Hypoxia-Inducible Factor 1-Dependent Induction of Intestinal Trefoil Factor Protects Barrier Function during Hypoxia

doi:10.1084/jem.193.9.1027

Published online 7 May 2001.

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© The Rockefeller University Press, 0022-1007/2001/5/1027/ $5.00
The Journal of Experimental Medicine, Volume 193, Number 9, May 7, 2001 1027-1034

Original Article

Hypoxia-Inducible Factor 1–Dependent Induction of Intestinal Trefoil Factor Protects Barrier Function during Hypoxia

Glenn T. Furuta^a^,c, Jerrold R. Turner^e, Cormac T. Taylor^a, Robert M. Hershberg^b, Katrina Comerford^a, Sailaja Narravula^a, Daniel K. Podolsky^d, and Sean P. Colgan^a

^a Center for Experimental Therapeutics and Reperfusion Injury, Brigham and Women's Hospital, the
^b Division of Gastroenterology, Brigham and Women's Hospital, the
^c Combined Program for Pediatric Gastroenterology and Nutrition, Children's Hospital,
^d Gastrointestinal Unit and Center for Study of Inflammatory Bowel Diseases, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02115
^e Department of Pathology, Wayne State University, Detroit, Michigan 48201
Center for Experimental Therapeutics and Reperfusion Injury, Brigham and Women's Hospital, Thorn Bldg. 704, 20 Shattuck St., Boston, MA 02115.617-278-6957617-732-5500 ext. 1401

colgan{at}zeus.bwh.harvard.edu

Abstract

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Mucosal organs such as the intestine are supported by a richand complex underlying vasculature. For this reason, the intestine,and particularly barrier-protective epithelial cells, are susceptibleto damage related to diminished blood flow and concomitant tissuehypoxia. We sought to identify compensatory mechanisms thatprotect epithelial barrier during episodes of intestinal hypoxia.Initial studies examining T84 colonic epithelial cells revealedthat barrier function is uniquely resistant to changes elicitedby hypoxia. A search for intestinal-specific, barrier-protectivefactors revealed that the human intestinal trefoil factor (ITF)gene promoter bears a previously unappreciated binding sitefor hypoxia-inducible factor (HIF)-1. Hypoxia resulted in parallelinduction of ITF mRNA and protein. Electrophoretic mobilityshift assay analysis using ITF-specific, HIF-1 consensus motifsresulted in a hypoxia-inducible DNA binding activity, and loadingcells with antisense oligonucleotides directed against the ${alpha}$ chain of HIF-1 resulted in a loss of ITF hypoxia inducibility.Moreover, addition of anti-ITF antibody resulted in a loss ofbarrier function in epithelial cells exposed to hypoxia, andthe addition of recombinant human ITF to vascular endothelialcells partially protected endothelial cells from hypoxia-elicitedbarrier disruption. Extensions of these studies in vivo revealedprominent hypoxia-elicited increases in intestinal permeabilityin ITF null mice. HIF-1–dependent induction of ITF mayprovide an adaptive link for maintenance of barrier functionduring hypoxia.

Key Words: epithelium • gastrointestinal disease • transcription factor • intestinal permeability • endothelium

Introduction

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Epithelial cells are anatomically positioned to provide a barrierto antigenic flux and luminal bacteria 1. Mucosal organs, suchas the intestine, rely on an extensive underlying vasculature,and therefore are primary sites for conditions of diminishedblood flow and resultant tissue hypoxia 2. Under such conditions,maintenance of barrier function depends on structures withinthe intercellular tight junction at the boundary of the apicaland basolateral membrane domain. At present, it is not knownif protective mechanisms exist to support functional epithelialbarrier properties during episodes of diminished blood flowand resultant hypoxia.

