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First published online 11 June 2008
doi: 10.1242/dev.022707
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1 Ecole Polytechnique Fédérale de Lausanne (EPFL), ISREC-Swiss
Institute for Experimental Cancer Research, School of Life Science, 1066
Epalinges, Switzerland.
2 Pacific Vascular Research Laboratory, Division of Vascular Surgery, Department
of Surgery, University of California, San Francisco, CA 94143, USA.
3 Wellcome Trust Centre for Human Genetics, University of Oxford, Roosevelt
Drive, Oxford OX3 7BN, UK.
Author for correspondence (e-mail:
andreas.trumpp{at}epfl.ch)
Accepted 29 April 2008
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SUMMARY |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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Key words: c-Myc, Hematopoietic stem cell, Placenta, Embryonic hematopoiesis, Fetal liver, Survival, Mouse
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INTRODUCTION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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;
Ferkowicz and Yoder, 2005).
Primitive pro-erythroblasts, characteristically large nucleated cells, enter
the circulation at E9 where they undergo further maturation. Primitive YS
hematopoiesis exists only transiently in the conceptus and although it does
not contribute to the hematopoietic system long term, it ensures the rapid
production of differentiated blood cells (primitive erythrocytes, macrophages,
megakaryocytes) for the immediate needs of the embryo before the definitive
system is sufficiently developed (Cumano
and Godin, 2007; Palis and
Yoder, 2001).
The first definitive hematopoietic cells to emerge in the conceptus are
hematopoietic stem cells (HSCs). The main site of HSC emergence occurs
autonomously within the aorta-gonad-mesonephros (AGM) region of the embryo
proper, where hematopoietic clusters are observed along the ventral wall of
the dorsal aorta from E10.0 (Dzierzak and
Speck, 2008; Medvinsky and
Dzierzak, 1996). Extra-embryonic tissues, including the YS
(Lux et al., 2008;
Samokhvalov et al., 2007),
vitelline and umbilical arteries (de
Bruijn et al., 2000) and placenta
(Gekas et al., 2005;
Ottersbach and Dzierzak, 2005;
Zeigler et al., 2006), have
also been attributed with definitive hematopoietic potential. AGM derived HSCs
isolated at E10.0-11.5 bear long-term repopulating HSC activity and can be
identified by a combination of cell-surface markers, including the
pan-hematopoietic marker CD45, AA4.1, Kit and CD34
(Bertrand et al., 2005;
Kumaravelu et al., 2002;
Sanchez et al., 1996;
Taoudi et al., 2005).
Newly generated HSCs are subsequently thought to migrate to the placenta,
which has recently been identified to act as a major (although temporary)
embryonic HSC niche, where nascent HSCs from the AGM or umbilical arteries
mature and expand (Gekas et al.,
2005; Ottersbach and Dzierzak,
2005). HSCs are then thought to migrate from the placenta via the
umbilical arteries to the second major hematopoietic organ, the fetal liver,
where they further mature, expand and undergo differentiation along erythroid,
myeloid and lymphoid lineages. Just before birth, definitive HSCs begin to
migrate to the bone marrow where they populate niches located at the endosteum
and from where adult hematopoiesis is controlled and maintained during
adulthood (Wilson and Trumpp,
2006). A number of genes have been shown to be important for
primitive and/or definitive hematopoiesis. Many genes affecting primitive YS
hematopoiesis encode transcription factors such as Scl, Lmo2 and Gata1, and
embryos lacking primitive hematopoiesis die before midgestation (E10.5). By
contrast, embryos containing mutations in genes that affect the proliferation
and/or differentiation of early definitive stem/progenitor cells or more
mature myeloid lineages, such as Myb, Rel, Aml/Runx1, Cbfβ and Lhx2,
survive significantly longer and die between E11.5 and E16
(Godin and Cumano, 2002).
The proto-oncogene c-myc plays an important role during normal
adult hematopoiesis and is overexpressed in numerous hematopoietic
malignancies. It encodes a nuclear basic helix-loop-helix leucine zipper
protein c-Myc, which coordinates expression of a large number of diverse genes
involved in processes necessary for cell expansion, cell growth, metabolism,
ribosome biogenesis, proliferation, differentiation and stem cell function
(Adhikary and Eilers, 2005;
Hurlin and Dezfouli, 2004).
