Departments of 1 Cell and Molecular Physiology and 2 Medicine, University of North Carolina, Chapel Hill, North Carolina 27599-7080; and 3 Division of Endocrinology and Metabolism, University of Cincinnati, Cincinnati, Ohio 45267
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ABSTRACT |
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Local IGF-I expression is frequently
increased in intestinal mesenchyme during adaptive growth of intestinal
epithelium, but paracrine growth effects of IGF-I in vivo are not
defined. We tested whether overexpression of IGF-I in intestinal
mesenchyme increases epithelial growth and if effects are distinct from
known effects of circulating IGF-I. SMP8-IGF-I-transgenic (TG) mice overexpress IGF-I driven by an -smooth muscle actin promoter. Mucosal and muscularis growth were assessed in the jejunum, ileum, and
colon of SMP8-IGF-I-TG mice and wild-type littermates. Abundance of the
SMP8-IGF-I transgene and IGF binding protein (IGFBP)-3 and -5 mRNAs was
determined. Mucosal growth was increased in SMP8-IGF-I-TG ileum but not
jejunum or colon; muscularis growth was increased throughout the bowel.
IGFBP-5 mRNA was increased in SMP8-IGF-I-TG jejunum and ileum and was
specifically upregulated in ileal lamina propria. Overexpression of
IGF-I in intestinal mesenchymal cells has preferential paracrine
effects on the ileal mucosal epithelium and autocrine effects on the
muscularis throughout the bowel. Locally expressed IGF-I has distinct
actions on IGFBP expression compared with circulating IGF-I.
insulin-like growth factor-I; mucosa; intestinal growth; insulin-like growth factor binding protein-3; insulin-like growth factor binding protein-5
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INTRODUCTION |
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IGF-I MEDIATES LINEAR body growth as well as growth of multiple organs, including the intestine (reviewed in Ref. 21). IGF-I stimulates proliferation of cultured intestinal epithelial cells, fibroblasts, myofibroblasts, and smooth muscle cells (9, 16, 17, 35, 36). Effects of circulating IGF-I to increase mass of small intestinal mucosa and muscularis propria in vivo are well documented (18, 29, 30, 38). The liver is a primary source of IGF-I in circulation (42), but IGF-I is also expressed locally in most, if not all, other tissues, including the intestine (22). Hepatocyte-specific deletion of the IGF-I gene results in normal body growth and normal growth of a number of organs despite a 75% reduction in circulating IGF-I (42). These findings indicate that IGF-I derived from nonhepatic sources has a greater role in mediating postnatal body and organ growth than has previously been suspected. Defining the role of increased local expression of IGF-I in intestinal growth in vivo independent of altered circulating IGF-I requires appropriate cell type-specific experimental manipulations of IGF-I expression.
Available evidence suggests that mesenchymal cells, including
-smooth muscle actin (
-SMA)-positive myofibroblasts and smooth muscle cells, are primary sources of locally expressed IGF-I in the
intestine (33, 41). In the normal intestine, IGF-I is expressed in scattered cells in the pericryptal regions and the lamina
propria (30, 33, 41). Several situations of increased growth of the mucosal epithelium, including refeeding and adaptive growth following bowel resection, are accompanied by increased local
IGF-I mRNA expression in mesenchymal cells in the lamina propria or
muscularis propria (23, 41, 43, 47). These findings
provide correlative evidence for paracrine actions of mesenchymal
cell-derived IGF-I on the intestinal epithelium. Recent studies
(36) of the contribution of IGF-I in conditioned medium from intestinal myofibroblasts to growth of cultured epithelial cells
provide support for this possibility but do not provide the important
in vivo evidence for paracrine actions of mesenchymal cell-derived
IGF-I on the intestinal epithelium.