Both adaptive (e.g., erythropoietin [EPO], glycolytic enzymes)and proinflammatory (e.g., TNF- ${alpha}$ , IL-8) responses have been attributedto conditions of diminished tissue oxygen delivery (hypoxia),and it is now clear that responses to hypoxia include transcriptionallyregulated gene expression 2 3. One such transcriptional pathwayrelies on the activation of hypoxia-inducible factor (HIF)-1,a member of the rapidly growing per-ARNT-sim family of basichelix-loop-helix (bHLH) transcription factors 4 5 6. FunctionalHIF-1 exists as an ${alpha}$ β heterodimer, the activation of whichis dependent on stabilization of an O₂-dependent degradationpathway 7_. Binding of HIF-1 to DNA consensus domains (5'-RCGTG-3')results in the transcriptional induction of HIF-1–bearinggene promoters 3. HIF-1 is widely expressed and recent studiesindicate that consensus HIF-1–binding sequences existin a number of genes 3. Here we demonstrate that hypoxia inducesthe epithelial-specific, barrier-protective protein intestinaltrefoil factor (ITF) through an HIF-1–dependent mechanism.

Materials and Methods

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Growth and Maintenance of Cell Lines.
T84 cells and a subclone of Caco-2 B Be cells with high epithelialresistance were grown as monolayers on polycarbonate permeablesupports as described previously 8 9. The KB cell line is a humanoral epithelial cell line derived from native human mucosa 10.Human microvascular endothelial cells (MVECs) are primary cultureendothelial cells (Cascade Biologics, Inc.) derived from thehuman dermis and were cultured as described previously 11. Madin-Darbycanine kidney (MDCK) cells were cultured and passaged as describedpreviously 12. Confluent cells were exposed to hypoxia in ahumidified hypoxic cell chamber (Coy Laboratory Products, Inc.)as described previously 13. Standard hypoxic conditions (basedon previous work; references 13 14 15) were pO₂ = 20 Torr, pCO₂= 35 Torr, with the balance made up of nitrogen and water vapor.Normoxic controls were cells exposed to the same experimentalprotocols under conditions of atmospheric oxygen concentrations(pO₂ = 147 Torr and pCO₂ = 35 Torr within a tissue culture incubator).Paracellular permeability was assessed as described previously11 using FITC-labeled dextran (40 kD).

Transcriptional Analysis.
The transcriptional profile of epithelial cells exposed to ambienthypoxia was assessed in RNA derived from control or hypoxicepithelia (T84 cells at 6- or 18-h hypoxia) using quantitativegene chip expression arrays (Affymetrix, Inc.; reference 16).Reverse transcription (RT)-PCR analysis of mRNA levels was performedusing DNase-treated total RNA as described previously 14 usingprimers specific for human ITF 17 resulting in a 108-bp fragmentor β-actin 14 resulting in a 661-bp fragment. In subsetsof experiments, the transcription inhibitor actinomycin D (10ng/ml final concentration) was used to determine the prevalenceof newly synthesized RNA in this response.

Western Blot Analysis.
After experimental treatment of epithelial cells, cell culturesupernatants (for examination of soluble ITF) were preparedas described previously 11. Nuclear extracts (for analysis ofHIF-1 ${alpha}$ ) were isolated from confluent monolayers of epitheliaon 100-mm petri dishes as described before 18. Samples (25 µg/lane)were resolved by reducing SDS-PAGE, transferred to nitrocellulose,and blocked overnight in blocking buffer (250 mM NaCl, 0.02%Tween 20, 5% goat serum, 3% BSA). For Western blotting, affinity-purifiedanti–HIF-1 ${alpha}$ (generated by immunizing rabbits with an antigenicpeptide encoded in the HIF-1 ${alpha}$ protein structure encoding aminoacids 527–541 [MVNEFKLELVEKLFA] of HIF-1 ${alpha}$ ) or anti-ITF19 was added for 3 h, blots were washed, and species-matchedperoxidase-conjugated secondary Ab is added, as described previously14. Labeled bands from washed blots were detected by enhancedchemiluminescence (Amersham Pharmacia Biotech).

Electrophoretic Mobility Shift Assay.
Nuclear extracts of cells exposed to indicated experimentalconditions were obtained as described elsewhere. Synthetic oligonucleotideswere synthesized (Genosys Biotechnologies, Inc.) and used asprobes in electrophoretic mobility shift assays (EMSAs). Thehypoxic response element (HRE) motif lies at –129 to –122relative to the transcription start site in the ITF promoter17. Oligonucleotide probes for EMSA were digoxigenin-labeled,incubated with nuclear lysates, and resolved on a 6% nondenaturingpolyacrylamide gel as described previously (Boehringer; reference14). DNA–protein complexes were transblotted to nylonmembrane, probed with antidigoxigenin-peroxidase, and developedby enhanced chemiluminescence. Controls consisted of free probealone, excess unlabeled probe, or a species-matched irrelevantAb (anti-cAMP response element–binding protein [CREB];Transduction Labs, Inc.).

