|
|
|
|
|
|
|
||||
| Home Help Feedback Subscriptions Archive Search Table of Contents | ||||
First published online 6 February 2008
doi: 10.1242/dev.013359
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
1 Section of Neonatology, Perinatal and Pulmonary Biology, Cincinnati Children's
Hospital Medical Center and The University of Cincinnati College of Medicine,
Cincinnati, OH 45229, USA.
2 Division of Developmental Biology, Cincinnati Children's Hospital Medical
Center and The University of Cincinnati College of Medicine, Cincinnati, OH
45229, USA.
* Author for correspondence (e-mail: jeff.whitsett{at}cchmc.org)
Accepted 2 January 2008
 |
SUMMARY |
|---|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
Key words: R-spondin 2, Lrp6, Lung, Larynx, Trachea, Limb, Development, Wnt signaling, Sp8, Mouse
|
INTRODUCTION |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
).
β-Catenin translocates to the nucleus and interacts with lymphoid
enhancer factor (Lef)/T-cell factor (Tcf) transcription factors to alter gene
transcription. Lrp6-mediated activation of the canonical Wnt signaling pathway
also occurs in response to a new family of ligands: the R-spondins (Rspo)
(Kazanskaya et al., 2004;
Nam et al., 2006;
Wei et al., 2007).
Disruption of the Wnt signaling pathway alters normal development of the
lung and limb. Murine lung development begins at E9.5 as the foregut endoderm
invaginates into the surrounding mesenchyme. Lung morphogenesis is dependent
upon mesenchymal-epithelial interactions that promote branching of lung
tubules. Primary branching forms the two bronchi, whereas asymmetric secondary
branching, which occurs between E10 and E11.5, defines the number of airways
and lobulation. Continued proximodistal branching generates the conducting
airways that lead to the alveoli in the mature lung. High levels of Wnt
signaling, indicated by the TOPGAL reporter, occur in the epithelium and
mesenchyme adjacent to the proximal airways between E10.5 and E12.5
(De Langhe et al., 2005). The
early epithelium expresses Wnt7b and Lrp6, whereas the
mesenchyme expresses Wnt2a (De
Langhe et al., 2005; Wang et
al., 2005). Both tissues express Wnt11, Wnt5a and
β-catenin (Li et al.,
2002; Tebar et al.,
2001; Weidenfeld et al.,
2002). Wnt5a-/- fetuses exhibit truncation of
the trachea, overexpansion of distal airways and disrupted lung maturation
(Li et al., 2002). Lung
hypoplasia and defects in pulmonary vessel smooth muscles were observed in
Wnt7b-/- mice (Shu et
al., 2002). Removal of β-catenin expression in the
respiratory epithelium resulted in a failure of distal airway formation
(Mucenski et al., 2003).
Canonical Wnt signaling is also required for normal limb formation. Cells
within the emerging limb bud ventral ectoderm will form the apical ectodermal
ridge (AER) (Bell et al.,
2003b). The mature AER is localized at the limb bud apex and
required for proximodistal elongation of the limb. The absence of
Wnt3 or β-catenin expression in murine AER precursor cells
disrupts AER formation, resulting in distal limb truncations
(Barrow et al., 2003). The AER
also fails to form in embryos that lack Lef and Tcf
(Galceran et al., 1999).
Lrp6 deletion causes limb abnormalities attributed to AER
deficiencies (Pinson et al.,
2000).
Reminiscent of Lrp6-/-, the hindlimbs of fetuses
homozygous for the footless mutation lack either the entire paw
(autopod) or the posterior digits and, frequently, the fibula
(Bell et al., 2003a).
footless homozygotes also lack right forelimb digits 1 and/or 2.
Distal telephalanges and fingernails were missing on formed digits. These
malformations were previously correlated with regional deficiencies in AER
formation at E10.5. Homozygous footless progeny had cleft palate and
died of unknown causes at birth.
Herein, we tested the hypothesis that integration of the footless transgene affected a component of the Wnt signaling pathway critical for formation of limbs and the respiratory tract. Transgene integration disrupted the R-spondin 2 (Rspo2) gene, creating a mutant allele: Rspo2Tg. We present data that Rspo2Tg/Tg fetuses possess laryngeal-tracheal cartilage malformations and lung hypoplasia. The limb and lung phenotypes were exacerbated by the absence of Lrp6.
|
MATERIALS AND METHODS |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
). E18.5
fetal crown-rump lengths, weights and body circumference under the forelimbs
were recorded. Lung, trachea and laryngeal tissues were dissected and weighed
prior to fixation. For visualization of cartilage and bone, alcohol (95%)
fixed, skinned fetuses and trachea were stained with Alizarin Red and Alcian
Blue, and cleared in graded 2% KOH:glycerol solutions (100:0-0:100).
Paraformaldehyde (4%) fixed tissue was embedded in paraffin wax. Genomic DNA
from the fetal viscera was used for genotyping.
Gene and cDNA characterization
RT-PCR and Northern blot analyses were performed on E11 embryo total RNA.
RNA was reversed transcribed using Oligo dT and Superscript II (Invitrogen)
and amplified with the Rspo2 primer pairs
5'-GCGGGTGTCGGCAAACTTTTTC-3' and
5'-ATCTGGGGCTCGGTGTCCATAATAC-3' (818 bp product spanning exons
1-3); 5'-CATCAGGGTATTATGGACACCGAG-3' and
5'-TGCTCTTGGGCTCTCTCAATCAGC-3' (spanning exons 3-6); and
5'-GCGGGTGTCGGCAAACTTTTTC-3' with the SV40 primer
AGGTAGTTTGTCCAATTATG-3' (spanning exon 1 into transgene). Products were
subcloned and sequence verified. The 818 bp product was hybridized to northern
blots.
Alkaline phosphatase-Rspo2 fusion constructs and cell lines
The Rspo2 cDNA was PCR amplified using a common NheI flanked
5' primer 5'-TCCAGCTAGCTAGCCACCATGCGTTTTTGCCTC-3' with
either 5'-AGTAGATCTTGCACATCTGTTCATATCTGG-3',
5'-CGGAAGATCTACCTTCTACACATTCCAT-3',
5'-TCCGGAAGATCTCTTTGGTGTTCTCTTTCC-3' or
5'-CCCGAGATCTTGGTTCACTCTGTC-3'. NheI/BglII
digested PCR products were subcloned into APTAG5 (GenHunter). Sequence
verified constructs were transfected into HEK293T cells and clonal cell lines
established by Zeocin (Invitrogen) selection (600 µg/ml). Clones were
maintained in 300 µg/ml Zeocin. For conditioned media, subconfluent cell
cultures were incubated in serum containing growth media or OptiPro
(Invitrogen) for 3-4 days. As a negative control, conditioned media was
collected from APTAG4 cells (GenHunter) secreting AP.
