thymic bright TCR) as well as with bright intensity of TCR in the immunofluorescence test. These hepatic alpha beta-T cells with intermediate TCR in normal mice were found to have properties similar to those of alpha beta-T cells in lpr mice. These results suggest that abnormal alpha beta-T cells in lpr mice are a counterpart of normal T cells in the liver. An abnormal expansion of such T cells in the liver might be fundamental to the pathogenesis involved in these autoimmune mice.

Unusual alpha beta-T cells expanded in autoimmune lpr mice are probably a counterpart of normal T cells in the liver

Autoimmune MRL-lpr/lpr (lpr) mice develop severe lymphadenopathy, characterized by the accumulation of alpha beta-T cells with CD4-8- double negative (DN) phenotype, at the onset of disease. We previously demonstrated that the liver is a major site for the proliferation of such DN alpha beta-T cells. Herein, we further demonstrate that a large proportion of alpha beta-T cells in the liver and other organs, except the thymus, of lpr mice have unique properties, such as DN phenotype, relatively dull TCR intensity, a preponderance of V beta 8+ cells, and Pgp-1 expression. Interestingly, alpha beta-T cells in the liver of normal mice were found to consist of T cells with intermediate intensity of TCR (i.e., brighter than thymic dull TCR and lower than thymic bright TCR) as well as with bright intensity of TCR in the immunofluorescence test. These hepatic alpha beta-T cells with intermediate TCR in normal mice were found to have properties similar to those of alpha beta-T cells in lpr mice. These results suggest that abnormal alpha beta-T cells in lpr mice are a counterpart of normal T cells in the liver. An abnormal expansion of such T cells in the liver might be fundamental to the pathogenesis involved in these autoimmune mice.

The appearance of T cells bearing self-reactive T cell receptor in the livers of mice injected with bacteria

We demonstrated in the present study that with bacterial stimulation, an increased number of alpha/beta T cells proliferated in the liver of mice and that even T cells bearing self-reactive T cell receptor (TCR) (or forbidden T cell clones), as estimated by anti-V beta monoclonal antibodies in conjunction with immunofluorescence tests, appeared in the liver and, to some extent, in the periphery. The majority (greater than 80%) of forbidden clones induced had double-negative CD4-8-phenotype. In a syngeneic mixed lymphocyte reaction, these T cells appear to be self-reactive. Such forbidden clones and normal T cells in the liver showed a two-peak pattern of TCR expression, which consisted of alpha/beta TCR dull and bright positive cells, as seen in the thymus. A systematic analysis of TCR staining patterns in the various organs was then carried out. T cells from not only the thymus but also the liver had the two-peak pattern of alpha/beta TCR, whereas all of the other peripheral lymphoid organs had a single-peak pattern of TCR. However, T cells in the liver were not comprised of double-positive CD4+8+ cells, which predominantly reside in the thymus. The present results therefore suggest that T cell proliferation in the liver might reflect a major extrathymic pathway for T cell differentiation and that this hepatic pathway has the ability to produce T cells bearing self-reactive TCR under bacterial stimulation, probably due to the lack of a double-positive stage for negative selection.

Predominant appearance of gamma/delta T lymphocytes in the liver of mice after birth

gamma/delta T lymphocytes residing in the liver of mice were systematically characterized with respect to their age-related variation, phenotype and V gene segment usage of gamma/delta T cell receptor (TcR). Previous human and murine studies have shown that a high proportion of gamma/delta T cells reside in the liver and that such liver gamma/delta T cells have lymphoblastic morphology and can spontaneously proliferate in vitro. In the present study, a predominant appearance of gamma/delta T cells (up to 23% among CD3+ cells) in the liver was confirmed in 4-week old mice of various strains. gamma/delta T cells in the liver preferentially co-expressed CD8 antigens, whereas the vast majority of gamma/delta T cells in the spleen lacked the CD8 antigens. The identification of gamma/delta T cells in various lymphoid and non-lymphoid organs also revealed the liver to be one of the organs where gamma/delta T cell are most abundant. The level of such liver gamma/delta T cells showed a clear age-related variation. In the fetal stage and just after birth, gamma/delta T cells were not detectable in the liver (less than 0.2%). However, a significantly higher percentage of gamma/delta T cells among both the total population of mononuclear cells and CD3+ cells was detected in the liver of young 2- to 8-week-old mice; this percentage subsequently declined. As the total number of liver mononuclear cells increased in aged mice, the absolute number of liver gamma/delta T cells also increased as a function of age. V gene segment usage analysis by the polymerase chain reaction method demonstrated that V gamma 1 or V gamma 2/V delta 6 were preferentially used by liver gamma/delta T cells. The age-related increase of gamma/delta T cells was more prominent in the liver of athymic nude mice, and such gamma/delta T cells highly co-expressed the CD8 antigens and also utilized the V gamma 1 or V gamma 2/V delta 6 for gamma/delta Tcr. The predominant appearance of unique gamma/delta T cells in the liver, which was inversely related to the existence of the thymus, indicates that these gamma/delta T cells may differentiate extrathymically in the liver.

