B cell precursors are present in the thymus during early development

The B lineage potential of thymus settling progenitors is critically dependent on mouse age

The nature and lineage potential, particularly that for B cells, of thymus settling progenitors (TSP) in the adult mouse has been the subject of considerable debate. Lack of B cell potential would suggest pre-thymic, whereas its presence would suggest intra-thymic loss of B cell potential. Using limiting dilution analysis (LDA) in vitro and transfer experiments in vivo, we show that the B cell potential of TSP is critically dependent on mouse age, reaching a maximum of about 1 in 20 cells at birth, decreasing 50-fold in adult mice. Cells with a TSP phenotype can be found in the neonatal blood. Furthermore, using LDA, we show that Notch ligand signaling of TSP results in the loss of B cell potential with a half-life of approximately 12 h. Taken together, these results indicate that loss of B cell potential by TSP is an intra-thymic event and highlight the developmental pressure acting on the immune system to rapidly colonize primary lymphoid organs with functional progenitors. This critical time coincides with birth in the mouse. In the adult mouse, we estimate than only about 5 TSP cells/day would be required to maintain steady-state thymopoiesis.

Development and maturation of the immune system in zebrafish, Danio rerio: a gene expression profiling, in situ hybridization and immunological study

The development and maturation of the immune system in zebrafish was investigated using immune-related gene expression profiling by quantitative real-time polymerase chain reaction, in situ hybridization (ISH), immunoglobulin (Ig) detection by immuno-affinity purification and Western blotting as well as immersion immunization experiments. Ikaros expression was first detected at 1 day post-fertilization (dpf) and thereafter increased gradually to more than two-fold between 28 and 42dpf before decreasing to less than the initial 1dpf expression level in adult fish (aged 105dpf). Recombination activating gene-1 (Rag-1) expression levels increased rapidly (by 10-fold) between 3 and 17dpf, reaching a maximum between 21 and 28dpf before decreasing gradually. However, in adult fish aged 105dpf, the expression level of Rag-1 had dropped markedly, and was equivalent to the expression level at 3dpf. T-cell receptor alpha constant region and immunoglobulin light chain constant region (IgLC) isotype-1, 2 and 3 mRNAs were detected at low levels by 3dpf and their expression levels increased steadily to the adult range between 4 and 6 weeks post-fertilization (wpf). Using tissue-section ISH, Rag-1 expression was detected in head kidney by 2wpf while IgLC-1, 2 and 3 were detected in the head kidney and the thymus by 3wpf onwards. Secreted Ig was only detectable using immuno-affinity purification and Western blotting by 4wpf. Humoral response to T-independent antigen (formalin-killed Aeromonas hydrophila) and T-dependent antigen (human gamma globulin) was observed in zebrafish immunized at 4 and 6wpf, respectively, indicating that immunocompetence was achieved. The findings reveal that the zebrafish immune system is morphologically and functionally mature by 4-6wpf.

B-cell development in the thymus is limited by inhibitory signals from the thymic microenvironment

B-cell precursors are present in the thymus, and the thymic microenvironment is the source of lymphopoietic factors that include interleukin-7 (IL-7). Despite the fact that intrathymic B-cell progenitors are bone marrow-derived cells, the data in this report demonstrate that these progenitors accumulate at an early pro-B-cell stage of development, cycle less than their bone marrow counterparts, and fail to differentiate efficiently. Additional studies presented herein indicate that these effects are mediated, at least in part, by soluble factors produced by the thymic microenvironment and suggest that they affect the ability of pro-B cells to respond optimally to IL-7. Taken together, these observations demonstrate a specific inhibition of intrathymic B lymphopoiesis, which in turn may explain why lymphoid cell production in the thymus is largely restricted to production of T-lineage cells despite the fact that B-cell precursors and B-lymphopoietic stimuli are present in that organ.

