{alpha}4-Integrin+ endothelium derived from primate embryonic stem cells generates primitive and definitive hematopoietic cells

doi:10.1182/blood-2006-06-031039

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Blood, 15 March 2007, Vol. 109, No. 6, pp. 2406-2415.
Prepublished online as a Blood First Edition Paper on November 7, 2006; DOI 10.1182/blood-2006-06-031039.

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HEMATOPOIESIS
${alpha}$ 4-Integrin⁺ endothelium derived from primate embryonic stem cells generates primitive and definitive hematopoietic cells
Gen Shinoda¹, Katsutsugu Umeda¹, Toshio Heike¹, Masato Arai¹, Akira Niwa¹, Feng Ma¹, Hirofumi Suemori², Hong Yuan Luo³, David H. K. Chui³, Ryuzo Torii⁴, Masabumi Shibuya⁵, Norio Nakatsuji⁶, and Tatsutoshi Nakahata¹
¹ Department of Pediatrics, Graduate School of Medicine, ² Laboratory of Embryonic Stem Cell Research, Stem Cell Research Center, Institute for Frontier Medical Sciences, and ⁶ Department of Development and Differentiation, Institute for Frontier Medical Sciences, Kyoto University, Japan; ³ Department of Medicine, Boston University School of Medicine, MA; ⁴ Research Center for Animal Life Science, Shiga University of Medical Science, Japan; ⁵ Division of Genetics, Institute of Medical Science, University of Tokyo, Japan

   Abstract

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Abstract
Introduction
Materials and methods
Results
Discussion
Authorship
References

The mechanism of commencement of hematopoiesis in blood islandsof the yolk sac and the aorta-gonad-mesonephros (AGM) regionduring primate embryogenesis remains elusive. In this study,we demonstrated that VE-cadherin⁺CD45^– endothelial cellsderived from nonhuman primate embryonic stem cells are ableto generate primitive and definitive hematopoietic cells sequentially,as revealed by immunostaining of floating erythrocytes and colony-formingassay in cultures. Single bipotential progenitors for hematopoieticand endothelial lineages are included in this endothelial cellpopulation. Furthermore, hemogenic activity of these endothelialcells is observed exclusively in the ${alpha}$ 4-integrin⁺ subpopulation;bipotential progenitors are 4-fold enriched in this subpopulation.The kinetics of this hemogenic subpopulation is similar to thatof hemogenic endothelial cells previously reported in the yolksac and the AGM region in vivo in that they emerge for onlya limited time. We suggest that VE-cadherin⁺CD45^– ${alpha}$ 4-integrin⁺endothelial cells are involved in primitive and definitive hematopoiesisduring primate embryogenesis, though VE-cadherin^–CD45^– ${alpha}$ 4-integrin⁺cells are the primary sources for primitive hematopoiesis.

   Introduction

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Abstract
Introduction
Materials and methods
Results
Discussion
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During mammalian embryogenesis, hematopoietic system developmentundergoes 2 distinct phases, primitive hematopoiesis and definitivehematopoiesis. The phases are distinguished from each otherby 2 characteristics. First, primitive hematopoiesis originatesexclusively in the extraembryonic yolk sac and is transient,whereas definitive hematopoiesis occurs in the intraembryonicaorta-gonad-mesonephros (AGM) region, shifts to the liver, spleen,and bone marrow, and persists for life. Evidence also indicatesthat the yolk sac serves as a source of initial definitive hematopoieticprogenitors in humans, as it does in mice.^1,2 Second, in primates,primitive erythrocytes are larger and primarily synthesize embryonicglobin chains ( ${zeta}$ , ${epsilon}$ ), whereas definitive erythrocytes are smallerand synthesize fetal/adult globin chains ( ${alpha}$ , ${gamma}$ , and ß).^3,4Because the embryonic–fetal globin switch ( ${zeta}$ $->$ ${alpha}$ and ${epsilon}$ $->$ ${gamma}$ )occurs gradually in the fetal liver, embryonic and fetal globinsare expressed during the transition from primitive to definitivehematopoiesis. However, adult ß-globin is predominantlyexpressed in definitive erythrocytes and is only marginallyexpressed, if at all, in primitive erythrocytes
The existence of the hemangioblast, the common precursor ofhematopoietic and endothelial lineages, has been discussed formany years. Histologically, hematopoietic and endothelial cellsdevelop from the same clusters of mesoderm in yolk sac bloodislands.^5,6 In addition to the shared expression of severalmarkers, gene-targeting experiments on vascular endothelialgrowth factor receptor-2 (VEGFR-2) disclose a common developmentalpathway between both cell types.^7,8 Furthermore, a single commonprecursor generates both cell types during in vitro differentiationof mouse embryonic stem cells (ESCs).⁹ Recent evidence showsthat intraembryonic hematopoiesis originates from the ventralendothelial walls of the dorsal aorta and the umbilical andvitelline arteries, challenging the concept of common progenitors.^10–16Endothelial cells capable of generating hematopoietic cellsare designated "hemogenic endothelium."^17,18 Earlier studiesusing mouse embryos demonstrate that endothelial cells in theyolk sac are able to generate hematopoietic cells, which isalso suggested by some reports on human embryos.^12,15,16 Theembryos were used, however, at the stage after vascular connectionbetween the yolk sac and the embryo proper. Hence, though itis established that definitive hematopoiesis in the AGM regionoriginates at least in part in endothelial cells, the originof primitive/definitive hematopoiesis in the yolk sac is stillunclear.
The aims of this study were to investigate the relationshipbetween hemogenic endothelium and primitive/definitive hematopoiesisin primates and to identify markers of the hemogenic endothelium.Analyses using primate materials are necessary because a numberof differences occur in hematopoietic development between miceand primates (human and monkey). These studies are difficultto perform because of the poor availability of primate embryosand the ethical limitations involved in their use. Recentlyestablished primate ESC lines^19–22 are promising alternativetools in developmental biology and regenerative medicine. Wepreviously showed the development of hematopoietic and endothelialcells when cynomolgus monkey ESCs were cocultured with OP9 stromalcells, which was enhanced by exogenous vascular endothelialgrowth factor (VEGF).^23,24 In our coculture system, the transitionfrom primitive to definitive hematopoiesis was induced, as confirmedby globin switching.²⁵ Here, we examined the hematopoietic potentialof endothelial cells in our coculture system and demonstratedthat isolated VE-cadherin⁺CD45^– endothelial cells generatedprimitive and definitive hematopoietic cells based on morphologicand globin expression analyses. We used ${alpha}$ 4-integrin, an effectivemarker of the hemogenic population among endothelial cells inmouse embryos and in in vitro differentiating ESCs,²⁶ as a candidatemarker of hemogenic endothelial cells in primates. Our datashow that the capacity for primitive and definitive hematopoiesisresides exclusively in the ${alpha}$ 4-integrin⁺ subpopulation among ESC-derivedendothelial cells, though VE-cadherin^–CD45^– ${alpha}$ 4-integrin⁺cells are primary sources for primitive hematopoiesis.

