Functionally active CD8alphabeta+ TCRgammadelta intestinal intraepithelial lymphocytes in athymic nu/nu mice

Murine intestinal intraepithelial lymphocytes (IEL) encompass a high proportion of TCRgammadelta cells. A vast majority of these TCRgammadelta IEL express CD8alpha, but not CD8beta (CD8alphaalpha homodimer), and are considered to develop in intestinal epithelial layers independently of a functional thymus. Here we show that TCRgammadelta cells expressing both CD8alpha and CD8beta (CD8alphabeta heterodimer) appear in athymic nu/nu mice, although their appearance is random. The IEL comprising CD8alphabeta(+) TCRgammadelta cells expressed pronounced cytolytic and IFN-gamma-producing activities after TCRgammadelta ligation, which were markedly stronger than activities of IEL lacking CD8alphabeta(+) TCRgammadelta cells. Purified CD8alphabeta(+) TCRgammadelta cells expressed strong cytolytic activities and produced large quantities of IFN-gamma after TCR engagement. CD8alphabeta(+) TCRgammadelta cells were also identified among IEL from euthymic C57BL/6 mice, although their abundance varied among individual animals. However, cytolytic and IFN-gamma-producing activities in euthymic C57BL/6 mice were markedly lower than those in athymic nu/nu mice. Our findings suggest that CD8alphabeta(+) TCRgammadelta cells can develop in the intestine independently of a functional thymus/thymic epithelial cells and that they perform biological functions in situ.     

Most parasite-specific CD8+ cells in Trypanosoma cruzi-infected chronic mice are down-regulated for T-cell receptor-alphabeta and CD8 molecules

The present study shows that CD8+ T lymphocytes expressing low levels of T-cell receptor (TCR)alphabeta, CD8 and CD3 accumulate in the spleen, blood, peritoneum and liver, but not in the lymph nodes of mice chronically infected with Trypanosoma cruzi. Analysis of spleen lymphocytes reveals that most CD8LOW TCRLOW T cells have an experienced phenotype (CD44HIGH CD62LLOW and CD45RA,B,CLOW). These cells have small size, lack activation markers such as CD69, CD25 and CD11b (Mac-1), and do not spontaneously secrete cytokines, suggesting they are at the resting state. When stimulated in vitro with T. cruzi-infected macrophages, TCRLOW CD8LOW T cells behave as parasite-specific memory cells, readily responding with interferon-gamma (IFN-gamma) production. Indeed, among parasite-activated CD8+ lymphocytes, IFN-gamma production was mostly due to TCRLOW CD8LOW cells. Upon in vitro stimulation with anti-CD3/CD28 monoclonal antibodies, down-regulated cells produce IFN-gamma and tumour necrosis factor-alpha, but not interleukin IL-10 or IL-4. Our results indicate that despite parasite persistence, most T. cruzi-specific experienced CD8+ cells are resting. Nevertheless, when encountering infected macrophages these cells differentiate to Tc1 effectors.     

CCL25/CCR9 promotes the induction and function of CD103 on intestinal intraepithelial lymphocytes

The integrin CD103 and the chemokine receptor CCR9 are co‐expressed on small intestinal CD8⁺ intraepithelial lymphocytes (IEL), naïve murine CD8⁺ T cells and by a small population of effector/memory CD8⁺ T cells, indicating a potential role for CCR9 in regulating CD103 expression and function. Here, we demonstrate that CD103, in contrast to CCR9, is down‐regulated on CD8⁺ T cells following their activation in mesenteric lymph nodes and that effector CD8⁺ T cells upon initial entry into the small intestinal epithelium are CCR9⁺CD103^–. CD103 was rapidly induced on wild‐type CD8⁺ T cells subsequent to their entry into the small intestinal epithelium, however, CCR9^–/– CD8⁺ T cells exhibited a significant delay in CD103 induction at this site. In addition, the CCR9 ligand, CCL25, that is constitutively expressed in the small intestinal epithelium, induced transient, dose‐dependent and pertussis toxin‐sensitive CD103‐mediated adhesion of CD8⁺ small intestinal IEL to a murine E‐cadherin human Fc (mEFc) fusion protein. Together, these results demonstrate a role for CCR9/CCL25 in promoting the induction and function of CD103 on CD8⁺ IEL and suggest that this chemokine receptor/chemokine pair may function to regulate lymphocyte‐epithelial interactions in the small intestinal mucosa.     

