Migration of putative progenitor T cells in response to thymus-derived chemotactic factors

Progenitor T cells reach the thymus through the circulation from hematopoietic organs and then migrate toward the site of differentiation in the thymus. The mechanism that regulates such intrathymic migration is not well understood. In order to clarify this mechanism, in vitro chemotactic activity for murine thymocytes was assayed in the extracts and culture supernatants of thymic tissue elements. A potent thymocyte chemotactic activity was found in the extract and culture supernatant from Ig-, Ia- thymic stromal cells. Peanut agglutinin-positive (PNA+1), Thy 1+, TL-, Lyt 1+2-, L3T4- thymocytes, Ig-, Thy 1- bone marrow cells, and mononuclear cells of spleen and peripheral blood, but neither B cells nor lymph node cells, were chemotactically attracted by the factor(s). The chemotactic activity was found in none of the following materials tested: the extract and culture supernatant of thymocytes, culture supernatant of lymph node stromal cells, normal mouse serum, and zymosan-activated serum. The chemotactic activity was found in three molecular fractions by gel chromatography. The activity in all three fractions was destroyed by trypsin digestion or by heating at 56 degrees C for 30 min. These results suggest that Ig-, Ia- thymic stromal cells but not thymocytes secrete a chemotactic factor(s) for progenitor T cells with three molecular species. The factor is considered to play an important role in the migration of intrathymic progenitor T cells into the site of differentiation.     

The in vitro effect of a thymic epithelial culture supernatant on mixed lymphocyte reactivity and intracellular cAMP levels of thymocytes and on antibody production to SRBC by Nu/Nu spleen cells.

Addition of supernatants from rat thymic epithelial cultures (TES) to rat thymocytes stimulated with T-cell-mitogens or allogeneic cells leads to an increase in ¹⁴C-TdR incorporation. Furthermore, in the presence of TES, spleen cells from athymic nu/nu mice exhibit an enhanced in vitro antibody production to SRBC, whereas TES has no such effect on spleen cells from T-cell-deprived mice. If TES is added together with thymocytes to T-cell-deprived spleen cell cultures, the number of plaque-forming cells to SRBC is enhanced, suggesting that TES induces a helper cell function in thymocytes which, if added alone, have no effect. TES also increases intracellular levels of cAMP in thymocytes in vitro and appears to act on a membrane site distinct from the β-adrenergic receptor. TES fails to affect mitogen responses, MLR and cAMP levels of lymphocytes from other lymphoid organs. The biological activity of TES as compared to that of thymic extracts is discussed.     

Identification of profound peripheral T lymphocyte immunodeficiencies in the spontaneously diabetic BB rat

The BB rat is presently the best available animal model for human insulin dependent diabetes (IDD). Because of the extreme susceptibility of the strain to opportunistic infections and because current studies suggest that they have an autoimmune diathesis, of which IDD is but one result, aspects of the immune system of the BB rat were studied. Severe T lymphopenia was observed in all BB rats, irrespective of sex or the presence of IDD, while numbers of B cells and serum immunoglobulin levels were normal. Both the helper T lymphocyte and cytotoxic/suppressor T lymphocyte subsets, defined by reactions with monoclonal antibodies, were depressed, and an inversion of the helper T cell subset to cytotoxic/suppressor T lymphocyte subset ratio occurred in all BB rats with increasing maturity. Concomitantly, severe impairments of T cell-mediated immune responses were noted. BB rats poorly rejected allografts across both major and minor histocompatibility barriers, and BB splenic or peripheral blood lymphocytes had markedly defective proliferative responses to mitogens and to allogeneic cells in MLC. Irradiated and nonirradiated BB spleen cells did not inhibit WF mitogenic or MLC responses, which suggests that the T cell defect in BB rats is not solely due to increased suppressor activity. Because irradiated WF cells and Con A supernatants did not restore BB proliferative responses, and BB lymphocytes were able to produce IL-2 normally, a reduced ability of BB lymphocytes to respond to helper factors such as IL-2 is suggested. In contrast to T lymphocytes from spleen or peripheral blood, BB thymocytes responded as well as did WF thymocytes to Con A or Con A supernatants. Percentages of T lymphocyte subsets and histology of BB thymuses were also normal when compared to WF thymuses. However, spleens and lymph nodes from BB rats were severely depleted of T lymphocytes, and thymocytotoxic autoantibodies were detected in many BB rat sera. The above findings indicate that BB rats have T lymphocyte immunoincompetence, which appears to be a post-thymic or peripherally acquired maturational defect.     