   Materials and methods

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Abstract
Introduction
Materials and methods
Results
Discussion
Authorship
References

Maintenance of cell lines
The ESC line CMK6, established from cynomolgus monkey blastocysts,was maintained as described .¹⁹ The GFP-transfected ESC subline²⁷was applied to exclude OP9 cells in some experiments. OP9 stromalcells, a kind gift from Dr Hiroaki Kodama, were maintained asreported previously.²⁴
Antibodies
Primary antibodies used in this study included mouse anti–humanCD34-phycoerythrin (PE), CD41a-allophycocyanin (APC), ${alpha}$ 4-integrin-PE,endothelial nitric oxide synthase (eNOS) monoclonal antibodies(mAbs; BD PharMingen, San Diego, CA), mouse anti–humanCD31-PE (eBioscience, San Diego, CA), rabbit anti–humanvon Willebrand factor (VWF; Nichirei, Tokyo, Japan), mouse anti–humanCD45 and CD41 mAbs (Dako, Kyoto, Japan), mouse anti–humanVE-cadherin mAb (Immunotech, Marseille, France), mouse anti–humanß-globin and ${gamma}$ -globin mAbs (Santa Cruz Biotechnology,Santa Cruz, CA), rabbit anti–human hemoglobin (Hb) polyclonalAb (Cappel, Aurora, OH), and their corresponding IgG1 isotypecontrols (BD PharMingen and Dako). Mouse anti–human VE-cadherinmAb (BD PharMingen) and its corresponding IgG1 isotype controlwere labeled with Alexa Fluor 647 monoclonal antibody labelingkit (Invitrogen, Carlsbad CA). Mouse anti–human ${epsilon}$ -globinand ${zeta}$ -globin and mouse anti–human VEGFR-2 mAbs were used,as reported previously.^28–30 Mouse anti–human ${alpha}$ -globinmAb was established in the laboratory of D.H.K.C. All primaryantibodies against human antigens used in this study cross-reactedwith cynomolgus monkey compartments.^23,24 Secondary Abs includedCy3-conjugated, horseradish peroxidase (HRP)–conjugated,or alkaline phosphatase (ALP)–conjugated donkey anti–mouseIgG, fluorescein isothiocyanate (FITC)–conjugated donkeyanti–rabbit IgG (Jackson ImmunoResearch Laboratories,West Grove, PA), PE-conjugated goat anti–mouse IgG (Dako),and FITC- or APC-conjugated goat anti–mouse IgG (BD PharMingen).
In vitro differentiation of primate ESCs
Initial differentiation of ESCs and cell sorting were basedon earlier experiments.^23,24 Briefly, trypsin-treated undifferentiatedESCs were transferred onto OP9 cells and cultured in the presenceof 20 ng/mL VEGF (R&D Systems, Minneapolis, MN).
For hematopoietic differentiation, cells sorted on day 10 werecultured in ${alpha}$ -MEM (Gibco BRL, Grand Island, NY) containing 10%fetal calf serum (FCS; Sigma, St Louis, MO), 50 µM 2-mercaptoethanol(ME), and a mixture of 10 ng/mL G-CSF, 2 U/mL EPO, 20 ng/mLIL-3, 100 ng/mL SCF, and 10 ng/mL TPO (hematopoietic cytokinemixture; all were provided by Kirin Brewery, Tokyo, Japan).For endothelial differentiation, sorted cells were culturedon OP9 cells in ${alpha}$ -MEM containing 10% FCS, 50 µM 2-ME, and20 ng/mL VEGF or were seeded onto type I collagen-coated platesin medium (CS-C Complete Medium; Cell Systems, Kirkland, WA)supplemented with 20 ng/mL VEGF.
Fluorescence-activated cell sorter analysis and cell sorting
Staining procedures, FACS analysis, and cell sorting were performedas described earlier.^23,24 For multicolor staining, single-cellsuspensions were initially stained with unconjugated anti–CD45mAb or its corresponding IgG1 isotype control, followed by FITC-,PE-, or APC-conjugated goat anti–mouse IgG. The cellswere washed twice, incubated with robust mouse IgG to preventredundant secondary Abs from reacting with other mouse mAbs,and stained with fluorochrome-conjugated mAbs, including CD34,VE-cadherin, and ${alpha}$ 4-integrin. Dead cells were excluded by propidiumiodide (PI) staining. Samples were analyzed with the use ofFACSCalibur and Cell Quest software (Becton Dickinson, San Jose,CA) or were sorted on a FACSVantage SE (Becton Dickinson).
Immunochemistry and acetylated low-density lipoprotein (Ac-LDL) uptake
May-Giemsa staining, immunostaining of floating erythrocytesand endothelial colonies, and DiI-Ac-LDL incorporation assaywere performed as described previously.^23,24 VE-cadherin⁺CD45^–cells isolated on day 10 or their progeny were cytospun ontoglass slides, fixed, and permeabilized in a staining proceduresimilar to that for hemoglobin.²⁴ Cells were initially stainedwith anti–VE-cadherin mAb and Cy3-conjugated donkey anti–mouseIgG, followed by double staining with various Abs using theVector MOM kit (Vector Laboratories, Burlingame, CA), visualizedwith the TSA fluorescence systems kit (PerkinElmer Life Sciences,Boston, WA), and counterstained with Hoechst 33342. Fluorescencewas detected on an Olympus IX70 microscope (Olympus, Tokyo,Japan) that was equipped with 4 x/0.13 NA, 10 x/0.30 NA, and20 x/0.40 NA objectives, and images were obtained with an AxioCamphotomicroscope and AxioVision software version 3.0.6 SP4 (CarlZeiss Vision, Hallbergmoos, Germany). Images were processedusing Adobe Photoshop 6.0 (Adobe Systems, San Diego, CA).
Colony-forming assays for primitive and definitive cells
Colony-forming assays were performed as described elsewhere.^24,31Briefly, for colonies consisting of primitive cells, sortedcells in each subpopulation were reseeded on OP9 layers, andthe medium was replaced with methylcellulose-containing mediumsupplemented with 30% FCS and hematopoietic cytokine mixtureon the following day. For colonies composed of definitive cells,we initially trypsinized cells and allowed OP9 stromal cellsto adhere to culture dishes to exclude OP9. Resultant floatingfractions were transferred to new Petri dishes with methylcellulose-containingmedium supplemented with 30% FCS and hematopoietic cytokinemixture and were cultured at 37°C, 5% CO₂, in a humidifiedincubator. Colonies were scored using an inverted microscope^24,32,33after 7 days for primitive cells and 14 days for definitivecells. Colonies were selected for cytospin and further staining.All assays were performed at a concentration of 0.5-2 x 10⁴cells/mL in duplicate or triplicate.
Single-cell deposition assay for hematopoietic and endothelial differentiation
Single-cell deposition assay was performed as described earlier.²³Briefly, single-sorted cells were deposited in individual wellsof 96-well plates with confluent OP9 layers and were culturedin ${alpha}$ -MEM containing 10% FCS, 50 µM 2-ME, and hematopoieticcytokine mixture for 7 days. Each well was initially stainedwith a mixture of anti-CD45, anti-CD41, and anti– ${gamma}$ -globinmAbs, followed by HRP-conjugated donkey anti–mouse IgGfor hematopoietic lineage detection, and each was double stainedwith anti–VE-cadherin mAb using the Vector MOM kit (Vector),followed by ALP-conjugated donkey anti–mouse IgG for endotheliallineage detection.
Reverse transcription–polymerase chain reaction
We performed RNA isolation and RT-PCR according to previouslyestablished protocols.^23,24 Samples were initially denaturedat 94°C for 5 minutes, followed by 35 to 40 amplificationreactions consisting of 94°C for 1 minute (denaturing),60°C to 62°C for 1 minute (annealing), 72°C for1 minute (extension), and a final extension at 94°C for7 minutes. Primers for eNOS, SCL, GATA-2, RUNX1, and GAPDH aredescribed elsewhere.^23,34 Other primers used included ${alpha}$ 4-integrin(434 bp) (sense, 5'-AGATGGGATCTCGTCAACCTTC-3'; antisense, 5'-TGGACACCTGTATGCTTCCTG-3'),VWF (472 bp) (sense, 5'-GGGACCTTTCGGATCCTAGTG-3'; antisense,5'-AGGAGGAATCCACCATCGTC-3'), and mouse ß-actin (613bp) (sense, 5'-ATCCTGACCCTGAAGTACCCCATT-3'; antisense, 5'-CCAAGAAGGAAGGCTGGAAAAGAG-3').cDNA from adult cynomolgus monkey BM cells, human erythroblasticcells (K562), and human umbilical vein endothelial cells wereused as positive controls, and mouse OP9 cells were used asa negative control. For semiquantitative comparison, sampleswere normalized by dilution to produce equivalent signals forGAPDH.
Statistical analysis
Statistical analyses were conducted using the Student t testor Fisher exact test. Statistical significance was defined asa P value below .05.