[Gamma delta TCR cells in hepatic sinusoids and intestinal intraepithelia]

We provided here the conception that the liver is an important immune organ after birth. On the other hard, it is well established that the liver in the fetal stage works as a hematopoietic organ. Although a significant number of gamma delta TCR cells are distributed in epithelia of the skin, intestine and reproductive organs, the liver is also one of the most predominant organs of gamma delta TCR cells. The percentages of gamma delta TCR cells in MNC of hepatic sinusoids increased up to 16.0% in young mice aged 4 wk, and approximately 40% of such gamma delta TCR cells expressed the CD8 antigens. V gene segment usage analysis by the PCR method demonstrated that a unique set of V gamma 2/V delta 6 was preferentially used by hepatic gamma delta TCR cells. The predominant appearance of unique gamma delta TCR cells in hepatic sinusoids of mice, including nude mice, proposed us the possibility that these gamma delta TCR cells may differentiate non-thymus dependently in the liver. The lymphocytes in the hepatic sinusoids may be intimately related to the antigens come from the intestine and to the lymphocytes sensitized there. Therefore, we introduced recent evidences about gamma delta T cells in the intestine and discussed their connection with the hepatic gamma delta T cells.

Inhibition of type 1 diabetes in BB rats with recombinant human tumor necrosis factor-alpha

We previously reported that streptococcal preparation (OK-432), which is a TNF inducer, inhibits insulitis and development of autoimmune diabetes in nonobese diabetic (NOD) mice and Bio-Breeding (BB) rats, as animal models of insulin-dependent diabetes mellitus. We have recently shown that recombinant human (h)TNF-alpha also suppresses development of diabetes in NOD mice. In this study we have extended our observation on TNF to BB rats in order to see whether TNF generally inhibits autoimmune diabetes. A total of 5 x 10(4) U of rhTNF-alpha was administered i.p., twice a week to male and female BB rats from 4 to 27 wk of age. The cumulative incidence of diabetes by 27 wk of age in nontreated rats was 36.4% (8/22), whereas that in hTNF-alpha-treated rats was 0% (0/21) (p less than 0.001). The hTNF-alpha-treated rats did not lose body weight and maintained normal blood glucose concentrations. Immunologic and histologic examinations were performed at the end of the experiment. Spleen cell cytotoxicities for NK-sensitive YAC-1 and rat insulinoma (RINm5F) cells in hTNF-alpha-treated rats significantly decreased in comparison with nontreated and nondiabetic BB rats. Intensity of insulitis was also inhibited in hTNF-alpha-treated rats. Interestingly, a huge hepatomegaly and splenomegaly was found in two of the 21 hTNF-alpha-treated rats. The latter consisted of W3/13dull+ and W3/25dull+ cells, which did not exhibit cytotoxicity for either YAC-1 or RINm5F cells. These results indicate that the chronic and systemic administration of TNF has a regulatory role in autoimmune diabetes in BB rats as well as in NOD mice, and that these animals may have a defect in TNF-mediated immunoregulation.

