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First published online 12 April 2006
doi: 10.1242/dev.02349
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1 Immunobiology and Cancer Program, Oklahoma Medical Research Foundation, 825 NE
13th Street, Oklahoma City, OK 73104, USA.
2 Department of Microbiology and Immunology, University of Oklahoma Health
Sciences Center, Oklahoma City, OK 73190, USA.
3 INSERM U506, Hopital Paul Brousse, 94807 Villejuif, France.
4 Department of Immunology, University of Toronto, Sunnybrook and Women's
Research Institute, Toronto, ON M4N 3M5, Canada.
5 University of Pittsburgh and Children's Hospital, Rangos Research Center,
Pittsburgh, PA 15213, USA.
* Author for correspondence (e-mail: kincade{at}omrf.ouhsc.edu)
Accepted 8 March 2006
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SUMMARY |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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25-somite
embryos produced myelo-erythroid cells but no lymphocytes. Notch receptor
signaling directed P-Sp cells to T lymphocytes but did not confer
lymphopoietic potential on YS cells. Thus, definitive hematopoiesis arises in
at least two independent sites that differ in lymphopoietic potential.
Expression of RAG1, the earliest known lymphoid event, first occurred around
E10.5 within the embryos. RAG1/GFP+ cells appeared in the liver at
E11.0 and progenitors with B and/or T lineage potential were enumerated at
subsequent developmental stages.
Key words: Para-aortic splanchnopleura/aorta-gonad-mesonephros, Yolk sac, Thymus, Liver, Mouse
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INTRODUCTION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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; Rossi et al.,
2003). This process depends on stem cells defined in mice
according to marker expression and long-term repopulating potential after
transplantation to lethally irradiated recipients
(Spangrude et al., 1988).
Considerable information is available about the surface properties and gene
expression of these stem cells, but many questions remain about their
origin(s) during embryonic and fetal life
(Dzierzak, 2003;
Peault and Tavian, 2003;
Phillips et al., 2000).
Indeed, fetal stem cells and primitive lymphoid cells differ in a number of
respects from their adult counterparts
(Kincade et al., 2002;
Yokota et al., 2003).
Furthermore, there is evidence that hematopoietic stem cells (HSC) can arise
from endothelial progenitors at multiple sites and stages of development
(Oberlin et al., 2002). This
raises the important possibility that independently arising stem cells yield
distinct components of the immune system. Immune defense in the fetal/neonatal
period might be provided by lymphocytes that are replaced from later emerging
stem cells (Emambokus and Frampton,
2003; Mikkola et al.,
2003b; Oberlin et al.,
2002). Precise information about dynamics and characteristics of
lymphoid populations would be helpful in resolving this important issue. The
goals of this study were to localize and precisely time the appearance of
progenitors for the first lymphocytes in embryonic life.
The relative importance of stem cells arising in intra-embryonic and
extra-embryonic sites to definitive hematopoiesis has been extensively studied
(Cumano et al., 1996;
Cumano et al., 2001;
Medvinsky and Dzierzak, 1996;
Müller et al., 1994;
Tavian et al., 2001).
Primitive hematopoietic cells first appear within blood islands of the yolk
sac (YS), but may be compromised with respect to lymphopoiesis
(Godin and Cumano, 2002;
Metcalf and Moore, 1971;
Palis and Yoder, 2001).
Indeed, a four decade controversy regarding the origin of HSC endowed with
lymphopoietic activity is still unsettled
(Moore, 2004;
Nishikawa et al., 1998). It
appears likely that HSC that generate definitive red blood cells and
lymphocytes emerge in association with the vasculature of the
aorta-gonad-mesonephros (AGM) region, derived in part from the paraaortic
splanchnopleura (P-Sp) (de Bruijn et al.,
2002; Godin et al.,
1999; Tavian et al.,
1996; Tavian et al.,
1999). Recent studies also show that the placenta may be a major
site for expansion, if not production, of stem and progenitor cells
(Gekas et al., 2005;
Ottersbach and Dzierzak,
2005). However, it has been argued that stem cells in the YS of E9
murine embryos are also capable of long-term multilineage reconstitution when
transplanted into appropriately conditioned newborn mice
(Yoder et al., 1997a;
Yoder et al., 1997b).
Therefore, doubt remains about the source of stem cells that account for the
first lymphocytes. Moreover, the route connecting the first lymphopoietic
cells to early lymphocyte progenitors (ELP) in liver or thymus is unclear.