Recent data also suggest an involvement of c-Myc in the control of various
stem/progenitor populations, including those found in the epidermis, intestine
and bone marrow (Arnold and Watt,
2001; Benitah et al.,
2005; Bettess et al.,
2005; Muncan et al.,
2006; Murphy et al.,
2005; Oskarsson et al.,
2006; Waikel et al.,
2001; Wilson et al.,
2004). In addition, c-Myc is a member of a group of four genes
sufficient to convert both mouse tail tip fibroblasts and human fibroblasts
into cells with pluripotent stem cell like activity, indicating that c-Myc may
be a component to supply cells with self-renewal activity
(Knoepfler, 2008;
Okita et al., 2007;
Takahashi et al., 2007;
Wernig et al., 2007). Many
primary and established cell lines require c-Myc to maintain proliferation,
suggesting that Myc activity is indispensable for cell cycle progression
(Grandori et al., 2000). This
assumption appeared to hold true in vivo, as embryos in which the
c-myc gene has been eliminated by gene targeting in ES cells
(c-myc
ORF/ORF) fail to thrive and die before
midgestation. c-Myc-deficient embryos are much smaller and are often delayed
in development. They exhibit multiple defects, including an enlarged
pericardial sac, failure to turn, a wavy neural tube, hypoplastic branchial
arches and lack of blood cells (Davis et
al., 1993; Trumpp et al.,
2001). However, in this report, we show that embryos derived from
epiblast-restricted deletion of c-Myc appear morphologically normal and
exhibit no obvious proliferation defects, and we attribute most of the
developmental defects of c-mycORF/ORF
embryos to placental insufficiency. Most interestingly, the only
epiblast-derived lineage that absolutely requires c-Myc activity through to
E12 is the hematopoietic 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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) were crossed with Sox2Cre transgenic mice
(Vincent and Robertson, 2003),
Tie2Cre transgenic mice (Braren et
al., 2006) or HNF4
Cre transgenic mice
(Vincent and Robertson, 2004)
to generate epiblast-, vascular and hematopoietic-, and liver-specific
c-myc-deficient mice, respectively. Controls are defined as
Sox2Cre;c-mycflox/+,
c-mycflox/+ or
c-mycORFrec/+. No difference was observed between
these embryos in any of the experiments described. For embryo analysis, timed
matings were set up and the morning of the vaginal plug was considered as
embryonic day 0.5 (E0.5). Analysis of the Cre-mediated deletion efficiency at
the c-mycflox locus was assessed by Southern blot analysis
as previously described (Trumpp et al.,
2001).
Histology
Freshly isolated embryos were fixed in 10% buffered formaldehyde overnight
at 4°C, then dehydrated to 70% ethanol. After embedding in paraffin, 4
µm sections were cut by using a microtome. For routine histology, sections
were stained with Hematoxylin and Eosin.
Immunohistochemistry
Histological slides were rehydrated and treated with 3% hydrogen peroxide
for 20 minutes. Antigen retrieval was performed by boiling samples in Tris
buffer (pH 9) for 20 minutes (c-Myc, BrdU, HNF4) or proteinase K
(laminin, cytokeratin). Blocking was carried out in 1% BSA in PBS for 30
minutes. Slides were incubated overnight at 4°C with the following primary
antibodies: c-Myc (Upstate, 06-340) 1:250 or (Santa Cruz, N262) 1:250; laminin
(Dako Cytomation, Z0097) 1:600; cytokeratin (Dako Cytomation, Z0622) 1:1200;
BrdU (Oxford Biotechnology, OBT 0030) 1:100; PECAM (CD31) (Pharmingen,
cat:01951D) 1:100; and HNF4 (Santa Cruz) 1:100. Slides were washed and
incubated for 1 hour with secondary HRP antibodies (Dako, K4000/K4002 or
Amersham, LA9350W) or Alexa488 (Molecular Probes, A11034).
Colony forming assay
CFU assays were performed as previously described
(Delassus and Cumano, 1996).
Single cell suspensions of E10.5 control and
Sox2Cre;c-mycflox2 embryos (devoid of
head and limbs) or YS were grown in methylcellulose containing a mixture of
rIL3, rSCF, rGM-CSF (2ng/ml) and human rEpo (4 U/ml) (StemCell Technology,
Vancouver, MethoCult M2231). Colonies were counted and analyzed after 8
days.
Flow cytometry analysis
Embryos were collected at E10.5-11.0 and dissected (to remove head and
limbs) under a stereomicroscope. Tissues were mechanically disrupted to obtain
single-cell suspensions by passing them through a 26 G needle. Cells were
incubated for 30 minutes on ice with the following mAb conjugates:
Ter119-APC-Cy7, Kit (CD117)-PE-Cy7, CD34-PE, CD71-PE (eBioscience) and
BrdU-FITC (BD Bioscience). For the TUNEL assay the `in situ cell death
detection kit (fluorescein)' from Roche was used according to the
manufacturer's instructions. Five- and six-color FACS analysis was performed
using a FACS Canto Flow Cytometer (Becton Dickinson) and data were analyzed
using FlowJo (Tree Star, USA) software. Cell sorting of CD45+ cells
was performed on a FACS Aria Flow Cytometer (Becton Dickinson).
