Tolerance induction in T helper (Th1) cells by thymic macrophages.

Most macrophages in the peripheral tissues present Ag optimally to a variety of functionally distinct Th cells. Although thymic macrophages have been implicated in deleting autoreactive thymocytes, their role in influencing the functional capacities of mature T cells is not clear. We have established a normal untransformed macrophage cell line, named TMC, from the mouse thymus. The TMC line presents protein Ag to an IL-4-producing Th2 type Th clone after IFN-gamma treatment as evidence by T cell proliferation and the release of IL-3 and IL-4. However, these thymic macrophages are inefficient at stimulating a well characterized cytochrome C-specific IL-2-producing Th1 clone, A.E7. Ag presentation by TMC results in the production of IL-3 but not IL-2 production or proliferation of A.E7 cells. This selective Ag presentation defect to Th1 cells is corrected by the addition of live but not fixed allogeneic irradiated spleen cells, suggesting that the thymic macrophages lack the expression of costimulatory activity required for Th1 activation. This is further demonstrated by the failure of live thymic macrophages to provide costimulatory activity to A.E7 cells stimulated with fixed spleen cells plus the antigenic peptide 81-104. Exposure of A.E7 cells to paraformaldehyde-treated TMC in the presence of 81-104 peptide induces specific hyporesponsiveness, anergy. These data demonstrate that thymic macrophages can have a profound influence on the response of selected T cells to Ag. Furthermore, the nature of the T cell stimulus is also critical because Th1 and Th2 cells responded equally well to the T cell mitogen, Con A, and a bacterial superantigen presented by the thymic macrophages.     

Signal transduction via CD4, CD8, and CD28 in mature and immature thymocytes. Implications for thymic selection.

The positive and negative selection of immature thymocytes that shapes the mature T cell repertoire appears to occur at an intermediate stage of development when the cells express low levels of TCR/CD3. These cells are also CD4+CD8+ and CD28+ (dull), and signals delivered by these three accessory molecules have been implicated in the selection process. We have examined the regulatory function of these accessory molecules on responses of immature thymocytes stimulated through the TCR/CD3 complex. Cross-linking CD4 or CD8 with CD3 strongly enhanced signal transduction via CD3 as assessed by protein tyrosine phosphorylation and calcium mobilization. Subsequent cell proliferation could be induced by soluble anti-CD28 mAb, which was comitogenic for cells stimulated with CD3 x CD4 or CD3 x CD8 cross-linking, but was without effect on cells stimulated with CD3 x CD3 cross-linking. A potential role for CD28 signal transduction in thymic maturation is suggested by the demonstration that the BB-1 molecule, a natural ligand for CD28, is expressed on thymic stromal cells. Taken together, our data suggest a model of thymic development in which CD4 or CD8 may enhance TCR/CD3 signaling upon coligation by an MHC molecule. If the CD28 surface receptor is simultaneously stimulated by a BB-1 expressing stromal cell, this set of interactions could lead to proliferation and positive selection. In the absence of CD28 stimulation the enhanced TCR/CD3 signals might lead to apoptosis and negative selection.     

The lymphoid past of mouse plasmacytoid cells and thymic dendritic cells

There has been controversy over the possible lymphoid origin of certain dendritic cell (DC) subtypes. To resolve this issue, DC and plasmacytoid pre-DC isolated from normal mouse tissues were analyzed for transient (mRNA) and permanent (DNA rearrangement) markers of early stages of lymphoid development. About 27% of the DNA of CD8(+) DC from thymus, and 22-35% of the DNA of plasmacytoid pre-DC from spleen and thymus, was found to contain IgH gene D-J rearrangements, compared with 40% for T cells. However, the DC DNA did not contain IgH gene V-D-J rearrangements nor T cell Ag receptor beta gene D-J rearrangements. The same DC lineage populations containing IgH D-J rearrangements expressed mRNA for CD3 chains, and for pre-T alpha. In contrast, little of the DNA of the conventional DC derived from spleen, lymph nodes, or skin, whether CD8(+) or CD8(-), contained IgH D-J rearrangements and splenic conventional DC expressed very little CD3 epsilon or pre-T alpha mRNA. Therefore, many plasmacytoid pre-DC and thymic CD8(+) DC have shared early steps of development with the lymphoid lineages, and differ in origin from conventional peripheral DC.     

