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.     

Relative resistance of intermediate TCR cells to anti-CD3 mAb in mice in vivo and their partial functional characterization.

In addition to T cells differentiated in the thymus, T cells, possibly of extrathymic origin, were recently demonstrated in the liver of mice. These T cells are characterized by the expression of intermediate TCR and contain double-negative CD4-8- cells. A further characterization of intermediate TCR cells was carried out. When mice were injected ip with anti-CD3 mAb, bright TCR cells (i.e., regular T cells) and intermediate TCR cells were reduced on Day 3, depending on the amount of mAb. Because of the resistance of intermediate TCR cells to treatment, injection of an appropriate dose of antibody (i.e., 100 micrograms/mouse) eliminated most bright TCR cells, but not intermediate TCR cells. This dose revealed that a significant proportion of intermediate TCR cells also reside in the periphery. Hepatic and splenic mononuclear cells (MNC), in which intermediate TCR cells became abundant after treatment, showed a unique response to T cell mitogens and IL-2. Thus, the intermediate TCR cell-enriched population could not respond to a T cell mitogen, Con A, but responded well to a super antigen, staphylococcal enterotoxin B, and IL-2. MNC obtained from athymic nude mice, which comprise only intermediate TCR cells, responded in the same manner. These findings revealed that intermediate TCR cells are present not only in the liver but also in the periphery, and that they have a unique function distinct from regular T cells.     

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.     

DNA-protein cross-links in cells of internal organs of rats after fractional irradiation at various doses

The influence of daily fractional irradiation of male Wistar rats for 30 days on DNA-protein cross-links (DPC) in spleen, thymus, and liver cells was studied. The level of DPC depended strongly on the daily dose of irradiation and the studied organ. After irradiation at dose 0.5 Gy per day increased DPC level was detected in all organs. The highest level was in the lymphoid organs and the lowest in the liver. After irradiation at dose 0.3 Gy per day DPC formation was detected only in the thymus. The data suggest the existence of a dose threshold for DPC formation during fractional irradiation.     

Augmentation of innate immunity by low-dose irradiation

The effect of low-dose irradiation on the immune system was investigated in mice. When a 0.2 Gy dose of X-ray irradiation was administered every other day for a total of four times, the number of lymphocytes yielded by the liver, spleen and thymus decreased at the initial stage (around day 10). At this stage, NK cells, extrathymic T cells and NKT cells were found to be radioresistant. In other words, conventional lymphocytes were radiosensitive, even in the case of low-dose irradiation. However, the number of lymphocytes in all tested immune organs increased beyond the control level at the recovery stage (around day 28). Enumeration of the absolute number of lymphocyte subsets showed that the most prominently expanding populations were NK cells, extrathymic T cells and NKT cells, especially in the liver where primordial lymphocytes are primarily present. Functional and phenotypic activation of these populations also occurred at the recovery stage. It raised a possibility that an initial activation of macrophages by low-dose irradiation then mediated the present phenomenon. These results suggest that low-dose irradiation eventually has the potential to induce a hormesis effect on the immune system.     

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.     

T cell differentiation in lethally irradiated and reconstituted mice: stem cell influx demonstrated with immunoperoxidase technique.

Using both an anti-stem cell serum and an anti-T cell serum the influx of stem cells in mouse thymus and spleen after lethal irradiation and reconstitution was determined by immunoperoxidase staining. In both organs a rapid influx was observed reaching a maximum on Day 5 after irradiation and cell transfer. Thereafter a decline of stem cells took place while the number of T cells in the thymus increased gradually, reaching a maximum on Day 12. T cells could only be detected in the spleen after 3 weeks.     

The majority of lymphocytes in the bone marrow, thymus and extrathymic T cells in the liver are generated in situ from their own preexisting precursors.

