1 Department of Nutritional Sciences, University of Wisconsin-Madison, Madison, Wisconsin 53706; and 2 Department of Cell and Molecular Physiology and Center for Gastrointestinal Biology and Disease, University of North Carolina at Chapel Hill, Chapel Hill, North Carolina 27599
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ABSTRACT |
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Rats maintained with parenteral nutrition following 60% jejunoileal resection plus cecectomy exhibit minimal adaptive growth in the residual jejunum but a dramatic adaptive growth in the residual colon. Coinfusion of insulin-like growth factor I (IGF-I) with parenteral nutrition induces jejunal growth but has minimal effects in the colon. Our objective was to study the role of the endogenous IGF-I system in the differential responses of jejunum and colon to resection and/or IGF-I during parenteral nutrition. We measured concentrations of immunoreactive IGF-I in plasma, jejunum, and colon, IGF-I receptor binding, and levels of IGF receptor, IGF-I, IGF binding protein (IGFBP)-3 and IGFBP-5 mRNA in residual jejunum and colon 7 days after resection and/or IGF-I treatment. IGF-I receptor number was increased (74-99%) in jejunum and colon due to resection; IGF-I mRNA was increased 5-fold in jejunum and 15-fold in colon due to resection. Resection increased circulating IGFBPs but did not alter plasma IGF-I concentration. Resection induced colonic growth in association with significantly greater colonic IGFBP-5 mRNA and significantly lower colonic immunoreactive IGF-I. IGF-I treatment had no significant effect on IGF-I mRNA or IGF-I receptor number. Concentrations of plasma and jejunal immunoreactive IGF-I were significantly increased in rats given IGF-I in association with jejunal growth. IGF-I treatment significantly increased IGFBP-5 mRNA in the jejunum, which also correlated with jejunal growth. Thus resection upregulated IGF-I receptor number and IGF-I mRNA in residual jejunum and colon, but differential adaptation of these segments correlated with differential regulation of IGFBP-5 mRNA.
insulin-like growth factor; binding proteins-3 and -5; intestinal adaptation
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INTRODUCTION |
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INTESTINAL ADAPTATION following resection is characterized by accelerated growth and renewal of the remaining bowel. Luminal nutrients, gastric and pancreatico-billiary secretions, and endogenous gut hormones are thought to regulate intestinal adaptation, but the mechanisms by which these factors induce gut growth are not fully defined. Intestinal adaptation has been studied primarily in enterally fed animal models (12, 13, 15, 28, 33, 34). Little evidence exists that adaptation occurs in humans with short bowel syndrome (SBS) who have large amounts of ileum and colon resected (29). Failure of the intestine to adapt following massive resection in humans may be due to a lack of endogenous growth factors and result in the patient becoming dependent on parenteral nutrition to maintain life.
Exogenous administration of some gut hormones such as glucagon-like peptide 2, growth hormone, and insulin-like growth factor I (IGF-I) have been shown to enhance intestinal adaptation in animals (25, 27, 28, 34). The use of exogenous growth factors to enhance intestinal adaptation in humans with SBS is under investigation. Administration of growth hormone has been used in humans with variable results (3, 24). Improved intestinal adaptation in patients with SBS may reduce the need for parenteral nutrition.
IGF-I is an anabolic peptide hormone with enterotrophic effects on the gut. The liver secretes IGF-I into the circulation in response to growth hormone and is the primary source of plasma IGF-I. In the circulation, the majority of IGF-I is bound to IGF binding proteins (IGFBP) that prolong the half-life of the hormone and modulate the ability of the ligand to bind to its receptor. IGF-I is synthesized in many tissues such as the intestine, where it can act in an autocrine/paracrine fashion. In some reports, increased expression of IGF-I mRNA has been noted in association with resection-induced adaptation in enterally fed rats (15, 34). IGF-I action is mediated via the type 1 IGF-I receptor, a tyrosine kinase receptor with structural homology to the insulin receptor. Type 1 IGF-I receptors are present in substantial amounts in small bowel and colonic mucosa cells (10). In rat models, IGF-I has been shown to enhance intestinal adaptation following resection (12, 15, 28, 34) and reverse intestinal atrophy observed with parenteral feedings (22). Thus IGF-I may support intestinal adaptation both as an endogenously synthesized and an exogenously administered growth factor.
We previously described a unique rat model for human SBS requiring parenteral nutrition that consists of a 60% jejunoileal resection plus cecectomy (6). This model mimics human resection, and adaptive growth may then be measured in both upstream (jejunum) and downstream (colon) segments. In addition, total parenteral nutrition (TPN) is used as rats, like humans after a similar resection, cannot maintain their body weight with enteral feedings. In this model, adaptive growth of the jejunum is minimal (6, 8); however, residual colon shows dramatic adaptive growth in the presence (15) or absence of luminal nutrients (6). Exogenous IGF-I stimulates adaptive growth of the jejunum but has minimal effects in the colon. In the present study, we have used this TPN resection model to study the role of the endogenous IGF-I system in the differential responses of jejunum and colon to resection and/or IGF-I treatment. We evaluated the effects of resection and IGF-I on IGF-I receptor binding and local expression of IGF-I and IGFBPs to determine their association with the differential adaptive growth of jejunum and colon.