Notch 1, but not Notch 2 is essential for conversion from primitive to
definitive stages of hematopoiesis and the use of intra-embryonic rather than
extra-embryonic sites (Kumano et al.,
2003). It has also been reported that primitive hematopoietic
cells can be converted to definitive ones by culture on AGM-derived stromal
cells or by inducing HoxB4 gene expression
(Kyba et al., 2002;
Matsuoka et al., 2001). This
suggests an important role for environmental cues such as Notch ligands that
might be exclusive to intra-embryonic sites and we investigated that with
respect to lymphopoiesis.
Elegant studies demonstrated that the thymus in avian embryos is populated
and then repopulated by hematopoietic cells during discrete periods
(Jotereau and Le Douarin,
1982). The thymus rudiment in mice is colonized at around
embryonic day 11, but it is not clear if the first immigrants arise entirely
or in part from intraembryonic stem cells. In addition, previous studies have
reached different conclusions about the degree to which the first thymus
immigrants begin the T-lymphoid differentiation program before migrating to
that site (Delassus and Cumano,
1996; Hattori et al.,
1996; Ikawa et al.,
2004; Péault et al.,
1994). Nonetheless, there is near consensus regarding rapid
commitment to the T-cell lineage on entry to the thymus because B lineage
potential drops abruptly at E12-13 and is very rare at E14
(Péault et al., 1994;
Schmitt et al., 2004). Fetal
liver contains lymphoid progenitors with some degree of dedication to the T
lymphoid lineage (Ema et al.,
1998; Kawamoto et al.,
2000; Yokota et al.,
2003). Their relationship to the thymus also requires further
study. The liver is a major site for expansion of long term repopulating stem
cells (Ema and Nakauchi, 2000;
Kumaravelu et al., 2002) and
lymphocyte production in that organ has been characterized as being a
synchronous wave (Strasser et al.,
1989). This process has also been the subject of intense
investigation, and the most numerous lymphocytes are dedicated to the B
lineage (Yokota et al., 2003).
A better understanding of lymphoid population dynamics in the fetal liver
should be informative about many aspects of immune system development.
Analysis of RAG1/GFP knock-in mice revealed that RAG1 expression is a valid
marker for the most primitive lymphoid progenitors in bone marrow and fetal
liver (Igarashi et al., 2002;
Yokota et al., 2003). This
feature was exploited in the present study to learn how the very first
populations of lymphocytes arise. We confirmed that the first lymphopoietic
cells are contained within the angiopoietin receptor Tie2+ category
of the P-Sp region and conclude that they must arise independently of the
first definitive myelo-erythropoietic cells in the YS. Furthermore, we
localized the earliest RAG1 expressing cells in the embryo proper. The RAG1
locus is activated in some thymus colonizers while still in the surrounding
mesenchyme, and this event is followed by very rapid progression through the
first stages of T lymphopoiesis. In addition to its role as a major producer
of B lineage cells, the liver generates progenitors that can contribute to
secondary waves of T lymphopoiesis. Thus, it is now possible to appreciate how
unique lymphopoietic cells arise within the embryo and spawn the first
components of the immune system.
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MATERIALS AND METHODS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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;
Yokota et al., 2003). Mating
homozygous male RAG1/GFP knock-in mice with wild-type C57BL/6 strain female
mice generated heterozygous RAG1/GFP embryos with no contaminating maternal
RAG1/GFP+ cells. In this study, the day of vaginal plug observation
was considered as day 0.5 post-coitus (E0.5), and the staging of embryos was
carefully confirmed by counting somite pairs.
Antibodies
FITC-conjugated anti-CD41 (MWReg30), anti-CD34 (RAM34) and anti-Kit (2B8)
mAbs; PE-conjugated anti-CD19 (1D3), ant-TCR
(GL3), anti-Kit
(2B8), anti-CD11b/Mac-1 (M1/70), anti-Sca1 (Ly6A/E; D7) and anti-CD25 mAbs;
biotinylated anti-CD34 (RAM34) and anti-AA4.1 mAbs; allophycocyanin
(APC)-conjugated anti-Kit (2B8), anti-TCRß (H57-597) and anti-CD44 (1M7)
mAbs; and purified anti-PECAM-1/CD31 (MEC13.3) mAb were all purchased from BD
Pharmingen. PE-conjugated anti-Tie2 (TEK4) and APC-conjugated anti-CD45
(30-F11) mAbs were purchased from eBioscience. A PE-conjugated goat-anti-rat
IgG Ab was purchased from Southern Biotechnology. A phycoerythrin-Texas Red
tandem-conjugated streptavidin (PE-TR-streptavidin) was purchased from
Caltag.