Analysis of Myc expression
RNA from control and Sox2Cre;c-mycflox2 embryos was
isolated using the RNeasy mini kit (Qiagen). cDNA was generated using
Stratascript Reverse Transcriptase (Stratagene) followed by gene-specific PCR
with primers for c-myc, N-myc and L-myc as previously
described (Wilson et al.,
2004). All samples were normalized using
β2-microglobulin.
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RESULTS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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ORF/ORF embryos). In order
to circumvent a putative requirement of c-Myc signaling activity in the
extra-embryonic tissues of the conceptus and specifically dissect the role of
c-Myc in the development of the embryo proper, we induced deletion of the
conditional c-mycflox allele
(Fig. 1A) exclusively in the
epiblast using a Sox2Cre mouse strain
(Hayashi et al., 2002;
Trumpp et al., 2001;
Vincent and Robertson, 2003).
Sox2Cre;c-mycflox/flox
embryos were observed in the expected Mendelian ratio up to E11.5; however, no
viable mutant embryos were observed beyond E12.5 (see Table S1 in the
supplementary material). Analysis of the recombination efficiency revealed
virtually complete deletion of the c-mycflox allele within
Sox2Cre;c-mycflox/flox
embryo proper (Fig. 1B),
whereas the extra-embryonic placental tissue comprised mostly of the
unrecombined c-mycflox allele (extra-embryonic
ectoderm-derived chorionic trophoblast and spongiotrophoblast cells) and, as
expected, few c-Myc-deficient epiblast-derived cells (chorionic mesoderm and
allantois components) (Fig.
1B). The level of c-myc transcripts within the
Sox2Cre;c-mycflox/flox
embryo proper was decreased about 600-fold, although no significant change in
the expression of N-myc (also known as Mycn) and
L-myc was observed (Fig.
1C).
Most noticeably,
Sox2Cre;c-mycflox/flox
mutant embryos exhibit an entirely different phenotype to that of
c-mycORF/ORF-null embryos
(Fig. 1D)
(Trumpp et al., 2001).
Sox2Cre;c-mycflox/flox
mutants die during a very tight window between E11.25 and E11.75, and appear
morphologically normal, with no apparent defects, delay in development or
significant difference in overall embryo size up to E10.5
(Fig. 1D, parts i,ii). The only
defect evident in both the embryo proper and YS was their pale appearance,
indicative of a hematopoietic/erythroid deficiency
(Fig. 1D, part ii). Close to
their time of death at E11.5, mutant embryos appear slightly smaller, probably
due to the severe anemia (see below) and consequently a failure to thrive
(Fig. 1D, part iii). Although
extra-embryonic rescue of c-Myc activity prolongs survival of the conceptus
for an additional 2 days, loss of c-Myc activity within the embryo proper
remains fatal.
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). However,
no significant c-Myc expression was detected in the deciduum, the maternal
compartment of the placenta (Fig.
2A). Circulating hematopoietic cells of embryonic origin, as
defined by their morphology (round cells with a high nucleus to cytoplasm
ratio) and localization within the fetal blood spaces, also express high
levels of c-Myc (Fig.
2A').
Next, we examined the histology of the chorioallantoic placenta of
c-mycORF/ORF embryos. The chorioallantoic
placenta is formed by the attachment of the epiblast-derived allantois to the
extra-embryonic ectoderm derived chorionic trophoblast cells (at E8.5) and the
subsequent invasion and branching of the fetal vessels into a highly
vascularized structure referred to as the labyrinth (E9.5-E10.5)
(Watson and Cross, 2005).
Histological analysis of E10.5 c-mycORF/ORF
mutants revealed severe structural defects in the chorioallantoic placenta
(Fig. 2B). Immunohistochemical
(IHC) analysis further revealed a severe reduction in the number of epithelial
derived (cytokeratin positive) chorionic-trophoblast cells
(Fig. 2C) and a failure of the
fetal blood vessels and allantoic mesenchyme (laminin positive) to invade the
chorion compartment, resulting in a strongly hypoplastic labyrinth layer
(Fig. 2C, right panel). Hence,
c-mycORF/ORF mutants appear to exhibit
normal chorioallantoic attachment, but a failure in the initiation of
branching morphogenesis. In addition, c-Myc deficient placentas as a whole are
severely hypoplastic and exhibit a dramatic loss in the number of
proliferating cells, as assayed by 5-bromodeoxyuridine (BrdU) incorporation
(Fig. 2D). These results
therefore indicate that c-Myc activity within the extra-embryonic chorionic
ectoderm or trophoblast cells is crucial for correct chorioallantoic
placentation.