Mature T cells generated from single thymic clones are phenotypically and functionally heterogeneous

A limiting dilution system for cloning thymic CFU (CFUt) from murine bone marrow has been critically evaluated to test the clonal origin of the thymic colonies. Simultaneous limiting dilution transfer of three populations of bone marrow, each expressing a unique allelic cell surface determinant, resulted in independent segregation of donor-derived thymocyte populations within groups of recipient mice. Statistical analysis of the data allowed an estimate of 1 CFUt/3.3 x 10(4) i.v. transferred bone marrow cells. A pulse-chase experiment was utilized to establish whether CFUt seed directly to the thymus, or whether thymic seeding is secondary to extra-thymic engraftment. The results supported the conclusion that bone marrow CFUt utilize a specific interaction with thymic blood vessel endothelial cells to recognize and enter the thymus, and that this seeding occurs within 4 h of i.v. infusion. A kinetic analysis of emigration of the CFUt progeny into the peripheral blood revealed that, in most cases, an early wave of predominantly CD4+ CD8- lymphocytes emerges from the thymus approximately 4 wk after radiation and reconstitution. In a few cases, the first progeny of CFUt to emerge from the thymus were predominantly CD4- CD8+. Commitment of CFUt to TCR beta-chain rearrangements was assessed by quantitating expression of the V beta 8 family of TCR V region genes. Although some clones expressed a significantly higher or lower percentage of V beta 8+ cells, these differences were not stable with time. Thus, CFUt do not undergo absolute commitment to cell surface phenotype of TCR rearrangement, as reflected by the phenotypes of their progeny. Clones of mature peripheral progeny of CFUt could be expanded in culture in the presence of mitogen and growth factors; approximately 30 to 50% of proliferating clones could mediate cytotoxicity in a lectin-dependent assay, further indicating that CFUt are not absolutely committed to a particular T cell function.     

Ontogeny of T cell receptors in the chicken thymus

A panel of murine mAb against chicken TCR and associated molecules was used to study the ontogeny of T cells. The intrathymic maturation of the TCR-gamma delta, (TCR-1) and TCR-alpha beta (TCR-2) sublineages was the focus of these studies employing immunoperoxidase staining of tissue sections and immunofluorescence analysis of cell suspensions. The first CD3+ cells appeared in the thymus on embryonic day 9 (E9) when the CD3 Ag was restricted to the cytoplasm. In tissue sections, both TCR-1+ and TCR-2+ cells were observed on E12, whereas only the TCR-1 cells were identifiable by surface immunofluorescence. On the next day, when a discrete thymic medullary region was first recognizable, the TCR-1 cells were present in both cortex and medulla. Two days later (E15), TCR-1 cells were found in the spleen. Surface TCR-2+ cells did not appear until E14, began to migrate in to the medulla on E17, and appeared in the spleen on E19. The first TCR-1 cells thus move quickly through this maturational pathway, whereas TCR-2 cells undergo a prolonged developmental period in the cortex. While most TCR-1+ cells were CD4-CD8-, a minor subpopulation (5 to 15%) were CD4-CD8+, and less than 1% were CD4+CD8+. In contrast, immature TCR-2+ thymocytes in the cortex were predominantly CD4+CD8+, whereas cells expressing a higher density of the CD3/TCR-2 complex were either CD4+CD8- or CD4-CD8+ and were localized in the thymic medulla. In the medulla of the mature thymus, the TCR-1+ cells preferentially occupy the cortico-medullary junction and form small aggregates around vessels. TCR-2+ cells were less frequent in these areas of TCR-1 accumulation. The thymic ontogeny and, by implication, the selection of the receptor repertoire thus differs substantially for these two TCR isotypes.     

