HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Reprints/Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Okuyama, H. Articles by Hayashi, S.-I. Search for Related Content PubMed PubMed Citation Articles by Okuyama, H. Articles by Hayashi, S.-I.

Discrete Types of Osteoclast Precursors Can Be Generated from Embryonic Stem Cells

^a Division of Immunology, Department of Molecular and Cellular Biology, School of Life Science, Faculty of Medicine, Tottori University, Yonago, Tottori, Japan;
^b Division of Regenerative Medicine and Therapeutics, Department of Genetic Medicine and Regenerative Therapeutics, Institute of Regenerative Medicine and Biofunction, Tottori University Graduate School of Medical Science, Yonago, Tottori, Japan;
^c The Center for Cell and Gene Therapy, Takara Bio Inc., Otsu, Shiga, Japan;
^d Department of Pathology, Stanford University School of Medicine, Beckman Center, Stanford, California, USA

Key Words. Clonal assays • Development • Embryonic stem cell • Experimental models • Hematopoiesis • In vitro culture • Mice • Progenitor • Osteoclast

Shin-Ichi Hayashi, M.D., Ph.D., Division of Immunology, Department of Molecular and Cellular Biology, School of Life Science, Faculty of Medicine, Tottori University, 86 Nishi-Machi, Yonago, Tottori, 683-8503, Japan. Telephone: 81-859-34-8269; Fax: 81-859-34-8272; e-mail: shayashi{at}grape.med.tottori-u.ac.jp

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

 
Osteoclast precursors (OCPs) share some characteristics with the monocyte/macrophage lineages, but the early events of OCP development are not yet clear. To investigate osteoclastogenesis from the earliest stage, we used step-wise cultures of embryonic stem (ES) cells to induce mature osteoclasts and assessed the effect of vascular endothelial growth factor receptor (VEGFR)-1/Fc chimeric protein on osteoclast development. Addition of VEGFR-1/Fc for the first 5 days of culture (phase I) severely inhibited the development of OCPs. Although OCPs were detected after culturing for a further 5 days (phase II), the reduction of OCPs in phase I was maintained in phase II. The generation of OCPs in phase I was resistant to signal blocking mediated by Kit receptors, but that in phase II was partially inhibited by either an anti-Kit antagonistic antibody or VEGFR-1/Fc and was severely inhibited by the combination of both reagents. Moreover, the OCPs in phase I gave rise to larger numbers of osteoclasts but required a longer period for maturation than the OCPs in phase II. We thus showed that OCPs expanded in phase II, but the majority of OCPs arose from ES cells in a manner dependent on VEGFR-1 binding factor(s) in phase I.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

 
Osteoclasts are hematopoietic cells that perform bone resorption and remodeling [1, 2]. Osteoclast precursors (OCPs) share some characteristics with the monocyte and macrophage lineages [1]. The potential to differentiate into mature osteoclasts in culture is maintained by a variety of cells [3, 4], including hematopoietic stem cells and colony-forming precursors (CFUs), elicited by hematopoietic colony-stimulating factors, and their progeny in the colonies [5]. Moreover, well-differentiated cells, such as monocytes and even mature macrophages, are capable of differentiating into osteoclasts [6]. OCPs are observed in yolk sacs and the aorta-gonad-mesonephros region of early embryos, and in liver, spleen, bone marrow (BM), alveoli, and the peritoneal cavity throughout life [7–9]. Although macrophage (M)-CSF and the receptor activator of nuclear factor-B ligand (RANKL) have been reported to be critical for osteoclastogenesis [10–12], the mechanisms of osteoclast development in the early phase have not been clearly elucidated.

To investigate osteoclast development from the earliest stage, we have developed an in vitro culture system that supports the differentiation of embryonic stem (ES) cells to mature osteoclasts. In this system, undifferentiated ES cells are cocultured with a stromal cell line (ST2) in the presence of 1,25-dihydroxyvitamin D₃ (1,25-(OH)₂D₃) and dexamethasone (Dex) for 10 days without any passage or manipulation (hereafter called the "one-step culture") [13, 14]. This is an appropriate system for examining the potential of ES cells to generate osteoclasts, as these cultures are stable and enable us to assess the whole process of osteoclastogenesis. We also employed a step-wise culture system, which experimentally divides the formation of osteoclasts from ES cells into three phases. In the first phase (phase I), ES cells are cultured on another stromal cell line (OP9) for 5 days. ES cells generate colonies containing hematopoietic progenitors [15], including OCPs, which was demonstrated by the transfer of these cells onto ST2 cells and further cultivation for 6 days in the presence of 1,25-(OH)₂D₃ and Dex (two-step culture) [13, 14]. This system allows the separation of the maturation phase on ST2 cells from the phase for the generation of OCPs on OP9 cells. When the cells are transferred on day 5 onto fresh OP9 cells and cultured for an additional 5 days, hematopoietic cells increase. From the cells from wild-type ES cells recovered on day 10, osteoclasts can be generated more efficiently on ST2 cells after 6 days of culture in the presence of 1,25-(OH)₂D₃ and Dex (three-step culture) than in the two-step culture [13, 14]. In addition to the generation phase (phase I) and the maturation phase of OCPs, we can also observe an amplification and/or another generation phase (phase II) of OCPs between these two phases using the three-step culture system. This culture system enables us to observe OCPs at the time of transfer onto ST2 stromal cells [13, 14].