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METHODS |
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Animals and experimental design. The University of Wisconsin-Madison Institutional Animal Care and Use Committee approved the animal facilities and protocols. Animal care and experimental design were previously described in detail (6). Briefly, male Sprague-Dawley rats were housed in individual, wire-bottomed, stainless steel cages in a room maintained at 22°C on a 12:12-h light-dark cycle and were randomized into four TPN groups, using a 2 × 2 factorial treatment design: gut resection (R), R + IGF-I (R+I), gut transection [transection (T)], and T + IGF-I (T+I). Animals were adapted to the facility, and 3 days before surgery, they were fed a fiber-free, semielemental liquid diet ad libitum as a bowel preparation (Vital, donated by Ross Labs, Columbus, OH). On the day of surgery, animals were anesthetized with an intraperitoneal injection of 2.5 mg acepromazine (Fermenta Veterinary Products, Kansas City, MO), 75 mg ketamine (Phoenix Pharmacy, St. Joseph, MO), and 0.02 mg atropine/kg body wt (Phoenix Pharmacy) and subjected to surgical procedures as previously described (6). Resected (R) animals had bowel removed beginning at 40 cm distal to the ligament of Trietz up to 1 cm distal to the cecum. Bowel continuity was then restored with an end-to-side jejunocolic anastomosis (6). Transected (T) animals had a transection made at a point 40 cm distal to the ligament of Trietz and at 1 cm distal to the cecum, but the bowel was not removed, and normal continuity was restored by anastomosis. The abdominal incision was closed, and a catheter for delivery of parenteral nutrients was placed in the superior vena cava via the external jugular vein as previously described (11).
All animals received oxymorphone HCl for pain management and prophylactic ampicillin for 48 h after surgery (6). Infusion of TPN solution was initiated, and water was provided ad libitum immediately following surgery (day 0). The composition and preparation of TPN solution were similar to our previous report (6). The infusion rate of the TPN solution was gradually increased from 20 g on day 0 to 40 g on day 1 and 60 g on days 2-6 providing the sole source of nutrition until the end of the experiment. IGF-I-treated animals received 3.0 mg recombinant human IGF-I (rhIGF-I) · kg body wtJejunal and colonic tissue. Small and large intestines were removed and flushed with ice-cold saline. For one-half the animals in each treatment group, the first 15 cm of jejunum distal to the ligament of Trietz were used for receptor-binding studies, the next 12 cm were used for RNA extraction, and the next 2 cm were fixed for histology or in situ hybridization analysis. The procedure was reversed for the other half of the animals to assure no bias due to regional differences in adaptive response. The ~11 cm of colon were divided as follows. For the first one-half of the animals, a 1-cm segment located ~5 cm distal to the anastomosis was fixed for histology, the following 1 cm was fixed for in situ analysis, and the remaining proximal and distal segments were frozen for receptor-binding studies. For the last half of the animals, the first 5 cm distal to the anastomosis were frozen for RNA extraction, and the same 2 cm were fixed for histology and in situ analysis.
Histology. Fixed tissue was paraffin embedded, cut into 5-µm sections, stained with hematoxylin and eosin, and examined for histomorphometry (6). Jejunal villus height and crypt depth were measured on at least 10 villus-crypt axes per animal using SigmaScan software (Jandel Scientific, San Rafael, CA). Colon crypt depth was measured similarly.
Western ligand blot.
Serum levels of IGFBPs were estimated by modified Western ligand
blotting as previously described (9). Briefly, 2 µl of serum were diluted in 20 µl of nonreducing Laemmli sample buffer and
heated to 60°C for 10 min. Samples were then fractionated by 12.5%
SDS-PAGE. Proteins were transferred onto nitrocellulose and probed for
IGFBPs with [125I]IGF-I (Amersham, Arlington Heights,
IL). IGFBPs were visualized by autoradiography at 70°C for 2 days.
A prestained standard (Bio-Rad, Hercules, CA) was used to determine
molecular weight. The band intensities of 38,000-43,000
(corresponding to glycosylated forms of IGFBP-3), 30,000 to 34,000 (IGFBP-1, 2, 4, and 5), and 24,000 (IGFBP-6) were quantified by
scanning densitometry and expressed as optical densitometry units times millimeters.
Immunoreactive IGF-I. Jejunum and colon (100-400 mg) were homogenized in 2 ml of 0.1 M ammonium formate (pH 7.0) and spun at 14,000 g for 15 min. The pellet was reextracted with 0.5 ml 10% formic acid and centrifuged, and the supernatants were combined. A C2 Bond Elut column (Varian, Harbor City, CA) was prewashed with 2 ml methanol and 2 ml 0.1 M ammonium formate. The supernatant was applied to the column then washed with 1 ml 7% acetic acid and 1 ml 20% acetonitrile, 0.1% trifluoroacetic acid (26). Samples were allowed to gravitate through the column; if necessary, minimal vacuum was applied using the Vac Elut (Varian) system. Immunoreactive IGF-I was extracted in 2 ml of 45% acetonitrile, 3% trifluoroacetic acid. An 80-µl fraction was used in the IGF-I assay described previously (18). Recovery of rhIGF-I with 0.5 ml supernatant through the Bond Elut column and IGF-I assay was 94%.
IGF-I receptor-binding studies.
