Nucleotide sequence of the bovine growth hormone chromosomal gene.

A library of cloned bovine DNA fragments was constructed and screened for growth hormone sequences. The growth hormone gene was isolated from this library and its nucleotide sequence determined. The likely transcription initiation site was located using the S1 nuclease protection procedure. The bovine growth hormone gene contains approximately 1793 nucleotides and consists of five exons separated by four intervening sequences. The sequence TATAAA is found in the 5' flanking region and probably is involved in facilitating transcription initiation. Comparison of the bovine growth hormone gene to the known sequence of the rat and human genes reveals that the coding regions of the three genes are highly conserved. In general the intervening sequences are much less similar than the coding regions. Interestingly, all three growth hormone genes share a conserved (but nonidentical) 40 base pair region within the 5' flanking region. This conserved region may be an important sequence involved in the hormonal regulation of growth hormone gene transcription. Analysis of GH sequences present in total bovine DNA suggests that the bovine genome contains a gene similar to the cloned gene as well as a different, but related, gene. The functional significance of the two genes remains to be explored. Analysis of nuclear species of growth hormone mRNA has demonstrated the presence of RNAs of 2100, 1400 and 1000 nucleotides containing growth hormone sequences. These likely correspond to a polyadenylated primary transcript, a processing intermediate and mature growth hormone mRNA, respectively.

Epidermal growth factor is critical for intestinal adaptation following small bowel resection.

The loss of small intestinal mucosal surface area is a relatively common clinical situation seen in both the pediatric and adult population. The most frequent causes include mesenteric ischemia, trauma, inflammatory bowel disease, necrotizing enterocolitis, and volvulus. Following surgical resection, the remnant intestine compensates or adapts to the loss of native bowel by increasing its absorptive surface area and functional capacity. Unfortunately, many patients fail to adapt adequately, and are relegated to lifelong intravenous nutrition. Research into intestinal adaptation following small bowel resection (SBR) has evolved only recently from the gross and microscopic level to the biochemical and genetic level. As understanding of this process has increased, numerous therapeutic strategies to augment adaptation have been proposed. Epidermal growth factor (EGF) is an endogenous peptide that is secreted into the gastrointestinal tract and able to influence gut ontogeny, as well as mucosal healing. Early studies have demonstrated its ability to augment the adaptive process. Focusing on a murine model of massive intestinal loss, the morphological, structural, biochemical, and genetic changes that occur during the intestinal adaptive process will be reviewed. The role of EGF and its receptor as critical mediators of the adaptive process will be discussed. Additionally, the ability of EGF to augment intestinal proliferation and diminish programmed cell death (apoptosis) following SBR will be examined. Enhancing adaptation in a controlled manner may allow patients to transition off parenteral nutrition to enteral feeding and, thereby, normalize their lifestyle.

Adaptation after small bowel resection is attenuated by sialoadenectomy: the role for endogenous epidermal growth factor.

BACKGROUND: Epidermal growth factor (EGF) is likely involved during adaptation after small bowel resection (SBR) because some studies have shown enhanced adaptation by EGF administration. Because the major source of endogenous EGF in mice is the submandibular glands, we sought to determine the effect of submandibular gland excision (SAL) and luminal or systemic EGF replacement on adaptation after SBR. METHODS: A 50% proximal SBR or Sham-SBR (bowel transection and reanastomosis) was performed on male C57BL/6 mice after either SAL or gland mobilization only. Additional mice underwent both SBR and SAL and then received daily EGF or saline solution by intraperitoneal or orogastric administration. At 1 week, adaptation was characterized in the ileum as changes in villus height, DNA, and protein content. RESULTS: SAL significantly attenuated the increase in ileal villus height, total protein, and DNA content after SBR. Both systemic and oral EGF reversed these findings equally and significantly augmented all parameters of intestinal adaptation after SAL. CONCLUSIONS: Submandibular EGF is important for the adaptive response to massive SBR. As both luminal and systemic EGF equally reversed the findings following SAL and SBR, the specific site of action for endogenous EGF during adaptation is either the luminal or basolateral surface of the enterocyte.