Alkaline phosphatase activity assays
AP assay reagents A and S (GenHunter) were used according to the
manufacturer instructions to quantitate AP activity in conditioned media,
eluates, or cell lysates. For cell binding assays, subconfluent cultures of
HEK293T, MLE15 or HeLa cells were rinsed in Hanks Balanced Salt Solution
(HBSS), incubated with conditioned media containing equivalent AP activity
units for 1.5 hours at room temperature, rinsed five times in HBSS and lysed
in 0.5 ml of AP lysis buffer (GenHunter). In some experiments, heparin (Sigma)
was added with the media. Lysates were heated at 65°C 15 minutes to
inactivate endogenous AP activity. Average activity from triplicate wells is
presented.
Heparin binding assay
Conditioned media were absorbed to 300 µl of heparin agarose (Sigma) at
4°C with rocking for 48 hours. The agarose was pelleted by centrifugation
and washed by sequential resuspensions in 50 mM Tris (pH 8.0) with the
indicated amount of NaCl. AP activity present in each eluate was
determined.
Luciferase assays
HEK293T cells (
1.5x105/well) were co-transfected with
TOPFLASH (Upstate), pRL-TK (Promega) and Lrp6 plasmids using Fugene 6 (Roche).
Conditioned medium containing equivalent levels of AP activity was added 24
hours post-transfection and incubated 24 hours prior to cell lysis. Firefly
luciferase and Renilla luciferase activity were determined using the
Promega Dual Luciferase assay. Each assay was performed in triplicate and all
experiments were performed at least twice.
β-Gal assays
E11.5 lung buds from 46-54 somite embryos were dissected and frozen at -70
until genotyped. Each lung was resuspended in 25 µl of lysis reagent. Two 5
µl aliquots were incubated with Galacton-Star substrate (Applied
Biosystems) for 90 minutes and light emission read in a Monolight 3010
luminometer. The amount of protein present in each lysate was determined in
duplicate using the Bio-Rad protein reagent according to the manufacturer's
directions. For each lung, β-galactosidase activity was normalized to
total protein.
For whole-mount visualization, lungs were fixed for 1 hour, rinsed three times in PBS, and developed for 5 hours in 5 mM K3Fe(CN)6, 5 mM K4Fe(CN)6, 2 mM MgCl2, 0.01% sodium deoxycholate, 0.2% NP-40 and 1 mg/ml X-Gal.
Lung organ culture
Dissected E11.5 lung buds were placed onto Nucleopore Trach-etched 8 µm
membranes (Whatman) in wells containing 0.5 ml of DMEM containing 10% FCS, 2
mM glutamine, 100 units/ml penicillin/streptomycin and 0.5 ml of the indicated
conditioned medium. Explants were incubated at 37°C with 5% CO2
and photographed every 24 hours.
Lrp6 constructs
Full length mouse Lrp6 with a single C-terminal Flag tag was provided by Dr
R. Lang (CCHMC). To create 
EGF2 Lrp6, the plasmid was partially
digested with EcoRV and religated, deleting amino acids 359-641. To
create EGF3-4 Lrp6, the XbaI/XhoI 7552 bp vector-Lrp6
fragment was isolated. PCR introduced an XhoI site at amino acid
1247; a product spanning from 1247 to the end of the flag epitope was
amplified. Ligation resulted in a construct deleting amino acids 638-1247.
Western blots
Samples were boiled in Laemmli buffer, electrophoresed under denaturing
conditions and blotted onto nitrocellulose. Rspo2-conditioned media were
concentrated using Centricon 30 centrifugal filter units (Millipore). Rspo2AP
fusion proteins were detected using a rabbit polyclonal antibody to human
placental AP (1:2000) (GenHunter). Lrp6 constructs were transfected into
HEK293T cells and cell lysates generated 48 hours later in the presence of
protease inhibitor cocktail (Sigma). The Lrp6-flag epitope was detected using
monoclonal M2 anti-Flag antibody (Sigma) (1:10,000), an anti-rabbit IgG
peroxidase conjugate (Calbiochem) (1:10,000) and ECL western blotting
detection reagent (GE Healthcare).
Immunohistochemistry
Paraffin wax-embedded tissue was sectioned at 5 µm, dewaxed, rehydrated
in graded ethanols, subjected to antigen retrieval, and endogenous peroxidase
activity was quenched in methanol and H2O2 for 15
minutes. Antibodies requiring antigen retrieval were FoxJ1 (using 0.1 M
citrate buffer, pH 6.0 and heat) and Pecam1 (15 minutes trypsin digestion at
37°C). Biotinylated secondary antibodies (1:200, Vector Laboratories) were
detected using an avidin-biotin-horseradish-peroxidase detection system (ABC
reagent, Vector Laboratories, Burlingame, CA). Sections were counterstained
with Nuclear Fast Red. As a negative control, primary antibody was omitted on
some slides. Primary antibodies used were rabbit anti-FoxJ1 (1:5000; from Dr
Robert Costa), mouse anti-
-smooth muscle actin (1:10,000; monoclone
1a4, Sigma), rabbit anti-proSP-C and rabbit anti-CCSP (1:1000, Seven Hills
Bioreagents), rat anti-Pecam-1 (1:500; monoclonal CD-31, Pharmigen), and
hamster anti-T1-alpha (1:500; Clone 8.1, Iowa Developmental Studies Hybridoma
Bank).
Real-time RT-PCR
cDNA was generated from ectodermal hulls of stage 1.5 and 4 hindlimb buds
or E11.5 lung buds, and real time RT-PCR was performed using gene specific
primers as previously described (Bell et
al., 2005). At least two independent cDNA samples generated from
pooled tissues were used. All values were normalized to -tubulin within
the sample.
|
RESULTS |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
). Using genomic fragments immediately flanking the
integration site, overlapping clones were isolated and characterized from a
genomic 129S/SvJ library. NCBI Blast analysis of sequenced clones localized
the transgene integration site to the third intron of the R-spondin 2
(Rspo2) gene (Kazanskaya et al.,
2004; Lowther et al.,
2005; Nam et al.,
2006), denoted the Rspo2Tg allele. The entire
Rspo2 gene uses six exons and spans 150 kb
(Fig. 1A). No other transcripts
have been mapped to this genomic region. EST analysis and whole-mount in situ
hybridization assays confirmed that the full-length transcript contains an
1.6 kb 5' untranslated region and includes sequences present within
NM_172815, EST BB707197 and EST AK011587.
|
4.5 kb band in Rspo2+/+ and
Rspo2+/Tg samples. A smaller transcript was also present
in Rspo2+/Tg and was the only band in
Rspo2Tg/Tg RNA (Fig.
