Abstract
The earliest blood vessels in mammalian embryos are formed when endothelial cells differentiate from angioblasts and coalesce into tubular networks. Thereafter, the endothelium is thought to expand solely by proliferation of pre-existing endothelial cells. Here we show that a complementary source of endothelial cells is recruited into pre-existing vasculature after differentiation from the earliest precursors of erythrocytes, megakaryocytes and macrophages, the erythro-myeloid progenitors (EMPs) that are born in the yolk sac. A first wave of EMPs contributes endothelial cells to the yolk sac endothelium, and a second wave of EMPs colonizes the embryo and contributes endothelial cells to intraembryonic endothelium in multiple organs, where they persist into adulthood. By demonstrating that EMPs constitute a hitherto unrecognized source of endothelial cells, we reveal that embryonic blood vascular endothelium expands in a dual mechanism that involves both the proliferation of pre-existing endothelial cells and the incorporation of endothelial cells derived from haematopoietic precursors.
Similar content being viewed by others
Main
Blood vessels distribute oxygen, nutrients, hormones and immune cells through the vertebrate body and help to remove waste molecules. Accordingly, the formation of functional blood vessels during embryogenesis is a prerequisite for vertebrate life. Endothelial cells (ECs) form the inner lining of blood vessels; they first arise from mesenchymal precursors termed angioblasts on embryonic day (E)7.0 in mice1. After condensing into the yolk sac vasculature and paired dorsal aortae, ECs proliferate within existing endothelium to increase vascular diameter, sprout into avascular tissue areas or remodel into smaller vessels by intussusceptive growth1. The current consensus is therefore that embryonic ECs are a self-contained cell lineage that expands without contribution from new angioblasts or circulating precursors. By contrast, circulating endothelial progenitors have been proposed to exist in adult vertebrates, although their relationship to myeloid cells remains controversial2.
In addition to their primary roles in the innate immune system, myeloid cells such as monocytes and macrophages also modulate vascular growth3. For example, the tissue-resident macrophages of the embryonic mouse brain, termed microglia, contact ECs at the tips of neighbouring vessel sprouts to promote their anastomosis into perfused vessel loops4. By contrast, no direct contribution of myeloid cells to embryonic vascular endothelium has been reported; thus, genetic lineage tracing with myeloid Vav or Lyz2 (also known as Lysm) promoters does not mark embryonic blood vascular endothelium in mice5,6.
Most tissue-resident macrophages arise from EMPs that form in the extra-embryonic yolk sac during embryogenesis and also serve as precursors for erythrocytes and megakaryocytes7,8,9,10,−11. In mice, an early wave of EMPs, also referred to as primitive haematopoietic progenitors, buds from the yolk sac endothelium between E7.0 and E8.25 and differentiates by E9.0 without monocytic intermediates into yolk sac macrophages7,10,12,13,−14. These macrophages colonize the embryo proper to generate tissue-resident macrophages, such as microglia in the brain or Langerhans cells in the epidermis13. A later wave of EMPs buds from the yolk sac endothelium from E8.25 onwards and colonizes the liver after the embryonic circulation has been established7,8,11,14,15. These later-born EMPs expand in the liver into monocytes that subsequently differentiate into tissue-resident macrophages in many organs except the brain7,13.
Csf1r lineage tracing identifies an EC subset
To target early EMPs7,10,12, microglia16,17 and other differentiated myeloid cells18, we and others have used a transgene that expresses CRE recombinase under the promoter for the myeloid lineage gene Csf1r (also known as Fms), which encodes the colony-stimulating factor 1 receptor CSF1R. Microglia appear as single YFP+ cells in hindbrains from Csf1r-iCre mouse embryos carrying the RosaYfp recombination reporter, with microglia and ECs also stained for isolectin B4 (IB4)16 (Fig. 1a). As previously shown4, the number of IB4+YFP+ microglia peaked in the hindbrain subventricular zone at E11.5, when vessels fuse into the subventricular vascular plexus (SVP) (Fig. 1b). Unexpectedly, we also observed sporadic, elongated IB4+YFP+ cells that appeared bound into the endothelium and increased steadily in number during SVP expansion (Fig. 1a–c; Extended Data Fig. 1a). Csf1r-iCre targeting of vessel-bound cells was not an artefact caused by spontaneous RosaYfp recombination or unspecific immunostaining, because littermates that did not carry Csf1r-iCre lacked YFP staining (Fig. 1a). Furthermore, hindbrain imaging from mice carrying Csf1r-iCre with CAG-Cat-Egfp or RosatdTom as alternative recombination reporters confirmed targeting of both microglia and vessel-bound elongated cells (Extended Data Fig. 1b, c). The tamoxifen-induced activation of CRE, expressed from an independently generated Csf1r-Mer-iCre-Mer transgene that targets myeloid cells19, also targeted vessel-bound cells in addition to microglia (Fig. 1d). Corroborating the endothelial identity of Csf1r-iCre-targeted, elongated vessel-bound cells, these cells expressed the EC markers ERG and PECAM1, had a similar morphology to ECs targeted with the endothelium-specific Cdh5-CreERT2 transgene, formed junctions with neighbouring ECs via the endothelial cadherin CDH5 and lacked both myeloid and pericyte markers (Fig. 1e, Extended Data Fig. 1d–f).
Csf1r-iCre-mediated EC targeting was not explained by Csf1r expression in brain ECs, because hindbrain ECs, unlike microglia, lacked expression of a Csf1r-Egfp transgene that faithfully reports Csf1r promoter activity20,21 and accordingly did not contain CSF1R protein (Extended Data Fig. 2a, b). Moreover, our analysis of published transcriptomic datasets22 showed that Csf1r is not expressed in ECs from embryonic brain, liver or lung, whilst quantitative PCR with reverse transcription (RT–qPCR) analysis of tdTomato+ ECs isolated by fluorescence-activated cell sorting (FACS) confirmed that they expressed Cdh5, but not Csf1r or the myeloid gene Spi1, which encodes the PU.1 transcription factor (Extended Data Fig. 2c–g). The lack of endothelial Csf1r expression suggests that Csf1r-iCre-targeted brain ECs arise from precursors in which Csf1r is activated before their incorporation into hindbrain vasculature. These precursors cannot be differentiated myeloid cells such as microglia, whose formation is PU.1-dependent4, because PU.1 deficiency did not reduce the number of Csf1r-iCre-targeted ECs in the hindbrain at E11.5 (Fig. 1f–h) or the striatum at postnatal day (P)0 (Extended Data Fig. 2h). We therefore investigated whether Csf1r-iCre-targeted ECs are derived from PU.1-independent, Csf1r-expressing precursors.
Csf1r lineage-traced ECs derive from EMPs
As EMPs are PU.1-independent23, we investigated whether the formation of Csf1r-iCre-targeted ECs was spatiotemporally linked to the emergence of Csf1r-expressing EMPs from yolk sac haemogenic endothelium, which was visualized by staining for the EC marker VEGFR2. At E8.5, yolk sacs from Csf1r-Egfp embryos contained clusters of round EGFP+VEGFR2+ cells that protruded from the endothelium into the vascular lumen (Fig. 2a), consistent with previous work showing that FACS-isolated EMPs express both Csf1r7 and Vegfr29, and that EMPs bud from the yolk sac endothelium11. Csf1r-iCre lineage tracing in yolk sacs at E8.5 similarly identified round YFP+ cells that protruded into the vascular lumen, expressed VEGFR2, persisted in PU.1-deficient yolk sacs and expressed the EMP marker KIT7 (Fig. 2b, c; Extended Data Fig. 3a, b). Even though EGFP expression could not be detected in Csf1r-Egfp yolk sac endothelium (Fig. 2a), Csf1r-iCre;RosaYfp also targeted a subset of yolk sac ECs that lacked obvious KIT expression (Extended Data Fig. 3b), showing that they were not haemogenic ECs24. Similar to Csf1r-iCre-targeted hindbrain ECs, the lineage-traced yolk sac ECs were PU.1-independent (Fig. 2b, c).