Immunohistochemistry
Embryos were accurately staged by counting somites and fixed in PBS
containing 4% paraformaldehyde at 4°C overnight. Fixed embryos were
embedded in PBS containing 7.5% gelatin, frozen in isopentane, cooled and then
stored at -80°C. Cryostat sections (10 µm) were thawed and hydrated in
PBS. As the intensity of GFP fluorescence decreases after fixation, the signal
was amplified using an anti-GFP antibody. Slides were incubated overnight at
4°C with rabbit anti-GFP antibody (MBL, Japan), then washed in PBS and
incubated at room temperature with Alexa Fluor 488-conjugated goat anti-rabbit
antibody (Molecular Probes). Sections were mounted in Mowiol (Calbiochem) and
examined under a DMR/HCS fluorescence microscope (Leica).
Flow cytometry
To determine the earliest timing of RAG1/GFP+ cell emergence in
embryonic development, embryos were prepared between E6.5 and E11.5. Whole
embryos or their dissected organs were mechanically minced, trypsinized,
filtered through a nylon mesh of 70 µm (Cell Strainer; Falcon) into single
cell suspensions and then evaluated by flow cytometry. The cells were stained
with APC-conjugated anti-CD45 and 7-amino actinomycin D (7AAD, Calbiochem).
Viable CD45+ cells were plotted on FL1-FL2 profiles without
compensation. Gating for authentic GFP+ cells and exclusion of
auto-fluorescent cells was performed as previously described
(Yokota et al., 2003).
To examine the phenotype of hematopoietic cells in early embryos or those generated in organ cultures, tissues were dissociated by incubation with dispase II (Roche Diagnostics) for 20-30 minutes at 37°C and cell dissociation buffer (Invitrogen) for 30 minutes at 37°C followed by vigorous pipetting. The cells were resuspended in PBS containing 3% FCS and meshed to remove debris. After incubation with anti-FcR (2.4G2), the cells were stained with mAbs, suspended in 7AAD-containing buffer and analyzed.
In other experiments, sorted or cultured cells were incubated with anti-FcR and then stained with FITC-, PE-, APC-conjugated mAbs and a biotinylated Ab followed by PE-TR-streptavidin. All the flow cytometry analyses were performed with a FACScalibur using the Cellquest program (Becton Dickinson).
Organ cultures
The stromal cell line OP9 (a kind gift from Dr S.-I. Hayashi, Tottori
University), MigR1(OP9-control) and murine Delta 1-like transduced OP9
(OP9-DL1) (Jaleco et al.,
2001; Schmitt and
Zúñiga-Pflücker, 2002;
Witte et al., 1986) was
maintained in 
-MEM (Invitrogen, Carlsbad, CA) supplemented with 20% FCS
(Hyclone, Logan, UT). Embryos were sterilely dissected under the microscope
and the tissues (see Table 1)
were placed on OP9 stromal cells prepared in six-well plates. The tissues were
mechanically dissociated with 26-gauge needles and cultured in -MEM
supplemented with 20% FCS for 14 days by feeding with half medium changes
every 2 days. When exogenous cytokines were used for T lineage
differentiation, 5 ng/ml FLT3 ligand and 5 ng/ml IL7 (R&D systems,
Minneapolis, MN) were added to the medium supplemented with 10% FCS and 50
µM 2-ME. At the end of culture, the tissues and cells were harvested from
culture, treated with dispase II and cell dissociation buffer to make single
cell suspensions, that were then subjected to flow cytometry analyses.
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E11.5-15.5 fetal livers were harvested and subjected to cell sorting as
described previously (Yokota et al.,
2003). In the first step, the cells were sorted into three
populations (GFP-, GFPLo, GFPHi), according
to levels of GFP expression. The cells were then fractionated according to
Sca1 and Kit expression.
Methylcellulose culture
Two hundred and fifty cells of each sorted fraction (see
Table 2) were cultured and
evaluated for their colony forming activity in IMDM-based methylcellulose
medium (Methocult GF3434, StemCell Technologies) as previously described
(Yokota et al., 2003).