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ORF/ORF-null embryos are secondary
defects owing to the failure to develop a functional placenta.
c-Myc deficient primitive erythroblasts undergo cell death
The pale appearance of
Sox2Cre;c-mycflox/flox
embryos suggests a defect in the generation and/or maintenance of the
embryonic hematopoietic system. Histological analysis of E11.0
Sox2Cre;c-mycflox/flox
embryos and YS revealed an almost complete absence of hematopoietic cells
(Fig. 3A; data not shown). The
majority of blood cells present during midgestation consist of primitive
nucleated erythroblasts, generated predominately by YS derived precursors,
which enter the embryo at the onset of circulation. Primitive erythroblasts
express high levels of the transferrin receptor CD71 and increasing levels of
the glycophorin A-associated TER119 during maturation
(Fraser et al., 2007). FACS
analysis of the erythroid lineage of E11.0
Sox2Cre;c-mycflox/flox
embryos revealed a 11.5-fold reduction (wild type 51,089±10,951, mutant
4430±1797) in the number of more mature
CD71+Ter119+ early basophilic erythroblasts (PE,
Fig. 3B,C). Even more apparent
was the striking loss of erythroblast precursor cells
(CD71+Ter119- primitive proerythroblasts; 1500-fold
decrease, wild type 141,439±7844, mutant 899±123)
(Fig. 3B,C).
In order to address whether the extremely low numbers of erythroid cells present in Sox2Cre;c-mycflox/flox embryos is due to aberrant cell death, we assayed TUNEL reactivity via FACS, which revealed a dramatic increase (19-fold) in the apoptosis rate of E9.5 Sox2Cre;c-mycflox/flox CD71+ cells compared with controls (wild type 0.98±1.2%, mutant 18.65±0.07%) (Fig. 3D). This apoptotic phenotype became even more pronounced at E10.5, whereby the CD71+ population of Sox2Cre;c-mycflox/flox embryos exhibit a 41-fold increase in apoptosis (wild type 0.49±0.08%, mutant 20.28±5.03%) (Fig. 3D). This strong increase in the apoptosis rate was specific to the cells of the erythroid lineage, as there was no significant overall increase in cell death within Sox2Cre;c-mycflox/flox embryos (E9.5 wild type 6.35±1.55%, mutant 10.05±0.21%; E10.5 wild type 2.08±0.15%, mutant 4.51±0.28%). The existence of erythroblasts in Sox2Cre;c-mycflox/flox embryos (albeit decreased numbers) suggests the initial presence of proerythroblast precursor cells. However, our data show that these cells undergo massive apoptosis and are no longer present in sufficient numbers to maintain hematopoiesis, probably leading to the embryonic death of Sox2Cre;c-mycflox/flox embryos.
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; Taoudi et al.,
2005). We therefore examined the expression of CD45 and observed a
striking reduction in the number of CD45+ blood cells in both the
dorsal aorta and fetal liver of E11.0
Sox2Cre;c-mycflox/flox
embryos (Fig. 4A).
Quantification by FACS analysis revealed a sixfold decrease in the absolute
number of CD45+ hematopoietic cells
(Fig. 4B and C). In order to
determine whether the c-mycflox allele was indeed
recombined in the few remaining CD45+ cells, these cells were
isolated from
Sox2Cre;c-mycflox/flox
embryos by flow cytometry and their RNA analyzed by real-time RT-PCR. This
analysis revealed a greater than 1000-fold downregulation of c-myc
transcripts compared with control cells, demonstrating efficient elimination
of c-myc mRNA within the small remaining CD45+
hematopoietic population.
Early definitive HSCs in the mid-gestation embryo express the cell-surface
markers AA4.1 (CD93), Kit (CD117) and CD34
(Cumano and Godin, 2007;
Dzierzak and Speck, 2008;
Mikkola and Orkin, 2006;
Sanchez et al., 1996). FACS
analysis of E11.0
Sox2Cre;c-mycflox/flox
embryos revealed an increase in the percentage of
c-Kit+AA4.1+ cells within the total CD45+
population (Fig. 4D and E).
However, the absolute number of
CD45+c-kit+AA4.1+ cells per mutant embryo was
similar to that of control embryos (Fig.
4F). This was further confirmed using the additional stem cell
marker CD34 (see Fig. S1 in the supplementary material). By contrast,
Sox2Cre;c-mycflox/flox
embryos exhibit a dramatic decrease in the number of all other definitive
hematopoietic cells (CD45+cKit+AA4.1-,
CD45+AA4.1+cKit- and
CD45+cKit-AA4.1-)
(Fig. 4D,
Fig. 3). In summary, these data
suggest that although c-Myc is not required for the generation of
CD45+AA4.1+c-kit+CD34+ cells,
which are highly enriched for definitive HSCs, c-Myc activity is essential to
efficiently generate differentiated progeny from HSCs.