Parabiotic pairs of B6.Ly5.1 and B6.Ly5.2 mice were used to investigate how lymphocytes in various organs and various lymphocyte subsets mixed with partner cells. The origin of partner cells was determined by using anti-Ly5.1 mAb in conjunction with immunofluorescence tests. Parabiosis was also produced after the irradiation of B6.Ly5.2 mice at various doses to prepare an immunosuppressive partner. Irrespective of irradiation, lymphocytes and other hematopoietic cells in the bone marrow and lymphocytes in the thymus showed a low mixture of partner cells in comparison with those of all other organs tested. On the other hand, lymphocytes in the blood, spleen, and lymph nodes became a half-and-half mixture of their own cells and partner cells by 14 days after parabiosis. Among lymphocyte subsets, intermediate CD3 cells (i.e., CD3int cells) and NKT cells (i.e., NK1.1+ subset of CD3int cells) in the liver also showed a low mixture of partner cells. The present results raise the possibility that lymphocytes in the bone marrow and thymus, and extrathymic T cells in the liver might be in situ generated from their own preexisting precursor cells. Another observation was that, after irradiation, partner cells showed accelerated mixture even if they showed a low mixture under non-irradiated conditions. However, only lymphocyte subsets with the same phenotype as those of preexisting cells entered the corresponding sites.     

Selective activation of extrathymic T cells in the liver by glycyrrhizin

Extrathymic pathways for T cell differentiation were recently demonstrated in the liver, intestine and omentum. In this study, glycyrrhizin (GL), a plant extract was investigated as to its effect on extrathymic T cells in the liver of mice. A new method using anti-LFA-1 mAb in conjunction with anti-TCR or -CD3 mAbs to sensitively identify such extrathymic T cells is included. Single injection and repeated injections of GL increased not only the number of total hepatic MNC but also the proportion of intermediate TCR cells, which are extrathymic T cells uniquely seen in the liver. In contrast to other tested reagents (e.g., lymphotoxin and estrogen) that activated the extrathymic T cells and simultaneously induced profound thymic atrophy, GL did not affect regular T cells in the thymus. The present results suggest that the selective activation of extrathymic T cells in the liver might be intimately related to the clinical effects of GL.     

Inhibition of the endocrine function of the rat thymus by x-irradiation

Whole-body X-irradiation of rats caused inhibition of endocrine function of thymus. The effect was a function of radiation dose and time after irradiation. 72 h following irradiation with doses of 6 and 8 Gy the thymus hormone content of blood serum fell down the level registered in the thymectomized animals. Cellularity of the thymus and spleen concurrently decreased. The kinetics of spontaneous chemiluminescence of blood serum, thymus and spleen cells characterized the hypersecretion of glucocorticoids in response to radiation activation of lipid peroxidation in radiosensitive rat organs.     

A Similar Expression Pattern of Adhesion Molecules between Intermediate TCR Cells in the Liver and Intraepithelial Lymphocytes in the Intestine

Two major populations of extrathymically differentiated T cells exist in the liver and intestine. Such T cells in the liver have TCR of intermediate intensity (i.e., intermediate TCR cells) and constitutively express IL-2 receptor β-chain (IL-2Rβ), whereas those in the intestine, especially intraepithelial lymphocytes, have TCR of bright intensity, consisting of a mixture of IL-2Rβ⁺ and IL-2Rβ^–. All mature thymocytes and thymus-derived T cells seen in the peripheral immune organs are TCR-bright⁺IL-2Rβ^– under resting conditions. When the expression pattern of adhesion molecules, including CD44, L-selectin, LFA-1 and ICAM-1, was compared among these T-cell populations, they displayed quite unique patterns of expression. All extrathymic T cells in the liver, intestine, and even other organs were CD44⁺L-selectin^– LFA-1⁺⁺ICAM-1⁺, whereas thymocytes and thymus-derived T cells were CD44^– L-selectin⁺LFA-1⁺ICAM-1^–. This inverted expression of adhesion molecules between extrathymic T cells and thymus-derived T cells might be associated with their unique tissue-localization.     

Repopulation of the mouse thymus after sublethal fission neutron irradiation. I. Sequential appearance of thymocyte subpopulations