Crude membrane preparations were made from whole jejunal and colonic
tissue by differential centrifugation (17). The protein concentration was determined using the bicinchoninic acid assay (Pierce
Chemical), and the membranes were stored at 70°C. IGF-I binding
studies were performed in triplicate using polyethylene microfuge tubes
as previously described (17). Each tube contained 150 µg
membrane protein and 0.2 ng/ml {3-[125I]iodotyrosyl}
rhIGF-I (Amersham Pharmacia Biotech, Arlington Heights, IL). The
radioligand binding was competed with 0 to 10
6 M rhIGF-I
(Genentech) in a final assay volume of 320 µl/tube. The specificity
of binding to the type 1 IGF-I receptor was confirmed by competing
radiolabeled IGF-I with unlabeled porcine insulin, which was
~300-fold less effective at competing off the IGF-I tracer.
Nonspecific binding was measured in the presence of excess cold ligand
(10
6 M), and total binding was measured in the absence of
cold competitor. Specific binding (the difference of total and
nonspecific binding) was used to determine receptor number
(Ro) and affinity (Kd) by Scatchard analysis with the LIGAND iterative curve fitting program (Biosoft, Ferguson, MO). The data produced linear Scatchard plots that
were best described by a single site model.
Jejunal and colonic IGF-I receptor, IGF-I, IGFBP-3, and IGFBP-5 mRNA. Ribonuclease protection assay (RPA) was used to measure type 1 IGF-I receptor, IGF-I, IGFBP-3, IGFBP-5 mRNA, and 18S ribosomal RNA in both jejunal and colonic tissue. Probes were derived from cDNAs cloned into pGEM series vectors. Plasmids were linearized with the appropriate restriction enzymes and then [32P]UTP antisense RNA probes derived by transcription with SP6 or T7 polymerase (MaxiScript from Ambion, Austin, TX). Dr. M. L. Adamo (San Antonio, TX) kindly provided the IGF receptor, IGF-I, IGFBP-3, and IGFBP-5 vectors.
Total RNA was isolated from frozen jejunum and colon tissue using TRIzol reagent (GIBCO BRL, Gaithersburg, MD). RNA concentration was determined by measuring absorbance at 260 nm; RNA integrity and concentration were confirmed using agarose/formaldehyde electrophoresis. Aliquots of total RNA were coprecipitated with radiolabeled antisense RNA probes as follows: 1) 50 pg (50,000 cpm) IGF receptor and 300 ng (4,000 cpm) 18S probes plus 15 µg jejunal and 12 µg colonic RNA; 2) 50 pg (80,000 cpm) IGF-1 probe plus 30 µg jejunal and 12 µg colonic RNA; 3) 75 pg (100,000 cpm) IGFBP-3 and 25 pg (40,000 cpm) IGFBP-5 probes plus 30 µg jejunal and 12 µg colonic RNA. Probe and tissue RNA were hybridized and single-stranded RNA removed by RNase digestion using the RPA II kit from Ambion according to the manufacturer instructions. Protected bands were separated on an acrylamide/urea gels. Gels were dried and exposed to phosphorimager screens. Each sample was analyzed at least twice in separate RNase protection assays and gels. Sizes of protected bands were 265 nucleotides (nt; IGF receptor), 80 nt (ribosomal 18S), 238 nt (IGF-I mRNA transcribed from the exon I promoter), 550 nt (IGFBP-3), and 300 nt (IGFBP-5). Protected bands were quantified using phosphor imaging (Packard Instrument, Meridan CT). Relative band intensities were calculated by dividing the band intensity in each sample by the mean band intensity in samples from T controls (n = 2-3) applied to each gel. A mean relative intensity for samples from R, R+I, and T+I groups was calculated by averaging the relative intensities of each sample across gels. Variance for the T samples was calculated based on comparison of each T sample to the mean. Statistical analysis assessed the fold difference between groups.In situ hybridization histochemistry.
[35S]UTP antisense and sense probes were prepared by in
vitro transcription of a linearized template as previously described (21, 30). In situ hybridization procedures were as
previously described (21, 30). Briefly, jejunal and
colonic segments were embedded in optimal cutting temperature
(OCT) compound (Miles, Elkhart, IN), frozen in isopentane at 40 to
50°C, and stored at
70°C before sectioning. Frozen
sections collected on poly-L-lysine-coated glass slides
were fixed with 4% paraformaldehyde, washed in phosphate-buffered saline, treated with proteinase K, acetylated by incubation with triethylammonium and acetic anhydride, and dehydrated through graded
alcohols. The slides were air-dried and incubated with 50 µl of
hybridization buffer containing 75% formamide and 1-2 × 106 cpm of labeled RNA probe. Slides were incubated at
55°C for 18 h, treated with RNase, and washed in 0.5 × sodium
chloride-sodium citrate (SSC) at 55°C. Slides were then dehydrated,
air-dried, and exposed to Kodax (Rochester, NY) NTB-2 autoradiographic
emulsion at 4°C for 10-21 days. Slides were developed and
counterstained with Mayer's hematoxylin or hematoxylin and eosin.
Sections were then examined under dark- and light-field illumination.
Statistical analysis.