Although definitive stem/progenitor cells are generated in the absence of c-Myc, they are non-functional
In order to address whether the phenotypic
Sox2Cre;c-mycflox/flox HSCs
are functional, we determined the number of cells with colony-forming unit
(CFU) activity in E10.5 mutant embryos. In control embryos, BFU-E
(blast-forming unit-erythroid) and CFU-G/M (colony-forming
unit-granulocyte/macrophage) were found at expected frequencies
(93±17.9) (Fig. 4G,H)
(Trumpp et al., 2001). By
contrast, cells derived from the embryo proper of
Sox2Cre;c-mycflox/flox
mutants formed no or only very few colonies (2.3±3.3)
(Fig. 4G,H), with abnormal
morphology (composed of extremely small cells), probably representing
aberrantly differentiated cells (Fig.
4G, bottom right panel). Very similar results were also obtained
in CFU assays derived from YS cells (data not shown). Thus, although the
absolute number of phenotypic HSCs is maintained in the absence of c-Myc
activity (Fig. 4F),
c-Myc-deficient HSCs are defective and unable to generate a significant number
of differentiated progeny.
Following the emergence of definitive HSCs within the AGM, hematopoietic
cells are thought to migrate via the placenta (recently shown to contribute to
HSC expansion) en route to the fetal liver, which serves as the major
intra-embryonic hematopoietic organ to support HSC expansion and maturation.
Although scarce, the presence of CD45+Kit+ cells in the
fetal liver of
Sox2Cre;c-mycflox/flox
mutants suggests migration of mutant stem/progenitor cells to the fetal liver
is unimpaired (data not shown). This is further supported by the fact that the
expression of a number of adhesion molecules overexpressed in c-Myc-deficient
adult HSCs (Wilson et al.,
2004) such as CD29 (β1 integrin), CD18 (β2 integrin),
CD49b (2 integrin), CD49e (5 integrin) and CD11a (L
integrin), are not significantly changed in
Sox2Cre;c-mycflox/flox
mutant stem/progenitor cells (data not shown). Consistent with the observation
that c-Myc-deficient HSCs are unable to generate colonies in vitro, all
CD45+ cells reside in the fetal liver of
Sox2Cre;c-mycflox/flox
mutants exclusively as single cells, suggesting that c-Myc deficient HSCs
(which constitute 
25% of the CD45+ population,
Fig. 4E) are unable to expand
and generate progeny in the mutant fetal liver micro-environment
(Fig. 4A bottom right panels).
Thus, despite the fact that HSC generation is unaffected in the absence of
c-Myc activity, these cells are functionally defective in vitro and in vivo.
Together these results show that c-Myc is an essential factor necessary for
embryonic HSC function.
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) and critical regulators of embryonic hematopoiesis,
including Scl (Shivdasani et al.,
1995), Runx1
(Castilla et al., 1996),
Gata1 (Pevny et al.,
1991), Gata2 (Tsai et
al., 1994), Klf4 and Klf6
(Matsumoto et al., 2006) in
CD45+ cells by real-time RT PCR. As has been observed in other
c-Myc-deficient cells (Oskarsson et al.,
2006), p21CIP1 was upregulated (2.1-fold), but among
the others, only Klf4 was statistically significantly upregulated (1.6-fold)
in c-Myc-deficient CD45+ cells (see Fig. S4 in the supplementary
material).
Non-hematopoietic tissues proliferate and develop normally even in the absence of c-Myc
In search of non-hematopoietic defects in
Sox2Cre;c-mycflox/flox
embryos, a detailed analysis of E10.5-E11.5 mutant embryos was performed. For
tissues difficult to distinguish by standard histological analysis alone,
specific markers such as Pdx1 (pancreas) and alkaline phosphatase (primordial
germ cells) were included (Kim and
MacDonald, 2002; Lawson et
al., 1999). Surprisingly, these studies revealed no obvious
developmental abnormalities (see Fig. S2 in the supplementary material) apart
from fetal liver hypoplasia (discussed in more detail below). In addition,
BrdU incorporation analyses revealed no significant difference in the
proliferative capacity of c-Myc-deficient organs/tissues
(Fig. 5A). Similarly, no major
change in the rate of apoptosis (caspase 3 and TUNEL) was observed in mutant
embryos (data not shown and see above). Moreover, PECAM (CD31) staining of
Sox2Cre;c-mycflox/flox and
c-mycORF/ORF embryos revealed the presence
of an extensive vascular network, suggesting that c-Myc is not required for
the establishment of the vascular system as has recently been reported
(Fig. 5B; data not shown)
(Baudino et al., 2002). These
results indicate that c-Myc is not directly required to maintain cell
proliferation and survival outside the hematopoietic system in vivo.