SMP8-IGF-I transgenic (SMP8-IGF-I-TG) mice express rat IGF-I under
transcriptional control of the murine -SMA promoter. SMP8-IGF-I-TG mice have normal levels of circulating IGF-I but have been shown to
exhibit high levels of transgene expression in smooth muscle in the
small intestine and several other tissues (40). Expression of the transgene would be predicted in subepithelial myofibroblasts in
the intestine because these cells are
-SMA positive and are proposed
to be major mediators of epithelial-mesenchymal interactions (reviewed
in Refs. 31 and 32). We used SMP8-IGF-I-TG mice as a model
to test the hypothesis that IGF-I overexpressed in intestinal
mesenchymal cells in vivo in the absence of altered circulating IGF-I
exerts paracrine actions on growth or function of the mucosal
epithelium. Increased length and weight of the small intestine of
SMP8-IGF-I-TG mice have been previously reported, associated with
increased thickness of the muscularis propria (40). The
present study evaluates mucosal mass, crypt cell proliferation, and the
activity of sucrase, a marker of differentiated epithelial cells, to
define whether mesenchymal cell-derived IGF-I overexpression increases
mucosal growth and whether observed effects are intestinal region
specific. Muscularis growth was assessed in more detail than previously
reported (40) in the small intestine as a positive control
and in the colon to define whether there are segmental differences in
the autocrine actions of locally expressed IGF-I on the intestinal muscularis.
Locally expressed IGF binding proteins (IGFBPs) are known to modulate IGF-I action. Of six known high-affinity IGFBPs, IGFBP-3 and IGFBP-5 have been of interest with respect to a role in regulating intestinal growth. IGFBP-3 mRNA is expressed primarily in the lamina propria of the normal intestine of the rat (41) and mouse (27). Decreases in intestinal IGFBP-3 expression accompany increased mucosal growth following small bowel resection (1). In vitro, IGFBP-3 can inhibit or potentiate IGF-I action, depending on the cell system (reviewed in Refs. 2 and 5). IGFBP-3 can inhibit IGF-I action on human chondrocytes when secreted or added to cell culture medium in conjunction with IGF-I (24). IGFBP-3 can potentiate IGF-I action when associated with the cell surface of some IGF-I-responsive cells (6) and has been implicated as a mediator of reduced proliferation and differentiation of colon cancer epithelial cell lines (15, 26). IGFBP-5 has been localized primarily to the muscularis propria of normal rat (30) and human small intestine (46). IGFBP-5 appears to potentiate the growth-promoting effects of IGF-I in cultured smooth muscle cells derived from the intestine (4) or other organs (8, 28).
Systemically administered IGF-I is known to increase the expression of both IGFBP-3 and -5 in rat small intestine (30) and colon (11), although there are segmental differences in the effects of circulating IGF-I on locally expressed IGFBPs, which correlate with segment-specific growth effects (11, 30). After jejunoileal resection in rats, systemic IGF-I stimulates growth of the ileum but not the jejunum (44). In the same model, systemic IGF-I increased IGFBP-3 mRNA expression in the jejunum but not in the ileum (44). Interestingly, IGF-I-dependent induction of IGFBP-5 in the pericryptal regions of the lamina propria, probably in myofibroblasts, has been linked to more potent growth-promoting effects of systemic IGF-I on the small bowel epithelium (11, 30). IGFBP-5 is also upregulated in hyperplastic regions of the muscularis propria at sites similar to those of elevated IGF-I expression in animal models of enterocolitis (47) or patients with Crohn's disease (46). Altered IGFBP-3 or -5 expression could therefore impact on the growth-promoting actions of locally expressed IGF-I in SMP8-IGF-I-TG mice. Furthermore, the SMP8-IGF-I-TG mice provide a model to directly assess whether local IGF-I overexpression in intestinal mesenchymal cells leads to changes in expression of IGFBP-3 or -5 that are similar to or distinct from the effects of circulating IGF-I on these molecules. In the present study, we therefore examined IGFBP-3 and -5 mRNA expression by Northern blot hybridization and in situ hybridization histochemistry to assess whether they are regulated by locally expressed IGF-I and whether any alterations in expression correlate with observed growth effects. Our data provide definitive in vivo evidence for autocrine and paracrine actions of mesenchymal cell-derived IGF-I on intestinal smooth muscle and epithelium. These studies also point to some interesting differences in paracrine effects of locally expressed IGF-I in the ileum compared with the jejunum and colon and demonstrate different effects of locally expressed IGF-I on intestinal IGFBP expression compared with effects of circulating IGF-I.