Thymic stromal cells in culture. I. Establishment and characterization of a line which is cytotoxic for normal thymocytes and produces hematopoietic growth factor(s).

Lines of thymic stromal cells have been established. One of these, designated TS-9, has been cloned and studied extensively. This line expresses both acid and alkaline phosphatases. Despite repeated cloning, TS-9 cells remain morphologically heterogeneous. The origin of these cells is not clear. They express low levels of immunologically identifiable cytokeratins, produce laminin, a basement membrane protein, but express antigens typically found on bone marrow stromal cells. The TS-9 cells are MHC Class I+ but Class II-. They express the Thy-1, Pgp-1, and Mac-2 antigens but not other lineage markers of T cells or macrophages. Coculturing TSC with normal thymocytes or with the CTLL-1 cell line leads to a profound inhibition of lectin-induced and/or IL-2 induced T cell proliferation. This requires direct cell-cell contact and ultimately results in the death of the bound lymphocytes. It cannot be reproduced by culturing the thymocytes with TSC culture supernatants. These supernatants do contain hematopoietic growth factor(s) which augment the growth of some T lineage cells and support the growth of monocytic colonies in semi-solid culture medium. Both normal thymocytes and a variety of T cell tumors bind to TSC but only the normal cells are killed as a consequence of this interaction. Neither the binding nor the killing appear to be MHC restricted. We suggest that this killing may provide a model for the effector mechanism of the negative selection imposed by the thymus on developing T cells.     

Analysis of thymic stromal cell subpopulations grown in vitro on extracellular matrix in defined medium. II. Cytokine activities in murine thymic epithelial and mesenchymal cell culture supernatants

Two morphologically distinct primary cultures of murine thymic stroma were established and found to be of epithelial (MTEC) and mesenchymal (MTMC) origin. These cultures were generated by selective conditions of tissue disruption and were maintained on extracellular matrix in defined medium. Culture supernatants (CS) from these cultures (EC-CS and MC-CS respectively), were tested for cytokine production and for effects on thymocyte maturation. Both supernatants displayed the activities of IL-3 and of granulocyte/macrophage-CSF and not of IL-1, -2, -4, or IFN. In addition they were found to be mitogenic to murine thymocytes in a "spontaneous" [3H]TdR incorporation assay. The two supernatants differed, however, in their effect on Con A stimulation. EC-CS had a strong enhancing effect, both when used for preincubation (18 h) before Con A stimulation or when present simultaneously with it. MC-CS had a small inconsistent effect under these conditions. Also EC-CS enhanced IL-2 and IL-3 production by thymocytes. The responsive thymocyte subpopulation was the one that does not bind peanut agglutinin. CS of an established thymic epithelial cell line displayed only part of these activities at a considerably lower level. CS from primary kidney cell culture was completely devoid of activity. The results suggest that primary thymic stromal cell cultures, cultivated under the defined conditions described here, may better preserve physiologic secretory activities, and probably also other cell functions, compared with established cell lines. Furthermore, the results are compatible with the hypothesis that the soluble factors, secreted by thymic stromal cells, are active on either very early or late stages of thymic differentiation, whereas the main intrathymic stages of differentiation are conceivable dependent primarily on direct contact with stromal cells.     