HIF-1 ${alpha}$ Antisense Oligonucleotide Treatment.
HIF-1 ${alpha}$ depletion in epithelial cells was accomplished by usingantisense oligonucleotide loading as described previously 20using phosphorothioate derivatives of antisense (GCC GGC GCCCTC CAT) or control sense (ATG GAG GGC GCC GGC) oligonucleotides.T84 epithelial cells were washed in serum free media, then inmedia containing 20 µg/ml effectene transfection reagent(QIAGEN) with 2 µg/ml HIF-1 ${alpha}$ antisense or sense oligonucleotide.Cells were incubated for 4 h at 37°C and then replaced withserum containing growth media. Treated cells were exposed tohypoxia or normoxia for indicated periods of time. As indicated,ITF mRNA was quantified by RT-PCR as described above (see TranscriptionalAnalysis).

HIF-1 Transfection.
Stable cell lines overexpressing HIF-1 ${alpha}$ (plasmid provided byH.F. Bunn, Harvard Medical School; reference 7) were generatedin the high resistance Caco-2 B Be cell line as described previously8. Primary screening for HIF-1 expression was by RT-PCR analysis.Clones with the highest expression underwent secondary screensbased on electrophysiologic characteristics (high resistancemonolayers) and Western blot analysis of HIF-1 ${alpha}$ .

Intestinal Permeability In Vivo.
The generation of ITF null mice has been described previously21. Intestinal permeability was examined in 6–10-wk-oldwild-type Bl6129 (Taconic, Inc.) or ITF null mice using an FITC-labeleddextran method as described previously 22. Mice were gavagedwith 60 mg/100 g body weight of FITC-dextran (4,000 kD at 80mg/ml; Sigma-Aldrich) and exposed to ambient hypoxia (8% O₂,92% N₂) or ambient room air for various times (n = 4–6per condition). In some experiments, mice were administeredeither recombinant human ITF (30 mg/kg, 75% gastric lavage,25% enema) or PBS 1 h before hypoxia. Cardiac puncture was performedand serum analysis of FITC concentration performed. In subsetsof experiments, tissues were collected from wild-type and ITFnull mice after hypoxia and fixed in 10% buffered formalin.5-µm sections were cut, stained with hematoxylin and eosin,and histologically characterized. Colonic tissue was harvestedand homogenized and RNA extracted with Trizol as described above.Another section of colonic mucosal scrapings was harvested andprocessed for Western blot analysis as described above. Thisprotocol was in accordance with National Institutes of Healthguidelines for use of live animals and was approved by the InstitutionalAnimal Care and Use Committee at Brigham and Women's Hospital.

Statistical Analyses.
ITF bioactivity and paracellular permeability data were comparedby one- or two-factor analysis of variance or by Student's ttest where appropriate. Values are expressed as the mean andSEM from at least three separate experiments.

Results

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Colonic Epithelia Resist Hypoxia-elicited Barrier Changes.
Previous reports indicate that colonic epithelial barrier functionis maintained during even severe conditions of hypoxia 13 14.In contrast, other cell types (e.g., vascular endothelia) appearto markedly lose barrier qualities during ambient hypoxia 23.As shown in Table , comparison of six barrier cell types revealedthat colonic epithelial cells (T84 and Caco-2 cells), as opposedto other epithelia (KB, A549, and MDCK) or MVECs, appear tobe uniquely resistant to increased permeability induced by hypoxia,suggesting that intestinal epithelial cells possess mechanismsthat sustain barrier function under such conditions.

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Table 1 Intestinal Epithelia Resist Hypoxia-elicited Disruption

Hypoxia Induces ITF Production.
Transcriptional profiling has been used to identify potentialfactors contributing to maintenance of barrier during hypoxia24 25. Microarray analysis 26 was adopted to broadly screen hypoxia-regulatedgenes in RNA derived from intestinal epithelia (T84 cells),and identified a time-dependent induction of the intestinal-specific,barrier-protective ITF gene (2.8- and 4.2-fold increase overcontrol normoxia at 6- and 18-h hypoxia, respectively). Subsequently,RT-PCR analysis was employed to corroborate results of microarrayscreening (Fig. 1 a). This analysis of Caco-2 cells demonstrateda time-dependent induction of ITF mRNA expression, and was evidentby 4-h exposure to hypoxia. Similar results were seen in T84cells (data not shown). Epithelial exposure to the RNA synthesisinhibitor actinomycin D blocked this hypoxia-elicited ITF induction(Fig. 1 b), indicating that this response reflects new transcriptionalactivity. To confirm these mRNA observations at the proteinlevel, Western blot analysis of soluble supernatants confirmedan increase of secreted ITF protein by 48 h (Fig. 1 b).