The ontogeny of B cells in the thymus of normal, CD3 epsilon knockout (KO), RAG-2 KO and IL-7 transgenic mice

The ontogeny of thymic B cells was determined by three-color flow cytometry and the presence or absence of B cell progenitors confirmed by cell culture experiments. In the thymus of young normal mice, CD117(+), B220(low) pro- and pre-B cells are present but disappear with age. B220(low), CD5(+), B-1 B cells are present in the thymus of older animals following the appearance of similar cells in the peritoneal cavity and blood. In CD3 epsilon gene-deleted mice, the phenotypic progression and number of thymic B cells remains unaltered, showing that blocking T cell development does not automatically result in an increase of thymic B lymphopoiesis. Pro-B cells in RAG-2 knockout mice are found in the fetal and neonatal blood, spleen and thymus, but with increasing age are only found in the bone marrow. B lymphopoiesis in adult IL-7 transgenic mice is dramatically altered with CD117(+) pro- and pre-B cells present in spleen, lymph node and blood. In the thymus of adult IL-7 transgenic mice, the fraction of CD117(+) thymic B cells is significantly increased. These results show that in the steady state, the phenotype of thymic B cells is critically dependent on both mouse age and the phenotype of circulating B cells.

Expression of Bright at Two Distinct Stages of B Lymphocyte Development

The B cell regulator of Ig heavy chain transcription (Bright) is a DNA-binding protein that was originally discovered in a mature Ag-specific B cell line after stimulation with IL-5 and Ag. It binds to the intronic heavy chain enhancer and 5′ of the V1 S107 family VH promoter. Several studies suggested that Bright may increase transcription of the heavy chain locus, and expression in cell lines was limited to those representing mature B cells. We have now analyzed normal hemopoietic tissues for the expression of Bright during B lymphocyte differentiation. We expected to find Bright expression in a subset of mature spleen cells, but also observed Bright in a subset of normal B lymphocytic progenitors in both adult bone marrow (BM) and in fetal liver as early as day 12 of gestation. Bright was also expressed in the small percentage of CD4low cells in the thymus that are newly arrived from the BM and are not yet committed to the T lymphocyte lineage, but was not observed at later stages of T cell differentiation in either the spleen or thymus. Bright mRNA was not detected in the immature B lymphocytes that initially populate the spleen after migration from the BM. In addition, new splice variants of Bright were observed in fetal tissues. Thus, Bright expression is highly regulated in normal murine lymphocytes and occurs both early and late during B cell differentiation. These findings may have important implications for the function of Bright in regulating Ig transcription.

Organ culture for thymus transplantation

A method is presented for organ culture of postnatal thymus. Such tissue has been used for transplantation for nearly 20 years, but lasting benefit has been observed only in patients with the DiGeorge anomaly. Transplantation in other diseases has produced little or no results. Recently, improved methods for preparing the tissue as well as modifications of the culture media show marked improvement in quality and quantity of tissue suitable for transplant. In addition, using recently available monoclonal antibodies, preservation of vital stromal components can be monitored. The availability of reasonable amounts of high quality thymus tissue for transplantation may stimulate interest in further clinical trials where thymus transplantation may augment or restore T cell immunity.

Thymic epithelium induces full tolerance to skin and heart but not to B lymphocyte grafts

Athymic nude mice reconstituted at birth with allogeneic thymic epithelia (TE) from day 10 embryos (E10), show life-long specific tolerance to skin and heart grafts, but eliminate B lymphocytes of the TE donor haplotype, nearly as well as those from a third strain. Previous immunizations with B cells do not alter the state of tolerance to skin grafts, but specifically accelerate elimination of lymphocytes. In contrast, transplantation of E15 allogeneic thymuses already seeded by hematopoietic cells resulted in chimeras tolerant to both skin and B lymphocytes. In vitro reactivities towards stimulator spleen cells of the haplotype of the thymus were observed in both E10 TE and E15 thymus chimeras. We conclude that induction of full in vivo tolerance to B cells requires hematopoietic cells, while this is not the case for induction of tolerance to skin and heart tissues; furthermore, in vitro reactivity to stimulator spleen cells of the tolerized haplotype is independent of in vivo tolerance.