1B). Using exon specific primers, the alternate band was
characterized by RT-PCR. A product spanning exons 1-3 was readily amplified
from Rspo2+/+ and Rspo2Tg/Tg cDNA. By
contrast, an exon 3-6 PCR product was robustly amplified from
Rspo2+/+ cDNA, but only a negligible amount of product was
generated from Rspo2Tg/Tg cDNA, indicating a very low
level of full-length transcript production in Rspo2Tg/Tg
embryos (Fig. 1C). Using exon 1
and SV40 primers, a PCR product was amplified from
Rspo2Tg/Tg cDNA. Sequence analysis indicated that exon 3
splices in frame to a cryptic splice-acceptor in the transgene, resulting in
the potential production of a Rspo2-CAT fusion protein containing amino acids
1-94 of Rspo2 and 148-219 of CAT (data not shown). The exon 1-3 and 3-6 PCR products were used to generate antisense riboprobes for whole-mount in situ hybridization assays. At E10.5, Rspo2 mRNA was detected in the AER of the limb buds from wild-type embryos using either riboprobe (Fig. 3B, data not shown). In Rspo2Tg/Tg embryos, the probe spanning exons 1-3 detected Rspo2 expression within the AER and other locations, whereas the probe for exons 3-6 failed to detect mRNA expression anywhere in the embryo (data not shown). Integration of the transgene generated a severe hypomorphic allele of the mouse Rspo2 gene that preferentially splices from exon 3 of Rspo2 into the transgene.
Secretion of Rspo2 and activation of canonical Wnt signaling
The murine R-spondin gene family consists of four structurally
similar members located on distinct chromosomes. Rspo2 is a 243 amino acid
protein comprising a 21 amino acid signal peptide followed by a cysteine-rich
region (amino acids 40-80 encoded by exon 3), a furin-like domain (amino acids
89-144 encoded by exon 4), a thrombospondin type 1 (TSP1) domain (amino acids
148-203 encoded by exon 5) and a C-terminal highly charged region (amino acids
207-243 encoded by exon 6) (Fig.
2A). Alkaline phosphatase (AP) was fused to the C-terminus of
either full-length Rspo2 (Rspo2AP) or domain deletion mutants. To create the
truncated protein encoded by Rspo2Tg, amino acids 96-243
(96-243AP) were deleted. 148-243AP removed the TSP1 and highly
charged domains of Rspo2. 212-243AP removed the highly charged
C-terminus. Stable HEK293T cell lines expressing each construct secreted AP
into the media (data not shown). Western blot analysis confirmed the presence
of correctly sized Rspo2-AP fusion proteins
(Fig. 2B) demonstrating that
all of the Rspo2-AP fusion proteins were secreted.
The TSP1 domain of Rspo2 is closely related to the single TSP1 domain in
mindin and fifth TSP1 domain in F-spondin, both previously shown to directly
interact with heparin (Feinstein et al.,
1999; Tzarfaty-Majar et al.,
2001). TSP1 domains identified in other heparin-binding signaling
molecules, including HB-GAM and midkine, form a heparin binding β-sheet
structure (Kilpelainen et al.,
2000). The basic C-terminal domain of Rspo2
(Fig. 2A) is similar to that
found in growth factors that interact with extracellular matrix proteins on
cell surfaces (Houck et al.,
1992; LaRochelle et al.,
1991). The ability of Rspo2 to interact with the cell surface was
evaluated by absorbing conditioned media containing Rspo2AP fusion proteins to
HEK293T, HeLa and MLE15 cells. Both the full-length and 212-243AP
fusion proteins bound the cell surface of all cell types with greatest binding
detected with Rspo2AP (Fig.
2C, data not shown). No cell-surface binding was observed with
media containing AP, 96-243AP or 148-243AP. Rspo2AP and
212-243AP cell-surface interactions were dose-dependently displaced
with heparin (see Fig. S1 in the supplementary material). To confirm direct
interactions between Rspo2 fusion proteins and heparin, conditioned media were
absorbed to heparin-agarose. The absorbed agarose was sequentially washed with
buffers containing increasing amounts of NaCl, and AP activity was evaluated
in the eluates. AP, Rspo2 96-243AP and Rspo2 148-243AP were
poorly retained by the heparin agarose. Consistent with the cell binding
assays, Rspo 2AP exhibited a higher affinity for heparin agarose than did
Rspo2 212-243AP (Fig.
2D). These data indicate that Rspo2 interacts with cell surface
heparin sulfate proteoglycans, that the TSP1 domain is critical for this
interaction and that amino acids 212-243 of Rspo2 potentiate heparin binding.
Homologous domains in mRspo3 are required for Rspo3 binding to heparin
sepharose (Nam et al.,
2006).
Rspo family members activate the canonical Wnt signaling pathway by
interacting with Lrp6 (Kazanskaya et al.,
2004; Nam et al.,
2006; Wei et al.,
2007). To evaluate the biological activity of the Rspo2-AP fusion
proteins and to further define the domains required for interaction with Lrp6,
HEK293T cells were transfected with the luciferase Wnt signaling reporter
TOPFLASH and pRL-TK (Renilla luciferase under control of the HSV-Tk promoter),
and exposed to the indicated conditioned media. TOPFLASH reporter activation
was observed in the presence of Rspo2AP, 212-243AP and, to a lesser
extent, 148-243AP, but was not induced by 96-243AP
(Fig. 2E). Thus, the truncated
Rspo2 product encoded by the Rspo2Tg allele would not be
able to activate the canonical Wnt signaling pathway.
Rspo2 and Lrp6 interactions
In HEK293T cells expressing Lrp6, Rspo2 increased Wnt signaling
approximately sevenfold (Fig.
2F). The extracellular domain of Lrp6 contains 4 EGF-like domains
separated by multiple LDL repeats. To identify the regions within the
extracellular domain of Lrp6 that interact with Rspo2, Flag-tagged Lrp6 and
deletion mutants lacking either EGF-like domain 2 (EGF2) or 3 and 4
(EGF3-4) were co-transfected with TOPFLASH and pRL-TK into HEK293T
cells and then exposed to Rspo2AP or AP conditioned media for 24 hours.
TOPFLASH expression was highest in the presence of Rspo2AP and full-length
Lrp6. Although EGF3-4 increased TOPFLASH activity in the presence of
Rspo2AP, EGF2 was not active (Fig.
2F). Western blot analysis detected appropriately sized Lrp6
proteins in the transfected cells (Fig.
2F insert). Therefore, Rspo2 activation of canonical Wnt signaling
is dependent on the second EGF-like domain of Lrp6. The reduction in the level
of TOPFLASH activation observed by EGF3-4 suggests that these domains
may also be involved in Rspo2 signaling.
|
; Nam et al.,
2007a).