The independent effects of IGF-I and resection were determined using a
two-way ANOVA to determine main treatment effects (SAS Institute, Cary,
NC). One-way ANOVA and the protected least-significant difference
technique were used to determine individual group differences. Data are
shown as means ± SE, and P 0.05 was considered
statistically significant for all parameters. Statistics were performed
on log-transformed data for jejunal and colonic IGF-I mRNA, IGFBP-5
mRNA, colonic IGFBP-3 mRNA, and colonic immunoreactive IGF-I because
residual plots of these data sets indicated there was an unequal
variance between groups.
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RESULTS |
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Body weight and plasma IGF-I.
After 7 days of treatment, R rats lost weight and weighed significantly
less than the other groups (Fig.
1A). IGF-I treatment attenuated the weight loss in R animals so that there was no difference in body weight gain between R+I and T controls. IGF-I stimulated weight
gain in T rats so that T+I gained significantly more weight than the
other three treatment groups. Weight loss induced by resection and
weight gain induced by IGF-I were similar to our previous report
(6). Resection did not alter plasma IGF-I relative to T
controls, but IGF-I treatment increased plasma IGF-I concentrations twofold in both T and R animals compared with animals not treated with
IGF-I (Fig. 1B).
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Tissue weights and histology.
There was no significant difference in jejunal mucosal wet weight,
jejunal villus height, or crypt depth between T and R rats maintained
with TPN alone (Table 1). In contrast,
colonic wet weight and crypt depth were dramatically increased in R
compared with T rats (Table 1). Jejunal mucosal wet weight, jejunal
villus height, and crypt depth were significantly greater in both R and T rats treated with IGF-I compared with R and T rats not treated with
IGF-I (Table 1). IGF-I treatment did not significantly change colonic
crypt depth of R or T rats, respectively, and had minimal effects on
colonic wet weight. These histology observations are similar to our
previous report (6) demonstrating the differential adaptive growth observed in the jejunum and colon due to IGF-I and
resection, respectively.
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Serum IGFBPs.
R rats had significantly greater IGFBPs in serum compared
with T controls as measured by Western ligand blotting (Fig.
2). Band intensity was significantly
greater for IGFBP-3 at 38-43 kDa (30% increase) and binding
proteins at 30-34 kDa (90% increase) in R rats compared with T
controls. Thus the sum of serum IGFBPs was significantly greater (40%
increase) in R compared with T rats. IGF-I treatment
significantly increased serum IGFBP-3 in T but not in R
rats. However, IGF-I treatment did significantly increase serum IGFBPs
at 30-34 kDa in both R and T rats. Overall, both resection and
IGF-I increased serum IGFBPs, but the effects were not additive. Thus
the magnitude of IGF-I-induced increases in serum IGFBPs was greater in
T compared with R rats.
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Jejunal and colonic immunoreactive IGF-I.
Two-way ANOVA indicates there was no main effect of resection on the
concentration of immunoreactive IGF-I, but there was a significant main
effect of IGF-I treatment to increase jejunal immunoreactive IGF-I
(Fig. 3A, 2-way ANOVA). Thus
the increase in circulating IGF-I due to IGF-I infusion resulted in
jejunal growth and a greater concentration of IGF-I in jejunum compared with rats not given IGF-I. Two-way ANOVA found a significant
interaction between resection and IGF-I treatment on colonic
immunoreactive IGF-I, indicating that IGF-I effects were different in R
compared with T rats (Fig. 3B; 2-way ANOVA). R rats treated
with IGF-I had significantly greater colonic immunoreactive IGF-I than
resection controls, but there was no difference in colonic
immunoreactive IGF-I between T groups (Fig. 3B). R rats not
treated with IGF-I had significantly lower colonic immunoreactive IGF-I
than T controls.
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IGF-I binding studies.
Ro was significantly increased (74-99%) in jejunal
and colonic membranes of R rats compared with T controls (Table
2). Resection with or without IGF-I
treatment significantly increased receptor Kd
~65%, indicating a lower apparent receptor affinity compared with T
controls in both jejunal and colonic membranes (Table 2). IGF-I
treatment did not significantly affect Ro in jejunum or colon of R rats given IGF-I compared with R rats not given IGF-I. Both
jejunal and colonic membranes showed no difference in
Kd or Ro between T rats treated with
IGF-I or vehicle. Overall, resection increased receptor Ro
and Kd compared with T control, but the proportionate increase in Ro is greater than the increase
in Kd, suggesting that resection leads to
increased IGF-I binding capacity in both jejunal and colonic membranes.
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IGF-I receptor mRNA.
Despite increases in Ro due to resection, there were no
significant differences in IGF-I receptor mRNA levels in the jejunum or
the colon between groups (Fig. 4). There
was no difference in jejunal or colonic 18S message between groups as
well, suggesting equal loading of RNA to all wells.
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IGF-I mRNA.
Two-way ANOVA demonstrates a main effect of resection to increase
jejunal IGF-I mRNA (Fig. 5A).
There is a fivefold increase in IGF-I mRNA of both vehicle and
IGF-I-treated R rats compared with T controls. There was no significant
effect of IGF-I treatment on jejunal IGF-I mRNA abundance. Similarly,
there was a main effect of resection to increase colonic IGF-I mRNA
(Fig. 5B). In particular, colonic IGF-I mRNA was elevated
15-fold in vehicle-treated R rats and 4-fold in IGF-I-treated R rats
compared with T controls.
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IGFBP-3 and -5 mRNA.
There was considerable variation in the abundance of IGFBP-3 mRNA and
no statistical difference between groups in either jejunum or colon
(data not shown). Jejunal IGFBP-5 mRNA abundance was not significantly
affected by resection (Fig.