Adriamycin-induced activation of NK activity may initially involve LAF production

C3HeB/FeJ spleen cells (unseparated or passaged over nylon wool columns) were cultured overnight (1-2 X 10(6) cells/microwell) in the presence and absence of resident or ADM-induced PEC and anti-YAC-1 (4h) NK activity was determined. The addition of resident PEC to spleen cells had little effect on NK activity. However, the addition of ADM-elicited PEC (10 mg/kg, IP, day -1 and day -5) to spleen cells prior to culture significantly augmented NK activity. If ADM-induced PEC were treated with carbonyl iron prior to coculture with spleen cells, augmentation of anti-YAC-1 activity was not observed. This suggested that ADM-activated macrophages augmented cultured splenic NK activity. Supernatants from overnight-cultured resident or ADM-induced adherent PEC were then prepared, dialyzed (to remove ADM), and tested for mitogenic activity or cocultured with spleen cells overnight. ADM-induced adherent PEC supernatants stimulated the proliferation of murine thymocytes (both LAF and IL-2 also stimulate) but not cultured CTL (only IL-2 stimulates). ADM-induced adherent PEC supernatants (as well as LAF, IL-2, and IFN) augmented overnight-cultured C3HeB/FeJ splenic NK activity. However, only IL-2 and IFN could augment overnight-cultured athymic BALB/c . nu/nu splenic NK activity. This suggested that ADM-elicited macrophages produce LAF which may act directly on NK cells or, more likely, may induce T cells to produce IL-2, IFN, or both.     

Effects of long-term estrogen treatment on IFN-gamma, IL-2 and IL-4 gene expression and protein synthesis in spleen and thymus of normal C57BL/6 mice.

Estrogens have been shown to markedly modulate the immune system. One mechanism by which estrogens could modulate the immune system is by regulating cytokines, an aspect not well-studied thus far. To address this issue, normal C57BL/6 orchiectomized mice were given estrogen and its effects on selected cytokines, interferon-gamma (IFN-gamma), interleukin 2 (IL-2) and IL-4 in lymphocytes from a developmental organ (thymus) and a mature lymphoid organ (spleen) examined. Estrogen significantly increased IFN-gamma and IL-2 mRNA in concanavalin-A (Con-A) activated thymocytes, splenic lymphocytes, and in enriched splenic T cells. Estrogen had no marked effect on IL-4 mRNA. While estrogen increased IFN-gamma mRNA in Con-A activated unseparated splenic lymphocytes and enriched splenic T cells, a numerical increase in IFN-gamma was noticed only in the supernatants of Con-A activated unseparated splenic lymphocytes, but not in enriched splenic T cells. This suggests that for optimal secretion of IFN-gamma in estrogen-treated mice, co-stimulatory signals from antigen presenting cells are needed. Gender differences in IFN-gamma and IL-2 mRNA were also evident. Con-A activated splenic lymphocytes from gonadal-intact, untreated female had a pattern of numerical increase in IFN-gamma mRNA, and IFN-gamma and IL-2 protein levels compared to their male counterparts. Taken together, our data suggests that estrogens regulate the expression of cytokines, which could account in part, for the gender differences in immune capabilities.     

Altered interleukin production during Friend leukemia virus infection

Spleen cells from BALB/c mice, infected 14 to 28 days earlier with Friend leukemia virus (FLV), were shown to be inhibited in their ability to produce interleukin 2 (IL-2) when stimulated with mitogen. Likewise, these spleen cell populations failed to respond following mitogenic stimulation or exogenous addition of recombinant IL-2. By contrast, the FLV-infected spleen cell populations produced normal levels of interleukin 1 (IL-1) and thymocytes from FLV-infected mice responded normally to addition of exogenous IL-1. This suggests that FLV infection selectively affects the ability of spleen cells to produce cytokines. Spleen cell populations enriched for T lymphocytes and depleted of tumor cells by density gradient centrifugation in Ficoll were unable to produce IL-2. This indicates that the failure to detect IL-2 in cells from FLV-infected mice was not due to a dilution of T lymphocytes by tumor cells but was a functional inability to produce IL-2. Furthermore, enriched T lymphocytes from FLV-infected mice failed to respond blastogenically to exogenous IL-2. Additional studies indicate that tumor cells, but not macrophages or T lymphocytes from FLV-infected spleens, suppressed the blastogenic response to mitogens and IL-2 production by normal splenic T lymphocytes.     