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). As
expected,
Tie2Cre;c-mycflox/flox
embryos are lethal at E11.5 and exhibit a hematopoietic phenotype identical to
that described above for
Sox2Cre;c-mycflox/flox
embryos (Fig. 6A; data not
shown). FACS analysis of E11.0
Tie2Cre;c-mycflox/flox
embryos revealed a severe decrease in the total number of CD45+
hematopoietic cells (Fig. 6B),
and the typical increase in the relative percentage of
CD45+c-Kit+AA4.1+ stem/progenitors and
concomitant decrease in progenitors and mature cells
(Fig. 6C). Similarly, we
observed no major vascular defects in E11.0
Tie2Cre;c-mycflox/flox YS or embryos (data not shown). The
virtually identical phenotypes of
Tie2Cre;c-mycflox/flox and
Sox2Cre;c-mycflox/flox
embryos provide strong genetic evidence that in the embryo proper, c-Myc is
uniquely required for the development of the hematopoietic lineage.
Fetal liver hypoplasia develops as a result of hematopoietic cell deficiency
Although the location of fetal liver niches, the cell types they are
comprised of or the molecules required for its activity are not known, it is
likely that hepatoblastic cells are at least in part involved in the fetal
liver niche (Cumano and Godin,
2007). To address whether c-Myc activity is important for the
generation, maintenance or function of hepatoblasts and putative HSC
micro-environment, E10.5
Sox2Cre;c-mycflox/flox
fetal livers were examined and observed to be dramatically reduced in size
compared with control liver samples (a decrease which is numerically larger
than the loss of hematopoietic cells alone). Histological analysis revealed
severe morphological defects, whereby mutant livers exhibited a mesenchymal
rather than typical epithelial organization of this organ
(Fig. 7A,B). Nevertheless,
Sox2Cre;c-mycflox/flox
liver cells expressed normal levels of the hepatocyte nuclear factor 4
(HNF4), confirming their identity as hepatoblasts
(Fig. 7C). To address
genetically whether c-Myc is directly required for early liver development,
the c-mycflox allele was specifically deleted in fetal
liver hepatoblasts from E9.0 using the Hnf4a-Cre mouse line
(Vincent and Robertson, 2004).
Unexpectedly,
Hnf4aCre;c-mycflox/flox
embryos were viable and histological analysis of E10.5-E16.5 embryos revealed
no apparent difference in liver size or morphology (Fig. S3). Moreover,
detailed analysis of all major hematopoietic cell types including HSCs were
present in normal numbers in hepatoblast-restricted c-Myc null embryos (data
not shown). These data suggest that c-Myc is neither directly required for
embryonic liver development nor for the establishment or maintenance of the
hematopoietic liver microenvironment. Moreover, these genetic results confirm
that the severe liver phenotype observed following epiblast-restricted
deletion of c-Myc
(Sox2Cre;c-mycflox/flox
embryos) is not due to loss of c-Myc within the hepatic cells, but rather
represents a secondary defect due to defective hematopoiesis. This hypothesis
is further supported by the observation that the fetal livers of
Tie2Cre;c-mycflox/flox
embryos, the hepatoblasts of which continue to express c-Myc, show the same
reduction in fetal liver size and hematopoietic defects observed in
Sox2Cre;c-mycflox/flox
embryos (Fig. 7D). These data
therefore show that in the absence of hematopoietic cells, hepatoblasts fail
to expand and are unable to establish a normal liver morphology. To our
knowledge, these results provide the first genetic evidence that hematopoietic
cells are crucial for the early expansion and structural establishment of the
embryonic liver.
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DISCUSSION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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ORF/ORF null embryos. Moreover, we
genetically demonstrate that most of the developmental defects present in
c-mycORF/ORF-null embryos, including
abnormalities of the heart, pericardium, neural tube, delay in embryo turning
and embryo size (Davis et al.,
1993; Trumpp et al.,
2001) are virtually absent in c-Myc-deficient embryos that develop
with a wild-type extra-embryonic support system
(Sox2Cre;c-mycflox/flox and
Tie2Cre;c-mycflox/flox
embryos). We have therefore shown that c-Myc, initially believed to be crucial
for the development of many embryonic structures, is indeed primarily
important for placental development, and that this causes severe secondary
defects and early lethality. Future studies detailing the spatio-temporal
expression of c-Myc in the individual components/structures necessary to
generate a functional chorio-vitelline and chorio-allantoic placenta should
reveal the exact role of this protein in placentation. However, this initial
assessment suggests that c-Myc plays an important role in the chorionic
trophoblast cells. c-Myc expression is controlled by a large number of
signaling pathways, including the canonical Wnt-β-catenin, Notch and
Ras-MAPK pathway or signaling occurring downstream of many receptor tyrosine
kinases such as PdgfR, Kit or TpoR (Barone
and Courtneidge, 1995;
Chanprasert et al., 2006;
Grandori et al., 2000;
Sansom et al., 2007;
Sharma et al., 2007). Given
that our study has uncovered c-Myc as a crucial component of placental
development, it is likely that other knockout mouse models of genes
influencing c-Myc expression may also exhibit thus far undocumented placental
defects.