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Figure 1 ITF induction of hypoxia. Confluent Caco-2 epithelial monolayers were exposed to indicated periods of ambient hypoxia (pO₂ = 20 Torr) or normoxia (pO₂ = 147 Torr). In a, total RNA was isolated and examined for ITF transcript by RT-PCR. β-Actin transcript was used as an internal control. In b, Caco-2 cells were pretreated with vehicle or actinomycin D (Act. D) before 24 h of hypoxia or normoxia. Total RNA was isolated and examined for ITF mRNA. In c, soluble supernatants derived from monolayers exposed to indicated periods of hypoxia were examined for ITF content by SDS-PAGE and Western blot analysis.

ITF Production Is HIF-1 Dependent.
Prompted by these results, a search of the cloned ITF gene identifieda previously unappreciated HIF-1 ${alpha}$ binding site at positions –129to –122 relative to the transcription start site 17 (DNAconsensus motif 5'-TACGTGGG-3'; reference 6). Consequently,we assessed the induction of HIF-1 ${alpha}$ and ITF by hypoxia. First,we determined whether conditions of hypoxia induce HIF-1 ${alpha}$ inintestinal epithelia (Fig. 2 a). Western blot analysis of nuclearlysates derived from hypoxic intestinal epithelia Caco-2 cellsdemonstrated abundant HIF-1 ${alpha}$ in nuclei. These data are consistentwith previous studies suggesting that HIF-1 ${alpha}$ is expressed inmost cell types during periods of hypoxia 3. Next, we examinedthe binding of HIF-1 ${alpha}$ to the HRE consensus in the ITF promoterby EMSA (Fig. 2 b). As can be seen, nuclear extracts derivedfrom hypoxic, but not normoxic, Caco-2 cells bind to the HIF-1 ${alpha}$ consensus of the ITF promoter. Pretreatment of epithelia with100 µM CoCl₂ for 4 h, conditions that promote nuclearaccumulation of HIF-1 ${alpha}$ 5, resulted in a similar band shift. Additionof anti–HIF-1 ${alpha}$ mAb, but not isotype-matched mAb, resultedin a diminution of shifted signal, but no obvious supershiftconsistent with Ab interference with DNA–protein interaction.Incubation with 100-fold excess unlabeled primer resulted incomplete loss of signal. Collectively, these results indicatethat hypoxia elicits nuclear accumulation of HIF-1 ${alpha}$ , which bindsto the consensus HRE located within the ITF promoter.

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Figure 2 Parallel induction of HIF-1 and ITF by hypoxia. Confluent Caco-2 epithelial monolayers were exposed to indicated periods of ambient hypoxia (pO₂ = 20 Torr) or normoxia (pO₂ = 147 Torr). In a, nuclear lysates derived from monolayers exposed to normoxia or hypoxia were examined for HIF-1 ${alpha}$ content by SDS-PAGE Western blot analysis. In b, interactions between HIF-1 ${alpha}$ and the HRE of the ITF promoter gene were examined by EMSA using synthetic oligonucleotides and nuclear lysates derived from cells exposed to normoxia, 4- or 24-h hypoxia, or CoCl₂ (100 µM for 4 h). Specificity was determined with the use of anti–HIF-1 ${alpha}$ Ab, anti-CREB Ab (control), or excess (XS) unlabeled probed. Note diminution of signal in the presence of anti–HIF-1 ${alpha}$ , but not by anti-CREB Ab.

