The embryonic site of definitive hematopoietic stem cell (dHSC) origination has been debated for decades. Although an intra-embryonic origin is well supported, the yolk sac (YS) contribution to adult hematopoiesis remains controversial. The same developmental origin makes it difficult to identify specific markers that discern between an intraembryonic versus YS-origin using a lineage trace approach. Additionally, the highly migratory nature of blood cells and the inability of pre-circulatory embryonic cells (i.e., 5–7 somite pairs (sp)) to robustly engraft in transplantation, even after culture, has precluded scientists from properly answering these questions. Here we report robust, multi-lineage and serially transplantable dHSC activity from cultured 2–7sp murine embryonic explants (Em-Ex). dHSC are undetectable in 2–7sp YS explants. Additionally, the engraftment from Em-Ex is confined to an emerging CD31+CD45+c-Kit+CD41− population. In sum, our work supports a model in which the embryo, not the YS, is the major source of lifelong definitive hematopoiesis.
The embryonic origin of cells that sustain lifelong mammalian hematopoiesis and blood production has long been debated. Resolving this debate is complicated by the emergence of sequential waves of blood cells at distinct sites within the embryo:1 blood-islands composed of primitive nucleated erythrocytes first appear at E7-E7.5 in the YS. Definitive erythroid-myeloid precursors also emerge from the YS at E8.5. Finally, around E10.5-E11.5, the first definitive HSC (dHSC) capable of reconstituting the hematopoietic system of adult recipients using existing assays are detected and presumably these precursors support lifelong blood production2,3. The site of origin of these dHSC has been contentious2,3,4,5,6,7,8,9,10,11,12,13,14,15,16. An intra-embryonic origin, concentrated around the para-aortic splanchnopleura (PSp)-derived aorta-gonad-mesonephros region (AGM), is currently the favored model. In contrast, the contribution of YS to the dHSC compartment is controversial1. Early work implicated the YS blood islands as a source of both primitive-erythroblasts and dHSC;1,4,5,6,8,15 however later work challenged this hypothesis. In particular, Dieterlen-Lievre and colleagues demonstrated an intra-embryonic origin for definitive hematopoiesis in vertebrates using quail-chick chimeras7,16. Recent work has formally demonstrated in chicken the presence of bona fide dHSC originating from the embryo aortas but not from the YS, allantois or head17. An intra-embryonic origin for dHSC in mammals was later supported by studies showing that the first dHSC capable of reconstituting adult recipients are detected in the PSp/AGM region2,3. Despite these findings, the potential contribution of YS to lifelong hematopoiesis has not been completely excluded13,14,18,19.
YS-derived and AGM-derived hematopoietic progenitors both arise from hemogenic endothelial (HE) precursors that are mesodermal in origin14,20,21,22,23,24,25. Very few markers have been identified that could potentially distinguish between AGM and YS hematopoietic precursors. The highly migratory nature of blood cells in circulating embryos and the inability of cells isolated from pre-circulation embryos to robustly engraft in transplantation assays, even after ex vivo culture, has precluded definitively addressing if the YS hemogenic endothelium (YS-HE) contributes to lifelong hematopoiesis and the adult dHSC pool12,26. PSp tissue from pre-circulation embryos generated long-term multi-lineage engraftment while YS did not, but reconstitution was extremely low (1–5%) in these experiments, raising concerns that lower activity present in the YS would have been very difficult to detect12. Furthermore, PSp-derived reconstitution was only observed in severely immunocompromised recipient mice (i.e., Rag2γc−/−)12. Indeed, it has recently been suggested that the YS may be a major embryonic source of dHSC14. Lineage tracing studies exploiting the high expression of LYVE1 (lymphatic vessel endothelial hyaluronan receptor-1) in the YS and vitelline-endothelium concluded that >40% of adult blood may ultimately derive from these sites in mice14.
Here, we present a platform that supports the ex vivo development of robust dHSC activity from pre-circulation embryos, allowing us to rigorously interrogate the dHSC-forming potential of both the early embryo and YS. We find that cultured pre-circulatory Em-Ex, but not YS explants (YS-Ex), yield robust dHSC activity. Importantly, this activity in cultured Em-Ex was restricted to an emerging CD31+CD45+c-Kit+CD41− population that also develops in cultured YS-Ex. Additionally, in pre-circulation embryos, we identify LYVE1+CD31+ aortic endothelial cells, confirming that LYVE1 expression is found outside the YS and vitelline HE at this early stage of development14. We further demonstrate that pre-circulatory Em-Ex-derived LYVE1+ precursors yield robust dHSC activity, indicating that LYVE1 constitutes an early marker of intraembryonic definitive hematopoiesis. In sum, our work strongly supports a model in which the YS is not a major source of lifelong definitive hematopoiesis.
Robust dHSC activity generation from pre-circulatory embryos
Blood circulation is established around 5–7sp (≈E8.5). The first heartbeat is detected at 5sp, a consistent blood flow begins around 7sp and fully functional circulation is established after E10, as evidenced by the uneven distribution of erythroblasts within the embryo vasculature prior to 35sp27,28. Although dHSC activity has previously been observed from cultured pre-circulation embryos, this activity was low, and only observed after transplantation into Rag2γc−/− immunocompromised recipients12. Here, we sought to determine if it might be possible to coax robust dHSC activity from E8-E8.5 concepti.
We collected CD45.2+ embryos at E8.0-E8.5 and staged them by number of somite pairs. Concepti were organized into two groups: 2–3sp (pre-circulation) and 5–7sp (peri-circulation). Embryos were separated from the YS and cultured at the air-liquid interface in the presence of SCF, FLT3L, and IL-3, as previously described29,30,31. We hypothesized that an extended culture period might be required for maturation of dHSC from these early embryos (Fig. 1a). Hence, embryos were cultured for 9–10 days. Cultured Em-Ex were then recovered, dissociated and transplanted into lethally irradiated CD45.1+CD45.2+ recipients along with 2 × 105 CD45.1+ whole bone marrow (WBM) cells for radio-protection (Fig. 1a). Remarkably, both 2–3sp and 5–7sp cultured embryos generated robust dHSC activity. 5–7sp embryos engrafted 9/11 (82%) recipients while 2–3sp embryos engrafted 5/7 (71%) recipients (Fig. 1b). Globally, >15% of recipient peripheral blood (PB) was CD45.2+ in 7/18 total recipients at 16 weeks post-transplant. Four recipients displayed >50% CD45.2+ PB reconstitution (Fig. 1b). Importantly, most engrafted recipients (11/14) displayed multi-lineage engraftment at 16 weeks post-transplant (Fig. 1b). To further test if Em-Ex developed robust dHSC activity, we performed secondary limiting dilution transplants. 0.8 × 106 (n = 9), 1 × 106 (n = 6), 2 × 106 (n = 8) or 5 × 106 (n = 8) WBM cells from three independent primary recipients of 5–7sp Em-Ex were transplanted into lethally irradiated CD45.2+CD45.1+ recipients (Fig. 2a). At the three highest doses of WBM, 100% of secondary recipients displayed significant Em-Ex-derived CD45.2+ chimerism (1–92%) at 16 weeks post-transplant (Fig. 2a). CD45.2+ reconstitution was >25% in 11/31 secondary recipients and >90% in two recipients. Multiple independent secondary recipients also yielded robust long-term Em-Ex-derived CD45.2+ chimerism after transplantation into lethally irradiated CD45.1+CD45.2+ tertiary recipients, although interestingly this reconstitution displayed dramatic lineage skewing (Fig. 2b). The robust hematopoietic reconstitution of primary, secondary, and tertiary recipients by cultured 5–7sp Em-Ex is indicative of self-renewing dHSC and long-term repopulating cells, confirming that our explant culture system supports the emergence and maturation of dHSC from embryos isolated at the onset of blood circulation.