Expression of inhibitory receptors Ly49E and CD94/NKG2 on fetal thymic and adult epidermal TCR V gamma 3 lymphocytes

Ly49 and CD94/NKG2 inhibitory receptors are predominantly expressed on murine NK cells, but they are also expressed on a subpopulation of peripheral CD8 memory TCR alphabeta lymphocytes. In this study we demonstrate that Ly49E and CD94/NKG2 receptors are expressed on mature TCR Vgamma3(+) cells in the fetal thymus. Expression correlated with a memory phenotype, such as expression of CD44, 2B4, and IL-2Rbeta (CD122), and absence of IL-2Ralpha (CD25) expression. No expression of Ly49A, C, D, G2, or I receptors was observed. This phenotype is similar to that of fetal thymic NK cells. Skin-located Vgamma3 T cells, the progeny of fetal thymic Vgamma3 cells, also expressed CD94/NKG2 and Ly49E but not the other members of the Ly49 family. The development and survival of Ly49E(+) or CD94/NKG2(+) Vgamma3 T lymphocytes was not dependent upon expression of MHC class I molecules. The cytotoxicity of TCR Vgamma3 cells was inhibited when Qdm, the ligand for CD94/NKG2, was presented by Qa1(b)-transfected target cells. Also, upon cross-linking of CD94/NKG2 with mAb 3S9, TCR Vgamma3 thymocytes were prevented from killing FcgammaR(+) P815 target cells. These effects were most pronounced in the CD94/NKG2(high) subpopulation as compared with the CD94/NKG2(low) subpopulation of Vgamma3 cells. Our data demonstrate that Vgamma3 T cells expressing inhibitory Ly49E and CD94/NKG2 receptors are mature and display a memory phenotype, and that CD94/NKG2 functions as an inhibitory receptor on these T lymphocytes.     

Human thymic epithelial cells inhibit IL-15- and IL-2-driven differentiation of NK cells from the early human thymic progenitors

T/NK progenitors are present in the thymus; however, the thymus predominantly promotes T cell development. In this study, we demonstrated that human thymic epithelial cells (TEC) inhibit NK cell development. Most ex vivo human thymocytes express CD1a, indicating that thymic progenitors are predominantly committed to the T cell lineage. In contrast, the CD1a(-)CD3(-)CD56(+) NK population comprises only 0.2% (n = 7) of thymocytes. However, we observed increases in the percentage (20- to 25-fold) and absolute number (13- to 71-fold) of NK cells when thymocytes were cultured with mixtures of either IL-2, IL-7, and stem cell factor or IL-15, IL-7, and stem cell factor. TEC, when present in the cultures, inhibited the increases in the percentage (3- to 10-fold) and absolute number (3- to 25-fold) of NK cells. Furthermore, we show that TEC-derived soluble factors inhibit generation of NK-CFU and inhibit IL15- or IL2-driven NK cell differentiation from thymic CD34(+) triple-negative thymocytes. The inhibitory activity was found to be associated with a 8,000- to 30,000 Da fraction. Thus, our data demonstrate that TEC inhibit NK cell development from T/NK CD34(+) triple negative progenitors via soluble factor(s), suggesting that the human thymic microenvironment not only actively promotes T cell maturation but also controls the development of non-T lineage cells such as the NK lineage.     

Differentiation of an immature T cell line: a model of thymic positive selection.

Thymocyte differentiation is dependent upon recognition of major histocompatibility complex (MHC) molecules on thymic stroma, a process called positive selection. Here we describe an immature CD4+8+ T cell line derived from a TCR transgenic mouse that differentiates into CD4+8- cells in response to antigen and nonthymic antigen-presenting cells. When injected intrathymically, these cells differentiate in the absence of antigen. The ability of immature T cells to recognize MHC molecules in the absence of foreign antigen in the thymus can thus be attributed to a unique property of thymic antigen-presenting cells. These studies also demonstrate the phenotypic and functional changes associated with TCR-mediated T cell maturation and establish an in vitro model system of positive selection.     

