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First published online 3 January 2007
doi: 10.1242/dev.02736
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1 Center for Animal Resources and Development (CARD), Graduate School of Medical
and Pharmaceutical Sciences, Kumamoto University, Honjo 2-2-1, Kumamoto
860-0811, Japan.
2 Molecular Neuropathology Group, Brain Research Institute, RIKEN, Wako,
Saitama, Japan.
3 RIKEN Center for Developmental Biology, Chuo-ku, Kobe 650-0047, Japan.
4 Department of Pediatrics and Program in Human Molecular Biology and Genetics,
University of Utah, UT 84112, USA.
* Author for correspondence (e-mail: gen{at}kaiju.medic.kumamoto-u.ac.jp)
Accepted 13 November 2006
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DISCUSSION
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Key words: Urinary bladder, External genitalia, Cloaca, Internal urethra, Pelvic urethra, Shh (sonic hedgehog), Gli, PCM (peri-cloacal mesenchyme), Smooth muscle, Exstrophy, Mouse
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;
Kimmel et al., 2000;
Kondo et al., 1996;
Penington and Hutson, 2003;
Yamada et al., 2003;
Yamada et al., 2006). It has
been suggested that the cloaca/urogenital sinus and adjacent tissues
differentiate into the urogenital and reproductive organs, including the
urinary bladder (hereafter described as the bladder) in both sexes. This is
supported by reports of complex congenital malformations such as:
exstrophy-epispadias complex (exstrophy of cloaca or bladder and abnormal
dorsal external genitalia; hereafter, dorsal external genitalia represents
upper external genitalia); defective body wall, bladder and genitalia
formation; and limb body wall defects that are probably caused by
abnormalities in early development of the cloaca and urogenital sinus
(Craven et al., 1997;
Manner and Kluth, 2005;
Penington and Hutson, 2003).
The constellation of defects reported in affected individuals suggests that
coordinated developmental programs regulate bladder and external genital
morphogenesis. However, the signaling and structural contributions of the
transient embryonic cloaca to formation of multiple urogenital and
reproductive organs inside and outside the pelvic cavity remain obscure.
The phenotypes of gene knockout mice have revealed that several growth and
signaling factor families play fundamental roles in reproductive and
urogenital organ formation (Batourina et
al., 2002; Doles et al.,
2006; Haraguchi et al.,
2001; Haraguchi et al.,
2000; Huang et al.,
2005; Jamin et al.,
2002; Kobayashi and Behringer,
2003; Kondo et al.,
1996; McMahon et al.,
2003; Morgan et al.,
2003; Perriton et al.,
2002; Suzuki et al.,
2003). Shh is expressed in the cloacal epithelia and is
vital for the regulation of structures derived from the genital tubercle (GT)
and the urogenital sinus, such as the external genitalia and the prostate,
respectively (de Santa Barbara and
Roberts, 2002; Freestone et
al., 2003; Pu et al.,
2004). Shh null mouse embryos display GT agenesis
associated with aberrant cloacal formation, suggesting that Shh signals
emanating from the epithelium of the cloaca may play an essential role in
peri-cloacal mesenchyme (PCM) development
(Haraguchi et al., 2001;
Perriton et al., 2002).
In this manuscript, we report our studies investigating the role of the hedgehog (HH) signaling pathway and of HH-responsive tissues in urogenital development. We analyzed the expression of members of the HH signaling pathway in structures developing from the cloacal region, including the GT, internal urethra (pelvic urethra), lower body wall and bladder. We performed phenotype analyses of Shh and Gli mutants, and employed HH-responsive transgenic marker alleles in mice to examine the lineage of these HH-responding tissues with regard to the reproductive and urogenital organs. In addition to the cloacal epithelium, Shh is expressed in the developing urethral plate (UP), internal urethra and epithelia lining the bladder. Shh and Gli mutant mice displayed hypoplasia and defects of the UP, internal urethra and bladder wall. We discovered that HH-responsive PCM contributes to both the dorsal GT and to mesenchymal precursors of bladder smooth muscle. These analyses demonstrate that coordinated formation of the bladder, internal urethra and external genitalia is orchestrated by HH signaling.
