|
|
|
|
|
|
|
||||
| Home Help Feedback Subscriptions Archive Search Table of Contents | ||||
First published online July 11, 2006
doi: 10.1242/10.1242/dev.02454
Department of Anatomy, University of Wisconsin-Madison School of Medicine and Public Health, 1300 University Avenue, Madison, WI 53706, USA.
* Author for correspondence (e-mail: kdowns{at}wisc.edu)
Accepted 23 May 2005
 |
SUMMARY |
|---|
 TOP SUMMARY INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
Key words: Allantois, Anteroposterior axis, Apoptosis, Brachyury, Primitive streak, Patterning, Proliferation, Vasculogenesis, Mouse, Yolk sac, Heart
|
INTRODUCTION |
|---|
|
TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
;
Papaioannou, 2001;
Showell et al., 2004). The
founding member of this family, T, was identified in mice as a
semi-dominant mutation affecting tail length in heterozygous adults
(Dobrovolskaia-Zavadskaia,
1927). T/T mutants died during mid-gestation
(Chesley, 1935;
Zavadskaia and Kobozieff,
1930), presumably because of a failure of the developing
umbilicus, the allantois, to unite with the chorion and vascularize it to form
a functional chorio-allantoic placenta
(Gluecksohn-Schoenheimer,
1944).
The allantois is derived from epiblast, the progenitor tissue of all three
primary germ layers (Lawson et al.,
1991). Once the primitive streak, or future anteroposterior (AP)
axis, appears, proximal epiblast ingresses into the posterior streak and
emerges as mesoderm, some of which is displaced into the extraembryonic region
to form the allantois. Two morphologically distinct cell types are
identifiable in the allantoic bud: an outer layer of squamous epithelial
cells, the `mesothelium' (Downs et al.,
2004; Snell and Stevens,
1966); and inner cells, referred to collectively as the `allantoic
core' (Downs and Gardner,
1995).
The allantoic bud then enlarges by cell proliferation, addition of mesoderm
from the streak, and distal cavitation
(Brown and Papaioannou, 1993;
Downs and Bertler, 2000).
Allantoic core mesoderm differentiates de novo into the umbilical vasculature
by vasculogenesis, as evidenced by the appearance of scattered angioblasts
containing Flk1 (Kdr - Mouse Genome Informatics), a tyrosine kinase receptor
for vascular endothelial growth factor (Vegf)
(Millauer et al., 1993;
Yamaguchi et al., 1993),
initially in the distal region of the allantois, farthest away from the embryo
(Downs et al., 1998).
Continued formation of angioblasts and subsequent coalescence into endothelial
tubules then follows a spatiotemporally regulated distal-to-proximal sequence
such that, by 4- to 6-somite pairs (-s), the nascent Flk1 vascular plexus
reaches the base of the allantois and merges with those of the yolk sac and
embryo (Downs et al., 1998;
Downs et al., 2004). Allantoic
vasculogenesis is not accompanied by primitive erythropoiesis; once vascular
amalgamation takes place, primitive erythroid cells enter the allantois from
the yolk sac (Downs et al.,
1998).
The elongated allantois contacts the chorion and fuses with it by 6- to
8-s, in a process that is dependent upon the developmental maturity of the
allantois (Downs and Gardner,
1995). Chorio-allantoic union is mediated by chorio-adhesive
mesothelial cells, located in the distal allantoic region
(Downs and Gardner, 1995) and
identified by gradual localization of vascular cell adhesion molecule 1
(Vcam1) (Downs, 2002;
Gurtner et al., 1995;
Kwee et al., 1995). Recent
studies have suggested that differentiation of allantoic mesoderm into its
three known cell types, angioblasts/endothelium, mesothelium and
chorio-adhesive cells, is intrinsic to the allantois and is not dependent upon
the primitive streak; nonetheless, information from the streak consigns the
Vcam1 chorio-adhesive cell domain to the distal allantoic region
(Downs et al., 2004).
Subsequent to molecular cloning of T
(Herrmann et al., 1990),
expression studies placed T within most sites defective in
T/T mutants, namely the primitive streak and its
derivatives, the node, notochord, nascent mesoderm and gut endoderm
(Wilkinson et al., 1990).
Results of chimeric studies in T/T
+/+ conceptuses
suggested that T acted in a cell-autonomous manner within the
embryonic body (Rashbass et al.,
1991; Wilson et al.,
1993). However, discrepancies in T expression within the
allantois (Herrmann, 1991;
Wilkinson et al., 1990),
together with inadequate understanding of the fundamental parameters of
allantoic development, confounded the interpretation of abnormalities observed
within T/T chimeric allantoises
(Rashbass et al., 1991;
Wilson et al., 1993). In light
of a recent model of allantoic ontogeny
(Downs et al., 2004), we set
out to discover the role of T in the allantois.
We recently re-investigated the spatiotemporal localization of T within the
murine gastrula, employing sectional, rather than whole mount,
immunohistochemistry, and paying particular attention to the allantois
(Inman and Downs, 2006). In
addition to identifying T protein in the heart and a variety of non-mesodermal
sites, including extraembryonic and embryonic visceral endoderm and chorionic
ectoderm, we localized T to a novel domain, the allantoic core. T was not
present in the early allantoic bud (EB). Then, between the neural plate/late
allantoic bud (LB) and 6-s stages, a period that coincides with allantoic
elongation toward the chorion (
7.5-8.5 dpc), T identified an allantoic
core domain that formed an uninterrupted continuum with embryonic T in the
primitive streak. By 6- to 8-s, when all normal allantoises have united with
the chorion (Downs, 2002;
Downs and Gardner, 1995),
allantoic T had disappeared, but it persisted in the streak and its anterior
derivatives, the node and notochord.