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MATERIALS AND METHODS |
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Animal care and genotyping. SMP8-IGF-I-TG founder mice on the inbred FVB/N genetic background were derived as previously described (40). A colony was established in the University of North Carolina animal facility by breeding hemizygous male transgenic founder mice with wild-type (WT) FVB/N females. Mice were housed and fed in accordance with guidelines established by the University of North Carolina at Chapel Hill Institutional Animal Use and Care Committee. Mice were genotyped by Southern blot analysis of tail DNA as previously described (40).
Sample collection. Sex-matched pairs of SMP8-IGF-I-TG and WT littermates were killed at 50-60 days of age. The entire small intestine and colon were dissected on ice, and the contents were flushed with ice-cold 0.9% saline. Wet weight of the entire small intestine was measured. The jejunum, ileum, and colon were then separately measured and weighed. Length of each segment was determined using a 5-g weight to provide constant tension. Care was taken to assess comparable regions of the bowel from each animal; the small intestine was dissected from the ligament of Treitz to the ileocecal valve. The most proximal third was dissected to provide a sample of jejunum, and the most distal third was dissected to provide ileum. Anatomically comparable 0.5-cm segments of jejunum, ileum, and colon from each animal were subsequently fixed in formalin for histological analyses, frozen in OCT embedding compound (Tissue-Tek, Torrance, CA) for in situ hybridization histochemistry, fixed in Carnoy's reagent for analysis of crypt cell mitosis, or snap frozen in liquid nitrogen for subsequent analyses of bowel mass or extraction of total RNA. In an additional four pairs of SMP8-IGF-I-TG and WT mice, the entire bowel was dissected and the jejunum, ileum, and colon were snap frozen for RNA isolation to permit analyses of regional expression of the transgene or IGFBP mRNAs.
DNA, protein, and sucrase assays. Mucosa was scraped from the samples of jejunum, ileum, and colon collected for evaluation of bowel mass as previously described (27). Briefly, tissue samples were thawed on ice and opened longitudinally. The mucosa was then removed by gently scraping a glass microscope slide over the tissue segment several times, resulting in a mucosal fraction and a submucosa/muscularis fraction. Each fraction was weighed and then sonicated in 5 mM sodium phosphate (pH 7.2). DNA content in homogenates of mucosa and muscularis was determined by using a fluorescent dye microassay as previously described (27). Protein content in mucosa and muscularis was determined by the method of Lowry et al. (20). Sucrase activity in mucosal homogenates was measured by standard methods (39).
Crypt cell mitoses. Whole crypts were dissected from Carnoy's fixed samples of jejunum, ileum, and colon and stained with Schiff's reagent. Mitotic cells were counted in microdissected crypts by a single blinded observer. Eight to twelve crypts were counted per sample, and samples were counted from ten to twelve mice of each genotype.
Histological analyses. Small (0.5-cm) segments of jejunum, ileum, and colon were opened longitudinally, placed on a strip of filter paper to maintain orientation, and fixed in formalin for 4 h. The tissue blocks were then embedded in paraffin, sectioned, and stained with hematoxylin and eosin. Crypt depth, villus height, and thickness of the muscularis propria were measured by a single blinded observer using a Nikon Microphot-FXA microscope with an Optronics DEI 750 three-chip charge-coupled device camera for digital imaging and morphometry.
In situ hybridization histochemistry.
Tissue blocks were oriented in OCT embedding compound and then frozen
in isopentane on dry ice. Sections (10 µm) were cut, and slides were
stored frozen at 80° until use. Sections were fixed in 4%
paraformaldehyde for 30 min and then washed in sterile PBS. In situ
hybridization was performed as previously described by using antisense
RNA probes (27). A rat IGF-I RNA probe (27) was used to localize transgene-derived rat IGF-I mRNA and endogenous mouse IGF-I mRNA. Antisense probes for IGFBP-3 and -5 have been described previously (41). Corresponding sense RNA probes
were used as negative controls. All probes were labeled with
35S-UTP (Amersham, Arlington Heights, IL) as previously
described (27).
IGF-I radioimmunoassay. Blood was collected by cardiac puncture at the time of death. Plasma was separated by centrifugation and extracted with Sep-Pak C18 cartridges (Millipore, Bedford, MA) to remove IGFBPs. IGF-I concentration in extracted samples was determined by radioimmunoassay as previously described (27) .