The T cell composition of the thymus of sublethal fission neutron-irradiated CBA/H mice was analyzed with cytofluorometry and immunohistology, using monoclonal antibodies directed to the cell surface antigens Thy-1, T-200, MT-4, Lyt-1, Lyt-2, and MEL-14. The results of this investigation show that whole body irradiation with 2.5 Gy fission neutrons results in a severe reduction and degeneration of the cortex, whereas the medulla is affected to a lesser extent. Irradiation selects, within 24 hr, for a population of dull Thy-1+, bright T-200+, bright Lyt-1+ cells localized in the medulla. Phenotype analysis of the regeneration of the thymus, which starts at about 5 days after irradiation, reveals the sequential appearance of: 1) "null" cells, i.e., lymphoblasts negative for all tested antigens, mainly in the subcapsular area but also in the medulla; 2) Thy-1+ "only" and T-200+ "only" cells in the subcapsular area; 3) Thy-1+, T-200+ cells; and 4) Thy-1+, T-200+, MT-4+, Lyt+ cells in the cortex. In addition, an increased MEL-14 expression is observed in correlation with the expression of Thy-1 and T-200 determinants during the regeneration of the thymus. From day 10 on up to at least 150 days after irradiation, no differences can be observed in the thymus of irradiated and age-matched sham-irradiated control mice, as measured by the expression and distribution of Thy-1, T-200, MT-4, Lyt-1, Lyt-2, and MEL-14 antigens. The observed sequence in phenotype shift in the regeneration of the thymus after irradiation is discussed in view of recently published data on the differentiation of the T cell system.     

Repopulation of the mouse thymus after sublethal fission neutron irradiation. II. Sequential changes in the thymic microenvironment

The stromal cells of the thymus of sham-irradiated and sublethal fission neutron-irradiated CBA/H mice were analyzed with immunohistology, using monoclonal antibodies directed to I-A and H-2K antigens as well as specific determinants for cortical and medullary stromal elements. In the control thymuses, I-A expression in the thymus shows a reticular staining pattern in the cortex and a confluent staining pattern in the medulla. In contrast, H-2K expression is mainly confluently located in the medulla. Whole body irradiation with 2.5 Gy fission neutrons reduces within 24 hr the cortex to a rim of vacuolized "nurse cell-like" epithelial cells, largely depleted of lymphoid cells. The localization of I-A antigens changes in the cortex and I-A determinants are no longer associated with or localized on epithelial reticular cells. Medullary stromal cells, however, are more or less unaffected. A high rate of phagocytosis is observed during the first 3 days after irradiation. About 5 days after irradiation, the thymus becomes highly vascularized and lymphoid cells repopulate the cortex. The repopulation of the thymic cortex coincides with the appearance of a bright H-2K expression in the cortex which is associated with both stromal cells as well as lymphoid blasts. During the regeneration of the thymus, the thymic stromal architecture is restored before the expression of cell surface-associated reticular MHC staining patterns. The observed sequential changes in the thymic microenvironment are related to the lymphoid repopulation of the thymus.     

Tissue distribution and appearance in ontogeny of alpha/beta T cell receptor (TCR2) in chicken

We have performed immunoperoxidase staining on cryostat tissue sections and immunofluorescence analysis on cell suspensions to identify cells expressing the alpha/beta T cell antigen receptor during ontogeny and adult life in chickens. We used the mouse monoclonal antibody, TCR2, which was previously shown to recognize the alpha/beta TCR in chickens. TCR2+ cells were observed in thymic cortex and medulla and in T-dependent areas of spleen, intestine, and cecal tonsils of young adult chickens. Some TCR2+ cells were found in the cortex of bursal follicles and in liver. The first TCR2+ cells appear in thymus on Day 13 of the embryonic life and it is only after hatching that TCR2+ cells begin to migrate to the periphery.     

Unusual T cell populations in adult murine bone marrow. Prevalence of CD3+CD4-CD8- and alpha beta TCR+NK1.1+ cells

The T cell populations present in normal murine bone marrow have not been previously analyzed in detail, mainly because of their relative rarity. In order to permit such analyses, bone marrow T cells were enriched by depleting Mac1-positive cells, which constitute 65 to 90% of bone marrow cells (BMC), and then studied by two-color flow cytometry. Analysis of the remaining cells revealed that the T cell profile of adult murine bone marrow is markedly different from that of other lymphoid organs. A very high proportion of bone marrow CD3+ cells (approximately one-third) are CD4-CD8-. CD3+CD4-CD8- cells are much more concentrated among BMC T cells than among thymocytes or splenic T cells, suggesting that bone marrow may be either a site of extrathymic TCR gene rearrangement, or a major site to which such cells home from the thymus. The expression of NK1.1 was also evaluated on Mac1-depleted BMC populations. Surprisingly, up to 39% of alpha beta TCR+ BMC were found to express NK1.1. Most alpha beta TCR+NK1.1+ BMC also expressed CD4 or CD8. NK1.1+ alpha beta TCR+ cells represented a much greater proportion of BMC T cells than of other lymphoid (splenocyte or thymocyte) T cell populations. Mac1-depleted BMC of nude mice contained very few cells with this phenotype. These results are consistent with the hypothesis that NK1.1+ alpha beta TCR+ cells are generated primarily in the thymus of normal animals and migrate preferentially to bone marrow, where they may function as regulatory elements in hematopoiesis.     