Bax is required for increased enterocyte apoptosis after massive small bowel resection.

BACKGROUND: Massive small bowel resection (SBR) increases rates of both enterocyte proliferation and apoptosis. Previous studies have demonstrated increased intestinal expression of proapoptotic bax mRNA and protein, as well as the appearance of an 18-kd bax cleavage product within 12 hours of SBR. This study tested the hypothesis that bax is required for postresection increases in enterocyte apoptosis. METHODS: Male bax-null and C57Bl/6 (control) mice underwent either a 50% proximal SBR or sham operation. After 3 days, the remnant ileum was harvested and weighed. Apoptotic indexes, proliferation indexes, villus heights, and crypt depths were determined. RESULTS: The usual adaptive increases in ileal wet weight, crypt depth, and rate of proliferation occurred in both the control and bax-null mice. Resection significantly increased the rate of apoptosis in the control mice; however, it failed to alter the apoptotic index in the bax-null mice. CONCLUSIONS: Bax is necessary for the increase in apoptosis that occurs after SBR, but its absence has no significant effect on short-term adaptation. These findings suggest that enterocyte proliferation and apoptosis are differentially regulated during intestinal adaptation.

Intestinal adaptation following massive small bowel resection in the mouse.

BACKGROUND: Transgenic mice represent powerful tools for studying the role of genes and their expression under multiple conditions, and they may provide a unique model for studies of intestinal adaptation after massive small bowel resection (SBR). This study characterized a successful model for SBR and intestinal adaptation in the mouse. STUDY DESIGN: Sham operation (bowel transection with reanastomosis) or SBR was performed on male C57BL/6 mice. A solid or liquid diet, various sizes of monofilament suture for the anastomosis, and resection of 50 or 75 percent of the proximal small intestine were studied. In other studies, intestinal adaptation was characterized as changes in intestinal wet weight, DNA, protein, villus height, crypt depth, and crypt cell proliferation rates at 12 hours, 24 hours, three days, and one, two, and four weeks after 50 percent SBR. RESULTS: Survival was significantly improved with a liquid diet (8 percent compared with 88 percent; p < .001) and modestly improved by using the smallest suture for anastomosis (60 percent for 7-0 compared with 88 percent for 9-0; p = not significant). Mice did not tolerate more than 50 percent SBR (16 percent survival rate for 75 percent SBR compared with 85 percent survival rate for 50 percent SBR; p < .01). Small bowel resection augmented ileal wet weight, DNA and protein content, villus height, crypt depth, and crypt-cell proliferation rates. CONCLUSIONS: Provision of a liquid diet, using a small suture for anastomosis, and resection of no more than 50 percent of the proximal small intestine are important for survival. This model will permit researchers using transgenic mice to better understand critical genes during intestinal adaptation after SBR.

Enterocyte apoptosis is increased following small bowel resection.

The intestinal mucosa is in a steady state of turnover as the rate of cellular proliferation is balanced by the rate of cell death. Although it is accepted that adaptation after small bowel resection (SBR) results in increased proliferation, its effect on apoptosis is not known. The purpose of this study was to determine the effect of adaptation following SBR on rates of enterocyte apoptosis. Male ICR mice underwent either 50% proximal SBR or sham operation (bowel transection/reanastomosis). After 12 and 24 hours, and 3 and 7 days, rates of proliferation were measured in the ileum as the percentage of crypt cells incorporating bromodeoxyuridine. Apoptosis was quantiated by end labeling of DNA strand breaks and propidium iodide staining of the number of apoptotic bodies per crypt and villus. Significant increases in enterocyte proliferation (30% to 40%) as well as apoptosis (57% to 87%) occurred at all time points following SBR when compared with sham-operated mice. Adaptation following SBR increases both the rate of enterocytc proliferation and the rate of apoptosis. Understanding the pathophysiology of intestinal adaptation and therapeutic interventions designed to augment this important response will require complete characterization of their effects on both proliferation and apoptosis.