Total RNA extraction and Northern blot analysis. Frozen tissues were homogenized in 4 M guanidine thiocyanate. Homogenates were layered over 5.7 M cesium chloride and centrifuged overnight to isolate total RNA. Total RNA was collected by ethanol precipitation and resuspended in sterile water. Concentration of RNA was determined by absorbance at 260 nm, and the quality of each RNA was verified by examination of 18S and 28S ribosomal RNAs on ethidium bromide-stained agarose gels. Northern blot hybridization was performed as previously described (27) using [32P]UTP-labeled antisense cRNA probes specific for IGFBP-3, IGFBP-5, or the SMP8-IGF-I transgene. The transgene-specific probe is a 351-bp fragment containing the rat IGF-I 3' untranslated region and sequences up to the SV40 early polyadenylation signal (40). To control for RNA loading differences, blots were reprobed with a probe specific for PL7 mRNA, which encodes a constitutively expressed ribosomal protein (34). Blots were scanned on a phosphoimager, and abundance of specific RNAs was quantified using Image Quant software for Macintosh. Abundance of each RNA examined was normalized to the abundance of PL7 RNA for comparisons of RNA abundance.
Statistical analysis. All growth data and mRNA abundance of IGFBP-3 and -5 were analyzed by converting the value obtained in each transgenic mouse to a ratio of the value in its WT littermate. This eliminates any effects of interlitter variation, which is a significant issue in assays of intestinal growth because litter size can affect food intake, and this, in turn, affects bowel mass. Ratios were analyzed by the nonparametric Wilcoxon signed rank test by using SyStat software for PC. Comparisons of absolute data such as morphometric analyses in SMP8-IGF-I-TG and WT mice were compared by using the Mann-Whitney t-test. The abundance of the SMP8-IGF-I transgene, IGFBP-3, and IGFBP-5 in jejunum, ileum, and colon was assessed by one-way ANOVA. A P value of <0.05 was considered statistically significant.
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RESULTS |
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Body weight and plasma IGF-I do not differ in SMP8-IGF-I-TG and WT mice. Mean body weight of SMP8-IGF-I-TG mice was 27.0 ± 1.2 g, which did not differ significantly from the mean body weight of WT littermates (27.3 ± 1.1 g). Plasma levels of IGF-I in SMP8-IGF-I-TG mice (351 ± 23 ng/ml) did not differ significantly from levels in WT littermates (321 ± 37 ng/ml; P = 0.40).
Levels and sites of expression of the SMP8-IGF-I transgene in small
and large intestine.
We first examined jejunum, ileum, and colon for levels of SMP8-IGF-I
transgene expression by Northern blot hybridization (Fig. 1). The transgene mRNA was detected in
each bowel segment, but the ileum and colon exhibited higher levels of
expression than the jejunum (Fig. 1). Since the transgene is expressed
at high levels in smooth muscle cells in the muscularis propria, this may reflect a larger relative mass of the muscularis layers compared with the mucosal layers in the ileum and colon (see Fig. 4). In situ
hybridization revealed high levels of transgene expression in the
muscularis propria of jejunum, ileum, and colon (Fig.
2). Transgene expression was also evident
in the pericryptal and villus regions of the jejunal and ileal mucosa
and in the muscularis mucosa and lamina propria of the colon (Fig. 2).
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Local overexpression of IGF-I increases bowel growth.