Stromal cells derived from spleen or bone marrow support the proliferation of rat natural killer cells in long-term culture.

Rat nylon wool nonadherent bone marrow cells were propagated for up to 75 days in co-culture with stromal cells derived from either spleen or bone marrow. Interleukin (IL) 1 enhanced the ability of spleen stroma to support the long-term culture of natural killer (NK) cells, ostensibly by inducing these support cells to synthesize other cytokines. Flow cytometry studies indicated that the nylon wool separation procedure enriched the concentrations of mature NK cells from 7.9% to 38.1% for splenocytes and from 3.8% to 19.5% for bone marrow cells. Analyses of the adherent zones of suspended nylon screen NK cell cultures revealed substantial numbers of large granular lymphocytes that expressed NK 323+/MOM/3F12/F2- phenotypes. The presence of both mature and immature cells of the NK lineage in this matrix was inferred by the presence of both IL-2 receptor (IL-2R) positive and IL-2R negative, and OX-8+ and OX-8- NK 323+ cells over the greater than 4-month experimental period. Suspended nylon screen cultures displayed a greater potential for producing cytolytic cells than either co-cultures of bone marrow nonadherent cells on stroma monolayers or suspension cultures. The large granular lymphocytes produced in suspended nylon screen cultures could be transformed into active killers of YAC-1 targets by IL-2. In contrast to bone marrow nonadherent cells, more splenic nylon-wool-passed cells displayed a mature NK phenotype, but their proliferative potential and ability to be transformed into cytolytic cells by IL-2 decreased rapidly in culture. In the suspended nylon screen culture system, NK cells migrate from the underlying stroma in stages as they mature, retain their cytolytic potential, and manifest a capacity for self-renewal. Cultured cells were routinely dissociated into single cell suspensions via enzyme treatment and were reinoculated onto "fresh" nylon screen/stromal cell templates after passage through nylon wool columns. These co-cultures continued to generate cytolytic cells in numbers greater than those of the initial inoculum.     

Effects of thymic myoid cell culture supernatant on cells from lymphatic tissues

Conditioned media (MCM) of cloned thymic myoid cells (IT45R92, R613Ad, and R615B2) were used to investigate their possible involvement in thymic biological events. Those myoid cells produced in a culture medium biological activities capable of stimulating the growth of thymocytes, spleen cells, and bone marrow cells of mice and rats. Surface markers detected on spleen cells proliferating in MCM were characteristic of monocyte-macrophage lineages (C3R, Fc gamma R, asialo GM1) and T-cell lineages (Thy 1) but not B cells (sIgG). Chromatographic studies also suggested that the biological activities of MCM could be separated into two different molecular entities, such as a colony-stimulating activity and an interleukin 1-like activity which supported the growth of monocyte-macrophage lineages and T-cell lineages, respectively. These results indicate that thymic myoid cells produce cytokines important for the regulation of intrathymic interleukin cascade by which clonally differentiated thymic lymphocytes may be expanded into a sizable pool.     

Expression of non-MHC-restricted T cell antigen-binding molecules by thymic lymphocytes