Second, via extensive analysis of
Sox2Cre;c-mycflox/flox and
Tie2Cre;c-mycflox/flox
embryos, we have shown that c-Myc activity is dispensable for the development
of most embryonic organs/tissues until E11.5. Given the large body of evidence
indicating that c-Myc is crucial to maintain proliferation
(Adhikary and Eilers, 2005;
Grandori et al., 2000;
Prathapam et al., 2006;
Trumpp et al., 2001;
de Alboran, 2001), it is
surprising that we did not observe multiorgan hypoplasia as previously
characterized in c-mycORF/ORF embryos
(Fig. 1D)
(Davis et al., 1993;
Trumpp et al., 2001). In
addition to other genetic studies reporting c-Myc independent proliferation in
a subset of cells in adult tissues (Baena
et al., 2005; Bettess et al.,
2005; Oskarsson et al.,
2006; Wilson et al.,
2004), it therefore appears that c-Myc activity is not required to
maintain at least some highly self-renewing adult tissues nor sustain the high
proliferative capacity of most embryonic cell types in vivo. These
observations are puzzling given the large quantity of data indicating that
c-Myc function is essential for cell cycle progression and cell growth of
diverse cell types in vitro (de Alboran et
al., 2001; Douglas et al.,
2001; Mateyak et al.,
1997; Oskarsson et al.,
2006; Prathapam et al.,
2006; Trumpp et al.,
2001). One possible explanation for the continued proliferation of
c-myc-deficient cells in vivo is functional redundancy with other Myc family
members (N-Myc and L-Myc). Although neither N- nor L-myc
transcripts are significantly upregulated in c-Myc-deficient embryos, the
phenotype of epiblast-specific deletion of both c-Myc and N-Myc is more severe
than ablation of either gene alone (N.C.D., Robert N. Eisenman and A.T.,
unpublished). Hence, it remains plausible that in cell types predominantly
expressing c-Myc, the remaining low levels of endogenous N-Myc may be
sufficient to maintain the proliferation of non-hematopoietic cell types in
Sox2Cre;c-mycflox/flox
midgestation embryos. Such functional redundancy does not appear to occur in
most cultured cells, however, given that cell cycle progression of many cell
types arrest upon inactivation of c-Myc alone. The only approach to address
whether a completely Myc independent proliferation program exists is to
eliminate all three Myc family members genetically (c-Myc, N-Myc and L-Myc) in
an inducible fashion in vivo. In any case, it is important to note that
elimination of c-Myc alone may not necessarily affect the proliferation and
survival of cells in vivo. This conclusion has important consequences
regarding the use of c-Myc inhibitors designed as anti-cancer drugs in a
clinical setting as they may have less severe side effects than so far
anticipated.
|
), and
both endothelial cells and hematopoietic cells are thought to arise from a
common progenitor (the hemangioblast)
(Lacaud et al., 2001). These
data would suggest that the hematopoietic phenotype we observe in
Sox2Cre;c-mycflox/flox embryos may arise due to defective
vasculogenesis or hemangioblast development. However, in contrast to the study
performed by Baudino and colleagues, we observed no major vascular defects in
the YS or embryo proper of three genetically distinct c-Myc-deficient mouse
models (conventional knockout, c-mycORF/ORF;
epiblast-specific deletion, Sox2Cre;c-mycflox/flox; and
endothelial/hematopoietic specific deletion,
Tie2Cre;c-mycflox/flox). The reason for this apparent
discrepancy remains unclear; however, we have found that
c-mycORF/ORF-null embryos exhibit
variability in their time of death (E9.0-E10.5) and it is likely that
endothelial markers are no longer informative in dying embryos. Nevertheless,
we provide strong genetic evidence that c-Myc is not directly required for the
formation of the embryonic vascular system. As described in the accompanying
paper by He et al. (He et al.,
2008) minor vascular abnormalities are present upon c-Myc
deletion; however, they arise secondarily owing to the lack of hematopoietic
cells (He et al., 2008).
