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RESEARCH COMMUNICATION
Netherlands Institute for Developmental Biology, Hubrecht Laboratory, Uppsalalaan 8, 3584CT Utrecht, The Netherlands
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Abstract |
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 Top Abstract Results and DiscussionMaterials and methodsAcknowledgmentsReferences |
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-catenin,
inhibition of c-myc expression, and subsequent up-regulation of
p21CIP1/WAF1. Thus, our data are the first to establish a direct
requirement for Wnt ligands in driving proliferation in the intestinal
epithelium, and also define an unexpected role for Wnts in controlling
secretory cell differentiation.
[Keywords: Intestinal epithelium; canonical Wnt signaling; Dickkopf1]
Received April 7, 2003; revised version accepted May 16, 2003.
). The
Wnt–Fz–LRP5/6 complex transduces a signal into the cell, resulting
in nuclear accumulation of -catenin and subsequent activation of TCF
target genes. Formation of this complex is inhibited specifically and potently
by the secreted protein Dickkopf1 (Dkk1;
Tamai et al. 2000;
Bafico et al. 2001;
Mao et al. 2001;
Semenov et al. 2001;
Andl et al. 2002).
Previous in vivo studies implicate Wnt signals in the regulation of
intestinal stem cell proliferation
(Kinzler and Vogelstein 1996;
Bienz and Clevers 2000;
Booth et al. 2002). First,
proliferative cells at the bottom of the small intestine
(Batlle et al. 2002) and the
colon (van de Wetering et al.
2002) crypts accumulate nuclear -catenin. Second, mutations
that activate the Wnt/-catenin pathway can lead to colorectal cancer in
humans (Powell et al. 1992;
Kinzler and Vogelstein 1996;
Fodde et al. 2001) as well as
adenomatous polyp formation in the mouse intestine
(Moser et al. 1990;
Fodde et al. 1994;
Oshima et al. 1995;
Shibata et al. 1997), whereas
mutation of Tcf4 leads to the depletion of intestinal proliferative
compartments in fetal mice (Korinek et al.
1998). Although these studies address the function of downstream
components of the Wnt/-catenin pathway, they do not provide evidence for
the requirement of Wnt signals themselves in the regulation of intestinal
proliferation.
Our initial studies indicated that at least four Wnt genes (i.e., Wnt4,
Wnt6, Wnt11, and Wnt14b; D. Pinto, A. Gregorieff, and H.
Clevers, unpubl.) were expressed specifically in crypts of embryonic and adult
small intestine. Potential redundancy precluded a direct analysis of the role
of these Wnt genes in crypt biology. We therefore adopted a strategy to block
all Wnt–Fz–LRP5/6 interactions by targeting expression of the Dkk1
inhibitor to the proliferative compartments of the mouse intestine. We
generated transgenic mouse lines expressing the murine Dkk1 cDNA
under the control of a 9-kb regulatory region of the mouse villin gene, which
has previously been shown to direct transgene expression specifically and
efficiently to the epithelial layer of the entire intestinal
crypt–villus unit (Pinto et al.
1999; Janssen et al.
2002).
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Results and Discussion |
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TopAbstractResults and DiscussionMaterials and methodsAcknowledgmentsReferences |
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-catenin downstream target gene
EphB3 is required for the correct allocation of Paneth cells to the
bottom of the crypts (Batlle et al.
2002). This prompted us to verify whether Dkk1 expression was
affecting Paneth cell allocation through control of Eph expression.
Immunohistochemical analysis of lysozyme (a Paneth cell marker) and EphB3
expression performed on serial sections of the small intestine from transgenic
adult animals revealed that the mispositioned Paneth cells in the midpart of
the crypt were devoid of EphB3 staining. In contrast, Paneth cells located at
normal positions at the crypt base were EphB3-positive (see Supplementary Fig.