Although the original T mutation has most frequently been selected
for study, it encompasses a 200 kilobase (kb) deletion
(Herrmann et al., 1990) that
eliminates at least one other gene, brachyury 2 (T2)
(Rennebeck et al., 1998;
Rennebeck et al., 1995). Thus,
to elucidate the role of T in the allantois, we selected
TC, a radiation-induced
(Searle, 1966) 19 base pair
(bp) deletion in exon 8 of T that results in a codon frame-shift
postulated to produce a C-terminally truncated protein product
(Herrmann and Kispert, 1994).
Our findings revealed that, in the absence of T, cell proliferation was
reduced in the allantois and core cells died, the major consequences of which
were foreshortening of the allantois and defective vasculogenesis. As
abnormalities were also observed in the heart and yolk sac, both of which were
recently identified as novel T sites
(Inman and Downs, 2006), our
data point not only to a major role for T in formation of the umbilical
vasculature, but also to widespread T function in vascularization of the
murine conceptus.
|
MATERIALS AND METHODS |
|---|
|
TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
3 specimens for all stages and genotypes
presented, unless otherwise noted. All animals were treated in accordance with
Public Health Service (PHS) Policy on Humane Care and Use of Laboratory
Animals (Public Law 99-158) as enforced by the University of
Wisconsin-Madison.
Animal husbandry, intercross mating, dissection, staging and genotyping
Animals were maintained under a 12-hour light/dark cycle (lights out
13:00). TC/+ breeding couples were established when
animals were 3-months old, and were provided with plastic igloos (BioServ,
Frenchtown, NJ) to improve nesting and breeding performance. Three lines of
TC mice were generated
(Table 1). Expected 1:1
Mendelian ratios were exhibited only in
STOCK-TC/JDown
(Table 1); furthermore,
offspring exhibited increased fertility and decreased incidence of anal
atresia relative to the other two mouse lines
(Table 1), and were thus used
throughout the study. To obtain TC/TC
conceptuses, STOCK-TC/JDown
TC/+ females (3- to 6-months old) were paired with
TC/+ males (3- to 10-months old) prior to the start of the
dark cycle. Females were examined for a copulation plug 4 and 15 hours later,
and the time of conception was taken as the midpoint of the dark cycle.
Pregnant females were killed by CO2 asphyxiation. Estrus selection,
dissection and embryo staging were as previously described
(Downs, 2006;
Downs and Davies, 1993;
Downs and Gardner, 1995).
Briefly, stages and their equivalent approximate days post-coitum (dpc) were:
early, mid- and late streak (ES, MS, LS) stages, 6.75-7.0 dpc; early and
late allantoic bud (EB, LB) stages, 7.25-7.5 dpc; and early and late
headfold (EHF, LHF) stages, 7.75-8.0 dpc. Thereafter, staging was by
numbers of somite pairs (1- to 2-s, 8.0-8.25 dpc; 2- to 4-s, 8.25 dpc; 4- to
6-s, 8.25-8.5 dpc; 6- to 8-s, 8.5 dpc). Until 4- to 6-s,
TC/TC conceptuses were staged by development of
anterior structures, after which they were assigned the average stage of +/+
and TC/+ littermates. For genotyping, a small piece of
yolk sac or anterior embryonic tissue was taken, after which conceptuses were
rinsed in phosphate-buffered saline (PBS, Sigma, St Louis, MO) before
processing (below). DNA was extracted in 25 mM NaOH (20 minutes, 95°C),
followed by neutralization with 40 mM Tris (pH 5.2), and precipitation using
sodium acetate and Pellet Paint (EMD Biosciences, San Diego, CA). The
polymerase chain reaction (PCR) protocol used was a modification of that
described by Stott et al. (Stott et al.,
1993), with primers (5'-TGCAAAGCCCTGTGATGCAA-3' and
5'-ACATCGGAGAACCAGAAGACGA-3') that identified a 267-bp
T+ and a 248-bp TC allele. Reactions
were run on a 4% GQA Sieve agarose gel (ISC Bioexpress, Kaysville, UT). By
9.5 dpc, only one TC/TC conceptus was
recovered from three litters of timed intercross matings, and none on later
days, indicating that TC/TC mutants died
between 9.5 and 10.5 dpc (Table
2). For apoptosis pilot experiments and production of `wild-type'
whole and bisected allantoic explants (Fig.
5B, parts g-m), the F2 generation of matings between the inbred
hybrid strain B6CBAF1/J (Jackson Laboratories) was used
(Downs, 2006). For the
Flk1/Pecam allantois whole-mount expression studies
(Fig. 6A), a male
Kdrtm1Jrt mouse (hereafter referred to as
Flk1lacZ) (Shalaby et
al., 1995) re-derived on the CD1 background was generously
provided by Dr T. N. Sato and mated to females of the inbred hybrid strain
B6CBAF1/J; conceptuses were collected between the LB- and 6-s stages.
|
|
;
Downs et al., 2004;
Inman and Downs, 2006). Stock
concentrations (200 µg/ml) of antibodies (Santa Cruz Biotechnologies, Santa
Cruz, CA; T, sc-17743; Vcam1, sc-1504; Flk1, sc-315g; and Bmp4, sc-6896) were
used at 1:100, 1:90, 1:50 and 1:90 working dilutions, respectively. For Vcam1,
signal was amplified using the Tyramide Signal Amplification (TSA) Kit
(Perkin-Elmer, Shelton, CT) according to the manufacturer's instructions.
Detection was with 3,3'-diaminobenzidine (DAB) in chromogen solution
(Dako, Carpinteria, CA) and was followed by counterstaining with
hematoxylin.