Pre and peri-circulation YS do not produce dHSC ex vivo
Dissected CD45.2+ YS from pre-circulation and peri-circulation concepti (2–3sp and 5–7sp) were cultured as explants (YS-Ex) in parallel and under the same conditions as Em-Ex. None of the cultured pre-circulation or peri-circulation CD45.2+ YS-Ex yielded detectable dHSC activity when transplanted into lethally irradiated CD45.1+CD45.2+ recipients along with 2 × 105 WBM CD45.1+ cells (0/5 and 0/11 recipients, respectively, Fig. 1b). It is possible that YS hemogenic precursors undergo distinct temporal maturation compared to intra-embryonic hemogenic endothelium. Indeed, YS-Ex displayed substantially greater CFU-GEMM (i.e., colony forming unit granulocyte, erythrocyte, monocyte, megakaryocytic) potential at day 5 versus day 10 of ex vivo culture (Supplementary Fig. 1A). Thus, 5–7sp YS-Ex were cultured for five or seven days prior to dissociation and transplanted into lethally irradiated recipients. These cultures also failed to produce detectable dHSC activity (0/8 for five-day YS-Ex cultures and 0/3 recipients for seven-day YS-Ex, Fig. 1c).
These data indicate that the only precursors capable of maturing into functional dHSC under these conditions are found in the embryo at this early stage of development. Additionally, we tested the ability of YS isolated from later developmental time-points (e.g., E9.5 (19–22 sp, n = 3), E10.5 (32–36 sp, n = 3) and E11.5 (46–47sp, n = 7)) to engraft lethally irradiated recipients after being cultured ex vivo for five days prior to transplantation. 100 and 71% of CD45.1+CD45.2+ recipients transplanted with CD45.2+ E10.5 and E11.5 cultured YS-explants showed robust CD45.2+ YS-derived engraftment, respectively (Fig. 1c). In contrast, CD45.1+CD45.2+ recipients transplanted with CD45.2+ E9.5 YS-derived explants displayed no evidence of CD45.2+ engraftment (Fig. 1c). To test if E9.5 hematopoietic precursors are capable of maturing into dHSC under our ex vivo culture conditions, embryonic caudal halves and YS isolated from CD45.2+ E9.5 concepti were cultured for five, seven or 10 days and then transplanted into lethally irradiated CD45.1+CD45.2+ recipients (Fig. 1d). 100% of recipients transplanted with embryonic caudal halves cultured for five or seven days (3/3 and 6/6, respectively, Fig. 1d) displayed robust CD45.2+ dHSC activity, confirming that post-circulation E9.5 dHSC can mature under these culture conditions. However, all E9.5 YS-derived explants failed to generate detectable dHSC in these experiments (Fig. 1d).
In sum, these findings support a model where the precursors in pre-circulation and peri-circulation concepti capable of maturing into functional dHSC under these conditions are located in the embryo.
SCF and IL-3 induce CD31+CD45+c-Kit+CD41− dHSC emergence
We next sought to phenotypically characterize functional dHSC that emerge during the ex vivo culture of peri-circulation Em-Ex. We took advantage of cell surface markers to isolate distinct populations from CD45.2+ 5–7sp Em-Ex for transplantation into lethally irradiated CD45.1+CD45.2+ recipients (Fig. 3a). Previous work showed that dHSC activity in E10.5-E11 Em-Ex cultured under similar conditions is contained in the CD31+CD45+ fraction29,31. This population was apparent in the Em-Ex cultures (Fig. 3b). CD41 and c-Kit are also expressed by nascent hematopoietic populations in early embryos30,31,32,33,34,35,36,37,38. Distinct populations expressing both CD41 and c-Kit were clear within CD31+CD45+ Em-Ex cells (Fig. 3b, Fig. 4b and Supplementary Fig. 1B). We therefore isolated CD31+CD45+c-Kit+CD41+, CD31+CD45+c-Kit+CD41−and CD31+CD45+c-Kit− cells by FACS from cultured 5–7sp Em-Ex and transplanted them into lethally irradiated CD45.1+CD45.2+ recipients (n = 5, Fig. 3a–c). All dHSC activity was restricted to CD31+CD45+c-Kit+CD41-cells (Fig. 3c). Interestingly, this same population was also apparent in 5–7sp YS cultures (Fig. 4b and Supplementary Fig. 1B).
We next tested whether the emergence of the CD31+CD45+c-Kit+CD41− engrafting population was selectively dependent on any of the three growth factors added to these cultures (i.e., SCF, IL-3, FLT3L). Embryos and YS isolated from 5–7sp concepti were cultured in the presence of different combinations of growth factors and assessed by flow cytometry for the emergence of CD31+CD45+ and CD31+CD45+c-Kit+CD41− cells (Fig. 3d, e). CD45.2+ Em-Ex cultures were also transplanted into lethally irradiated CD45.1+CD45.2+ recipients to test for dHSC activity (Fig. 3d, f). Removal of FLT3L had no effect on the frequency of CD31+CD45+ or CD31+CD45+c-Kit+CD41− cells in YS-Ex or Em-Ex cultures (Fig. 3e). Moreover, removal of FLT3L did not affect the emergence of dHSC in Em-Ex cultures: the contribution of CD45.2+ cells to the PB of transplant recipients was 18% in the presence of all three factors and 21% in the absence of FLT3L (Fig. 3e, f and Supplementary Fig. 1B). In contrast, removal of IL-3 or SCF reduced the frequency of CD31+CD45+ or CD31+CD45+c-Kit+CD41− cells, respectively, in YS-Ex and Em-Ex cultures, which correlated with a loss of dHSC activity from CD45.2+ Em-Ex cultures (Fig. 3e, f and Supplementary Fig. 1B). The average CD45.2+ hematopoietic reconstitution in these recipients dropped to about 5 and 10% in the absence of IL-3 or SCF, respectively (Fig. 3f). Em-Ex cultured in the absence of both FLT3L and IL-3 also displayed reduced hematopoietic engraftment potential (p < 0.1, exact Wilcoxon rank sum test (eWrs-test)) (Fig. 3f). Em-Ex cultured in the absence of all three cytokines displayed dramatic reductions in the frequency of CD31+CD45+ and CD31+CD45+c-Kit+CD41− cells and lacked detectable dHSC activity (Fig. 3e, f and Supplementary Fig. 1B). In sum, administration of both SCF and IL-3 is required for the efficient development of CD31+CD45+c-Kit+CD41− cells from pre-circulation concepti during YS-Ex and Em-Ex culture and dHSC potential in Em-Ex cultures. These results are consistent with the observation that SCF and IL-3 can both promote the in vitro derivation of bona fide HSC from other cell sources29,30,31,39,40,41.