Effect of massive small bowel resection on the Bax/Bcl-w ratio and enterocyte apoptosis.

Following small bowel resection (SBR), the remnant intestine undergoes adaptation. Enterocyte proliferation is increased and counterbalanced by increased rates of apoptosis. To elucidate a mechanism for increased enterocyte apoptosis, this study tested the hypothesis that the ratio between pro-apoptotic Bax and pro-survival Bcl-w correlates with the apoptosis that occurs following SBR. Mice (C57Bl/6; n = 76) underwent a 50% proximal SBR or sham operation. After 12 hours and 1, 2, 3, and 7 days, the ileum was removed, the apoptotic index (apoptotic bodies/crypt) was recorded, and the messenger RNA and protein for Bax and Bcl-w were quantified. The apoptotic index was equivalent in the sham and SBR mice at 12 hours; however, it was significantly elevated following SBR at every other day measured. The ratio of Bax to Bcl-w messenger RNA relative to sham operation increased after SBR at 24 hours, decreased by day 3, and returned to baseline levels by 1 week. The protein ratio showed an increase by day 1, which remained elevated through day 7. An augmented ratio of Bax to Bcl-w messenger RNA and protein corresponded with the increase in enterocyte apoptosis. Alterations in the expression ratio of these genes may play a role in establishing a new homeostatic set point between proliferation and apoptosis during adaptation.

Analysis of intestinal adaptation gene expression by cDNA expression arrays.

BACKGROUND: As a tool for determining gene expression on a genomic scale, cDNA microarrays are a promising new technology that can be applied to the study of complex physiologic processes. The objective of this study was to characterize the expression of individual genes and patterns of gene expression that might provide insight into the mechanism of intestinal adaptation after massive small bowel resection. METHODS: Male ICR mice underwent a 50% proximal small bowel resection (SBR) or sham operation. After 3 days, the remnant ileum was harvested, weighed, and RNA extracted. Changes in gene expression were detected utilizing Clontech Atlas mouse cDNA expression arrays. Some of these changes were confirmed by reverse transcriptase-polymerase chain reactions (RT-PCR) and Northern blots. RESULTS: Analysis of these cDNA arrays revealed changes in the expression of multiple genes, including those involved in cell cycle regulation, apoptosis, DNA synthesis, and transcriptional regulation. The patterns of expression were consistent with the increased cell proliferation and apoptosis observed during intestinal adaptation. A large number of genes not previously associated with intestinal adaptation were identified. CONCLUSIONS: This technology may facilitate the elucidation of the intricate cellular mechanisms underlying intestinal adaptation.

Diminished epidermal growth factor levels in infants with necrotizing enterocolitis.

BACKGROUND/PURPOSE: Because epidermal growth factor (EGF) is trophic to the intestinal mucosa, and neonatal necrotizing enterocolitis (NEC) is associated with a disrupted intestinal mucosal barrier, the authors sought to determine whether diminished levels of EGF were present in infants with NEC. METHODS: Saliva, serum, and urine specimens were obtained from infants with NEC during a 3-year period (February 1995 to May 1998). Control patients without NEC were chosen based on similar postnatal age and birthweight. EGF levels were determined by enzyme-linked immunosorbent assay (ELISA). Differences between groups were compared using Mann-Whitney Rank sum test with P less than .05 considered significant. Results are presented as mean values +/-SEM. RESULTS: Twenty-five infants with NEC were compared with 19 control patients. Birth weight (1,616+/-238 g control v. 1,271+/-124 g NEC) and postnatal age (23+/-6 days control v. 22+/-3 days NEC) were similar. Infants with NEC had significantly lower levels of EGF in both saliva (590+/-80 pg/mL control v. 239+/-41 pg/mL NEC; P<.001) and serum (35+/-8 pg/mL control v. 5.6+/-1.9 pg/mL NEC; P<.001). Urinary EGF was also lower in the NEC group, but was not statistically significant. CONCLUSIONS: Premature infants with NEC have significantly diminished levels of salivary and serum EGF. Reduced levels of this growth factor may distinguish infants at risk for NEC and play a pivotal role in the pathogenesis of the perturbed intestinal mucosal barrier that is central to this condition.