Using mutant ES cells in this culture system, molecules required for early osteoclast development were assessed [14]. Moreover, distinct dependency on signaling via Kit receptor tyrosine kinase and on the GATA-2 transcription factor accounted for the difference between OCPs and CFUs-M [14]. The majority of osteoclasts are generated in a Kit-independent manner [5, 9, 13]. OCP but not CFU-M generation from GATA2-null ES cells is severely reduced [14]. These results suggest that a part of the osteoclast lineage might diverge from other myeloid lineages at a relatively early stage of hematopoiesis.

Hematopoietic cells share common progenitor cells, named hemangioblasts, with endothelial cells. In Vegfa-null embryos, both vasculogenesis and hematopoiesis may be impaired, resulting in death at midgestation [16, 17]. This is why the effect of the mutation on the osteoclast lineage has not been explored. In this study, we attempted to examine osteoclast development from the earliest stage by adding an Flt-1 (vascular endothelial growth factor receptor [VEGFR]-1-human [h] IgG1-Fc portion chimeric protein [VEGFR-1/Fc]) to our one-step and step-wise ES cell cultures. The addition of VEGFR-1/Fc, which binds to VEGFs and neutralizes their function, should mimic the effect of knocking out the Vegfa gene.

We report here the characteristics of OCPs developed in the first 5 days of culture (phase I) and OCPs after culturing for a further 5 days (phase II) as indicated by the effects of VEGFR-1/Fc and antagonistic anti-Kit antibody (Ab) on the number of osteoclasts derived from single OCPs and the period of differentiation into mature osteoclasts. The majority of OCPs appeared to be derived from ES cells via a mechanism dependent on the binding of factor(s) to VEGFR-1 in phase I.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Cells
D3 [18] and CCE (kindly provided by Dr. Stuart H. Orkin, Harvard University) ES cell lines were maintained on mitomycin C- (Kyowa Hakko Kogyo Co. Ltd.; Shizuoka, Japan; http://www.kyowa.co.jp/eng/index.htm) treated mouse embryonic fibroblasts in Dulbecco’s modified essential medium (GIBCO/BRL; Grand Island, NY; http://www.invitrogen.com) supplemented with 15% fetal bovine serum (FBS; JRH Biosciences; Lenexa, KS; http://www.jrhbio.com), 1x nonessential amino acids (GIBCO/BRL), 2 mM L-glutamine (GIBCO/BRL), 1 x 10^-4 M 2-mercaptoethanol (2-ME; Wako Pure Chemical Industries, Ltd.; Osaka, Japan; http://www.wako-chem.co.jp), a culture supernatant from Chinese hamster ovary cells producing leukemia inhibitory factor (LIF; a gift from Genetics Institute Inc; Cambridge, MA; http://www.genetics.com), 50 U/ml streptomycin, and 0.05 mg/ml penicillin (Meiji Chem. Co. Ltd.; Tokyo, Japan). The BM-derived stromal cell line ST2 was maintained in RPMI-1640 (GIBCO/BRL) containing 5% FBS (Trace Scientific Ltd.; Melbourne, Australia), 5 x 10^-5 M 2-ME, 50 U/ml streptomycin, and 0.05 mg/ml penicillin [19]. A newborn carvalia-derived stromal cell line (OP9) [20] was maintained in alpha-minimum essential medium (-MEM; GIBCO/BRL) containing 20% FBS, streptomycin, and penicillin [13, 21, 22].

Induction of Differentiation of ES Cells
Induction of the differentiation of ES cells was described previously [13, 21, 22]. For one-step cultures, undifferentiated ES cells (75 cells/well) were added onto confluent ST2 monolayers in 24-well culture plates (Corning Inc.; Acton, MA; http://www.corning.com) and cultured in -MEM supplemented with 10% FBS, streptomycin, penicillin, 10^-7 M Dex (Sigma Chemical Co. Ltd.; St. Louis, MO; http://www.sigmaaldrich.com), and 10^-8 M 1,25-(OH)₂D₃ (Biomol Research Laboratories, Inc.; Plymouth Meeting, PA; http://www.biomol.com). Cultures were fed every 3 days by replacing spent medium with fresh medium. In one-step cultures, formation of osteoclasts was detected by tartrate-resistant acid phosphatase (TRAP) staining on day 10.

For multistep cultures, undifferentiated ES cells (10⁴ cells) were inoculated in 6-well culture plates (Corning), seeded with OP9 stromal cells, and cultured in -MEM supplemented with 20% FBS (Intergen Company; Burlington, MA; http://www.intergen.com), streptomycin, and penicillin. On day 5, a cell suspension in phase I was prepared by treatment with 0.25% trypsin/0.5 mM EDTA (GIBCO/BRL). Harvested cells (10³) were induced to differentiate into osteoclasts on ST2 cells for 6 days in the same medium as used for the one-step culture (two-step culture). For the three-step culture, the harvested cells (10⁵) were further cultured for 5 days on a fresh OP9 stromal layer under the same conditions used for phase I. Hematopoietic cells generated on the OP9 cells were harvested by pipetting culture medium over the cell layers on day 10. The cells recovered were induced to differentiate into osteoclasts, as described previously, and TRAP staining was performed 6 days later. All cultures were incubated at 37°C with 5% CO₂ in a humidified incubator [13, 14, 21].