The finding that EMP formation correlates with the emergence of Csf1r-iCre-targeted yolk sac ECs was corroborated by temporally restricted Csf1r-Mer-iCre-Mer-mediated lineage tracing. As tamoxifen-induced, CRE-mediated reporter recombination peaks approximately 6 h and ends 24 h after tamoxifen injection25, we activated Csf1r-Mer-iCre-Mer;RosatdTom in discrete temporal windows by single injections at E8.5, E9.5 or E10.5 before identifying lineage-traced cells in E12.5 yolk sacs (Extended Data Fig. 3c). Induction at all three stages labelled yolk sac macrophages (Extended Data Fig. 3d), consistent with their origin from Csf1r-expressing EMPs7 and their maintenance of Csf1r expression10,12. In addition, induction at E8.5 or E9.5 yielded tdTomato+ ECs, whereas induction at E10.5 did not (Extended Data Fig. 3d). As EMPs are present in the yolk sac at E8.5 and E9.5, but move to the liver thereafter13, their local availability makes them plausible precursors of Csf1r-iCre-labelled yolk sac ECs. Consistent with this, tamoxifen induction of a KitCreERT2 knock-in allele at E8.5, when KIT+ early EMPs are still present in the yolk sac7, lineage-traced both yolk sac ECs and macrophages (Extended Data Fig. 3e, f).
In contrast to early wave EMPs that remain in the yolk sac, the late wave EMPs that populate the embryo are reported to lack Csf1r expression, at least when they form in the yolk sac7. We therefore investigated whether late wave EMPs begin to express Csf1r after homing to the liver and whether they are the precursors of the Csf1r-iCre-targeted ECs that appear in the hindbrain from E10.5 onwards. Thus, we combined the Csf1r-Egfp expression reporter with Csf1r-Mer-iCre-Mer;RosatdTom and induced CRE-mediated recombination at E10.5; 24 h later, we used FACS to separate the differentiated myeloid cells from EMPs and EMP-derived myeloid progenitors7 contained in the liver or blood (Fig. 3a, b). The differentiated myeloid cell populations from both sources contained tdTomato+EGFP+ cells, as expected, but tdTomato+EGFP+ cells were also present in the EMP/myeloid progenitor populations from both liver and blood (Fig. 3a, b; Extended Data Fig. 3g–i). These findings suggest that a subset of intraembryonic EMPs expresses Csf1r and can access organs such as the hindbrain via the circulation.
To determine whether the intraembryonic presence of Csf1r-expressing late wave EMPs correlated with the emergence of Csf1r-iCre-targeted hindbrain ECs, we visualized tdTomato expression in hindbrains from E12.5 Csf1r-Mer-iCre-Mer;RosatdTom mice after tamoxifen induction at E8.5, E9.5 or E10.5 (Fig. 3c). The hindbrain vasculature contained tdTomato+ ECs following induction at E10.5, but not at E8.5 or E9.5, even though the Csf1r-expressing microglia were targeted at all stages (Fig. 3d). KitCreERT2 induction at E8.5 also caused microglia targeting (Fig. 3e, f), consistent with microglia arising from yolk sac macrophages generated at around E8.5 from KIT+ early wave EMPs7. Induction of KitCreERT2 at E8.5, when late wave EMPs begin to arise in the yolk sac7, also yielded tdTomato+ ECs in the hindbrain at E12.5 (Fig. 3e, f), confirming that yolk sac-born EMPs can give rise to intraembryonic ECs. Lineage tracing from three independent Cre alleles therefore suggests that EMPs give rise to both yolk sac and hindbrain ECs.
Csf1r-expressing EMPs give rise to ECs in vitro
The myeloid and erythroid potential of EMPs has been demonstrated through in vitro differentiation11,26. Using similar assays, we compared the endothelial potential of FACS-isolated differentiated myeloid cell and EMP/myeloid progenitor populations from E12.5 Csf1r-iCre;RosatdTom liver and blood, while ensuring that we were excluding contamination by PECAM1+ ECs (Fig. 4a, b). Both cell populations were mostly tdTomato+ (Fig. 4c, d). As expected7, the EMP-containing population comprised round cells with a large nucleus and little cytoplasm, whereas the myeloid cell population contained granulocytes, in addition to monocytes in the liver and macrophages in the blood (Fig. 4c, d). For cell culture, we used methocult to promote the formation of haematopoietic colonies, but included a fibronectin substrate to facilitate EC differentiation. Differentiated myeloid cells persisted in these cultures as single round or amoeboid cells (Fig. 4e, f) that were tdTomato+ERGlowVEGFR2low (Fig. 4g, h; antibody controls in Extended Data Fig. 4a, b). By contrast, both liver and blood EMPs formed myeloid and erythroid cell colonies in suspension (Fig. 4e, f) and additionally gave rise to single adherent cells that appeared spindle-shaped, were tdTomato+ERGhighVEGFR2high and lacked myeloid cell markers, consistent with an EC identity (Fig. 4g, h; Extended Data Fig. 4c). Together, these experiments demonstrate that EMPs have endothelial potential alongside their known haematopoietic capacity.
Csf1r lineage ECs support blood vessel growth
Hoxa cluster genes modulate haematopoiesis27 and are upregulated in perinatal ECs compared to adult ECs28 (Fig. 5a); HOXA9 also promotes EC differentiation from progenitors in ischaemic disease in adults29. Our analysis of published transcriptomic data9,30 revealed that Hoxa transcripts are enriched in E10.25 EMPs compared to E9.0 EMPs and macrophages (Fig. 5a). To investigate whether Hoxa deficiency impairs the formation of EMP-derived hindbrain ECs, we combined Csf1r-iCre with a conditional null Hoxa cluster mutation (Hoxafl) (Extended Data Fig. 5a). Gene copy analysis showed effective gene targeting in KIT+ cells from Csf1r-iCre;Hoxafl/fl mutants at E12.5 compared to control livers, but the number of liver CD45+ cells, including differentiated myeloid cells, was not reduced (Extended Data Fig. 5b–f). Hoxa genes are therefore dispensable for myeloid cell specification from late wave EMPs. By contrast, fewer tdTomato+ ECs, also derived from late wave EMPs, had formed in RosatdTom-carrying Csf1r-iCre;Hoxafl/fl mutant hindbrains compared to control hindbrains; moreover, SVP complexity was reduced in mutant hindbrains (Fig. 5b–d). Although we observed 20% fewer microglia in mutant hindbrains than in control hindbrains (Extended Data Fig. 5g–i), this is not likely to have contributed to the vascular defect, because even a 50% microglia reduction in Csf1op/+ mutants did not reduce SVP complexity (Extended Data Fig. 5j–l). Together, these findings suggest that Hoxa cluster genes promote the formation of EMP-derived brain ECs, which in turn support normal brain vascular development.