Intestinal adaptation occurs independent of transforming growth factor-alpha.

BACKGROUND/PURPOSE: Signal transduction via the epidermal growth factor receptor (EGFR) is critical for intestinal adaptation after massive small bowel resection (SBR). Although it has been assumed that the major ligand for the EGFR during adaptation is EGF, the role for transforming growth factor-alpha (TGF-alpha), another major ligand for the EGFR is unknown. The purpose of this study was to test the hypothesis that TGF-alpha is an important ligand for the EGFR during intestinal adaptation. METHODS: Wild-type mice (C57BI/6) underwent a 50% proximal SBR or sham operation (bowel transection or reanastomosis) and were then assigned randomly to receive either intraperitoneal TGF-alpha or placebo. In a separate experiment, SBR or sham operations were performed in mice lacking TGF-alpha (Waved-1). After 3 days, adaptation was measured in the ileum. RESULTS: Exogenous TGF-alpha enhanced intestinal adaptation in the wild-type mice after SBR as shown by increased ileal wet weight and DNA content. Normal adaptation occurred in the mice lacking TGF-alpha as shown by increased ileal wet weight, protein and DNA content, proliferation, villus height, and crypt depth. CONCLUSIONS: Although exogenous TGF-alpha enhanced adaptation after massive SBR, adaptation was preserved in TGF-alpha-absent mice. These results refute TGF-alpha as an essential ligand for EGFR signaling during intestinal adaptation.

The distribution of endogenous epidermal growth factor after small bowel resection suggests increased intestinal utilization during adaptation.

BACKGROUND/PURPOSE: Although exogenous epidermal growth factor (EGF) amplifies adaptation after massive small bowel resection (SBR), the role for endogenous EGF is unclear. The authors sought to determine whether SBR was associated with changes in the levels of EGF in the serum, saliva, or urine and EGF receptor (EGF-R) signaling in the ileum. METHODS: Male ICR mice underwent 50% proximal SBR or sham surgery bowel transection/reanastomosis). After 3 days, levels of EGF were measured by enzyme-linked immunosorbent assay (ELISA) in the serum, saliva, and urine. EGF-R activation was measured in isolated ileal enterocytes by probing an EGF-R immunoprecipitate with an antibody to phosphotyrosine. RESULTS: When compared with sham, SBR resulted in no change in serum, increased salivary (2209+/-266 nmol SBR v 1183+/-119 nmol sham, P<.05) and decreased urinary (417+/-58 nmol SBR v 940+/-143 nmol sham; P<.05) EGF levels. EGF-R activation increased 2.5-fold after SBR. CONCLUSIONS: Increased salivary and reduced urinary EGF linked with enhanced EGF-R activation suggests increased ileal utilization of EGF during adaptation. This observation, along with the known beneficial effects of exogenous EGF, infers a crucial role for endogenous EGF in the pathogenesis of intestinal adaptation after SBR.

The effect of epidermal growth factor on differentiation of isolated enterocytes after small bowel resection.