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RESULTS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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; Melchers,
1979; Ottersbach and Dzierzak,
2005; Yoder et al.,
1997a; Yoder et al.,
1997b), as well as the P-Sp/AGM
(de Bruijn et al., 2002;
Godin et al., 1999;
Tavian et al., 1996;
Tavian et al., 1999) area
within embryos, are sites known to be primary sites for initial generation
and/or expansion of hematopoietic stem cells. Small numbers of
GFPLo CD45+ hematopoietic cells were present in the yolk
sac and embryo bodies from E10.5, while they were also detectable in the
placenta from E11.5 (Fig. 1A).
Given the numbers of viable GFPLo CD45+ cells, the
embryo proper was the principal location of lymphoid progenitors and they
expanded nearly 18-fold during this one day interval
(Fig. 1B). The AGM region also
contained a conspicuous GFP+ population at E11.5. However, this is
unlikely to be an active site for lymphopoiesis, because percentages of
GFP+ cells were not higher in this organ than in peripheral blood
or other non-hematopoietic organs throughout the embryonic period (data not
shown). We conclude that spontaneous RAG1/GFP expression initiates and expands
in the embryo proper at around E10.5.
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1%) displayed surface IgM (see Fig. S1 in the
supplementary material).
Thus, primitive cells with the potential of generating the earliest
lymphoid progenitors in stromal cell co-cultures are localized in the P-Sp
area by E9.5. These lymphopoietic cells were easily detectable in the
circulation, limbs, neck area and liver beyond E10.5, a stage when the
circulation is known to be fully established
(McGrath et al., 2003).
Primitive fetal cells that give rise to the immune system are responsive to Notch signals and can be directed to a T lineage lymphoid fate
Notch1 plays a key role in initiation of the definitive hematopoiesis
program (Kumano et al., 2003)
and we hypothesized that signaling via this receptor might induce
lymphopoietic potential in extra-embryonic cells. However, neither RAG1/GFP
nor B/T lineage markers were expressed when 15-20 somite YS cells were
cultured with OP9 stromal cells transduced with the Delta 1 Notch ligand,
OP9-DL1 (Schmitt and
Zúñiga-Pflücker, 2002)
(Fig. 2A). By contrast, P-Sp
progenitors were very responsive to Notch signals and could be directed into
the T lymphocyte lineage. They generated numerous RAG1/GFP+
CD45R/B220+ CD19+ cells on OP9-control cells (see Fig.
S1 in the supplementary material), but B lymphopoiesis was completely arrested
and conspicuous populations of TCR+ cells appeared in OP9-DL1
co-cultures (Fig. 2A). T
lineage progression was also demonstrable with respect to CD4 and CD8
expression (data not shown). Given that TCR+ cells
normally constitute the first wave of lymphopoiesis in the fetal thymus
(Havran and Allison, 1988), it
was surprising to find that most lymphocytes produced in OP9-DL1 cultures
expressed TCRß (Fig. 2B).
We then reduced concentrations of FCS from 20% to 10% and added the cytokines
Flt3 ligand and IL7 to one group of cultures. Total cell recoveries were
three- to fivefold higher, yields of TCR+ cells were
five- to eightfold more and TCRß+ cells were still present
under these conditions (Fig.
2B,C). Thus, primitive cells located within the P-Sp region of
early embryos have the potential to make both major subsets of T lymphocytes,
as well as B cells. Ligation of Notch receptors is sufficient to shift
differentiation from the B lineage to the T lineage, and the ratio of
TCR+ to TCRß+ cell production
is influenced by cytokines.
Characteristics of the earliest lymphopoietic progenitors
Flow cytometry experiments were then conducted to learn more about the
properties of cells in early embryos endowed with the potential of generating
lymphocytes in co-cultures. In particular, we used markers that have
previously been used to characterize hemangioblasts, hemogenic endothelial
cells and HSC. For example, the CD41 integrin is reportedly expressed by
definitive HSC in YS (Corbel and Salaun,
2002; Mikkola et al.,
2003a; Mitjavila-Garcia et
al., 2002). We could easily resolve CD41+ cells in E9.5
(19-25 somites) YS and they could be further divided into subsets according to
Kit or CD45 expression (Fig.
3A). CD41+ YS cells yielded myelo-erythroid cells in
methylcellulose cultures (Table
2). Indeed, 922 and 100 hematopoietic colonies were developed when
a total of 26,150 CD41+ Kit+ cells or 29,700
CD41+ Kit- cells were cultured with OP9 stromal cells.