Transcriptional signature of Csf1r lineage ECs
Csf1r-iCre-targeted ECs not only appeared morphologically similar to neighbouring ECs (Fig. 1), but also had similarly slow proliferation and overall cell cycle kinetics (Extended Data Fig. 6). Moreover, RNA sequencing (RNA-seq) analysis of FACS-isolated tdTomato+ and tdTomato− ECs from E12.5 Csf1r-iCre;RosatdTom embryos showed that they had largely similar transcriptomes, with only a few differentially expressed genes, including the expected difference in the tdTomato transcript (Fig. 6a–c; Extended Data Fig. 7a). Corroborating their endothelial identity, tdTomato+ ECs lacked markers for differentiated myeloid cells and other non-EC lineages, but expressed core EC transcripts at similar levels to tdTomato− ECs (Fig. 6d, e). Amongst the differentially expressed genes, markers typical of EC specialization, such as ephrins and EPH receptors regulating arteriovenous differentiation, were under-represented in tdTomato+ ECs (Fig. 6e). This observation is consistent with Csf1r-iCre-targeted ECs being derived from progenitors that are recruited into preformed vascular endothelium. Whereas brain EC markers (for example, Slc2a1) were under-represented in the embryo-wide tdTomato+ EC population, liver EC markers (for example, Oit3, Mrc1) were over-represented, including early markers of liver sinusoidal differentiation (Stab2, Lyve1)31 (Fig. 6c, f; Extended Data Fig. 7b, c). Similar expression of Oit3 and Mrc1 in tdTomato+ and tdTomato− liver ECs (Extended Data Fig. 7d) suggests that the over-representation of liver EC transcripts in the total embryonic tdTomato+ EC population reflects their preferential contribution to liver vasculature. Immunostaining and FACS of Csf1r-iCre;RosatdTom E12.5 and E18.5 embryos confirmed that tdTomato+ ECs were more prevalent than tdTomato− ECs in liver endothelium (Fig. 6g, i; Extended Data Figs. 8, 9a, b). As liver EC specialization markers were present in both tdTomato− and tdTomato+ liver ECs at E12.5 (Fig. 6g; Extended Data Fig. 8a), liver ECs from two distinct origins appear to undergo similar organ-specific EC differentiation.
Csf1r lineage ECs persist in multiple adult organs
Immunostaining and FACS analyses at E12.5 and E18.5 showed that Csf1r-iCre-targeted ECs were also present in the heart and lung vasculature at similar levels to the brain (Fig. 6i; Extended Data Figs. 8, 9a, b). Corresponding immunostaining and FACS analyses showed that tdTomato+ ECs persisted in the brain, heart, lung and liver of adults and continued to dominate the adult liver sinusoidal endothelium (Fig. 6h, j; Extended Data Figs. 9c, 10a). Accordingly, all adult organs examined contained EMP-derived ECs.
Discussion
The heterogeneous origin of blood vascular mural cells from distinct populations of mesodermal progenitors, haematopoietic and neural crest cells has been established32. Here we have shown that embryonic vascular endothelium has two major origins. Thus, ECs emerge via a classical pathway of angioblast differentiation into ECs and the pathway described in this report, which entails differentiation of ECs from the EMP lineage (Extended Data Fig. 10b). Multiple previous investigations have used Csf1r-iCre together with recombination reporters to follow the embryonic myeloid lineage7,10,12. These studies predominantly used FACS with haematopoietic markers, which precluded observation of Csf1r-iCre-targeted ECs. By contrast, we included EC markers in FACS protocols to additionally isolate Csf1r-iCre-targeted ECs. In addition, immunostaining was previously used to identify Csf1r-iCre-targeted cells in the retina17, liver and colon18, but without description of EC targeting, possibly because of the close spatial proximity of ECs and perivascular macrophages4,33. We overcame this limitation by performing high-resolution imaging of tissues immunostained with both EC and myeloid cell markers. The contribution of EMP-derived ECs to the yolk sac, brain, heart and lung vasculature is proportionally smaller than that of ECs of classical origin, whereas EMP-derived ECs predominate in the liver, particularly the sinusoidal endothelium. Liver endothelium was previously reported to be heterogeneous in origin, with an endoderm lineage contribution of approximately 15% and the remainder of the liver EC population attributed to a venous origin34. Our results suggest that liver endothelium contains approximately 60% EMP-derived ECs. Preferential homing of EMPs to the liver after their entry into the embryonic circulation13, and the dependence of liver growth on rapid vascular expansion35, may explain the relatively large contribution of EMP-derived ECs to this organ. Ultimately, the discovery that EMPs provide a source of ECs for organ vasculature may open up new therapeutic avenues for vessel-dependent organ repair and regeneration. For example, EMPs or EMP-like EC progenitors, derived from human stem cells by modulating the expression of factors such as Hoxa genes, might be delivered systemically to support vascular growth in ischaemic diseases or to provide angiocrine signals that stimulate tissue stem cells.
Methods
Mouse strains
All animal procedures were performed in accordance with the institutional Animal Welfare Ethical Review Body (AWERB) and UK Home Office guidelines. To obtain mouse embryos of defined gestational age, mice were paired in the evening and the presence of a vaginal plug the following morning was defined as E0.5. In some studies, we analysed adult mice, defined as more than eight weeks of age. Mice carrying the Csf1r-iCre transgene18 were mated to mice carrying the Cre recombination reporters RosaYfp (ref. 36), RosatdTom (ref. 37) or CAG-cat-Egfp (ref. 38). PU.1+/− mice39 were mated to RosaYfp mice and then Csf1r-iCre mice to obtain Csf1r-iCre;RosaYfp;Pu.1−/− embryos that lacked differentiated myeloid cells including microglia4,39,40 as well as the myeloid cell precursors of skin pericytes41. Hoxafl/fl mice42 were mated to RosatdTom mice and then Csf1r-iCre mice to obtain Csf1r-iCre;RosatdTom;Hoxafl/fl embryos. Csf1r-Mer-iCre-Mer (ref. 19) and KitCreERT2 (ref. 43) as well as endothelial-specific Cdh5-CreERT2 (refs 41,44) mice were mated to RosatdTom mice. In some experiments, mice carrying the Csf1r-Egfp-Ngfr/Fkbp1a/Tnfrsf6 (short: Csf1r-Egfp) reporter of Csf1r expression21 were mated to Csf1r-Mer-iCre-Mer;RosatdTom mice. We also used mice with a heterozygous loss of function mutation in Csf1 (Csf1+/op)45. All mouse strains were maintained on a mixed background (C57Bl6/J;129/Sv), with the exception of Csf1r-Mer-iCre-Mer, which was maintained on a mixed FVB:C57/Bl6 background. For tamoxifen induction of CRE activity, tamoxifen (Sigma) was dissolved in peanut oil and administered via a single intraperitoneal injection into each pregnant dam. For Csf1r-Mer-iCre-Mer induction, we injected 1 mg tamoxifen; to achieve mosaic Cdh5-Cre-ERT2 activation, we injected 20 μg tamoxifen; for KitCreERT2 induction at E8.5, we injected 3 mg tamoxifen together with 1.75 mg progesterone to increase induction without inducing abortions (Sigma).
