Distribution of MEL-14+ cells in various lymphoid tissues

Induction of autoimmunity by expansion of autoreactive CD4+CD62Llow cells in vivo

The prerequisites of peripheral activation of self-specific CD4(+) T cells that determine the development of autoimmunity are incompletely understood. SJL mice immunized with myelin proteolipid protein (PLP) 139-151 developed experimental autoimmune encephalomyelitis (EAE) when pertussis toxin (PT) was injected at the time of immunization but not when injected 6 days later, indicating that PT-induced alterations of the peripheral immune response lead to the development of autoimmunity. Further analysis using IA(s)/PLP(139-151) tetramers revealed that PT did not change effector T cell activation or regulatory T cell numbers but enhanced IFN-gamma production by self-specific CD4(+) T cells. In addition, PT promoted the generation of CD4(+)CD62L(low) effector T cells in vivo. Upon adoptive transfer, these cells were more potent than CD4(+)CD62L(high) cells in inducing autoimmunity in recipient mice. The generation of this population was paralleled by higher expression of the costimulatory molecules CD80, CD86, and B7-DC, but not B7-RP, PD-1, and B7-H1 on CD11c(+)CD4(+) dendritic cells whereas CD11c(+)CD8alpha(+) dendritic cells were not altered. Collectively, these data demonstrate the induction of autoimmunity by specific in vivo expansion of CD4(+)CD62L(low) cells and indicate that CD4(+)CD62L(low) effector T cells and CD11c(+)CD4(+) dendritic cells may be attractive targets for immune interventions to treat autoimmune diseases.

CD4+ CD25+ CD62+ T-regulatory cell subset has optimal suppressive and proliferative potential

CD4+ CD25+ regulatory T cells (Treg) are potent suppressors, and play important roles in autoimmunity and transplantation. Recent reports suggest that CD4+ CD25+ Treg are not a homogeneous cell population, but the differences in phenotype, function, and mechanisms among different subsets are unknown. Here, we demonstrate CD4+ CD25+ Treg cells can be divided into subsets according to cell-surface expression of CD62L. While both subsets express foxp3 and are anergic, the CD62L+ population is more potent on a per cell basis, and proliferates and maintains suppressive function far better than the CD62L- population and unseparated CD4+ CD25+ Treg. The CD62L+ population preferentially migrates to CCL19, MCP-1 and FTY720. Both CD62L+ and CD62L- subsets prevent the development of autoimmune gastritis and colitis induced by CD4+ CD25-CD45RBhigh cells in severe combined immunodeficiency (SCID) mice. Overall, these results suggest CD4+ CD25+ Treg are not a homogenous cell population, but can be divided into at least two subsets according to CD62L expression. The CD62L+ subset is a more potent suppressor than the CD62L- population or unfractionated CD4+ CD25+ Treg cells, can be expanded far more easily in culture, and is more responsive to chemokine-driven migration to secondary lymphoid organs. These properties may have significant implications for the clinical manipulation of the CD4+ CD25+ CD62L+ cells.

Flow cytometric analysis of thymocyte subpopulations in mice after whole-body X-irradiation

To determined the cellular kinetics of thymocyte subpopulations in DBA1 mice after whole-body 6.8 Gy X-irradiation, they were analyzed for the expression of several cell surface antigens using flow cytometry. The results show that i) The majority of thymocytes rapidly depleted by irradiation was CD4+8+ cells. ii) radioresistant CD4+8- and CD4-8+ survived 18-48 hr after X-irradiation were considered to be relatively mature type, since they expressed high levels of CD3 and LECAM-1. iii) CD3-positive cells were detected in CD4-8- cells at 72 hr after irradiation.

Intrinsic Differences in L-Selectin Expression Levels Affect T and B Lymphocyte Subset-Specific Recirculation Pathways