Our genetic studies have revealed that during early embryogenesis, only
primitive and definitive hematopoietic cells are dependent on c-Myc function
(Fig. 7E). At time of death,
Sox2Cre;c-mycflox/flox and
Tie2Cre;c-mycflox/flox mutant embryos present with
10% of the normal number of erythroblasts and exhibit an almost complete
lack of erythroblast precursors, owing to vast apoptosis of CD71+
cells. Thus, we provide the first genetic evidence that, in contrast to
pathologically high Myc expression, as is often found in many tumors
(Evan et al., 2005;
Pelengaris et al., 2002),
endogenous c-Myc activity has a pro-survival role in primitive erythroid
cells. Although this is a novel finding, it is not completely unexpected given
c-Myc is a downstream target of a number of receptor tyrosine kinases that
have known pro-survival function, including Kit, Pdgf and Tpo
(Kaushansky, 2005;
Levitzki, 2004;
Martelli et al., 2006). Future
studies will need to determine whether the here uncovered pro-survival role of
endogenous c-Myc is specific for hematopoietic cells or whether this is a
general feature of endogenous Myc function in other cell types too.
E11.0
Sox2Cre;c-mycflox/flox
embryos exhibit a striking decrease in the absolute number of CD45+
hematopoietic cells. By contrast, the number of phenotypic definitive HSCs
remains constant in the presence or absence of c-Myc, suggesting that the
generation, specification and proliferation of HSCs is a c-Myc-independent
process. Despite the generation of normal HSC numbers, c-Myc-deficient HSCs
fail to give rise to a significant amount of differentiated progeny and lack
CFU activity, strongly suggesting that HSCs lacking c-Myc activity are
non-functional. These data are in agreement with what we observed following
elimination of c-Myc in adult bone marrow HSCs
(Murphy et al., 2005;
Wilson et al., 2004;
Wilson and Trumpp, 2006).
Although our analysis of the hematopoietic regulators Scl, Runx1, Gata1 and
Klf6 revealed no change in expression levels within the CD45+ cell
compartment of
Sox2Cre;c-mycflox/flox
embryos, it is important to note that the proportion of phenotypic HSCs within
this population is five times higher than in control embryos. This may
indicate that the expression of each transcription factor is indeed up to five
times lower in mutant HSC/progenitors. Unfortunately, isolation of a
significant number of highly pure HSC populations from mutant embryos have
technical limitations and thus prohibited us from addressing this possibility
directly.
In the embryo, HSCs emerge from the AGM and migrate in a β1
integrin-dependent manner to the fetal liver where they mature and expand
(Cumano and Godin, 2007;
Hirsch et al., 1996).
c-Myc-deficient embryonic HSCs express normal levels of β1 integrin and
CD45+Kit+ cells are found in the liver, suggesting that
the migration of HSCs to the fetal liver is not c-Myc dependent. However, in
contrast to normal embryonic HSCs, which upon reaching the fetal liver undergo
massive expansion, c-Myc-deficient hematopoietic cells reside exclusively as
single cells, further supporting the conclusion that they are unable to
generate hematopoietic progeny. However, unlike in the adult, no accumulation
of phenotypic HSCs is observed in c-Myc mutant embryos. This may be
attributable to the lack of appropriate fetal liver stromal environment
required to support hematopoietic activity, given the severely impaired
development of the fetal liver in mutant embryos. Only Sox2Cre (but not
Tie2Cre) induces recombination in the hepatoblast lineage, yet both mouse
models exhibit hepatic disorganization and hypoplasia, thus it is likely that
the liver phenotype arises as a direct result of hematopoietic insufficiency.
This is further supported by the fact that restricted elimination of c-Myc in
the hepatoblast lineage has no discernable effect on either fetal liver or
hematopoietic development. At the onset of fetal liver development (at E9.5),
only primitive hematopoietic cells are present, raising the possibility that
primitive erythroblasts are required to promote fetal liver development in
order to generate an appropriate microenvironment or `niche' for incoming
HSCs. In conclusion, these data provide first genetic evidence that proper
fetal liver development requires the presence of hematopoietic cells and
suggests that hepatic and hematopoietic progenitors develop in a symbiotic
relationship in which hematopoietic and hepatic cells exchange signals
required to promote the development of each other.
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/135/14/2455/DC1
|
ACKNOWLEDGMENTS |
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Footnotes |
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|
REFERENCES |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
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 C. He, H. Hu, R. Braren, S.-Y. Fong, A. Trumpp, T. R. Carlson, and R. A. Wang c-myc in the hematopoietic lineage is crucial for its angiogenic function in the mouse embryo Development, July 15, 2008; 135(14): 2467 - 2477. [Abstract] [Full Text] [PDF]
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0.001).
(D) Quantitative analysis of TUNEL-positive CD71+ cells in
E9.5 and E10.5 embryos (**P