Whole-mount immunostaining for Pecam1
Flk1lacZ conceptuses were fixed in 4% paraformaldehyde
(2 hours, 4°C), rinsed in PBS, and then X-gal stained for 2 hours, as
previously reported (Downs et al.,
2004). Yolk sac, amnion and chorion were dissected away, and
specimens were processed and stained according to published methods
(Schlaeger et al., 1995) with
the following modifications. Blocking solutions contained goat serum
(Chemicon), and ready-to-use ABC reagent (Vector Laboratories, Burlingame, CA)
was applied prior to the DAB color reaction. Primary antibody was monoclonal
rat anti-mouse Pecam1 (Mec13.3) diluted 1:100 (537355, BD Biosciences, San
Jose, CA). Secondary antibody was a biotinylated goat anti-rat IgG diluted
1:500 (sc-2041, Santa Cruz Biotechnologies). Conceptuses were developed for 5
minutes at room temperature after which they were re-fixed in
paraformaldehyde, rinsed in PBS, equilibrated in 70% glycerol, gently squashed
beneath a cover slip (which sometimes had the effect of distorting relative
allantoic lengths), and viewed and photographed using a compound
microscope.
Cell counts, mitotic index (MI) and morphological measurements
Cell counts and mitotic index were from sagitally oriented histological
sections (4-µm thickness) and were calculated in the entire allantois as
previously reported (Downs and Bertler,
2000), except that distal, mid- and proximal domains were not
distinguished, and ImageJ software (National Institutes of Health, Bethesda,
MD) was used to visualize the sections. The boundary between the allantois and
the primitive streak was previously diagrammed
(Downs and Harmann, 1997).
Boundaries with the allantois and the node defined the posterior and anterior
limits of the primitive streak, respectively. Within this domain, the
primitive streak was taken as dense tissue where clear boundaries between
epiblast and mesoderm were absent. Measurements of allantoic length for
ascertaining the Vcam1 domain were carried out as previously described
(Downs et al., 2004).
Statistical significance of TC/+ and
TC/TC compared with +/+
(Fig. 3B-D,
Fig. 4D,E, and
Fig. 5A, part d) was assessed
by two-way Student's t-test; equal variances were assumed, and the
significance level (P) was taken as 
0.05.
DiI labeling, whole embryo and explant cultures
Cell movements were traced by microinjecting a small volume (0.5
µl) of 0.05 mg/ml CellTracker CM-DiI (1,1'
dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate,
Molecular Probes, Eugene, OR) in 0.3 M sucrose into the midline of the
posterior primitive streak. Bright-field and fluorescence images were taken
immediately following injection and conceptuses were placed into whole embryo
culture (WEC) (Downs, 2006).
After 6 hours, conceptuses were removed from the incubator, placed in
HEPES-buffered dissection medium (Downs,
2006), photographed, and returned to culture for 6 hours. At 12
hours after culture, fluorescent images were taken of the posterior end of the
conceptus, first with the yolk sac intact, and then after peeling it away to
expose the allantois using a Spot RT-Slider camera attached to a Nikon Diaphot
inverted microscope with a G2A filter cube (excitation, 535 nm; emission, 590
nm; Chroma Technology Corporation, San José, CA). Fluorescent images
were pseudocolored in Metavue and superimposed with bright field using
PhotoShop 7.0 software. Not all specimens for all genotypes contained labeled
allantoic cells; labeled cells were found in the posterior primitive streak
alone (n=1, 3 and 4 for +/+, TC/+ and
TC/TC, respectively), or in both the posterior
streak and proximal allantois (n=1, 7 and 4 for +/+,
TC/+ and TC/TC,
respectively), the latter similar to previous fate mapping this region
(Smith et al., 1994).
Allantoises were explanted, cultured and processed as previously described
(Downs, 2006). For halved
allantoises, whole allantoises were bisected transversely or longitudinally
using handcrafted glass scalpels
(Beddington, 1987). To ensure
orientation, initial cuts were made into the allantois while it was still
attached to the posterior end of the embryo, after which all bisected pieces
were released and pipetted individually into the wells of a 24-well plate.
Explants were stained with antibodies against Flk1 (1:100 dilution).
For yolk sac explants, the allantois was first aspirated from the
exocoelomic cavity, after which glass scalpels were used to make two cuts, one
below the chorion and one above the amnion
(Fig. 7B, part a). Liberated
yolk sacs were placed into WEC (Downs,
2006) for 24 hours. At the end of culture, yolk sac spheres were
prepared for sectional immunohistochemistry, as described above.
LysoTracker Red staining
Conceptuses (EB- to 6-s) were transferred to WEC medium containing 5 µM
LysoTracker Red DND-99 (Molecular Probes, Eugene, OR) and 0.01 mg/ml Hoechst
(bis-benzimide, Sigma H33258) for 30 minutes. After labeling, conceptuses were
rinsed three times in dissection medium, then in PBS, and fixed in 4%
paraformaldehyde at 4°C for 1 hour. Following fixation, conceptuses were
rinsed in PBS and equilibrated in 70% glycerol. Allantoises were isolated and
gently squashed beneath a coverslip, which sometimes had the effect of
distorting relative allantoic lengths. To assess cell death in the primitive
streak, 6 µm transverse sections were prepared as above on samples at each
of the EB, LB, EHF, LHF and 1-s stages. After dewaxing, Hoechst-stained nuclei
were imaged using a DAPI/Hoechst/AMA filter cube (excitation, 360 nm;
emission, 469 nm; Chroma) and LysoTracker was detected with a G2A cube. As
reported in other studies (Ghatnekar et
al., 2004; Zucker et al.,
1999), pilot experiments in B6CBA/J F2 conceptuses confirmed the
specificity of LysoTracker Red uptake. Briefly, apoptotic cells were detected
in B6CBA/J F2 conceptuses primarily within the neurectoderm (LB to LHF
stages), with a few positive cells in the allantoic core (data not shown).
Amongst the three genotypes of the
STOCK-TC/JDown strain, no differences in cell
death were observed within the primitive streak (data not shown). Thus,
subsequent evaluation of cell death in TC/TC
mutants focused on the allantois.