L-selectin expression on thymic emigrants defines two distinct tissue-migration pathways

We have studied the appearance and phenotype of recent thymic emigrants in blood, spleen and lymph nodes (LN) of neonatal lambs. Using in situ labelling of thymocytes with fluoroscein isothiocyanate (FITC), we examined the expression of the LN homing receptor L-selectin on alphabeta and gammadelta subsets of recent thymic emigrants 24 hr after labelling. There were marked differences in the proportions of CD4+, CD8+ and gammadelta T-cell receptor (TCR+) cells exported from the thymus to spleen compared to lymph nodes. Spleen was enriched in CD8+ and gammadelta TCR+ emigrants while LN were enriched in CD4+ emigrants. There were also marked differences in the expression of L-selectin by emigrants homing to spleen compared with those homing to lymph nodes. While the majority of thymic emigrants in LN expressed L-selectin, considerably fewer emigrants in spleen were L-selectin+. The presence of large numbers of CD8+ L-selectin- and gammadelta TCR+ L-selectin- thymic emigrants homing to spleen raises the possibility that unique homing receptor specificities underpin the migration of T cells to spleen as distinct from lymph nodes.     

Phenotype, functions and fate of adoptively transferred tumor draining lymphocytes activated ex vivo in mice with an aggressive weakly immunogenic mammary carcinoma

Background

Regression of established tumors can be induced by adoptive immunotherapy with tumor draining lymph node lymphocytes activated with bryostatin and ionomycin. We hypothesized that tumor regression is mediated by a subset of the transferred T lymphocytes, which selectively infiltrate the tumor draining lymph nodes and proliferate in vivo.

Results

Adoptive transfer of B/I activated tumor draining lymphocytes induces regression of advanced 4T1 tumors, and depletion of CD8, but not CD4 T cells, abrogated tumor regression in mice. The predominant mediators of tumor regression are CD8+ and derived from CD62L^- T cells. Transferred lymphocytes reached their peak concentration (10.5%) in the spleen 3 days after adoptive transfer and then rapidly declined. Adoptively transferred cells preferentially migrated to and/or proliferated in the tumor draining lymph nodes, peaking at day 5 (10.3%) and remained up to day 28. CFSE-stained cells were seen in tumors, also peaking at day 5 (2.1%). Bryostatin and ionomycin-activated cells proliferated vigorously in vivo, with 10 generations evident in the tumor draining lymph nodes on day 3. CFSE-stained cells found in the tumor draining lymph nodes on day 3 were 30% CD8⁺, 72% CD4⁺, 95% CD44⁺, and 39% CD69⁺. Pre-treatment of recipient mice with cyclophosphamide dramatically increased the number of interferon-gamma producing cells.

Conclusions

Adoptively transferred CD8+ CD62L^low T cells are the principal mediators of tumor regression, and host T cells are not required. These cells infiltrate 4T1 tumors, track preferentially to tumor draining lymph nodes, have an activated phenotype, and proliferate in vivo. Cyclophosphamide pre-treatment augments the anti-tumor effect by increasing the proliferation of interferon-gamma producing cells in the adoptive host.     