Production of a monoclonal antibody strongly reacting with immature thymic T lymphocytes and its immunohistological application

A monoclonal antibody Th-5 has been produced against mouse immature thymic lymphocytes and employed to study the process of T cell differentiation in the thymus. Immunohistologically, Th-5 positive thymic T lymphocytes were first found at Day 12 of gestation. They increased in number as well as staining intensity until Day 18 of gestation and decreased thereafter. Th-5 antigen expression was not seen in lymphoid cells in the fetal liver. In the newborn thymus, lymphocytes in the subcapsular layer were still strongly positive, while other cortical lymphocytes became moderately positive for Th-5. Th-5 positiveness was more pronounced in the medulla than in the cortex in the thymus of young adult mice. The staining pattern of Th-5 in the thymus was apparently different from those with other T cell markers (Thy-1, CD3, CD4, CD5, CD8) including J11d, Pgp-1, IL-2R, and 3A10 (TCR gamma delta). Flow cytometric analyses showed that the expression of Th-5 was mostly associated with the Thy-1 antigen. However, the fluorescent intensity of Th-5 gradually declined with ontogenic development of the thymus, and the molecular size of the antigen was approximately 100 kDa, which is different from Thy-1 antigen (25-30 kDa). Considering these findings, the strong expression of Th-5 could be one of the markers of immature thymic T lymphocytes in the early phase of the ontogenic development.     

Peripheral but not thymic T cells participate in an autoreactive T cell network

Splenic T cells proliferate in response to the anti-I-Ab reactive T cell hybridoma T1.203 in an H-2-restricted but MHC antigen-independent manner. We propose that this anti-idiotypic response is mediated by "Type 2 autoreactive" T cells that are induced in peripheral lymphoid tissues following interaction with the particular idiotype expressed by the anti-self-I-A T cells. Thus, we define this phenomenon as an idiotype-restricted MHC-related cell interaction. To study the ontogeny of this response, we examined the distribution of Type 2 autoreactive cells. Spleen and lymph node but not thymic C57BL/6 T cells vigorously proliferate to T1.203. Mature (PNA-) as well as immature (PNA+) thymic T cells respond poorly. The frequency of cells responding to T1.203 is far greater in the spleen than in the thymus. The responding T cells were of both Lyt 1+ and Lyt 2+ T phenotype. The results suggest that Type 2 autoreactive cells are induced in peripheral lymphoid tissues following interaction with anti-I-A autoreactive T cells which escape from the thymus or develop in the periphery.     

Expression of LIF in transgenic mice results in altered thymic epithelium and apparent interconversion of thymic and lymph node morphologies.

Leukemia inhibitory factor (LIF) is a cytokine involved in embryonic and hematopoietic development. To investigate the effects of LIF on the lymphoid system, we generated a line of transgenic mice that expresses diffusible LIF protein specifically in T cells. These mice display two categories of phenotype that were not previously attributed to LIF overexpression. First, they display B cell hyperplasia, polyclonal hypergammaglobulinemia and mesangial proliferative glomerulonephritis, defects similar to those described for transgenic mice overexpressing the functionally related cytokine, interleukin-6. Secondly, the LIF transgenic mice display novel thymic and lymph node abnormalities. In the thymus, cortical CD4+CD8+ lymphocytes are lost, while numerous B cell follicles develop. Peripheral lymph nodes contain a vastly expanded CD4+CD8+ lymphocyte population. Furthermore, the thymic epithelium is profoundly disorganized, suggesting that disruption of stroma-lymphocyte interactions is responsible for many observed defects. Transplantation of transgenic bone marrow into wild type recipients transfers both the thymic and lymph node defects. However, transplantation of wild type marrow into transgenic recipients rescues the lymph node abnormality, but not the thymic defect, indicating the thymic epithelium is irreversibly altered. Our observations are consistent with a role for LIF in maintaining a functional thymic epithelium that will support proper T cell maturation.     

A murine thymic stromal cell line which may support the differentiation of CD4-8- thymocytes into CD4+8- alpha beta T cell receptor positive T cells.