2C,D). These observations provided formal proof that Paneth cell positioning
in the normal adult intestinal epithelium is tightly regulated by canonical
Wnt signaling, and for the consequent control over EphB3 expression. Because
lysozyme expression was unaffected by Dkk1 transgene expression, our findings
also demonstrate in vivo selective regulation by Wnts of a -catenin/Tcf4
downstream target gene (i.e., EphB3) in a terminally differentiated
epithelial cell type, namely, in Paneth cells.
To increase expression of the transgene, we next generated homozygous
F2 mice. Wild-type and homozygous littermates were killed at adult
stages (1–3 mo) to ensure analysis of mature intestines exhibiting a
definitive crypt–villus architecture (achieved in the mouse by postnatal
day 28; Gordon and Hermiston
1994). At low magnification, sections of small intestines from
Dkk1 homozygous transgenic mice revealed a disorganized and unpacked mucosa
with shortened villi that were significantly decreased in number compared with
nontransgenic samples (Fig.
1A,B). At higher magnification, whereas wild-type crypts and villi
were seen to alternate with strict regularity
(Fig. 1C), the villi in
transgenic animals appeared shorter and the crypts were drastically reduced in
size and number to a few residual structures
(Fig. 1D). Regionally, the
epithelium of transgenic mice displayed stronger phenotypes with no apparent
crypts (Fig. 1E) and very few
residual villi (Fig. 1F). No
obvious alteration in submucosal and muscular layers could be observed. In
situ hybridization revealed that transgene expression was restricted to the
epithelial layer of the small intestine and coincided with regions of crypt
loss in transgenic mice, whereas no expression was detected in wild-type
littermates (Fig. 1G,H), as
expected. Taken together, these findings showed that ectopic expression of
Dkk1 induces morphological alteration of the intestinal epithelium by
affecting crypt integrity.
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The absence of crypts suggested that proliferation could be perturbed in
the small intestine of Dkk1 transgenic mice. We assessed the proliferative
status of the transgenic mucosa by performing immunohistochemistry for the
nuclear proliferation marker Ki-67
(Schluter et al. 1993). In the
wild-type epithelium, proliferative cells were distributed regularly and
uniformly in every crypt (Fig.
2A,C). In contrast, patches of Ki-67-positive crypts were
scattered throughout the transgenic epithelium with frequent and large
unstained areas corresponding to regions lacking crypts, except for some rare
positive cells in a few residual crypts
(Fig. 2B,D). These observations
were confirmed by analysis of 5-bromo-2-deoxyuridine (BrdU) incorporation
(Fig. 2E,F). These results
implied that ectopic expression of Dkk1 induces a failure of crypt maintenance
by inhibition of proliferation. The patchy loss of crypts probably reflects
the previously demonstrated mosaic expression achieved with the fragment of
the villin gene used in the transgene construct
(Pinto et al. 1999). This
could also explain why transgenic animals with locally disorganized intestinal
epithelium can still survive to adulthood.
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The hallmark of activated canonical Wnt signaling is accumulation of
nuclear -catenin (Batlle et al.
2002; van de Wetering et al.
2002). As previously described, immunostaining with a
-catenin antibody revealed membrane-localized -catenin along the
crypt–villus axis as well as nuclear -catenin in cells occupying
basal positions of the crypt in sections of wild-type small intestine
(Fig. 3A). In contrast, in
areas of transgenic sections where crypts were missing, the resulting lining
epithelium was devoid of nuclear -catenin staining
(Fig. 3B). Thus, ectopic
expression of Dkk1, indeed, blocked activation of the Wnt pathway, strongly
implying that the loss of canonical Wnt signaling is responsible for the
observed intestinal phenotype in transgenic mice.
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We next asked whether this Dkk1-dependent down-regulation of nuclear
-catenin affected the expression of -catenin target genes. We
chose Enc-1 as a crypt marker and alkaline phosphatase (AP) as a villus marker
(van de Wetering et al. 2002),
and examined their expression by immunohistochemistry. In wild-type small
intestine sections, Enc-1 immunostaining was restricted to the cytoplasm of
crypt epithelial cells, whereas this staining was completely absent from
transgenic specimens (Fig.