However, no GFP+ or CD19+ cells were produced among the
1022 clones derived from CD41+ E9.5 YS cells
(Table 2; see Fig. S2 in the
supplementary material). This again indicates that YS initially lacks
lymphopoietic cells demonstrable with the OP9-DL1 co-culture system.
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), and
small numbers of RAG1/GFP+ fetal liver cells express this marker
(Yokota et al., 2003).
However, few distinctly positive cells were found in the E8.5-9.5 P-Sp.
Therefore, we used the Tie2 angiopoietin receptor that has also been found on
hemogenic endothelium at E10.5 (Hamaguchi
et al., 1999). As shown in Fig.
3B, 1-2% of total mononuclear cells in E9.5 P-Sp/AGM clearly
expressed this receptor and the Tie2+ cells were further
characterized as CD34Lo/- Kit+. The efficiency of generating CD45+ GFP+ CD19+ cells was reduced when the P-Sp was enzymatically dissociated and sorted before OP9 co-culture. However, 21 clones of hematopoietic cells developed when a total of 24,890 Tie2+ P-Sp cells were cultured with OP9 cells, and 12 out of the 21 clones contained RAG1/GFP+ CD45+ CD19+ cells (Table 2; see Fig. S2 in the supplementary material). No hematopoietic colonies developed from Tie2- cohorts. Flow cytometry analyses further verified that the colonies derived from YS cells in the OP9 co-culture contained no RAG1/GFP+ CD45+ CD19+ cells, while those from Tie2+ P-Sp cells generated robust B lymphocytes (Fig. 3C). As a more stringent test of lymphopoietic potential, stem cell factor, Flt3 ligand and IL7 were added to the OP9 co-cultures. Confluent populations of approximately 80% CD19+ GFP+ lymphocytes were produced within 10 days from E9.5 Tie2+ P-Sp/AGM cells, while the Tie2- cohort contained no activity (T.Y., unpublished). Surprisingly, no myeloid colonies were grown from a total of 2,500 Tie2+ P-Sp/AGM cells in methylcellulose cultures in three experiments. Only small numbers of non-lymphoid cells arose when the same fraction was placed in stromal cell co-cultures. Thus, the most primitive of lymphopoietic cells have been localized in the P-Sp and defined as Tie2+ RAG1- CD34Lo/- Kit+ CD41-.
Initiation of lymphopoiesis in the fetal thymus
The thymus rudiment is devoid of lympho-hematopoietic potentiality until
E10.5 when an influx of progenitors begins
(Owen and Ritter, 1969).
GFP+ cells, which were actually the first ones during embryonic
development, became conspicuous both within and surrounding the thymus
rudiment slightly later (Fig.
4A, left panel). At E12.5, lymphoid progenitors were more
circumscribed and completely surrounded by epithelium in the E14.5 thymus
(Fig. 4A, middle and right
panels). Sufficient cells could be obtained from the E12.5 thymus for flow
cytometry analysis. At that stage, more than 70% of the CD45+
mononuclear cells in the thymus expressed GFP and virtually all hematopoietic
cells became GFP positive at E13 (Fig.
4B; T.Y., unpublished). Gating on those GFP+ cells
revealed surprisingly homogeneous expression of Kit, CD34 and PECAM1/CD31
(Fig. 4C). Although E12.5
thymocytes were also uniformly CD4- CD8-
CD44+ CD25- and Mac-1Lo, they rapidly
differentiated (Fig. 4C,D;
T.Y., unpublished). Indeed, nearly half of the cells, and especially ones with
very high levels of GFP, had already progressed to the CD44+
CD25+ DN2 stage in E13 embryos. These observations indicate that
activation of the RAG1 locus by KitHi CD34+
CD31+ CD4- CD8- CD44+
CD25- Mac-1Lo progenitors occurs within the vicinity of,
or immediately after entry into, the thymus rudiment.
Population dynamics in the fetal liver
Organ culture data suggest that the fetal liver is colonized with
hematopoietic cells as early as E9.0, a stage when its anlage emerges in the
mesodermal septum transversum (Metcalf and
Moore, 1971; Zaret,
1998). Thereafter, it is a major site for stem cell production and
our goal was to chart accurately the appearance and expansion of lymphoid
progenitors. RAG1 locus activation does not begin in this site until E11.0
(data not shown). This timing is important because it indicates that the first
GFP+ cells in liver could not contribute to ones emerging in the
thymus at E10.5. At E11.5, one liver contained 800 RAG1/GFP+
CD45Hi cells that corresponded to 3.8% of the CD45+
cells (Fig. 5A). These earliest
spontaneously arising GFP+ cells were Kit+
Mac-1+ AA4Lo (Fig.