CD4+CD8+ murine intestinal intraepithelial lymphocytes

We have studied a population of CD4+ intestinal intraepithelial lymphocytes using two-color flow cytometric analyses, and in highly purified fluorescent-activated cell-sorted preparations. Although CD4+ T cells present within the epithelial immune compartment comprised only approximately 10-20% of the total intestinal epithelial lymphoid cells, an unusually high proportion of those CD4+ lymphocytes expressed a CD4+CD8+ phenotype which is rarely encountered in peripheral T cells. By comparison, CD4+ lymphocytes from spleen or lymph nodes existed exclusively as single-positive T cells. Analyses of CD4 and CD8 expression on lymphocytes from Peyer's patches, the lamina propria, and IEL indicated that CD4+CD8+ lymphocytes were unique to the IEL. Using CD4+CD8+ preparations obtained by fluorescent-activated cell sorting, CD4+CD8+ epithelial T cells were found also to express CD3 and Thy-1 surface markers. This heretofore undescribed extrathymic population of double-positive T cells constitutes a unique peripheral T cell subset which may be involved in intestinal T cell maturation and development, or could represent a highly specialized effector population.     

T-cell receptor-gamma delta association with lymphocyte populations in sheep intestinal mucosa.

T cells expressing T-cell receptor (TcR)-gamma delta and CD8 represent a significant population in mouse and chicken intra-epithelial lymphocytes (IEL) but represent a minor population in human IEL. We examined the TcR-gamma delta usage and co-expression of CD5, CD4, CD8 and major histocompatibility complex (MHC) class II on isolated sheep IEL and lamina propria lymphocytes (LPL), and compared them with the TcR-gamma delta + cells in peripheral blood, intestinal lymph and jejunal Peyer's patches (PP). There were a number of notable differences. TcR-gamma delta + cells comprised 18% of IEL and 10% of LPL. Among the population of TcR-gamma delta + IEL, 24% were CD8+ and 54% were CD5+, which contrasts with the TcR-gamma delta + cells in blood and intestinal lymph that were universally CD5+ CD4- CD8-. A notable feature of the IEL was the presence of distinct CD8+ and TcR-gamma delta + populations that lacked CD5. Also a high percentage of IEL and LPL were CD2+ and MHC class II+. Analysis of the expression of MHC class II on T-cell subsets, as an indicator of activation, showed that 60-95% of the various IEL and LPL subsets were MHC class II+ compared with only 5-40% in jejunal PP, lymph nodes, spleen and blood. Therefore, it is possible that the circulating TcR-gamma delta + and CD8+ cells that localize in the gut epithelium might become activated and stop the expression of CD5 under the influence of the local microenvironment. These cells appear not to emigrate while still expressing the TcR-gamma delta + (CD8+) CD5- MHC class II+ phenotype. Our data, together with those from other studies, show that there is much heterogeneity in the use of TcR-gamma delta and accessory T-cell molecules by IEL.     

Microbial colonization induces oligoclonal expansions of intraepithelial CD8 T cells in the gut

Two populations of CD8(+) IEL generally express restricted, but apparently random and non-overlapping TCR repertoires. Previous studies in mice suggested that this could be explained by a dual origin of CD8(+) IEL, i.e. that CD8alphabeta(+) IEL derive from a few peripheral CD8(+) T cell lymphoblasts stimulated by microbial antigens in gut-associated lymphoid tissue, whereas CD8alphaalpha(+) IEL descend from an inefficient intestinal maturation pathway. We show here that the gut mucosa, instead, becomes seeded with surprisingly broad and generally non-overlapping CD8 IEL repertoires and that oligoclonality is induced locally after microbial colonization. In germ-free (GF) rats, both CD8alphabeta(+) and CD8alphaalpha(+) IEL displayed surprisingly diverse TCR Vbeta repertoires, although beta-chain diversity tended to be somewhat restricted in the CD8alphaalpha(+) subset. CDR3 length displays in individual Vbeta-Cbeta and Vbeta-Jbeta combinations generally revealed polyclonal distributions over 6-11 different lengths, similar to CD8(+) lymph node T cells, and CDR3beta sequencing provided further documentation of repertoire diversity. By contrast, in ex-GF rats colonized with normal commensal microflora, both CD8alphabeta(+) and CD8alphaalpha(+) IEL displayed oligoclonal CDR3 length distributions for most of the Vbeta genes analyzed. Our data suggest that microbial colonization induces apparently random clonal expansions of CD8alphabeta(+) and CD8alphaalpha(+) IEL locally in the gut.     