SMP8-IGF-I-TG mice had increased wet weight and length of small
intestine relative to WT littermates (Table
1). Wet weight per unit length was
increased in SMP8-IGF-I-TG mice in jejunum, ileum, and colon (Table 1),
indicating an increase in thickness of the bowel wall. SMP8-IGF-I-TG
mice had increased mass (weight per unit length), DNA content, and
protein content of the ileal mucosa but not of the jejunal or colonic
mucosa (Fig. 3A). Sucrase activity was assessed in the mucosa of the jejunum and ileum as a
measure of differentiated epithelial cell function. Sucrase activity
was increased in the ileum but not the jejunum of SMP8-IGF-I-TG mice
(Fig. 3A). Crypt cell mitoses were measured in
microdissected crypts to assess IGF-I transgene effects on crypt cell
proliferation. Consistent with the data on mucosal DNA and protein
content, increased crypt cell mitoses were observed in the ileum but
not jejunum or colon of SMP8-IGF-I-TG mice (Fig. 3A). Mass,
DNA content, and protein content were significantly increased in the
submucosa/muscularis layer throughout the small intestine and the
colon, as shown in Fig. 3B. Histological evaluation
supported these biochemical findings. There was no significant
difference in crypt depth or villus height in the jejunum and colon
(Table 2), which is consistent with the
lack of effect of transgene expression on mucosal growth in these bowel
segments. An increase in crypt depth and/or villus height might have
been anticipated in the ileum. However, the observed increase in crypt
cell proliferation was relatively modest, and the increased DNA and
protein content and sucrase activity could reflect greater numbers of
villi and crypts per unit length rather than an increase in size of the
crypt/villus axis.
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Local IGF-I overexpression modulates IGFBP-5 but not IGFBP-3. Expression of IGFBP-3 and -5 mRNAs was assessed by both Northern blot hybridization and in situ hybridization. In situ hybridization controlled for the possibility that differences in the relative mass of IGFBP-3- and IGFBP-5-expressing cells could affect our ability to accurately detect differences in IGFBP expression in SMP8-IGF-I-TG and WT mice by Northern blot and allowed us to detect altered expression at the cellular level.
By Northern blot hybridization, IGFBP-3 mRNA expression was significantly increased in the colon of WT mice compared with the jejunum in the same WT mice (Fig. 5). An overall aboral gradient was observed such that the ileum and colon had generally higher levels of expression of IGFBP-3 and -5 mRNAs than jejunum in both SMP8-IGF-I-TG and WT mice (Figs. 5 and 6). Within a given bowel segment, there were no major differences in levels of expression of IGFBP-3 mRNA between SMP8-IGF-I-TG vs. WT mice (Fig. 5). In contrast, IGFBP-5 mRNA was significantly higher in the ileum of SMP8-IGF-I-TG ileum compared with WT ileum (Fig. 6). There was also a trend toward increased IGFBP-5 mRNA expression in the jejunum of SMP8-IGF-I-TG mice relative to WT mice, but this did not achieve statistical significance at the 95% confidence level (P = 0.06). No difference in IGFBP-5 mRNA expression was detected in the colon of SMP8-IGF-I-TG mice relative to WT mice. In situ hybridization data, although not strictly quantitative, was consistent with the Northern blot hybridization data. In both SMP8-IGF-I-TG and WT mice, hybridization signals for IGFBP-3 and -5 were stronger in the ileum and colon than in jejunum (Figs. 7 and 8). Note also the striking pattern of IGFBP-3 expression, particularly in the colon, where cells within the lamina propria, adjacent to surface epithelial cells, express much higher levels of IGFBP-3 mRNA than that observed in the lamina propria adjacent to epithelial cells at the base of the crypts (Fig. 7). Hybridization signals for IGFBP-5 mRNA were weak in all bowel segments of WT mice and were localized to the lamina propria and muscularis propria (Fig. 8). In situ hybridization in SMP8-IGF-I-TG mice revealed strong induction of IGFBP-5 in the villus and pericryptal regions of the ileal lamina propria (Fig. 8), which was not detected in SMP8-IGF-I-TG jejunum or colon. Modest induction of IGFBP-5 was also observed in scattered cells between the circular and longitudinal layers of the muscularis propria of SMP8-IGF-I-TG intestine.
