Microenvironmental studies of pre-B and B cell development in human and mouse fetuses

Immunofluorescence techniques were used to trace the development of cells expressing mu heavy chains in humans and mice. IgM B cells were distinguished from pre-B cells by their additional expression of kappa or lambda light chains. Generation of pre-B and progeny B cells was evident in hemopoietic fetal liver and bone marrow, but not in thymus, heart, lung, spleen, kidney, and placental tissues. Pre-B and B cells, in a ratio of 2 to 1, were abundant in sections of hemopoietic liver and in bone marrow from 12- to 15-wk-old human fetuses, whereas these cells were rare in nonhemopoietic liver samples obtained beyond the 34th week. In mouse fetal liver mu+ cells appeared first around the 12th day of gestation and increased in frequency throughout the third trimester. On day 17 of gestation, kappa light chain expression by 1% of mu+ cells was noted, and the percentage of kappa+/mu+ cells increased progressively to more than 80% by 5 days after birth. Pre-B and B cells were interspersed among myeloid and more abundant erythropoietic cellular elements in the extrasinusoidal areas adjacent to hepatic cords. A loose clustering or "starburst" distribution pattern of pre-B cells became evident around day 17. These observations suggest a model for in situ generation of pre-B and progeny B cells in the hemopoietic fetal liver. In the midst of more numerous erythropoietic elements, immunoglobulin-negative precursors divide to generate a loose colony of mu+ pre-B cells that divide again before giving rise to a wave of IgM B cells.     

Emergence of T cell progenitors without B cell or myeloid differentiation potential at the earliest stage of hematopoiesis in the murine fetal liver

It has been unclear whether the progenitors colonizing the thymus are multipotent or T cell lineage restricted. We investigated the developmental potential of hematopoietic progenitors in various populations of liver and blood cells from day 12 fetuses using the recently established in vitro experimental system effective in determining the capability of individual progenitors to generate T, B, and myeloid cells. Multipotent progenitors (p-Multi) were exclusively found in the Sca-1 high-positive (Sca-1high) subpopulation of lineage marker (Lin)-c-kit+CD45+ fetal liver cells. Restriction of developmental capacity begins at the Sca-1high stage, and a large majority of progenitors in the Sca-1low or Sca-1- population are restricted to generate T, B, or myeloid cells. Such a lineage commitment or restriction taking place in the fetal liver is independent of the thymus, because no difference in the proportion of different types of progenitors were seen between nu/nu and nu/+ fetuses. T cell lineage-restricted progenitors (p-T) were abundant in the blood of day 12 fetuses, whereas p-Multi were undetectable. It was further shown that the p-Multi generated a large number of B and myeloid cells in the thymic lobe. These results strongly suggest that it is p-T but not p-Multi that migrate into the thymus.     

Identification of pro-thymocytes in murine fetal blood: T lineage commitment can precede thymus colonization.

Phenotype and commitment of thymus-colonizing precursors are unknown. Here we report the identification of T lineage-committed precursors (designated prothymocytes) in murine fetal blood at day 15.5 of development. Fetal blood pro-thymocytes are Thy-1+c-kit(low)CD3- in contrast to fetal blood-derived pluripotent hematopoietic progenitors which are Thy-1-c-kit+. Upon transfer into the thymus, fetal blood pro-thymocytes generate a single wave of CD4+CD8+ thymocytes and subsequently mature TCR alpha beta+ peripheral T cells. However, fetal blood pro-thymocytes lack multipotent progenitor potential since they fail to reconstitute B lymphocytes and myeloid and erythroid lineages. In contrast, T and B lymphocytes as well as myeloid and erythroid lineages are reconstituted from fetal blood-derived pluripotent progenitors. Pro-thymocytes are equally present in peripheral blood of athymic fetal mice, suggesting that this novel precursor population is T lineage-committed prior to thymus colonization and represents the earliest T lineage precursor identified.     

Ly1+ PRO-B lymphocyte clones. Phenotype, growth requirements and differentiation in vitro and in vivo.