Tumor necrosis factor alpha is an autocrine growth factor for normal human B cells

Transcription of the human tumor necrosis factor alpha (TNF-alpha) gene is one of the earliest events that occurs after stimulation of B or T cells via their antigen receptors. Antibody directed at surface immunoglobulin (anti-Ig) on B cells has previously been shown to induce a rapid burst of TNF-alpha gene transcription, which can be blocked by the immunosuppressants cyclosporin A (CsA) and FK506. Here, TNF-alpha gene transcription is shown also to be highly and rapidly induced in human B cells after stimulation via the CD40 and interleukin 4 pathways, which similarly is inhibited by CsA and a panel of CsA or FK506 analogues that block calcineurin phosphatase activity. Endogenous TNF-alpha produced after stimulation was involved in B-cell proliferation since anti-TNF-alpha monoclonal antibody inhibited both anti-Ig- and anti-CD40-induced B-cell proliferative responses. Moreover, addition of TNF-alpha during stimulation resulted in augmentation of B-cell proliferation, which was also inhibited by anti-TNF-alpha monoclonal antibody. Although lymphotoxin alpha (LT-alpha) mRNA is induced by both pathways, it is not blocked by CsA, whereas LT-beta mRNA is constitutively expressed in B cells. Thus, TNF-alpha is a necessary autocrine growth factor for human B cells stimulated via two independent CsA-sensitive pathways and plays a role similar to that of interleukin 2 in T-cell proliferation. The autocrine nature of TNF-alpha in activated B cells implies a potential role for this cytokine in infection-related polyclonal B-cell expansion and in B-cell malignancies.

Transplantation tolerance is unrelated to superantigen-dependent deletion and anergy

C57BL/6 (B6; I-E-, Mls-2b) nude mice, reconstituted at birth with thymic epithelium (TE) from BALB/c (BA; I-E+, Mls-2a) day 10 embryos (E10), permanently accepted BALB/c skin, when grafted as adults. T-cell receptor repertoire analyses in the periphery of these mice revealed no difference in frequencies of I-E/superantigen-reactive T-cell receptor V beta families, as compared to chimeras constructed with syngeneic B6 E10 TE. T lymphocytes bearing V beta 3, V beta 5, and V beta 11 T-cell receptors, from either allogeneic or syngeneic TE chimeras, responded equally well to in vitro receptor-dependent stimulation. Similar results were obtained with nude mice reconstituted at birth with E14 thymuses, already colonized by hemopoietic cells. These observations indicate that neither TE cells nor the progenies of hemopoietic precursors that colonize the thymus up to E14 express or functionally present the superantigens addressed here; it follows that tolerance to skin grafts and superantigen-related T-cell deletions are unrelated phenomena.

Selection of murine T cell receptor alpha beta and gamma delta cells in organ cultures established from 14-day embryos

The expression of minor lymphocyte stimulatory locus (Mls) determinants in combination with murine major histocompatibility complex (MHC) class II molecules, leads to the destruction of lymphocytes bearing specific V region-encoded T cell receptor (TcR) products. A much studied example is the elimination of V beta 6+ cells in IE+/Mls-1a mice, in which deletion can be detected 7-10 days after birth but is not fully operational earlier in embryonic life. Here we investigate this transitional period in development and show that selective deletion of V beta 6 occurs in vitro, approximately 1 week after organ cultures are established from 14 day embryos. These unmanipulated organ cultures receive no additional cell immigrants after day 14, suggesting that the cellular elements mediating negative selection (or their direct precursors), are already resident in the fetal thymus by day 14 of gestation. Hence, the developmental timing of the outset of rigorous negative selection of V beta 6 is not dictated by the postnatal entry of deleting elements into the thymus, but perhaps by the maturation of the pre-existing environment. Using a parallel organ-culture approach we have looked at the development of V delta 4 and V gamma 3, TcR gamma delta+ cells in a variety of mouse strains. These receptors have recently been reported to be subject of MHC and non-MHC linked selection, respectively. We find that after an initial period of expansion, the number of V gamma 3-expressing cells dramatically declines. However, this selective loss of V gamma 3 cells is not contingent on the C57BL/6 mouse strain (in contrast to a previous report). These findings are discussed in the context of current models of ontogeny and repertoire selection.