Inhibition of type 1 diabetes in BB rats with recombinant human tumor necrosis factor-alpha

We previously reported that streptococcal preparation (OK-432), which is a TNF inducer, inhibits insulitis and development of autoimmune diabetes in nonobese diabetic (NOD) mice and Bio-Breeding (BB) rats, as animal models of insulin-dependent diabetes mellitus. We have recently shown that recombinant human (h)TNF-alpha also suppresses development of diabetes in NOD mice. In this study we have extended our observation on TNF to BB rats in order to see whether TNF generally inhibits autoimmune diabetes. A total of 5 x 10(4) U of rhTNF-alpha was administered i.p., twice a week to male and female BB rats from 4 to 27 wk of age. The cumulative incidence of diabetes by 27 wk of age in nontreated rats was 36.4% (8/22), whereas that in hTNF-alpha-treated rats was 0% (0/21) (p less than 0.001). The hTNF-alpha-treated rats did not lose body weight and maintained normal blood glucose concentrations. Immunologic and histologic examinations were performed at the end of the experiment. Spleen cell cytotoxicities for NK-sensitive YAC-1 and rat insulinoma (RINm5F) cells in hTNF-alpha-treated rats significantly decreased in comparison with nontreated and nondiabetic BB rats. Intensity of insulitis was also inhibited in hTNF-alpha-treated rats. Interestingly, a huge hepatomegaly and splenomegaly was found in two of the 21 hTNF-alpha-treated rats. The latter consisted of W3/13dull+ and W3/25dull+ cells, which did not exhibit cytotoxicity for either YAC-1 or RINm5F cells. These results indicate that the chronic and systemic administration of TNF has a regulatory role in autoimmune diabetes in BB rats as well as in NOD mice, and that these animals may have a defect in TNF-mediated immunoregulation.

Identification of activated T cell receptor gamma delta lymphocytes in the liver of tumor-bearing hosts

T cell receptor (TcR)gamma delta cells are known to be a minor population of T lymphocytes in the blood (less than 10%) and other peripheral lymphoid organs in healthy donors. We demonstrated here that a large proportion of TcR gamma delta cells, i.e., up to 30% of mononuclear cells (MNC) were detectable in the liver, but not other lymphoid organs of cancer patients. More importantly, the majority of such TcR gamma delta cells (greater than 70%) were shown to be lymphoblastic by electron microscopy. An activation marker of T lymphocytes, Leu-19 (CD56) was also highly expressed on the hepatic TcR gamma delta cells. The possibility of hepatic TcR gamma delta cells being activated was further examined in mice. C3H/He mice injected with syngeneic tumor cells were demonstrated to have an increased number of liver MNC; such MNC showed an ability to proliferate in vitro. These mice eventually had a considerable proportion of TcR gamma delta cells in the liver, showing activation markers, the Ia and LFA-1 antigens. These results suggest that the liver may be an important organ for activation and probably expansion of TcR gamma delta cells especially in tumor bearing hosts.

Liver is a possible site for the proliferation of abnormal CD3+4-8- double-negative lymphocytes in autoimmune MRL-lpr/lpr mice

MRL-lpr/lpr mice develop a severe autoimmune disease that resembles systemic lupus erythematosis in humans. The predominant immunological feature in these mice is the development of peripheral lymphadenopathy due to the expansion of an unusual T cell subset (TCR-alpha/beta +5CD3+4-8-B220+), which may be related to the onset of their autoimmunity. However, it is unknown whether such abnormal lymphocytes proliferate in the specific organs or not. We demonstrated in the present study that the number of liver nonparenchymal mononuclear cells (MNC) in the diseased MRL-lpr/lpr mice was 10 times greater than that of control MRL-+/+ mice. Moreover, the freshly isolated liver MNC of MRL-lpr/lpr mice vigorously proliferated in vitro and consisted of abnormal CD3+4-8- lymphocytes. Such in vitro proliferation was not observed in the MNC of other peripheral lymphoid organs. A potent natural cytotoxicity was also confined to the liver MNC in MRL-lpr/lpr mice. In vivo injection of [3H]TdR demonstrated that liver MNC incorporated [3H]TdR; such incorporation showed a peak on day 1, and the MNC-incorporated [3H]TdR appeared in the lymph nodes as late as day 5 after the injection. These results suggest that the liver is a possible site for the proliferation of abnormal lymphocytes, which may migrate thereafter into the peripheral organs in MRL-lpr/lpr mice.