Sp8 is required for expression of Rspo2 in the AER
Morphogenesis of the AER is dependent upon expression of the transcription
factor Sp8 in the ventral ectoderm of the emerging limb bud
(Bell et al., 2003b). Cells
initially fated to form the AER are present in the ventral ectoderm of
Sp8-/- hindlimb buds, express a variety of AER markers,
but fail to form a mature AER (Bell et al.,
2003b). Rspo2 expression was assessed in
Sp8-/- embryos since Rspo2Tg/Tg
embryos exhibit a disruption in AER maturation
(Bell et al., 2003a) and
Rspo2 is coordinately expressed with Sp8 in the forming and
mature AER cells (Fig.
3A,B,D,J,K). Rspo2 mRNA was not detected in limb buds of
E10 Sp8-/- embryos, although expression was present in the
telencephalon (Fig. 3C).
Real-time RT-PCR determined that the Rspo2 mRNA level in E10.5
Sp8-/- hindlimb ectoderm was reduced eightfold compared
with controls (Fig. 3I). The
AER markers Bmp4 and Dlx2 were reduced only 1.5- to twofold
(Fig. 3I, data not shown). As
the hindlimb AER matured between stages 1
(Fig. 3B) and 4
(Fig. 3D), Rspo2 mRNA
increased approximately fourfold. Expression of Bmp4 and
Dlx2 was unchanged (Fig.
3I, data not shown). By contrast, Sp8 expression was
detectable in the fore and hindlimb AERs of Rspo2+/+ and
Rspo2Tg/Tg embryos
(Fig. 3J,K). As previously
described (Bell et al., 2003a),
AER deficiencies are not readily detectable in E10.5
Rspo2Tg/Tg embryos with fewer than 35 somites. Like
other AER markers, disruptions in Sp8 expression were observed along
the posterior hindlimb and anterior forelimb margins of
Rspo2Tg/Tg embryos
(Fig. 3K). Notably,
Sp8 expression within the AER containing areas of the
Rspo2Tg/Tg fore and hindlimbs appeared weaker. Nam et al.
recently reported a similar limb phenotype in fetuses homozygous for a gene
targeted Rspo2 allele and also observed a decrease in Sp8
expression (Nam et al.,
2007b). These observations suggest that Rspo2 expression
is dependent on Sp8 within the AER precursors and support previous
observations indicating that continued Sp8 expression is regulated by
canonical Wnt signaling (Bell et al.,
2003b; Kawakami et al.,
2004).
|
). Forelimb
ectrodactyly 5 was a characteristic of
Rspo2+/+;Lrp6-/- fetuses (99%)
(Pinson et al., 2000) and was
also observed in the right forelimb of
Rspo2+/Tg;Lrp6+/- animals (20%)
(Fig. 4B,D; see Table S1 in the
supplementary material). An increase in the number of progeny missing digits
and with malformations of more proximal skeletal elements was observed in
Rspo2Tg/Tg;Lrp6+/- and
Rspo2+/Tg;Lrp6-/- mice
(Fig. 4C,E).
Rspo2Tg/Tg;Lrp6-/- fetuses lacked all forelimb
skeletal elements and had scapular malformations
(Fig. 4F).
Severe malformations of the hindlimb, including loss of the autopod and
fibula were observed in Rspo2Tg/Tg fetuses
(Fig. 4G)
(Bell et al., 2003a).
Similarly, Lrp6 homozygotes lacked the autopod and fibula (100%
penetrant) and possessed malformations of the tibia (52%) and femur (24%)
(Fig. 4H)
(Pinson et al., 2000).
Rspo2Tg/Tg;Lrp6+/- mice exhibited a higher
incidence of tibia and femur defects (Fig.
4I). Reciprocally,
Rspo2+/Tg;Lrp6-/- fetuses consistently lacked
both autopods and all or most of the tibia and fibula. Additionally, an
increase in the severity of femur and pelvic girdle malformations was observed
(compare Fig. 4K with
4H). No hindlimb structures and
only rudiments of the pelvic girdle were observed in
Rspo2Tg/Tg;Lrp6-/- progeny
(Fig. 4L). A few
Rspo2+/Tg;Lrp6+/- fetuses lacked digits
(Fig. 4J).
Rspo2 and Lrp6 influence laryngeal-tracheal morphogenesis
Malformations in laryngeal and tracheal cartilages of E18
Rspo2Tg/Tg fetuses were observed and exacerbated by the
progressive loss of Lrp6 alleles. The laryngeal region consists of
the hyoid bone and thyroid, arytenoid and cricoid cartilages. In
Rspo2+/+ or +/Tg animals, regardless
of Lrp6 genotype, the arytenoid cartilages floated freely above the
cricoid cartilage. These cartilages were usually fused to the top of the
cricoid in Rspo2Tg/Tg;Lrp6+/+ and
Rspo2Tg/Tg;Lrp6+/- fetuses
(Fig. 5B-D; see Table S2 in the
supplementary material). The cricoid normally forms a thickened ring with a
dorsal region of cartilage that extends caudally. The cricoid ring was not
formed in Rspo2Tg/Tg fetuses and the dorsal aspect of the
cricoid was absent (Fig. 5A-C).
In Rspo2+/+;Lrp6+/+and
Rspo2+/Tg;Lrp6+/+ progeny, 12-15 tracheal rings
were evenly spaced with one or two bifurcated rings. Defects in cartilage ring
formation varied from normal to bifurcated or consisted of abnormal
cartilaginous nodules within the trachea and mainstem bronchi in
Rspo2Tg/Tg;Lrp6+/+ and
Rspo2Tg/Tg;Lrp6+/- mice
(Fig. 5B,C). A severe phenotype
was observed in Rspo2Tg/Tg;Lrp6-/- fetuses;
only rudiments of the thyroid cartilage were present and tracheal rings were
absent (Fig. 5D). Laryngeal and
tracheal cartilages were normal in
Rspo2+/+;Lrp6-/- and
Rspo2+/Tg;Lrp6-/- fetuses
(Fig. 5E). Supporting the
hypothesis that Rspo2 signals to the airway epithelium and acts through the
canonical Wnt signaling pathway, tracheal ring defects were observed in
doxycycline-exposed
Tg(SFPTC-rtTA)5Jaw+;Tg(TetO7-CMVcre)+;β-cateninflox/flox
mice (Mucenski et al., 2003)
in which β-catenin was conditionally deleted from the embryonic
airway epithelium (Fig. 5F, see
Table S3 in the supplementary material).
|
50% or more
reduction in normalized lung weight was observed in
Rspo2Tg/Tg;Lrp6+/+,
Rspo2Tg/Tg;Lrp6+/-,
Rspo2Tg/Tg;Lrp6-/- and
Rspo2+/Tg;Lrp6-/- fetuses, all statistically
significant at P<0.05. Although the right lung lobes of
Rspo2Tg/Tg mice were frequently fused proximally, the
overall lung structure and was not substantially altered. Immunohistochemical
staining for specific cell types using antibodies to pro-surfactant protein C
(type II epithelial cells), FoxJ1 (ciliated epithelial cells), Pecam1
(vascular endothelial cells), T1-alpha (type I epithelial cells), alpha-smooth
muscle actin (smooth muscle cells) and Clara cell secretory protein
(nonciliated bronchiolar cells) indicated that the expected differentiation of
the various pulmonary cell types had occurred in lungs of all genotypes
(Fig. 5G-N; see Fig. S2 in the
supplementary material, data not shown). Thus, the hypoplasia observed in
Rspo2Tg/Tg;Lrp6+/+ and
Rspo2Tg/Tg;Lrp6-/- animals did not correlate
with the absence of a specific population of differentiated cells in the E18.5
lung.