Characterization of Gut-Associated Lymphoid Tissue (GALT) of Normal Rhesus Macaques

This study characterizes the gut-associated lymphoid tissue (GALT) of normal healthy rhesus macaques and compares the percentages of T and B cell subsets to those of systemic lymphoid tissue. Lymphocytes from the systemic lymphoid tissue (spleen, axillary, and inguinal lymph nodes), mesenteric lymph nodes (MLN), and intestinal epithelium (IEL) and lamina propria (LPL) of the jejunum, ileum, and colon were examined from both adult and juvenile, normal rhesus macaques. Lymphocytes were analyzed for expression of CD2, CD3, CD4, CD8, CD25, γδ TCR, and CD20 by two- or three-color flow cytometric analysis. Sections of jejunum, ileum, and colon were examined for CD3, CD20, and CD103 expression by immunohistochemistry. Peyer's patches were also examined for CD3, CD4, CD8, and CD20 expression by immunohistochemistry. Most IEL and LPL were CD103⁺, CD3⁺T cells with significantly fewer CD20⁺B cells. The IEL were predominantly CD3⁺CD8⁺(63–80%), with very few CD4⁺cells, whereas CD4:CD8 ratios in the LPL ranged from 0.74 to 1.3. Three to 38% of the IEL were γδ TCR positive, but γδ expression was rare in the LPL and MLN. γδ TCR expression was also higher in the IEL of younger animals. LPL had higher expression of CD25 compared to IEL and systemic tissues, particularly in aged animals. CD4⁺CD8⁺, double-positive and CD3⁺CD4⁻CD8⁻double-negative cells were also observed in GALT. These results demonstrate that GALT of rhesus macaques is remarkably similar to that of humans, further justifying the use of these animals as models for various intestinal disorders.     

Novel phenotypes and migratory properties distinguish memory CD4 T cell subsets in lymphoid and lung tissue

Memory T cells are heterogeneous in expression of lymph node homing receptors, delineating "central-memory" (TCM, CD62Lhi/CCR7+) and "effector-memory" (TEM, CD62Llo/CCR7-) subsets that migrate to lymphoid and non-lymphoid tissues, respectively. It is not known how these subsets arise or how homing receptor expression and tissue origin determine their functional and migratory properties. Here, we investigated the role of CD62L expression in the generation, function, distribution and migration of heterogeneous memory CD4 T cells specific for influenza hemagglutinin (HA). We found that CD62Lhi and CD62Llo memory subsets are generated independent of CD62L expression by the activated precursor, and both subsets distribute into spleen and lung. Functionally, spleen- and lung-derived CD62L memory subsets produce effector cytokines at similar kinetics but differ strikingly in cell surface phenotype and migration: the CD62Llo memory subset expresses a classic memory phenotype (CD45RBlo/CD44hi/CD11a(hi)), while the CD62Lhi subset expresses an unconventional phenotype (CD45RBhi/CD44int/CD11a(int)), defining a new polyclonal memory subset. The CD62Lhi subset also trafficked more efficiently than CD62Llo cells into lymph nodes; however, only lung but not spleen CD62Llo memory T cells homed to lung. Our results reveal novel phenotypic heterogeneity of memory CD4 T cells co-segregating with CD62L expression and tissue-specific tropism of non-lymphoid memory CD4 T cells.     

Memory CD4 cells do not migrate into peripheral lymphnodes in the absence of antigen.