BACKGROUND/PURPOSE: In previous studies using mucosal scrapings or whole-bowel homogenates, epidermal growth factor (EGF) augments adaptation after massive small bowel resection (SBR). The purpose of this study was to determine directly the effect of adaptation and EGF on enterocyte differentiation using an explicit enterocyte cell population. METHODS: Male ICR mice underwent 50% proximal SBR or sham (bowel transection-reanastomosis) and were selected randomly to either orogastric saline or EGF (50 microg/kg/d). After 3 days, enterocytes were isolated from the remnant ileum by mechanical vibration and assayed for DNA and protein content as well as sucrase and alkaline phosphatase (AlkP) activity. RESULTS: Ileal wet weight, enterocyte protein, and DNA content were increased significantly after SBR and boosted even further with EGF. When normalized for protein, SBR caused an increase in AlkP and sucrase activity, and EGF treatment caused AlkP and sucrase activity to return to baseline. CONCLUSIONS: EGF enhances adaptation; however, when normalized for protein, the activity of two enterocyte-specific enzymes was not significantly altered by EGF. This analysis of an explicit enterocyte population supports the notion that the beneficial effects of EGF are more likely caused by increased numbers of enterocytes rather than an increase in the functional activity of each individual cell.

The expression and activation of EGF and c-NEU receptors are increased in enterocytes during intestinal adaptation.

BACKGROUND/PURPOSE: After massive small bowel resection (SBR), epidermal growth factor (EGF) and its intestinal receptor (EGF-R) play major roles during adaptation. The expression of a homologous enterocyte receptor termed c-neu (c-neu-R) is capable of forming heterodimers with EGF-R to facilitate cellular signaling. The purpose of this study was to determine the expression and activation of EGF-R and c-neu-R during the adaptive intestinal response to SBR. METHODS: Male ICR mice underwent either SBR or sham surgery. After 1, 3, and 7 days, enterocytes were isolated and protein immunoprecipitated with antibody to either EGF-R or c-neu-R. Receptor protein expression and activation status were determined. RESULTS: When compared with sham operation, the expression and activation status of both EGF-R (six- and twofold, respectively) and c-neu-R (nine- and twofold, respectively) were increased substantially in enterocytes from the adapting ileum after SBR by postoperative day 3. Minimal changes were appreciated for either EGF-R or c-neu-R expression or activation in the remnant bowel after enterocyte removal, liver, or kidney. CONCLUSIONS: Both the expression and activation status of EGF-R and c-neu-R are increased substantially in enterocytes from the adapting ileum by postoperative day 3 after massive SBR. These changes provide a unique mechanism for the enterocyte to enhance cellular signaling in response to EGF during intestinal adaptation.

The adaptive intestinal response to massive enterectomy is preserved in c-SRC-deficient mice.

BACKGROUND/PURPOSE: The Src family of protein tyrosine kinases has been implicated in the downstream mitogenic signaling of several ligands including epidermal growth factor (EGF). Because EGF likely plays a role in adaptation after massive small bowel resection (SBR), we tested the hypothesis that c-src is required for this important response. METHODS: A 50% proximal SBR or sham operation (bowel transection or reanastomosis alone) was performed on c-src-deficient (n = 14) or wild-type (C57bl/6) mice (n = 20). The ileum was harvested on postoperative day 3 and adaptive parameters determined as changes in ileal wet weight, protein and DNA content, proliferation index, villus height, and crypt depth. Comparisons were done using analysis of variance (ANOVA), and a Pvalue less than .05 was considered significant. Values are presented as mean +/- SEM. RESULTS: The activity of c-src was increased in the ileum of wild-type mice after SBR but remained unchanged in c-src-deficient mice. Despite this lack of increase, adaptation occurred after SBR in the c-src-deficient mice as demonstrated by increased ileal wet weight, protein and DNA content, proliferation index, villus height, and crypt depth similar to wild-type mice. CONCLUSIONS: The adaptive response of the intestine to massive SBR is preserved despite reduced activity of the c-src protein. The mitogenic signaling that characterizes intestinal adaptation and is associated with receptor activation by EGF or other growth factors probably occurs by mechanisms independent of c-src protein tyrosine kinase.

Intestinal adaptation is enhanced by epidermal growth factor independent of increased ileal epidermal growth factor receptor expression.