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; Ding et al.,
1998; Hui and Joyner,
1993; Motoyama et al.,
1998; Park et al.,
2000), as was the Gli1-CreERT2 mouse line
(Ahn and Joyner, 2004;
Ahn and Joyner, 2005). The
Del5-LacZ reporter transgenic construct included an HH-responding
regulatory element (Sasaki et al.,
1997) consisting of eight synthetic `del-5' sequences that each
contain a Gli-binding site (TTATGA CGGAGG CTAACA AGCAGG GAACAC CCAAGT AGAAGC
TGGCTG TC). This element was cloned adjacent to the basal gamma-crystalline
promoter and inserted 5' to the ß-galactosidase coding sequence
(Sasaki et al., 1997) (see
Fig. 5A). This construct (total
length 5.2 kb) was microinjected into fertilized C57BL/6 oocytes to generate
transgenic animals using standard procedures
(Sasaki and Hogan, 1996). For
sampling, pregnant females were sacrificed from embryonic day (E) 10.5 to
newborn, and the urogenital and reproductive tissues were examined
(Haraguchi et al., 2000).
Histology
Mouse embryos were fixed overnight in 4% paraformaldehyde (PFA) or PBS,
dehydrated through methanol, embedded in paraffin, and 8 µm serial sections
were prepared. Hematoxylin and Eosin (HE) staining were processed by standard
procedures (Haraguchi et al.,
2000).
Immunohistochemistry and X-Gal staining
Immunohistochemical analysis was performed by standard procedures using the
following antibodies: anti-AR (Androgen receptor) Ab (1:100; Santa Cruz, N-20)
or anti-SMM (smooth muscle myosin) Ab (1:200; Biomedical Technology BF-562).
ß-Galactosidase activity was detected with previously described methods
(Suzuki et al., 2003).
X-Gal-stained embryos were postfixed with 4% PFA at 4°C overnight,
embedded in paraffin, and 8 mm serial sections were counterstained with Eosin.
Newborn animals were fixed in 0.2% PFA in the buffer (1 mmol/l
MgCl2, 0.02% NP40 in PBS [pH 7.4]) at 4°C overnight, embedded
in OCT, and frozen sections were prepared using a cryostat at a thickness of
10 µm. The sections were then postfixed in 0.2% PFA in the buffer at room
temperature for 10 minutes before X-Gal staining.
In situ hybridizations for gene expression analyses
Section in situ hybridizations for gene expression analyses were performed
as previously described (Suzuki et al.,
2000). The antisense riboprobe templates for Ptc1
(Ptch1 - Mouse Genome Informatics), Gli1 and Shh
were as described by previous authors
(Ding et al., 1998;
Haraguchi et al., 2001;
Motoyama et al., 1998).
Lineage analysis of HH-responding tissues
Tissue lineage analyses were conducted by analyzing
Gli1-CreERT2;R26R mice
(Ahn and Joyner, 2004;
Ahn and Joyner, 2005). The
Gli1-CreERT2 mice were crossed with R26R-LacZ
indicator mice (Soriano, 1999)
to obtain Gli1-CreERT2/+;R26R/R26R males, which were
subsequently crossed with ICR females. Noon of the day of a vaginal plug was
designated as E0.5. A 20 mg/ml stock solution of tamoxifen (T-5648, Sigma) was
prepared in corn oil. Two milligrams of tamoxifen per 40 g body weight was
administered to the pregnant ICR mouse females using oral gavage at
E8.75
9.0 to label the PCM region. Mouse embryos and newborn animals were
processed for whole-mount or section X-gal staining. No overt teratologic
effects were observed after tamoxifen administration at E9.0 of pregnancy
under these conditions (data not shown). We monitored the post-pubescent
reproductive activity of some animals exposed to tamoxifen as embryos by the
current conditions and found that they had normal reproductive activity (data
not shown).
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). From
E11.5 to E13.5, the Shh expression domain expanded further and
included the developing urethral plate and the epithelia lining the internal
urethra and bladder (Fig. 2B,C;
note continuity of Shh expression in these three epithelial structures).
Widespread Ptc1 and Gli1 expression were detected in the
mesenchyme adjacent to these epithelia
(Fig. 2E,F,H,I).
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;
Ding et al., 1998;
Haraguchi et al., 2001;
Hardcastle et al., 1998;
Hui and Joyner, 1993;
Matise and Joyner, 1999;
Mo et al., 1997;
Motoyama et al., 1998). During
urogenital tissue formation (E10.5-13.5), Gli2 and Gli3
expression was detected in the GT and bladder mesenchyme
(Haraguchi et al., 2001) (R.H.
and G.Y., unpublished). To confirm a role for HH signaling in urogenital
tissue development, we examined these structures in Gli1, Gli2 and
Gli1;Gli2 compound mutants (Fig.