NKT cells in the rat: organ-specific distribution of NK T cells expressing distinct V alpha 14 chains

Rat invariant TCR alpha-chains and NKT cells were investigated to clarify whether CD1d-mediated recognition by NKT cells is conserved further in evolution. Rats had multiple-copies of TRAV14 genes, which can be categorized into two types according to the diversity accumulated in the CDR2 region. Rats retained invariant TCR alpha forms with the homogeneous junctional region similar to mouse invariant TRAV14-J281. The proportion of invariant TCR among V alpha 14+ clones was 12.9% in the thymus and increased in the periphery, 31% in the spleen and 95% in hepatic sinusoidal cells. The invariant TRAV14-J281 was expressed by liver sinusoidal and splenic NKT cells with CD8, CD44high, and TCR V beta 8. Type 1 invariant TCR alpha was expressed more frequently in hepatic lymphocytes, while type 2 invariant TCR alpha was expressed predominantly in the spleen. Both types of cells cytolyzed to and were stimulated to proliferate by CD1d-expressing cells in a CD1d-restricted manner. These results suggested that rat NKT cells bearing distinct V alpha 14 chains are distributed in a tissue-specific pattern. NKT cell populations in rats were more variable than those in mice, indicating that they play novel roles in nature. The implication of the molecular interaction between the structurally diverse invariant TCR alpha and CD1d/ligand complex in different organs is discussed.     

Clonal analysis of the peripheral T cell compartment of the SCID-hu mouse.

Severe combined immunodeficiency (SCID) mice can be transplanted successfully with human fetal liver and thymus (SCID-hu mice). Precursor cells derived from the fetal liver differentiate in the thymus and migrate into the blood as mature T cells. In the present paper, the peripheral T cell compartment of such mice was studied. Peripheral WBC were activated by PHA and cultured in the presence of irradiated human feeder cells. The resultant cell population consisted exclusively of human CD1- CD2+ CD3+ CD7+ T lymphocytes; up to 4% of the T cells expressed the TCR gamma delta, whereas 95 to 100% were TCR alpha beta +. The CD4bright (42 to 66%) and CD8bright (30 to 54%) populations coexpressed variable but low levels of CD8 and CD4, respectively. The T cell cultures from the SCID-hu mice did not display reactivity towards the autologous human EBV-transformed B cell lines (B-LCL). On the other hand, these human T cells proliferated and were cytotoxic against allogeneic human B-LCL. T cell clones were established from cultured SCID-hu T cells. All T cell clones were TCR alpha beta + CD3+ CD2+; 61% of the clones were CD4+ CD8-, 27% were CD8+ CD4-, 11% were CD8+ CD4lo, and 2% were CD4+ CD8lo. None of these clones recognized the autologous B-LCL established from the fetal human donor. Fourteen of 100 T cell clones had specific alloreactivity, as tested on a panel of five B-LCL. Of these 14, two CD8+ CD4lo and two CD8+ CD4- clones were cytotoxic and did not proliferate in response to specific stimulator cells. Furthermore, two CD4+ CD8lo and eight CD4+ CD8- clones proliferated specifically in response to alloantigens. In conclusion, the peripheral human T cells of SCID-hu animals are functional and their TCR repertoire is polyclonal, alloreactive, and devoid of self-reactive cells. Therefore, the SCID-hu mouse can be a suitable model for the study of alloreactivity and allotolerance in vivo, as well as for the study of negative selection in the human thymus.     