|
212-243AP, and terminal epithelial tips were counted after 3 days
in organ culture. Confirming a defect in branching morphogenesis, the
branching of Rspo2Tg/Tg lung buds in AP medium was
significantly reduced compared with controls, P<0.001 by
two-tailed Student's t-test (compare
Fig. 6A with
6C). This defect was
substantially rescued by culturing Rspo2Tg/Tg lung buds in
media containing Rspo2 212-243AP, P<0.001
(Fig. 6A,B). Within individual
experiments, similar levels of branching were observed in
Rspo2+/+ and Rspo2+/Tg lung buds
exposed to Rspo2 212-243AP or AP
(Fig. 6C,D).
To determine whether Rspo2 deficiency influenced canonical Wnt
signaling during embryogenesis, the TOPGAL reporter transgene
(DasGupta and Fuchs, 1999) was
mated into the Rspo2Tg line. In E11.5
Rspo2Tg/Tg;TOPGAL+/- lung buds, the normal
pattern of TOPGAL activity was disrupted; staining was decreased at the distal
tips of the branching epithelium (compare
Fig. 7A with
7B,C,E). A statistically
significant difference in the amount of TOPGAL signaling was found by assaying
protein concentration and β-galactosidase activity in individual E11.5
wild-type and Rspo2Tg/Tg lung buds (P<0.00002
by two-tailed Student's t-test of unequal variance)
(Fig. 7D). Real-time RT-PCR of
E11.5 lung cDNA samples evaluated the expression of the Wnt downstream target
genes Lef1 and Irx3
(Braun et al., 2003;
Hovanes et al., 2001), both
expressed by the lung epithelium (De
Langhe et al., 2005; Houweling
et al., 2001). Fgf10 expression was also examined owing
to its known role in branching morphogenesis
(Bellusci et al., 1997).
Irx3 expression was decreased threefold in
Rspo2Tg/Tg lung buds, consistent with its proposed role in
branching morphogenesis (van Tuyl et al.,
2006) (Fig. 7F).
Lef1 and Fgf10 expression varied between the two
Rspo2Tg/Tg samples but were decreased less than 1.5-fold.
These observations are consistent with the concept that Rspo2 is involved in
activation of canonical Wnt signaling in the embryonic lung.
|
|
DISCUSSION |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
In vitro evidence indicates that Rspo binding to Lrp6 activates canonical
Wnt signaling. In the present studies, Rspo2 increased TOPFLASH activity in
response to increasing levels of cellular Lrp6, consistent with previous
studies (Kazanskaya et al.,
2004; Nam et al.,
2006). Rspo1 and Rspo3 have been co-immunoprecipitated with the
extracellular domain of Lrp6 (Nam et al.,
2006; Wei et al.,
2007). Herein, we observed that the second Lrp6 EGF-like repeat
was required for Rspo2 activation of canonical Wnt signaling, whereas some
signaling was retained in the absence of EGF-like repeats 3 and 4. Prior
studies using human Lrp6 constructs demonstrated that EGF-like domains 1 and 2
were required for binding to Wnts and Wise
(Itasaki et al., 2003;
Mao et al., 2001). As the
cellular response to Wnts is increased in the presence of Rspo2, it is unclear
whether Rspo2 competes with Wnts for binding to the EGF 1 and 2 domains on the
same Lrp6 molecule or whether a Wnt ligand binds to one EGF domain and Rspo2
to the other to activate signaling. The higher affinity of Rspo proteins for
Lrp6, when compared with frizzled proteins, may indicate that they bind in a
larger complex, with Lrp6-Rspo2 interacting with a Wnt-frizzled
(Wei et al., 2007).
Alternatively, the effects of ligand binding to frizzled or Lrp6 receptors may
activate shared downstream targets independently.
|
|
).
By contrast, the progressive loss of distal limb structures in
Rspo2Tg/Tg;Lrp6+/+ and
Rspo2Tg/Tg;Lrp6+/- or
Rspo2+/+;Lrp6-/- and
Rspo2+/Tg;Lrp6-/- is probably related to the
progressive loss of AER. Both Lrp6 and Rspo2 mutants are known to affect AER
morphogenesis (Bell et al.,
2003a; Pinson et al.,
2000) and the AER is required for outgrowth of the underlying
mesenchyme. The importance of Rspo2 for normal AER morphogenesis is supported
by the observations that Rspo2 expression increased as the AER
matured and that it was dramatically decreased in Sp8-/-
limb buds that fail to form an AER (Bell et
al., 2003b). The highest levels of canonical Wnt signaling
colocalize in the pre and mature AER cells where Rspo2 is expressed
(Barrow et al., 2003;
Maretto et al., 2003).
Notably, Wnt3 and Lrp6 both are expressed throughout the
limb ectoderm and, together with β-catenin, are required for normal AER
morphogenesis (Barrow et al.,
2003; Pinson et al.,
2000). We propose a model in which Rspo2 in the AER enhances
canonical Wnt signaling to a level necessary for normal limb morphogenesis.
This process is tightly regulated as the AER simultaneously expresses the Wnt
signaling antagonist Dickkopf 1 (Dkk1)
(Mukhopadhyay et al., 2001).
An overactive AER is present in Dkk1 mutants, resulting in limbs with
extra digits. Notably, in the absence of Dkk1, reduction of either
Lrp5 or Lrp6 expression lowers the incidence of limb
malformations (MacDonald et al.,
2004).
The morphogenetic defects present in Rspo2Tg/Tg
included severe malformations of the larynx, trachea, bronchi and lung. At
E18.5, Rspo2Tg/Tg fetal lungs were approximately half the
size of littermate lungs but generally retained normal structure and
cephalo-caudal patterning of differentiated cell types. Laryngeal and
tracheal-bronchial ring abnormalities were observed in all
Rspo2Tg/Tg fetuses and included malformation of the
cricoid ring and arytenoids within the larynx, and absent or malformed
cartilage rings in the trachea and bronchi. Lrp6 heterozygosity did
not increase the severity of these Rspo2Tg/Tg
malformations, suggesting that other Rspos or Wnts can compensate in the
absence of Rspo2. The lack of tracheal and laryngeal defects in
Rspo2+/+;Lrp6-/- and
Rspo2+/Tg;Lrp6-/- fetuses suggests that in the
absence of Lrp6, Rspo2 may signal through Lrp5. Like Lrp6, Lrp5 can mediate
canonical Wnt signaling but, surprisingly, loss of Lrp5 is compatible with
life (Holmen et al., 2004;
Mikels and Nusse, 2006). The
dramatic effect of the Rspo2 mutation on lung growth and
laryngeal-tracheal-bronchial morphogenesis observed in
Rspo2Tg/Tg;Lrp6-/- mice indicates a critical
requirement for early Lrp6-mediated Rspo2 signaling. The finding that deletion
of β-catenin from the embryonic respiratory epithelium also resulted in
tracheal ring malformations supports a role of Rspo2-mediated activation of
the canonical Wnt signaling pathway in tracheal cartilage morphogenesis.