Lymphocyte migration into lymphoid organs is regulated by tissue-specific adhesion molecules such as L-selectin and the α4β7 integrin. Whether L-selectin also regulates lymphocyte subset-specific migration into specific lymphoid tissues was examined in this study by comparing the migration of CD4+ T cells, CD8+ T cells, and B cells from L-selectin-deficient and wild-type mice. T cells were the predominant lymphocyte subset entering PLN, MLN, Peyer’s patches, and spleen during short term (1-h) migration assays. However, both B cell and CD4+ and CD8+ T cell entries into PLN, MLN, and Peyer’s patches were dramatically impaired (73–98%) by loss of L-selectin. Lymphocyte expression of α4β7 integrin did not compensate for the loss of L-selectin, since both B and T cells predominantly migrated into the spleen in the absence of L-selectin. The more efficient migration of T cells into peripheral lymphoid tissues relative to that of B cells was partly explained by the finding that T cells expressed L-selectin at 50 to 100% higher levels than B cells. In addition, a 50% reduction in L-selectin expression by lymphocytes from hemizygous L-selectin+/− mice resulted in a 50 to 70% decrease in short term lymphocyte migration into peripheral lymphoid tissues relative to that of wild-type lymphocytes. Thus, the differential migration of T and B lymphocyte subsets to lymphoid tissues is regulated in part by subset-specific differences in L-selectin expression levels.

Calcium-dependent lectin activity with novel distribution on thymocyte subsets

In this study we use carbohydrate probes to search for novel cell surface lectins in the immune system. Many carbohydrate binding proteins are members of the C-type lectin superfamily, whose ligand binding is dependent on calcium. To identify potential new members of this superfamily, fluorescein-conjugated carbohydrate polymers were used to probe for calcium-dependent cell surface binding. This approach offers advantages over the use of monoclonal antibody probes since only carbohydrate binding proteins would be identified. We have identified a cell surface lectin, referred to as thy-lec, detected by the probe fucoidan-fuorescein isothiocyanate. This calcium-dependent lectin has a novel distribution on thymocyte subsets. It is present on the surface of immature CD4+8+ and on large, cycling CD4-8- cells and CD8+4- cells, but not on small, mature phenotype CD8+4- or CD4+8- thymocytes. This lectin is not found on mature T cells or other leukocytes in lymph nodes, spleen or bone marrow. It is proposed that this novel cell surface has a function in the maturation of T cells in the thymus.

Production of minor lymphocyte stimulatory-1a antigens from T cell subsets

T cell subsets that produce minor lymphocyte stimulatory (Mls) antigens were analyzed using mixed lymphocyte reaction (MLR) in vitro or clonal elimination assay in vivo. When lymph node T cells from B10.BR(Mls-1b) mice were stimulated with various T cell subsets from AKR (Mls-1a) mice in the presence of B10.BR antigen presenting cells (APC), proportions of Mls-1a reactive T cell blasts (V beta 6+, V beta 8.1+) increased. The stimulatory potency of CD8+ T cells was higher than that of CD4+ T cells. Furthermore, among either CD8+ or CD4+ T cell subset, CD44+ T cells appeared to produce larger amounts of Mls-1a antigens than CD44- T cells. More marked difference was demonstrated, when stimulator AKR T cells were being activated by immobilized anti-T cell antigen receptor (TCR) antibody during MLR. Thus, AKR T cells appeared to produce large amounts of Mls-1a antigens on appropriate stimulations. These findings were confirmed by the semiquantitative analysis of mRNA levels of MTV-7 in the AKR T cell subsets. When CD8+CD44+ T cells from (AKR x B10.BR)F1 mice were injected intravenously into [B10.BR-->B10.BR] syngeneic bone marrow (BM) chimeras 1 week after BM reconstitution and proportions of V beta 6+ T cells were quantitated 7 weeks later, significant clonal elimination of V beta 6+ T cells was induced among both thymocyte population and lymph node T cell population in a dose-dependent manner of the inoculated F1 T cells. Inoculation of CD8+CD44-F1 T cells eliminated V beta 6+ T cells less efficiently from lymph node T cells and inoculation of CD4+F1 T cells induced no significant clonal elimination of the V beta 6+ T cells. The present findings demonstrate clearly that CD8+CD44+ T cells represent the cells producing large amounts of Mls-1a antigens and inducing clonal elimination of V beta 6+ T cells in vivo.

Quantitative and qualitative changes in CD44 and MEL-14 expression by T cells in C57BL/6 mice during aging