In these experiments, 100 ng/ml of a recombinant mouse VEGFR-1 (Flt-1)/Fc chimera (R&D Systems, Inc.; Abington, UK; http://www.rndsystems.com), 100 ng/ml of human IgG1 (Chemicon International, Inc.; Temecula, CA; http://www.chemicon.com), or 0.01 mg/ml of a rat anti-mouse monoclonal antagonistic Ab against Kit (ACK2) [23] was added to the cultures.

OCP Frequency Analysis
The frequency of OCPs was determined by limiting dilution assay [9]. Various numbers of cells harvested on day 5 or day 10 from phase I or II, respectively, were inoculated into wells of 96-well plates (Corning), preseeded with ST2 cells, and cultured for 6 days in the presence of 1,25-(OH)₂D₃ and Dex. The presence of osteoclasts was determined by TRAP staining. After calculating the frequency of OCPs, the numbers of TRAP-positive cells in the wells containing TRAP-positive cells were counted.

TRAP Staining
Cultured cells were fixed with 10% formalin (3.7% formaldehyde; Wako) in phosphate-buffered saline for 10 minutes with ethanol-acetone (50:50; v/v; Wako) for 1 minute at room temperature and incubated in acetate buffer (pH 5.0; Sigma) containing naphthol AS-MX phosphate (Sigma) as a substrate and fast red violet LB salt (Sigma) as a stain in the presence of 50 mM sodium tartrate (Wako) [24].

Antibodies
Monoclonal rat anti-mouse Abs directed against Kit (ACK2) [23] and CD31 (Pharmingen; San Diego, CA; http://www.bdbiosciences.com/pharmingen) were used for staining.

Reverse Transcription-Polymerase Chain Reaction
Hot-lid polymerase chain reaction (PCR) amplification of cDNA equivalent to 20 ng of total RNA was carried out in 1 x PCR buffer (1.5 mM MgCl₂) containing 0.2 mM deoxynucleoside triphosphate (Takara; Shiga, Japan; http://www.takara-bio.co.jp/english), 0.75 U of rTaq DNA polymerase (Toyobo; Osaka, Japan; http://www.toyobo.co.jp/e), and 500 nM primers. Amplifications were carried out on a DNA thermal cycler (PTC DNA Engine; MJ Research Inc.; Watertown, MA; http://www.mjr.com). Following an initial 1-minute denaturation step (94°C), each PCR cycle consisted of 30 seconds of denaturation (94°C), 1 minute of annealing (55°C), and 1 minute of elongation (72°C). After the final cycle, the reaction was held for 3 minutes at 72°C. The PCR products were then separated on 1.5% agarose gel, stained with ethidium bromide, and photographed. The primers used were as follows: ß-globin (Hbb): 5'-CAC AAC CCC AGA AAC AGA CA-3' and 5'-CTG ACA GAT GCT CTC TTG GG-3'; -globin (Hbb-bh1): 5'-GCT CAG GCC GAG CCC ATT GG-3' and 5'-TAG CGG TAC TTC TCA GTC AG-3'; and hypoxanthine phosphoribosyl transferase (Hprt): 5'-AAT GAT CAG TCA ACG GGG GAC A-3' and 5'-CCA GCA AGC TTG CAA CCT TAA CCA-3'.

Statistical Analysis
The numbers of OCPs derived from single ES cells on day 5 (phase I) and on day 10 (phase II) were calculated as follows: phase I = [(the frequency of OCPs on day 5) x (the number of recovered cells per well on day 5)] / 10⁴ and phase II = [(the frequency of OCPs on day 10) x (the number of recovered cells per well on day 10)] / 10⁵ x [(the number of recovered cells per well on day 5) / 10⁴]. Data are presented as mean ± standard deviation (SD). Statistical significance was assessed by the Student’s t-test.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

 
VEGFR-1/Fc Inhibits Osteoclast Development in ES Cell Colonies
The development of endothelial cells and hematopoietic cells is known to depend on signaling via VEGFRs. Since VEGFR-1 binds VEGF (VEGF-A), VEGF-B, and PlGF [25], the addition of soluble VEGFR-1/Fc chimeric protein neutralizes the function of these factors in culture. We used the ES cell culture system to induce both osteoclast and endothelial cell lineages in a colony (one-step culture) [13, 26, 27]. D3 ES cells were cultured at a low cell density on an ST2 stromal cell layer for 10 days in the presence of 1,25-(OH)₂D₃ and Dex. Usually, TRAP-positive osteoclasts were located at the periphery of the colonies (Fig. 1A), while endothelial cells were arrayed radially (Fig. 1B) [26, 27]. Under these conditions, we continuously supplemented the culture medium with 100 ng/ml VEGFR-1/Fc and found that, on day 10, the generation of endothelial cells expressing CD31 and of TRAP-positive osteoclasts were markedly reduced. The majority of ES cell colonies lacked both CD31-positive cells and TRAP-positive cells (Fig. 1C), but some of the colonies contained small numbers of CD31-positive cells and/or TRAP-positive cells (Fig. 1D and 1E). We used the same dose of hIgG1 as an Fc control and ascertained that it did not influence the generation of CD31-positive endothelial cells or TRAP-positive osteoclasts.

