Kazuhiro Sudo

A role for pref-1 and HES-1 in thymocyte development.

T lymphocyte development requires a series of interactions between developing thymocytes and thymic epithelial (TE) cells. In this paper we show that TE cells in the developing thymus express Pref-1, a Delta-like cell-surface molecule. In fetal thymus organ cultures (FTOC), thymocyte cellularity was increased by the exogenous dimeric Pref-1 fusion protein, but was reduced by the soluble Pref-1 monomer or anti-Pref-1 Ab. Dimeric Pref-1 in FTOC also increased thymocyte expression of the HES-1 transcription factor. Thymocyte cellularity was increased in FTOC repopulated with immature thymocytes overexpressing HES-1, whereas FTOC from HES-1-deficient mice were hypocellular and unresponsive to the Pref-1 dimer. We detected no effects of either Pref-1 or HES-1 on developmental choice among thymocyte lineages. These results indicate that Pref-1 expressed by TE cells and HES-1 expressed by thymocytes are critically involved in supporting thymocyte cellularity.

Asymmetric Division and Lineage Commitment at the Level of Hematopoietic Stem Cells Inference from Differentiation in Daughter Cell and Granddaughter Cell Pairs

How hematopoietic stem cells (HSCs) commit to a particular lineage is unclear. A high degree of HSC purification enabled us to address this issue at the clonal level. Single-cell transplantation studies revealed that 40% of the CD34−/low, c-Kit+, Sca-1+, and lineage marker− (CD34−KSL) cells in adult mouse bone marrow were able, as individual cells, to reconstitute myeloid and B- and T-lymphoid lineages over the long-term. Single-cell culture showed that >40% of CD34−KSL cells could form neutrophil (n)/macrophage (m)/erythroblast (E)/megakaryocyte (M) (nmEM) colonies. Assuming that a substantial portion of long-term repopulating cells can be detected as nmEM cells within this population, we compared differentiation potentials between individual pairs of daughter and granddaughter cells derived in vitro from single nmEM cells. One of the two daughter or granddaughter cells remained an nmEM cell. The other showed a variety of combinations of differentiation potential. In particular, an nmEM cell directly gave rise, after one cell division, to progenitor cells committed to nm, EM, or M lineages. The probability of asymmetric division of nmEM cells depended on the cytokines used. These data strongly suggest that lineage commitment takes place asymmetrically at the level of HSCs under the influence of external factors.

Mesenchymal Progenitors Able to Differentiate into Osteogenic, Chondrogenic, and/or Adipogenic Cells In Vitro Are Present in Most Primary Fibroblast-Like Cell Populations

MSCs and mesenchymal progenitor cells (MPCs) are studied for their potential in regenerative medicine. MSCs in particular have great potential, because various reports have shown that they can differentiate into many different cell types. However, the difference between mesenchymal stem/progenitor cells and so‐called fibroblasts is unclear. In this study, we found that most of the distinct populations of primary fibroblast‐like cells derived from various human tissues, including lung, skin, umbilical cord, and amniotic membrane, contained cells that were able to differentiate into at least one mesenchymal lineage, including osteoblasts, chondrocytes, and adipocytes. We therefore propose that primary fibroblast‐like cell populations obtained from various human tissues do not comprise solely fibroblasts, but rather that they also include at least MPCs and possibly MSCs, to some extent.

Efficient enucleation of erythroblasts differentiated in vitro from hematopoietic stem and progenitor cells

Erythroblast enucleation is thought to be largely dependent on signals mediated by other cells, such as macrophages. In an attempt to improve the in vitro production of red blood cells (RBCs) from immature hematopoietic progenitor cells, we have developed a method to produce enucleated RBCs efficiently in the absence of feeder cells. Our method may represent an efficient way to produce transfusable RBCs on a large scale from hematopoietic progenitors.

Establishment of immortalized human erythroid progenitor cell lines able to produce enucleated red blood cells.