Several clones obtained from the bone marrow of a BALB/c mouse were found to contain the heavy and light chain Ig genes in the germline configuration, to express Ly1 and to carry the B cell lineage markers B-220, Lyb8 and BP-1; these clones are Pgp-1+, LFA-1+, J11d+, Mac-1+ and Thy1-, Lyt2-, L3T4-, GM1.2- and Ia-. Three clones analyzed in detail (Lyd9, LyH7 and Lyb9) have receptors for interleukin (IL) 2 and IL3 as assessed with the 7D4 and CC11 monoclonal antibodies respectively. They grow in rIL3 but not in rIL2 or rIL1; both rIL4 and rIL5 also promote their proliferation, albeit to a much lesser extent than rIL3. None of the interleukins tested alone or in various combinations promoted the clones to differentiate in vitro along the B cell pathway. Treatment with 5-Azacytidine (5-Aza) induced cell surface Ia expression but not rearrangement or expression of Ig genes. However, 5-Aza-treated Lyd9, LyH7 and Lyb9 cells co-cultured with X-ray irradiated accessory cells and LPS gave rise to Ly1+, IgM+ B lymphocytes (range 14-51%) including mu + kappa + (78-93%), and mu + lambda + (9-25%) B lymphocytes. In vivo, the Lyd9, LyH7 and Lyb9 clones gave rise to IgM+ B lymphocytes (8.5-17%) including mu + kappa +, and mu + lambda +, but not to Lyt2+ or L3T4+ T lymphocytes after 4-6 weeks of transfer into Scid mice. Our results indicate that Ly1+ IgM+ cells comprise a subpopulation of B lymphocytes that is derived from IL3-responsive Ly1+ PRO-B lymphocytes.     

Ia-positive nonlymphoid cells and T cell development in murine fetal thymus organ cultures: monoclonal anti-Ia antibodies inhibit the development of T cells

A fetal thymus organ culture system has been developed to study the differentiation of murine thymus-derived immunocompetent cells (T cells) such that cell yields can be easily monitored. This system has been used to study the effects of monoclonal anti-I-A antibodies on the growth of T cells. The addition of anti-I-A antibodies, but not anti-H2K monoclonal antibodies, to fetal thymus organ cultures resulted in a decreased yield of lymphoid cells. Anti-I-A-treated cultures did not produce cells that gave an immune response in MLC assays. Anti-I-A antibodies stained a small subpopulation of nonlymphoid cells in untreated cultures by indirect immunofluorescence that were no longer detectable in cultures that had been pretreated with anti-I-A antibody. Culture of fetal thymus lobes at low temperature (20 degrees C) for 1 wk resulted in a decrease in lymphocyte production, as well as a concomitant increase in the frequency of Ia-positive nonlymphoid cells. Co-culture of fetal liver or anti-thy-1 plus complement-treated adult bone marrow with such Ia-positive cell-enriched fetal thymus lobes at 37 degrees C resulted in the production of T cells. Anti-Thy-1.1 or -1.2 staining by indirect immunofluorescence of cells obtained from co-cultures that differed at the Thy-1 locus showed that the T cells produced were derived from the bone marrow or fetal liver. T cell production occurred in both syngeneic and allogeneic cocultures. However, if co-cultures were made by using 14-day gestation fetal thymus instead of fetal liver or bone marrow as donors of T cell precursors, T cell growth was observed only in syngeneic combinations. These results suggest that Ia-positive nonlymphoid cells play a role in the development of T cells in the fetal thymus, and that "thymus processed" T cell progenitors (but not the more immature progenitors in the fetal liver or bone marrow) are self-Ia restricted in their differentiation.     