Thymic epithelium induces neither clonal deletion nor anergy to Mls 1a antigens

Grafting of thymic anlagen from day-10 DBA/2 (H-2d; Mls-1a) embryos to newborn athymic BALB/c (H-2d; Mls-1b) mice leads to reconstitution of T cell populations in the recipients. Analysis of adult chimeras shows that their V beta T cell receptor (TcR) repertoires, particularly V beta 6 and V beta 8.1, do not significantly differ in most animals (10 out of 13) from those scored in control chimeras that received syngeneic thymic anlagen. In all cases analyzed, such Mls-1a-reactive T cells could be stimulated at levels comparable to control responses, both in vitro and in vivo. The few cases in which Mls-1a reactive V beta TcR were reduced seem to reflect the variability in TcR V beta repertoires found in this experimental system. In contrast, BALB/c mice, injected at birth with DBA/2 spleen cells show a marked, albeit variable, reduction in the frequencies of V beta 6- and V beta 8.1-bearing CD4+ T cells, and lower frequencies of Mls-1a-reactive T cells in limiting dilution analyses. It appears, however, that V beta 6- and V beta 8.1-bearing T cells remaining in these mice are functionally competent. We conclude that Mls-1 antigens are not expressed by thymic epithelium.

Distinct mechanisms of neonatal tolerance induced by dendritic cells and thymic B cells

To assess the role of different types of antigen-presenting cells (APC) in the induction of tolerance, we isolated B cells, macrophages, and dendritic cells from thymus and spleen, and injected these into neonatal BALB/c mice across an Mls-1 antigenic barrier. One week after injection of APC from Mls-1-incompatible mice or from control syngeneic mice, we measured the number of thymic, Mls-1a-reactive, V beta 6+ T cells and the capacity of thymocytes to induce a graft-vs.-host (GVH) reaction in popliteal lymph nodes of Mls-1a mice. Injection of thymic but not spleen B cells deleted thymic, Mls-1a-reactive V beta 6+ T cells and induced tolerance in the GVH assay. The thymic B cells were primarily of the CD5+ type, and fluorescence-activated cell sorter-purified CD5+ thymic B cells were active. Injection of dendritic cells from spleen or thymus also induced tolerance, but the V beta 6 cells were anergized rather than deleted. Macrophages from thymus did not induce tolerance. Dendritic cells and thymic B cells were also effective in inducing tolerance even when injected into Mls-, major histocompatibility complex-incompatible, I-E- mice, but only thymic B cells depleted V beta 6-expressing T cells. Therefore, different types of bone marrow-derived APC have different capacities for inducing tolerance, and the active cell types (dendritic cells and CD5+ thymic B cells) can act by distinct mechanisms.

Ontogeny of thymic B cells in normal mice

Ontogeny of thymic B cells and their surface characteristics were analyzed using monoclonal antibodies (mAbs) against B220 molecules (CD45, CD45R). A small number of B cells were detected in fetal thymus on Gestation Day 14 (approximately 3.5% of the low-density fraction). Similarly, the percentage of B cells in the low-density fraction was 3.2% on Gestation Day 18, and 3.5% on Day 1 after birth. These were the same level as that of adult mice. CD5+ B cells, which form the major population of thymic B cells, were also found in the fetal life (0.5% on Day 14 and 2.2% on Day 16 in the low-density cells). The percentage of CD5+ B cells in B cell-enriched fraction was about 65% on Day 1 after birth, which is the same level as that in adult mice. These results indicate that a small number of B cells or cells in the B-cell lineage are present in the fetal thymus and also suggest the importance of these thymic B cells in the negative selection of T cells during early developmental stages.

