Yoshimoto Katsura

In Vitro Generation of Lymphohematopoietic Cells from Endothelial Cells Purified from Murine Embryos

We have investigated the lymphohematopoietic potentials of endothelial cells (EC) and hematopoietic cells (HPC) sorted from embryos. Expression of VE-cadherin, CD45, and Ter119 was used to distinguish EC (VE-cadherin+CD45-Ter119-) from HPC (VE-cadherin-CD45+). Thus defined, EC population takes up acetylated LDL and coexpresses CD31, Flk1, and CD34. In E9.5 embryos, EC from yolk sac (YS) and the embryo proper generate blood cells, including lymphocytes. Thus, lymphohematopoietic EC do exist in the embryo, and they are generated both in YS and the embryo proper. On the other hand, HPC with lymphopoietic potency appear first in the embryo proper. These findings implicate involvement of multiple environmental cues for acquiring lymphopoietic competency during differentiation of HPC.

The monoclonal antibody TER-119 recognizes a molecule associated with glycophorin A and specifically marks the late stages of murine erythroid lineage.

The antigen specificity of a rat monoclonal antibody TER‐119 was investigated. In adult mice, TER‐119 reacted with mature erythrocytes, 20–25% of bone marrow cells and 2–3% of spleen cells but not with thymocytes nor lymph node cells. In fetal haematopoietic tissues, 30–40% of d 10 yolk sac cells, 80–90% of d 14 fetal liver cells and 40–50% of newborn liver cells were reactive with TER‐119. TER‐119+ cells in adult bone marrow expressed significant levels of CD45 but not myeloid (Mac‐1, Gr‐1) or B‐cell (B220) markers. Morphological examination and haematopoietic colony‐forming assays for isolated TER‐119+ cells revealed that TER‐119 reacts with erythroid cells at differentiation stages from early proerythroblast to mature erythrocyte, but not with cells showing typical erythroid blast‐forming unit (BFU‐E) and erythroid colony‐forming unit (CFU‐E) activities. Erythroleukaemia cell lines do not express the TER‐119 antigen even after stimulation with dimethylsulphoxide. TER‐119 immunoprecipitated protein bands with molecular masses of 110 kDa, 60 kDa, 52 kDa and 32 kDa from erythrocyte membrane, whereas only a 52‐kDa band was detected by TER‐119 in Western blot analysis. Further molecular and cellular analyses indicated that the TER‐119 antigen is a molecule associated with cell‐surface glycophorin A but not with glycophorin A itself.

Adult T-cell progenitors retain myeloid potential

During haematopoiesis, pluripotent haematopoietic stem cells are sequentially restricted to give rise to a variety of lineage-committed progenitors. The classical model of haematopoiesis postulates that, in the first step of differentiation, the stem cell generates common myelo-erythroid progenitors and common lymphoid progenitors (CLPs). However, our previous studies in fetal mice showed that myeloid potential persists even as the lineage branches segregate towards T and B cells. We therefore proposed the ‘myeloid-based’ model of haematopoiesis, in which the stem cell initially generates common myelo-erythroid progenitors and common myelo-lymphoid progenitors. T-cell and B-cell progenitors subsequently arise from common myelo-lymphoid progenitors through myeloid-T and myeloid-B stages, respectively. However, it has been unclear whether this myeloid-based model is also valid for adult haematopoiesis. Here we provide clonal evidence that the early cell populations in the adult thymus contain progenitors that have lost the potential to generate B cells but retain substantial macrophage potential as well as T-cell, natural killer (NK)-cell and dendritic-cell potential. We also show that such T-cell progenitors can give rise to macrophages in the thymic environment in vivo. Our findings argue against the classical dichotomy model in which T cells are derived from CLPs; instead, they support the validity of the myeloid-based model for both adult and fetal haematopoiesis.

An Essential Developmental Checkpoint for Production of the T Cell Lineage

One Two T T cells develop in the thymus, where they proceed through several developmental stages, losing alternative lineage potential as they progress. The molecular regulation of this developmental process, however, is not fully understood (see the Perspective by Di Santo). P. Li et al. (p. 85, published online 10 June), L. Li et al. (p. 89), and Ikawa et al. (p. 93) now identify expression of the zinc finger transcription factor Bcl11b as the earliest checkpoint in T cell development in mice. Genetic deletion of Bcl11b in developing T cells inhibited commitment to the T cell lineage. Under conditions that should have stimulated T lineage differentiation, Bcl11b-deficient T cell progenitors failed to up-regulate genes associated with lineage-committed T cells and maintained stem cell– and progenitor cell–associated gene expression. In both developing and committed T cells, loss of Bcl11b resulted in the generation of cells that resembled natural killer (NK) cells in both phenotype and function. These NK-like cells could be expanded easily in vitro and possessed antitumor cytotoxicity, but they did not exhibit cytotoxicity against normal cells and were not tumorigenic. Because T cells are much easier to obtain from human patients than NK cells, deletion of Bcl11b in T cells may thus provide a source of easy-to-grow NK cells for cell-based antitumor therapies. A transcription factor is essential for maintenance of T cell identity. In early T cell development, progenitors retaining the potential to generate myeloid and natural killer lineages are eventually determined to a specific T cell lineage. The molecular mechanisms that drive this determination step remain unclarified. We show that, when murine hematopoietic progenitors were cultured on immobilized Notch ligand DLL4 protein in the presence of a cocktail of cytokines including interleukin-7, progenitors developing toward T cells were arrested and the arrested cells entered a self-renewal cycle, maintaining non-T lineage potentials. Reduced concentrations of interleukin-7 promoted T cell lineage determination. A similar arrest and self-renewal of progenitors were observed in thymocytes of mice deficient in the transcription factor Bcl11b. Our study thus identifies the earliest checkpoint during T cell development and shows that it is Bcl11b-dependent.