Heterologous antisera which recognize non-major histocompatibility complex (MHC)-restricted T cell antigen-binding molecules (TABM) were used to characterize the expression and structure of TABM on thymic lymphocytes. Approximately 70% of thymocytes express membrane molecules bound by anti-TABM antibodies (mTABM). Antibody activity for thymocyte TABM could be removed by adsorption to splenic T cells, but not by adsorption to splenic B cells. Similarly, adsorption of the antiserum to thymocytes or splenic T cells removed antibody activity to a purified TABM whereas adsorption with B cells had no effect. Radioiodinated thymic and splenic T cell mTABM were resolved by 2D-polyacrylamide gel electrophoresis and when reduced, both populations of mTABM migrated primarily as Mr 23,000 proteins with an isoelectric point range of 6.8-7.8. Multimers of this protein were also observed at Mr 85-97,000 and 130-150,000 on both thymocytes and splenic T cells. These data indicate that MHC-unrestricted antigen-binding molecules are expressed by a majority of thymocytes and these thymic TABM are structurally and antigenically similar to mTABM on peripheral cells. This suggests an ontogenic relationship between thymic TABM and peripheral TABM.     

Lymphokine-mediated induction of antigen-presenting ability in thymic stromal cells

We have established and characterized long term thymic stromal cultures from BALB/c (H-2d) and CBA/J (H-2k) mice. All cultures contained multiple adherent cell types, whereas some also contained thymic macrophages (TM). Culture supernatants from all cultures tested contained macrophage colony-stimulating factor activity, whereas only cultures with TM had soluble or membrane-associated interleukin (IL)-1. However, a thymic epithelial cell line (3D . 1), cloned from one of these cultures, produced IL-1 bioactivity. Further analysis confirmed the production of IL-1 alpha mRNA by the epithelial cell. No IL-2 or IL-4 (formerly called B cell stimulatory factor 1) activity was detected in any of the cultures. Antigen-presenting (AP) ability was determined using the chicken ovalbumin (OVA)-specific, I-Ad-restricted T cell hybridoma 3DO-18.3. Harvested TM exhibited antigen-specific, Ia-restricted AP ability which was enhanced by IL-4 as well as interferon-gamma (IFN-gamma). In contrast, AP ability was detected in non-macrophage stromal cell cultures (NMSC) only after preincubation with IFN-gamma. AP by preinduced NMSC was also Ia-restricted and could be blocked by anti-I-Ad antibodies. Since the T cell receptor of 3DO-18.3 is known to recognize a peptide produced by CNBr degradation of OVA, these observations suggest that both TM and NMSC can process OVA to produce this peptide. Glutaraldehyde-fixation experiments confirmed that NMSC must process native OVA into antigenic peptides for successful AP. Assays using several cloned stromal cell lines of different lineages suggested that only epithelial cells could be induced with IFN-gamma to exhibit competent AP. Given the possible role for IFN-gamma in the maintenance of Ia in the thymus, we investigated whether IFN-gamma production could be ascribed to a subpopulation of thymocytes. Culture supernatants from calcium ionophore and phorbol ester-stimulated peanut agglutinin-negative, but not peanut agglutinin-positive, thymocytes induced AP ability in NMSC. Thus, some thymocytes can produce an Ia-inducing lymphokine (most likely IFN-gamma) which may play an important role in T cell ontogeny through its effects on both thymic macrophages and thymic epithelial cells.     

Participation of the cyclase system in the molecular mechanisms of differentiation control of immunocompetent cells

The effects of polypeptide thymic and bone marrow factors on the cyclase system of rat thymus and spleen lymphocytes were studied. It was shown that the induction of maturation of rat T-lymphocyte precursors into immunocompetent T-cells under effects of the thymic factor is accompanied by the activation of the adenylate cyclase system and the elevation of the cAMP/cGMP ratio. The observed increase in the cGMP level in splenic lymphocytes suggests the presence of cAMP- and cGMP-dependent steps of in the reaction of T-lymphocyte maturation. The bone marrow factor causes an elevation of the cAMP level only in splenic lymphocytes, which points to differences in the lymphocyte subpopulations that are sensitive to thymus and bone marrow factors. Impairments in T-lymphocyte maturation in patients with immunodeficiencies are concomitant with shifts in the isoenzyme spectrum of lactate dehydrogenase in peripheral blood lymphocytes as well as with changes in the sensitivity of the cAMP system to the thymic factor and isoproterenol. These disturbances are relieved by administration of the thymic factor. The roles of the cyclase system and polypeptide thymic and bone marrow factors in the molecular mechanisms of immunocompetent cell maturation are discussed.     