View larger version (48K): [in this window] [in a new window]   Figure 1. VEGFR-1/Fc inhibits osteoclastogenesis in the early phase of ES cell culture. ES cell colonies in one-step cultures grown with 1,25-(OH)2D3 and Dex on ST2 stromal cell layers for 10 days without (A, B) or with (C-E) VEGFR-1/Fc. Cells positive for TRAP activity (A) or CD31 molecules (B) were stained. Cultures grown with VEGFR-1/Fc were double stained for TRAP and reactivity with anti-CD31 Ab (C-E). The majority of colonies treated with VEGFR-1/Fc lacked cells positive for these markers (C), but some of the colonies contained one or both cell lineages (D, E). Arrows and arrowheads indicate the TRAP-positive and CD31-positive cells, respectively. F) In one-step cultures of early (0–5 days) and/or late (5–10 days) phases, ES cells were cultured with or without exogenous hIgG1 or VEGFR-1/Fc for 10 days, and the number of TRAP-positive MNCs was counted. Bars indicate mean ± SD of triplicate cultures. *Significant difference compared with medium alone (p < 0.05).

VEGFR-1/Fc Inhibits OCP Generation in the Early Phase of ES Cell Culture
To assess the stage of osteoclast development affected by the addition of VEGFR-1/Fc, we performed the two-step culture with VEGFR-1/Fc (Table 1). ES cells (10⁴/well) were cultured on OP9 stromal cell layers with or without VEGFR-1/Fc, anti-Kit Ab, or hIgG1 for 5 days (phase I), and growing cells were harvested. These cultures were repeated four times independently using two different ES cell lines (D3 and CCE) (upper section of Table 1). On day 5, the numbers of cells recovered from cultures with and without VEGFR-1/Fc, anti-Kit Ab, or hIgG were comparable (Table 1). Flow cytometric analysis demonstrated that CD45-positive hematopoietic cells comprised less than 0.3% of the recovered cells with or without VEGFR-1/Fc (data not shown). The harvested cells (10³/well) were transferred onto ST2 cell layers in the presence of 1,25-(OH)₂D₃ and Dex for 6 days. In three of five trials in which VEGFR-1/Fc was added during phase I of the cultures, the generation of TRAP-positive MNCs was totally abolished (Experiments #1, #3 with CCE cells, and #4 of the middle section of Table 1), and only a few TRAP-positive MNCs were detected in the other two experiments (Experiments #2 and #3 with D3 cells in Table 1).

OCPs in Phase II Are Inhibited by VEGFR-1Fc and/or Anti-Kit Abs
After ES cells are cultured on OP9 for 5 days, if the harvested cells are recultured on a fresh OP9 cell layer for an additional 5 days (phase II), hematopoietic progenitors expand efficiently [15]. To determine the effect of VEGFR-1/Fc on OCP generation in this phase, we performed three-step cultures under various conditions (Table 2 and Fig. 2). We reported previously that the increase in the OCP number in phase II was 10- to 20-fold [14].

View larger version (27K): [in this window] [in a new window]   Figure 2. OCPs in phase II were inhibited by VEGFR-1/Fc and/or anti-Kit Ab. ES cells were cultured under the conditions of the three-step cultures. Medium alone or the exogenous anti-Kit Ab ACK2 and/or VEGFR-1/Fc was added in phase I of these cultures, and the cells harvested on day 5 were further cultured on new OP9 cell layers in the presence or absence of anti-Kit Ab and/or VEGFR-1/Fc for 5 days (phase II). The cells obtained in phase II were further cultured on ST2 cells for 6 days under osteoclast culture conditions. On day 16, the numbers of TRAP-positive MNCs were counted. Data are expressed as the mean ± SD of triplicate cultures. The upper panel is an outline of the culture system used in this study. *Significant difference compared with medium alone in both phases I and II. **Significant difference compared with VEGFR-1/Fc in phase I only (p < 0.05).

We also assessed the frequency of OCP-I and OCP-II using the limiting dilution assay. D3 ES cells cultured in medium alone in both phases I and II contained OCP-II at a frequency of one OCP-II in 5.7 or 4.8 cells, and single ES cells gave rise to 107 or 13 OCP-II (Experiments #2 or #3, respectively, in Table 2). In the cultures treated with VEGFR-1/Fc in phase I, the frequency of OCP-II was significantly greater than that of OCP-I; however, since the number of cells recovered on day 10 was lower in this experiment (#2), the number of OCPs obtained from a single ES cell was still low (Table 2). In Experiment #3 using CCE ES cells, the number of cells recovered in phase II after culturing with VEGFR-1/Fc in phase I was approximately half the number of cells recovered after culturing with medium alone, but the frequency of OCP-II and the number of OCP-II obtained from a single ES cell in the cultures with VEGFR-1/Fc in phase I were still significantly lower than those with medium alone (Table 2). Therefore, the reduction of OCP-II generation was related to the treatment with VEGFR-1/Fc in phase I, even if the number of cells recovered was different in phase II.

Moreover, the presence of both VEGFR-1/Fc and anti-Kit Ab during phase II following the addition of VEGFR-1/Fc during phase I further decreased the frequency of OCP-II (Table 2). In contrast, the addition of anti-Kit Ab during phase II reduced the number of TRAP-positive MNCs from ES cells cultured with VEGFR-1/Fc in phase I, but the frequency of OCP-II was comparable with that obtained in medium only (Table 2). Continuous addition of either hIgG1 or anti-Kit Ab for 10 days throughout phases I and II did not decrease the number of TRAP-positive MNCs (Fig. 2). This result suggests that OCPs may require different signaling to develop in phases I and II.