During early lung formation, canonical Wnt signaling is highest in the
distal lung epithelium and immediately adjacent mesenchyme
(De Langhe et al., 2005). At
E11.5, a reduction in expression of the Wnt signaling reporter TOPGAL was
observed in distal epithelial tips of Rspo2Tg/Tg lung buds
with a defect in epithelial branching. As Rspo2 is expressed in the
distal tip mesenchyme, we propose that paracrine Rspo2 signaling occurs in the
lung. In support of this concept, the highest levels of Lrp6 and
Lrp5 expression are observed in the respiratory epithelium that also
expresses Wnt7b, Wnt5a, Wnt11, Fzd8 and Fzd10
(De Langhe et al., 2005;
Li et al., 2002). Wnt2a,
Wnt5a, Wnt11, Fzd1, Fzd4 and Fzd7 are expressed in the lung
mesenchyme (Li et al., 2002;
Wang et al., 2005;
Weidenfeld et al., 2002). In
vitro studies demonstrated R-spondin activation of the canonical Wnt pathway
through interactions with Lrp6 and Fzd1, Fzd4, Fzd5 and Fzd8, as well as
potentiation of Wnt1 and Wnt3a signaling
(Kazanskaya et al., 2004;
Nam et al., 2006;
Wei et al., 2007;
Weidenfeld et al., 2002).
Whether Rspo2 acts independently or potentiates the canonical signaling
activity of Wnt7b, Wnt5a, Wnt2 or Wnt11 in the lung remains to be determined
(Mikels and Nusse, 2006).
Wnt7b signaling is thought to be dependent on interactions with Lrp5, Fzd1 and
Fzd10 (Wang et al., 2005). The
early branching defects and lung hypoplasia observed in
Rspo2Tg/Tg embryos, were similar to those observed in
Wnt7b mutants. However, epithelial cell differentiation proceeded
normally in Rspo2Tg/Tg mice, whereas
Wnt7b-/- mice exhibited a deficiency in type I cell
differentiation (Shu et al.,
2002).
The distinct combination of tracheal malformations and lung hypoplasia
observed in Rspo2Tg/Tg mice is reminiscent of other
genetic mutations. Retinoic acid receptor (Rar)
-/-β2-/- animals exhibit
lung hypoplasia attributable to a delay in branching morphogenesis that was
detectable as early as E11.5 (Mendelsohn
et al., 1994). Laryngeal and tracheal defects in
Rar-/-Rarβ2-/-
fetuses also included failure of the cricoid to fuse dorsally, fusion of the
arytenoids to the cricoid, and abnormally shaped cartilage rings. By contrast,
the foreshortening of the trachea seen in
Rar-/-Rarβ2-/-
was not observed in Rspo2Tg/Tg mice. Abnormally formed
tracheal-bronchial rings were also observed after conditional deletion of
Shh in the respiratory epithelium
(Miller et al., 2004). By
contrast, the tracheal cartilage abnormalities found in Wnt5a and TNF
receptor-associated factor 4 (Traf4)-null mice are distinct. In
Wnt5a-/- mice, tracheal length was shorter but the
tracheal rings were normal (Li et al.,
2002). The upper three to six cartilage rings below the cricoid
were consistently either frontally disrupted or fused in
Traf4-/- fetuses
(Regnier et al., 2002;
Shiels et al., 2000). The role
of Rspo2 in this developmental process is currently unclear.
In summary, the footless insertional mutation disrupts the
Rspo2 gene, causing severe malformations in the lung, larynx,
trachea, bronchi, limb and palate. The restricted sites of Rspo2
expression correlated with the sites of malformation. The effects of the
Rspo2 mutation on morphogenesis is distinct from those associated
with mutations of other R-spondin family members. Deletion of Rspo3
resulted in embryo lethality at E10 that was attributed to impaired
placentation (Aoki et al.,
2007). RSPO1 mutations were associated with XX sex
reversal, palmoplantar hyperkeratosis and a predisposition to squamous cell
carcinoma (Parma et al.,
2006). RSPO4 mutations result in anonychia
(Blaydon et al., 2006),
consistent with the finding that Rspo4 is selectively expressed in
the nail bed. The present studies indicate that Rspo2 and Lrp6 interact to
activate canonical Wnt signaling affecting limb and laryngeal-tracheal
cartilages, and lung morphogenesis.
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/135/6/1049/DC1
|
ACKNOWLEDGMENTS |
|---|
|
REFERENCES |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
Aoki, M., Mieda, M., Ikeda, T., Hamada, Y., Nakamura, H. and
Okamoto, H. (2007). R-spondin3 is required for mouse
placental development. Dev. Biol.
301,218
-226.[CrossRef][Medline]
Barrow, J. R., Thomas, K. R., Boussadia-Zahui, O., Moore, R.,
Kemler, R., Capecchi, M. R. and McMahon, A. P. (2003).
Ectodermal Wnt3/β-catenin signaling is required for the establishment of
the apical ectodermal ridge. Genes Dev.
17,394
-409.
Bell, S. M., Schreiner, C. M., Hess, K. A., Anderson, K. P. and
Scott, W. J. (2003a). Asymmetric limb malformations in a new
transgene insertional mutant, footless. Mech.
Dev. 120,597
-605.[CrossRef][Medline]
Bell, S. M., Schreiner, C. M., Waclaw, R. R., Campbell, K.,
Potter, S. S. and Scott, W. J., Jr (2003b). Sp8 is
crucial for limb outgrowth and neuropore closure. Proc. Natl. Acad.
Sci. USA 100,12195
-12200.
Bell, S. M., Schreiner, C. M., Goetz, J. A., Robbins, D. J. and
Scott, W. J. J. (2005). Shh signaling in limb bud ectoderm:
Potential role in teratogen-induced postaxial ectrodactyly. Dev.
Dyn. 233,313
-325.[CrossRef][Medline]
Bellusci, S., Grindley, J., Emoto, H., Itoh, N. and Hogan, B.