Isolation and characterization of novel suppressor T cell clones from murine fetal thymus

Murine fetal thymus from C57BL/6J (B6) and DBA/2J contains a cell population that suppresses CTL responses to alloantigens. This suppressor cell population was found to exist in high frequency in murine fetal thymus at the 14th day of gestation. The activity of this cell in the thymus declined rapidly with increasing time of gestation, and suppressor activity in the thymus was undetectable by the time of birth. On the other hand, suppressor activity could be detected in organ cultures of 14-day fetal thymus even after the organs were cultured for 14 or 21 days. Fetal thymocytes from B6 or DBA/2J mice were grown as long-term lines in interleukin 2 (IL 2)-containing medium. Clones of suppressor cells were derived from long-term cultures by micromanipulation. The clones had an average doubling time of 13 to 16 hr and were dependent on IL 2 for growth. The clones were 10- to 100-fold more efficient in suppressing CTL responses to alloantigens than day 15 fetal thymocytes. Analyses of cell surface molecules with the use of monoclonal antibodies and conventional anti-H-2 sera by radioactive binding assays showed that cloned suppressor cells from B6 fetal thymus were Thy-1 and Lyt-2+, and expressed little or no L3T4, Lyt-1, H-2K, H-2D, and class II molecules. The suppressor clones lacked the cytolytic activity of conventional CTL and also served as very poor target cells in CTL-mediated cytolysis. The suppressor function of the cloned cells was radiation-resistant, and this suppression could not be reversed by the addition of excess exogenous IL 2. The cloned cells suppressed CTL responses only when they were added within the first 48 hr of a 5-day culture period. Analyses of the antigen specificity of the suppressor cells showed that they suppressed CTL responses in a nonantigen-specific manner.     

Differentiation of NK1.1+, Ly49+ NK cells from flt3+ multipotent marrow progenitor cells.

To delineate factors involved in NK cell development, we established an in vitro system in which lineage marker (Lin)-, c-kit+, Sca2+ bone marrow cells differentiate into lytic NK1.1+ but Ly49- cells upon culture in IL-7, stem cell factor (SCF), and flt3 ligand (flt3L), followed by IL-15 alone. A comparison of the ability of IL-7, SCF, and flt3L to generate IL-15-responsive precursors suggested that NK progenitors express the receptor for flt3L. In support of this, when Lin-, c-kit+, flt3+ or Lin-, c-kit+, flt3- progenitors were utilized, 3-fold more NK cells arose from the flt3+ than from the flt3- progenitors. Furthermore, NK cells that arose from flt3- progenitors showed an immature NK1.1dim, CD2-, c-kit+ phenotype as compared with the more mature NK1.1bright, CD2+/-, c-kit- phenotype displayed by NK cells derived from flt3+ progenitors. Both progenitors, however, gave rise to NK cells that were Ly49 negative. To test the hypothesis that additional marrow-derived signals are necessary for Ly49 expression on developing NK cells, flt3+ progenitors were grown in IL-7, SCF, and flt3L followed by culture with IL-15 and a marrow-derived stromal cell line. Expression of Ly49 molecules, including those of which the MHC class I ligands were expressed on the stromal or progenitor cells, as well as others of which the known ligands were absent, was induced within 6-13 days. Thus, we have established an in vitro system in which Ly49 expression on developing NK cells can be analyzed and possibly experimentally manipulated.     

HEMCAM, an adhesion molecule expressed by c-kit+ hemopoietic progenitors

We have characterized the adhesion molecule HEMCAM, which is expressed by hemopoietic progenitors of embryonic bone marrow. HEMCAM belongs to the immunoglobulin superfamily and consists of the V-V-C2-C2-C2 Ig domains. There are three mRNA splice variants. One has a short cytoplasmic tail; another has a long tail; while the third seems to lack transmembrane and cytoplasmic regions. Except for the NH2-terminal sequence, HEMCAM is identical to gicerin, a molecular involved in neurite outgrowth and Wilm's kidney tumor progression in the chicken and it is significantly homologous with MUC18 a molecule involved in melanoma progression and metastasis in human beings. In the bone marrow the HEMCAM+ cell population contains c-kit+ subsets. HEMCAM+ cells coexpressing the receptor tyrosine kinase c-kit give rise to T cells at a frequency of 0.17 when injected intrathymically in congenic animals. As HEMCAM+, c-kit+ cells differentiate into myeloid and erythroid CFU's the double-positive cell population seems to contain precursors for multiple lineages. HEMCAM promotes cell-cell adhesion of transfected cells. Cross-linking of murine HEMCAM leads to cell spreading of T- lymphocyte progenitors adhering to the vascular adhesion molecules, PECAM-1 and VCAM-1. Thus, HEMCAM is likely to be involved in cellular adhesion and homing processes.     

