doi: 10.1101/gad.267103.
Canonical Wnt signals are essential for homeostasis of the intestinal epithelium
Affiliations
- PMID: 12865297
- PMCID: PMC196179
- DOI: 10.1101/gad.267103
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Canonical Wnt signals are essential for homeostasis of the intestinal epithelium
Genes Dev.
.
Abstract
To assess the critical role of Wnt signals in intestinal crypts, we generated transgenic mice ectopically expressing Dickkopf1 (Dkk1), a secreted Wnt inhibitor. We find that epithelial proliferation is greatly reduced coincidentally with the loss of crypts. Although enterocyte differentiation appears unaffected, secretory cell lineages are largely absent. Disrupted intestinal homeostasis is reflected by an absence of nuclear beta-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.
Figures
Dkk1 ectopic expression deleteriously affects crypt–villus
organization. Representative sections of the small intestine from wild-type
(A,C) and transgenic (B,D–F) adult animals
stained with hematoxylin/eosin. The number and the size of crypts and villi
are drastically reduced in the transgenic mucosa to rare residual crypt-like
structures (arrowheads in D) or few residual villi (arrows in
F). In situ hybridization analysis of small intestine sections from
wild-type (G) and transgenic (H) mice hybridized with a Dkk1
antisense RNA probe. Note that Dkk1 is only expressed in the transgenic
epithelium. Original magnification: A,B, 2×;
C–H, 20×.
Intestinal cell proliferation is inhibited in Dkk1 transgenic mice.
Immunohistochemical analysis of small intestine sections from wild-type
(A,C) or transgenic (B,D) adult mice stained with an
antibody against proliferating cell antigen Ki-67, and wild-type (E)
or transgenic (F) adult mice labeled with BrdU and stained with an
anti-BrdU antibody. Note that proliferative cells are abundantly present in
regularly distributed crypts flanking the villi from the wild-type intestine
(C, inset), but are absent from patchy cryptless areas in the
transgenic intestine, persisting only in scarce residual crypts (D,
inset). Original magnification: A,B, 2×; C,D,
10×; insets, 60×; E,F, 20×.
Nuclear β-catenin and related target genes expression in transgenic
intestinal mucosa. Immunohistochemical analysis of small intestine sections
from wild-type (A,C,E) and transgenic (B,D,F) adult mice
stained with antibodies against β-catenin (A,B), Enc-1
(C,D), and AP (E,F). Staining of β-catenin shows
accumulation in the nucleus of cells at the crypt base (A and
inset), but is absent from the nucleus of cells of the lining
epithelium in the cryptless regions (B and inset). Staining
indicates that Enc-1 cytoplasmic expression restricted to the crypt cells
(C and inset) is completely absent from the intervillus
lining epithelium (D and inset). Staining reveals that AP
expression at the apical domain of the villus-associated cells (E and
inset) is found in the cells of the lining epithelium in cryptless
areas (F and inset). Original magnification:
A–F, 20×; insets, 60×.
Secretory cell lineage is depleted in Dkk1 transgenic intestinal
epithelium. Representative sections of the small intestine from wild-type
(A,C,E,G) and transgenic (B,D,F,H) adult animals stained for
representation of secretory cell types: anti-lysozyme antibody (Paneth cells;
A,B), periodic acid/Schiff (goblet cells; C,D),
anti-synaptophysin (enteroendocrine cells and nerve fibers; E,F), and
anti-Math1 antibody (all three types and common progenitors; G,H).
Note that all three secretory cell types and their Math1-positive common
progenitors (G, bottom inset) are absent from cryptless areas of the
transgenic epithelium (except in residual crypts). Original magnification:
A–H, 20×; insets, 40×.
Complementary pattern of expression for c-Myc and p21CIP1/WAF1
in wild-type and transgenic intestinal epithelium. Representative sections of
the small intestine from wild-type (A,B,E,F) and transgenic
(C,D,G,H) adult animals stained with an anti-c-myc antibody
(A–D) or an anti-p21CIP1/WAF1 antibody
(E–H). The arrows in B and F
indicate Paneth cells displaying a reverse nuclear staining for c-Myc and
p21CIP1/WAF1. The arrowheads in D and H show that
p21CIP1/WAF1 is expressed in the nucleus of the cells lining the
intervillus epithelium contrary to c-Myc. Original magnification:
A,C,E,G, 20×; B,D,F,H, 40×.
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