3C,D). For AP, in contrast, membrane immunostaining was only
visible for villus-associated cells of wild-type animals, whereas both villi
and the intervillus epithelium appeared positive in transgenic sections
(Fig. 3E,F). The same pattern
was obtained by immunostaining with another differentiation (villus) marker,
FABP-L (liver fatty acid-binding protein;
Simon et al. 1993; data not
shown). These results showed that the surface epithelium replacing the crypts
in Dkk-1 transgenic mice displayed a differentiated phenotype, thus indicating
that inhibition of proliferation in presumptive crypt regions by blockade of
canonical Wnt signaling promotes terminal differentiation.
The epithelium of the mouse small intestine consists of four principal cell
types: absorptive enterocytes, and secretory goblet, enteroendocrine, and
Paneth cells (Stappenbeck et al.
1998). Because AP is a differentiation marker for enterocytes, we
investigated the status of the three other cell types. All three secretory
cell types were absent from affected areas of the small intestine epithelium
of transgenic specimens when compared with wild-type specimens, except for
some cells in rare residual crypts (Fig.
4A–F). Notably, these data established that the activity of
the Wnt/-catenin pathway is required for the emergence of secretory cell
types in the epithelium of the small intestine, possibly through regulating
the proliferation of a common secretory lineage progenitor. Consistent with
this idea and based on the knowledge that this progenitor expresses Math1
(Yang et al. 2001), we
performed immunostaining with an anti-Math1 antibody
(Helms and Johnson 1998). We
confirmed that Math1 was expressed in the nucleus of all three secretory cell
types as well as in certain progenitor cells in the midpart of the crypt in
wild-type small intestine sections (Fig.
4G). In contrast, no Math1 expression was found in the intestinal
epithelium of transgenic animals (Fig.
4H). We tentatively concluded that the Wnt/-catenin pathway
is essential for the maintenance of Math1-positive progenitors for the
secretory cell lineage. Nonetheless, Math1 itself did not appear to be a
direct target gene of Tcf4 in the gut because its expression was maintained
within goblet cells of Tcf4-deficient mice (see Supplementary Fig. 3).
Intriguingly, although goblet cells were absent from Dkk1 transgenic
intestines, their differentiation did not seem to be affected in
Tcf4-deficient mice. This suggests that in the fetal gut, an initial wave of
goblet cell differentiation may occur independently of Tcf4.
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To determine by which molecular mechanism loss of nuclear -catenin
could affect proliferation in the adult small intestine, we examined the
expression of the -catenin target gene c-myc and also of the
cell cycle inhibitor p21CIP1/WAF1. Our laboratory recently showed
that in the nucleus of colorectal cancer cells, the formation of a
-catenin/Tcf4 complex results in the direct up-regulation of
c-myc, which, in turn, represses p21CIP1/WAF1 by direct
promoter binding, thereby allowing cells to proliferate
(van de Wetering et al. 2002).
In wild-type small intestine sections, immunohistochemical detection of c-Myc
revealed a nuclear localization restricted to the progenitor cells of the
crypts, whereas no expression was observed in affected areas of transgenic
sections (Fig. 5A–D). In
wild-type animals, p21CIP1/WAF1 was found mainly in the nuclei of
differentiated cells like Paneth cells and villus-associated cells, whereas in
transgenic specimens the staining was also detected in the lining epithelium
replacing the crypts (Fig.
5E–H). Taken together, these results demonstrated that
blocking Wnt–Fz–LRP5/6 interactions leads to repression of
c-myc expression and induction of
p21CIP1/WAF1 expression. These in vivo findings
confirm the proposed role for c-Myc in maintaining intestinal epithelial cells
in a proliferative, undifferentiated state, and a role for
p21CIP1/WAF1 as a key mediator of cell cycle arrest and terminal
differentiation in the intestinal epithelium.
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Homeostasis of the intestinal epithelium is strongly dependent on the
balance existing among cell proliferation, cell cycle arrest, cell
differentiation, and cell migration (Simon
and Gordon 1995). By targeting expression of Dkk1, a potent and
specific inhibitor of canonical Wnt signals, we demonstrated that the
signaling pathway is active in adult normal intestinal epithelium and is
required for the formation of normal crypt–villus units through the
regulation of proliferation, cell positioning, and differentiation.