Early Steps in Erythropoiesis also Require VEGF Family Cytokines
Signaling via VEGFRs is critical for the early development of hematopoietic cell lineages [16, 17]. Therefore, the addition of VEGFR-1/Fc to ES cell cultures may widely affect the development of hematopoietic cell lineages. To examine this effect, we assessed erythropoiesis in our culture system. Semiquantitative reverse transcription (RT)-PCR for - (Hbb-bh1) and ß-hemoglobin (Hbb) gene expression was carried out to detect the presence of erythropoiesis. ES cell cultures treated with VEGFR-1/Fc in phase I contained approximately 10 times less Hbb-bh1 transcript than those cultured with medium alone or with hIgG1 (Fig. 3A and 3B). We could not detect any message from the Hbb gene in the VEGFR-1/Fc-treated cultures (Fig. 3A). These results indicate that the addition of VEGFR-1/Fc during phase I inhibits the development of both - and ß-hemoglobin-producing erythrocytes.

View larger version (41K): [in this window] [in a new window]   Figure 3. Early steps in erythropoiesis require VEGF family cytokines. A) ES cells were cultured on OP9 cells for 5 days, and RT-PCR for the ß- (Hbb) or -hemoglobin (Hbb-bh1) genes of the recovered cells was performed. Hprt was used as a control transcript, and twice distilled water (D2W) as a negative control without template cDNA. B) One (equivalent to 50 ng of total RNA), 1/10, or 1/100 relative amounts of cDNAs were used as templates for PCR for Hbb-bh1 and Hprt.

The Number of TRAP-Positive Cells Derived from Single OCPs
To compare the characteristics of the OCPs generated in phases I and II, we investigated the number of TRAP-positive cells derived from single OCP-I and OCP-II (Table 4). After calculating the frequency of OCPs, the numbers of TRAP-positive cells in the wells containing TRAP-positive cells were assessed. Since no TRAP-positive cells were detected in the VEGFR-1/Fc-treated cultures in three of five trials when VEGFR-1/Fc was added in phase I of the two-step culture, we could not make comparisons using these experiments. In Experiment #2 (Table 1), a single VEGFR-1/Fc-treated OCP-I gave rise to approximately one sixth the number of TRAP-positive cells (23) derived from an OCP-I cultured in medium only (136) (Table 4).

These results indicate that a single OCP-I produces a higher number of osteoclasts than a single OCP-II, and that treatment with VEGFR-1/Fc in phase I does not affect the number of osteoclasts generated from a single OCP-II. Similar results were obtained by using CCE ES cells (Experiment #3 in Table 4), although OCP-I were not present.

The Timing of TRAP-Positive Cell Appearance in the Osteoclast Culture
The period of TRAP-positive cell appearance after the induction of ES cells into osteoclasts was examined. Cells transferred to osteoclast culture conditions on day 5 of culturing with or without VEGFR-1/Fc differentiated into TRAP-positive cells 4 or 3 days after the transfer, respectively. Cells from phase II on day 10 gave rise to TRAP-positive cells for 2 days, regardless of whether or not they had been treated with VEGFR-1/Fc in phase I (Fig. 4A). It is thus likely that OCP-II are more mature than OCP-I.

View larger version (18K): [in this window] [in a new window]   Figure 4. The numbers of TRAP-positive cells generated from single OCPs. A) For phase I, ES cells were cultured in the presence or absence of VEGFR-1/Fc. For phase II, a portion of the cells was harvested on day 5 and further cultured on new OP9 cell layers. Cells (103/well) harvested in phase I or II were cultured on ST2 cell layers under osteoclast culture conditions, and the appearance of TRAP-positive cells was assessed. Circles show the results of cells from phase I, and squares show those of cells from phase II with (closed) or without (open) VEGFR-1/Fc in phase I of the cultures. B) The appearance of TRAP-positive cells from adult BM cells (104/well; closed squares), E7.5 embryos proper (103/well; open circles), and E7.5 yolk sacs (103/well; closed circles) are shown. Data are mean ± SD of the number of TRAP-positive cells/well in triplicate cultures.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

 
To investigate the mechanisms of osteoclastogenesis from the earliest stage, we examined the effects of the addition of VEGFR-1/Fc chimeric protein on osteoclast development using step-wise ES cell cultures. The addition of VEGFR-1/Fc affected the development of not only endothelial cells but also OCPs, CFUs-M, and erythroid cells, indicating that our study conditions permitted observation of osteoclastogenesis from the early phase of embryogenesis.

Supplementation with VEGFR-1/Fc in phase I of ES cell step-wise cultures severely inhibited the generation of both OCP-I and OCP-II. In some of the repeated experiments, a small number of OCP-I were detected in the VEGFR-1/Fc-treated cultures, and the lower number of OCPs compared with the control (medium only) was maintained after the passage of these OCP-I through phase II without VEGFR-1/Fc. Maturation of OCP-I to TRAP-positive cells was delayed for 1–2 days compared with that of OCP-II. Moreover, we found that OCP-I produced higher numbers of osteoclasts than OCP-II (Table 4). These results support the notion that OCP-I may be more immature than OCP-II and suggest that OCP-II may be the progeny of OCP-I.