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DISCUSSION |
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IGF-I has been demonstrated to have mitogenic effects on cultured
intestinal epithelial cells (9, 35, 36). However, in vivo
studies to assess paracrine actions of IGF-I on intestinal epithelial
cells have previously been hampered by the difficulty of altering IGF-I
expression in the intestinal mesenchyme without simultaneously altering
circulating IGF-I. This study provides the first in vivo evidence for
paracrine effects of IGF-I on the mucosal epithelium in the murine
ileum. Circulating IGF-I was not altered in SMP8-IGF-I-TG mice,
indicating that these effects reflect the actions of locally derived
IGF-I. Wang et al. (40) have previously shown
that transgene expression in SMP8-IGF-I-TG mice is localized to the
muscularis propria layer of the small intestine. By in situ
hybridization histochemistry, we have localized IGF-I overexpression in
SMP8-IGF-I-TG mice to cells in the pericryptal and midvillus regions of
the lamina propria as well as the muscularis propria in small intestine
and colon. This is an expected but important finding because
-SMA-positive subepithelial myofibroblasts and smooth muscle cells
are known to reside in these regions (31, 32). Intestinal
subepithelial myofibroblasts are particularly important mediators of
growth and differentiation of the intestinal epithelium (31, 32,
37). Expression of the SMP8-IGF-I transgene in subepithelial
cells of the lamina propria places IGF-I overexpression in an ideal
location for potential paracrine growth or differentiative effects on
neighboring epithelial cells. In addition, the pattern of IGF-I
overexpression in the intestine of SMP8-IGF-I-TG mice reflects sites of
documented IGF-I upregulation in models of adaptive intestinal growth
(23, 41, 43, 44). This model was thus ideal for testing
whether IGF-I expressed in the muscularis and lamina propria
mesenchymal cells can exert local actions on growth of intestinal
epithelial or mesenchymal cells.
The observed increase in crypt cell mitoses, sucrase activity, and mucosal mass in the ileum of SMP8-IGF-I-TG mice provides new and definitive evidence that local IGF-I overexpression in intestinal mesenchymal cells has paracrine actions in vivo to stimulate growth of the mucosal epithelium. However, it is intriguing that this paracrine effect was limited to the ileum and was not observed in the jejunum or colon. Several studies have shown that the jejunal and colonic epithelium are capable of responding to IGF-I (11, 23, 30). Thus it is unlikely that the lack of effect of mesenchymal cell-derived IGF-I on the jenunal and colonic epithelia is due to an inability of these tissues to respond to IGF-I. Recent reports in a rat model of jejunoileal resection and subsequent total parenteral nutrition support the concept that endogenous, locally expressed IGF-I may have segment-specific effects on mucosal growth (10, 11). In SMP8-IGF-I-TG mice, transgene expression was lower in the jejunum than in the ileum. However, the colon, which did not exhibit increased mucosal growth, showed higher levels of SMP8-IGF-I transgene expression than the levels observed in the ileum. Thus the specific mucosal growth effect in the ileum of SMP8-IGF-I-TG mice cannot be attributed simply to higher levels of transgene expression.
In the jejunoileal resection model, increased local IGFBP-5 expression within the lamina propria as well as increased local IGF-I expression occurred in those bowel segments that exhibited enhanced mucosal growth (11). IGFBP-5 is known to potentiate IGF-I action in a number of settings (8, 28), and its induction within the lamina propria correlates with growth of intestinal mucosa in response to elevated circulating IGF-I in several models (10, 11, 30). This has led to the concept that coinduction of mucosal IGFBP-5 may be an important determinant of mucosal growth responses to circulating or locally expressed IGF-I (10, 11, 30). Our findings that IGFBP-5 is specifically increased in the villus and pericryptal regions of the ileal lamina propria of SMP8-IGF-I-TG mice support a hypothesis that interaction between transgene-derived IGF-I and locally induced IGFBP-5 may contribute to the specific paracrine actions of IGF-I on the mucosal epithelium in the ileum.
In vitro studies have demonstrated that IGF-I induces IGFBP-5 in enteric smooth muscle cells (45). In vivo studies have reported coinduction of IGF-I and IGFBP-5 in the muscularis propria in models of intestinal inflammation (47). Despite high levels of transgene expression in muscularis layers of SMP8-IGF-I-TG mice, we observed only modest induction of IGFBP-5 in scattered cells within the muscularis propria and no evidence that locally expressed IGF-I induced widespread increases in IGFBP-5 expression within the bulk of the enteric smooth muscle. We cannot exclude the possibility that the transgene induces IGFBP-5 expression at earlier times in development and that feedback responses, such as IGF-I receptor downregulation, prevent maintained increases in IGFBP-5 within the muscularis. Though we cannot definitively identify the IGFBP-5-expressing cells that lie between the circular and longitudinal muscle layers, their location suggests that these cells are likely enteric ganglia, neurons, or interstitial cells of Cajal.