Aging is associated with a decrease in the functional activity of T cells. We have explored age-related alterations in CD44 and MEL-14 expression by spleen cells bearing the Thy1.2, CD4 or CD8 antigens in C57BL/6 mice at 2, 8, 15 and 23 months of age. The membrane expression of CD44 and MEL-14 molecules can be used to distinguish naive (CD44low, MEL-14high) from preactivated/memory (CD44high, MEL-14low) T cells. Our results show that the proportion of CD4+ splenic cells begins to decrease at an intermediate age (8-month-old mice), whereas the proportion of CD8+ cells remains unaltered. The proportion of CD4+ and CD8+ splenic cells with the CD44high memory phenotype was increased at an early stage of aging (in 8-month-old mice) without a concomitant change in MEL-14 expression. In older mice, MEL-14 expression decreased on CD4+ but not on CD8+ subsets. Recent studies have reported that following activation, the expression of CD44 molecules containing additional, so-called variable exons can be detected. By PCR, we observed an increase in CD44 transcripts containing the v6 or v7 variable exons in murine lymph nodes at the age of 15 months. Our results suggest that v6- or v7-containing variants of CD44 may be involved in the development of memory cells. Taken together, these results suggest that the trafficking of memory T cells in aging may be altered by quantitative and/or qualitative differences in the expression of molecules involved in lymphocyte recirculation.

Functional analysis of Mel-14+ and Mel-14- early precursor cells in the adult mouse thymus

The earliest T-cell precursor population in the adult mouse thymus (low CD4 precursors) may be divided into 85% of cells expressing surface Mel-14 (LECAM-1, the lymphocyte homing receptor) and 15% of cells which are Mel-14. To date, this is the only surface marker for which we have found this population to be heterogeneous. The precursor activity of the Mel-14+ and Mel-14- subpopulation was assessed by both intrathymic and intravenous transfer of sorted cells into Ly5 congenic irradiated recipient mice. On both a cell-for-cell and a total activity basis, almost all precursor activity was associated with the Mel-14+ cells. No segregation was seen between T-cell, B-cell and dendritic cell precursor activity of the low CD4 population, all activities being concentrated in the Mel-14+ fraction. This strengthens the hypothesis that one precursor cell has the potential to form all three lineages.

Functional studies on MEL-14+ and MEL-14- T cells in peripheral lymphoid tissues

Functions of MEL-14+ T cells and MEL-14- T cells in peripheral lymphoid tissues were analyzed and compared. The MEL-14- T cells, representing a minor subpopulation of spleen and lymph node T cells, generated considerably higher mixed lymphocyte reaction and mitogen responses than the MEL-14+ T cells in any lymphoid tissues studied. Furthermore, upon stimulation with ConA the MEL-14- CD8+ T cells produced significantly larger amounts of IL-2 and IFN-gamma than MEL-14+ CD8+ T cells did. A similar but less marked observation was obtained with the CD4+ T cell population. Furthermore, when B10.BR mice were immunized with AKR (Mls-1a) spleen cells, the proportion of the Mls-1a reactive V beta 6+ T cells from draining lymph nodes increased and a substantial proportion of the increasing V beta 6+ T cells was shown to be MEL-14-. The present findings on the whole indicate that MEL-14- T cells in the peripheral lymphoid tissues are at functionally high levels and may represent memory cells which have been previously stimulated in vivo.

Quantitative analysis of MEL-14 expression on various lymphocyte subpopulations

Amounts of gp90MEL-14 molecules in various lymphocyte subpopulations were analyzed. The expression of gp90MEL-14 was rapidly up-regulated in the course of usual procedures for preparing single cell suspensions. On the other hand, the gp90MEL-14 expression was down-modulated after short term culture in the presence of PMA. Addition of NaN3 in the medium for preparing cell suspension was shown to stabilize the expression profile of the gp90MEL-14. By this simple improvement, we could successfully evaluate the precise amounts of gp90MEL-14 expressed on various lymphoid cells which appeared to reflect the expression pattern of gp90MEL-14 in vivo. The proportion of MEL-14+ cells and amounts of gp90MEL-14 on the cells were clearly associated with the anatomical and functional distance from endothelial cells of HEV in peripheral lymph nodes. The present findings, thus, support the role of gp90MEL-14 molecules as homing receptors for HEV that was originally proposed by Weissman and his colleagues.

Lymphocyte recirculation: the need for site-specific receptors to dictate T-lymphocyte localization into different tissue sites

This paper addresses the need for receptors involved in recirculation of T lymphocytes both during development and during an immune response or inflammation. Some known receptors present on T lymphocytes which are important in maintaining normal T-cell localization and function, i.e. the integrins, LECAMs, LPAM-1 and H-CAM (CD44) are considered in terms of the specificity which they confer on lymphocyte recirculation. A clear understanding of lymphocyte trafficking patterns and of the receptors involved may provide, for example, novel therapies for treatment of malignant cancer, alleviation of damage caused by lymphocytes during inflammatory responses, and targeting of cells to sites of infection.