Memory T cells are thought to protect against previously encountered pathogens in part by preferentially recirculating through the lymphoid tissues where they were primed and where challenge with antigen (Ag) is likely to occur. In this study, we examined the distribution of memory CD4 cells after priming, and analyzed their capacity to localize in lymph nodes after transfer to normal and Ag-primed recipients. Immunization induced a high frequency of Ag-specific CD4 cells in the primary response in draining lymph nodes and spleen. Thereafter, the numbers in lymph nodes declined dramatically whereas frequencies in the spleen were unchanged, suggesting that memory CD4 cells primarily reside in or recirculate through the spleen. Indeed, memory CD4 cells, unlike naive CD4 cells, failed to home to lymph nodes after adoptive transfer to normal recipients and were detected predominantly in the spleen for extended periods, suggesting that recirculation through lymph nodes was limited. Memory cells also did not home to lymph nodes recipients in response to specific Ag, but subsequently, recruitment that could be blocked with monoclonal antibodies to CD44 and LFA-1 and was independent of naive cells did occur. The data indicate that memory and naive CD4 cells can be distinguished on the basis of their patterns of circulation.     

Characterization of CD4+ T cells in mouse bone marrow. I. Increased activated/memory phenotype and altered TCR Vbeta repertoire

A significant proportion of memory B cells home to bone marrow (BM) which is a major site of anamnestic antibody responses in mice. We hypothesized that memory T cells likewise accumulate in BM perhaps to provide help for antibody production, and that the compartment of CD4+ T cells in BM of unimmunized mice would be enriched for memory phenotype cells that might have been activated by environmental antigens. The phenotype of activated/memory CD4+ lymphocytes has been defined as CD44hi CD45RBlo CD62L-. Conversely, the phenotype of immunologically naive cells is CD44lo CD45RBhi CD62L+. Flow cytrometric analysis of tissue from normal, adult C57BL/6 mice identified 1-2 % CD3+CD4+ cells in BM. Up to 40 % of CD3+CD4+ cells in the BM expressed the activated/memory phenotype compared with < or = 10% in the spleen and lymph nodes. Analysis of TCR Vbeta repertoire revealed that expression of Vbeta3 and Vbeta7 genes was increased as much as fourfold in BM compared to the periphery; most of this increase was within the CD44hi T cells. The accumulation of activated/memory T cells and clonotypic expansion(s) was not seen in the BM of germ-free mice, indicating that it reflects the history of the animal's exposure to antigens. Finally, immunization of mice which express a transgenic T cell receptor specific for ovalbumin peptide resulted in appearance of antigen-specific T cells with activated/memory phenotype in the BM.     

Accumulation of intestinal intraepithelial lymphocytes in association with lack of polymeric immunoglobulin receptor

Immunoglobulin A (IgA) is transported by the polymeric immunoglobulin receptor (pIgR) through epithelial cells of the gut, the airways, the tear and salivary glands, and the lactating mammary gland, and IgA accumulates in serum and the intestinal lamina propria of pIgR-deficient (pIgR(-/-)) mice. Intraepithelial lymphocytes (IEL) increased in number and Thy-1(+)CD8alphabeta(+)TCRalphabeta(+) IEL preferentially expanded in the small intestine (SI) of pIgR(-/-) mice. Cytotoxic activity of SI-IEL was comparable in pIgR(+/+) and pIgR(-/-) mice. Accumulation and cytotoxic activity of SI-IEL was attenuated in germ-free pIgR(-/-) mice. Furthermore, Thy-1(+)CD8alphabeta(+) IEL did not expand in pIgR(-/-)TCRbetadelta(-/-) mice compared with TCRbetadelta(-/-) mice, and SI-IEL from pIgR(-/-)TCRbetadelta(-/-) mice as well as TCRbetadelta(-/-) mice expressed perforin and granzyme B mRNA and serine esterase. The proliferative status of SI-IEL from pIgR(+/+) and pIgR(-/-) mice was similar, but adoptive transfer experiment showed that SI-IEL from pIgR(-/-) mice might have a stronger tendency to migrate into the intestinal epithelia than those from pIgR(+/+) mice. These results demonstrate that the accumulation of Thy-1(+)CD8alphabeta(+)TCRalphabeta(+) IEL in pIgR(-/-) mice triggered by intestinal microorganisms needed the expression of functional TCR and might be caused by lymphocyte migration into the intestinal epithelia.     