Redefinition of lymphoid progenitors

Similarities between T and B lymphocytes might have led to the idea that these functionally distinct cells develop from a common lymphoid progenitor. However, investigations with a new clonal assay which allows for T-, B- and myeloid-lineage development indicate that commitment to T-cell and B-cell lineages occurs instead through myeloid/T and myeloid/B bipotential stages, respectively. These findings provide an opportunity to reconsider the ontogeny and phylogeny of T- and B-cell development.

The earliest stages of B cell development require a chemokine stromal cell-derived factor/pre-B cell growth-stimulating factor.

Environmental factors essential for the first stages of B lymphopoiesis remain elusive. Here, we report that immediately after commitment to B lineage, precursors become dependent on a chemokine SDF-1 and its receptor CXCR4 using mutant and radiation chimeric mice. In bone marrow, generation of the earliest identifiable B cell precursor populations requires CXCR4. In fetal liver, we identified Lin(-)CD19(-)c-kit(+)IL-7Ralpha(+)AA4.1(+), the earliest unipotent B cell precursor population, and found that its development was severely affected in SDF-1(-/-) embryos but not in IL-7(-/-) embryos. Lin(-) T cell progenitors appeared normal in SDF-1(-/-) embryos. Moreover, SDF-1 exhibited specific biologic activities on the earliest B cell precursors. SDF-1 provides the first example of a cytokine responsible for the earliest B lineage stages.

Commitment to natural killer cells requires the helix–loop–helix inhibitor Id2

We have previously described how T and natural killer (NK) lineage commitment proceeds from common T/NK progenitors (p-T/NK) in the murine fetal thymus (FT), with the use of a clonal assay system capable of discriminating p-T/NK from unipotent T or NK lineage-committed progenitors (p-T and p-NK, respectively). The molecular mechanisms controlling the commitment processes, however, are yet to be defined. In this study, we investigated the progenitor activity of FT cells from Id2−/− mice that exhibit defective NK cell development. In the Id2−/− FT, NK cells were greatly reduced, and a cell population that exclusively contains p-NK in the wild-type thymus was completely missing. Id2−/− FT progenitors were unable to differentiate into NK cells in IL-2-supplemented-FT organ culture. Single progenitor analysis demonstrated that all Id2−/− fetal thymic progenitors are destined for the T cell lineage, whereas progenitors for T/NK, T, and NK cell lineages were found in the control. Interestingly, the total progenitor number was similar between Id2−/− and Id2+/+ embryos analyzed. Expression of Id2 was correlated with p-NK activity. Our results suggest that Id2 is indispensable in thymic NK cell development, where it most probably restricts bipotent T/NK progenitors to the NK cell lineage.

T Cell Progenitors Emerge Earlier Than B Cell Progenitors in the Murine Fetal Liver

The developmental potential of individual cells in the Lin-c-kit+CD45+IL-7R+ (IL-7R+) population from murine fetal liver was investigated using a clonal assay capable of determining the potential of a progenitor to give rise to myeloid, T, and B cells. Unipotent progenitors generating T cells (p-T) or B cells (p-B) but not other types of progenitors were found in the IL-7R+ population. A large proportion of progenitors at day 12 of gestation are p-T, whereas the frequency of p-T dramatically decreases with gestational age. In marked contrast, p-B are very rare by day 12, but they rapidly increase thereafter. These findings strongly suggest that the commitment of multipotent progenitors to T and B cell lineages occurs independently.

Expression of α4β7 integrin defines a distinct pathway of lymphoid progenitors committed to T cells, fetal intestinal lymphotoxin producer, NK, and dendritic cells

During embryogenesis, the Peyer’s patch anlagen are induced by a cell population that produces lymphotoxin (LT) α1β2 following stimulation of IL-7Rα. In this study, we show that the LT-producing cell is localized within the IL-7Rα+ and integrin α4β7 (α4β7)+ population in the embryonic intestine. Lineage commitment to the LT producer phenotype in the fetal liver coincides with expression of α4β7. Before expression of α4β7, the potential of IL-7Rα+ population to generate B cells is lost. However, the progenitors for T cells and LT producer cells reside in the IL-7Rα+α4β7+ cells, but during subsequent differentiation, the potential to give rise to T cells is lost. This IL-7Rα+α4β7+ population migrates to the intestine, where it induces the Peyer’s patch anlagen. When stimulated with IL-15 or IL-3 and TNF, the intestinal IL-7Rα+α4β7+ population can differentiate into fully competent NK1.1+ NK cells or CD11c+ APCs. Expression of α4β7 is lost during differentiation of both lineages; IL-7Rα expression is lost during NK1.1+ cells differentiation. A newly discovered lineage−IL-7Rα+c-Kit+α4β7+ population in the fetal liver is committed to T, NK, dendritic, and fetal intestinal LT producer lineage, the latter being an intermediate stage during differentiation of NK and dendritic cells.

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-1high 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.