The common myelolymphoid progenitor: a key intermediate stage in hemopoiesis generating T and B cells

We have previously shown that the common progenitors for myeloid, T, and B cell lineages are enriched in the earliest population of murine fetal liver. However, it remained unclear whether such multipotent progenitors represent the pluripotent progenitors capable of generating all hemopoietic cells or they also comprise progenitors restricted to myeloid, T, and B cell lineages. To address this issue, we have developed a new clonal assay covering myeloid, erythroid, T, and B cell lineages, and using this assay the developmental potential of individual cells in subpopulations of lineage marker-negative (Lin(-)) c-kit(+) murine fetal liver cells was investigated. We identified the progenitor generating myeloid, T, and B cells, but not erythroid cells in the Sca-1(high) subpopulation of Lin(-)c-kit(+) cells that can thus be designated as the common myelolymphoid progenitor (CMLP). Common myeloerythroid progenitors were also detected. These findings strongly suggest that the first branching point in fetal hemopoiesis is between the CMLP and common myeloerythroid progenitors. T and B cell progenitors may be derived from the CMLP through the previously identified myeloid/T and myeloid/B bipotent stages, respectively.     

Expression of MEL-14 antigen is not an absolute requirement for dissemination to lymph nodes after adoptive transfer of murine T lymphocyte clones

The inability of established antigen-specific murine T lymphocyte clones to recirculate well in vivo has been attributed to loss of the surface glycoprotein gp90MEL-14, which is important for specific adherence to post-capillary high endothelial venules in peripheral lymph nodes (LN). Defective recirculation of clones may contribute to inefficient adoptive immunotherapy when compared with fresh immune spleen or LN populations. To optimize models of adoptive immunotherapy, we sought to improve recirculation of Thy-1.2+, L3T4+ clones by inducing reexpression of MEL-14 antigen (gp90MEL-14). Clones were analyzed after treatment with differentiating agents, incubation in the presence or absence of recombinant interleukin 2 (rIL 2), coincubation in vitro with nonirradiated Thy-1.1 LN or thymus cells, or adoptive transfer into Thy-1.1 hosts. We were unable to demonstrate induction of gp90MEL-14 in any case. However, although clones remained MEL-14 negative, they were able to disseminate widely after subcutaneous adoptive transfer in the presence of clone-specific antigen and rIL 2 into Thy-1.1 mice pretreated with cyclophosphamide. Withdrawal of exogenous rIL 2 was associated with rapid disappearance of clones from all sites. We conclude that murine T cell clones undergo a step in terminal differentiation that precludes surface expression of gp90MEL-14 and that these clones would be unlikely to provide a source of long-lived recirculating memory T lymphocytes. However, under appropriate circumstances it is possible for antigen-specific clones to disseminate widely among host LN and mediate short-term immune responses.     

Lymphoid EVA1 Expression Is Required for DN1-DN3 Thymocytes Transition

Background

Thymus organogenesis and T lymphocyte development are accomplished together during fetal life. Proper development and maintenance of thymus architecture depend on signals generated by a sustained crosstalk between developing thymocytes and stromal elements. Any maturation impairment occurring in either cellular component leads to an aberrant thymic development. Gene expression occurring during T lymphocyte differentiation must be coordinated in a spatio-temporal fashion; one way in which this is achieved is through the regulation by cell-cell adhesion and interactions.

Principal Findings

We examined the role played by Epithelial V-like Antigen 1 (EVA1), an Ig adhesion molecule expressed on thymus epithelial cells (TEC) and immature thymocytes, in T cell development by employing RNA interference in vitro and in vivo models. Fetal liver derived haematopoietic progenitors depleted of Eva1, displayed a delayed DN1-DN3 transition and failed to generate CD4CD8 double positive T cells in OP9-DL1 coculture system. In addition, we could observe a coordinated Eva1 up-regulation in stromal and haematopoietic cells in coculture control experiments, suggesting a possible EVA1 involvement in TEC-haematopoietic cells crosstalk mechanisms. Similarly, Rag2-γc double knock out mice, transplanted with Eva1 depleted haematopoietic progenitors displayed a 10-fold reduction in thymus reconstitution and a time delayed thymocytes maturation compared to controls.