Differential thymus dependence of rat CD8 isoform expression.

Expression of the rat CD8 molecule was studied using five novel monoclonal antibodies (mAb), four of which are specific for the V-like domain of CD8 alpha, whereas one reacts either with the beta chain or with a determinant only expressed on the CD8 alpha/beta heterodimer. mAb to both chains effectively blocked purified lymph node CD8 T cells in mixed lymphocyte reaction and in cell-mediated cytotoxicity. Flow cytometric analysis showed that CD8 T cells from lymph nodes or spleen of normal rats almost exclusively express the alpha/beta isoform, regardless of the T cell receptor isotype (alpha/beta or gamma/delta). In contrast, natural killer (NK) cells carry only CD8 alpha chains. This CD8 alpha + beta - phenotype was also prominent among CD8 T cells from athymic rats and from intestinal epithelium of normal rats. CD8 alpha homodimers can also be expressed as a result of activation, as shown by analysis of CD4 CD8 double-positive T cells obtained from highly purified lymph node CD4 T cells by in vitrok stimulation. Such CD4+CD8 alpha + beta - cells also represent a major subset among adult intestinal intraepithelial lymphocytes (IEL), suggesting local activation. Taken together, the difference in CD8 isoform expression among T cells from athymic rats, NK cells, and gut IEL versus CD8 T cells from peripheral lymphatic organs of euthymic animals suggests that like in mice, expression of the CD8 heterodimer is more dependent on intrathymic maturation than that of the homodimer. Since the more stringent thymus dependence of CD8 alpha + beta + T cells may be due to a requirement for thymic selection on self major histocompatibility complex class I antigens, the virtually exclusive CD8 alpha + beta + phenotype of peripheral rat gamma/delta T cells could mean that antigen recognition by this subset is also restricted by MHC class I molecules.     

Late postnatal expansion of self-reactive CD8alphaalpha+ intestinal intraepithelial lymphocytes in mice

The intestinal epithelium is unique in that it harbors auto-reactive T cells largely absent from the peripheral TCR repertoire in normal mice. Intestinal intraepithelial lymphocytes (IEL) expressing self-reactive TCR are mostly CD8alphaalpha+ cells in adult H-Y TCR RAG(-/-) male mice homozygous for the restricting MHC I allele, H-2D(b). By contrast, in male mice heterozygous for the restricting and non-restricting MHC I allele, H-2D(d) (MHC F(1), H-2D(b/d)), IEL are composed of CD8alphabeta and CD8alphaalpha+ T cells. Here we demonstrate that IEL in the immediate postnatal period of MHC homozygous male mice were mostly CD8(-) T cells, while IEL in MHC F(1) male mice were CD8(-) and CD8alphabeta+ T cells. Regardless of the MHC I configuration and the ability to support positive selection of CD8alphabeta+ cells in the thymus, the expansion of CD8alphaalpha+ IEL was a late postnatal event that followed a reduction in CD8(-) IEL. Furthermore, although in vivo treatment with the specific peptide antigen resulted in an earlier accumulation of activated IEL, the expansion of CD8alphaalpha+ IEL remained inefficient until late in postnatal life. Finally, as CD8(-) IEL stimulated with TCR agonists in vitro, acquired expression of CD8alphaalpha, we propose that CD8alphaalpha+ IEL derive from CD8(-) IEL intermediates. Whether CD8(-) IEL are CD8alphabeta-lineage cells that escape deletion in the thymus or are T cells targeted to the intestine from the thymus because of the early and high level TCR transgene expression in this model, is not clear. The signals required for the expansion of CD8alphaalpha+ IEL are however, incomplete in the immediate postnatal intestine. Determining the factors required for the expansion or retention of CD8alphaalpha+ IEL bearing high affinity, self-specific TCR will further elucidate the in vivo role of these T cells in intestinal homeostasis and perhaps, autoimmunity.     