   Results

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Abstract
Introduction
Materials and methods
Results
Discussion
Authorship
References

Development of primate ESC-derived VE-cadherin⁺CD45^– endothelial cells
Initially, we investigated when cells positive for hematopoieticor endothelial markers emerged during ESC differentiation. GFP-transfectedESCs were induced to differentiate by coculture with OP9 stromalcells in the presence of exogenous VEGF. Sequential FACS analysisfor various surface markers was performed, and the percentageof positive cells among viable GFP⁺ cells was quantified (Figure 1A).Undifferentiated ESCs expressed low levels of VEGFR-2 but notother hematopoietic or endothelial markers, such as CD31, CD34,VE-cadherin, CD41a, or CD45 (Figure 1B). VEGFR-2 was down-regulatedby day 4 of culture but subsequently was re-expressed on a fractionof differentiating cells. CD31⁺, CD34⁺, and VE-cadherin⁺ cellsinitially appeared on day 6, and CD41a⁺ and CD45⁺ cells appearedon day 12. Thus, cells positive for VE-cadherin, an endothelialmarker, emerged in the OP9 coculture earlier than those positivefor the hematopoietic marker CD41a or CD45.

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Figure 1. ESC-derived VE-cadherin⁺CD45^– cells have endothelial properties. Undifferentiated GFP-transfected ESCs (ES) and subsequent differentiating cells were analyzed by FACS. GFP⁺PI^– cells were gated as ESC-derived viable cells. (A) Percentage of gated cells among the total cells is specified. (B) Sequential analysis of the percentage of cells positive for each antigen among ESC-derived viable cells. Data are presented as mean ± SD of 3 independent experiments. (C) VE-cadherin⁺CD45^–(VEcad⁺CD45^–) or VE-cadherin^–CD45^–(VEcad^–CD45^–) cells were sorted on day 10. Representative FACS dot plots and percentages of gated cells are shown. Purities of viable VE-cadherin⁺CD45^– and VE-cadherin^–CD45^– cells are 99.2% ± 0.6% and 99.9% ± 0.1%, respectively, from at least 3 independent experiments. (D) VE-cadherin⁺ cells on day 10 were analyzed by FACS with various mAbs. Percentages of cells positive for each antigen among VE-cadherin⁺ cells are shown. Gray line indicates isotype control; black line, VE-cadherin⁺ cells. (E-J) Untransfected ESC-derived VE-cadherin⁺CD45^– cells sorted on day 10 were evaluated by the DiI-Ac-LDL incorporation assay (E) or immunostaining with IgG1 (F), anti–Hb (G), VEGFR-2 (H), eNOS (I), or VWF (J) Abs. Hoechst 33342 (E-J) and anti–VE-cadherin mAb (F-J) were used to detect nuclei and endothelial cells, respectively. Original magnification x 200. Scale bar, 50µm.