Immunolabelling
Samples were fixed in 4% formaldehyde in PBS and processed as whole-mounts or dehydrated in sucrose and embedded in optimal cutting temperature (OCT, Tissue-Tek) compound to cut 20-µm cryosections. Immunolabelling was performed as described previously for whole-mount hindbrains46. We used the following antibodies and dilutions: goat anti-CDH5 (1:200; AF1002, lot FQI0116101, R&D Systems), rabbit anti-CSF1R (1:500; sc-692, lot K1212, Santa Cruz), rat anti-EMCN (1:50; sc-65495, lot C2917, Santa Cruz), rabbit anti-ERG (1:200; ab92513, lot GR32027 69-1, Abcam), rat anti-F4/80 (1:500; MCA497R, lot 1605, Serotec), chicken anti-GFP (1:1,000; GFP-1020, lot 0511FP12, Aves) and rabbit anti-GFP (1:500; 598, lot 079, MBL) for YFP or EGFP labelling, rabbit anti-IBA1 (1:500; 019-19741, Wako Chemicals), rat anti-KIT (1:500; 553353, lot 30259, BD Pharmingen), rabbit anti-NG2 (1:200; AB5320, lot 2726769, Millipore), rat anti-PECAM1 (1:200; 553370, lot 5205656, BD Pharmingen), rabbit anti-pHH3 (1:400; 06-570, lot 2825969, Millipore), rabbit anti-RFP (1:1,000; PM005, lot 045, MBL), goat anti-VEGFR2 (1:200; AF644, lot COA0417021, R&D Systems). Secondary antibodies used included Alexa Fluor-conjugated goat anti-chick, -rabbit or -rat IgG (Life Technologies), or, for primary antibodies raised in goat, donkey fluorophore-conjugated FAB fragments of anti-chick, -goat, -rabbit or -rat IgG (Jackson ImmunoResearch). Note that CDH547, ERG48, EMCN49, PECAM150 and VEGFR251 were used as EC markers, whereas F4/8052 and IBA153 were used as macrophage markers and NG254 as a pericyte marker. Biotinylated IB4 (L2140, lot 085M4032V, Sigma) followed by Alexa-conjugated streptavidin (ThermoFisher) was also used to detect brain ECs and microglia4,16. Nuclei were labelled with DAPI. Images were acquired with a LSM710 laser scanning confocal microscope (Zeiss) and processed using LSM image browser (Zeiss) and Photoshop CS4 (Adobe) software. Three-dimensional reconstructions including surface rendering and the generation of virtual slices for lateral views of high-resolution confocal z-stacks was performed using Imaris (Bitplane). Z-stack projections of confocal images are shown unless indicated otherwise in the figure legends.
FACS and cell culture
Tissues were mechanically and enzymatically homogenized in RPMI1640 with 2.5% fetal bovine serum (ThermoFisher), 100 µg/ml collagenase/dispase (Roche), 50 µg/ml DNase (Qiagen) and 100 µg/ml heparin (Sigma), incubated for 5 min with 0.5 mg/ml rat Fc block (Becton Dickinson) and labelled with a combination of PE/Cy7-conjugated rat anti-PECAM1 (clone 390, cat 102418, lot B212262), FITC-conjugated rat anti-CD45 (clone 30-F11, cat 103108, lot B246762) or CD41 (clone MWReg30, cat 133903, lot B201955), APC-conjugated rat anti-KIT (clone 2B8, cat 105812, lot B217855) and PerCp/Cy5.5-conjugated rat anti-CD11b (clone M1/70, cat 101227) (all BioLegend). Appropriate fluorescence gating parameters were established with unstained tissue, Csf1r-iCre- or Csf1r-Egfp-negative tissues and fluorescence-minus-one (FMO) staining. For cell cycle analysis, cell populations were incubated with 10 µg/ml Hoechst 33342 (Sigma) for 30 min at 37 °C55 before labelling with PE/Cy7-conjugated rat anti-PECAM1 and performing FACS analysis. In all experiments, doublets were eliminated using pulse geometry gates (FSC-H versus FSC-A and SSC-H versus SSC-A), whereas dead cells were removed using SYTOX Blue (Life Technologies) or LIVE/DEAD Fixable Violet (Life Technologies). Single-cell suspensions were analysed using the BD LSRFortessa X-20 cell analyser or sorted using the BD Influx cell sorter (BD Biosciences); FlowJo software (FlowJo LLC) was used for subsequent analyses. In some experiments, a fraction of each population was cytospun onto a glass slide for Wright–Giemsa staining (Sigma) followed by imaging using an LSM510 microscope equipped with an AxioCam MRc camera (Zeiss). For cell culture experiments, cell populations were sorted into DMEM with 100 U/ml penicillin, 100 U/ml streptomycin and 20% fetal bovine serum (all ThermoFisher) before seeding the cells into a 96-well plate coated with 10 µg/ml fibronectin (ThermoFisher) to facilitate EC differentiation. Cells were then cultured in methocult (STEMCELL Technologies) to promote the formation of haematopoietic colonies, which were imaged using a TS100 microscope equipped with a DS-5M colour camera (Nikon). After removal of methocult, adherent cells were fixed with 4% formaldehyde in PBS and then labelled for VEGFR2, ERG, CD45, F4/80 and CSF1R (see above) before imaging using a Ti-E microscope (Nikon).
RNA-seq
PECAM1+CD45−CD11b−KIT− ECs were isolated from E12.5 Csf1r-iCre;RosatdTom embryos and divided into tdTomato+ and tdTomato− populations with the BD Influx cell sorter before RNA was extracted with the RNeasy Micro Kit (QIAGEN). cDNA was generated and amplified using the SMART-seq V4 ultra low input RNA kit (Clontech). 100 pg of amplified cDNA per sample was used to prepare a library with the Nextera XT kit (Illumina) and run on the NextSeq 500 sequencer (lllumina). Raw sequence data were pre-processed to trim poor quality base calls and adaptor contamination using Trimmomatic v.0.36.456 and aligned to the mouse mm10 genome with STAR v.2.5.2b57. Mapped reads were deduplicated to reduce PCR bias using Picard v2.7.1.1 software (http://broadinstitute.github.io/picard/), and the reads-per-transcript were then calculated using FeatureCount v1.4.6.p5 software58. Differential expression was performed using the BioConductor package DESeq2 via the SARTools wrapper v1.3.2.059.
RT–PCR
We extracted RNA from cells isolated with the BD Influx cell sorter (see above) with the RNeasy Micro Kit for cDNA synthesis with Superscript IV (ThermoFisher). Quantitative (q)RT–PCR was performed with SYBR Green on an HT7900 system (Applied Biosystems) using the following oligonucleotide pairs: Actb 5′-CACCACACCTTCTACAATGAG-3′ and 5′-GTCTCAAACATGATCTGGGTC-3′; Cdh5 5′-GATGCAGATGACCCCACTGT-3′ and 5′-AGGGCATCTTGTGTTCCAC-3′; Csf1r 5′-TGCGTCTACACAGTTCAGAG-3′ and 5′-ATGCTGTATATGTTCTTCGGT-3′; Spi1 5′-GCCATAGCGATCACTACTG-3′ and 5′-CAAGGTTTGATAAGGGAAGC-3′; Hoxa11 5′-TCTTTGCCTCTCTCCTTCCTT-3′ and 5′-TTGCAGACGCTTCTCTTTGTT-3′; Evx1 5′-GTGTGCTCTGGGCTCCTGT-3′ and 5′-GCCAGGGTGCCTTGAGAG-3; Slc2a1 5′-CCCCAGAAGGTTATTGAGGAGT and 5′-ACAAAGAGGCCGACAGAGAA; Mrc1 5′-ACTGGGCAATGCAAATGGAG and 5′- CCCTCAAAGTGCAATGGACA; Oit3 5′-CGTCTGCTTCCATGTCTACTG and 5′-GTGCTCACATTCATTTTCGTCA. For each oligonucleotide pair, a no-template control reaction was included.
Microarray analysis
Published microarray data were used to compare gene expression levels (normalized log2 OD) in E14.5 CD45−PECAM1+ brain versus pooled lung and liver ECs (GSE35802)22 and in HUVECs versus adult retinal ECs (GSE20986)30 using GEO2R software (NCBI).