Furthermore, we provide in vivo evidence to substantiate the opposing roles of
c-Myc and p21CIP1/WAF1 in regulating the
proliferation-differentiation switch in the intestinal epithelium, as
suggested by previous studies with cultured cells
(van de Wetering et al. 2002).
An unexpected finding of our work is the apparent increased requirement of
secretory cell progenitors for canonical Wnt signaling compared with
enterocyte progenitors. In conclusion, our studies attest to the critical
importance of canonical Wnt signals in the homeostasis of the intestinal
epithelium.
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Materials and methods |
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TopAbstractResults and DiscussionMaterials and methodsAcknowledgmentsReferences |
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The villin-Dkk1 transgenic expression construct was generated by cloning
the murine Dkk1 ORF sequence (a kind gift from C. Niehrs, DKFZ, Heidelberg,
Germany) at the initiation codon of the 9-kb regulatory region of the mouse
villin gene (Pinto et al.
1999) using standard techniques. An SV40 termination and
polyadenylation cassette was added downstream.
Generation of Villin-Dkk1 mice
Villin-Dkk1 transgenic mice were generated by microinjection of linearized plasmid into the pronuclei of fertilized eggs of B6CBAF1/JIco mice. Transgenic mice were identified by Southern blotting and PCR analysis using tail genomic DNA. Founder mice were bred to C57BL/6 wild-type mice to produce F1 hemizygous mice, and the littermates were bred to generate F2 homozygous mice. All mice were maintained at the Central Laboratory Animal Institute (Utrecht, The Netherlands) according to institutional guidelines.
Reverse transcription-PCR analysis
Total RNA was isolated with Trizol reagent (Life Technologies), and reverse
transcription and PCR experiments were processed as described
(Pinto et al. 1999). For the
transgene amplification, 5'-CAACTTCCTAA GATCTCC-3' sense primer
and 5'-GATCAGAACTGAGTTCAAGG-3' antisense primer were used,
generating a 176-bp product.
Histology, immunohistochemistry, BrdU labeling, and in situ
hybridization
Tissues were fixed in 10% formalin or 4% paraformaldehyde,
paraffinembedded, and sectioned at 3–6 µm for hematoxylin/eosin
staining or immunostaining procedure as described
(Batlle et al. 2002). The
primary antibodies used were rabbit anti-lysozyme (1:500; DAKO), goat
anti-EphB3 (1:50; R&D Systems), mouse anti-Ki67 (1:100; Novocastra), mouse
anti-BrdU (1:500; Becton Dickinson), mouse anti--catenin (1:50;
Transduction Laboratories), mouse anti-Enc1 (1:100; Pharmingen), rabbit
anti-alkaline phosphatase (1:400; BioTrend), rabbit anti-synaptophysin (1:100;
DAKO), rabbit anti-Math1 (1:50; a kind gift from J. Johnson, University of
Texas Southwestern Medical Center, Dallas, TX;
Helms and Johnson 1998), rabbit
anti-c-myc (1:500; Upstate Biotechnology), and rabbit
anti-p21CIP1/WAF1 (1:500; Pharmingen). The peroxidase-conjugated
secondary antibodies used were Mouse or Rabbit EnVision+ (DAKO). For BrdU
labeling, mice were injected with 100 µg of BrdU (Sigma) per gram of body
weight and killed after 2 h. For in situ hybridization, Dkk1 antisense
riboprobe was synthesized from the mouse cDNA (a kind gift from C. Niehrs,
DKFZ, Heidelberg, Germany), and the procedure was performed as described
(Moorman et al. 2001).
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Acknowledgments |
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TopAbstractResults and DiscussionMaterials and methodsAcknowledgmentsReferences |
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The publication costs of this article were defrayed in part by payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 USC section 1734 solely to indicate this fact.
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Footnotes |
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1 Corresponding author.