However, the signal requirements for OCP generation in phases I and II are different. The generation of OCP-I was not affected by the presence of the anti-Kit Ab. In contrast, that of OCP-II was partially inhibited by either the anti-Kit Ab or VEGFR-1/Fc, and severely inhibited in the presence of both reagents (Fig. 2). Although treatment with VEGFR-1/Fc in phase I completely abolished the generation of OCP-I in three of five trials, OCP-II were detected in all experiments. OCP-II might have been generated from very few OCP-I we could not detect; alternatively, OCP-II may newly form in phase II. If so, OCP-I and OCP-II may be derived from different origins.

The reduction of CFUs-M by VEGFR-1/Fc in phase I did not influence the number of CFUs-M that arose in phase II (Table 3). The number of CFUs-M in control cultures was consistent in both phase I and phase II, indicating that CFU-M might newly form in each phase. It is unlikely that treatment with VEGFR-1/Fc in phase I totally eliminates cells with the potential to differentiate into hematopoietic progenitors. Using the GATA2^-/- ES cell line, we previously demonstrated that the frequency of GATA2^-/- OCP-I was significantly reduced, while that of CFUs-M was only slightly diminished [14]. Lee et al. have reported that OCPs might be more immature than macrophage progenitors that respond to M-CSF but more mature than multilineage progenitors that respond to stem cell factor [8]. These findings further support the idea that the majority of OCPs are derived from cells other than CFUs-M.

Adult hematopoiesis depends on signaling via the Kit receptor because Kit-deficient Kit^W/Kit^W mice and anti-Kit Ab-treated mice harbor severe anemia [23, 29], whereas the development of osteoclasts from ES cells is totally Kit independent [13], and Kit^W/Kit^W mice also have normal numbers of osteoclasts [3]. Continuous addition of anti-Kit Ab for 10 days throughout phases I and II did not decrease the number of TRAP-positive MNCs (Fig. 2). The addition of anti-Kit Ab in phase II reduced the number of TRAP-positive MNCs from ES cells cultured with VEGFR-1/Fc in phase I (Fig. 2). However, the frequency of these OCP-II was comparable with that obtained in medium only (Table 2). This result suggests that Kit signaling may be associated with the growth of part of the OCP-II fraction resistant to treatment with VEGFR-1/Fc in phase I. Since they would constitute only a small fraction of the total OCPs, we may not have detected these OCPs previously [5, 9, 13].

Definitive hematopoiesis has been reported to depend on Kit signaling, but primitive hematopoiesis in the yolk sac and early fetal liver does not [23, 30]. These facts imply that the majority of osteoclasts may develop through a primitive hematopoietic pathway, which the erythroid and monocytic lineages follow only at the earliest stage in yolk sacs. The OCP-I in control cultures were present at frequencies of 1/300 (0.3%) to 1/34 (3%) in phase I (Table 1), although less than 0.3% of cells expressed CD45, which is a hematopoietic cell-specific marker. This may mean that the OCP-I are very immature cells that have not yet committed to the hematopoietic cell lineage.

Endothelial cells were normally induced from a bloodless ES cell colony. The addition of M-CSF and RANKL increased the numbers of TRAP-positive osteoclasts and changed their locations from the peripheries to the centers of colonies [26, 27]. However, endothelial cells were normally generated in this culture condition. Subsequently, the addition of ligands for VEGFR, VEGF₁₆₄ but not PlGF accelerated endothelial cell growth, and reciprocally, VEGF₁₆₄ but not PlGF reduced the generation and frequency of OCPs and CFUs-M in ES cell cultures (Okuyama, unpublished observation). These results may suggest that osteoclasts do not regulate vasculogenesis, but exogenous VEGF leads to the acceleration of endothelial cell growth, resulting in a decline in the differentiation toward hematopoietic cells, including the osteoclast lineage, in cultures. VEGF (VEGF-A) binds to not only VEGFR-1 but also to VEGFR-2 (Flk-1) and neuropilin-1 [31–39]. VEGF-A, PlGF, and VEGF-B bind to VEGFR-1 [40]. PlGF does not affect osteoclastogenesis or vasculogenesis in vivo [40]. The function of VEGF-B is not obvious [41]. In the future, we should identify the VEGFR-1/Fc-neutralized signaling that is critical for OCP development.

Finally, the OCP-I that remained in the cultures treated with VEGFR-1/Fc in phase I and the OCP-II resistant to VEGFR-1/Fc treatment in phases I and II gave rise to significantly fewer numbers of TRAP-positive cells (Experiment #2 in Table 4). The lack of signaling via VEGFR(s) may reduce the growth ability of the few OCPs that develop under these conditions. Alternatively, this result may suggest the presence of another OCP subpopulation that is independent of signaling via VEGFR(s). Further studies are needed to examine these possibilities.

In this study, we showed that the majority of OCPs may be derived from ES cells in a manner dependent on factor(s) binding to VEGFR-1 in phase I, which is a very early developmental stage.