VE-cadherin belongs to the cadherin family of adhesive transmembraneproteins and is expressed solely in endothelial cells.³⁵ Theprotein is additionally detected in all developing vessels fromearly embryonic stages.³⁶ To date, VE-cadherin has been usedfor the isolation of cells committed to endothelial lineageas an endothelial-specific marker.^15,16,26,37 Accordingly, weused anti–VE-cadherin and CD45 mAbs to purify endothelialcells and exclude hematopoietic cells (Figure 1C). Indeed, isolatedVE-cadherin⁺CD45^– cells on day 10 exclusively coexpressedCD31 and CD34 but not CD41a (Figure 1D). Moreover, all VE-cadherin⁺CD45^–cells on day 10 had Ac-LDL uptake capacity and expressed VEGFR-2and eNOS but not Hb (Figure 1E-I). On the other hand, only 27.4%± 7.8% cells expressed VWF (n = 3) (Figure 1J), suggestingthat most were functionally immature. Our results indicatedthat VE-cadherin⁺CD45^– cells generated on day 10, beforethe emergence of hematopoietic cells, had several endothelialcharacteristics.
VE-cadherin⁺CD45^– population generates hematopoietic and endothelial cells
To determine the hematoangiogenic capacity of isolated VE-cadherin⁺CD45^–cells, VE-cadherin⁺CD45^– and VE-cadherin^–CD45^–cells were reseeded separately onto fresh, confluent OP9 cellsand cultured with hematopoietic cytokine mixture (see "Materialsand methods") for hematopoietic differentiation or with VEGFfor endothelial differentiation.
In hematopoietic differentiation cultures, adherent hematopoieticclusters initially emerged from the VE-cadherin⁺CD45^–population at approximately day 10 + 3 (3 days after sortingon day 10) (Figure 2A) and covered large areas of OP9 stromallayers by day 10 + 21 (Figure 2B). In contrast, adherent hematopoieticclusters from the VE-cadherin^–CD45^– population wererare and small and disappeared by day 10 + 12 (data not shown).Under hematopoietic differentiation conditions, the numbersof CD45⁺ and CD45⁺CD34⁺ hematopoietic cells generated from theVE-cadherin⁺CD45^– population were 9.5- and 16.1-fold higher,respectively, than from the VE-cadherin^–CD45^– populationat day 10 + 7 (P < .05) (Figure 2N-O). It should be notedthat VE-cadherin^–CD45^– cells generated a small butsignificant minority of hematopoietic cells at day 10 + 7.

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Figure 2. ESC-derived VE-cadherin⁺CD45^– cells generate hematopoietic and endothelial cells/colonies. Light micrographs of adherent hematopoietic clusters on days 10 + 5 (A) and 10 + 23 (B). (C-D) May-Giemsa staining of floating hematopoietic cells on days 10 + 6 (C) and 10 + 30 (D). (E) Immunostaining of floating hematopoietic cells on day 10 + 30 with anti–CD41 (red) and Hb (green) Abs. (F-K) Light micrographs and May-Giemsa staining of a GM (F-G), erythroid (H-I), or mixed colony (J-K) are depicted. (L) Immunostaining of an endothelial colony with anti–VE-cadherin mAb (blue). (M) Immunostaining of VE-cadherin⁺CD45^– cell-derived cells after 7-day culture with anti–VE-cadherin (red) and VWF (green) Abs. (E, M) Nuclei were labeled with Hoechst 33342. (N, O) Numbers of CD45⁺ (N) or CD45⁺CD34⁺ cells (O) derived from 1 x 10⁵ VE-cadherin⁺CD45^– (VEcad⁺CD45^–) or VE-cadherin^–CD45^– (VEcad^–CD45^–) cells. (P) Sequential analysis of the percentages of nucleated erythrocytes (red), enucleated erythrocytes (yellow), myeloid lineage cells (green), and megakaryocytes (blue) among floating cells. Each bar represents the mean of 3 independent experiments. (Q) Sequential analysis of the numbers of hematopoietic colonies per 1 x 10⁴ VEcad⁺CD45^– or VEcad^–CD45^– cell-derived cells. (R) Numbers of endothelial colonies per 1 x 10³ VEcad⁺CD45^– or VEcad^–CD45^– cells. (A-P) Data obtained from VEcad⁺CD45^– cells are shown. Data are presented as mean ± SD of 3 independent experiments in N-O and Q-R. Each experiment was performed in triplicate in P-R. Original magnification x 40 (B, F, L), x 100 (A, H, J), and x 200 (C-E, G, I, K, M). Scale bars, 20 µm (C-E, G, I, K), 50 µm (M), and 100 µm (A-B, F, H, J, L).