E-MAIL
clevers{at}niob.knaw.nl;
FAX 31-30-2121801. 
Supplemental material is available at http://www.genesdev.org.
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TopAbstractResults and DiscussionMaterials and methodsAcknowledgmentsReferences |
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V. Muncan, O. J. Sansom, L. Tertoolen, T. J. Phesse, H. Begthel, E. Sancho, A. M. Cole, A. Gregorieff, I. M. de Alboran, H. Clevers, et al. Rapid Loss of Intestinal Crypts upon Conditional Deletion of the Wnt/Tcf-4 Target Gene c-Myc Mol. Cell. Biol., November 15, 2006; 26(22): 8418 - 8426. [Abstract] [Full Text] [PDF]
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R. G. Jones, X. Li, P. D. Gray, J. Kuang, F. Clayton, W. S. Samowitz, B. B. Madison, D. L. Gumucio, and S. K. Kuwada Conditional deletion of {beta}1 integrins in the intestinal epithelium causes a loss of Hedgehog expression, intestinal hyperplasia, and early postnatal lethality J. Cell Biol., November 6, 2006; 175(3): 505 - 514. [Abstract] [Full Text] [PDF]
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S. C.M. Martinico, S. Jezzard, N. J. H. Sturt, G. Michils, S. Tejpar, R. K. Phillips, and G. Vassaux Assessment of Endostatin Gene Therapy for Familial Adenomatous Polyposis-Related Desmoid Tumors Cancer Res., August 15, 2006; 66(16): 8233 - 8240. [Abstract] [Full Text] [PDF]
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G R van den Brink and J C H Hardwick Hedgehog Wnteraction in colorectal cancer Gut, July 1, 2006; 55(7): 912 - 914. [Full Text] [PDF]
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M. Takano-Maruyama, K. Hase, H. Fukamachi, Y. Kato, H. Koseki, and H. Ohno Foxl1-deficient mice exhibit aberrant epithelial cell positioning resulting from dysregulated EphB/EphrinB expression in the small intestine Am J Physiol Gastrointest Liver Physiol, July 1, 2006; 291(1): G163 - G170. [Abstract] [Full Text] [PDF]
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A. M. Carothers, A. E. Moran, N. L. Cho, M. Redston, and M. M. Bertagnolli Changes in Antitumor Response in C57BL/6J-Min/+ Mice during Long-term Administration of a Selective Cyclooxygenase-2 Inhibitor. Cancer Res., June 15, 2006; 66(12): 6432 - 6438. [Abstract] [Full Text] [PDF]
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W. Zhang, X. Chen, Y. Kato, P. M. Evans, S. Yuan, J. Yang, P. G. Rychahou, V. W. Yang, X. He, B. M. Evers, et al. Novel Cross Talk of Kruppel-Like Factor 4 and {beta}-Catenin Regulates Normal Intestinal Homeostasis and Tumor Repression. Mol. Cell. Biol., March 1, 2006; 26(6): 2055 - 2064. [Abstract] [Full Text] [PDF]
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D. Boerboom, L. D. White, S. Dalle, J. Courty, and J. S. Richards Dominant-Stable {beta}-Catenin Expression Causes Cell Fate Alterations and Wnt Signaling Antagonist Expression in a Murine Granulosa Cell Tumor Model Cancer Res., February 15, 2006; 66(4): 1964 - 1973. [Abstract] [Full Text] [PDF]
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 A. Malliri, T. P. Rygiel, R. A. van der Kammen, J.-Y. Song, R. Engers, A. F. L. Hurlstone, H. Clevers, and J. G. Collard The Rac Activator Tiam1 Is a Wnt-responsive Gene That Modifies Intestinal Tumor Development J. Biol. Chem., January 6, 2006; 281(1): 543 - 548. [Abstract] [Full Text] [PDF]
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H. Clevers and E. Batlle EphB/EphrinB Receptors and Wnt Signaling in Colorectal Cancer Cancer Res., January 1, 2006; 66(1): 2 - 5. [Abstract] [Full Text] [PDF]
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 C. C. LEOW, P. POLAK |