Conclusions

Our findings show that modulation of Eva1 expression in thymocytes is crucial for lymphocyte physiological developmental progression and stromal differentiation.     

Differentiation patterns of CD4/CD8 thymocyte subsets in cocultures of fetal thymus and lymphohemopoietic cells from c-fos transgenic and normal mice.

This study examined the involvement of c-fos protooncogene in thymocyte development from lymphohemopoietic T cell progenitors, within the thymic microenvironment. We first analyzed the thymocytes developing in vitro in the fetal thymus from the c-fos transgenic mice and found a high proportion of CD4+ single positive (SP) cells. We then seeded either fetal liver or bone marrow (BM) cells from normal donors onto lymphocyte-depleted fetal thymus explants of c-fos transgenic mice. The results showed an increased proportion of mature CD4+ SP and decreased CD4+CD8+ double positive (DP) cells. A similar pattern of CD4/CD8 thymocyte subsets was observed when either thymus or BM cells from c-fos transgenic mice developed within a normal thymic stroma. The kinetics of thymocyte development in organ culture (from Days 3 to 11) suggested that the SP cells obtained under these conditions may have bypassed the CD4+CD8+ DP phase. It appears that the altered pattern of thymocyte development manifested in adult c-fos transgenic mice can be induced by the early embryonic thymic stroma, and may also involve cells in the lymphohemopoietic tissues.     

Emergence of T, B, and myeloid lineage-committed as well as multipotent hemopoietic progenitors in the aorta-gonad-mesonephros region of day 10 fetuses of the mouse.

We investigated the developmental potential of hemopoietic progenitors in the aorta-gonad-mesonephros (AGM) region, where the definitive type hemopoietic progenitors have been shown to emerge before the fetal liver develops. By using an assay system that is able to determine the developmental potential of individual progenitors toward the T, B, and myeloid lineages, we show that not only multipotent progenitors but also progenitors committed to the T, B, or myeloid lineage already exist in this region of day 10 fetuses. Bipotent progenitors generating myeloid and T cells or those generating myeloid and B cells were also detected, suggesting that the commitment to T and B cell lineages is in progress in the AGM region. The numbers of these progenitors, however, were only 1/200-1/1000 of those in fetal liver of day 12 fetuses. Such small numbers of progenitors suggest that hemopoiesis has just started in the AGM region of day 10 fetuses. Although most of T cell lineage-committed progenitors in the AGM region generated only a small number of immature T cells, some were able to generate a large number of mature T cells. The detection of various types of lineage-committed progenitors strongly suggests that the AGM region is not only the site of stem cell emergence, but also the site of hemopoiesis, including lineage commitment. The T cell progenitors found in the AGM region may represent the first immigrants to the thymus anlage.     

Recombinant interleukin 2 enhanced natural killer cell-mediated cytotoxicity in human lymphocyte subpopulations expressing the Leu 7 and Leu 11 antigens