RNA isolation and RT-PCR
Anterior tissue beneath the heart was cut by means of glass scalpels and
used for genotyping, after which conceptuses were individually snap-frozen,
and pooled by stage and by genotype (3-5 conceptuses/stage/genotype) during
RNA isolation using the RNeasy Micro Kit (Qiagen, Valencia, CA). Total RNA
(100 ng) served as template in all reverse-transcription PCR reactions (Access
RT-PCR kit, Promega, Madison, WI) using gene-specific, intronspanning primers.
Primers were: T or TC,
5'-TGCTGCAGTCCCATGATAAC-3',
5'-CCCCTTCATACATCGGAGAA-3'; ß-actin,
5'-ATGAAGATCCTGACCGAGCG-3',
5'-TACTTGCGCTCAGGAGGAGC-3'. Cycling conditions were 35 cycles of
94°C for 30 seconds, 60°C for 1 minute and 68°C for 2 minutes.
Five percent of the reaction was run on a 4% GQA Sieve agarose gel.
|
RESULTS |
|---|
|
TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
;
MacMurray and Shin, 1988;
Stott et al., 1993) have
suggested that the TC allele produces a mutant gene
product. To clarify the status of TC expression in
homozygotes used in this study, RT-PCR was carried out on total RNA from +/+,
TC/+ and TC/TC conceptuses
using primers that flanked the TC deletion and thus
distinguished T from TC transcripts (see
Materials and methods). A single T transcript was detected in +/+
samples, T and TC transcripts were detected in
TC/+ samples, and a single TC
transcript was detected in TC/TC samples at all
stages examined (LHF- to 8-s in +/+ and TC/+; LHF- to 5-s
in TC/TC;
Fig. 1A).
|
)
in +/+ and TC/TC conceptuses, respectively
(Fig. 1B, parts a,c), including
the primitive streak and ectoplacental endoderm (data not shown), but, in
accord with our previous findings, not in the allantois at this stage. With
the exception of the ectoplacental endoderm, where high levels of
TC protein persisted in the cytoplasm of this tissue (data not
shown), TC was absent in all sites in the
TC/TC conceptus between the EHF- to 4-s stages,
at which point we ended this study (e.g.
Fig. 1B, parts b,d; data not
shown). No differences were noted in protein localization between +/+ and
TC/+ embryos at these stages. We conclude that the
TC transcript and protein are produced in
TC/TC conceptuses, and that the protein is
initially correctly localized but, with the exception of ectoplacental
endoderm, it is not maintained in the homozygous mutants.
Allantoic dysmorphogenesis is associated with reduced cell proliferation
TC/TC conceptuses were examined prior to
embryonic death (Table 2).
Although gross defects included an absence of somites (8.25 dpc), and
failure of chorio-allantoic union (8.5 dpc), axial rotation (9.0
dpc) and mid-/hindgut and neural tube closure (9.5 dpc; data not shown),
the earliest discernible gross defect was a short, misshapen allantois at the
EHF stage (data not shown). No gross differences were noted for any feature
between TC/+ and +/+ conceptuses during this period of
development.
The remainder of our study focused on T-related allantoic defects.
Allantoic dysmorphogenesis was examined between the onset of appearance of the
bud and 1-s (Fig. 2). Although
they emerged from the appropriate site at the correct developmental time
(7.25 dpc), TC/TC allantoic buds were
immediately less pronounced than those of +/+ littermates (data not shown). By
the EHF stage, it was evident that, rather than elongating toward the chorion,
TC/TC mutant allantoises tended to spread
toward the amnion (Fig. 2A,D),
making display of the entire length of mutant allantoises in any given
histological section impossible (Fig.
2, compare A-C with D-F). Flattening of the allantoic projection
seemed to be due to loss of the allantoic core
(Fig. 2, compare A-C with D-F),
which normally contained T (Fig.
1B, parts b,e-g). Thereafter, the homozygous mutant
TC/TC allantois appeared to consist
predominantly of outer mesothelial cells and some underlying core cells, few
of which showed signs of endothelialization, which is typically seen in the
distal allantoic region by 1-s (Downs et
al., 1998) (Fig. 2,
compare C with F).
As the primitive streak contributes cells to the allantois throughout the
latter's pre-chorionic fusion stages (7.25-8.5 dpc)
(Downs and Bertler, 2000;
Kinder et al., 1999;
Tam and Beddington, 1987),
with the largest number added at headfold stages
(Downs and Bertler, 2000;
Downs et al., 2004), we
investigated the possibility that TC/TC
allantoic stunting involved a failure of cell displacement from the streak
into the allantois. EHF-stage posterior streak cells of +/+,
TC/+ and TC/TC
conceptuses were labeled with the fluorescent lineage tracer DiI
(Fig. 3A). In all genotypes,
labeled descendants were observed in the proximal allantois in some specimens
after 12 hours of culture (Fig.
3A; data not shown; see Materials and methods for further
explanation). Thus, TC/TC cells were capable of
exiting the primitive streak and entering the allantois throughout the period
of allantoic elongation.
|
Thus, decreased cell proliferation resulted in reduced cell numbers in
TC/TC allantoises. However, as the MIs were
calculated in sagitally sectioned material to make direct comparisons with a
previous study (Downs and Bertler,
2000), we could not accurately calculate the MI in nascent streak
mesoderm and, thus, could not conclude whether defective allantoic
proliferation originated within nascent streak mesoderm prior to entering the
allantois, or whether the proliferation defect was allantois-limited.
The allantoic core dies in the absence of T
Given that T was expressed within the allantoic core, we
investigated whether the core domain was maintained in the mutants. The
specificity of uptake of the acidotropic dye LysoTracker Red as a marker of
apoptosis was verified by comparison with activated caspase-3 in pilot
experiments (see Materials and methods; data not shown). Patterns of cell
death in mutant allantoises were then assessed using LysoTracker Red in
whole-mount preparations (Fig.