As proof of principle for this concept, intestinal epithelialcell lines overexpressing HIF-1 ${alpha}$ were generated by stable transfection(Fig. 3 a). As shown in Fig. 3 b, overexpression of HIF-1 ${alpha}$ resultedin increased basal expression of ITF and enhanced hypoxia-elicitedinduction of ITF. Next, antisense oligonucleotides directedagainst HIF-1 ${alpha}$ were used to block HIF-1 ${alpha}$ expression (Fig. 3 c)and the influence of HIF-1 ${alpha}$ depletion on ITF mRNA induction byhypoxia was assessed (Fig. 3 d). As can be seen, the directedloss of HIF-1 ${alpha}$ resulted in a nearly complete loss of ITF mRNAexpression at 4- and 24-h periods of hypoxia. Control oligonucleotidesgenerated to the sense strand of HIF-1 ${alpha}$ did not influence ITFhypoxia inducibility. Taken together, these results indicatethat hypoxia induces a time-dependent HIF-1 ${alpha}$ nuclear accumulationand parallel ITF induction.

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Figure 3 Induction of ITF is HIF-1 ${alpha}$ dependent. (a) Analysis of HIF-1 ${alpha}$ in transfected Caco-2 cells. Shown are mock transfected (Mock), cells overexpressing HIF-1 ${alpha}$ (HIF), and wild-type (WT) Caco-2 cells exposed to hypoxia and examined for HIF-1 ${alpha}$ expression by Western blot analysis. In b, ITF expression was analyzed by RT-PCR in HIF-1 ${alpha}$ transfectants and mock transfectants after exposure to indicated periods of hypoxia. In c, cells were loaded with antisense or sense oligonucleotides directed against HIF-1 ${alpha}$ as indicated and examined for HIF-1 ${alpha}$ mRNA. In d, Caco-2 cells pretreated with sense or antisense oligonucleotides as indicated were exposed to hypoxia or normoxia, and ITF mRNA expression was analyzed by RT-PCR.

ITF Promotes Barrier Function In Vitro and In Vivo.
Given the findings described above, studies were undertakento determine whether ITF played a functional role in maintenanceof the epithelial integrity during hypoxia. For this purpose,Caco-2 monolayers were exposed to hypoxia in the presence orabsence of anti-ITF (Fig. 4 a). Increasing concentrations ofanti-ITF sera (titer $~$ 1:100,000), but not isotype-matched antisera,resulted in a dose-dependent increase in epithelial permeabilityin response to hypoxia (no Ab versus anti–human [h] ITFat 1:100 dilution; P < 0.001). These results demonstratethat ITF participates in the maintenance of barrier functionduring hypoxia. Further evidence in support of ITF as a barrier-protectiveagent were provided by addition of recombinant hITF to hypoxia-sensitivecells. Monolayers of endothelial cells (which respond to hypoxiawith increase paracellular permeability, Table ) were used todefine this principle. As shown in Fig. 4 b, addition of hITFto confluent endothelial cells during conditions of hypoxiaresulted in a concentration-dependent protection against barrierdisruption (no hITF versus 1 mg/ml hITF; P < 0.01). Thesedata provide direct evidence for a key role of ITF protein inbarrier protection and suggest that ITF's functional actionmay be independent of the cell type, as illustrated here bythe vascular endothelia.

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Figure 4 Functional role of ITF peptide on barrier function. In a, Caco-2 cells were grown to electrical confluence on polycarbonate supports. Anti-ITF immune serum at indicated concentrations or control anti-CREB (1:100) was added to the apical well of the support. Cells were exposed to indicated periods of ambient hypoxia (pO₂ = 20 Torr) or normoxia. Transepithelial electrical resistance was measured at 48 h and indicated as data normalized to untreated control monolayers. 1:100 anti-ITF versus no Ab; ***P < 0.001. (b) The influence of recombinant ITF protein on permeability changes elicited in human MVEC exposure to hypoxia. Endothelia were grown to confluence on polycarbonate supports. Recombinant human ITF at indicated concentrations were applied to the apical well, and cells were exposed to indicated periods of ambient hypoxia (pO₂ = 20 Torr) or normoxia. Flux of 40-kD FITC-labeled dextran was used to assess endothelial paracellular permeability. 1 mg/ml hITF versus no recombinant protein; *P < 0.001.