An HSC-like population is generated by embryo explants
YS and embryos are separated and cultured before the onset of the circulation in our experimental platform. Thus, this represents an opportunity to selectively study embryo versus YS-derived hematopoiesis under controlled conditions that allow for the maturation of dHSC from early embryonic precursors. Indeed, novel cell surface markers of dHSC-derived from early embryos could be useful reporters in efforts to isolate dHSC from pluripotent stem cells or other sources. Although CD31+CD45+c-Kit+CD41−cells develop in both YS-Ex and Em-Ex cultures, cultured YS-Ex-CD31+CD45+c-Kit+CD41− cells do not harbor dHSC activity (Figs. 1b, 3b, 3f, Supplementary Fig. 1B). Therefore, we decided to interrogate the gene expression profiles of 5–7sp YS-Ex-CD31+CD45+c-Kit+CD41− cells and Em-Ex-CD31+CD45+c-Kit+CD41− cells on day 10 post-culture for molecularly distinct cell populations that might explain the absence of dHSC activity in YS explants by single cell RNA sequencing (scRNAseq) (Fig. 4).
First, we determined the frequency of the engrafting population within cultured Em-Ex. Limiting dilution transplantation revealed 0.83 repopulating units (RUs) per Em-Ex (95% C.I. = (0.48, 1.42); results fit the LDA model: p-value = 0.717, t-test) (Fig. 4a). Next, 49 concepti were dissected and cultured as separate YS-Ex and Em-Ex for scRNAseq. In this experiment we are interrogating approximately 40.67 RUs in the Em-Ex sample (i.e.,: 49Em-Ex*0.83RUs).
To identify Em-Ex-derived populations of putative biological interest, the resulting scRNAseq data was projected as tSNE1 Vs tSNE2. A population specific to the Em-Ex sample was apparent (X-cells, Fig. 4c). It was comprised of 623 cells (17.8% of the Em-Ex population). To interrogate the developmental state of this population, we compared its expression profile to Zhou and colleagues scRNAseq dataset of embryonic hematopoiesis (Fig. 4d)42. Em-Ex cells were most similar transcriptionally to E11-T2-pre-HSC (CD31+CD45+cKit+CD41low, 60% of the X-cells were assigned to this group) or E12.5 Fetal Liver (FL) HSC (Lineage−Sca-1+Mac-1lowCD201+, 37% of the X-cells were assigned to this group) and thus ‘assigned’ to these populations computationally (Fig. 4d). Interestingly, Em-Ex-derived X-cells were highly enriched for cells assigned to FL HSC. Indeed, 70 and 6% of Em-Ex-derived X-cells were assigned to E12.5 FL HSC and E14.5 FL HSC (CD45+CD150+CD48−CD201+), respectively (Fig. 4d). These data suggest that X-cells are enriched for developmentally more mature hematopoietic progenitors43. Interestingly, the vast majority of profiled YS-Ex cells (92%) were assigned to E11.0-T2-pre-HSC, suggesting developmental immaturity relative to Em-Ex cells (Fig. 4d). A comparison of E11.0-T2-pre-HSC and E12.5-FL HSC revealed 353 downregulated genes and 80 upregulated genes (FDR<0.05 and Log2 fold change <−2 or >2, respectively; eWrs-test and Benjamini and Hochberg p-value adjustment) (Fig. 4e). Remarkably, compared to other analyzed cells in our scRNAseq dataset, X-cells showed lower expression for the downregulated genes and higher expression for the upregulated genes (Fig. 4f). Upregulated genes were enriched in proliferation related functional terms (i.e., E2F cell cycle targets and DNA-repair genes (FDR q-values = 3.98 × 10−3 and 1.58 × 10−2, respectively; Fisher’s exact test and Benjamini and Hochberg p-value adjustment). This is consistent with increasing proliferation as HSC transition from the AGM to the FL1. Genes defining epithelial-to-mesenchymal downregulated in the E11.0-pre-HSC to E12.5-HSC transition were also downregulated in the X-cells (FDR q-value = 2.85 × 10−6; Fisher’s exact test and Benjamini and Hochberg p-value adjustment). Of note, multiple cell surface proteins appear selectively upregulated in Em-Ex X-cells (e.g., Cxcr4, Mpl, Il6ra, and Tnfrsf1, Supplementary Fig. 2). Further work will be required to determine if these cell surface markers hold functional utility for further enrichment of transplantable dHSC from Em-Ex. Indeed, identifying a specific marker for embryonic populations with bona fide dHSC potential could be very useful for in vitro screens.
Intraembryonic LYVE1+ blood precursors yield dHSC activity
Our studies suggest that the pre-circulation and peri-circulation YS is not a major source of dHSC. However, it was recently reported that >40% of adult blood may emerge from the early YS and vitelline endothelium14. Lee and colleagues used Lyve1-eGFP-hCre knock-in mice (Lyve1Cre) (Fig. 5a) to claim an extraembryonic origin for a significant fraction of adult blood, but not primitive erythrocytes or the definitive hematopoietic precursors of the embryo, placenta or umbilical vessels. LYVE1 expression was reportedly highest in the endothelium of the YS and vitelline vessels (VV) in the mid-gestation conceptus14.
We used Lyve1Cre, Rosa26+/mTmG and Rosa26+/Confetti mice to further examine the contribution of LYVE1+ cells to lifelong hematopoiesis. The unrecombined Rosa26mTmG allele ubiquitously labels all cells with the tdTOMATO protein (Fig. 5a). CRE recombinase (CRE) drives the excision of the tdTomato cassette and stably labels CRE+ cells and their progeny with GFP (Fig. 5a)44. The unrecombined Rosa26Confetti multicolored cassette does not drive any fluorescent expression. Here, CRE induces recombination of the Rosa26Confetti allele, which results in cells and their progeny stably labeled with one of four fluorescent proteins (GFP, CFP, RFP, or YFP, Fig. 5a)45. We observed ≈20 and ≈5% labeled cells in the adult blood of Lyve1+/CreRosa26+/mTmG and Lyve1+/CreRosa26+/Confetti mice, respectively (Fig. 5b), confirming that cells expressing CRE via the Lyve1Cre allele at some point during their development contribute to adult hematopoiesis, albeit in our hands less than the 40% previously reported14. Similar to previous reports, we observed that the endogenous eGFP signal from the Lyve1Cre knock-in allele (Fig. 5a) was faint and did not hinder detection of the eGFP signal from the Rosa26mTmG reporter allele14,46.
To further interrogate LYVE1 as a marker of early hematopoietic progenitors, we next assessed LYVE1 expression in post-circulation concepti. We observed both LYVE1low and LYVE1high cells in E9.5 (19–22sp) and E10.5 (32–36sp) YS and embryos (Fig. 5c–f). Most embryo LYVE1+ cells were LYVE1low (Fig. 5c–f). Indeed, at E9.5 and E10.5 the absolute numbers of embryo- and YS-LYVE1lowVE-Cadherin+CD31+CD41+c-Kit+ cells were not significantly different (Fig. 5d, f). Thus, LYVE1 expressing cells are readily detectable in post-circulation embryos and YS. Further, examination of public gene expression databases revealed Lyve1 mRNA in dHSC precursors in E11-E11.5AGM (Supplementary Fig. 3)42,43. Altogether, these data confirm that LYVE1 is expressed by putative hematopoietic progenitors in both YS and embryonic tissues post-circulation14.