L. (1997). Fibroblast growth factor 10 (FGF10) and branching
morphogenesis in the embryonic mouse lung. Development
124,4867
-4878.[Abstract]
Blaydon, D. C., Ishii, Y., O'Toole, E. A., Unsworth, H. C., Teh,
M.-T., Ruschendorf, F., Sinclair, C., Hopsu-Havu, V. K., Tidman, N., Moss, C.
et al. (2006). The gene encoding R-spondin 4
(RSPO4), a secreted protein implicated in Wnt signaling, is mutated
in inherited anonychia. Nat. Genet.
38,1245
-1247.[CrossRef][Medline]
Braun, M. M., Etheridge, A., Bernard, A., Robertson, C. P. and
Roelink, H. (2003). Wnt signaling is required at distinct
stages of development for the induction of the posterior forebrain.
Development 130,5579
-5587.
DasGupta, R. and Fuchs, E. (1999). Multiple
roles for activated LEF/TCF transcription complexes during hair follicle
development and differentiation. Development
126,4557
-4568.[Abstract]
De Langhe, S. P., Sala, F. G., Del Moral, P. M., Fairbanks, T.
J., Yamada, K. M., Warburton, D., Burns, R. C. and Bellusci, S.
(2005). Dicckopf-1 (Dkk1) reveals that fibronectin is a major
target of Wnt signaling in branching morphogenesis of the mouse embryonic
lung. Dev. Biol. 277,316
-331.[CrossRef][Medline]
Feinstein, Y., Borrell, V., Garcia, C., Burstyn-Cohen, T.,
Tzarfaty, V., Frumkin, A., Nose, A., Okamoto, H., Higashijima, S., Soriano, E.
et al. (1999). F-spondin and mindin: two structurally and
functionally related genes expressed in the hippocampus that promote outgrowth
of embryonic hippocampal neurons. Development
16,3637
-3648.
Galceran, J., Farinas, I., Depew, M. J., Clevers, H. and
Grosschedl, R. (1999). Wnt3a-/- -like
phenotype and limb deficiency in
Lef1-/-Tcf1-/- mice. Genes
Dev. 13,709
-717.
Holmen, S. L., Giambernardi, T. A., Zylstra, C. R.,
Buckner-Berghuis, B. D., Resau, J. H., Hess, J. F., Glatt, V., Bouxsein, M.
L., Ai, M., Warman, M. L. et al. (2004). Decreased BMD and
limb deformities in mice carrying mutations in both Lrp5 and
Lrp6. J. Bone Miner. Res.
19,2033
-2040.[CrossRef][Medline]
Houck, K. A., Leung, D. W., Rowland, A. M., Winer, J. and
Ferrara, N. (1992). Dual regulation of vascular endothelial
growth factor bio-availability by genetic and proteolytic mechanisms.
J. Biol. Chem. 267,26031
-26037.
Houweling, A. C., Dildrop, R., Peters, T., Mummenhoff, J.,
Moorman, A. F., Ruther, U. and Christoffels, V. M. (2001).
Gene and cluster specific expression of the Iroquois family members during
mouse development. Mech. Dev.
107,169
-174.[CrossRef][Medline]
Hovanes, K., Li, T. W., Munguia, J. E., Truong, T., Milovanovic,
T., Marsh, J. L., Holcombe, R. F. and Waterman, M. L. (2001).
Beta-catenin-sensitive isoforms of lymphoid enhancer factor-1 are selectively
expressed in colon cancer. Nat. Genet.
28, 53-57.[CrossRef][Medline]
Itasaki, N., Jones, M., Mercurio, S., Rowe, A., Domingos, P. M.,
Smith, J. C. and Krumlauf, R. (2003). Wise, a
context-dependent activator and inhibitor of Wnt signaling.
Development 130,4295
-4305.
Kawakami, Y., Esteban, C. R., Matsui, T., Rodriguez-Leon, J.,
Kato, S. and Izpisua Belmonte, J. C. (2004). Sp8 and
Sp9, two closely related buttonhead-like transcription factors,
regulate Fgf8 expression and limb outgrowth in vertebrate embryos.
Development 131,4763
-4774.
Kazanskaya, O., Glinka, A., del Barco Barrantes, I., Stannek,
P., Niehrs, C. and Wu, W. (2004). R-spondin2 is a secreted
activator of Wnt/β-catenin signaling and is required for Xenopus
myogenesis. Dev. Cell 7,525
-534.[CrossRef][Medline]
Kilpelainen, I., Kaksonen, M., Kinnunen, T., Avikainen, H.,
Fath, M., Linhardt, R. J., Raulo, E. and Rauvala, H. (2000).
Heparin-binding growth associated molecule contains two heparin-binding
β-sheet domains that are homologous to the thrombospondin type I repeat.
J. Biol. Chem. 275,13564
-13570.
LaRochelle, W. J., May-Siroff, M., Robbins, K. C. and Aaronson,
S. A. (1991). A novel mechanism regulating growth factor
association with the cell surface: identification of a PDGF retention domain.
Genes Dev. 5,1191
-1199.
Li, C., Xiao, J., Hormi, K., Borok, Z. and Minoo, P.
(2002). Wnt5a participates in distal lung morphogenesis.
Dev. Biol. 248,68
-81.[CrossRef][Medline]
Logan, C. Y. and Nusse, R. A. (2004). The Wnt
signaling pathway in development and disease. Annu. Rev. Cell Dev.
Biol. 20,781
-810.[CrossRef][Medline]
Lowther, W., Wiley, K., Smith, G. H. and Callahan, R.
(2005). A new common integration site, Int7, for Mouse Mammary
Tumor virus in mouse mammary tumors identifies a gene whose product has
furin-like and thrombospondin-like sequences. J.
Virol. 79,10093
-10096.
MacDonald, B. T., Adamska, M. and Meisler, M. H.
(2004). Hypomorphic expression of Dkk1 in the
doubleridge mouse: dose dependence and compensatory interactions with
Lrp6. Development
131,2543
-2552.
Mao, B., Wu, W., Li, Y., Hoppe, D., Stannek, P., Glinka, A. and
Niehrs, C. (2001). LDL-receptor-related protein 6 is a
receptor for Dickkopf proteins. Nature
411,321
-325.[CrossRef][Medline]
Maretto, S., Cordenonsi, M., Dupont, S., Braghetta, P.,
Broccoli, V., Hassan, B. A., Volpin, D., Bressan, G. M. and Piccolo, S.
(2003). Mapping Wnt/β-catenin signaling during mouse
development and in colorectal tumors. Proc. Natl. Acad. Sci.
USA 100,3299
-3304.
Mendelsohn, C., Lohnes, D., Decimo, D., Lufkin, T., LeMeur, M.,
Chambon, P. and Mark, M. (1994). Function of the retinoic
acid receptors (RARs) during development. Development
120,2749
-2771.[Abstract]
Mikels, A. J. and Nusse, R. (2006). Purified
Wnt5a protein activates or inhibits β-catenin-TCF signaling depending on
receptor context. PLOS Biol.