4). Gli2-/- mutants have hypoplasia of the
external genitalia, internal urethra and bladder
(Fig. 4B). Although
Gli1-/- mutant mice were phenotypically normal (data not
shown), additional loss of function of a single allele of Gli2 in a
Gli1 homozygous mutant
(Gli1-/-;Gli2+/-) resulted in similar
urogenital malformations to those observed in Gli2-/-
mutants (Fig. 4C). Previous
studies of Gli compound mutants demonstrated that Gli family members
have redundant functions in organogenesis
(Bai et al., 2004;
Hardcastle et al., 1998;
Mo et al., 1997;
Motoyama et al., 1998;
Park et al., 2000). Our
findings reveal that such redundancy also occurs during development of the
urogenital tissues. In summary, mouse mutants lacking either the Shh ligand or
HH transcriptional effectors display similar defects in external genitalia,
internal urethra and bladder formation.
Localizing activity of the HH pathway in vivo using reporter mouse strains
Next, we employed a new reporter mouse strain to localize active HH
signaling in vivo (Fig. 5). We
developed an HH-responsive, LacZ marker strain called del5-LacZ (see
Materials and methods) employing a Gli-responsive binding site that had been
previously identified in the 5' flanking upstream sequence of the
Foxa2 gene (Sasaki et al.,
1997). Deletion analyses on the upstream sequences of
Foxa2 gene revealed the sequences to detect HH signaling using in
vitro systems (Sasaki et al.,
1997) (H.S., unpublished). Based on such studies, an HH-responsive
transgenic mouse line was generated, employing this Gli-responsive binding
site (this study and J.M. and H.S., unpublished). Here, we assayed the
efficacy of this reporter as a readout of intracellular HH by examining LacZ
activity in the E11.5 limb and neural tube
(Fig. 6), both embryonic
regions of HH activities (McMahon et al.,
2003) (Fig. 6A,C).
Furthermore, as would be predicted, del5-LacZ activity was increased in limb
buds lacking the Gli3 repressor (genotype:
del5-LacZ/+;Xt/Xt, Fig.
6B) and was reduced in the neural tube and notochord of
Shh null mutants (Fig.
6D).
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We also noted that the intensity of del5-LacZ staining varied with the
embryonic stage and tissue examined: the LacZ signal was faint in the PCM at
E11.5 but quite robust in the bladder mesenchyme by E12-13.5
(Fig. 5C,D, white arrow),
whereas no staining was detected in the GT mesenchyme at these stages (black
arrows; see Discussion). Thus, the pattern of del5-LacZ expression is
restricted within the broader Ptc1 and Gli1 expression
domains in urogenital tissues at multiple stages (compare
Fig. 5B with
Fig. 2D,G and
Fig. 5D with
Fig. 2F,I; expression data not
shown for E9.5). As our in vitro and in vivo data showed that the expression
regulated by the del5 sequence reflects intracellular HH signaling
(Sasaki et al., 1997), it is
likely that restricted HH signaling revealed by the del5-LacZ staining data
reflects the net of positive and negative Gli activity in this region. In
fact, we detected Gli3 repressor expression during urogenital tissue
development (data not shown).
Analysis of the contribution of HH-responding urogenital tissues utilizing tamoxifen-inducible tissue labeling
An important feature of urogenital and reproductive organ formation is the
dynamic transition of the initial epithelial lined cavity (the cloaca and
urogenital sinus) into bladder, GT, urethral plate and urethra. In order to
follow the tissue lineages that respond to HH signals at different time points
and locations during development of these structures, we used an inducible
genetic labeling system. Taking advantage of the regulation of the activity of
the Gli1 locus by HH signaling, the Joyner lab generated a unique
HH-responding tissue lineage analysis system by targeting a
tamoxifen-inducible Cre recombinase to the Gli1 locus
(Gli1-CreERT2; see schematic in
Fig. 8)
(Ahn and Joyner, 2004). This
system has been shown to be effective for analyzing the tissue lineage of
HH-responding cells during limb formation and central nervous system
development (Ahn and Joyner,
2004; Ahn and Joyner,
2005; Harfe et al.,
2004).