A fibroblastoid cell line TSt-4 was established from fetal thymus tissue of C57BL/6 mice. When fetal thymus (FT) cells or CD4-8- (DN) cells of adult thymuses were cultured on the monolayer of TSt-4, a considerable proportion of lymphocytes expressed CD4 or both CD4 and CD8 within 1 day, and the CD4+CD8- cells were maintained further while the CD4+8+ cells disappeared by Day 5. A large proportion of cells generated from DN cells but not FT cells was shown to express CD3 and T cell receptor alpha beta. Addition of recombinant interleukin (IL)-7 into the cultures resulted in a marked increase of cell recovery without virtual change in differentiation process of alpha beta lineage. The present work strongly suggests that thymic fibroblasts play an important role in T cell differentiation and IL-7 contributes to supporting proliferation of differentiated cells.     

Isolation of a thymus-homing Lyt-2-, L3T4- T-cell line from mouse spleen

We have selectively isolated and transformed a population of T-cell-receptor+, Lyt-2-, L3T4- cytotoxic T cells from mouse spleen following stimulation in vivo with a radiation leukemia virus-induced thymoma, C6VL/1. The two sublines analyzed here were found to induce tumors with primarily thymic involvement and one of these has been shown to have specific homing capacity for the thymus. Properties displayed by this cell line are evidence that T cells do exist in peripheral lymphoid tissue which can traffic back to the thymus and that Lyt-2-, L3T4- immature T cells can enter peripheral lymphoid organs.     

Induction of high level IL-2 production in CD4+8- T helper lymphocytes requires post-thymic development.

Triggering of the CD3:TCR complex by optimal concentrations of anti-CD3, anti-TCR beta-chain, and allogeneic stimulator cells induced dramatically higher levels (fivefold for anti-CD3, greater than 10-fold for anti-TCR beta-chain, 84-fold for alloantigen) of IL-2 production in spleen CD4+8- T cells than their thymic counterparts, despite comparable levels of CD3 and TCR beta-chain expression. The nature of the reduced IL-2 production was examined by analysis of anti-CD3-induced IL-2 production at the single cell level. The frequency of IL-2-producing cells in spleen CD4+8- T cells (40.0%) was approximately threefold that of thymus CD4+8- T cells (14.5%). Furthermore, the average IL-2 levels among positive IL-2 producers was also approximately threefold higher in spleen CD4+8- T cells than their thymic counterparts. Adoptive transfer of purified Thy-1.2+ CD4+8- T cells into Thy-1.1-congenic hosts provided a physiologic and histocompatible system that enabled identification of transferred donor (Thy-1.2+) among a sea of host (Thy-1.2-) CD4+ T cells, whose immune function with respect to IL-2 inducibility was examined after isolation by electronic cell sorting. Donor CD4+ T cells thus isolated from host spleen shortly (1 day) after i.v. transfer of thymus CD4+8- T cells were similar to freshly isolated thymus CD4+8- T cells in that they both produced little IL-2 in response to anti-CD3. However, by day 3 post-transfer, IL-2 production by donor CD4+8- T cells had more than doubled and by day 8, they produced IL-2 levels comparable to those of host spleen CD4+8- T cells. A similar acquisition of high level IL-2 inducibility in thymus CD4+8- T cells upon i.v. transfer into Thy-1.1-congenic hosts was also observed using allogeneic cells as the stimulus of IL-2 production. When thymus CD4+8- T cells were intra-thymically transferred into Thy-1.1-congenic hosts, those donor cells that emigrated to the periphery became high IL-2 producers in a time-dependent manner, whereas those that remained inside the thymus showed no signs of up-regulation in IL-2 inducibility. Intrathymic transfer of CD4-8- thymocytes revealed that the most recent thymic emigrant CD4+8- T cells contained few IL-2-producing cells and were not functionally mature with respect to high level IL-2 inducibility.     