Next, we examined LYVE1 expression in peri-circulation (5–7sp concepti) mouse concepti using flow cytometry and confocal microscopy. We again observed distinct LYVE1high and LYVE1low populations in both YS and embryos (Fig. 6a). Although both populations were more abundant in YS relative to embryos, especially LYVE1high cells, LYVE1 expressing cells were clearly detectable by flow cytometry in 5–7sp embryos (% of YS-LYVE1high = 2.86; % of Em-LYVE1high = 0.11; % of YS-LYVE1low = 3.11; % of Em-LYVE1low = 0.56) (Fig. 6a, b). Most LYVE1high and LYVE1low cells in both 5–7sp YS and embryos also expressed CD41 (≈70 and ≈85%, respectively, Fig. 6a, c). Moreover, LYVE1+CD31+ cells were apparent in the endothelium of the paired aorta of E8.5 embryos (Fig. 6d). Altogether, these data demonstrate that LYVE1 expression is not restricted to YS in peri-circulation embryos.
To gain further insight into the fidelity of LYVE1 as a specific marker of YS and vitelline hemogenic endothelium, YS and embryos were collected at the onset of the heartbeat from 5–7sp- Lyve1+/CreRosa26+/mTmG concepti (Fig. 7a). Here, GFP+ cells were readily detected in YS (Fig. 7b, c), with an average frequency of 3.9% (Fig. 7c). Labeled cells were much less frequent in 5–7sp embryos (average labeling of 0.067%, Fig. 7b, c). We previously observed that the vast majority of LYVE1+ cells in Lyve1+/+Rosa26+/+ concepti are CD41+ (Fig. 6c). Similarly, most GFP+ cells in 5–7sp Lyve1+/CreRosa26+/mTmG concepti were CD41+ (Fig. 7b, d). Additionally, the %CD41+ cells was about 20 times larger in the YS than in the embryo (Fig. 7e). As CD41 labels hematopoietic precursors at this early developmental stage, we focused on the recombination efficiency in the CD41+ compartment and found it to be about 5% in the YS and 1.1% in the embryo (Fig. 7f)30,32,33,34,36,37. Importantly, GFP+ cells in E8.5 embryos were confined to the endothelium of the paired aortas (Fig. 7g).
As our explant culture system allows us to visualize the emergence of phenotypic hematopoietic precursors from pre-circulation and peri-circulation concepti, we next examined GFP labeling in cultured YS-Ex and Em-Ex-derived hematopoietic precursors (CD31+CD45+c-Kit+CD41−). We observed that, on average, 61% of YS-Ex-derived and 47% of Em-Ex-derived CD31+CD45+c-Kit+CD41−cells were GFP+ (Fig. 7h, i). Lethally irradiated CD45.1+CD45.2+ recipients were next transplanted with cells isolated from Lyve1+/CreRosa26mTmG 5–7sp Em-Ex and 2 × 105 CD45.1+ WBM cells (Fig. 7j-l). As expected from our previous experiments (Fig. 1b), 5–7sp Lyve1+/CreRosa26mTmG cultured Em-Ex harbored dHSC activity and reconstituted 15–80% of recipient PB (Fig. 7k). Importantly, 3/4 recipients of E8.5 Lyve1+/CreRosa26mTmG-derived Em-Ex displayed GFP+ engraftment, demonstrating that Lyve1Cre labels the progeny of intra-embryonic HE precursors (Fig. 7l). Indeed, in one recipient, 88% of Em-Ex-derived PB was GFP+ (Fig. 7l). Differences in the %GFP+ recipient PB reflects the small number of Em-Ex-derived RUs transplanted per recipient (3.32 RUs = 4EE*0.83RUs per explant, Fig. 4a) and low recombination efficiency of the Rosa26mTmG allele (about 20%, Fig. 5b). We also tested cells isolated from 19–22sp Lyve1+/CreRosa26mTmG Em-Ex and YS-Ex for dHSC activity via transplantation. Here, Em-Ex-derived PB reconstitution was high (averaging 51%, n = 10). Although the %GFP+ PB varied widely (Fig. 7l), 8/10 recipients displayed GFP + PB reconstitution. As expected (Fig. 1c, d), Lyve1+/CreRosa26mTmG YS-Ex did not engraft recipient mice (Fig. 7k, l). In sum, our data reveal that the embryo harbors LYVE1+ blood precursors capable of giving rise to dHSC.
Identifying the original site of dHSC specification during embryogenesis has been a major challenge due to the migratory nature of blood precursors in the circulating embryo and the absence of assays to rigorously test hematopoietic potential of pre-circulatory tissues. Here, we report the robust generation of dHSC activity from pre-circulation and peri-circulation murine embryos. dHSC activity could only be detected in cultured embryo explants and not cultured YS explants, indicating that the YS is unable to autonomously generate dHSC activity, at least under the conditions tested here. This implies that either the YS does not contain dHSC precursors or that it lacks the essential support environment for maturation of such precursors. Our findings are consistent with those of Cumano and colleagues, but in those studies, the authors were only able to detect very low levels of HSC activity from pre-circulation intra-embryonic tissues (<5%), and only after transplantation into immunocompromised Rag2γc−/− recipients12. Poor reconstitution activity left open the possibility that YS harbored dHSC activity that fell below their detection threshold. Indeed, very recent studies suggest an extraembryonic (i.e., YS and/or vitelline hemogenic endothelium) origin for a large fraction of lifelong hematopoiesis13,14. However, the high levels of dHSC activity detected in our culture system (up to >75% reconstitution of PB after transplantation into immunologically competent mice) allows us to rigorously compare YS and embryos and demonstrate that pre-circulation YS lacks significant dHSC potential (Fig. 1b). None-the-less, our data support a model in which dHSC originate from intra-embryonic precursors in pre-circulation and peri-circulation concepti.
CD31+CD45+c-Kit+CD41−cells harbored all Em-Ex-derived dHSC activity in our experimental system. The development of this population required exogenous administration of SCF and IL-3 (Fig. 3). This agrees with previous studies where SCF is also required for the maturation of E9.5 pro-HSCs and E10.5 type I and type II pre-HSCs. Scf is expressed in the E9.5 dorsal aorta and upregulated at E10.5 when HSPC specification accelerates29,30,31. Scf−/− mice display reduced dHSC activity and peri-natal death39. IL-3 induces maturation of dHSC between E10.5 and E11.5 in the AGM40,41. In contrast, exogenous administration of FLT3L is dispensable for dHSC maturation ex vivo31. Our finding that 5–7sp Em-Ex also require SCF and IL-3 to effect dHSC maturation ex vivo suggests that even very early dHSC precursors require these same signals.
Interestingly, CD31+CD45+c-Kit+CD41− cells also emerged in cultures of early YS (Fig. 4b), where they clearly lack detectable dHSC activity (Fig. 1b–d). The ability of our culture conditions to yield bona fide dHSC from pre-circulation concepti provides a unique opportunity to study YS-specific and embryo-specific hematopoiesis and the critical molecular features that allow Em-Ex to render dHSC activity. This could be useful for efforts to derive bona fide dHSC from alternative sources ex vivo and provide specific reporters for in vitro screening. Remarkably, single cell global gene expression profiling identified an Em-Ex-derived population (X-cells, Fig. 4c) that does not emerge from YS cultures and displays enrichment for genes expressed by dHSC found in the FL (Fig. 4d). Further analysis identified multiple cell surface molecules selectively expressed by this unique population (e.g., Cxcr4, c-Mpl, Il6ra, and Tnfrsf1, Supplementary Fig. 2). These cell surface markers harbor putative utility to both refine the Em-Ex population harboring dHSC activity and explore for in vivo surrogates that may represent critical transitions in the maturation of dHSC in vivo. Exploring the biological significance of these and other markers will be the subject of future investigations.