Statistical analysis
No randomization method was used, because tissues for analysis were allocated to experimental groups according to genotype, gestational age, organ or cell type. To ensure unbiased interpretation of results, the genotype and gestational age were disclosed only after data collection was complete, but the investigators were not blinded to sample origin (organ or cell type). All experiments involving two or more genotypes for comparison included littermate controls, and the minimum sample number was three. No statistical methods were used to predetermine sample size. The number of YFP+ ECs and YFP+ microglia in Csf1r-iCre;RosaYfp hindbrains (Fig. 1a, b, f–h) was determined in three randomly chosen 0.72-mm2 regions of each whole-mount labelled and flat-mounted hindbrain. For hindbrains in Hoxa-targeting experiments, the number of F4/80+ microglia (Extended Data Fig. 5) and tdTomato+ and IB4+ volume (Fig. 5b, c) were determined from confocal z-stacks of four randomly chosen 0.18-mm2 regions on the lateral side of each hindbrain (Extended Data Fig. 5g). The z-stacks were surface rendered with Imaris (Bitplane) to obtain the F4/80+, tdTomato+ and IB4+ volumes, and the F4/80+ volume was then subtracted from both the IB4+ and tdTomato+ total volumes to obtain the IB4+ EC and tdTomato+ EC volumes before calculating the ratio of tdTomato+ to IB4+ EC volume. To determine the number of vascular intersections in Hoxa-targeting experiments (Fig. 5b,d), the same confocal z-stacks were analysed with Imaris filament tracer after F4/80+ microglia were masked. For Figs. 1, 5, all counts obtained from one hindbrain were averaged to yield the value for that hindbrain. For all experiments, we calculated the mean value for at least three independent samples, where error bars represent the standard deviation of the mean (for details, see legends). Comparison of medians against means justified the use of a parametric test; to determine whether two datasets were significantly different, we therefore calculated P values with a two-tailed unpaired Student’s t-test; P < 0.05 was considered significant. When more than two datasets were compared, we used the statistical tests indicated in the associated legends. Statistical analyses were performed with Excel 12.2.6 (Microsoft Office) or Prism 7 (GraphPad Software).
Reporting summary
Further information on experimental design is available in the Nature Research Reporting Summary linked to this paper.
Data availability
All sequence data used in this study have been deposited in the NCBI Gene Expression Omnibus database (accession number GSE117978) and are listed in the Source Data for Fig. 6.
References
Potente, M., Gerhardt, H. & Carmeliet, P. Basic and therapeutic aspects of angiogenesis. Cell 146, 873–887 (2011).
Hirschi, K. K., Ingram, D. A. & Yoder, M. C. Assessing identity, phenotype, and fate of endothelial progenitor cells. Arterioscler. Thromb. Vasc. Biol. 28, 1584–1595 (2008).
Pollard, J. W. Trophic macrophages in development and disease. Nat. Rev. Immunol. 9, 259–270 (2009).
Fantin, A. et al. Tissue macrophages act as cellular chaperones for vascular anastomosis downstream of VEGF-mediated endothelial tip cell induction. Blood 116, 829–840 (2010).
Clausen, B. E., Burkhardt, C., Reith, W., Renkawitz, R. & Förster, I. Conditional gene targeting in macrophages and granulocytes using LysMcre mice. Transgenic Res. 8, 265–277 (1999).
de Boer, J. et al. Transgenic mice with hematopoietic and lymphoid specific expression of Cre. Eur. J. Immunol. 33, 314–325 (2003).
Hoeffel, G. et al. C-Myb+ erythro-myeloid progenitor-derived fetal monocytes give rise to adult tissue-resident macrophages. Immunity 42, 665–678 (2015).
Frame, J. M., McGrath, K. E. & Palis, J. Erythro-myeloid progenitors: “definitive” hematopoiesis in the conceptus prior to the emergence of hematopoietic stem cells. Blood Cells Mol. Dis. 51, 220–225 (2013).
Mass, E. et al. Specification of tissue-resident macrophages during organogenesis. Science 353, aaf4238 (2016).
Gomez Perdiguero, E. et al. Tissue-resident macrophages originate from yolk-sac-derived erythro-myeloid progenitors. Nature 518, 547–551 (2015).
McGrath, K. E. et al. Distinct sources of hematopoietic progenitors emerge before HSCs and provide functional blood cells in the mammalian embryo. Cell Rep. 11, 1892–1904 (2015).
Schulz, C. et al. A lineage of myeloid cells independent of Myb and hematopoietic stem cells. Science 336, 86–90 (2012).
Ginhoux, F. & Guilliams, M. Tissue-resident macrophage ontogeny and homeostasis. Immunity 44, 439–449 (2016).
Hoeffel, G. & Ginhoux, F. Fetal monocytes and the origins of tissue-resident macrophages. Cell. Immunol. 330, 5–15 (2018).
Lux, C. T. et al. All primitive and definitive hematopoietic progenitor cells emerging before E10 in the mouse embryo are products of the yolk sac. Blood 111, 3435–3438 (2008).
Fantin, A. et al. NRP1 acts cell autonomously in endothelium to promote tip cell function during sprouting angiogenesis. Blood 121, 2352–2362 (2013).
Stefater, J. A., III et al. Regulation of angiogenesis by a non-canonical Wnt–Flt1 pathway in myeloid cells. Nature 474, 511–515 (2011).
Deng, L. et al. A novel mouse model of inflammatory bowel disease links mammalian target of rapamycin-dependent hyperproliferation of colonic epithelium to inflammation-associated tumorigenesis. Am. J. Pathol. 176, 952–967 (2010).
Qian, B. Z. et al. CCL2 recruits inflammatory monocytes to facilitate breast-tumour metastasis. Nature 475, 222–225 (2011).
Sasmono, R. T. et al. A macrophage colony-stimulating factor receptor-green fluorescent protein transgene is expressed throughout the mononuclear phagocyte system of the mouse. Blood 101, 1155–1163 (2003).
Burnett, S. H. et al. Conditional macrophage ablation in transgenic mice expressing a Fas-based suicide gene. J. Leukoc. Biol. 75, 612–623 (2004).
Tam, S. J. et al. Death receptors DR6 and TROY regulate brain vascular development. Dev. Cell 22, 403–417 (2012).
Kierdorf, K. et al. Microglia emerge from erythromyeloid precursors via Pu.1- and Irf8-dependent pathways. Nat. Neurosci. 16, 273–280 (2013).
Goldie, L. C., Lucitti, J. L., Dickinson, M. E. & Hirschi, K. K. Cell signaling directing the formation and function of hemogenic endothelium during murine embryogenesis. Blood 112, 3194–3204 (2008).
Wilson, C. H. et al. The kinetics of ER fusion protein activation in vivo. Oncogene 33, 4877–4880 (2014).
Palis, J., Robertson, S., Kennedy, M., Wall, C. & Keller, G. Development of erythroid and myeloid progenitors in the yolk sac and embryo proper of the mouse. Development 126, 5073–5084 (1999).
Alharbi, R. A., Pettengell, R., Pandha, H. S. & Morgan, R. The role of HOX genes in normal hematopoiesis and acute leukemia. Leukemia 27, 1000–1008 (2013).
Toshner, M. et al. Transcript analysis reveals a specific HOX signature associated with positional identity of human endothelial cells. PLoS ONE 9, e91334 (2014).
Rössig, L. et al. Histone deacetylase activity is essential for the expression of HoxA9 and for endothelial commitment of progenitor cells. J. Exp. Med. 201, 1825–1835 (2005).
Browning, A. C. et al. Comparative gene expression profiling of human umbilical vein endothelial cells and ocular vascular endothelial cells. Br. J. Ophthalmol. 96, 128–132 (2012).
Nonaka, H., Tanaka, M., Suzuki, K. & Miyajima, A. Development of murine hepatic sinusoidal endothelial cells characterized by the expression of hyaluronan receptors. Dev. Dyn. 236, 2258–2267 (2007).
Majesky, M. W. Developmental basis of vascular smooth muscle diversity. Arterioscler. Thromb. Vasc. Biol. 27, 1248–1258 (2007).