6A). There was a significant
main effect of IGF-I treatment to increase jejunal IGFBP-5 mRNA
abundance. IGFBP-5 mRNA was approximately threefold higher in
IGF-I-treated groups (T+I and R+I) compared with T controls (Fig.
6A). IGF-I-induced increases in IGFBP-5 mRNA correlates with
IGF-I-induced adaptive growth in jejunum of T and R rats treated with
IGF-I. In situ hybridization of jejunal segments showed IGFBP-5 mRNA
localized to both the inner and outer muscularis layers, but there was
no observable difference between treatment groups (Fig.
7A).
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DISCUSSION |
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In our recent report, we described the differential growth pattern in residual jejunum and colon of parenterally fed rats due to resection and/or IGF-I treatment (6). That is, residual jejunum did not adapt structurally or functionally following a 60% jejunoileal resection plus cecectomy. In contrast, the colon showed dramatic adaptive growth following resection. Treatment of R rats with IGF-I induced a significant structural and functional adaptation in the jejunum but had minimal effects on colonic structure and no effect on colonic electrogenic ion transport (6). The changes in body weight and jejunal and colonic morphology in the current report were similar to those observed previously. The primary purpose of this study was to investigate whether alterations in the IGF-I axis in residual jejunum and colon due to resection and/or IGF-I were associated with differential tissue growth.
Resection-induced upregulation of the IGF-I axis has been associated with intestinal adaptive growth in enterally fed rat models (15, 34). The present study confirms and extends these prior findings in a resection model particularly relevant to the human condition. The majority of humans with SBS requiring TPN also have large amounts of ileum and colon removed. Many of these patients are dependent on TPN to maintain their nutritional status because of lack of intestinal adaptation. Our study investigates the changes in the IGF-I axis in a rat resection model in which one tissue (jejunum) does not adapt and one tissue (colon) does adapt following resection.
Resection-induced adaptation. Resection significantly increased both jejunal and colonic IGF-I mRNA, which suggests an upregulation of the IGF-I system in residual bowel. Previous studies in enterally fed rats following an 80% jejunoileal resection observed significant structural adaptation associated with increases in IGF-I mRNA of residual jejunum and ileum (33, 34). In parenterally fed rats, we observed similar increases in jejunal IGF-I mRNA with no structural adaptation. In colon, Mantell et al. (15) observed increased IGF-I mRNA associated with colonic adaptive growth in enterally fed rats following a 60% jejunoileal resection plus cecectomy. We report similar results using the same surgical procedure in parenterally fed rats. Increased IGF-I mRNA following resection did not necessarily correlate with bowel segment adaptive growth, suggesting that increased local IGF-I mRNA alone is not sufficient to induce adaptation. However, the increased jejunal and colonic IGF-I mRNA observed in R rats was not associated with increased jejunal or colonic immunoreactive IGF-I compared with T controls. In both jejunum and colon, increased tissue IGF-I message did not result in increased tissue IGF-I protein. This is most likely due to altered posttranscriptional processing of the message (4).
IGF-I receptor binding studies demonstrate increased IGF-I Ro in both jejunal and colonic membranes following resection, but the increase was most dramatic in the colon. Intestinal mucosal hyperplasia in rats refed following a fast is associated with increased IGF-I binding capacity (Ro) compared with orally fed controls (32). However, parenterally fed rats also have increased IGF-I binding capacity (Ro) compared with orally fed rats, and parenteral nutrition results in intestinal atrophy (17). Thus increased Ro is not always associated with intestinal growth but may be a marker of the potential responsiveness of the intestine to IGF-I. Increased IGF-I Ro was associated with colonic but not jejunal adaptive growth, suggesting that increased IGF-I Ro is not sufficient to induce adaptation. The increase in Ro observed following resection was accompanied by an increase in Kd, indicating a decrease in receptor affinity. Ziegler et al. (32) reported a 50% increase in Kd in rats after 24 h of refeeding compared with orally fed controls. The mechanism by which increased numbers of lower affinity receptors are expressed following resection is unknown, but possible explanations include negative cooperativity of cell surface receptors or increased expression of IGF-I/insulin receptor hybrids (2, 5). Because there was no difference in IGF receptor mRNA between treatment groups, our data suggest the observed increase in IGF-I Ro occurred at a posttranscriptional level. This posttranscriptional regulation may be at the level of translation, protein trafficking, protein stability, and/or inherent binding activity. Resection did not alter serum IGF-I concentration but significantly increased serum IGFBPs. Previous studies also report no change in serum IGF-I concentrations following resection (15, 34), but this is the first report of changes in circulating IGFBPs following resection. As resection caused a 40% increase in circulating IGFBPs but no increase in circulating ligand, the serum IGFBPs may decrease the free endogenous bioactive IGF-I available to IGF-I receptors. Resection increased IGFBP-5 mRNA abundance in colonic but not jejunal tissue. Resection also induced IGFBP-5 expression in colonic mucosa but did not alter localization of IGFBP-5 message in jejunum. IGFBP-5 has been shown to have IGF-I-independent and -dependent growth-promoting effects. A putative IGFBP-5 receptor has been described (1). IGFBP-5 infusion induces osteoblast proliferation in IGF-I knockout mice, suggesting IGFBP-5 has IGF-I-independent growth effects (16, 23). Breast cancer cells incubated with IGFBP-5 are resistant to apoptotic inducers, suggesting IGFBP-5 can inhibit programmed cell death (20). IGFBP-5 has also been shown to promote IGF-I-induced mitogenesis in smooth muscle cells by binding to the extracellular matrix of the cells and acting as an IGF-I reservoir (7, 19). Inflamed and fibrotic intestine from humans undergoing intestinal resection for Crohn's disease has increased IGF-I and IGFBP-5 mRNA compared with normal tissue, suggesting IGFBP-5 modulates cellular proliferation in the intestine (35). Our data in jejunum and colon demonstrate that situations of increased tissue growth are associated with increased local IGFBP-5 expression. Locally expressed IGFBP-5 may have IGF-I-independent and/or -dependent growth effects.IGF-I-induced adaptation. IGF-I treatment has been shown to enhance intestinal adaptation following resection in numerous studies using orally fed models (12, 13, 15, 28, 33, 34). Our study characterizes the effects of IGF-I administration on the local IGF-I axis in the residual bowel of parenterally fed rats.