4A), and the apparent sites of expression were subsequently
confirmed by sectional analysis (data not shown). At 1-s, dying cells were
found within the TC/TC allantois, initiating in
the mid-region of the allantoic core (Fig.
4A, parts a,b). By 3-s, these extended along the entire length of
the core, including the distal-most part of the
TC/TC allantois
(Fig. 4A, parts f,g). By 6-s,
mutant allantoises were much reduced in size compared with +/+ and only a few
apoptotic cells were observed (Fig.
4A, parts h,j). At all stages, apoptosis was rare in mesothelium
and immediately subjacent cell layers of the
TC/TC allantois. In TC/+
allantoises, cell death was also confined to the core at 1-s, although it was
more variable and less robust than in TC/TC
(Fig. 4A, compare parts c-e
with b). By 6-s, cell death was minimal in both
TC/+ and TC/TC
allantoises, and was indistinguishable from +/+ allantoises
(Fig. 4A, parts h-j).
T does not affect the formation of mesothelium or chorio-adhesive cells
Collectively, our data suggest that T maintains the allantoic core. Loss of
the core coincides with failure of the allantois to elongate toward the
chorion. However, loss of the core did not appear to affect formation or
maintenance of the outer layer of mesothelium. We had previously demonstrated
that bone morphogenetic protein 4 (Bmp4), required for formation of the
allantois (Winnier et al.,
1995), is first expressed in the allantoic mesothelium and
underlying several cell layers until about 4-s, after which expression extends
to allantoic blood vessels (Downs et al.,
2004; Lawson et al.,
1999). As judged by sectional immunohistochemistry in the current
study, Bmp4 was present in all cells remaining in
TC/TC allantoises at intensities similar to +/+
and TC/+ (Fig.
4B, parts a-d); comparison of Bmp4 expression patterns in
TC/TC with +/+ further highlighted the loss of
the allantoic core.
To provide additional support for the presence of mesothelium in the
TC/TC mutants, we next examined Vcam1, which
identifies the distal chorio-adhesive mesothelial subpopulation that mediates
union with the chorion (Downs and Gardner,
1995; Gurtner et al.,
1995; Kwee et al.,
1995). We had previously demonstrated that the Vcam1 domain is
maintained at a distance of 220 µm from the primitive streak
(Downs et al., 2004). In
contrast to +/+ and TC/+ allantoises at 5-s
(Fig. 4C, part a; data not
shown), Vcam1 was not detected in TC/TC
allantoises at equivalent stages (Fig.
4C, part b), despite correct localization within the myocardium of
the heart (Gurtner et al.,
1995; Kwee et al.,
1995) (Fig. 4C,
part b, inset). These results initially suggested that T was in the
same pathway as Vcam1, acting upstream of it in an allantois-specific
manner. However, after measuring it, we found that the 5-s
TC/TC allantois was not long enough to exhibit
Vcam1 (Fig. 4D). By 8- to 16-s
(8.5-9.25 dpc), TC/TC mutant allantoises
had exceeded 220 µm and contained Vcam1
(Fig. 4C, parts c,d;
Fig. 4D,E), although they never
elongated far enough to contact the chorion.
Thus, these results suggest that, could
TC/TC allantoises elongate far enough, they
might fuse with the chorion. However, we, and others, have recently
demonstrated the presence of T mRNA
(Rivera-Perez and Magnuson,
2005) and protein (Inman and
Downs, 2006) in extraembryonic ectoderm and its derivative,
chorionic ectoderm (Inman and Downs,
2006), during the allantoic fusion period, suggesting that T may
have a role in chorio-allantoic union. Thus, chorio-allantoic fusion may
nonetheless be precluded in homozygous TC/TC
mutants because of chorionic defects, a possibility that awaits further
investigation.
|
), Flk1 was detected in scattered cells throughout the
allantoic core of +/+ and TC/+ allantoises at the EHF
stage (Fig. 5A, parts a,b).
Despite decreased cell numbers in TC/+ allantoises at this
stage (Fig. 3C), the percentage
of Flk1-positive angioblasts did not differ significantly from +/+
(Fig. 5A, part d). By contrast,
although Flk1 was correctly localized to TC/TC
core cells (Fig. 5A, part c;
data not shown), the percentage of Flk1-positive angioblasts was significantly
reduced (Fig. 5A, part d).
Allantoic angioblasts do not endothelialize in TC/TC mutants
To examine the endothelialization of TC/TC
allantoic angioblasts, allantoises were explanted at the EHF stage and
cultured in isolation for 24 hours. As judged by morphology and Flk1
immunohistochemistry, no obvious differences were detected between +/+ and
TC/+ explants
(Fig. 5B, parts a,b). Explants
consisted of an adherent layer of mesothelial-derived cells
(Downs et al., 2004) on top of
which was an expanded Flk1-positive vasculature. By contrast, the majority of
cells in the TC/TC explant were mesothelial,
the cell population that did not die in intact
TC/TC allantoises
(Fig. 5B, part c). Although
some angioblasts were present, assembly into a vascular plexus was not
observed.
|
|
), did not
rescue angioblasts or endothelialization and therefore had no discernible
effect on the mutants (data not shown).