Individual germinal centres of myasthenia gravis human thymuses contain polyclonal activated B cells that express all the Vh and Vk families

Using in situ hybridization, we analysed the immunoglobulin repertoire expressed by the B cells present in myasthenia gravis thymuses from four patients. B cells, mostly in activated state, were clustered in germinal centres, in which multiple isotypes were identified. A majority of cells expressed IgG as compared with IgM, with a roughly similar contribution of kappa and lambda chains. Hybridization with the six VH and the 4 VK human family probes was observed in serial sections, providing additional evidence that individual germinal centres were polyclonal. The thymic B cell repertoire closely reflected the VH and the VK family usage of normal peripheral blood lymphocytes with the preferential utilization of VH3, VK1 and VK3.

Presentation of endogenous immunoglobulin determinant to immunoglobulin-recognizing T cell clones by the thymic cells

Using immunoglobulin (Ig)-recognizing T helper clones the expression of Ig peptide/major histocompatibility complex class II complexes derived by the processing of endogeneous Ig molecules in the thymus was demonstrated. It was found that thymic B cells but not "classic" thymic antigen-presenting cells and macrophages represent the major antigen-presenting cell type of determinants of endogenously synthesized surface Ig (Ig kappa-1b) and anti-surface Ig antibodies (IdC3B9). The Ig kappa-1b-presenting activity in the thymus appears relatively late, only after 3 weeks of postnatal life, while in the spleen an efficient presentation of endogenous Ig kappa-1b epitope is observed very early after birth. This difference between thymic and peripheral presentation of endogeneous Ig determinant could be important for understanding the mechanisms of T cell tolerance to self Ig and the role of self Ig in negative and positive selection of T cell repertoire.

Rat bone marrow cells undergo thymopoiesis in mouse fetal thymic organ culture

We have developed an in vitro differentiation assay allowing the study of thymopoiesis from rat bone marrow cells. In this assay, Wistar rat bone marrow cells repopulated fetal Swiss mouse thymic lobes depleted in endogeneous lymphoid cells by deoxyguanosine treatment. Due to the xenogeneic situation, repopulating rat cells from any hemopoietic lineage could be easily recognized by anti-rat monoclonal antibodies such as anti-Thy-1.1 that did not react with Swiss mouse thymocytes. After 15 days in vitro, 80% of the developing rat cells were Thy-1.1+ lymphoid cells and about 70% of the Thy-1.1+ cells expressed CD5, CD2 and leukosialin. The percentages of cells expressing pre-B cell, B cell and myeloid determinants were less than 20%. The developing thymocytes comprised CD4-CD8- T cell receptor (TcR) alpha/beta-, CD4-CD8+TcR alpha/beta low and CD4+CD8+TcR alpha/beta low cells, indicating that the early stages of rat thymopoiesis occurred within mouse thymic lobes. Limiting dilution assays showed that 50% of positive assays were obtained with 3000 nucleated bone marrow cells, which is in good agreement with recent estimates derived from in vivo reconstitution after intrathymical transfer. Moreover the limiting dilution assays proved to be sensitive enough to evidence a tenfold enrichment of pre-T cell activity in the low-density fraction of rat bone marrow. This xenogeneic system might greatly facilitate studies on prethymic and intrathymic stages of rat T cell development and permit new in vitro approaches of the colonizing bone marrow T cell precursor properties.

Ontogenic characterization of thymic B lymphocytes. Analysis in different mouse strains

We have characterized a population of murine B lymphocytes present in the thymus (TBL). They are a minor subset (0.2%-1% of total thymocytes), present from perinatal periods onwards and constituted by activated cells with a high proportion of Ig-secreting cells. They represent the first B lymphocytes detected that secrete IgG after birth. Functional analysis reveals that the frequency of lipopolysaccharide-responding cells in TBL is 5- to 10-fold lower than in the spleen. TBL from adult mice did not show any significant difference in their VH repertoire expression when compared to peripheral B lymphocytes. Furthermore, we have been able to isolate a subpopulation of B220+IgM-CD3- thymocytes whose putative B cell precursor potential needs to be directly analyzed. These and other findings support the intrathymic resident characteristics of TBL and suggest new ways of elucidating its physiological role in the complex selective processes occurring inside the thymus.