An alternative approach to defining the embryonic origins of lifelong hematopoiesis is the use of YS versus embryo-specific lineage markers. This approach has proved challenging as YS and embryo-derived hematopoietic precursors exhibit similar developmental programs1. Both are mesodermal in origin and emerge from endothelial precursors. Previously, temporally controlled Runx1−based lineage tracing suggested YS-derived contribution to adult hematopoiesis13. However, the duration of the labeling pulse was unclear and only a low percentage of adult blood cells were labeled1,13. Additionally, RUNX1+ cells were apparent outside the YS, raising doubts that all Runx1-induced Cre recombinase activity in early embryos was YS-restricted1,13. Further, this study employed a Cre recombinase knock-in mouse model that was hemizygous for Runx1. Runx1−/+ mice are severely perturbed in both the timing of hematopoietic specification and the cell surface phenotype of emerging hematopoietic progenitors47. Thus, observations made in a hemizygous Runx1 mouse model are unlikely to reflect normal steady-state hematopoietic ontogeny.
It is possible that the YS harbors dHSC precursors that fail to ‘mature’ in our system due to the absence of key embryo-derived non-cell-autonomous cues. In this scenario, YS-precursors may need to migrate to a maturation niche in the embryo, as proposed by Matsuoka and colleagues18. Indeed, Runx1+Gata-1− (hemogenic angioblasts) have been reportedly observed migrating from the E7.5 extraembryonic YS into the embryo proper in cultured embryo explants, where they were proposed to receive a currently undefined signal that induces competence to contribute to lifelong hematopoiesis19. However, here again the duration of the 4-OHT labeling pulse was unclear, raising the possibility that rare Runx1 + intraembryonic precursors could have been labeled between E8 and E8.5. Further, it has not been explicitly demonstrated that Runx1+Gata-1− cells seen migrating in ex vivo cultures from the extra-embryonic to the intra-embryonic region are capable of contributing to lifelong hematopoiesis in vivo. In our explant system, pre-circulation and peri-circulation YS explants failed to generate any dHSC activity.
Although, Lyve1−Cre lineage tracing was recently employed to discern blood derived from YS versus embryonic endothelial precursors14, we observed two distinct LYVE1+ populations (LYVE1high and LYVE1low) in both YS and embryos isolated from E8.5, E9.5 and E10.5 concepti (Figs. 5–6). Although the frequency and absolute numbers of LYVE1high cells is higher in the YS, the absolute numbers of LYVE1low cells between YS-derived and embryo-derived blood precursors is not significantly different (Figs. 5–6). Moreover, we observed LYVE1+ endothelial cells in the endothelium of the paired embryo aortas prior to the onset of circulation (Fig. 6d and Fig. 7g). Furthermore, Lyve1+/Cre Rosa26+/mTmG embryos isolated at the onset of the first heartbeat (5–7sp) and cultured as explants gave rise to GFP+CD31+CD45+c-Kit+CD41− cells, which is the transplantable population that emerges in this system (Fig. 3c and Fig. 7h, i). On average, about 50% of emerging CD31+CD45+c-Kit+CD41− cells were GFP+ in these cultures, with one Em-Ex yielding 100% GFP+CD31+CD45+c-Kit+CD41− cells (Fig. 3c and Fig. 7h, i). Most importantly, transplantation of 5–7sp Lyve1+/Cre Rosa26+/mTmG Em-Ex revealed that LYVE1+ embryo-derived progeny consistently contributed to the engraftment of lethally irradiated recipients (Fig. 7j–l). Thus, embryo-derived hematopoietic precursors must also express LYVE1. Altogether, these data confirm LYVE1 as an early marker of definitive hematopoiesis, reveal that LYVE1 expression is not restricted to YS hematopoietic precursors and suggest that most LYVE1+ contribution to adult hematopoiesis is embryonic in origin.
In summary, here we report the generation of robust dHSC activity from pre-circulation and peri-circulation embryo explants during ex vivo culture. Cultured YS explants failed to yield dHSC activity under these same conditions, suggesting that the YS contains few precursors capable of maturing into dHSC. We also present evidence that both YS and embryo-derived hemogenic precursors express LYVE1 during ontogeny. Our study supports a model in which most of lifelong hematopoiesis derives from hematopoietic precursors that develop de novo in the embryo proper. Future studies will be required to better define the pre-circulation and peri-circulation embryonic precursors that ultimately mature into dHSC. These studies would benefit any effort to coax bona fide dHSC from pluripotent stem cells.
C57BL/6 J, C57BL/6.SJL-PtprcaPep3b/BoyJ, ROSA26+/mTmG (Gt(ROSA)26Sortm4(ACTB-tdTomato,-EGFP)Luo/J), ROSA26+/Confetti (Gt(ROSA)26Sortm1(CAG-Brainbow2.1)Cle/J) and Lyve1-eGFP-hCre knock-in mice (Lyve1Cre) mice were acquired from The Jackson Laboratory (Bar Harbor, Maine) and housed in a pathogen-free facility. Both females and males were used. All animal experiments were carried out according to procedures approved by the St. Jude Children’s Research Hospital Institutional Animal Care and Use Committee and comply with all relevant ethical regulations regarding animal research.
Polymerase chain reactions (PCR) were performed using Go Taq DNA Polymerase (Promega, Madison WI) as indicated by the manufacturer. PCR conditions: (95 °C, 2’);((94 °C, 30”; 56 °C, 30”; 72 °C, 30”]×35); (72 °C, 10’).
Primers: Cre F1 (5’ CTGTTACGTATAGCCGAAAT 3’), Cre
R1 (5’ CTACACCAGAGACGGAAATC T 3’). CRE Positive PCR band: 203 bp. Detection of the GFP allele was used for mTmG and Confetti allele genotyping: GFP Fw (5’ CAGATGAAGCAGCACGACTTCT 3’), GFP Rv (5’ AACTCCAGCAGGACCATGTGAT 3’). GFP PCR band: 400 bp.
For all transplants, 8–12 weeks old CD45.2+/CD45.1+ C57BL/6 J recipients were treated with 11 Gy of ionizing radiation in split doses of 5.5 Gy prior to transplant. Males and females were used as recipients. In each experiment, sexes of the recipient mice were evenly distributed among experimental groups. All cells were transplanted by tail vein injection. E8.5, E9.5, E10.5, and E11.5 CD45.2+ Em-Ex-derived or YS-derived cells were transplanted along with 2 × 105 CD45.1+ C57BL/6.SJL WBM cells into recipients. For secondary and tertiary transplantation, 5 × 106, 2 × 106, 1 × 106, or 0.8 × 106 WBM cells were transplanted from primary or secondary recipients. Engraftment was defined as >0.5% CD45.2+ cells in each lineage (T cells, B cells, and myeloid cells) and >1% CD45.2+ total PB.