To define the role of hypoxia-elicited ITF on mucosal barrierin vivo, intestinal permeability was examined in wild-type andITF null mice 21 during 4-h exposure to ambient hypoxia (8%O₂). Under such conditions, increases in both ITF mRNA (Fig. 5a) and protein (Fig. 5 b) were induced in tissues derived fromwild-type animals subjected to hypoxia. As shown in Fig. 5 c,upon exposure to hypoxia, ITF null mice exhibited a significantlygreater increase in intestinal permeability to FITC-dextran(4 kD) when compared with wild-type mice (ITF knockout versuswild-type exposed to hypoxia; P < 0.01). Interestingly, nohistologically evident lesions were observed in the colonicmucosa with 4-h exposure to hypoxia (representative sectionfrom wild-type and ITF null animals are shown in Fig. 5 d).Longer periods of time in hypoxia did not significantly increaseintestinal permeability beyond the 4-h time point. For example,intestinal permeability of wild-type animals subjected to hypoxiafor 18 h (3.3 ± 1.2-fold increase in permeability, n= 4 animals) were not different than animals exposed to 4-hhypoxia (4.4 ± 1.3-fold increase, n = 19 animals). Moreover,these longer time periods resulted in an unexpected death inITF null (four out of six animals tested) but not wild-typeanimals (zero out of six animals tested, data not shown). Interestingly,increased intestinal permeability was also evident in ITF nullmice not exposed to hypoxia as compared with wild-type (P <0.05 for ITF null compared with wild-type exposed to normoxia),consistent with the presumption that ITF may contribute to themaintenance of intestinal barrier under physiological conditions.

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Figure 5 Role of ITF in vivo. ITF null or wild-type Bl6129F1 mice were gavaged with 60 mg/100 g body weight of FITC-dextran and exposed to 4-h ambient hypoxia (8% O₂) or ambient room air. Mice were killed, colonic tissue harvested for RNA (a), Western blot analysis (b), histologic analysis original magnification: x10 (d), and serum FITC-dextran was quantified as a measure of intestinal permeability (c). *P < 0.05; **P < 0.01.

To further define these principles, wild-type and ITF null micewere administered recombinant ITF protein (30 mg/kg in PBS with75% intragastric and 25% rectal infusion) before hypoxia. Thesestudies revealed that administration of ITF to normoxic ITFnull animals resulted in a significant decrease in permeability(550 ± 40 vs. 320 ± 90 ng/ml in the absence andpresence of ITF administration, respectively; n = 4 mice percondition, P < 0.04). ITF addback to ITF null mice in hypoxiaresulted in a trend toward resolution of increased permeability(1,310 ± 310 and 970 ± 110 ng/ml in the absenceand presence of ITF administration; n = 6 mice per condition),however, these results were not statistically significant (P> 0.05). Similar to these results, ITF administration towild-type mice in normoxia and hypoxia trended toward resolutionof increased permeability but were not statistically significant(data not shown).

Discussion

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

These studies provide the first molecular link between hypoxiaand intestinal epithelial barrier protection. Here, we identifya previously unappreciated HIF-1 ${alpha}$ regulated pathway for inductionof ITF. ITF is a small, protease-resistant peptide that is abundantthroughout the mammalian intestinal tract 27 28. Increased ITFexpression has been observed in proximity to sites of injuryin the gastrointestinal tract, including peptic ulcers and activeinflammatory bowel disease 27 28 29. ITF can promote epithelialbarrier function, protecting against injury, and facilitatingrepair after damage occurs irrespective of the nature of theinitial wound. However, specific transcriptional pathways forITF induction are not well understood 30.

The hypoxia-dependent production of ITF represents a novel,innate protective mechanism that may guard the immunologic componentsof the lamina propria from exposure to pathogenic luminal bacteria,antigens, and toxins during episodes of diminished oxygen delivery.Accumulating evidence suggests a variety of physiological rolesfor ITF 28, however, molecular mechanisms regulating ITF expressionhave not been studied in detail. Rather, the signaling pathwaysactivated by the addition of exogenous ITF have been more closelyexamined and include the inactivation of extracellular signalregulatory kinase, regulated expression of ${alpha}$ - and β-catenin,and transactivation of the epidermal growth factor receptor31 32 33. Recent work has delineated that ITF can elicit distinctsignaling pathways for epithelial restitution and inhibitionof apoptosis, the latter of which involves activation of mitogen-activatedprotein kinase pathways independent of epidermal growth factorreceptor phosphorylation 33. Important for the present studies,these same extracellular signal regulatory kinase pathways wererecently demonstrated to critically function in the developmentof intestinal epithelial barrier function through regulatedexpression of claudin-2 and organization of membrane proteinswithin the tight junction 34. Thus, it is likely that ITF-specific,extracellular signaling pathways regulate epithelial barrierunder these defined conditions.