Fucose and galactose receptor and liver recognition by lymphoma cells

A syngeneic model system for the study of metastases is described. The system consisted of 2 lymphoma clones (A/63-I and A/63-2) derived from a single thymoma (A/63) induced by a wild-type Abelson-Moloney viral complex. Phenotype and genotype analyses revealed that both clones were derived from transformation of early T-cell precursors. An in vivo study of the colonizing potential following intravenous (i.v.) injection of clones showed that only the A/63-I cell clone colonized the liver. This observation was confirmed by quantitative analysis of organ distribution of both cell clones consecutive to i.v. injection of 125IUdR-labelled cells. In the same way, an in vitro study of the invasive potential of both clones was performed on frozen liver sections and showed that only the A/63-I cell clone had the ability to attach to liver. This specific adhesion was inhibited by L-fucose, D-galactose, N-acetyl-D-galactosamine (D-GalNAc) and with D-galactose- and L-fucose-containing neoglycoproteins. Differences in cell surface carbohydrates of the 2 cell clones were detected using various lectins: peanut agglutinin (PNA), Dolichos biflorus (DBA), Aleuria aurantia (AAA) and Galactia tenuiflora agglutinins (GTA). A/63-I was found to react strongly with PNA, DBA and GTA, and the removal of sialic acid by neuraminidase treatment increased DBA and PNA receptor sites of A/63-2 as compared to A/63-I. The present data suggest that cell-surface GalNAc, galactosyl and fucosyl residues are responsible for the ability of the A/63-I cell clone to recognize liver tissue probably through binding to a Kupffer-cell-associated lectin.

Thymic dendritic cells and B cells: isolation and function

The thymus is the primary organ in which T cells undergo rearrangement of T cell receptor alpha and beta genes, positive selection for affinity to self MHC products, and elimination (negative selection) of reactivity to self antigens. These events require an interaction of the developing T cell with other cell types in the thymus. The latter include epithelial cells, macrophages, dendritic cells, and the recently described thymic B cells the majority of which are CD5+. Here we review the identification and isolation of thymic dendritic cells and CD5+ B cells. We consider phenotype, ontogeny, and function, including possible contributions to the induction of self tolerance. Thymic dendritic cells are similar to spleen dendritic cells, but are larger and exhibit a few differences in phenotype. Dendritic cells from both organs are equally potent accessory cells for the MLR and lectin-induced, T cell proliferation. Thymic dendritic cells have higher levels of Fc receptors and support anti-CD3 dependent mitogenesis. Thymic CD5+ B cells share phenotypic features with peritoneal CD5+ B cells. However thymic B cells neither proliferate nor form antibody producing cells in response to the stimulation with LPS or anti-IgM plus IL-4, but do respond to stimulation with MHC class II-restricted helper T cells. Thymic dendritic cells and CD5+ B cells both appear at a similar time in ontogeny, about 14 d of gestation, which is the time T cell differentiation begins to take place. Dendritic cells from spleen, which are potent activators for peripheral T cells, are also potent inactivators for thymic-derived cytotoxic T cells. A correlation between reactivity to MIs products and the expression of TCR-V beta genes is well documented, and B cells are the primary APC for this antigen. Therefore, thymic CD5+ B cells may be a good tool for the investigation of tolerance to M1s products.

Elimination of self-tolerogen turns nonresponder mice into responders

Two sets of genes control the immune response of H-2d mice to the synthetic antigen poly(Glu50Tyr50) (GT). One set involves class II major histocompatibility complex (Mhc) loci encoding an Ad product that serves as a recognition context to GT-reactive helper T cells (Th). The other one is a background gene, the product of which, in association with the same Mhc-restricting element, mimics the GT/Ad complex. Mice expressing the GT-mimicking background-encoded structure (Imgt), which is preferentially displayed on B lymphoblasts, do not respond to GT as a consequence of self-tolerance. On the other hand, elimination of cells bearing Imgt renders these mice responsive to GT, demonstrating that tolerance to self can impoverish the immune system. Imgt is probably not identical to GT, but resembles it in the way it forms complexes with Ad molecules of Mhc.