Disruption of the allantoic core phenocopies the TC/TC vascularization defect
As a `community effect' is required for cell populations to achieve
localized threshold levels of factors required for differentiation
(Gurdon et al., 1993), we
investigated whether a reduced starting population of Flk1-positive
angioblasts in TC/TC explants was the reason
for the failed vasculogenesis. To decrease overall allantoic cell number,
wild-type EHF-stage allantoises were microsurgically bisected transversely
(T1/2; Fig. 5B, part h) or
longitudinally, either in direct register with the embryonic axis [axial
halves (A1/2); Fig. 5B, part
j], or at 90° with respect to this axis [presumptive dorsoventral halves
(DV1/2); Fig. 5B, part i]. Each
half was then plated in isolation. Previous results had demonstrated that,
although the distal half of the EHF-stage allantois contained more
Flk1-positive angioblasts, the base contained more cells
(Downs et al., 1998). However,
although careful systematic experiments of allantoises in transverse section
have not been carried out to identify distinct dorsoventral or left-right
allantoic coordinates, no obvious differences in Flk1 localization had
previously been noted in the presumptive dorsoventral or left-right allantoic
domains (Downs et al., 1998).
Thus, at the outset, longitudinal explants, whatever their polarity relative
to the embryonic axis, were assumed to contain roughly equivalent numbers of
cells and Flk1-positive angioblasts.
All EHF-stage T1/2 and DV1/2 bisected explants formed convincing vascular
plexi, although these were smaller than wild type
(Fig. 5B, parts g-i). Not
unexpectedly, as the mesothelium crawls off the allantois and forms a cell
base onto which the vasculature adheres
(Downs et al., 2004),
allantoic halves contained roughly half the amount of mesothelium as whole
allantoises. In striking contrast, all A1/2 explants exhibited a failure of
vasculogenesis similar to that seen in
TC/TC explants
(Fig. 5B, part j). Preservation
of the central axial allantoic core resulted in normal vascularization
(Fig. 5B, part j, inset). Thus,
we conclude that, rather than a reduction in cell number, perturbation of the
T core domain appears to affect allantoic endothelialization, but only along
the axis of bilateral symmetry that is in register with the AP axis of the
embryo.
To determine whether perturbation to the axial allantoic core was specific
to the headfold stage, we then longitudinally bisected allantoises at slightly
later stages when these bore morphological evidence of endothelialization
(Downs et al., 1998;
Downs et al., 2004). Although
older A1/2 explants were not as robust as undivided EHF-stage and T1/2
explants, they did form an endothelialized vascular plexus similar to those
found in +/+ and TC/+
(Fig. 5B, parts k-m). Thus,
once angioblast clustering and endothelialization had begun, disruption of the
axial core did not have a striking effect on plexus formation. We conclude
that the axial core does not play a role in the formation of mesothelium but
profoundly affects angioblast survival and endothelialization.
Absence of Pecam1 and vascular patterning in TC/TC mutant allantoises
In contrast to Flk1, which is scattered throughout the allantoic core
during pre-fusion stages (see Downs et
al., 2004), Pecam1 has been observed anecdotally within a central
midline vessel of the allantois as early as headfold stages
(Ilic et al., 2003;
Naiche and Papaioannou, 2003).
Pecam1 is a member of the immunoglobulin (Ig) superfamily, containing a
cytoplasmic immunoreceptor tyrosine-based inhibitory motif (ITIM), and playing
roles in endothelial cell survival and migration
(Newman, 1999;
Newman and Newman, 2003).
Pecam1 is dispersed across the cell surface in migrating endothelial cells,
but localizes to endothelial cell intercellular junctions in non-migrating
cells (Gratzinger et al.,
2003; Newman et al.,
1992; Wong et al.,
2000). The spatial relationship between Pecam1 and Flk1 is not
known, but, given that the allantoic core died in
TC/TC mutants, and that numbers of Flk1
angioblasts were severely diminished, we examined Pecam1 first in wild-type
allantoises whose Flk1 angioblasts were marked with a reporter lacZ
construct (Flk1lacZ; see Materials and methods), and then
in littermates of TC/+ intercrosses.
Pecam1 was initially observed in a clustered group of allantoic cells at
the LB stage, whereas Flk1 angioblasts, as described previously, were
scattered throughout the core (Fig.
6A, part a, inset). From the LB cluster, the Pecam1 domain
extended distally (Fig. 6A,
parts a,b), forming a central vessel that showed signs of increased branching
with increasing age (Fig. 6A,
part c). At 2-s, the central track of proximal Pecam1 seemed to split and
triangulate around the proximal allantoic core
(Fig. 6A, part b), but, by 6-s,
it formed a robust central vessel that had amalgamated with the embryonic
dorsal aorta (Fig. 6A, part c).
Between 2- and 6-s, Pecam1 was most clearly observed on the cell surface,
outlining individual cells (e.g. Fig.
6A, part c). Intriguingly, Flk1-positive angioblasts did not
coalesce into a central vessel and amalgamate with the embryonic vasculature
until 6-s (Fig. 6A, part d).
Thus, in contrast with Flk1, Pecam1 defines a spatially patterned vascular
domain in the allantois between 7.25 and 8.5 dpc.
In +/+ littermates of TC/TC mutants, Pecam1 was detected along the central allantoic vessel, where it was also present on the cell surface, as well as on the surface of the developing dorsal aortae of the embryo (Fig. 6B, part a and inset). In TC/+ allantoises, the Pecam1-positive vessel was present but of variable length, and Pecam1 staining was absent in the dorsal aortae (Fig. 6B, parts b,c). Given that TC/+ pups are viable, these observations may reflect a delay in vasculogenesis. Neither the Pecam1-positive allantoic midline nor dorsal aortae were observed in TC/TC conceptuses at the stages examined (2- and 5-s), although an occasional Pecam1-positive cell was found in the distal TC/TC allantois (Fig. 6B, part d). Thus, we conclude that, although T is not required for the differentiation of Flk1 or Pecam1 angioblasts, its absence results in loss of vascular patterning in the allantois.
|
9.5 and 10.5
dpc (Table 2), slightly earlier
than presumptive embryonic dependence on the chorio-allantoic placenta, and
coinciding more precisely with activity of the chorio-vitelline placenta
(Copp, 1995) and the presence
of a robust circulation (Downs et al.,
1998). As T protein was recently described within the developing
heart and within the extraembryonic visceral endoderm overlying nascent blood
islands of the yolk sac (Inman and Downs,
2006), we examined these major vascular organs for evidence of
aberrancies in TC/TC mutant conceptuses.