4, e115.[CrossRef][Medline]
Miller, L. D., Wert, S. E., Clark, J. C., Xu, Y., Perl, A.-K. T.
and Whitsett, J. A. (2004). Role of Sonic hedgehog
in patterning of tracheal-bronchial cartilage and the peripheral lung.
Dev. Dyn. 231,57
-71.[CrossRef][Medline]
Mucenski, M. L., Wert, S. E., Nation, J. M., Loudy, D. E.,
Huelsken, J., Birchmeier, W., Morrisey, E. E. and Whitsett, J. A.
(2003). Beta-catenin is required for specification of
proximal/distal cell fate during lung morphogenesis. J. Biol.
Chem. 278,40231
-40238.
Mukhopadhyay, M., Shtrom, S., Rodriguez-Esteban, C., Chen, L.,
Tsuki, T., Gomer, L., Dorard, D. W., Glinka, A., Grinberg, A., Huang, S. P. et
al. (2001). Dickkopf1 is required for embryonic head
induction and limb morphogenesis in the mouse. Dev.
Cell 1,423
-434.[CrossRef][Medline]
Nam, J.-S., Turcotte, T. J., Smith, P. F., Choi, S. and Yoon, J.
K. (2006). Mouse Cristin/R-spondin family proteins are novel
ligands for the Frizzled8 and Lrp6 receptors and activate
β-catenin-dependent gene expression. J. Biol.
Chem. 281,13247
-13257.
Nam, J.-S., Turcotte, T. J. and Yoon, J. K.
(2007a). Dynamic expression of R-spondin family genes in mouse
development. Gene Expr. Patterns
3, 306-312.
Nam, J. S., Park, E., Turcotte, T. J., Palencia, S., Zhan, X.,
Lee, J., Yun, K., Funk, W. D. and Yoon, J. K. (2007b). Mouse
R-spondin2 is required for apical ectodermal ridge maintenance in the
hindlimb. Dev. Biol.
311,124
-135.[CrossRef][Medline]
Parma, P., Radi, O., Vidal, V., Chaboissier, M. C., Dellambra,
E., Valentini, S., Guerra, L., Schedl, A. and Camerino, G.
(2006). R-spondin1 is essential in sex determination, skin
differentiation and malignancy. Nat. Genet.
38,1304
-1309.[CrossRef][Medline]
Pinson, K. I., Brennan, J., Monkley, S., Avery, B. J. and
Skarnes, W. C. (2000). An LDL-receptor-related protein
mediates Wnt signalling in mice. Nature
407,535
-538.[CrossRef][Medline]
Regnier, C. H., Masson, R., Kedinger, V., Textoris, J., Stoll,
I., Chenard, M.-P., Dierich, A., Tomasetto, C. and TRio, M.-C.
(2002). Impaired neural tube closure, axial skeleton
malformations, and tracheal ring disruption in TRAF4-deficient mice.
Proc. Natl. Acad. Sci. USA
99,5585
-5590.
Shiels, H., Li, X., Schumacker, P. T., Maltepe, E., Padrid, P.
A., Sperling, A., Thompson, C. B. and Lindsten, T. (2000).
Traf4 deficiency leads to tracheal malformation with resulting alterations in
air flow to the lungs. Am. J. Pathol.
157,679
-688.
Shu, W., Jiang, Y. Q., Lu, M. M. and Morrisey, E. E.
(2002). Wnt7b regulates mesenchymal proliferation and vascular
development in the lung. Development
129,4831
-4842.[Medline]
Sun, X., Mariani, F. V. and Martin, G. R.
(2002). Functions of FGF signaling from the apical ectodermal
ridge in limb development. Nature
418,502
-508.
Tebar, M., Destree, O., deVree, W. J. A. and Ten Have-Opbrock,
A. A. W. (2001). Expression of Tcf/Lef and sFrp and
localization of β-catenin in the developing mouse lung. Mech.
Dev. 109,437
-440.[CrossRef][Medline]
Tzarfaty-Majar, V., López-Alemany, R., Feinstein, Y.,
Gombau, L., Goldshmidt, O., Soriano, E., Muñoz-Cánoves, P. and
Klar, A. (2001). Plasmin-mediated release of the guidance
molecule F-spondin from the extracellular matrix. J. Biol.
Chem. 276,28233
-28241.
van Tuyl, M., Liu, J., Groenman, F., Ridsdale, R., Han, R. N.
N., Venkatesh, V., Tibboel, D. and Post, M. (2006). Iroquois
genes influence proximo-distal morphogenesis during rat lung development.
Am. J. Physiol. Lung Cell Mol. Physiol.
290,L777
-L789.
Wang, Z., Shu, W., Lu, M. M. and Morrisey, E. E.
(2005). Wnt 7b activates canonical signaling in epithelial and
vascular smooth muscle cells through interactions with Fzd1, Fzd10, and Lrp5.
Mol. Cell. Biol. 25,5022
-5030.
Wei, Q., Yokota, C., Semenov, M. V., Doble, B., Woodgett, J. and
He, X. (2007). R-spondin 1 is a high affinity ligand for LRP6
and induces LRP6 phosphorylation and β-catenin signaling. J.
Biol. Chem. 282,15903
-15911.
Weidenfeld, J., Shu, W., Zhang, L., Millar, S. E. and Morrisey,
E. E. (2002). The Wnt7b promoter is regulated by TTF-1,
GATA6, and Foxa2 in lung epithelium. J. Biol. Chem.
277,21061
-21070.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati 
Twitter What's this?
This article has been cited by other articles:
|
|
 |
|
  C. L. Marcus, R. J. H. Smith, L. A. Mankarious, R. Arens, G. S. Mitchell, R. G. Elluru, V. Forte, S. Goudy, E. W. Jabs, A. A. Kane, et al. Developmental Aspects of the Upper Airway: Report from an NHLBI Workshop, March 5-6, 2009 Proceedings of the ATS, September 15, 2009; 6(6): 513 - 520. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 M. S. Friedman, S. M. Oyserman, and K. D. Hankenson Wnt11 Promotes Osteoblast Maturation and Mineralization through R-spondin 2 J. Biol. Chem., May 22, 2009; 284(21): 14117 - 14125. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 O. Kazanskaya, B. Ohkawara, M. Heroult, W. Wu, N. Maltry, H. G. Augustin, and C. Niehrs The Wnt signaling regulator R-spondin 3 promotes angioblast and vascular development Development, November 15, 2008; 135(22): 3655 - 3664. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
H. Wan, F. Luo, S. E. Wert, L. Zhang, Y. Xu, M. Ikegami, Y. Maeda, S. M. Bell, and J. A. Whitsett Kruppel-like factor 5 is required for perinatal lung morphogenesis and function Development, August 1, 2008; 135(15): 2563 - 2572. [Abstract] [Full Text] [PDF]
|
|
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