Based on our data documenting the histogenesis of the cloaca and urogenital
sinus and Shh expression by this tissue, we were interested in
defining the contribution of early HH-responsive cells to the bladder, urethra
and external genitalia. We therefore utilized tamoxifen to induce activity of
Cre protein present at E8.75-9.0 (expressed from the
Gli1-CreERT2 allele) and then assayed LacZ activity from
the Rosa26 Cre reporter (Ahn and Joyner,
2004; Ahn and Joyner,
2005) at E10-11 and at later stages. Under these temporal
conditions, we detected significant LacZ staining in the PCM
[Fig. 8A,B; the LacZ signals in
the yellow region correspond to the Ptc1 and Gli1 expression
domains in Fig. 2D,G; this
point is also suggested by the earlier expression of Ptc1 and
Gli1 (data not shown)]. Remarkably, assaying for LacZ activity at
E13.5 revealed that `early-onset and long-contributing' lineages in the PCM
make a dynamic contribution to the dorsal (upper) GT and the bladder
(Fig. 8C,D). This developmental
LacZ transition from PCM to GT and bladder suggests a coordinated
developmental formation of these organs for the first time (see below).
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; Yamada et al.,
2006). We assayed the LacZ-positive bladder mesenchyme in
Gli1-CreERT2 reporter embryos (tamoxifen induced at
E8.75-9.0) for smooth muscle myosin production. Co-staining of the mesenchyme
in the bladder wall at E14.5 confirms that these smooth muscle myosin-positive
tissues derive from early HH-responsive lineages (genetically labeled at E9;
co-staining revealed by blue LacZ signals and brown anti-smooth muscle myosin
signals, Fig. 9A,B).
The external genitalia undergo hormone-dependent, dimorphic morphogenesis
after E16.5, which leads to penis and clitoris formation in males and females,
respectively (Cobb and Duboule,
2005; Dolle et al.,
1991; Yamada et al.,
2003; Yamada et al.,
2006). Androgen receptor (AR) plays a fundamental role in
directing the GT toward penis formation, including tubular urethra formation
from the UP. AR gene is prominently expressed in male GTs later than
E16.5 and also its expression is detected in the hormone-independent early
phase of GT formation (R.H. and G.Y., unpublished). Thus, we examined
mesenchymal AR expression in the GT mesenchyme of LacZ-stained,
tamoxifen-induced HH reporter mice. At E14.5, co-staining for LacZ and
AR in the dorsal GT mesenchyme reveals a developmental link between
the AR-expressing dorsal GT and early HH-responding tissues derived
from the PCM (Fig. 9C,D). This
dorsal GT mesenchyme probably contributes to corporal bodies and penile bones
(Yamada et al., 2006)
(Fig. 8E). LacZ staining of the
dorsal GT and bladder mesenchyme in Gli1-CreERT2 reporter
newborns that were tamoxifen-induced at E8.75-9.0 also supports the
contribution of early HH-responsive PCM to these structures
(Fig. 8E-G).
To further confirm these results, we assayed the effects of reduced Shh gene dosage on the contribution of HH-responsive tissues to the GT and bladder in compound mutants (Shh-/-; Gli1-CreERT; R26R/+, Fig. 9E-J) and noted a significant reduction in the contribution of LacZ-positive tissues in Shh null mutants (Fig. 9H-J; blue arrow indicates the reduced LacZ activity relative to Fig. 9E-G).
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The urogenital and reproductive tissue primordia ultimately form the organs
necessary for uresis, ejaculation and sperm intake and implantation and
urino-retention. How PCM region (partly mentioned as infra-umbilical
mesenchyme; basically locating in the upper part of the cloacal field) could
contribute to various urogenital tissues has remained a mystery for decades
(Mildenberger et al., 1988).
By using a tamoxifen-inducible genetic lineage system to label HH-responding
tissues, we have been able to define the temporally distinct contributions of
different HH-responding lineages to the complex urogenital organs
(Fig. 9K). Labeling at
E8.75-9.0 revealed that early HH-responsive tissues contribute first to the
PCM and later, to the dorsal GT and bladder mesenchyme. Of the mesenchyme
derived from the PCM, the dorsal GT mesenchyme displayed sexual dimorphism at
late embryonic stages but bladder mesenchyme did not.