There was no difference in jejunal or colonic IGF-I mRNA between T rats with or without IGF-I treatment. We previously reported no difference in jejunal IGF-I mRNA between rats fed orally, fed parenterally, or fed parenterally with IGF-I treatment (31). Thus resection but not IGF-I stimulates increased jejunal and colonic IGF-I mRNA expression, strengthening the evidence that resection upregulates the local IGF-I system. IGF-I treatment increased jejunal immunoreactive IGF-I in both R and T rats but increased colonic immunoreactive IGF-I only in R rats. Increased circulating IGF-I resulted in an increase in tissue IGF-I except in the colon of T rats. Significant adaptation of colon in resection controls occurred with a significant decrease in tissue IGF-I levels, suggesting elevated tissue IGF-I is not essential to induce adaptation. IGF-I receptor-binding capacity (Ro) was not decreased in jejunum or colon of R rats treated with IGF-I. This is contrary to our previous observation that IGF-I treatment in parenterally fed rats decreased jejunal IGF-I Ro by 50% (17) and observations in cultured cells that IGF-I typically downregulates its receptor. Resection, therefore, appears to block the IGF-I-induced decrease in IGF-I Ro observed in non-R parenterally fed rats, which may promote increased IGF responsiveness during adaptive growth. Elevated serum IGFBPs with IGF-I treatment occurs concomitantly with a twofold increase in serum IGF-I. We have previously observed an increase in serum IGFBPs in IGF-I- and growth hormone-treated parenterally fed rats (14). Thus the pool of free IGF-I may be higher in R rats given IGF-I even though IGFBPs are also increased. Increased immunoreactive IGF-I in the jejunum of IGF-I-treated rats supports this concept. Both T and R rats treated with IGF-I showed jejunal growth and increased serum IGF-I that was associated with a significantly greater jejunal immunoreactive IGF-I. This suggests that the jejunal growth associated with increased circulating IGF-I is related to increased jejunal levels of IGF-I. IGF-I treatment increased jejunal IGFBP-5 mRNA abundance. We have previously shown that IGF-I treatment in parenterally fed rats increases jejunal mucosal IGFBP-5 mRNA and that IGFBP-5 is localized to the jejunal muscularis and lamina propria (21, 31). Thus the ability of IGF-I to induce jejunal growth is associated with increases in local expression of IGFBP-5 mRNA in both R and non-R parenterally fed rats. In conclusion, resection significantly upregulated the local IGF-I system in both residual jejunum and colon of parenterally fed rats. IGF-I treatment increased both plasma and jejunal IGF-I levels, which were associated with jejunal adaptive growth. In addition, IGFBP-5 mRNA levels best correlate with the tissue growth state. Jejunal IGFBP-5 mRNA was increased in both T and R rats treated with IGF-I compared with rats not treated with IGF-I, and jejunal adaptation was observed in these animals. Colonic IGFBP-5 mRNA was increased in R rats compared with T rats, and colonic adaptation was induced by resection in these animals. We conclude that although resection upregulates the IGF-I system in both residual jejunum and colon, this is not sufficient to induce residual bowel adaptation without parallel increases in tissue IGFBP-5 mRNA. ![]() |
ACKNOWLEDGEMENTS |
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We thank M. Grahn and D. Huss for technical assistance and animal care and J. Kozminski for graphic artistry. We thank C. DaCosta for expert assistance with the in situ analysis.
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FOOTNOTES |
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This work was supported by the National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) Grants RO1-DK-42835 (D. M. Ney), T32-DK-07665 (D. M. Ney), and DK-40247 (P. K. Lund). The work was also supported by funds from the College of Agriculture and Life Sciences, Univ. of Wisconsin-Madison, facilities of the Center for Gastrointestinal Biology and Disease at the Univ. of North Carolina-Chapel Hill, and by NIDDK Grant DK-3487.
Address for reprint requests and other correspondence: D. M. Ney, Dept. of Nutritional Sciences, Univ. of Wisconsin-Madison, 1415 Linden Dr., Madison, WI 53706 (E-mail: ney{at}nutrisci.wisc.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.
Received 7 March 2001; accepted in final form 11 July 2001.
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REFERENCES |
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1.