Exposure of cynomolgus monkey embryos to retinoic acid causes thymic defects: effects on peripheral lymphoid organ development

We have previously reported that exposure of monkey embryos to 13-cis-retinoic acid (cRA) results in thymic defects. In this study, we analyzed lymphocyte and antigen-presenting cell populations at gestational days (GDs) 80-100 in the thymus, spleen, mesenteric lymph nodes, and gut-associated lymphoid tissue following a teratogenic dosing regimen of cRA (2.5 and 5 mg/kg) at GD14-27. Tissue sections were immunostained for T-cells (anti-CD3), B-cells (anti-CD20), dendritic cells (p55), and major histocompatibility class II (anti-HLA-DR). Digital images of spleen sections were analyzed to obtain the relative area occupied by the cell subsets within the white pulp (WP). Compared with controls, the T-cell dependent compartment of the spleen WP in specimens with perturbed thymic development (aplasia and severe hypoplasia) showed a reduction in size and proportion of CD3(+) T cells. Our findings indicate that cRA-induced thymic defects result in disrupted development of the splenic T-cell dependent compartment.     

Homeostatic signals do not drive post-thymic T cell maturation

Recent thymic emigrants, the youngest T cells in the lymphoid periphery, undergo a 3 week-long period of functional and phenotypic maturation before being incorporated into the pool of mature, na?ve T cells. Previous studies indicate that this maturation requires T cell exit from the thymus and access to secondary lymphoid organs, but is MHC-independent. We now show that post-thymic T cell maturation is independent of homeostatic and costimulatory pathways, requiring neither signals delivered by IL-7 nor CD80/86. Furthermore, while CCR7/CCL19,21-regulated homing of recent thymic emigrants to the T cell zones within the secondary lymphoid organs is not required for post-thymic T cell maturation, an intact dendritic cell compartment modulates this process. It is thus clear that, unlike T cell development and homeostasis, post-thymic maturation is focused not on interrogating the T cell receptor or the cell's responsiveness to homeostatic or costimulatory signals, but on some as yet unrecognized property.     

Peptide specificity of thymic selection of CD4+CD25+ T cells.

The CD4(+)CD25(+) regulatory T cells can be found in the thymus, but their need to undergo positive and negative selection has been questioned. Instead, it has been hypothesized that CD4(+)CD25(+) cells mature following TCR binding to MHC backbone, to low abundant MHC/peptide complexes, or to class II MHC loaded with peripheral autoantigens. In all these circumstances, processes that are distinct from positive and negative selection would govern the provenance of CD4(+)CD25(+) cells in the thymus. By comparing the development of CD4(+)CD25(-) and CD4(+)CD25(+) cells in mice expressing class II MHC molecules bound with one or many peptide(s), we show that the CD4(+)CD25(+) cells appear during natural selection of CD4(+) T cells. The proportion of CD4(+)CD25(+) cells in the population of CD4(+) thymocytes remains constant, and their total number reflects the complexity of selecting class II MHC/peptide complexes. Hence, thymic development of CD4(+)CD25(+) cells does not exclusively depend on the low-density, high-affinity MHC/peptide complexes or thymic presentation of peripheral self-Ags, but, rather, these cells are selected as a portion of the natural repertoire of CD4(+) T cells. Furthermore, while resistant to deletion mediated by endogenous superantigen(s), these cells were negatively selected on class II MHC/peptide complexes. We postulate that while the CD4(+)CD25(+) thymocytes are first detectable in the thymic medulla, their functional commitment occurs in the thymic cortex.     

Abnormal T cell development in CD3-zeta-/- mutant mice and identification of a novel T cell population in the intestine.