痢疾杆菌口服免疫小鼠肠道相关淋巴组织中CD45R~+和CD45RB~+细胞动态变化的观察

为了解肠道相关淋巴组织（GALT）对痢疾杆菌口服免疫的应答状况,分离了Shigella fiexneri四次免疫后Balb/c 小鼠牌（SP）、肠系膜淋巴结（MLN）、Peyer’s结（PP）、固有膜（LP）和上皮内（IE）淋巴细胞,对末次免疫后1～13d内免疫组与对照组GALT中的CD45R~+和CD45RB~+细胞群作了FACS分析。结果免疫后起初7d IE和LPCD45R~+细胞增加而MLN和PP CD45R~+细胞减少。CD45RB~+LPL在起初4d增加,而CD45RB~+IEL总是低于对照。CD45RB~(lo)/CD45RB~(hi)比例在SP和MLN中几乎无变化,但在PP中先降至最低后上升并超过对照。LP中主要为CD45RBD~(lo),IE中主要为CD45RB~(hi)。这些结果在一定程度上反映了粘膜淋巴细胞CD45表达的组织特异性及在痢疾杆菌免疫后B细胞、记忆细胞和辅助细胞的功能状态和变化趋势。     

Cytokine production and migration of in vitro-expanded NK1.1(-) invariant Valpha14 natural killer T (Valpha14i NKT) cells using alpha-galactosylceramide and IL-2

Mouse natural killer T cells with invariant Valpha14 rearrangement (Valpha14i NKT cells) can rapidly produce both Th1 and Th2 cytokines and regulate various immune responses, such as autoimmunity and tumor immunity. In this study, we describe the phenotypical and functional characterization of in vitro-expanded mouse Valpha14i NKT cells from spleen using a combination of alpha-galactosylceramide (alpha-GalCer) and IL-2. The expanded Valpha14i NKT cells retained the memory/activated (CD44(+)CD69(+)CD62L(-)) and CD4(+) or CD4(-)8(-) double negative phenotypes but modulated or lost the classical NKT cell marker, NK1.1. The expanded Valpha14i NKT cells continuously released IL-4 and IFNgamma and induced NK cell IFNgamma production in vitro. Furthermore, the expanded Valpha14i NKT cells migrated into the liver and spleen after adoptive transfer into lymphopenic SCID mice, and they were able to rapidly produce IL-4 and IFNgamma after alpha-GalCer injection. Our findings suggest that the intrinsic characteristics of the cytokine secretion of Valpha14i NKT cells were equivalent to that of in vitro-expanded Valpha14i NKT cells. In vitro-expanded Valpha14i NKT cells are considered to be useful for NKT cell defect-related diseases, such as autoimmunity and cancer.     

Microbial colonization influences composition and T-cell receptor V beta repertoire of intraepithelial lymphocytes in rat intestine.

Studies in mice have shown that the composition of intestinal intraepithelial lymphocytes (IEL) may be markedly altered by gut microbial colonization. Such modulation was studied in a rat model by the use of germ-free and conventionalized animals from which IEL from the small intestine were isolated and analysed by flow cytometry. Conventionalization caused expansion as well as phenotypic alterations of T-cell receptor (TCR) alpha/beta + IEL in that the proportions of CD4+ and CD8 alpha beta + TCR alpha/beta + cells were increased, while the double negative (CD4- CD8-) fraction was reduced. microbial colonization also influenced the TCR V beta repertoire of CD8+ IEL in that the proportions of V beta 8.2+ and V beta 10+ cells were increased, whereas V beta 8.5+ and V beta 16+ cells were relatively decreased. Moreover, conventionalization influenced the levels of TCR cell surface expression in the same V beta subsets. Three-colour flow-cytometric analysis demonstrated that skewing of the V beta repertoire was most pronounced in the CD8 alpha alpha + subset, although the numerical increase of IEL mainly included the CD8 alpha beta + subset. In contrast to IEL, the TCR V beta repertoire in mesenteric lymph nodes was unchanged after intestinal colonization. These results confirm that TCR alpha/beta + IEL subpopulations respond dynamically to the microbial gut flora and suggest that their V beta repertoire can be shaped by luminal microbial antigens.     