Liu, C. et al. Macrophages mediate the repair of brain vascular rupture through direct physical adhesion and mechanical traction. Immunity 44, 1162–1176 (2016).
Goldman, O. et al. Endoderm generates endothelial cells during liver development. Stem Cell Reports 3, 556–565 (2014).
Matsumoto, K., Yoshitomi, H., Rossant, J. & Zaret, K. S. Liver organogenesis promoted by endothelial cells prior to vascular function. Science 294, 559–563 (2001).
Srinivas, S. et al. Cre reporter strains produced by targeted insertion of EYFP and ECFP into the ROSA26 locus. BMC Dev. Biol. 1, 4 (2001).
Madisen, L. et al. A robust and high-throughput Cre reporting and characterization system for the whole mouse brain. Nat. Neurosci. 13, 133–140 (2010).
Kawamoto, S. et al. A novel reporter mouse strain that expresses enhanced green fluorescent protein upon Cre-mediated recombination. FEBS Lett. 470, 263–268 (2000).
McKercher, S. R. et al. Targeted disruption of the PU.1 gene results in multiple hematopoietic abnormalities. EMBO J. 15, 5647–5658 (1996).
Scott, E. W., Simon, M. C., Anastasi, J. & Singh, H. Requirement of transcription factor PU.1 in the development of multiple hematopoietic lineages. Science 265, 1573–1577 (1994).
Yamazaki, T. et al. Tissue myeloid progenitors differentiate into pericytes through TGF-β signaling in developing skin vasculature. Cell Rep. 18, 2991–3004 (2017).
Kmita, M. et al. Early developmental arrest of mammalian limbs lacking HoxA/HoxD gene function. Nature 435, 1113–1116 (2005).
Klein, S. et al. Interstitial cells of Cajal integrate excitatory and inhibitory neurotransmission with intestinal slow-wave activity. Nat. Commun. 4, 1630 (2013).
Zarkada, G., Heinolainen, K., Makinen, T., Kubota, Y. & Alitalo, K. VEGFR3 does not sustain retinal angiogenesis without VEGFR2. Proc. Natl Acad. Sci. USA 112, 761–766 (2015).
Yoshida, H. et al. The murine mutation osteopetrosis is in the coding region of the macrophage colony stimulating factor gene. Nature 345, 442–444 (1990).
Fantin, A., Vieira, J. M., Plein, A., Maden, C. H. & Ruhrberg, C. The embryonic mouse hindbrain as a qualitative and quantitative model for studying the molecular and cellular mechanisms of angiogenesis. Nat. Protoc. 8, 418–429 (2013).
Gory-Fauré, S. et al. Role of vascular endothelial-cadherin in vascular morphogenesis. Development 126, 2093–2102 (1999).
McLaughlin, F., Ludbrook, V. J., Kola, I., Campbell, C. J. & Randi, A. M. Characterisation of the tumour necrosis factor (TNF)-(alpha) response elements in the human ICAM-2 promoter. J. Cell Sci. 112, 4695–4703 (1999).
Morgan, S. M., Samulowitz, U., Darley, L., Simmons, D. L. & Vestweber, D. Biochemical characterization and molecular cloning of a novel endothelial-specific sialomucin. Blood 93, 165–175 (1999).
Albelda, S. M., Muller, W. A., Buck, C. A. & Newman, P. J. Molecular and cellular properties of PECAM-1 (endoCAM/CD31): a novel vascular cell-cell adhesion molecule. J. Cell Biol. 114, 1059–1068 (1991).
Shalaby, F. et al. Failure of blood-island formation and vasculogenesis in Flk-1-deficient mice. Nature 376, 62–66 (1995).
Austyn, J. M. & Gordon, S. F4/80, a monoclonal antibody directed specifically against the mouse macrophage. Eur. J. Immunol. 11, 805–815 (1981).
Ohsawa, K., Imai, Y., Sasaki, Y. & Kohsaka, S. Microglia/macrophage-specific protein Iba1 binds to fimbrin and enhances its actin-bundling activity. J. Neurochem. 88, 844–856 (2004).
Ozerdem, U., Grako, K. A., Dahlin-Huppe, K., Monosov, E. & Stallcup, W. B. NG2 proteoglycan is expressed exclusively by mural cells during vascular morphogenesis. Dev. Dyn. 222, 218–227 (2001).
Goodell, M. A., Brose, K., Paradis, G., Conner, A. S. & Mulligan, R. C. Isolation and functional properties of murine hematopoietic stem cells that are replicating in vivo. J. Exp. Med. 183, 1797–1806 (1996).
Bolger, A. M., Lohse, M. & Usadel, B. Trimmomatic: a flexible trimmer for Illumina sequence data. Bioinformatics 30, 2114–2120 (2014).
Dobin, A. et al. STAR: ultrafast universal RNA-seq aligner. Bioinformatics 29, 15–21 (2013).
Liao, Y., Smyth, G. K. & Shi, W. featureCounts: an efficient general purpose program for assigning sequence reads to genomic features. Bioinformatics 30, 923–930 (2014).
Varet, H., Brillet-Guéguen, L., Coppée, J. Y. & Dillies, M. A. SARTools: A DESeq2- and EdgeR-based R pipeline for comprehensive differential analysis of RNA-seq data. PLoS ONE 11, e0157022 (2016).
Acknowledgements
We thank the Biological Resources, FACS, Imaging and Genomics facilities at UCL and E. Scarpa for technical help; D. Saur, A. Mass, D. Duboule, M. Kmita and Y. Kubota for mouse strains; and M. Golding for helpful discussions. This research was supported by grants from the Wellcome Trust (095623/Z/11/Z, 101067/Z/13/Z), Medical Research Council (MR/N011511/1) and British Heart Foundation (FS/17/23/32718).
Reviewer information
Nature thanks L. Iruela-Arispe and the other anonymous reviewer(s) for their contribution to the peer review of this work.
Author information
Authors and Affiliations
Contributions
A.P., A.F. and C.R. conceived and planned this study, analysed data and co-wrote the manuscript. L.D. performed genetic crosses and genotyping. A.P. and A.F. either performed experiments together or replicated each other’s experiments, except for the cell cycle and Hoxa studies, which were carried out by A.P and A.F., respectively. J.W.P. provided mouse strains. C.R. supervised the project. All authors reviewed and edited the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Extended data figures and tables
Extended Data Fig. 1 Endothelial Csf1r-iCre-targeting is observed with different recombination reporters, and targeted ECs are distinguishable from macrophages and pericytes.
a–c, Csf1r-iCre;RosaYfp (a), Csf1r-iCre;CAG-Cat-Egfp (b) and Csf1r-iCre;RosatdTom (c) hindbrains (n = 3 each) at the indicated stages were whole-mount labelled with IB4 and for YFP (a) or GFP (b) or are shown with tdTomato fluorescence (c). In a, the white squares indicate areas that were imaged at higher magnification for Fig. 1a. The indicated single channels are also shown individually. d, Csf1r-iCre;RosatdTom E12.5 hindbrains (n = 3), whole-mount labelled for ERG and CDH5 and shown including tdTomato fluorescence to demonstrate that Csf1r-iCre targets ECs that form junctions with neighbouring non-targeted ECs. e, f, E12.5 Csf1r-iCre;RosaYfp hindbrains, labelled for YFP and the microglia marker F4/80 (e) or the pericyte marker NG2 (f) together with IB4, show that Csf1r-iCre-targeted vessel-bound cells are neither microglia nor pericytes; n = 3 each. In e, the boxed area is shown in higher magnification and as single channels adjacent to the panel. In f, a single optical y/z cross section at the position indicated with the yellow line is displayed at higher magnification with single channels. Arrowheads, microglia; arrows, ECs; double arrowheads, pericytes; curved arrow, junctional CDH5 staining; solid and clear symbols indicate the presence or absence of marker expression, respectively. Scale bars: 100 µm (a), 20 µm (b, c, e, f), 50 µm (d).