Until 2- to 3-s, the developing
TC/TC heart field was grossly
indistinguishable from +/+ (data not shown). As early as 4-s, when T was first
observed in the heart (Inman and Downs,
2006), histological sections of
TC/TC hearts revealed a reduced cardiogenic
mass (data not shown). By 6-s, when levels of T were maximal in myo- and
endocardium (Inman and Downs,
2006), the heart appeared dysmorphic, exhibiting a decreased
pericardial cavity, and reduced myo- and endocardium
(Fig. 7A, parts a,b). In
contrast to +/+, only low levels of Flk1 were detected in the mutant
myocardium (Fig. 7A, parts
a,b). By 16-s (9.5 dpc), large numbers of pyknotic cells were observed in
TC/TC hearts (data not shown). Similar to
previous results in T/T mice
(King et al., 1998), defects
in TC/TC hearts were observed during the time
of heart looping and involved structural abnormalities of developing heart
layers.
In addition, aberrant TC/TC yolk sac blood
island morphology was observed in some histological sections as early as the
EHF stage when T was recently reported in extraembryonic visceral endoderm
overlying blood island mesoderm (Inman and
Downs, 2006); however, abnormalities were most pronounced by 1-s
(e.g. Fig. 2F,
Fig. 5A, part c).
TC/TC conceptuses had a thickened region in the
approximate location of developing blood islands, where cells were found
between the extraembryonic mesoderm and visceral endoderm layers but were not
packaged inside a continuous Flk1-positive endothelium.
To examine development of mutant yolk sacs in isolation, yolk sacs of +/+, TC/+ and TC/TC conceptuses were separated from the rest of the conceptus (Fig. 7B, part a) and cultured for 24 hours. +/+ yolk sacs exhibited continuity of the visceral endoderm, and Flk1-positive vascular channels contained an abundance of hematopoietic cells (Fig. 7B, parts b,c). By contrast, the visceral endoderm of TC/TC mutant yolk sacs was discontinuous, and appeared to contain an abnormally high lipophilic content within cytoplasmic vacuoles (Fig. 7B, parts d,e). Presumptive hematopoietic precursors remained in a compact cluster within discontinuous Flk1 vessels and exhibited evidence of pyknosis (Fig. 7B, parts d,e). TC/+ yolk sacs exhibited a phenotype intermediate between +/+ and TC/TC; for example, some blood islands and associated extraembryonic visceral endoderm appeared relatively normal (e.g. Fig. 7B, part f), whereas others were dysmorphic (Fig. 7B, part g).
|
DISCUSSION |
|---|
|
TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
). In that landmark study, presumptive +/+, T/+ and
T/T conceptuses were explanted and cultured within the chick
extraembryonic coelom to elucidate the role of the allantois in embryonic
development. It was concluded, however, that the variability in the resultant
T allantoic phenotypes and the inability to correlate genotype with
each class of allantoic defect precluded an elucidation of the role of T in
the allantois, and the role of the allantois in the embryo.
Thanks to the `tour-de-force' molecular cloning of T
(Herrmann et al., 1990), we
were able to readily genotype conceptuses bearing
TCurtailed, a T-limited allele
(Searle, 1966;
Stott et al., 1993), and to
combine this information with recent technical and intellectual advances in
allantoic development. These included knowledge of the origin of allantoic
mesoderm (Lawson et al.,
1991), a morphological staging system
(Downs and Davies, 1993), a
reliable and practical method of whole embryo culture
(Lawson et al., 1991), and an
explant system (Downs et al.,
1998; Downs et al.,
2001). Moreover, we made use of an emerging developmental context
for the allantois (see Downs et al.,
2004).
|
). We
show here that, in the absence of T, the core died, resulting in a failure of
the allantois to elongate toward the chorion and appropriately
vascularize.
Whilst the major focus of our study was on the role of T in the allantois,
our results link T function to widespread vascularization in the mouse
conceptus. Although not yet extensively studied, loss of T affected
development of the heart, the first signs of cardiac dysmorphology beginning
at 4-s when T was first detectable in the cardiogenic mass
(Inman and Downs, 2006). This
finding suggests that T is required autonomously within the heart. T
also appeared to be required for correct yolk sac vascularization, as T was
identified within yolk sac endoderm (Inman
and Downs, 2006). Yolk sac endoderm is required for the formation
of yolk sac blood vessels in the chick
(Miura and Wilt, 1970;
Wilt, 1965) and yolk sac blood
islands in the mouse (Belaoussoff et al.,
1998). Thus, on the basis of these findings, we conclude that
T plays a global role in vascularization of the mouse conceptus.
The TC allele produces a mutant gene product
Previous studies indicated that the TC deletion
produces a mutant protein (Herrmann and
Kispert, 1994; MacMurray and
Shin, 1988) that may interfere with T in
TC/+ conceptuses. Dominant-negative (antimorphic) action
of the TC allele was revealed in experiments where
introduction of a full-length T transgene failed to completely
restore tail length in TC/+ animals
(Stott et al., 1993). The work
presented here revealed that TC/+ heterozygotes
exhibited allantoic phenotypes intermediate between those of +/+ and
TC/TC for all parameters examined, including
allantoic elongation, cell number, mitotic index, cell death and
vasculogenesis, the latter affecting the yolk sac as well. Despite being
shorter than wild type, all TC/+ allantoises
ultimately grew far enough to fuse with the chorion. Thus, these results
support an antimorphic nature of the TC allele with
respect to the wild-type protein product.