	ACKNOWLEDGMENT

Top Abstract Introduction Materials and Methods Results Discussion References

 
We are grateful to Dr. Minetaro Ogawa (Kumamoto University) and Dr. Hitoshi Niwa (RIKEN Kobe) for critical suggestions, to Dr. Shin-Ichi Nishikawa (RIKEN Kobe) for monoclonal antibodies, and to Dr. Stuart H. Orkin (Harvard University) for the CCE ES cell line. We also thank Dr. Tomohiro Kurosaki (Kansai Medical School), Dr. Toru Nakano (Osaka University), and Dr. Mitsuo Oshimura (Tottori University) for their warm encouragement. This work was supported by grants from the Grant-in-Aid for Scientific Research from the Ministry of Education, Culture, Sports, Science and Technology; the Japanese Government; and the Molecular Medical Science Institute, Otsuka Pharmaceutical Co., Ltd.

	REFERENCES

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Suda T, Udagawa N, Takahashi N. Cells of bone: osteoclast generation. In: Bilezikian JP, Raisz LG, Roden GA, eds. Principles of Bone Biology. New York: Academic Press Inc., 1996:87–102.

2. Roodman GD. Cell biology of the osteoclast. Exp Hematol 1999;27:1229–1241.[CrossRef][Medline]

3. Hayashi SI, Yamane T, Miyamoto A et al. Commitment and differentiation of stem cells to the osteoclast lineage. Biochem Cell Biol 1998;76:911–922.[CrossRef][Medline]

4. Chambers TJ. Regulation of the differentiation and function of osteoclasts. J Pathol 2000;192:4–13.[CrossRef][Medline]

5. Yamazaki H, Kunisada T, Yamane T et al. Presence of osteoclast precursors in colonies cloned in the presence of hematopoietic colony-stimulating factors. Exp Hematol 2001;29:68–76.[CrossRef][Medline]

6. Akagawa KS, Takasuka N, Nozaki Y et al. Generation of CD1⁺RelB⁺ dendritic cells and tartrate-resistant acid phosphatase-positive osteoclast-like multinucleated giant cells from human monocytes. Blood 1996;88:4029–4039.[Abstract/Free Full Text]

7. Kurihara N, Suda T, Miura Y et al. Generation of osteoclasts from isolated hematopoietic progenitor cells. Blood 1989;74:1295–1302.[Abstract/Free Full Text]

8. Lee MY, Lottsfeldt JL, Fevold KL. Identification and characterization of osteoclast progenitors by clonal analysis of hematopoietic cells. Blood 1992;80:1710–1716.[Abstract/Free Full Text]

9. Hayashi SI, Miyamoto A, Yamane T et al. Osteoclast precursors in bone marrow and peritoneal cavity. J Cell Physiol 1997;170:241–247.[CrossRef][Medline]

10. Yoshida H, Hayashi SI, Kunisada T et al. The murine mutation osteopetrosis is in the coding region of the macrophage colony stimulating factor gene. Nature 1990;345:442–444.[CrossRef][Medline]

11. Yasuda H, Shima N, Nakagawa N et al. Osteoclast differentiation factor is a ligand for osteoprotegerin/osteoclastogenesis-inhibitory factor and identical to TRANCE/RANKL. Proc Natl Acad Sci USA 1998;95:3597–3602.[Abstract/Free Full Text]

12. Lacey DL, Timms E, Tan HL et al. Osteoprotegerin ligand is a cytokine that regulates osteoclast differentiation and activation. Cell 1998;93:165–176.[CrossRef][Medline]

13. Yamane T, Kunisada T, Yamazaki H et al. Development of osteoclasts from embryonic stem cells through a pathway that is c-fms but not c-kit dependent. Blood 1997;90:3516–3523.[Abstract/Free Full Text]

14. Yamane T, Kunisada T, Yamazaki H et al. Sequential requirements for SCL/tal-1, GATA-2, macrophage colony-stimulating factor, and osteoclast differentiation factor/osteoprotegerin ligand in osteoclast development. Exp Hematol 2000;28:833–840.[CrossRef][Medline]

15. Nakano T, Kodama H, Honjo T. Generation of lymphohematopoietic cells from embryonic stem cells in culture. Science 1994;265:1098–1101.[Abstract/Free Full Text]

16. Carmeliet P, Ferreira V, Breier G et al. Abnormal blood vessel development and lethality in embryos lacking a single VEGF allele. Nature 1996;380:435–439.[CrossRef][Medline]

17. Ferrara N, Carver-Moore K, Chen H et al. Heterozygous embryonic lethality induced by targeted inactivation of the VEGF gene. Nature 1996;380:439–442.[CrossRef][Medline]

18. Doetschman TC, Eistetter H, Katz M et al. The in vitro development of blastocyst-derived embryonic stem cell lines: formation of visceral yolk sac, blood islands and myocardium. J Embryol Exp Morphol 1985;87:27–45.[Medline]

19. Nishikawa SI, Ogawa M, Nishikawa S et al. B lymphopoiesis on stromal cell clone: stromal cell clones acting on different stages of B cell differentiation. Eur J Immunol 1988;18:1767–1771.[Medline]

20. Kodama H, Nose M, Niida S et al. Involvement of the c-kit receptor in the adhesion of hematopoietic stem cells to stromal cells. Exp Hematol 1994;22:979–984.[Medline]

21. Yamane T, Kunisada T, Hayashi SI. Embryonic stem cells as a model for studying osteoclast lineage development. Methods Mol Biol 2002;185:97–106.[Medline]

22. Tsuneto M, Yamane T, Okuyama H et al. In vitro differentiation of mouse ES cells into hematopoietic, endothelial, and osteoblastic cell lineages: a possibility of in vitro organogenesis. Methods Enzymol 2003;365:98–114.