Transfusion of red blood cells (RBCs) is a standard and indispensable therapy in current clinical practice. In vitro production of RBCs offers a potential means to overcome a shortage of transfusable RBCs in some clinical situations and also to provide a source of cells free from possible infection or contamination by microorganisms. Thus, in vitro production of RBCs may become a standard procedure in the future. We previously reported the successful establishment of immortalized mouse erythroid progenitor cell lines that were able to produce mature RBCs very efficiently. Here, we have developed a reliable protocol for establishing immortalized human erythroid progenitor cell lines that are able to produce enucleated RBCs. These immortalized cell lines produce functional hemoglobin and express erythroid-specific markers, and these markers are upregulated following induction of differentiation in vitro. Most importantly, these immortalized cell lines all produce enucleated RBCs after induction of differentiation in vitro, although the efficiency of producing enucleated RBCs remains to be improved further. To the best of our knowledge, this is the first demonstration of the feasibility of using immortalized human erythroid progenitor cell lines as an ex vivo source for production of enucleated RBCs.

Establishment of Mouse Embryonic Stem Cell-Derived Erythroid Progenitor Cell Lines Able to Produce Functional Red Blood Cells

Background The supply of transfusable red blood cells (RBCs) is not sufficient in many countries. If erythroid cell lines able to produce transfusable RBCs in vitro were established, they would be valuable resources. However, such cell lines have not been established. To evaluate the feasibility of establishing useful erythroid cell lines, we attempted to establish such cell lines from mouse embryonic stem (ES) cells. Methodology/Principal Findings We developed a robust method to obtain differentiated cell lines following the induction of hematopoietic differentiation of mouse ES cells and established five independent hematopoietic cell lines using the method. Three of these lines exhibited characteristics of erythroid cells. Although their precise characteristics varied, each of these lines could differentiate in vitro into more mature erythroid cells, including enucleated RBCs. Following transplantation of these erythroid cells into mice suffering from acute anemia, the cells proliferated transiently, subsequently differentiated into functional RBCs, and significantly ameliorated the acute anemia. In addition, we did not observe formation of any tumors following transplantation of these cells. Conclusion/Significance To the best of our knowledge, this is the first report to show the feasibility of establishing erythroid cell lines able to produce mature RBCs. Considering the number of human ES cell lines that have been established so far, the intensive testing of a number of these lines for erythroid potential may allow the establishment of human erythroid cell lines similar to the mouse erythroid cell lines described here. In addition, our results strongly suggest the possibility of establishing useful cell lines committed to specific lineages other than hematopoietic progenitors from human ES cells.

Lipocalin 2-mediated growth suppression is evident in human erythroid and monocyte/macrophage lineage cells

Lipocalin 2 (LCN2), a secreted protein of the lipocalin family, induces apoptosis in some types of cells and inhibits bacterial growth by sequestration of the iron‐laden bacterial siderophore. We have recently reported that LCN2 inhibits the production of red blood cells in the mouse. Here we analyzed the role of LCN2 in human hematopoiesis. Expression of LCN2 was observed not only in mature cells such as those of the granulocyte/macrophage and erythroid lineages but also in hematopoietic stem/progenitor cells. We also examined expression of two candidate receptors for LCN2, brain type organic cation transporter (BOCT) and megalin, in various cell types. BOCT showed relatively high levels of expression in erythroid and hematopoietic stem/progenitor cells but lower levels in granulocyte/macrophage and T lymphoid cells. Megalin was expressed at high levels in T lymphoid and erythroid cells but at lower levels in granulocyte/macrophage lineage cells. LCN2 suppressed the growth of erythroid and monocyte/macrophage lineages in vitro, but did not have this effect on cells of other lineages. In addition, immature hematopoietic stem/progenitor cells were not sensitive to LCN2. These results demonstrate a lineage‐specific role for LCN2 in human hematopoiesis that is reminiscent of its effects upon mouse hematopoiesis and strongly suggest an important in vivo function of LCN2 in the regulation of human hematopoiesis. J. Cell. Physiol. 215: 526–537, 2008.