Highly purified recombinant human interleukin 2 (rIL 2) markedly augments the natural killer (NK) cell-mediated cytotoxicity of peripheral blood lymphocytes. In this study, we examined the cellular and metabolic basis of rIL 2-mediated activation of human lymphocyte subpopulations expressing the NK cell-associated surface antigens Leu 7 and Leu 11. All rIL 2-responsive cytotoxic NK cells were found within the subset of lymphocytes expressing the Leu 11 marker, an antigen associated with the Fc-IgG receptor on human NK cells. Cells lacking the Leu 11 antigen, including cells expressing another NK cell-associated marker, Leu 7, did not express NK cell-mediated cytotoxicity either before or after rIL 2 treatment. By contrast, rIL 2 augmented the NK activity of both Leu7-,11+ and Leu 7+,11+ subpopulations. Activation of Leu 11+ NK cells resulted from a direct effect of rIL 2 on these cells and neither required nor was amplified by the presence of T lymphocytes. Enhanced NK cell-mediated cytotoxicity occurred within 4 hr after exposure to rIL 2, and was blocked by the protein synthesis inhibitor cyclohexamide, but not by the DNA synthesis inhibitor mitomycin C or 1500 rad of x-irradiation. Neither Tac antigen, a high-affinity receptor for IL 2, nor other activation markers, such as transferrin receptor or HLA-DR antigen, were detectable on a significant proportion of Leu 11+ cells, either before or after incubation with rIL 2 for 48 hr. In addition, saturating concentrations of antibodies to each of these markers had no effect on the enhancement of NK activity by rIL 2. Finally, preliminary experiments with neutralizing antibodies to gamma- and alpha-interferons also failed to prevent rIL 2 enhancement of NK cell-mediated cytotoxicity, suggesting that rIL 2 does not mediate its effect via release of these cytokines.     

The earliest thymic progenitors in adults are restricted to T, NK, and dendritic cell lineage and have a potential to form more diverse TCRbeta chains than fetal progenitors

T cell progenitors in the adult thymus (AT) are not well characterized. In the present study, we show that the earliest progenitors in the murine AT are, like those in fetal thymus (FT), unable to generate B or myeloid cells, but still retain the ability to generate NK cells and dendritic cells. However, AT progenitors are distinct from those in FT or fetal liver, in that they are able to produce approximately 100 times larger numbers of T cells than progenitors in fetuses. Such a capability to generate a large number of T cells was mainly attributed to their potential to extensively proliferate before the TCRbeta chain gene rearrangement. We propose that the AT is colonized by T/NK/dendritic cell tripotential progenitors with much higher potential to form diversity in TCRbeta chains than FT progenitors.     

EVA regulates thymic stromal organisation and early thymocyte development

Epithelial V-like antigen (EVA) is an immunoglobulin-like adhesion molecule identified in a screen for molecules developmentally regulated at the DN to DP progression in thymocyte development. We show that EVA is expressed during the early stages of thymus organogenesis in both fetal thymic epithelia and T cell precursors, and is progressively downregulated from day 16.5 of embryonic development. In the postnatal thymus, EVA expression is restricted to epithelial cells and is distributed throughout both cortical and medullary thymic regions. Transgenic overexpression of EVA in the thymus cortex resulted in a modified stromal environment, which elicited an increase in organ size and absolute cell number. Although peripheral T lymphocyte numbers are augmented throughout life, no imbalance either in the repertoire, or in the different T cell subsets was detected. Collectively, these data suggest a role for EVA in structural organisation of the thymus and early lymphocyte development.     

Long-term proliferating early pre B cell lines and clones with the potential to develop to surface Ig-positive, mitogen reactive B cells in vitro and in vivo

Cell lines and clones were established from PB76-positive mouse fetal liver at day 13 and 14 of gestation, which proliferated with division times of a day in serum-substituted cultures under the stimulatory influence of adherent stromal cells and the cytokine IL-7 for periods longer than half a year. These lines expressed varying levels of the B lymphocyte lineage related markers PB76, B220, BP-1, VpreB and lambda 5, but no surface Ig or MHC class II molecules. All clones expressed PB76, VpreB and lambda 5 in a high percentage of cells, while B220 and/or BP-1 expression was low or undetectable in some. A cell line, and several clones established from it, all had kappa and lambda light chain genes in germ-line configuration. Either one or both of their H-chain-gene containing chromosomes carried a DH to JH. These pre B cell lines and clones could be induced to VH to DH and VL to JL rearrangements. This resulted in the development of varying percentages of sIg-positive surface, MHC class II negative, LPS-reactive B cells within 2-3 days, in the absence of contacts with stromal cells and/or IL-7. When injected into SCID mice, the cultured pre B cells populated the spleen of these mice to 5% with surface Ig-, MHC class II-positive LPS-reactive cells for greater than 25 weeks. The long-term in vitro proliferative capacity of these DH-JH rearranged pre B cell clones makes them major candidates for committed stem cells of the B lineage.