Floating hematopoietic cells emerged from the VE-cadherin⁺CD45^–population at approximately day 10 + 3. Their number was lowuntil day 10 + 12 but increased exponentially afterward. Cellsconsisted exclusively of mature hematopoietic cells, such aserythrocytes, myeloid lineage cells, and megakaryocytes, asrevealed by May-Giemsa staining and immunostaining (Figure 2C-E).Floating erythrocytes on day 10 + 6 were apparently larger thanthose on day 10 + 30 (Figure 2C-D). The percentage of erythrocytesamong floating cells was approximately 60% to 70% throughoutthe experiments, which increased to some degree with time (Figure 2P).Enucleated erythrocytes accounted for less than 1% of totalerythrocytes on day 10 + 6 and 6% to 10% from day 10 + 12 onward.Again, floating cells from the VE-cadherin^–CD45^–population were rarely observed.
We also performed a sequential standard methylcellulose colonyassay to evaluate the clonogenic potential of VE-cadherin⁺CD45^–-derivedor VE-cadherin^–CD45^–-derived cells. As shown inFigure 2Q, few colonies were generated from VE-cadherin⁺CD45^–cells (denoting day 10 + 0) and coculture of VE-cadherin⁺CD45^–cells on the OP9 layer for another 12 days (day 10 + 12), consistingexclusively of granulocyte-macrophage (GM) colonies. After 18days of coculture (day 10 + 18), other colonies, including GM(Figure 2F-G), erythroid (Figure 2H-I), and mixed (Figure 2J-K),were detected. During the experiment, few colonies were generatedfrom the coculture of VE-cadherin^–CD45^– cells onthe OP9 layer.
In endothelial differentiation cultures, sheetlike or cordlikeVE-cadherin⁺ endothelial colonies were generated after 7 daysalmost exclusively from the VE-cadherin⁺CD45^– population(P < .05) (Figure 2L, R). In 7-day culture, all endothelialcells had Ac-LDL uptake capacity and expressed VE-cadherin,VWF, VEGFR-2, CD31, CD34, and eNOS (Figure 2M and data not shown).Our results indicated that VE-cadherin⁺CD45^– cells isolatedon day 10 composed a population of early endothelial cells withhemogenic properties that could differentiate into mature endothelialcells.
VE-cadherin⁺CD45^– population contains single cells with hematopoietic and endothelial capacities
We performed a single-cell deposition assay to analyze whetherthe VE-cadherin⁺CD45^– population contained common progenitorsfor hematopoietic and endothelial lineages. Individual wellsof a 96-well plate were subjected to fluorescence microscopy24 hours after cell deposition, and wells that contained morethan one GFP⁺ cell (ESC-derived cells) were excluded from subsequentanalyses (5 of 2885 wells). Consistent with previous reports,²³when a mixture of anti–CD45, CD41, and ${gamma}$ -globin mAbs wasused, all the round cells belonging to the hematopoietic lineagewere stained positively.
Of the 2880 wells analyzed, 269 (8.6%) demonstrated clonal outgrowthconsisting of endothelial progeny only (7.4%; 213 wells) (FigureS1A, available on the Blood website; see the Supplemental Figureslink at the top of the online article), hematopoietic progenyonly (0.17%; 5 wells) (Figure S1B), and both endothelial andhematopoietic progeny (1.1%; 31 wells) (Figure S1C). Thus, ourresults clearly demonstrated that the VE-cadherin⁺CD45^–population contained common progenitors for hematopoietic andendothelial lineages.
VE-cadherin⁺CD45^– cells generated primitive and definitive erythrocytes sequentially
To determine whether the erythrocytes derived from the VE-cadherin⁺CD45^–population were primitive or definitive, we analyzed the expressionpatterns of embryonic ( ${zeta}$ and ${epsilon}$ ), fetal ( ${alpha}$ and ${gamma}$ ), and adult (ß)globins in floating erythrocytes by sequentially immunostainingfor various globin chains (Figure 3). Until day 10 + 6, allfloating erythrocytes expressed ${epsilon}$ - and ${zeta}$ -globins, whereas ß-globinexpression was hardly detected (less than 1%). The percentageof floating erythrocytes positive for ß-globin increasedgradually from day 10 + 12, and almost all erythrocytes werepositive by day 10 + 30. Meanwhile, expression of ${epsilon}$ - and ${zeta}$ -globinsdeclined gradually to approximately 90% and 80% by day 10 +30, respectively. All floating erythrocytes expressed ${alpha}$ - and ${gamma}$ -globins throughout the experimental period. Others and we havefound ß-globin the most specific type of globin genesfor the identification of definitive erythrocytes.^{4,25,29,30,34}Results here showed that ß-globin, a specific markerfor definitive erythrocytes, is up-regulated gradually in theOP9 coculture and that VE-cadherin⁺CD45^– cells generateprimitive and definitive erythrocytes sequentially.

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Figure 3. ESC-derived VE-cadherin⁺CD45^– cells generate primitive and definitive erythrocytes sequentially. Immunostaining of floating erythrocytes on days 10 + 6 (A-E) and 10 + 30 (F-J). Cy3 detection of erythrocytes stained with anti– ${alpha}$ -, anti–ß-, anti– ${epsilon}$ -, anti– ${gamma}$ -, or anti– ${zeta}$ -globin mAbs (red) and FITC detection with anti–Hb polyclonal Ab (green). Anti-Hb Ab, which reacts with embryonic, fetal, and adult erythrocytes, was used to detect all erythrocytes. Nuclei were labeled with Hoechst 33342. Merged images are shown. Original magnification x 200. Scale bars, 50 µm. (K-L) Sequential analysis of the proportion of erythrocytes positive for anti– ${alpha}$ - or anti– ${zeta}$ -globin mAbs (K) and anti–ß-, anti– ${gamma}$ -, or anti– ${epsilon}$ -globin mAbs (L) among the total erythrocytes. Data are presented as mean ± SD of 3 independent experiments.

Hematopoietic progenitors exclusively reside in the ${alpha}$ 4-integrin⁺ subpopulation of VE-cadherin⁺CD45^– cells
In vivo and in vitro experiments in mice show that ${alpha}$ 4-integrinis a marker of the earliest precursor of hematopoietic celllineage from endothelial progenitors.²⁶ To determine whetherthis is applicable to primates, we sequentially traced the expressionpatterns of VE-cadherin, CD45, and ${alpha}$ 4-integrin in differentiatingESCs cocultured with OP9 cells. As shown in Figure 4, VE-cadherin⁺ ${alpha}$ 4-integrin⁺cells first appeared on day 6, peaked at approximately days8 to 10, and almost disappeared by day 16. In contrast to thepreviously reported time-course of mouse ESC differentiation,²⁶VE-cadherin⁺ and ${alpha}$ 4-integrin⁺ cells simultaneously developedfrom monkey ESCs. CD45⁺ cells appeared from day 12 onward, andmost coexpressed ${alpha}$ 4-integrin.

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Figure 4. Temporal emergence of VE-cadherin⁺ ${alpha}$ 4-integrin⁺ cells during ESC differentiation. As described for Figure 1, undifferentiated GFP-transfected ESCs and subsequent differentiating cells were analyzed by FACS. Percentages of cells in each quadrant among the total viable GFP⁺ cells are indicated. Representative results from 1 of 3 independent experiments are shown.