Unusual phenotype of intestinal intraepithelial lymphocytes in the rat: predominance of T cell receptor alpha/beta+/CD2- cells and high expression of the RT6 alloantigen.

The phenotype of intraepithelial lymphocytes (IEL) from the small intestine of adult rats was studied by flow cytometry. Using appropriate monoclonal antibodies the expression patterns of the T cell receptor alpha/beta (TcR2), CD2, the alloantigen RT6 and several other T cell antigens were analyzed. The vast majority of rat IEL expressed TcR2 which is in contrast with data reported for the mouse. The comparison of IEL with lymph node cells revealed major phenotypic differences. Whereas CD2 was present on virtually all lymph node T cells it was found on only less than 5% of IEL. The T cell-specific differentiation antigen RT6 present on only a fraction of lymph node cells was found on about 99% of IEL demonstrating uniform expression with an approximately tenfold higher density. Identity of the detected molecule with RT6 was proven by using congenic controls and by the demonstration of phosphatidylinositol linkage to the IEL membrane. About 86% of IEL expressed CD8 but a substantial proportion of these cells co-expressed the CD4 molecule (34%). Two-color analysis revealed that the CD4+CD8+ double-positive subset completely lacked CD45RB suggesting that they represent memory cells. In the CD4-CD8+TcR2+ subset there was a remarkable heterogeneity of CD5 expression. A substantial number of these cells did not express CD5 despite high density of TcR2. Phenotypic peculiarities found on all or most IEL such as the lack of CD2 and the increased expression of RT6 indicate that the intestinal epithelial environment exerts strong effects on the development and maturation of these cells.     

Rapid killing of murine lymph node T blasts by intestinal intraepithelial lymphocytes in vitro

We examined the effect of murine intestinal intraepithelial lymphocytes (IEL) on the proliferation of murine lymph node T cells (LN-T) in vitro. An IEL fraction prevented the proliferation of LN-T stimulated with antigen and X-irradiated spleen cells, or with anti-CD3 monoclonal antibodies (mAb). Concanavalin A-activated LN-T were less sensitive. Such an inhibitory activity was recovered from a CD8-depleted population by panning of bulk IEL using anti-CD8α mAb. This population of BALB/c IEL showed less granzyme A activity, and its surface markers were positive for CD8 (～4%), CD3 (80–90%), CD4 (2–6%), αβTcR (45–70%), and γδTcR (4–9%). Asialo-GM1 and Thy1.2 were variably expressed, but interleukin-2 (IL-2) receptor-α and FcγR were not. By contrast, no cytotoxicity against YAC-1 was detected in a CD8-depleted IEL population by a 6-h ⁵¹Cr-release assay. Although IEL from severe-combined immunodeficient mice lacking CD4, CD8 and TcR, but expressing IL-2 receptor, showed cytotoxicity against YAC-1, their inhibitory activity against LN-T was almost the same as that by IEL from BALB/c mice. When LN-T blasts (>75% CD4⁺) activated with anti-CD3 were treated with CD8-depleted IEL, intact cellular DNA of the T blasts disappeared within 1 h with increased amounts of small-sized DNA. These results suggest that CD8^? IEL directly and nonspecifically kill lymph node CD4⁺ T blasts and possibly down-regulate TcR-mediated proliferation of peripheral T cells in the gut epithelium.