Andress, DL.
Insulin-like growth factor-binding protein-5 (IGFBP-5) stimulates phosphorylation of the IGFBP-5 receptor.
Am J Physiol Endocrinol Metab
274:
E744-E750,
1998
2.
Bailyes, EM,
Nave BT,
Soos MA,
Orr SR,
Hayward AC,
and
Siddle K.
Insulin receptor/IGF-I receptor hybrids are widely distributed in mammalian tissues: quantification of individual receptor species by selective immunoprecipitation and immunoblotting.
Biochem J
327:
209-215,
1997[ISI][Medline].
3.
Byrne, TA,
Persinger RL,
Young LS,
Ziegler TR,
and
Wilmore DW.
A new treatment for patients with short-bowel syndrome. Growth hormone, glutamine, and a modified diet.
Ann Surg
222:
243-255,
1995[ISI][Medline].
4.
Duguay, SJ.
Post-translational processing of insulin-like growth factors.
Horm Metab Res
31:
43-49,
1999[ISI][Medline].
5.
Federici, M,
Porzio O,
Zucaro L,
Fusco A,
Borboni P,
Lauro D,
and
Sesti G.
Distribution of insulin/insulin-like growth factor-I hybrid receptors in human tissues.
Mol Cell Endocrinol
129:
121-126,
1997[ISI][Medline].
6.
Gillingham, MB,
Dahly EM,
Carey HV,
Clark MD,
Kritsch KR,
and
Ney DM.
Differential jejunal and colonic adaptation due to resection and IGF-I in parenterally fed rats.
Am J Physiol Gastrointest Liver Physiol
278:
G700-G709,
2000
7.
Jones, JI,
Gockerman A,
Busby WH, Jr,
Camacho-Hubner C,
and
Clemmons DR.
Extracellular matrix contains insulin-like growth factor binding protein-5: potentiation of the effects of IGF-I.
J Cell Biol
121:
679-687,
1993[Abstract].
8.
Kripke, SA,
De Paula JA,
Berman JM,
Fox AD,
Rombeau JL,
and
Settle RG.
Experimental short-bowel syndrome: effect of an elemental diet supplemented with short-chain triglycerides.
Am J Clin Nutr
53:
954-962,
1991[Abstract].
9.
Kritsch, KR,
Huss DJ,
and
Ney DM.
Greater potency of IGF-I than IGF-I/BP-3 complex in catabolic parenterally fed rats.
Am J Physiol Endocrinol Metab
278:
E252-E262,
2000
10.
Laburthe, M,
Rouyer-Fessard C,
and
Gammeltoft S.
Receptors for insulin-like growth factors I and II in rat gastrointestinal epithelium.
Am J Physiol Gastrointest Liver Physiol
254:
G457-G462,
1988
11.
Lasekan, JB,
Rivera J,
Hirvonen MD,
Keesey RE,
and
Ney DM.
Energy expenditure in rats maintained with intravenous or intragastric infusion of total parenteral nutrition solutions containing medium- or long-chain triglyceride emulsions.
J Nutr
122:
1483-1492,
1992[ISI][Medline].
12.
Lemmey, AB,
Ballard FJ,
Martin AA,
Tomas FM,
Howarth GS,
and
Read LC.
Treatment with IGF-I peptides improves function of the remnant gut following small bowel resection in rats.
Growth Factors
10:
243-252,
1994[ISI][Medline].
13.
Lemmey, AB,
Martin AA,
Read LC,
Tomas FM,
Owens PC,
and
Ballard FJ.
IGF-I and the truncated analogue des-(1-3)IGF-I enhance growth in rats after gut resection.
Am J Physiol Endocrinol Metab
260:
E213-E219,
1991
14.
Lo, HC,
Hinton PS,
Peterson CA,
and
Ney DM.
Simultaneous treatment with IGF-I and GH additively increases anabolism in parenterally fed rats.
Am J Physiol Endocrinol Metab
269:
E368-E376,
1995
15.
Mantell, MP,
Ziegler TR,
Adamson WT,
Roth JA,
Zhang W,
Frankel W,
Bain A,
Chow JC,
Smith RJ,
and
Rombeau JL.
Resection-induced colonic adaptation is augmented by IGF-I and associated with upregulation of colonic IGF-I mRNA.
Am J Physiol Gastrointest Liver Physiol
269:
G974-G980,
1995
16.
Miyakoshi, N,
Richman C,
Kasukawa Y,
Linkhart TA,
Baylink DJ,
and
Mohan S.
Evidence that IGF-binding protein-5 functions as a growth factor.
J Clin Invest
107:
73-81,
2001
17.
Ney, DM,
Huss DJ,
Gillingham MB,
Kritsch KR,
Dahly EM,
Talamantez JL,
and
Adamo ML.
Investigation of insulin-like growth factor (IGF)-I and insulin receptor binding and expression in jejunum of parenterally fed rats treated with IGF-I or growth hormone.
Endocrinology
140:
4850-4860,
1999
18.
Ney, DM,
Yang H,
Smith SM,
and
Unterman TG.
High-calorie total parenteral nutrition reduces hepatic insulin-like growth factor-I mRNA and alters serum levels of insulin-like growth factor-binding protein-1, -3, -5, and -6 in the rat.
Metabolism
44:
152-160,
1995[ISI][Medline].
19.