To provide insight into the molecular nature of T, we demonstrated that
TC expresses a single mRNA transcript that is maintained
in the heterozygous and homozygous genotypes throughout the period examined
here. By contrast, the TC protein, although initially localized
properly to the T expression domain, was only transiently expressed in the
TC/TC conceptus, except within ectoplacental
(distal extraembryonic) endoderm, which will line the sinuses of Duval
(Duval, 1891), thought to be
involved in calcium transport (Bruns et
al., 1985). It was previously shown that, in T/T
ES cells, the T promoter can be activated in the absence of
functional T protein (Schmidt et al.,
1997). Our results reveal that the unaltered promoter region of
TC is activated in vivo in a completely mutant
environment. This finding is similar to reports of another T allele,
TWis (Herrmann,
1991; Kispert and Herrmann,
1994), and supports some degree of autoregulation of T. A
series of studies in Xenopus
(Casey et al., 1998;
Isaacs et al., 1994;
Schulte-Merker and Smith,
1995) and mouse (Clements et
al., 1996; Galceran et al.,
2001; Yamaguchi et al.,
1999) indicated an indirect autoregulatory feedback loop involving
T and members of the fibroblast growth factor (Fgf) family
(Xenopus) and the Wnt family (mouse). Together, these studies
proposed that Fgf and Wnt family members are targets of T.
Furthermore, although neither Fgfs nor Wnts are required for the initiation of
T expression, signaling from these T targets is required to
sustain further production of T. Why the mutant TC protein persists
only in ectoplacental endoderm is not clear; although very little is known
about this tissue, one possibility is that it lacks the machinery to degrade
defective proteins.
T maintains a novel allantoic core domain required for allantoic elongation
As discussed in previous sections, recent results from our laboratory
demonstrated that T is localized to a novel allantoic core domain between LB
and 6-s (7.25-8.25 dpc), which, as observed in sagittal section, was
continuous with the embryonic primitive streak
(Inman and Downs, 2006). Here,
we have confirmed by transverse immunohistochemical sections that T lies
within the allantoic core (Fig.
1B, parts e-g). In the absence of T, only the outer few
allantoic cell layers were maintained. In addition, overall allantoic cell
proliferation was diminished and cells in the allantoic core died. Together,
these had the effect of abrogating allantoic elongation. By contrast, the
primitive streak, which also expresses T, appeared normal for both cell
proliferation and survival during the stages examined. That Vcam1 was
correctly expressed and positioned within the distal allantoic region further
supported normal streak activity, as we have previously demonstrated that
positioning of allantoic Vcam1 is dependent upon signaling from the streak
(Downs et al., 2004). Finally,
these results provide a plausible explanation for why T/T
mutant cells were not found within some defective allantoises of otherwise
chimeric T/T conceptuses
(Wilson et al., 1993): instead
of failure to be displaced from the streak into the allantois, which we showed
was not the case (Fig. 3A),
T/T cells likely contributed to the allantois. In those
chimeras where mutant cells had contributed to the core, the latter might have
died during a developmental window that was overlooked in those previous
studies.
T is not required for differentiation of mesoderm into angioblasts, but is required for vascular patterning
In the absence of T, angioblasts formed, but their population did
not expand, either because of diminished proliferation and/or because of
failure to survive. Moreover, although the odd Pecam1-positive cell was found
in homozygous TC/TC mutant allantoises,
vascular patterning, as revealed by an increasingly branched Pecam1-positive
allantoic midline vessel in normal allantoises, was abolished.
Although the precise relationship between Flk1 and Pecam1 within the
allantois is not yet known, our results suggest that Pecam1-positive cells
provide a vascular scaffolding upon which the dispersed Flk1-positive cells
can assemble. Flk1-positive cells did not form a central vessel until 6-s
(Fig. 5A, part d). By contrast,
Pecam1 cells immediately assembled into a central vessel that began to extend
toward the embryonic region at 2-s, although its embryonic connection was not
certain until 6-s (Fig. 5A-C).
Amalgamation of the vascular systems of the conceptus by 6-s is consistent
with previous results that demonstrated that infiltration of yolk sac
primitive erythroid cells into the allantois takes place at about 5-s
(Downs et al., 1998).
Localization of Pecam1 to the surface of angioblasts has been implicated in
angioblast migration and assembly into cords
(Bohnsack and Hirschi, 2003).
This process may involve heterophilic interactions between Pecam1 and
integrins (Wong et al., 2000).
In addition, mutants bearing a disruption in focal adhesion kinase (FAK; Ptk2
- Mouse Genome Informatics) exhibit differentiation of angioblasts but lack an
endothelialized and patterned allantoic vasculature
(Ilic et al., 2003). Thus,
further investigation into the molecular hierarchies involved in vascular
patterning may identify integrins and FAK as downstream members of a
T-activated pathway for vascular patterning.
Finally, Vegf165, the predominant isoform of Vegfa, which has an
affinity for heparin (Ferrara and
Davis-Smyth, 1997), was not able to rescue
TC/TC mutant Flk1 cells, as it did wild-type
allantoic angioblasts cultured in low serum
(Downs et al., 2001). Although
further study is required, heparin or heparan sulfate proteoglygans may be
absent from or defective in mutant allantoises, which accords with
observations that T/T mutants are defective in the
extracellular matrix (Jacobs-Cohen et al.,
1983).
The source of the allantoic vascular patterning signal may reside within the allantoic core. Physically disrupting the core within its plane of continuity with the embryonic midline phenocopied the T endothelialization defect: angioblasts formed, but they did not endothelialize. Longitudinal bisections 90° to this axis or perpendicular to it had no affect on vascularization. Thus, these observations suggest that the allantoic core possesses polarity that is aligned with respect to the embryonic AP axis.
|
ACKNOWLEDGMENTS |
|---|