Next, we isolated VE-cadherin⁺ ${alpha}$ 4-integrin^–, VE-cadherin⁺ ${alpha}$ 4-integrin⁺,and VE-cadherin^– ${alpha}$ 4-integrin⁺ cells on day 10 after excludingdead cells and CD45⁺ cells to evaluate their hematopoietic andendothelial capacity (Figure 5A). Isolated cells were reseededonto fresh confluent OP9 layers and were cultured with hematopoieticcytokine mixture. Among the VE-cadherin⁺CD45^– population,only the ${alpha}$ 4-integrin⁺ subpopulation gave rise to adherent hematopoieticclusters and floating hematopoietic cells (Figure 5C, F, H).Adherent clusters grew, and the number of floating cells increasedthroughout the experimental period (Figure 5D, G-H). VE-cadherin⁺ ${alpha}$ 4-integrin⁺cells generated 5- to 10-fold more floating hematopoietic cellsthan total VE-cadherin⁺ cells. VE-cadherin^– ${alpha}$ 4-integrin⁺cells yielded more adherent clusters and floating cells thanVE-cadherin⁺ ${alpha}$ 4-integrin⁺ cells until day 10 + 6 (Figure 5B, E).Interestingly, however, the adherent clusters from VE-cadherin^– ${alpha}$ 4-integrin⁺cells disappeared by day 10 + 12, and the number of floatingcells declined drastically (Figure 5H). Again, the sizes offloating erythrocytes on day 10 + 6 derived from VE-cadherin⁺ ${alpha}$ 4-integrin⁺and VE-cadherin^– ${alpha}$ 4-integrin⁺ cells were larger than thoseon day 10 + 30 from VE-cadherin⁺ ${alpha}$ 4-integrin⁺ cells (Figure 5E-G).

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Figure 5. Hematopoietic progenitors exclusively reside in the ${alpha}$ 4-integrin⁺ subpopulation among VE-cadherin⁺CD45^–cells. (A) VE-cadherin⁺ ${alpha}$ 4-integrin^– (VEcad⁺ ${alpha}$ 4^–), VE-cadherin⁺ ${alpha}$ 4-integrin⁺ (VEcad⁺ ${alpha}$ 4⁺), or VE-cadherin^– ${alpha}$ 4-integrin⁺ (VEcad^– ${alpha}$ 4⁺) cells were sorted on day 10 after the exclusion of PI⁺ and CD45⁺ cells. Representative FACS dot plots and percentages of gated cells are shown. Purities of viable VEcad⁺ ${alpha}$ 4^–, VEcad⁺ ${alpha}$ 4⁺, and VEcad^– ${alpha}$ 4⁺ cells are 95.0%± 3.0%, 94.1%± 0.5%, and 96.9%± 2.1%, respectively, from at least 3 independent experiments. (B-D) Light micrographs of adherent hematopoietic clusters on day 10 + 6 from VEcad^– ${alpha}$ 4⁺ cells (B) and days 10 + 6 (C) and 10 + 18 (D) from VEcad⁺ ${alpha}$ 4⁺ cells. (E-G) May-Giemsa staining of floating hematopoietic cells on day 10 + 6 from VEcad^– ${alpha}$ 4⁺ cells (E) and days 10 + 6 (F) and 10 + 30 (G) from VEcad⁺ ${alpha}$ 4⁺ cells. Original magnification x 40 (B-D) and x 200 (E-G). Scale bars, 100 µm (B-D) and 20 µm (E-G). (H) Sequential analysis of the numbers of floating viable cells per cultured 1 x 10⁴ VE-cadherin⁺ ( ${blacksquare}$ ), VE-cadherin^– ( ${square}$ ), VEcad⁺ ${alpha}$ 4^– ( ${circ}$ ), VEcad⁺ ${alpha}$ 4⁺ ( $bullet$ ), or VEcad^– ${alpha}$ 4⁺ ( ${blacktriangleup}$ ) cells. (I) Numbers of endothelial colonies per 1 x 10³ cells in each subpopulation. (H-I) Data are presented as mean ± SD of 3 independent experiments. Each experiment was performed in triplicate. (J) RT-PCR analysis of genes associated with hematopoietic or endothelial development. Each lane contained cDNA from the following cells: adult cynomolgus monkey BM cells (lane 1), K562 erythroblastic cells (lane 2), human umbilical vein endothelial cells (lane 3), OP9 stromal cells (lane 4), total GFP⁺ ESC-derived cells (lane 5), VE-cadherin⁺ ${alpha}$ 4-integrin^– cells (lane 6), VE-cadherin⁺ ${alpha}$ 4-integrin⁺ cells (lane 7), and VE-cadherin^– ${alpha}$ 4-integrin⁺ cells (lane 8) sorted on day 10. Representative results from 1 of 3 independent experiments are shown.

