Stabilized beta-catenin in thymic epithelial cells blocks thymus development and function.

Thymic T cell development is dependent on a specialized epithelial microenvironment mainly composed of cortical and medullary thymic epithelial cells (TECs). The molecular programs governing the differentiation and maintenance of TECs remain largely unknown. Wnt signaling is central to the development and maintenance of several organ systems but a specific role of this pathway for thymus organogenesis has not yet been ascertained. In this report, we demonstrate that activation of the canonical Wnt signaling pathway by a stabilizing mutation of beta-catenin targeted exclusively to TECs changes the initial commitment of endodermal epithelia to a thymic cell fate. Consequently, the formation of a correctly composed and organized thymic microenvironment is prevented, thymic immigration of hematopoietic precursors is restricted, and intrathymic T cell differentiation is arrested at a very early developmental stage causing severe immunodeficiency. These results suggest that a precise regulation of canonical Wnt signaling in thymic epithelia is essential for normal thymus development and function.

Early lymphocyte development in bone marrow and thymus.

Haematopoietic stem cells (HSCs), a very rare cell type in the bone marrow, are responsible for the life-long production of all cells of the blood including T and B cells. Until recently, it was thought that the differentiation of HSCs into the various haematopoietic cells was rather hierarchical in that differentiation along a given lineage was associated with a progressive loss of potential to give rise to other blood cell lineages. The recent development of very sensitive and quantitative in vitro assays, together with the identification of new progenitor subpopulations, has challenged this idea. Thus, lymphocyte progenitors can be shown to keep their developmental potential to give rise to myeloid, dendritic and NK cells until just prior to their final commitment stage. Here we review these new findings and concepts.

The potential involvement of Notch signaling in NK cell development.

NK cells constitute an essential element of the innate immune system; however, the cellular and molecular mechanisms that guide their early development are still poorly understood. Here, we demonstrate that in addition to its known crucial role in T cell development, Notch signaling can also be involved in NK cell development. Thus, upon co-culture on OP9 stroma expressing the Notch ligand Delta-like 1 (OP9-DL1), Pax5-deficient pro-B cells, which have multi-lineage potential, efficiently differentiate into T and NK cells. Upon DL-1 signaling, Pax5-deficient pro-B cells down-regulate both surface CD93 expression and transcripts for B cell-specific genes and concomitantly up-regulate T lineage gene transcripts. Subsequent transfer of DL-1-signaled Pax5-deficient pro-B cells onto OP9 stroma in the presence of IL-2 leads to their efficient differentiation into NK1.1(+), functional NK cells. Moreover, bone marrow early progenitor with lymphoid and myeloid differentiation potential (EPLM), which we have previously described as the normal in vivo-equivalent of Pax5-deficient pro-B cells, also gain the ability to differentiate into effector NK cells following transient DL1 Notch-mediated signaling. The potential involvement of Notch signaling in the generation of the NK cell repertoire in vivo is discussed.

Early lymphocyte development in bone marrow and thymus.

Haematopoietic stem cells (HSCs), a very rare cell type in the bone marrow, are responsible for the life-long production of all cells of the blood including T and B cells. Until recently, it was thought that the differentiation of HSCs into the various haematopoietic cells was rather hierarchical in that differentiation along a given lineage was associated with a progressive loss of potential to give rise to other blood cell lineages. The recent development of very sensitive and quantitative in vitro assays, together with the identification of new progenitor subpopulations, has challenged this idea. Thus, lymphocyte progenitors can be shown to keep their developmental potential to give rise to myeloid, dendritic and NK cells until just prior to their final commitment stage. Here we review these new findings and concepts.

Increasing Flt3L availability alters composition of a novel bone marrow lymphoid progenitor compartment.

We have recently described a CD19(-) B220(+)CD117(low) bone marrow subpopulation with B, T, and myeloid developmental potential, which we have called "early progenitors with lymphoid and myeloid potential" or EPLM. These cells also expressed Fms-like tyrosine kinase 3, Flt3, or CD135. Treatment of mice with the corresponding ligand, Flt3L, showed a 50-fold increase in EPLM. In addition to the expected increase in dendritic cell numbers, Flt3L treatment had a reversible inhibitory effect on B lymphopoiesis. Limiting dilution analysis of sorted EPLM from Flt3L-treated mice showed that B-lymphocyte progenitor activity was reduced 20-fold, but that myeloid and T-cell progenitor activity was largely preserved. EPLM from treated mice transiently reconstituted the thymus and bone marrow of recipient mice, generating cohorts of functional T and B cells in peripheral lymphoid organs. Thus, Flt3L treatment results in a dramatic increase in a novel bone marrow cell with lymphoid and myeloid progenitor activity.

Critical role for c-kit (CD117) in T cell lineage commitment and early thymocyte development in vitro.