BACKGROUND/PURPOSE: Intestinal adaptation after massive small bowel resection (SBR) is augmented by epidermal growth factor (EGF) via an unknown mechanism. We recently have observed that EGF increases the expression of EGF receptor mRNA and protein content in the remnant ileum after SBR. The purpose of this study was to determine whether the magnitude of EGF-induced receptor expression correlates with intestinal adaptation. METHODS: A 50% proximal SBR or sham operation (bowel transection with reanastomosis) was performed on male ICR mice. Animals from each group were then selected randomly to receive either human recombinant EGF (150 microg/kg/d) or saline by twice daily intraperitoneal injections. The remnant ileum was harvested at 1 week, and parameters of adaptation measured as changes in protein content. Ileal EGF receptor mRNA was quantitated using a ribonuclease protection assay. Changes in the expression ileal EGF receptor protein were determined by Western blot after immunoprecipitation. Comparisons of mean values between groups was performed using analysis of variance (ANOVA) and a P value of less than .05 was considered significant. Values are presented as mean +/- SEM. RESULTS: EGF was mitogenic to the ileum after sham operation as monitored by increases in ileal protein content (2.21 +/- 0.002 mg/cm Sham v 2.97 +/- 0.25 mg/cm Sham +/- EGF; P < .05). After SBR, adaptation resulted in increased ileal protein content (4.45 +/- 0.27 mg/cm), which was substantially boosted by EGF (5.98 +/- 0.39 mg/cm; P < .05). No differences were detected in ileal EGF receptor mRNA or protein expression between Sham or SBR groups that did not receive EGF. However, EGF significantly enhanced the expression of ileal EGF receptor mRNA to an equal extent after both sham and SBR (approximately threefold). The magnitude of this increase in EGF receptor protein (four- to sixfold) was similar in both EGF groups as shown by Western blotting. CONCLUSIONS: Changes in ileal EGF receptor expression are not mandatory for adaptation to occur. EGF upregulates the expression of mRNA and protein for its own intestinal receptor in vivo. Because EGF-induced receptor expression was comparable after both SBR and Sham operation, the beneficial effect of EGF during adaptation is likely caused by other factors in addition to increased receptor expression.

Epidermal growth factor upregulates the expression of its own intestinal receptor after small bowel resection.

BACKGROUND/PURPOSE: Epidermal growth factor (EGF) binds to its enterocyte receptor and enhances intestinal adaptation after massive small bowel resection (SBR). To ascertain the mechanism for enhanced adaptation by EGF, we sought to determine the effect of EGF administration on in vivo expression of the intestinal EGF receptor after SBR. METHODS: Male ICR mice underwent a 50% proximal SBR and then were assigned randomly to EGF (150 microg/kg/d) or saline by twice daily intraperitoneal injection. After 3 days, the ileum was harvested and total protein and DNA content were measured. Northern hybridization and a ribonuclease protection assay were used to detect qualitative and quantitative expression of EGF receptor mRNA. The remaining ileum was pooled for each group and Western blotting used to determine expression of EGF receptor protein. RESULTS: EGF augmented adaptation after SBR as monitored by significant increases in ileal protein (2.7+/-0.08 saline versus 3.9+/-0.17 mg/cm EGF; P<.001) and DNA (55.8+/-1.6 saline versus 104+/-8.4 microg/cm EGF; P<.001) content. Northern blotting results showed a marked (>fivefold) increase in ileal EGF receptor mRNA, which was confirmed with the ribonuclease protection assay. Administration of EGF after SBR induced a similar expression of EGF receptor protein. CONCLUSIONS: EGF enhanced intestinal adaptation after SBR. This augmented response is associated with increased ileal expression of EGF receptor mRNA and protein. Increased EGF receptor expression and subsequent enhanced ligand/ receptor activity may be one important mechanism for the beneficial effect of EGF administration during intestinal adaptation.