Extended Data Fig. 2 Endothelial Csf1r-iCre-targeting is not caused by endothelial Csf1r expression and occurs independently of myeloid differentiation.
a, b, Csf1r-Egfp (a) and Csf1r-iCre;RosaYfp (b) E11.5 hindbrains (n = 3 each), whole-mount labelled for CSF1R and EGFP or YFP together with IB4, show lack of Csf1r promoter activity and CSF1R protein in ECs. c, Relative Cdh5 and Csf1r expression levels in our analysis of published E14.5 brain or pooled lung/liver EC microarrays22; n = 5 each; ***P < 0.0001 (two-tailed unpaired t-test). d–g, FACS separation of tdTomato+ cells from Csf1r-iCre;RosatdTom embryos (n = 3) for gene expression analysis, including representative gating strategy to exclude dead cells and doublets in this and subsequent experiments (d) and sorting into PECAM1+CD45− ECs versus CD45+PECAM1− MCs (e). f, Representative RT–qPCR gene amplification graphs for Csf1r and Actb from tdTomato+ MCs and ECs; ΔRn, normalized reporter value for SYBR Green minus baseline instrument signals. g, Graphic representation of the fold change in RT–qPCR amplification of the indicated genes relative to Actb for both cell populations; each data point represents one embryo; *P = 0.0242, ***P < 0.0001 (two-tailed unpaired t-test). h, Csf1r-iCre;RosaYfp P0 striatum on a Pu.1+/+ versus Pu.1−/− background (n = 3 brains each), cryosectioned and labelled for YFP and F4/80 together with IB4 to show that Csf1r-iCre-targeted ECs are PU.1-independent and persist postnatally. Arrowheads, microglia; arrows, YFP+ ECs; clear arrows, YFP+ ECs that are CSF1R− and F4/80−. Scale bars, 20 µm.
Extended Data Fig. 3 Lineage tracing of yolk sac and liver EMPs.
a, b, E8.5 wild-type (a) and Pu.1−/− (b) yolk sacs on a Csf1r-iCre;RosaYfp background (n = 3 yolk sacs each), whole-mount labelled for YFP and KIT, show Csf1r-iCre-targeted KIT+ round cells corresponding to EMPs and MPs as well as Csf1r-iCre-targeted KIT− flat cells corresponding to ECs. Scale bars, 20 µm. c–f, Pregnant Csf1r-Mer-iCre-Mer;RosatdTom (c, d) and KitCreERT2;RosatdTom (e, f) dams were injected with a single tamoxifen dose on the indicated days; E12.5 yolk sacs were whole-mount labelled for the indicated markers to identify Csf1r-iCre-targeted ECs and macrophages (n = 3 yolk sacs for each genotype). Wavy arrows, EMPs; straight arrows, Csf1r-iCre-lineage-traced ECs; arrowheads, macrophages; solid and clear symbols indicate the presence or absence, respectively, of the indicated markers. Scale bars, 20 µm. g–i, Pregnant dams were injected with a single tamoxifen dose on E10.5 (g) before using the indicated markers for FACS analysis of E11.5 Csf1r-Egfp;Csf1r-Mer-iCre-Mer;RosatdTom (h) or Csf1r-Mer-iCre-Mer;RosatdTom control (i) livers (n = 4 each); the CD45highKIT− differentiated MC (blue), CD45lowKIT+ EMP/MP (pink) and CD45−KIT+ (grey) populations were gated further for Csf1r-Egfp and tdTomato. CD45−KIT+ cells were neither MCs nor EMPs, because they lacked CD45, tdTomato and EGFP.
Extended Data Fig. 4 Immunostaining controls for cultured Csf1r-iCre-targeted cells.
The indicated cell populations were FACS-isolated from E12.5 Csf1r-iCre;RosatdTom liver or blood with the indicated markers and cultured for three days in methocult (met.) on fibronectin (FN); n = 1 experiment. a, b, Adherent cells from tdTomato+ liver MC (a) and EMP/MP (b) cultures were stained for ERG and VEGFR2 (top) or with secondary antibodies only (bottom). c, Adherent cells from tdTomato+ blood EMP and MP cultures were immunostained for CSF1R together with the myeloid markers CD45 (top) or F4/80 (bottom). In the first panel in each row, the phase contrast and DAPI images were merged. In panels 2–4 in each row, immunolabelled cells were visualized together with tdTomato fluorescence, with single channels for the indicated markers shown separately in greyscale. Arrows, tdTomato+ ECs; arrowheads, tdTomato+ MCs; solid and clear symbols indicate the presence or absence, respectively, of the indicated markers. Scale bars, 20 µm.
Extended Data Fig. 5 Hoxa gene targeting with Csf1r-iCre.
a, Schematic representation of the Hoxa gene cluster and adjacent Evx1 gene using the UCSC Genome Browser with the mouse December 2011 (GRCm38/mm10) Assembly, including position of the LoxP sites used for gene targeting. b, c, Validation of Hoxa targeting. b, FACS strategy to isolate KIT+ cells from E12.5 control (pooled Csf1r-iCre− or Csf1r-iCre+;Hoxa+/+; n = 14), Hoxa+/fl;Csf1r-iCre (n = 6) and Hoxafl/fl;Csf1r-iCre (n = 8) livers. c, qPCR analysis of Hoxa11 gene copy number relative to Evx1; mean ± s.d.; each symbol represents the value for one liver; *P = 0.0156, ***P < 0.001 (one-way ANOVA, Tukey’s multiple comparisons test). d–f, Representative FACS analysis (d) and quantification (e, f) of liver cell populations at E12.5 shows a similar number of total CD45+ and CD45+CD11b+ differentiated myeloid cells in Hoxafl/fl;Csf1r-iCre mutants (n = 7 for CD45+; n = 6 for CD45+CD11b+) versus pooled Csf1r-iCre− and Csf1r-iCre+;Hoxa+/+controls (n = 25 for CD45+, n = 17 for CD45+CD11b+); mean ± s.d. fold change in mutants compared to controls; each data point represents one liver; NS, not significant, P = 0.6519 (e) and P = 0.496 (f) (two-tailed unpaired t-test). g–i, E12.5 hindbrains of the indicated genotypes were immunolabelled to determine vascular complexity and quantify microglia. g, Schematic representation of a whole-mount embryonic hindbrain (left) and location of the hindbrain areas i–iv used for quantification (right); values for the four areas in each hindbrain were averaged to obtain the value for that hindbrain; EC quantifications are shown in Fig. 5c. h, Hindbrains were whole-mount labelled with IB4 and for RFP to visualize tdTomato and for F4/80 to visualize microglia; white boxes indicate areas shown in higher magnification in Fig. 5. i, Quantification of microglia in Hoxafl/fl;Csf1r-iCre mutants (n = 9) versus controls (n = 10, pooled Csf1r-iCre+;Hoxa+/+ and Csf1r-iCre− of any Hoxa genotype); mean ± s.d. fold change in mutant compared to control hindbrain; each data point represents one hindbrain; **P = 0.0055 (two-tailed unpaired t-test). j–l, E11.5 Csf1+/+ and Csf1+/op littermate hindbrains, whole-mount labelled for F4/80 together with IB4 (j) before quantification of microglia number (k) and vascular branchpoints as a measure of vascular complexity (l). Mean ± s.d.; each data point represents one hindbrain, n = 3 each; NS, not significant, P = 0.808, **P = 0.0012 (two-tailed unpaired t-test). Scale bars: 200 µm (h), 100 µm (j).