Interestingly, the expression of IGFBP-3, an IGFBP that is known to be induced in the intestine by elevated circulating IGF-I (30), was not increased in SMP8-IGF-I-TG mice relative to WT mice. In vitro studies and in vivo evidence suggest that IGFBP-3 has predominantly inhibitory effects on crypt cell proliferation but may play a role in enterocyte differentiation (15, 26). Sites of expression of IGFBP-3 mRNA in the ileum and colon have not, to our knowledge, been reported previously. It was striking that the highest level of IGFBP-3 expression in the ileum occurred in the midvillus level of the lamina propria, whereas in the colon IGFBP-3 was strongly expressed in the lamina propria adjacent to the midcrypt and surface epithelial cells. These regions correspond to sites of terminal differentiation of enterocytes (3), providing indirect evidence that, in vivo, locally expressed IGFBP-3 may play a role in enterocyte differentiation. It is also worth noting that that, whereas Northern blot hybridization did not reveal a significant increase in IGFBP-3 in any bowel segment of SMP8-IGF-I-TG mice, in situ hybridization provided evidence for increased IGFBP-3 expression in the villus lamina propria of the ileum but not in other bowel segments. Because the ileum also showed increased expression of sucrase, a marker of enterocyte differentiation, this supports the possibility that IGFBP-3 may contribute to the increase in sucrase activity observed in the ileal mucosa of SMP8-IGF-I-TG mice. Although in situ hybridization is not strictly quantitative, it is important to note that it can be useful in situations such as the SMP8-IGF-I-TG mice, where increases in the relative proportion of the muscularis to the mucosa could attenuate any increase in expression of specific mRNAs in the mucosa when assessed by Northern blot on RNA from whole tissue.
Although these studies provide definitive evidence that mesenchymal cell-derived IGF-I can increase growth of ileal mucosal epithelium, these effects were somewhat less potent and more regionally restricted than those observed in other models in which circulating IGF-I is elevated by systemic administration (18, 30, 38) or due to transgene-mediated overexpression of growth hormone (39) or IGF-I (27). Circulating IGF-I was not altered in SMP8-IGF-I-TG mice compared with WT mice and in fact was similar to levels previously observed in WT mice in these other mouse models (27, 39). Together with findings that SMP8-IGF-I-TG mice had dramatic overgrowth of the muscularis layers in all bowel segments, our findings suggest that locally expressed, mesenchymal cell-derived IGF-I exerts less potent and less widespread effects on growth of the mucosal epithelium than circulating IGF-I. In addition, these data support a concept that locally expressed IGF-I derived from intestinal mesenchymal cells may predominantly or most potently regulate growth of the muscularis layers.
The potent mucosal effect of circulating IGF-I seen in other studies (18, 23, 27, 30, 38, 39) may relate to the fact that the mucosa receives a majority of the blood flow in the intestine (7, 19), facilitating potent endocrine actions of blood-borne IGF-I on the mucosa. Indeed, the muscularis and mucosal circulations are arranged in parallel, each branching from common small submucosal arteries and draining into common small veins in the submucosa (14). Thus IGF-I derived from the muscularis propria may not be able to access the mucosal epithelium. However, IGF-I derived from the muscularis mucosa, and particularly that from subepithelial myofibroblasts, would have ready access to vessels supplying the crypt and villus epithelium. Therefore, it is unlikely that the structural arrangement of the intestinal blood supply can entirely explain the modest overgrowth of the intestinal epithelium in SMP8-IGF-I-TG mice.