Prolonged increase in T-cell receptor (TCR) variant fractions of spleen T lymphocytes in pregnant mice after gamma irradiation

To investigate the relationship between the radiation-induced increase of T-cell receptor (TCR) defective variant fractions and physiological status such as pregnancy, C57BL/ 6N mice were irradiated with 3 Gy of gamma rays at various days of gestation, just before and just after pregnancy. While the highest level of variant fractions in spleen T lymphocytes appeared at 9 days postirradiation and resolved fairly rapidly for nonpregnant mice, the increased variant fractions for pregnant mice irradiated at 16.5 days of gestation reached a plateau at 14 days postirradiation and remained at high levels until 28 days after irradiation. Therefore, variant fractions 28 days postirradiation were measured to determine the overall effect of radiation on the kinetics of TCR variant fractions during gestation. There was no significant difference in the baseline TCR variant fraction between unirradiated nonpregnant and pregnant mice. TCR variant fractions after irradiation were about twofold higher in pregnant mice (from 10.5 days of gestation until delivery) than those in nonpregnant mice. Both gamma radiation and pregnancy caused a decrease in the proportion of na?ve T-cell subsets and an increase in TCR variant fractions of na?ve T cells. In addition, the prolonged postirradiation increase in the TCR variant fractions of pregnant mice was associated with an increase in serum progesterone level. Differences between pregnant and nonpregnant mice in the kinetics of postirradiation restoration of T-cell systems may be involved in producing the differences in residual TCR variant fractions of these mice.     

Role of the complementarity-determining region 3 (CDR3) of the TCR-beta chains associated with the V alpha 14 semi-invariant TCR alpha-chain in the selection of CD4+ NK T Cells

The NK1.1(+)TCRalphabeta(int) CD4(+), or double negative T cells (NK T cells) consist of a mixture of CD1d-restricted and CD1d-unrestricted cells. The relationships between CD4(+)NK1.1(+) T cells and conventional T cells are not understood. To compare their respective TCR repertoires, NK1.1(+)TCRalphabeta(int), CD4(+) T cells have been sorted out of the thymus, liver, spleen, and bone marrow of C57BL/6 mice. Molecular analysis showed that thymus and liver used predominantly the Valpha14-Jalpha281 and Vbeta 2, 7, and 8 segments. These cells are CD1d restricted and obey the original definition of NK T cells. The complementarity-determining region 3 (CDR3) sequences of the TCR Vbeta8.2-Jbeta2.5 chain of liver and thymus CD4(+) NK T cells were determined and compared with those of the same rearrangements of conventional CD4(+) T cells. No amino acid sequence or usage characteristic of NK T cells could be evidenced: the Vbeta8.2-Jbeta2.5 diversity regions being primarily the same in NK T and in T cells. No clonal expansion of the beta-chains was observed in thymus and liver CD1d-restricted CD4(+)NK T cells, suggesting the absence of acute or chronic Ag-driven stimulation. Molecular analysis of the TCR used by Valpha14-Jalpha281 transgenic mice on a Calpha(-/-) background showed that the alpha-chain can associate with beta-chains using any Vbeta segment, except in NK T cells in which it paired predominately with Vbeta 2, 7, and 8(+) beta-chains. The structure of the TCR of NK T cells thus reflects the affinity for the CD1d molecule rather than a structural constraint leading to the association of the invariant alpha-chain with a distinctive subset of Vbeta segment.     

带γδ和αβ受体的T细胞（TCR）在人胎儿组织内分布的研究

本文用细胞免疫化学方法,在冰冻切片上,检测了胎儿不同组织和器官内带γδ和αβ受体的Ｔ细胞（ＴＣＲ）的分布,结果发现ＴＣＲ细胞的分布与,般Ｔ细胞不同,有相对固定的分布区,如胸腺内ＴＣＲ细胞主要分布在皮筋质交界处和髓质部;脾脏内的γδＴ主要位于边缘区,而αβＴ主要位于动脉周围淋巴鞘,在红髓和血窦两种细胞共存;淋巴结内只有少数ＴＣＲ细胞位于滤泡间或副皮质,滤泡内则未见。消化管内的ＴＣＲ细胞主要分布在小肠的固有膜,而胃、大肠和阑尾的固有膜内很少见;肝内ＴＣＲ细胞主要集中在血管和血窦周围;皮肤切片内的少数ＴＣＲ细胞见于真皮内,表皮基底层细胞内未见。这些细胞在胎儿期的免疫皮应及其生理功能还不清楚。