The T cell antigen receptor (TCR)-associated invariable membrane proteins (CD3-gamma, -delta, -epsilon and -zeta) are critical to the assembly and cell surface expression of the TCR/CD3 complex and to signal transduction upon engagement of TCR with antigen. Disruption of the CD3-zeta gene by homologous recombination resulted in a structurally abnormal thymus which primarily contained CD4- CD8- and TCR/CD3very lowCD4+CD8+ cells. Spleen and lymph nodes of CD3-zeta-/- mutant mice contained a normal number and ratio of CD4+ and CD8+ single positive cells that were TCR/CD3very low. These splenocytes did not respond to antibody cross-linking or mitogenic triggering. The V beta genes of CD4-CD8- and CD4+CD8+ thymocytes and splenic T cells were productively rearranged. These data demonstrated that (i) in the absence of the CD3-zeta chain, the CD4- CD8- thymocytes could differentiate to CD4+CD8+ TCR/CD3very low thymocytes, (ii) that thymic selection might have occurred, (iii) but that the transition to CD4+CD8- and CD4-CD8+ cells took place at a very low rate. Most strikingly, intraepithelial lymphocytes (IELs) isolated from the small intestine or the colon expressed normal levels of TCR/CD3 complexes on their surface which contained Fc epsilon RI gamma homodimers. In contrast to CD3-zeta containing IELs, these cells failed to proliferate after triggering with antibody cross-linking or mitogen. In comparison to thymus-derived peripheral T cells in the spleen and lymph nodes, the preferential expression of normal levels of TCR/CD3 in intestinal IELs suggested they mature via an independent extrathymic pathway.     

Developmental regulation of the intrathymic T cell precursor population

The maturation potential of CD4-8- thymocytes purified from mice of different developmental ages was examined in vivo after intrathymic injection. As previously reported, 14-day fetal CD4-8- thymocytes produced fewer CD4+ than CD8+ progeny in peripheral lymphoid tissues, resulting in a CD4+:CD8+ ratio of less than or equal to 1.0. In contrast, adult CD4-8- thymocytes generated CD4+ or CD8+ peripheral progeny in the proportions found in the normal adult animal (CD4+:CD8+ = 2 to 3). Here we have shown that CD4-8- precursor cells from the 17-day fetal thymus also produced peripheral lymphocytes with low CD4+:CD8+ ratios. Precursors from full term fetuses produced slightly higher CD4+:CD8+ ratios (1.1-1.6) and precursors from animals three to 4 days post-birth achieved CD4+:CD8+ ratios intermediate between those produced by fetal and adult CD4-8- thymocytes. Parallel changes in the production of alpha beta TCR+ peripheral progeny were observed. Fetal CD4-8- thymocytes generated fewer alpha beta TCR+ progeny than did adult CD4-8- thymocytes. However, peripheral lymphocytes arising from either fetal or adult thymic precursors showed similar proportions of gamma delta TCR+ cells. The same pattern of progeny was observed when fetal CD4-8- thymocytes matured in an adult or in a fetal thymic stromal environment. In contrast to fetal thymic precursors, fetal liver T cell precursors resembled adult CD4-8- thymocytes by all parameters measured. These results suggest that fetal thymic precursors are intrinsically different from both adult CD4-8- thymocytes and fetal liver T cell precursors. Moreover, they lead to the hypothesis that the composition of the peripheral T cell compartment is developmentally regulated by the types of precursors found in the thymus. A model is proposed in which migration of adult-like precursors from the fetal liver to the thymus approximately at birth triggers a transition from the fetal to the adult stages of intrathymic T cell differentiation.     

Studies of CD4- CD8- alpha beta bone marrow T cells with suppressor activity.

The predominant T cell subset in the bone marrow of specific pathogen-free C57BL/Ka and BALB/c mice expressed the alpha beta+ TCR CD4- CD8- surface phenotype. Purified C57BL/Ka alpha beta+ TCR CD4- CD8- marrow cells obtained by cell sorting suppressed the MLR of C57BL/Ka responder and BALB/c stimulator spleen cells. Although the percentage of typical T cells in the spleen was markedly reduced in adult nude mice or normal neonatal mice as compared to the normal adult, the percentage of alpha beta+ TCR CD4- CD8- cells in the spleen and marrow was not. The percentage of "self-reactive" V beta 5+ T cells in the BALB/c spleen was markedly reduced as compared to that in the C57BL/Ka spleen. However, the percentages in the bone marrow were similar. The results indicate that the predominant subset of marrow T cells in these pathogen-free mice differ with regard to surface marker phenotype, function, dependence on the adult thymus, and deletion of certain self-reactive V beta receptors as compared to typical spleen T cells. The marrow T cells appear to develop directly from marrow precursors without rearranged beta chain genes during a 48 hour in vitro culture.