5A), properties that closely correspond to fetal stem cells
(Godin and Cumano, 2002;
Jordan et al., 1990;
Morrison et al., 1995). This
observation indicates that the first wave of hepatic lymphopoiesis may arise
directly from immigrant stem cells.
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). The
OP9-DL1 co-culture system provided a means to simultaneously detect T and B
lineage potential of these otherwise well characterized progenitors.
RAG1/GFPHi progenitors that have high B potential in stromal cell
free cultures (Yokota et al.,
2003) were suppressed on OP9 stromal cells. OP9-DL1 completely
blocked B lineage progression of RAG1/GFPLo cells and promoted them
to T lymphopoiesis. The RAG1/GFPLo KitHi
Sca1+ fraction was particularly effective in generating
TCR+ cells on OP9-DL1 (Fig.
5B). Surprisingly, the HSC containing RAG1-
KitHi Sca1+ fraction did not produce large numbers of
T-lineage cells in this model, although the same subset efficiently gave rise
to CD19+ cells on OP9. Furthermore, we know that the OP9-DL1
stromal cells support T lymphopoiesis from primitive P-Sp cells
(Fig. 2). These results suggest
that, while hepatic RAG1/GFPLo cells produce the first wave of B
lymphopoiesis, they can also contribute to early T lineage development in
thymus around E14.
Fig. 5C shows the kinetics
of hepatic lymphopoietic progenitors resolved according to these parameters.
The RAG1/GFPLo KitHi Sca1+ subset, that was
the most potent with respect to T lineage in OP9-DL1 co-cultures peaked in
number (6x104 liver) at E14.5. Restricted B lineage
progenitors detectable in stromal cell free cultures are present in the
GFPHi KitLo Sca1- fraction and a majority
(75%) of them express CD19 at E14.5
(Yokota et al., 2003). Numbers
of these cells increased dramatically from E14.5
(Fig. 5C). Indeed, there was
logarithmic expansion of CD19+ lymphocytes between 12.5 and 15.5
days of gestation.
Thus, hepatic lymphopoiesis begins around E11.0 and leads to explosive production of B lineage cells. Smaller numbers of cells with T lymphoid potential are present slightly later and might participate in secondary seeding of the thymus.
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DISCUSSION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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Lymphopoietic cells first arise in an intraembryonic site
The earliest hematopoietic cells appear within YS blood islands at around E
7.0 (pre-somite stage), followed by the P-Sp region at E9.5 (24-27 somites)
(Medvinsky et al., 1993).
Previous studies used RT-PCR to conclude that trace levels of RAG1 and RAG2
were detectable as early as E9.5, while active B lymphocyte precursors emerged
in both liver and AGM at E11.5 (De
Andrés et al., 2002;
Marcos et al., 1997). It has
been reported that the placenta contains B cell precursors and recent studies
indicate that site harbors many stem/progenitor cells
(Gekas et al., 2005;
Ottersbach and Dzierzak, 2005;
Melchers, 1979). In our
analysis, RAG1/GFP+ cells were undetectable before E10.5 and
careful examination did not thereafter reveal a concentration within either
the YS, P-Sp/AGM or placenta. Rather, the highest density was in the vicinity
of the thymus rudiment around E11.0 and it appears unlikely the placenta is a
primary lymphopoietic organ.
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;
Nishikawa et al., 1998;
Ogawa et al., 1988;
Tavian et al., 2001). This
powerful approach revealed that progenitors of RAG1/GFP+ cells were
often present after E8.5 (eight somites) within the P-Sp, and after E9.5 (21
somites) in the YS. Although the vasculature and heart develop earlier, actual
blood cell circulation was documented at E9.0
(McGrath et al., 2003). Many
studies have shown that HSC bud from endothelial cells and are thus poised to
be distributed from that time (de Bruijn et
al., 2000; Oberlin et al.,
2002; Tavian et al.,
1999; Tavian et al.,
1996). In addition, the vitelline artery connecting the AGM and YS
is one site for de novo stem cell production
(de Bruijn et al., 2000;
Tavian et al., 1999).
Determining the origin of stem/progenitor cells is therefore difficult at or
beyond the E9.0 stage.