The precise roles played by the transmembrane receptor tyrosine kinase c-kit and its ligand stem cell factor in early T cell development are difficult to study. Using cloned Pax5-deficient progenitor B cells, we show that following Notch signaling, which induces their commitment to the T cell developmental pathway, c-kit expression is rapidly up-regulated at both the transcriptional and cell surface level. Using either an anti-c-kit monoclonal antibody or Gleevec, a pharmacological inhibitor of c-kit signaling, we show that the Notch-induced T cell differentiation of either Pax5-deficient progenitor B cells, or the equivalent cell from the bone marrow of normal mice, is strictly dependent on c-kit signaling, whereas the differentiation of normal progenitors into the B cell lineage is not. Moreover, we show that the Notch and IL-7 signaling-induced proliferation and differentiation of CD44+CD25-c-kit(high) and CD44+CD25+c-kithigh thymocytes along the T cell, but not natural killer cell or macrophage, pathway also requires c-kit signaling, whereas the Notch-induced proliferation and differentiation of CD44-CD25+c-kitint cells along the T cell pathway is independent of c-kit. These results further highlight the complex inter-relationships existing between c-kit, Notch and IL-7 receptor signaling that control the proliferation and differentiation of early T cell progenitors.

A B220+ CD117+ CD19- hematopoietic progenitor with potent lymphoid and myeloid developmental potential.

In this report, we identify in the bone marrow (BM) of normal mice a subpopulation of B220+ CD117+ CD19- NK1.1- cells with potent lymphoid and myeloid developmental potential. These cells represent 0.1-0.2% of nucleated BM cells. By limiting dilution analysis in the presence of the appropriate combination of stromal cells and cytokines, 1 in 5-10 sorted cells formed B cells, 1 in 10-15 formed T cells and 1 in 5-10 generated macrophages. When cultured on a mixture of OP9 stroma and OP9 stromal cells expressing the Notch ligand Delta-like-1, single cells generated both T and B cells. Following intravenous infusion, freshly sorted cells transiently reconstituted both the T and B cell progenitor compartments, generating cohorts of mature T and B lymphocytes. The relationship between B220+ CD117+ CD19- NK1.1- cells of wild-type mice and other multi-lineage BM progenitors is discussed.

The earliest subpopulation of mouse thymocytes contains potent T, significant macrophage, and natural killer cell but no B-lymphocyte potential.

The B-lymphocyte potential of progenitor thymocytes and whether the thymus is colonized by common lymphocyte progenitor cells have been subjects of considerable debate. Herein, we have used limiting dilution analysis to determine the lineage potential of phenotypically defined subpopulations of CD4-CD8- double-negative thymocytes. Culture systems used showed single-hit kinetics and had a high plating efficiency for B-, myeloid, and natural killer cell development. The T-cell potential of sorted cells was confirmed by transferring cells to fetal thymus organ cultures. Our results indicate that the earliest population of CD117+ double-negative cells, although containing potent T-cell developmental potential and significant myeloid and natural killer potential, does not have any residual B-cell potential. Gene transcription analysis also indicated that these double-negative cells contained abundant T and myeloid, but not B cell-specific transcripts. The implications of these results within the context of current models of thymocyte development are discussed.

The role of Notch and IL-7 signaling in early thymocyte proliferation and differentiation.

We have analyzed the roles of Notch and IL-7 signaling in the proliferation and differentiation of mouse progenitor thymocyte subpopulations cultured on Notch delta-like-1 ligand-expressing OP9 stromal cells. Using bulk and limiting dilution cultures, we show that DN1 and DN2 cells require both Notch and IL-7 signaling for efficient proliferation and differentiation into cytoplasmic TCRbeta and surface TCRalpha/beta and TCRgamma/delta expressing T cells. Selection for cytoplasmic TCRbeta-positive cells is dependent on preTalpha expression. Both gamma/delta and alpha/beta TCR expressing T cells arising in culture can be efficiently stimulated by anti-CD3 cross-linking, suggesting that they might be functional. The differentiation of adult, but not fetal, DN1 and DN2 thymocytes into CD4 and/or CD8 expressing cells is inhibited by IL-7. Finally, efficient proliferation and differentiation of DN3 cells requires Notch signaling and preTCR expression, but is independent of IL-7.

Wnt glycoproteins regulate the expression of FoxN1, the gene defective in nude mice.

T cell development and selection require the fully mature and diverse epithelial microenvironment of the thymus. Acquisition of these characteristics is dependent on expression of the forkhead (also known as winged-helix) transcription factor FoxN1, as a lack of functional FoxN1 results in aberrant epithelial morphogenesis and an inability to attract lymphoid precursors to the thymus primordium. However, the transcriptional control of Foxn1 expression has not been elucidated. Here we report that secreted Wnt glycoproteins, expressed by thymic epithelial cells and thymocytes, regulate epithelial Foxn1 expression in both autocrine and paracrine fashions. Wnt molecules therefore provide regulatory signals critical for thymic function.