23. Ogawa M, Matsuzaki Y, Nishikawa S et al. Expression and function of c-kit in hemopoietic progenitor cells. J Exp Med 1991;174:63–71.[Abstract/Free Full Text]

24. Shevde N, Anklesaria P, Greenberger JS et al. Stromal cell-mediated stimulation of osteoclastogenesis. Proc Soc Exp Biol Med 1994;205:306–315.[Abstract]

25. Neufeld G, Cohen T, Gengrinovitch S et al. Vascular endothelial growth factor (VEGF) and its receptors. FASEB J 1999;13:9–22.[Abstract/Free Full Text]

26. Hemmi H, Okuyama H, Yamane T et al. Temporal and spatial localization of osteoclasts in colonies from embryonic stem cells. Biochem Biophys Res Commun 2001;280:526–534.[CrossRef][Medline]

27. Okuyama H, Yamazaki H, Yamane T et al. Development of osteoclast lineage cells. Research Advances in Blood. (Global Research Network) 2001;1:75–84.

28. Galli SJ, Zsebo KM, Geissler EN. The kit ligand, stem cell factor. Adv Immunol 1994;55:1–96.[Medline]

29. Russell ES. Hereditary anemias of the mouse: a review for geneticists. Adv Genet 1979;20:357–458.[Medline]

30. Ogawa M, Nishikawa S, Yoshinaga K et al. Expression and function of c-Kit in fetal hemopoietic progenitor cells: transition from the early c-Kit-independent to the late c-Kit-dependent wave of hemopoiesis in the murine embryo. Development 1993;117:1089–1098.[Abstract]

31. de Vries C, Escobedo JA, Ueno H et al. The fms-like tyrosine kinase, a receptor for vascular endothelial growth factor. Science 1992;255:989–991.[Abstract/Free Full Text]

32. Terman BI, Dougher-Vermazen M, Carrion ME et al. Identification of the KDR tyrosine kinase as a receptor for vascular endothelial cell growth factor. Biochem Biophys Res Commun 1992;187:1579–1586.[CrossRef][Medline]

33. Soker S, Takashima S, Miao HQ et al. Neuropilin-1 is expressed by endothelial and tumor cells as an isoform-specific receptor for vascular endothelial growth factor. Cell 1998;92:735–745.[CrossRef][Medline]

34. Fong GH, Rossant J, Gertsenstein M et al. Role of the Flt-1 receptor tyrosine kinase in regulating the assembly of vascular endothelium. Nature 1995;376:66–70.[CrossRef][Medline]

35. Barleon B, Sozzani S, Zhou D et al. Migration of human monocytes in response to vascular endothelial growth factor (VEGF) is mediated via the VEGF receptor flt-1. Blood 1996;87:3336–3343.[Abstract/Free Full Text]

36. Sawano A, Iwai S, Sakurai Y et al. Flt-1, vascular endothelial growth factor receptor 1, is a novel cell surface marker for the lineage of monocyte-macrophages in humans. Blood 2001;97:785–791.[Abstract/Free Full Text]

37. Shalaby F, Rossant J, Yamaguchi TP et al. Failure of blood-island formation and vasculogenesis in Flk-1-deficient mice. Nature 1995;376:62–66.[CrossRef][Medline]

38. Carmeliet P, Ng YS, Nuyens D et al. Impaired myocardial angiogenesis and ischemic cardiomyopathy in mice lacking the vascular endothelial growth factor isoforms VEGF₁₆₄ and VEGF₁₈₈. Nat Med 1999;5:495–502.[CrossRef][Medline]

39. Yamada Y, Takakura N, Yasue H et al. Exogenous clustered neuropilin 1 enhances vasculogenesis and angiogenesis. Blood 2001;97:1671–1678.[Abstract/Free Full Text]

40. Carmeliet P, Collen D. Vascular development and disorders: molecular analysis and pathogenic insights. Kidney Int 1998;53:1519–1549.[CrossRef][Medline]

41. Aase K, Lymboussaki A, Kaipainen A et al. Localization of VEGF-B in the mouse embryo suggests a paracrine role of the growth factor in the developing vasculature. Dev Dyn 1999;215:12–25.[CrossRef][Medline]

This article has been cited by other articles:

				L. Duplomb, M. Dagouassat, P. Jourdon, and D. Heymann Concise Review: Embryonic Stem Cells: A New Tool to Study Osteoblast and Osteoclast Differentiation Stem Cells, March 1, 2007; 25(3): 544 - 552. [Abstract] [Full Text] [PDF]

				A. L. Olsen, D. L. Stachura, and M. J. Weiss Designer blood: creating hematopoietic lineages from embryonic stem cells Blood, February 15, 2006; 107(4): 1265 - 1275. [Abstract] [Full Text] [PDF]

				S.-I. Hayashi, M. Tsuneto, T. Yamada, M. Nose, M. Yoshino, L. D. Shultz, and H. Yamazaki Lipopolysaccharide-Induced Osteoclastogenesis in Src Homology 2-Domain Phosphatase-1-Deficient Viable Motheaten Mice Endocrinology, June 1, 2004; 145(6): 2721 - 2729. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Reprints/Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Okuyama, H. Articles by Hayashi, S.-I. Search for Related Content PubMed PubMed Citation Articles by Okuyama, H. Articles by Hayashi, S.-I.