An alternate possibility for the modest and bowel segment-specific mucosal effect of IGF-I in SMP8-IGF-I-TG mice is that the strong elevation of IGF-I mRNA in the muscularis mucosa and subepithelial myofibroblasts of SMP8-IGF-I-TG mice does not lead to elevations in the encoded IGF-I protein. This could occur if the transgene-derived mRNA is not translated into protein or if the translated protein is degraded. We think these possibilities are unlikely because the potent effects of IGF-I on the muscularis in this model, both in the intestine and in other smooth muscle-rich tissues (40), indicate that the transgene product is translated, biologically active, and available, at least in the muscularis propria. The SMP8-IGF-I transgene encodes an identical precursor to the endogenous IGF-I mRNA (40). We do acknowledge that we have not verified that the encoded precursor or mature IGF-I is increased in the mucosa of SMP8-IGF-I-TG mice in parallel with increased IGF-I mRNA. This is because immunohistochemical quantification and localization of the IGF-I precursor or mature IGF-I in intestinal tissue is technically difficult, possibly because the peptide is rapidly cleared from tissues or is bound to IGFBPs and is not detectable by antibodies (reviewed in Ref. 21).
As well as providing novel evidence about mucosal growth, our studies extend the prior findings of Wang et al. (40) to demonstrate that mesenchymal cell-derived IGF-I can act as a potent autocrine regulator of mass of the muscularis propria throughout the intestine. Increased thickness and length of the muscularis propria and smooth muscle cell hyperplasia have been reported following small bowel resection (25), but adaptive responses in the muscularis layers have been much less studied than mucosal adaptation. Growth of the muscularis can be altered in disease. Decreases in thickness of the muscularis propria are associated with intestinal perforation in infants treated with dexamethasone (13). Interestingly, dexamethasone administration to newborn mice resulted in decreased proliferation of enteric smooth muscle cells, which correlated with decreased IGF-I immunoreactivity in the muscularis propria (12). Our characterization of trophic actions of mesenchymal cell-derived IGF-I on the muscle in the normal intestine provides an important basis for the use of the SMP8-IGF-I-TG mouse model to address the significance of autocrine actions of IGF-I on enteric muscle development and disease. It is clear that overexpression of IGF-I in SMP8-IGF-I-TG mice results in increased length of the intestine as well as increased thickness of the muscularis propria. This raises an intriguing question: what is the relative importance of the muscularis propria vs. the mucosa in determining length of the intestine? Increased length of the small intestine and colon occurs in SMP8-IGF-I-TG mice despite no increases in jejunal or colonic mucosal growth. This indicates that intestinal lengthening accompanies muscularis overgrowth even when there are no associated increases in growth of the mucosa.
It is possible that the intestinal lengthening observed in
SMP8-IGF-I-TG mice is a result of chronic exposure to IGF-I and might
not be seen in situations of acute increases in IGF-I expression in
intestinal mesenchymal cells. In this regard, it would be interesting to develop a model with a cis-inducible element added to the
-SMA promoter to allow assessment of acute, inducible vs. chronic
alterations in IGF-I expression in intestinal mesenchymal cells.
Validation that the SMP8 promoter targets downstream genes to the
appropriate cell types is an important prerequisite to development of
an inducible model.
In conclusion, these studies provide new and conclusive evidence for paracrine effects of mesenchymal cell-derived IGF-I on the intestinal epithelium in vivo. This paracrine effect occurs preferentially in the ileum, whereas potent autocrine effects on muscularis growth occur throughout the intestine. In addition, we conclude that locally expressed, mesenchymal cell-derived IGF-I has distinct actions on intestinal IGFBP expression compared with circulating IGF-I.
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ACKNOWLEDGEMENTS |
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We thank K. McNaughton for assistance with histology and E. Bruton for assistance with radioimmunoassays.
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FOOTNOTES |
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This work was supported by National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) Grant DK-40247 to P. K. Lund. K. L. Williams was supported by a predoctoral fellowship from the Howard Hughes Medical Institute and is currently supported by a postdoctoral fellowship from the SPIRE program at the University of North Carolina, funded by the MORE division of the National Institutes of General Medical Sciences (GM-00678). These studies were facilitated by the molecular histopathology and animal cores of the University of North Carolina Center for Gastrointestinal Biology and Disease (NIDDK P30-DK-34987).
Address for reprint requests and other correspondence: K. L. Williams, Dept. of Medicine, Univ. of North Carolina at Chapel Hill, 763 Burnett-Womack Bldg, CB#7080, Chapel Hill, NC 27599-7080 (E-mail: kristen_williams{at}med.unc.edu).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
June 5, 2002;10.1152/ajpgi.00089.2002
Received 4 March 2002; accepted in final form 3 June 2002.
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