Induction of allospecific suppressor T cells in vitro.

Incubation of mouse thymic lymphocytes with irradiated allogeneic spleen cells gave rise to suppressor cells. The suppressor activity was assayed by adding the incubated cell mixture to a mixed lymphocyte culture (MLC) in which the responder cells were syngeneic with the sensitized thymocytes and the stimulator cells were syngeneic with the sensitizing spleen cells. Such addition suppressed significantly thymidine incorporation in the mixed lymphocyte reaction (MLR). The suppressor cells were found to carry the θ antigen and to function allospecifically, as shown by cross-testing in three allogeneic combinations. Our data suggest that these cells may originate from immature cortisone-sensitive thymic lymphocytes and also provide some preliminary information concerning their mode of action.     

20 alpha hydroxysteroid dehydrogenase (20 alpha SDH) activity in New Zealand mice T lymphocytes and bone marrow cells: effect of age, sex, and castration.

The activity of 20 alpha hydroxysteroid dehydrogenase (20 alpha SDH), a T lymphocyte-associated enzyme, was measured in fetal liver, thymus, spleen, and bone marrow cells from NZB, NZW, and (NZB X NZW)F1 (B/W) mice. There was an age-dependent increase of 20 alpha SDH activity in bone marrow cells, and a decrease in thymocytes and splenic T lymphocytes. Treatment with anti-theta and complement did not reduce the 20 alpha SDH activity of bone marrow and fetal liver cells, but reduced the activity of spleen cells. PHA stimulates both 20 alpha SDH activity and thymidine incorporation in splenic, bone marrow, and fetal liver lymphocytes. The results suggest that the enzyme in the bone marrow and fetal liver is located in pre-T lymphocytes. Enzymatic activity in bone marrow cells taken from female B/W mice (older than 7 months) was 40 to 20% lower than in male mice. Orchidectomy, but not ovariectomy, caused a significant decrease in thymocyte 20 alpha SDH activity. Orchidectomy depressed and ovariectomy enhanced 20 alpha SDH activity of bone marrow cells. The 20 alpha SDH activity of fetal liver cells from B/W mice was twice as high as in either parent strain. No 20 alpha SDH activity was found in fetal liver cells taken from BALB/C SJL or C57BL/6 mice. A model is proposed to explain the age- and sex-related changes in 20 alpha SDH activity of pre-T and T lymphocytes in healthy and pathologic conditions.     

Lymphokines and aging: interleukin-2 production and activity in aged animals

The capacity of aged animals to produce and respond to the T cell-replacing factor, interleukin-2 (IL-2), has been examined. IL-2 activity in the supernatants of concanavalin A-activated aged spleen cells is 5- to 10-fold lower than comparable supernatants prepared using young spleen cells. This lesion in IL-2 synthesis may limit antibody production to T-dependent antigens, because supplementation with purified IL-2 markedly enhances the number of anti-SRBC plaques generated by aged spleen cells. The response of aged splenocytes can be fully restored to that obtained using young adult cells. However, there appears to be a defect in the ability of aged cells to effectively translate the IL-2 signal into B cell helper activity, in the absence of T lymphocytes. That is, although young adult, nylon wool-purified T cells can interact with aged T-depleted spleen cells, producing a normal high level anti-SRBC response, IL-2 is incapable of reconstituting the response in aged animals to this level. On the other hand, both young adult T cells and IL-2 can interact with young adult T-depleted splenic lymphocytes to produce a normal, high level anti-SRBC response.     