PB was collected from the retro-orbital plexus in heparinized capillary tubes (Fisherbrand, Pittsburgh, PA) and lysed in red blood cell lysis buffer (Sigma-Aldrich, St. Louis, MO). Cells were stained with the following antibodies: CD45.1-APC (A20) (Biolegend, San Diego, CA) or CD45.1-FITC (A20) (BD Biosciences, San Diego, CA), B220-PECy7 and CD8-PECy7 (53–6.7) (Tonbo Biosciences, San Diego, CA), CD45.2-V500 (104), B220- PerCPCy5.5 (RA3-6B2), Gr1-PerCPCy5.5 (RB6-8C5), Cd11b-PerCPCy5.5 (M1/70) and CD4-PECy7 (RM4-5) (BD Biosciences, San Diego, CA). All antibodies were used at 1:200 dilution. 4’,6-diamidino-2-phenylindole (DAPI) staining was used to gate live events. Analysis was performed on a LSR Fortessa and a BD FACSAria III SORP (Special Order Research Product, which contains the following LASERs: 405 nm, 445 nm, 488 nm, 562 nm, and 640 nm) (both BD Biosciences, San Diego, CA) and the data analyzed with FlowJo version 9.4.11 (Tree Star, Ashland, OR). To discern the four Confetti colors: the filter arrangements for each LASER were: CFP, 445 nm LASER—470/24 band-pass filter (BP); GFP, 488 nm LASER—515/20 BP and 505 long-pass filter (LP); YFP, 488 nm LASER—545/10 BP and 525 LP; RFP, 562 nm LASER—610/20 BP and 600 LP48.
Explants cultures and flow cytometry analysis
Explant culture conditions were adapted from the protocol developed by Medvinsky and colleagues29. Embryo and YS-explants were cultured at the air-liquid interface on 0.65 μm DV Durapore Membrane Filters (Merck Millipore, Cork, Ireland) in Iscove’s Modified Dulbecco’s Medium-Glutamax (IMDM-Glutamax, Thermo Fisher Scientific, Waltham, MA), 20% FCS (Lot #535905; Cat #FB-02; Omega Scientific, Tarzana, CA), 0.1 mM 2-Mercaptoethanol (Thermo Fisher Scientific, Waltham, MA), and 100 units/ml of Penicillin/Streptomycin (Thermo Fisher Scientific, Waltham, MA) supplemented with recombinant murine SCF, recombinant murine IL-3, and recombinant murine FLT3 Ligand (Peprotech, Rocky Hill, NJ, all at 100 ng/ml) (or with other cytokine combinations indicated along the text) for 9–10 days to allow engraftment from E8.5 tissues or for other time periods as detailed in each figure. Membrane filters were sterilized and rinsed three times in boiling water (five minutes/wash). Up to eight explants were carefully placed on each membrane filter. Filters were then placed on in-house-made ring stands (3.175 mm high; outside diameter: 32.3 mm; inside diameter: 23 mm; Teflon) positioned in the well of a non-tissue-culture-treated 6-well-plate (Corning, NY, USA) containing 2.25 mL of the above described culture media. Media was not refreshed during the culture. Explants were recovered from filters using a sterilized scalpel.
Freshly isolated embryonic tissues or cultured explants were dissociated with collagenase (0.0012 g/ml, Sigma-Aldrich, St. Louis, MO) in Phosphate-Buffered Saline (PBS, Thermo Fisher Scientific, Waltham, MA) supplemented with 10% FCS (Omega Scientific, Tarzana, CA). For flow cytometry cell sorting or analysis, dissociated cells were stained with one or more of these antibodies: CD45.2-V500 (104) (BD Biosciences, San Diego, CA), CD41-PerCP-eFluor710 (eBioMWReg30) (eBioscience, San Diego, CA), CD31-FITC (MEC13.3) (BD Biosciences, San Diego, CA), c-Kit-APC-eFluor780 (2B8) (eBioscience, San Diego, CA), Lyve1-PE (#223322) R&D Byosystems, Minneapolis, MN). All antibodies were used at 1:200 dilution. 4’,6-diamidino-2-phenylindole (DAPI) staining was used to gate live events. Analysis was performed on a LSR Fortessa and cell sorting on a BD FACSAria III SORP (Special Order Research Product) (both BD Biosciences, San Diego, CA). Cells were collected employing the BD FACSDiva Software (version 8.0.1) (BD Biosciences, San Diego, CA). Data was analyzed with FlowJo version 9.4.11 (Tree Star, Ashland, OR).
Statistics and reproducibility
Summary statistics, including mean and standard deviation, were reported for analyses. Two sample t or exact Wilcoxon rank sum test were used to test for a difference between two groups depending on the normality of the data, which was tested by the Shapiro-Wilk test. False discovery rate (FDR) method developed by Benjamini and Hochberg49 was used to correct for multiple comparisons at a level of 0.05. Otherwise, p-values < 0.05 were considered statistically significant. Analyses were conducted in R-3.3.1.
For limiting dilution analysis, parameters were estimated using a generalized linear model with a complementary log-log link. The generalized Pearson Chi-square was used to assess the goodness-of-fit to the model. The analyses were done using program L-Calc and ELDA online software50.
All in vitro experiments were reliably reproduced at least 3 times with the exception of Fig. 3Eii (the 5 days culture time point was n = 2) and Fig. 3Ei (within the 5 days culture time point the SCF/IL3 and the SCF conditions were n = 2). Sample size and number of experiment replicates are detailed in each Figure Legend.
Single cell RNA-seq
Sorted YS-Ex-CD31+CD45+c-Kit+CD41− and Em-Ex-CD31+CD45+c-Kit+CD41− were resuspended in PBS containing 0.04%BSA at a concentration of 500–600 cells/ul. In total, 8600 cells per sample were loaded into each well of a 10X Chromium single cell capture chip with a recovery of 3000–3500 cells per sample. The captured cells then underwent lysis, reverse transcription, cDNA amplification, and library preparation with indexing per the manufacturer’s protocol (10X Genomics). The libraries were sequenced together on an Illumina Nextseq500 (Illumina Inc., San Diego, CA) using a high output 150 cycle kit with read lengths recommended by 10X Genomics.
Single-cell RNAseq analysis
Raw data processing: Cellranger 2.0.151 was used to process the raw fastq files and to generate unique molecular identifiers (UMI) counts for each gene in each cell. The UMI count table was imported into R and analyzed with Seurat 2.1.0 package52. The raw counts were normalized using NormalizeData function with default parameters (normalization.method = LogNormalize). Cells expressing less than 1000 genes, more than 5000 genes or having over 5% mitochondria reads were removed from the analysis to exclude potential dead, broken or doublet cells. Bach effect is removed using R package scran v1.8.153 with k = 20, sigma = 0.1. To identify the X-cell population, R package Rtsne v0.1354 was used to reduce data dimension to two for visualization with perplexity = 20, initial_dims = 100. X-cell population was defined by clusters generated with R package pdfCluster v1.0-255 and selected for further analysis. R package scmap v1.1.556 was used to map single cells to cell clusters from Zhou et al.42 with threshold = 0.7. In detail, R package scmap v1.1.5 computed the similarity between expression profile of a single cell and centroid of cell clusters in the reference data56. Cells were assigned to reference cell clusters with the highest similarity. Multiple types of correlations (including Cosine similarity and Pearson and Spearman correlations) were calculated and at least one of them had to be larger than 0.7 (i.e., threshold = 0.7).