Lipocalin 2 functions as a negative regulator of red blood cell production in an autocrine fashion

Members of the lipocalin protein family are typically small, secreted proteins that possess a variety of functions. Although the physiological role of lipocalin 2 remains to be fully elucidated, a few pivotal functions have recently been reported, e.g., regulation of the apoptosis of leukocytes. Unexpectedly, lipocalin 2 is abundantly expressed in erythroid progenitor cells. An in vitro culture experiment demonstrated that lipocalin 2 induces apoptosis and inhibits differentiation of erythroid progenitor cells. During acute anemia the expression of lipocalin 2 was reduced in erythroid cells by a feedback system. Furthermore, injection of recombinant lipocalin 2 into mice suffering from acute anemia retarded the recovery of red blood cell (RBC) numbers, suggesting the importance of reduced expression of lipocalin 2 for the efficient recovery of RBC numbers. These results indicate that lipocalin 2 suppresses RBC production in an autocrine fashion. Hence, anemia arising from pathological conditions, such as chronic inflammation, might be partly due to increased levels of lipocalin 2 secreted from expanded leukocytes and/or macrophages. Also, anemia arising from malignancies might be partly due to the abundant secretion of lipocalin 2 from tumor cells. Thus, lipocalin 2 may represent an attractive therapeutic target for anemia under certain pathological conditions.

Lentiviral vector-mediated transduction of murine CD34- hematopoietic stem cells

OBJECTIVE Efficient gene transfer into murine hematopoietic stem cells (HSCs) provides a powerful tool for exploring hematopoietic stem cell biology. In this study, we evaluated the efficiency of lentiviral vector-mediated gene transfer into murine CD34(-/low)c-Kit(+)Sca-1(+)Lin(-) (CD34(-) KSL) cells that are highly enriched for HSCs. MATERIALS AND METHODS FACS-sorted CD34(-) KSL cells were transduced with the vesicular stomatitis virus G glycoprotein-pseudotyped HIV-1-based lentiviral vector containing the green fluorescent protein (GFP) gene under the control of the cytomegalovirus promoter, and then 50 transduced cells were transplanted into lethally irradiated mice. Transduction efficiency was assessed by FACS analysis for GFP expression in peripheral blood (PB) cells. FACS-sorted GFP(+) KSL bone marrow (BM) cells from primary recipients were used for secondary transplantation, and GFP expression in PB cells of reconstituted mice was analyzed by FACS. RESULTS GFP expression was detected in PB cells of all primary recipients (n = 10) at an average of 40% (range 26-58%) when the lentiviral vector containing the woodchuck hepatitis virus posttranscriptional regulatory element was used. GFP(+) cells were found in multilineage cells in PB, BM, spleen, and thymus for at least 8 months posttransplantation. In secondary recipients, donor-derived GFP(+) KSL BM cells could reconstitute and GFP expression was detected in both myeloid and lymphoid cells in PB. CONCLUSION Our results indicate that lentiviral vectors can efficiently transduce highly enriched murine HSCs and sustain long-term expression of the transgene in the multilineage differentiated progeny in reconstituted mice.

Quantitative assessment of the stem cell self-renewal capacity.

Abstract: Little is known about the manner in which hematopoietic stem cells (HSCs) self‐renew. To address this issue, we used a serum‐free single‐cell culture, followed by transplantation of cultured cells into lethally irradiated mice. CD34‐negative or low, c‐Kit‐positive, Sca‐1‐positive, lineage marker‐negative (CD34−KSL) cells are highly enriched for murine bone marrow HSCs. Successful long‐term reconstitution with a single CD34−KSL cell enabled us to study in vitro self‐renewal of HSC at clonal level. Using this clonal cell transplantation system, we examined the effect of various cytokines on CD34−KSL cells. Among the cytokines examined, stem cell factor (SCF) and thrombopoietin (TPO) were minimum cytokines to induce cell division of CD34−KSL cells most efficiently. Similarly, multilineage repopulating activity was detected in the cells derived from a significant portion of single cells after culture in the presence of TPO and SCF. However, SCF + IL‐3, SCF + IL‐6, or SCF + IL‐11 + FL appeared to be less effective for self‐renewal of HSCs. The activity of HSCs as indicated by repopulation unit (RU) remaining after culture with SCF and TPO was not so different from that of freshly isolated HSCs. However, there was a substantial loss of HSC number in these cultured cells. Taken together, this study provides definitive proof that one HSC can generate at least one HSC in vitro.