To clarify the difference in hematopoietic kinetics betweenVE-cadherin⁺ ${alpha}$ 4-integrin⁺ and VE-cadherin^– ${alpha}$ 4-integrin⁺ populations,we examined whether floating erythrocytes derived from eachpopulation were primitive or definitive. As in the VE-cadherin⁺CD45^–population, all floating erythrocytes derived from both populationsexpressed ${alpha}$ -, ${epsilon}$ -, ${gamma}$ -, and ${zeta}$ -globins but were devoid of ß-globinon day 10 + 6 (Figure S2A-E, K-O), indicative of primitive erythrocytes.Moreover, almost all erythrocytes from the VE-cadherin⁺ ${alpha}$ 4-integrin⁺population were positive for ß-globin by day 10 +30, whereas the expression of ${epsilon}$ - and ${zeta}$ -globins declined gradually(Figure S2F-J), characteristic of definitive erythrocytes.
In endothelial differentiation cultures with VEGF, VE-cadherin⁺ ${alpha}$ 4-integrin⁺cells generated significantly more endothelial colonies thanVE-cadherin⁺ ${alpha}$ 4-integrin^– cells after 7-day culture (P <.05) (Figure 5I). VE-cadherin^– ${alpha}$ 4-integrin⁺ cells barelygenerated endothelial colonies.
To verify the hematopoietic and endothelial capacities of these3 populations, gene expression profiles were investigated withthe use of RT-PCR (Figure 5J). The presence of ${alpha}$ 4-integrin wasconfirmed specifically in the VE-cadherin⁺ ${alpha}$ 4-integrin⁺ and VE-cadherin^– ${alpha}$ 4-integrin⁺populations. eNOS and VWF, representative endothelial proteins,were expressed in VE-cadherin⁺ ${alpha}$ 4-integrin^– and VE-cadherin⁺ ${alpha}$ 4-integrin⁺populations, whereas VWF was expressed weakly in the VE-cadherin^– ${alpha}$ 4-integrin⁺population. SCL and GATA-2, transcriptional factors associatedwith hematopoietic and endothelial development,^38,39 were expressedin all 3 populations. Notably, RUNX1, a transcriptional factorassociated with definitive hematopoiesis,^40,41 was expressedin the VE-cadherin⁺ ${alpha}$ 4-integrin⁺ and VE-cadherin^– ${alpha}$ 4-integrin⁺populations but not in VE-cadherin⁺ ${alpha}$ 4-integrin^– cells.
Finally, we performed a single-cell deposition assay of VE-cadherin⁺ ${alpha}$ 4-integrin⁺cells. We differentiated GFP-transfected ESCs, and single VE-cadherin⁺ ${alpha}$ 4-integrin⁺cells that were exclusively negative for CD45 were assayed onday 10. Of the 958 wells analyzed (2 of 960 wells were omittedbecause they contained more than 1 GFP⁺ cell), 106 (11.1%) demonstratedclonal outgrowth consisting of endothelial progeny only (6.3%;60 wells), hematopoietic progeny only (0.52%; 5 wells), andboth endothelial and hematopoietic progeny (4.3%; 41 wells).Hence, common progenitors for hematopoietic and endotheliallineages in the VE-cadherin⁺CD45^– population were 4.0-foldmore enriched in the ${alpha}$ 4-integrin⁺ subpopulation (P < .001).
Thus, these results suggested that among VE-cadherin⁺CD45^–cells, only the ${alpha}$ 4-integrin⁺ subpopulation participated in primitiveand definitive hematopoiesis, whereas ${alpha}$ 4-integrin⁺ and ${alpha}$ 4-integrin^–subpopulations were involved in endothelial lineage development.Our results also showed that VE-cadherin^–CD45^– ${alpha}$ 4-integrin⁺and VE-cadherin⁺CD45^– ${alpha}$ 4-integrin⁺ cells were primary sourcesfor primitive and definitive hematopoiesis, respectively.
Colonies consisting of primitive and definitive erythrocytes are generated from VE-cadherin⁺ ${alpha}$ 4-integrin⁺ cells
As shown, erythroid colonies were not generated from VE-cadherin⁺CD45^–cells by day 10 + 18 with the standard methylcellulose assay(Figure 2Q). Others and we^24,42 have reported the successfuldevelopment of colonies consisting of primitive erythrocyteson OP9 stromal layers. Colony-forming assays were performedon OP9 layers. Colonies consisting of primitive erythrocyteswere generated after 7-day coculture on OP9 cells from the VE-cadherin⁺,VE-cadherin⁺ ${alpha}$ 4-integrin⁺, and VE-cadherin^– ${alpha}$ 4-integrin⁺ populationsbut not the VE-cadherin⁺ ${alpha}$ 4-integrin^– population (Figure 6A-D,I). All erythrocytes in individual colonies from these populationswere positive for ${zeta}$ -globin but devoid of ß-globin,indicative of primitive erythrocytes. The primitive erythroidclonogenic progenitors in the VE-cadherin⁺ population were 8.7-foldmore enriched in the ${alpha}$ 4-integrin⁺ subpopulation (Figure 6I).On the other hand, the VE-cadherin^– ${alpha}$ 4-integrin⁺ populationyielded a significantly higher number of colonies consistingof primitive erythrocytes and GM than the VE-cadherin⁺ ${alpha}$ 4-integrin⁺population (each P < .05), analogous to the patterns forfloating hematopoietic cells in both populations (Figure 5H).We used the standard methylcellulose assay to generate coloniesconsisting of definitive erythrocytes after day 10 + 18 fromthe VE-cadherin⁺ and VE-cadherin⁺ ${alpha}$ 4-integrin⁺ populations butnot the VE-cadherin⁺ ${alpha}$ 4-integrin^– and VE-cadherin^– ${alpha}$ 4-integrin⁺populations (Figure 6E-H, J). All erythrocytes in individualcolonies were positive for ß-globin, and some weredevoid of ${zeta}$ -globin, characteristic of definitive erythrocytes.

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Figure 6. ${alpha}$ 4-Integrin⁺ subpopulation among VE-cadherin⁺CD45^– cells generates hematopoietic colonies composed of primitive and definitive erythrocytes. (A-H) Light micrographs and May-Giemsa staining of colonies consisting of primitive (A-B) and definitive (E-F) erythrocytes from VE-cadherin⁺ ${alpha}$ 4-integrin⁺ cells are depicted. Immunostaining data from colonies consisting of primitive (C-D) and definitive (G-H) erythrocytes from VE-cadherin⁺ ${alpha}$ 4-integrin⁺ cells are also presented. Cy3 detection of erythrocytes stained with anti–ß-globin (C, G) or anti– ${zeta}$ -globin (D, H) mAbs (red) and FITC detection with anti-Hb polyclonal Ab (green). Nuclei were labeled with Hoechst 33342. Merged images are shown. Original magnification x 100 (A, E) and x 200 (B-D, F-H). Scale bars, 50 µm. (I-J) Numbers of hematopoietic colonies per 1 x 10⁴ cells sorted on day 10 (I) or after 30-day coculture on OP9 layers (J) in each subpopulation. VEcad⁺ denotes the VE-cadherin⁺CD45^– population. EryP and EryD represent colonies consisting of primitive and definitive erythrocytes, respectively. Data are presented as mean ± SD of 3 (I) or 2 (J) independent experiments. Each experiment was performed in duplicate (I) or triplicate (J).

Thus, the VE-cadherin⁺ ${alpha}$ 4-integrin⁺ population displayed primitiveand definitive erythroid clonogenic activity. Our data showedthat hemogenic endothelial cells are not only the sole progenitorpopulation for definitive hematopoiesis, they are deeply involvedin primitive hematopoiesis.