Serum from mice after small bowel resection enhances intestinal epithelial cell growth.

BACKGROUND/PURPOSE: The adaptive response of the intestine to massive small bowel resection (SBR) is remarkably complex. An in vitro model of adaptation may facilitate the elucidation of signaling pathways involved in this process. In an effort to establish such a model, the effects of serum from resected mice on cultured intestinal epithelial cells were studied. METHODS: Serum was collected and pooled from male ICR mice 3 days after either 50% SBR or sham operation. Rat intestinal epithelial cells (RIEC-6) were plated at equal density and grown in the presence of 1% fetal bovine serum (FBS), 10% FBS, 1% FBS plus 9% sham serum, or 1% FBS plus 9% SBR serum. Cell number, proliferation, and caspase-3 activity were determined. RESULTS: RIEC-6 cell growth was reduced significantly in 1% FBS or sham serum. SBR serum markedly accelerated cell growth and proliferation when compared with all other groups and significantly suppressed caspase-3 activity. CONCLUSIONS: Massive intestinal resection in mice results in a serum factor that induces intestinal cell growth in vitro. This in vitro model of trophic signaling will permit further detailed investigations into the mechanisms of intestinal adaptation.

cDNA microarray analysis of adapting bowel after intestinal resection.

BACKGROUND/PURPOSE: Studies of the genetic regulation of various physiologic processes have been hampered by methodologies that are limited to the analysis of individual genes. The advent of cDNA microarray technology has permitted the simultaneous screening of numerous genes for alterations in expression. In this study, cDNA microarrays were used to evaluate gene expression changes during the intestinal adaptive response to massive small bowel resection (SBR). METHODS: Male ICR mice (n = 20) underwent either a 50% SBR or sham operation and then were given either orogastric epidermal growth factor (EGF, 50 microg/kg/d) or saline. After 3 days, cDNA microarray analysis was performed on mRNA extracted from the remnant ileum. RESULTS: From over 8,700 different genes, the array identified 27 genes that were altered 2-fold or greater after SBR. Small proline-rich protein 2 (sprr2), the gene with the greatest expression change (4.9-fold), was further upregulated by EGF. This gene has never been characterized in the intestine or described in intestinal adaptation. CONCLUSIONS: cDNA microarray analysis showed enhanced expression of sprr2, a gene not previously known to be involved in the physiology of adaptation after SBR. This technology provides a more rapid and efficient means of dissecting the complex genetic regulation of gut adaptation.

A defective EGF-receptor in waved-2 mice attenuates intestinal adaptation.

While the pathophysiology of intestinal adaptation following small bowel resection (SBR) is not well understood, there is evidence to suggest an important role for epidermal growth factor (EGF) in this process. In waved-2 mice, a naturally occurring mutation results in reduced EGF receptor protein tyrosine kinase activity. We tested the hypothesis that an intact EGF receptor is essential for adaptation by subjecting this strain of mice to SBR. A 50% proximal SBR or sham operation (bowel transection with reanastomosis only) was performed in waved-2, heterozygous, and wildtype mice. After 3 days, adaptation was characterized in the remnant ileum as changes in DNA and protein content per unit length. Villus height and crypt depth were measured, and crypt cell proliferation rates were determined by the percentage of crypt cells taking up 5-bromodeoxyuridine. Following sham surgery, all mice regained their preoperative weight by the third postoperative day. After SBR, all mice gained weight while the waved-2 mice did not. Ileal DNA and protein significantly increased after SBR in wild-type and heterozygous mice while these parameters were unchanged in the waved-2 mice. Villus height and crypt cell proliferation increased in response to SBR in all groups; however, the changes were less pronounced in the waved-2 mice. Adaptation after SBR is impaired in waved-2 mice. Signal transduction by the EGF receptor is a critical component of this response. These data endorse a crucial role for EGF and its receptor in the pathogenesis of intestinal adaptation.