For analysis of CFU potential, 5–7sp embryos and YS were cultured as explants at the air-liquid interface for five or 10 days in the same conditions as indicated above (20% FCS, SCF, IL-3, FLT3L in IMDM). CD31+CD45+ and CD31−CD45− cells were then isolated by FACS and plated in M3434 methylcellulose (STEMCELL Technologies, Vancouver, Canada). Approximately 60,000 sorted cells were dispensed to 3 mL of M3434 and equally distributed into two plates (#27150, STEMCELL Technologies, Vancouver, Canada). Colonies were analyzed 10 days after plating.
E8.5 concepti were isolated and fixed in 4% paraformaldehyde (Electron Microscopy Sciences, Hatfield, PA) overnight at 4 °C. Concepti were then embedded in 4.5% low-melting-point agarose (Thermo Fisher Scientific, Waltham, MA) and sectioned (100 μm slices) using a vibratome (microtome with vibrating blade VT1200, Leica Byosystems Wetzlar, Germany). Sections were washed three times with PBS 0.3% Triton X-100 (Biorad, Hercules, CA) (30 min/wash) and permeabilized at 4 °C overnight in PBS 0.3% Triton X-100 (Biorad, Hercules, CA). Sections were then blocked in 0.3% Triton X-100 with 3% donkey serum (Sigma-Aldrich, St. Louis, MO) in PBS at 4 °C overnight. Sections were next incubated with previously conjugated anti-LYVE1 (Clone ALY7; eBioscience. San Diego, CA), anti-CD41 (Clone MWReg30; BD Bioscience, San Diego, CA), BV421−Rat Anti-Mouse CD31 (Clone MEC 13.3 (RUO); BD Biosciences, San Diego, CA) at 1:200 in 1% skimmed milk in 0.3% Triton X-100-PBS overnight. Anti-LYVE1 and anti-CD41 antibodies were conjugated following manufacture’s protocol to CFTM568 and CFTM488 fluorophores, respectively, using the Mix-n-StainTM labeling kits (Sigma-Aldrich, St. Louis, MO). Sections were then washed three times with 0.3% Triton X-100 in PBS (30 min/wash). Sections were mounted on Fisherbrand Superfrost Microscope Slides (Fisher Scientific, Pittsburgh, PA) and covered with 22 × 22 mm No.1.0 microscope cover glass (Infolab, Indianapolis, IN). Sections were imaged on a Zeiss LSM780 Confocal Microscope (Zeiss, Oberkochen, Germany) using a ×40, 1.1NA water immersion lens. Images were processed employing a ZEN 2012 software (Zeiss, Oberkochen, Germany).
The authors declare that all data supporting the findings of this study are available within the article and its supplementary information files or from the corresponding author upon reasonable request. Single-cell RNAseq data have been deposited in NCBI’s Gene Expression Omnibus (GEO) database under accession code GSE110909. The source data underlying Figs. 1, 2, 3, 4A, 5, 6A-C and 7 and Supplementary Figs. 1A, and 3 are provided as a Source Data file.
Medvinsky, A., Rybtsov, S. & Taoudi, S. Embryonic origin of the adult hematopoietic system: advances and questions. Development 138, 1017–1031 (2011).
Muller, A. M., Medvinsky, A., Strouboulis, J., Grosveld, F. & Dzierzak, E. Development of hematopoietic stem cell activity in the mouse embryo. Immunity 1, 291–301 (1994).
Medvinsky, A. & Dzierzak, E. Definitive hematopoiesis is autonomously initiated by the AGM region. Cell 86, 897–906 (1996).
Moore, M. A. & Owen, J. J. Chromosome marker studies on the development of the haemopoietic system in the chick embryo. Nature 208, 956 (1965). passim.
Moore, M. A. & Owen, J. J. Chromosome marker studies in the irradiated chick embryo. Nature 215, 1081–1082 (1967).
Moore, M. A. S. & Owen, J.J. T. Stem cell migration in developing myeloid and lymphoid systems. Lancet ii, 658–659 (1967).
Dieterlen-Lievre, F. On the origin of haemopoietic stem cells in the avian embryo: an experimental approach. J. Embryol. Exp. Morphol. 33, 607–619 (1975).
Weissman, I. L., Baird, S., Gardner, R. L., Papaioannou, V. E. & Raschke, W. Normal and neoplastic maturation of T-lineage lymphocytes. Cold Spring Harb. Symp. Quant. Biol. 41(Pt 1), 9–21 (1977).
Toles, J. F., Chui, D. H., Belbeck, L. W., Starr, E. & Barker, J. E. Hemopoietic stem cells in murine embryonic yolk sac and peripheral blood. Proc. Natl Acad. Sci. USA 86, 7456–7459 (1989).
Yoder, M. C. et al. Characterization of definitive lymphohematopoietic stem cells in the day 9 murine yolk sac. Immunity 7, 335–344 (1997).
Yoder, M. C., Hiatt, K. & Mukherjee, P. In vivo repopulating hematopoietic stem cells are present in the murine yolk sac at day 9.0 postcoitus. Proc. Natl Acad. Sci. USA 94, 6776–6780 (1997).
Cumano, A., Ferraz, J. C., Klaine, M., Di Santo, J. P. & Godin, I. Intraembryonic, but not yolk sac hematopoietic precursors, isolated before circulation, provide long-term multilineage reconstitution. Immunity 15, 477–485 (2001).
Samokhvalov, I. M., Samokhvalova, N. I. & Nishikawa, S. Cell tracing shows the contribution of the yolk sac to adult haematopoiesis. Nature 446, 1056–1061 (2007).
Lee, L. K. et al. LYVE1 marks the divergence of yolk sac definitive hemogenic endothelium from the primitive erythroid lineage. Cell Rep. 17, 2286–2298 (2016).
Metcalf, D. & Moore M. A. S. Embryonic aspects of haematopoiesis. In: Neuberger A., Tatum E.L. (eds.) Haematopoietic Cells. pp. 173–271, North-Holland Publishing Company, Amsterdam, London (1971).
Cormier, F. & Dieterlen-Lievre, F. The wall of the chick embryo aorta harbours M-CFC, G-CFC, GM-CFC and BFU-E. Development 102, 279–285 (1988).
Yvernogeau, L. & Robin, C. Restricted intra-embryonic origin of bona fide hematopoietic stem cells in the chicken. Development 144, 2352–2363 (2017).
Matsuoka, S. et al. Generation of definitive hematopoietic stem cells from murine early yolk sac and paraaortic splanchnopleures by aorta-gonad-mesonephros region-derived stromal cells. Blood 98, 6–12 (2001).
Tanaka, Y. et al. Circulation-independent differentiation pathway from extraembryonic mesoderm toward hematopoietic stem cells via hemogenic angioblasts. Cell Rep. 8, 31–39 (2014).
Fouquet, B., Weinstein, B. M., Serluca, F. C. & Fishman, M. C. Vessel patterning in the embryo of the zebrafish: guidance by notochord. Dev. Biol. 183, 37–48 (1997).
Gering, M., Rodaway, A. R., Gottgens, B., Patient, R. K. & Green, A. R. The SCL gene specifies haemangioblast development from early mesoderm. EMBO J. 17, 4029–4045 (1998).
Zovein, A. C. et al. Vascular remodeling of the vitelline artery initiates extravascular emergence of hematopoietic clusters. Blood 116, 3435–3444 (2010).
Frame, J. M., Fegan, K. H., Conway, S. J., McGrath, K. E. & Palis, J. Definitive hematopoiesis in the yolk sac emerges from wnt−responsive hemogenic endothelium independently of circulation and arterial identity. Stem Cells 34, 431–444 (2016).