Our data supports previous work in indicating that lymphocytes derive from
progenitors that are produced in an intra-embryonic site
(Cumano et al., 1996;
Cumano et al., 2001;
Nishikawa et al., 1998).
Although the P-Sp/AGM environment is apparently unable to initiate lymphoid
gene expression, it generates cells that commit to that fate on migration to
other organs. In that context, it is interesting that co-culture with an AGM
derived stromal cell line altered YS stem cells such that they could give rise
to lymphocytes on transplantation
(Matsuoka et al., 2001). It is
possible that YS-derived progenitors migrate to the AGM and acquire
lymphopoietic potential, but a lineage tracing experiment in Xenopus
indicates that it is an unlikely event
(Ciau-Uitz et al., 2000). In
addition, we found differences in surface markers displayed by progenitors in
the YS and P-Sp (Fig. 3).
Notch1 is essential for establishment of intraembryonic definitive
hematopoiesis (Kumano et al.,
2003) and might represent a cue for generation of lymphopoietic
cells. However, we found that lymphocytes were not produced when E8.5 YS was
held on Delta1 transduced OP9 stromal cells.
CD41 has been reported to be a marker for definitive hematopoiesis in YS
(Mikkola et al., 2003a) and we
thought that display of this marker would provide evidence for a relationship
to the first lymphopoietic cells. However, we found that while the
non-lymphoid progenitors that develop in OP9 co-cultures were
CD41+, sorting for this characteristic from the YS of
25-somite embryos did not enrich primitive cells with the potential to
express RAG1/GFP. Cumano and colleagues recently published a description of
E10.5 AGM, where extremely low levels of CD41 were present on multipotent
progenitors (Bertrand et al.,
2005). Their interesting study suggests that many of the
lymphopoietic cells we have characterized at E9.5 could be located in
sub-aortic patches as mesodermal ancestors of HSC. However, surface levels of
CD41 at that early stage did not permit its use in manipulation of
intraembryonic hematopoietic cells.
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;
Takakura et al., 1998). We
found Tie2+ Kit+ CD34Lo/- cells in the E9.5
P-Sp/AGM and showed that they could give rise to RAG1/GFP+
CD19+ lymphocytes in stromal cell co-cultures. These findings
confirm that this antigen marks the first lymphopoietic cells in embryonic
life. However, it is still unclear whether those cells correspond to hemogenic
endothelium, `definitive' HSC or other cell types. Two groups reported that
multipotent long-term reconstituting HSC dominantly emerge in P-Sp/AGM,
although this occurs after E10.0 (30 somites) in mice
(Cumano et al., 2001;
Medvinsky and Dzierzak, 1996;
Müller et al., 1994).
It will be interesting to explore the relationship of Tie2+
progenitors in E9.5 P-Sp/AGM to subsequent waves of lymphopoiesis and learn if
they are involved in replenishment of the immune system throughout life.
Fate-mapping experiments with additional markers could be used to address this
important issue. In this context, it is interesting that CD41 only marks a
small subset of lympho-hematopoietic cells after the fetal/neonatal stage
(Emambokus and Frampton,
2003). We conclude that CD41+ YS cells lacking lymphoid
potential produce the first wave of definitive hematopoiesis and are
subsequently replaced by Tie2+ cells that initially generate the
immune system.
RAG1 gene expression in the vicinity of the thymus rudiment
The first wave of T lymphopoiesis, characterized by TCR /
receptor expression (Havran and Allison,
1988), probably derives from P-Sp/AGM progenitors or ones that
leave the liver before substantial progression in any lymphoid lineage. In the
avian embryo where the liver is not hematopoietic, the first T progenitors
originate in paraaortic mesoderm and initially colonize the thymus via blood
delivery (Dunon et al., 1999).
There has long been a controversy regarding the potential of the earliest
thymus immigrants (Delassus and Cumano,
1996; Hattori et al.,
1996; Ikawa et al.,
2004; Péault et al.,
1994) Some groups thought they were multipotent, whereas others
insisted that commitment to T lineage was determined at a pre-thymic stage.
Those conclusions might not be mutually exclusive, as recently discussed
regarding T-lymphopoiesis in adults
(Petrie and Kincade, 2005). We
show here that the RAG1 locus is activated even before cells are fully
encapsulated within the E11.25 thymus, although the cells retain surface
markers corresponding to HSC (Fig.