   Discussion

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Despite several similarities, a number of differences were observedbetween mouse and primate hematopoietic development, such asthe pattern of globin switching during the shift of hematopoieticsites. To clarify the pathogenesis and treatment of hematologicdisorders in humans, it was important to investigate hematopoieticdevelopment using primate materials. In the near future, itmay be necessary to apply human ESC-derived products to nonhumanprimates as preclinical models for cell transplantation, aheadof their use in clinical settings. However, relatively littleis known about hematopoiesis during primate embryogenesis comparedwith mouse embryogenesis, partly because of poor availabilityand ethical limitations of primate embryos. Thus, primate ESCsare more promising for studies on primate embryogenesis. Inaddition, coculture with the OP9 stromal cells has been usedsuccessfully for hematopoietic differentiation of mouse andprimate ESCs.^{23,24,31,42,43} In this report, we used the primateESC and OP9 coculture system and demonstrated for the firsttime that ${alpha}$ 4-integrin⁺ hemogenic endothelial cells are deeplyinvolved in primitive and definitive hematopoiesis in primates.
Sequential development of primitive and definitive hematopoiesis from ESC-derived endothelial cells
We showed that VE-cadherin⁺CD45^– endothelial cells derivedfrom nonhuman primate ESCs generate primitive and definitiveerythrocytes. To date, several studies demonstrate hematopoieticdifferentiation of human and nonhuman primate ESCs.^{23,24,34,43–46}Previous in vivo and in vitro experiments in humans indicatethat at least a proportion of hematopoietic cells originatein vascular endothelial cells.^12,45 However, whether primitivehematopoiesis and definitive hematopoiesis originate in hemogenicendothelium in primates remains to be elucidated. Data obtainedin mice are controversial. Numerous investigators report thatonly multilineage definitive, but not primitive, hematopoieticprogenitors arise from endothelial cells,⁴⁷ whereas others showthat VE-cadherin⁺ endothelial cells derived from mouse ESCsgenerate primitive and definitive hematopoietic cells.⁴⁸ Here,we demonstrate that primitive and definitive hematopoietic cellsare, at least in part, generated from a subset of endothelialcells in primates. Because primitive hematopoiesis occurs onlyin the yolk sac, we hypothesized that ESC-derived VE-cadherin⁺CD45^–endothelial cells are equivalent to those in yolk sac bloodislands and possibly in the AGM region in vivo.
VE-cadherin is a specific endothelial lineage marker,^15,16,26,37whereas CD45 is widely accepted as a specific hematopoieticlineage marker except in erythroid and megakaryocytic lineagecells. Based on reports that VE-cadherin⁺CD45⁺ intermediatecells exist in mouse embryos,^49,50 we isolated VE-cadherin⁺CD45^–cells as definitive endothelial, but not hematopoietic, cells.In addition, our immunochemistry and FACS analyses demonstratedthat VE-cadherin⁺CD45^– cells on day 10 of culture coexpressother endothelial markers, such as CD31, CD34, VEGFR-2, andeNOS, and take up Ac-LDL but that they lack mature endothelialproperties, including VWF expression (Figure 1D-J). These resultsare consistent with the established multiparameter criteriafor defining endothelial cells.^45,51 Furthermore, VE-cadherin⁺CD45^–cells are devoid of hematopoietic specific marker expression,such as hemoglobin, CD45, and CD41a. Thus, the VE-cadherin⁺CD45^–cells in this study are confirmed as endothelial, albeit immature,cells.
Studies show that ß-globin is the most specific typeof globin gene for the identification of definitive erythrocytesduring human embryogenesis and primate ESC differentiation.^{4,25,29,30,34}In our experiments, VE-cadherin⁺CD45^– cells initiallyproduced larger, nucleated erythrocytes almost with no ß-globinexpression and later generated smaller, partly enucleated, erythrocytesexpressing ß-globin (Figures 2C-D, P, 3). This resultis morphologically supported by the finding that human ESC-derivederythroblasts devoid of ß-globin expression are megaloblasticand similar to primitive erythroid cells found in 4- to 5-week-oldhuman embryos.⁴⁴ On the other hand, our results showed thatthe high proportion of ß-globin⁺ cells on day 10 +30 also expressed embryonic globins ( ${epsilon}$ and ${zeta}$ ). This is consistentwith previous reports that the embryonic globins and ß-globinare expressed in early definitive hematopoietic cells.^29,30Hence, VE-cadherin⁺CD45^– endothelial cells isolated onday 10 generated primitive and definitive erythrocytes sequentially.
Clonal analysis disclosed that 1.1% of the single VE-cadherin⁺CD45^–cells yielded endothelial and hematopoietic cells (Figure S1).Our results are in agreement with previous data,⁴⁵ and the characteristicsof endothelial cells isolated by both groups are similar. Giventhat VE-cadherin^–CD45^– cells almost never generatedendothelial colonies, even under endothelial culture conditions(Figure 2R), we suggest that bipotential cells among the VE-cadherin⁺CD45^–population are not the contaminating cells during cell sorting.
${alpha}$ 4-Integrin is a marker of the hemogenic endothelial cells in primates
The differences between hemogenic and nonhemogenic endothelialcells and how a subset of endothelial cells acquires hemogeniccapacity during early embryogenesis in primates remain unclear.Here, we used ${alpha}$ 4-integrin as a candidate marker of hemogenicendothelial cells. To our knowledge, there are no reports onthe expression or function of ${alpha}$ 4-integrin during early primateembryogenesis. Developmentally, in mice, ${alpha}$ 4-integrin is expressedon yolk sac blood islands and all hematopoietic cells in thefetal liver.^52,53 It is essential for the maintenance of efficientdevelopment of multilineage progenitors in the fetal liver⁵⁴and is a marker of the earliest precursor of the hematopoieticcell lineage from endothelial progenitors in vivo and in vitro.²⁶We show that the ${alpha}$ 4-integrin⁺, not the ${alpha}$ 4-integrin^– subpopulationamong ESC-derived endothelial cells, yields hematopoietic cells.Except for the generation of primitive hematopoiesis, this isconsistent with previous findings in mice.²⁶ In our study, ${alpha}$ 4-integrin⁺h