Chen, M. J. et al. Erythroid/myeloid progenitors and hematopoietic stem cells originate from distinct populations of endothelial cells. Cell Stem Cell 9, 541–552 (2011).
Yzaguirre, A. D. & Speck, N. A. Extravascular endothelial and hematopoietic islands form through multiple pathways in midgestation mouse embryos. Dev. Biol. 415, 111–121 (2016).
Rybtsov, S., Ivanovs, A., Zhao, S. & Medvinsky, A. Concealed expansion of immature precursors underpins acute burst of adult HSC activity in foetal liver. Development 143, 1284–1289 (2016).
Ji, R. P. et al. Onset of cardiac function during early mouse embryogenesis coincides with entry of primitive erythroblasts into the embryo proper. Circ. Res. 92, 133–135 (2003).
McGrath, K. E., Koniski, A. D., Malik, J. & Palis, J. Circulation is established in a stepwise pattern in the mammalian embryo. Blood 101, 1669–1676 (2003).
Taoudi, S. et al. Extensive hematopoietic stem cell generation in the AGM region via maturation of VE-cadherin + CD45 + pre-definitive HSCs. Cell Stem Cell 3, 99–108 (2008).
Rybtsov, S. et al. Hierarchical organization and early hematopoietic specification of the developing HSC lineage in the AGM region. J. Exp. Med. 208, 1305–1315 (2011).
Rybtsov, S. et al. Tracing the origin of the HSC hierarchy reveals an SCF-dependent, IL-3-independent CD43(-) embryonic precursor. Stem Cell Rep. 3, 489–501 (2014).
Bertrand, J. Y. et al. Characterization of purified intraembryonic hematopoietic stem cells as a tool to define their site of origin. Proc. Natl Acad. Sci. USA 102, 134–139 (2005).
McKinney-Freeman, S. L. et al. Surface antigen phenotypes of hematopoietic stem cells from embryos and murine embryonic stem cells. Blood 114, 268–278 (2009).
Ferkowicz, M. J. et al. CD41 expression defines the onset of primitive and definitive hematopoiesis in the murine embryo. Development 130, 4393–4403 (2003).
Yokomizo, T. & Dzierzak, E. Three-dimensional cartography of hematopoietic clusters in the vasculature of whole mouse embryos. Development 137, 3651–3661 (2010).
Mikkola, H. K., Fujiwara, Y., Schlaeger, T. M., Traver, D. & Orkin, S. H. Expression of CD41 marks the initiation of definitive hematopoiesis in the mouse embryo. Blood 101, 508–516 (2003).
Mikkola, H. K. & Orkin, S. H. The search for the hemangioblast. J. Hematother. Stem Cell Res. 11, 9–17 (2002).
Liakhovitskaia, A. et al. Runx1 is required for progression of CD41 + embryonic precursors into HSCs but not prior to this. Development 141, 3319–3323 (2014).
Ding, L., Saunders, T. L., Enikolopov, G. & Morrison, S. J. Endothelial and perivascular cells maintain haematopoietic stem cells. Nature 481, 457–462 (2012).
Robin, C. et al. An unexpected role for IL-3 in the embryonic development of hematopoietic stem cells. Dev. Cell. 11, 171–180 (2006).
Gordon-Keylock, S., Sobiesiak, M., Rybtsov, S., Moore, K. & Medvinsky, A. Mouse extraembryonic arterial vessels harbor precursors capable of maturing into definitive HSCs. Blood 122, 2338–2345 (2013).
Zhou, F. et al. Tracing haematopoietic stem cell formation at single-cell resolution. Nature 533, 487–492 (2016).
McKinney-Freeman, S. et al. The transcriptional landscape of hematopoietic stem cell ontogeny. Cell Stem Cell 11, 701–714 (2012).
Muzumdar, M. D., Tasic, B., Miyamichi, K., Li, L. & Luo, L. A global double-fluorescent Cre reporter mouse. Genesis 45, 593–605 (2007).
Snippert, H. J. et al. Intestinal crypt homeostasis results from neutral competition between symmetrically dividing Lgr5 stem cells. Cell 143, 134–144 (2010).
Pham, T. H. et al. Lymphatic endothelial cell sphingosine kinase activity is required for lymphocyte egress and lymphatic patterning. J. Exp. Med. 207, 17–27 (2010).
North, T. E. et al. Runx1 expression marks long-term repopulating hematopoietic stem cells in the midgestation mouse embryo. Immunity 16, 661–672 (2002).
Ganuza, M. et al. Lifelong haematopoiesis is established by hundreds of precursors throughout mammalian ontogeny. Nat. Cell Biol. 19, 1153–1163 (2017).
Benjamini, Y. & Hochberg, Y. Controlling the false discovery rate: a practical and powerful approach to multiple testing. J. R. Stat. Soc. Ser. B 57, 289–300 (1995).
Hu, Y. & Smyth, G. K. ELDA: extreme limiting dilution analysis for comparing depleted and enriched populations in stem cell and other assays. J. Immunol. Methods. 347, 70–78 (2009).
Zheng, G. X. et al. Massively parallel digital transcriptional profiling of single cells. Nat. Commun. 8, 14049 (2017).
Butler, A., Hoffman, P., Smibert, P., Papalexi, E. & Satija, R. Integrating single-cell transcriptomic data across different conditions, technologies, and species. Nat. Biotechnol. 36, 411–420 (2018).
Lun, A. T., McCarthy, D. J. & Marioni, J. C. A step-by-step workflow for low-level analysis of single-cell RNA-seq data with Bioconductor. F1000Res. 5, 2122 (2016).
Krijthe, J. T-distributed stochastic neighbor embedding using Barnes-Hut implementation. R package version 0.13. https://github.com/jkrijthe/Rtsne (2015). Accessed Date: Feb 2018.
Azzalini, A., Giovanna, M. Clustering via nonparametric density estimation: the R Package pdfCluster. J. Stat. Softw. 57, 18637/jss.v18057.i18611 (2013).
Kiselev, V. Y., Yiu, A. & Hemberg, M. scmap: projection of single-cell RNA-seq data across data sets. Nat. Methods 15, 359–362 (2018).
We thank W. Clements, H. Mikkola, the McKinney-Freeman laboratory and Department of Hematology at St. Jude Children’s Research Hospital (St. Jude) for critical discussions and reading of the manuscript; D. Ashmun, S. Schwemberger, and J. Laxton for FACS support; C. Davis-Goodrum, K. Millican, A. Reap, and C. Savage for help with timed pregnancies and transplants. V. Frohlich, S. King, J. Peters and A. Pitre for help with confocal imaging. This work was supported by the American Society of Hematology (S.M.-F.), the Hartwell Foundation (S.M.-F.), the NIDDK (K01DK080846 and R01DK104028, S.M.-F.), the American Lebanese Syrian Associated Charities (ALSAC) (S.M.-F. and St. Jude Cell and Tissue Imaging Center), and the NCI (P30 CA021765-35, SJCRH Cell and Tissue Imaging Center) and the Burroughs Wellcome Fund (C.G.).
The authors declare no competing interests.
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Ganuza, M., Chabot, A., Tang, X. et al. Murine hematopoietic stem cell activity is derived from pre-circulation embryos but not yolk sacs. Nat Commun 9, 5405 (2018). https://doi.org/10.1038/s41467-018-07769-8