4) (Suniara et al.,
1999). Transcription of the ikaros gene was also detectable in
progenitors before they entered the thymic epithelial region
(Itoi et al., 2001). Thymic
mesenchymal cells, which still surround the thymus anlage at E11.5, may create
an environment that is crucial for early T cell development
(Suniara et al., 2000), or the
process could be initiated in fetal liver progenitors
(Harman et al., 2005;
Ikawa et al., 2004). As fetal
thymocytes normally use / T cell receptors, it was surprising to
find that TCRß lymphocytes predominated in co-cultures initiated
with P-Sp/AGM cells. However, addition of IL7 to the cultures enhanced
production of TCR+ cells. Cytokine concentrations in
early fetal versus later thymuses might account in part for the TCR
rearrangement and selection events needed to generate these two major types of
T lymphocytes (Kang and Der,
2004; Zamisch et al.,
2005). Appropriate and timely delivery of Notch signals may also
govern the /ß versus / choice
(Washburn et al., 1997;
Wolfer et al., 2002). It is
only important to stress here that the most primitive lymphopoietic cells thus
far identified have the potential to generate both.
The fetal liver provides an environment for expansion of B lineage cells and generation of secondary thymic colonizers
Several significant points emerged from our analysis of lymphoid
progenitors in liver. RAG1/GFPHi subsets of lymphoid progenitors in
the developing liver accumulated in concert with organ size. Many studies have
documented tremendous expansion of B-lineage cells in that site
(Strasser et al., 1989). The
conspicuous GFPHi KitLo Sca1- subset
expresses little GATA3 and rapidly generates CD19+ cells in stromal
cell free cultures (Yokota et al.,
2003). However, all GFP+ subsets are in cycle (20-30%
in S+G2+M) and rapidly incorporate BrdU (R. Pelayo, unpublished). Therefore,
there must be rapid progression through differentiation stages and/or export
to other organs. The GFPLo cells in E13-14 liver would seem to be
good candidates for secondary thymus seeding and some of them might represent
the KitLo progenitors of TCR /ß+ T cells
present in blood at that stage (Carlyle and
Zúñiga-Pflücker, 1998;
Rodewald et al., 1994).
There has been substantial controversy concerning the presence of lymphoid
restricted progenitors in fetal tissues. For example, a series of impressive
studies used a fetal thymic organ culture system to conclude that single T/B
restricted cells without myelo-erythroid potential do not exist
(Katsura, 2002). We have
recently found that non-lymphoid options are sharply downregulated with
activation of the RAG1 locus in fetal liver cells and RAG1Lo
Kitlo subsets had the most potential for T lineage differentiation
in a fetal thymus reaggregate culture containing IL3
(Yokota et al., 2003). We now
report that the best subsets for T cell production in OP9-DL1 co-cultures
expressed Kit at high density (Fig.
5B). A RAG1Lo Kitlo Sca1+
fraction was an efficient source of CD19+ B lineage cells when
cultured with OP9 stromal cells and, although this activity was blocked by
expression of Delta1, they generated only small numbers of TCR+
lymphocytes. These observations highlight the importance of experimental
conditions in determining how differentiation potential is assessed. In
addition, we stress that production of B cells from non-committed progenitors
would not be possible within a micro-environmental niche that is ideal for T
lymphopoiesis (Schmitt and
Zúñiga-Pflücker, 2002). Two RAG1Lo
KitHi fractions of fetal liver are rich in progenitors for the two
lymphoid lineages, but it would be difficult to ascertain if individual ones
are B-only, T-only or bi-potent. That would require expansion of individual
cells without introducing bias and then separately testing aliquots of progeny
cells under ideal conditions for each lineage.
Concluding remarks
Our data support and extend previous studies
(Godin and Cumano, 2002;
Tavian et al., 2001) in
suggesting that the P-Sp/AGM first generates lymphopoietic cells. Although
adult-type myelo-erythroid progenitors may emerge from a CD41+
population found in the YS, that organ is unlikely to be essential for
building the immune system. Indeed, lymphoid progenitors previously found in
the YS (Paige et al., 1979;
Weissman et al., 1977) could
have arisen in the P-Sp and migrated to extra-embryonic tissues via the
circulation. Lymphopoietic potential appears independently of the YS and is
associated with a Tie2+ Kit+ CD34Lo/-
CD41- subset that may arise even before conventional stem cells.
Activation of the RAG1 locus is one of the earliest events in lymphopoiesis
and that first occurs in an intra-embryonic site.
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ACKNOWLEDGMENTS |
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Footnotes |
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Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/133/10/2041/DC1
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REFERENCES |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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