The tamoxifen-inducible labeling system described by Ahn et al. is thought to label cells within approximately one day of tamoxifen injection. In our tamoxifen/Gli1-CreERT2 labeling experiments, the LacZ signal was relatively weak in the PCM compared with the prominent staining and contribution of these cells to bladder mesenchyme and the dorsal GT. We suggest that the initial cell population within the PCM undergoes transient expansion by proliferation (data not shown). Our data obtained with the HH-responsive marker allele, del5-LacZ, also suggested very dynamic urogenital organ formation, consistent with these findings; in this system, LacZ expression is directly regulated by the HH-inducible promoter in vivo (not from the Rosa locus). In fact, the latter approach revealed prominent HH signal activation in the bladder mesenchyme, but not in the dorsal GT, at E12-13. Overall, these data illustrate the varying level of participation of HH-responsive tissues in specific aspects of urogenital organ development at different stages.
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Crosstalk between HH and other signaling pathways, such as fibroblast
growth factors (Fgfs), bone morphogenetic proteins (Bmps) and Wnts, and
integration of these multiple inputs, is likely to be as crucial for
regulating normal development of the these tissues as has been proposed in
other regions of the developing embryo
(Lamm et al., 2001;
McMahon et al., 2003;
Ovchinnikov et al., 2006;
Roberts et al., 1998;
Yamada et al., 2006;
Zuniga et al., 1999).
Genetic cascades for urogenital organogenesis and insights into human birth defects
Orchestration of complex urogenital organ formation is one of the key
events in embryogenesis. How the PCM contributes to multiple urogenital
tissues has remained a mystery for decades. Our demonstration of the
contribution of early PCM to different urogenital tissues, including the
bladder and external genitalia, is a unique finding that supports previous
speculation in medical embryology text books
(Carlson, 1994;
Larsen, 1997;
Moore, 1998). In human
teratology, abnormal human phenotypes reflecting simultaneous dysgenesis of
the bladder and external genitalia have been described. Affected human
phenotypes often display exstrophy of the bladder, epispadias, or `flattened
or hypoplasic external genitalia', which are intriguingly similar to
phenotypes in the mutants analyzed here. These complex congenital defects
prompted the idea of coordinated urogenital organ development. However, there
has previously been little experimental exploration of the tissue lineages or
signaling pathways involved that would provide a mechanistic basis for such a
hypothesis.
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). Moreover, significantly higher frequency of such birth
defects in male infants is reported
(Larsen, 1997;
Moore, 1998). Defects of the
dorsal external genitalia include epispadias with urethral defects and various
dorsal external genitalia anomalies with relatively low frequency
(Jeffs, 1987). Birth defects
affecting the bladder, such as bladder exstrophy with associated malformation
of the urethra has been reported in 1 of about 30,000-50,000 births
(Cheng et al., 2006;
Jeffs, 1987). Affected
children often require multiple reconstructive surgical procedures
(Jeffs, 1987;
Johnston, 1975), increasing
the impetus for research into the developmental bases of normal and abnormal
urogenital organogenesis.
Another point for consideration is the lack of understanding of the
embryonic mesenchymal precursors of the bladder walls. Improving our knowledge
in this regard is vital to support medical efforts in bladder reconstruction.
In fact, current bladder reconstruction approaches often utilize other
endodermal organs, such as the ileum and the colon as the source of autograft
tissue to construct bladder-like reservoirs
(Staack et al., 2005).
Although the development of these endodermally derived tissues was also
influenced by Shh, the ultimate structure and physiological character of
mature gut and bladder are obviously significantly different. Hence, multiple
complications, including electrolyte imbalance and stone formation were
observed after the use of gastrointestinal mucosa or mesenchyme for bladder
repair (Staack et al., 2005).
Therefore, elucidation of the developmental mechanisms driving embryonic
mesenchyme toward functional bladder tissues is likely to have significant
impact when translated to the medical arena. Although further studies are
necessary, our work has provided insight into the functions of Shh signaling
during embryonic bladder formation. The current findings of the importance of
HH signaling and the structural roles of HH-responsive tissues during
urogenital organogenesis may not only provide clues to understanding the basis
of human urogenital birth defects, but may also stimulate translational
research that can have an impact on the management of these defects.
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ACKNOWLEDGMENTS |
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REFERENCES |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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