Parker, A,
Rees C,
Clarke J,
Busby WH, Jr,
and
Clemmons DR.
Binding of insulin-like growth factor (IGF)-binding protein-5 to smooth-muscle cell extracellular matrix is a major determinant of the cellular response to IGF-I.
Mol Biol Cell
9:
2383-2392,
1998
20.
Perks, CM,
McCaig C,
and
Holly JM.
Differential insulin-like growth factor (IGF)-independent interactions of IGF binding protein-3 and IGF binding protein-5 on apoptosis in human breast cancer cells. Involvement of the mitochondria.
J Cell Biochem
80:
248-258,
2000[ISI][Medline].
21.
Peterson, CA,
Gillingham MB,
Mohapatra NK,
Dahly EM,
Adamo ML,
Carey HV,
Lund PK,
and
Ney DM.
Enterotrophic effect of insulin-like growth factor-I but not growth hormone and localized expression of insulin-like growth factor-I, insulin-like growth factor binding protein-3 and -5 mRNAs in jejunum of parenterally-fed rats.
J Parenteral Enteral Nutr.
24:
288-295,
2000[Abstract].
22.
Peterson, CA,
Ney DM,
Hinton PS,
and
Carey HV.
Beneficial effects of insulin-like growth factor I on epithelial structure and function in parenterally fed rat jejunum.
Gastroenterology
111:
1501-1508,
1996[ISI][Medline].
23.
Richman, C,
Baylink DJ,
Lang K,
Dony C,
and
Mohan S.
Recombinant human insulin-like growth factor-binding protein-5 stimulates bone formation parameters in vitro and in vivo.
Endocrinology
140:
4699-4705,
1999
24.
Scolapio, JS,
Camilleri M,
Fleming CR,
Oenning LV,
Burton DD,
Sebo TJ,
Batts KP,
and
Kelly DG.
Effect of growth hormone, glutamine, and diet on adaptation in short-bowel syndrome: a randomized, controlled study.
Gastroenterology
113:
1074-1081,
1997[ISI][Medline].
25.
Scott, RB,
Kirk D,
MacNaughton WK,
and
Meddings JB.
GLP-2 augments the adaptive response to massive intestinal resection in rat.
Am J Physiol Gastrointest Liver Physiol
275:
G911-G921,
1998
26.
Shambaugh, GE, 3rd,
Natarajan N,
Davenport ML,
Oehler D,
and
Unterman T.
Nutritional insult and recovery in the neonatal rat cerebellum: insulin-like growth factors (IGFs) and their binding proteins (IGFBPs).
Neurochem Res
20:
475-490,
1995[ISI][Medline].
27.
Shulman, DI,
Hu CS,
Duckett G,
and
Lavallee-Grey M.
Effects of short-term growth hormone therapy in rats undergoing 75% small intestinal resection.
J Pediatr Gastroenterol Nutr
14:
3-11,
1992[ISI][Medline].
28.
Vanderhoof, JA,
McCusker RH,
Clark R,
Mohammadpour H,
Blackwood DJ,
Harty RF,
and
Park JH.
Truncated and native insulin-like growth factor I enhance mucosal adaptation after jejunoileal resection.
Gastroenterology
102:
1949-1956,
1992[ISI][Medline].
29.
Wilmore, DW.
Growth factors and nutrients in the short bowel syndrome.
J Parenter Enteral Nutr
23, Suppl 5:
S117-S120,
1999[Medline].
30.
Winesett, DE,
Ulshen MH,
Hoyt EC,
Mohapatra NK,
Fuller CR,
and
Lund PK.
Regulation and localization of the insulin-like growth factor system in small bowel during altered nutrient status.
Am J Physiol Gastrointest Liver Physiol
268:
G631-G640,
1995
31.
Yang, H,
Ney DM,
Peterson CA,
Lo HC,
Carey HV,
and
Adamo ML.
Stimulation of intestinal growth is associated with increased insulin- like growth factor-binding protein 5 mRNA in the jejunal mucosa of insulin-like growth factor-I-treated parenterally fed rats.
Proc Soc Exp Biol Med
216:
438-445,
1997[Abstract].
32.
Ziegler, TR,
Almahfouz A,
Pedrini MT,
and
Smith RJ.
A comparison of rat small intestinal insulin and insulin-like growth factor I receptors during fasting and refeeding.
Endocrinology
136:
5148-5154,
1995[Abstract].
33.
Ziegler, TR,
Mantell MP,
Chow JC,
Rombeau JL,
and
Smith RJ.
Gut adaptation and the insulin-like growth factor system: regulation by glutamine and IGF-I administration.
Am J Physiol Gastrointest Liver Physiol
271:
G866-G875,
1996
34.
Ziegler, TR,
Mantell MP,
Chow JC,
Rombeau JL,
and
Smith RJ.
Intestinal adaptation after extensive small bowel resection: differential changes in growth and insulin-like growth factor system messenger ribonucleic acids in jejunum and ileum.
Endocrinology
139:
3119-3126,
1998[ISI][Medline].
35.
Zimmermann, EM,
Li L,
Hou YT,
Mohapatra NK,
and
Pucilowska JB.
Insulin-like growth factor I and insulin-like growth factor binding protein 5 in Crohn's disease.
Am J Physiol Gastrointest Liver Physiol
280:
G1022-G1029,
2001