Extended Data Fig. 6 Csf1r-iCre-targeted ECs proliferate in vivo.
a, b, E12.5 Csf1r-iCre;RosatdTom yolk sac (a) or hindbrain (b), whole-mount stained for the proliferation marker pHH3 and VEGFR2 or for pHH3 together with IB4, respectively, and shown together with tdTomato fluorescence (n = 3 each). Areas indicated with white squares were imaged at higher magnification and are shown below the corresponding panels, with tdTomato and pHH3 channels also shown separately in greyscale. Arrows, proliferating tdTomato+pHH3+ ECs; solid and clear symbols indicate the presence or absence, respectively, of tdTomato fluorescence; wavy arrow, a tdTomato−pHH3+ neural progenitor. Scale bars: 100 µm (top), 20 µm (bottom). c–e, Cell cycle distribution of tdTomato+ and tdTomato− ECs. c, FACS strategy to isolate tdTomato+ and tdTomato−PECAM1+ ECs from E12.5 Csf1r-iCre;RosatdTom embryos (n = 3 embryos). d, Cell cycle distribution based on Hoechst 33342 fluorescence as a measure of DNA content; low and high staining intensity is observed in cells with a DNA ploidy of 2n (G0/G1 phase) or 4n (G2/M phase), respectively; intermediate staining intensity corresponds to S phase. e, Mean ± s.d. proportion of tdTomato+ and tdTomato− ECs in G1, S and G2/M based on the area of the corresponding peaks in d; NS, not significant, P > 0.9999 (two-way ANOVA, Bonferroni’s multiple comparisons test).
Extended Data Fig. 7 Validation of gene expression data from RNA-Seq and microarray studies.
ECs were FACS-isolated from E12.5 Csf1r-iCre;RosatdTom embryos (n = 3) as in Fig. 6a to validate the RNA-seq and microarray data shown in Fig. 6d–f. Slc2a1 was analysed as a representative brain EC-enriched transcript/differentiation marker, and Mrc1 and Oit3 as representative liver EC-enriched transcripts. a, Relative transcript levels of the Gt(ROSA)26Sor (tdTomato) transcript by RNA-seq of the E12.5 tdTomato+ and tdTomato− EC populations (analysis presented in Fig. 6a–f); mean ± s.d. of normalized counts, n = 3 each; **P = 0.0085 (two-sided unpaired t-test). b, RT–qPCR analysis for the indicated genes in tdTomato+ versus tdTomato− ECs isolated from whole E12.5 embryos (n = 5) to validate genes identified by RNA-seq in Fig. 6e, f as differentially expressed. Mean ± s.d. of fold change; ***P < 0.0001 (Slc2a1), ***P = 0.0008 (Mrc1) **P = 0.0056 (Oit3) (two-sided unpaired t-test). c, RT–qPCR analysis for the indicated genes in tdTomato− ECs isolated from the E12.5 brain versus liver (n = 3 for each organ) to validate organ-specific transcript enrichment identified via microarray analysis shown in Fig. 6f. Mean ± s.d. of fold change; *P = 0.019, **P = 0.0082, ***P < 0.0001 (two-sided unpaired t-test); ND, not detectable. d, RT–qPCR analysis for the indicated genes to directly compare the expression levels of brain and liver EC differentiation markers in tdTomato+ versus tdTomato− ECs isolated from brain (n = 3) or liver (n = 5). Mean ± s.d. of fold change; NS, not significant, P = 0.9398 (liver Slc2a1), P = 0.8045 (liver Mrc1), P = 0.6327 (liver Oit3), **P = 0.0073 (brain Slc2a1) (two-sided unpaired t-test); ND, not detectable.
Extended Data Fig. 8 Csf1r-iCre-targeted ECs contribute to embryonic vasculature in multiple organs.
a, 20-µm cryosections of the indicated E12.5 Csf1r-iCre;RosatdTom organs (n = 3 each) were immunolabelled for the indicated EC markers together with antibodies for RFP to identify tdTomato protein (top and bottom) or are shown with tdTomato fluorescence (middle); single channels are shown in greyscale. The white boxes indicate the positions of areas shown in higher magnification in Fig. 6g; some areas selected for higher magnification are not contained entirely within the field of view, and accordingly the boxes are shown incomplete. Scale bars, 200 µm. b, Gating strategy for FACS analysis of tdTomato+ and tdTomato− ECs from E12.5 Csf1r-iCre;RosatdTom brain, lung, heart and liver versus control organs lacking iCre, using antibodies for CD11b, CD41, CD45, KIT and PECAM1; associated EC quantifications are shown in Fig. 6i. An analogous strategy was used for the quantifications shown in Fig. 6j and in Extended Data Fig. 9b.
Extended Data Fig. 9 Csf1r-iCre-targeted ECs contribute to organ vasculature in late-stage embryos and adults.
a, 20-µm cryosections of the indicated organs from E18.5 Csf1r-iCre;RosaYfp mice (n = 2 each) were immunolabelled for YFP, PECAM1 and IBA1; single channels are shown in greyscale. Arrowheads, YFP+IBA1+ macrophages; solid and empty arrows, ECs that are YFP+ and lack IBA1 expression, respectively. Scale bars, 20 µm. b, FACS analysis of dissociated cells from the indicated organs of E18.5 Csf1r-iCre;RosatdTom embryos after staining with antibodies for CD11b, CD41, CD45, KIT and PECAM1, using the gating strategy shown in Extended Data Fig. 8b; mean ± s.d., n = 5 each; ***P < 0.0001 (one-way ANOVA, Tukey’s multiple comparisons test). c, 20-µm cryosections of the indicated organs from 6-month-old adult Csf1r-iCre;RosaYfp mice (n = 3 organs each) were immunolabelled for YFP, PECAM1 and F4/80; single channels are shown in greyscale. Arrowheads and arrows as in a. Scale bars, 20 µm.
Extended Data Fig. 10 Csf1r-iCre-targeted ECs contribute to adult organ vasculature.
a, 20-µm cryosections of 3-month-old adult Csf1r-iCre;RosatdTom livers (n = 3) were immunolabelled for RFP, VEGFR2 and F4/80 or MRC1 and then counterstained with DAPI; single channels are shown in greyscale. The white box indicates an area shown in higher magnification in Fig. 6h. Scale bars, 100 µm. b, Working model for the role of EMPs in generating extra-embryonic yolk sac and intra-embryonic organ ECs alongside their known role in generating myeloid and erythrocyte/megakaryocyte lineage cells. It is not yet known whether EMP-derived and non-EMP-derived ECs have different functions to regulate normal organ physiology or pathological vascular responses in the adult.
Supplementary information
Rights and permissions
About this article
Cite this article
Plein, A., Fantin, A., Denti, L. et al. Erythro-myeloid progenitors contribute endothelial cells to blood vessels. Nature 562, 223–228 (2018). https://doi.org/10.1038/s41586-018-0552-x
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/s41586-018-0552-x
- Springer Nature Limited
Keywords
This article is cited by
-
Endothelial cells and macrophages as allies in the healthy and diseased brain
Acta Neuropathologica (2024)
-
The niche matters: origin, function and fate of CNS-associated macrophages during health and disease
Acta Neuropathologica (2024)
-
Macrophages and endothelial cells in the neurovascular unit
Acta Neuropathologica (2024)
-
Discovery of an embryonically derived bipotent population of endothelial-macrophage progenitor cells in postnatal aorta
Nature Communications (2024)
-
Testicular macrophages are recruited during a narrow fetal time window and promote organ-specific developmental functions
Nature Communications (2023)