Intrathymic T cell differentiation in radiation bone marrow chimeras and its role in T cell emigration to the spleen. An immunohistochemical study

Immunohistochemical studies were made on the regeneration of T cells of host- and donor-type in the thymus and spleen of radiation bone marrow chimeras by using B10- and B10.BR-Thy-1 congenic mice. Both the thymic cortex and the medulla were first repopulated with thymocytes of irradiated host origin, restoring the normal histologic appearance by days 11 to 14, regardless of the H-2 compatibility between the donor and the host. In Thy-1 congenic chimeras, thymocytes of donor bone marrow origin, less than 100 cells in one thymic lobe, were first recognized at day 7, when the thymus involuted to the smallest size after the irradiation. The thymocytes of donor-type then proliferated exponentially, showing a slightly faster rate when higher doses of bone marrow cells were used for reconstitution, reaching a level of 100 million by day 17 and completely replacing the cortical thymocytes of host origin by day 21. The replacement of cortical thymocytes started from the subcapsular layer in a sporadic manner. The replacement of medullary thymocytes from host- to donor-type occurred gradually between days 21 and 35, after the replacement in the cortex was completed. In the spleen, about 1 million survived cells were recovered at day 3 after the irradiation, and approximately 60% of them were shown to be host-type T cells that were observed in the white pulp areas. The host-type T cells in the spleen increased gradually after day 10, due to the influx of host-type T cells from the regenerating thymus. Thus a pronounced increase of T cells of host-type was immunohistochemically observed in the splenic white pulp between days 21 and 28, when thymocytes of host-type were present mainly in the thymic medulla. These host-type T cells were shown to persist in the spleen for a long time, as long as 420 days after the treatment. Phenotypically, they were predominantly Lyt-1+2+ when examined at day 28, but 5 mo later, they were about 50% Lyt-1+2+ and 50% Lyt-1+2-. Donor-type T cells in the spleen began to appear at about day 14 in chimeras that were transplanted with a larger dose of bone marrow cells, whereas this was slightly delayed in those grafted with a smaller dose of bone marrow cells, starting at about day 28.(ABSTRACT TRUNCATED AT 400 WORDS)     

Chemotaxis of rat lymphocytes.

Rat lymphocytes obtained from spleens, lymph nodes, and thymus glands showed migratory responses to a variety of factors including fluids from mixed lymphocyte culture fluids from concanavalin A-stimulated cells, fluids from phagocytizing macrophages, and to anti-rat IgG. Migratory responses to the last factor were bimodal over a dose range of anti-Ig; at high concentrations of anti-Ig, the response appeared to be nonspecific, whereas, at low concentrations, the responses seemed to be chemotactic in character. When lymphocytes from spleens, lymph nodes, and thymic glands were compared, qualitative and quantitative differences on the responses were evident with use of the three attractants. When spleen lymphocytes were separated into T cell- and B cell-enriched fractions, T cells responded to the culture fluids from mixed lymphocyte cultures, whereas B cells seemed to respond poorly, if at all. Only B cells responded to anti-Ig. These findings may explain, at least in part, the accumulation of lymphoid cells at sites of inflammatory stimuli.     

A novel cell surface antigen involved in thymocyte and thymic epithelial cell adhesion.

A murine mAb, 7D3, was produced by fusion of spleen cells obtained from mice immunized with a rat thymic epithelial cell line, Tu-D3 and NS/1 myeloma cells. 7D3 antibody reacted with approximately 95% thymocytes, 17% spleen cells, less than 9% of mesenteric lymph node cells and 32% of bone marrow cells of rat origin. 7D3 also reacted with two rat thymic epithelial cell lines but not with a rat fibroblastic cell line. Immunochemical analysis demonstrated that 7D3 antibody recognized a single polypeptide with molecular weight of 80,000 in FTE cells and 80,000 to 96,000 in thymocytes. 7D3 antibody strongly inhibited the thymocyte binding to thymic epithelial cells. In addition, 7D3 antibody inhibited TPA-induced thymocyte aggregation. 7D3 negative rat thymic lymphoma cells bound to 7D3 positive thymic epithelial cells and this binding was inhibited by 7D3 antibody, indicating that a part of thymocyte-thymic epithelial cell binding was mediated by the interaction of 7D3 Ag and undefined ligand to 7D3.