At the tissue and cellular level, an array of genes pivotalto survival in low oxygen states are activated 4 35 36 37. Originalstudies of hypoxia-induced EPO production concentrated on theregulation of gene transcription. Sequences from the EPO promoterwere isolated and identified as a heterodimer with independentlyregulated subunits termed HIF-1, a member of the rapidly growingper-ARNT-sim family of basic helix-loop-helix transcriptionfactors 5 6. HIF-1 exists as an ${alpha}$ β heterodimer, the activationof which is dependent on stabilization of an O₂-dependent degradationdomain of the ${alpha}$ subunit by the ubiquitin–proteasome pathway7. Although not certain, HIF-1 appears to reside in the cytoplasmof normoxic cells, and like a number of other transcriptionfactors (e.g., nuclear factor ${kappa}$ B, β-catenin), HIF-1 translocatesto the nucleus to form a functional complex 38 39. Binding ofHIF-1 to consensus domains in the EPO enhancer results in thetranscriptional induction of HIF-1–bearing gene promoters4. Subsequently, it was determined that HIF-1 is widely expressedand that consensus HIF-1–binding sequences exist in anumber of genes other than EPO and are termed HRE 4. Of noteon this accord, we did not precisely map the ITF HRE. Attemptsto define this site in exact terms were hampered by the complexityof the flanking region around the HIF-1 consensus sequence (datanot shown). For example, the immediate region of the HIF-1 consensussite also contains consensus binding sites for the transcriptionfactors myeloid zinc finger-1 (MZF1, consensus 5'-AGGGGGA-3'),GATA-1 (consensus 5'-GGGGATTCTG-3'), GATA-2 (consensus 5'-CAGGATAAGG-3'),Sp1 (consensus 5'-GTGGCAGGGT-3'), MyoD (consensus 3'-GCTGTCCACCGG-5'),and upstream stimulatory factor (USF, consensus 5'-CCACCTGT-3').Important in this regard, at least three of these transcriptionfactors (GATA-1, GATA-2, and MyoD) have been recently implicatedin either induction or repression of genes in hypoxia 40 41 42 43.Therefore, it is possible that regulation of the ITF gene atthis site could be an interplay of positive and negative signalingpathways, and given this complexity, more work will be necessaryto define the exact details of this HRE.

Our results suggest that ITF may represent a potential noveltherapeutic approach for a variety of diseases associated withmucosal hypoxia and altered epithelial barrier function, includinginflammatory bowel disease, necrotizing enterocolitis, and ischemiccolitis 44. In addition, these results suggest that a receptor/bindingsite for ITF may be present at sites other than the gastrointestinaltract, such as the endothelium. Thus, the protective effectof ITF on the hypoxia-induced decline in endothelial permeabilitysuggests that ITF may have even broader therapeutic relevancein conditions of vascular leakiness such as septic shock. Althoughit is unknown whether ITF would function alone in these responses,it is possible, as previously proposed, that ITF acts in concertwith and complementary to other protective growth factors andcytokines resident at sites of tissue damage 29. Efforts tobetter understand ITF signaling pathways and to identify otherhypoxia-elicited protective elements could provide future focusfor the development of novel treatments.

	Acknowledgments

We thank Eric Black, Kristin Synnestvedt, and Robyn Carey fortheir superb technical assistance. The authors also thank I.K.Ezedi and I. Rosenberg for production of recombinant ITF usedin these studies.

This work was supported by National Institutes of Health grantsDK02564 (to G.T. Furuta), DK02682 (to C.T. Taylor), DK02503(to J. Turner), DK43351 and DK46776 (to D.K. Podolsky), andDK50189 and HL60569 (to S.P. Colgan).

Submitted: 18 July 2000
Revised: 8 February 2001
Accepted: 26 March 2001

Abbreviations used in this paper: EMSA, electrophoretic mobilityshift assay; EPO, erythropoietin; HIF, hypoxia-inducible factor;HRE, hypoxic response element; ITF, intestinal trefoil factor;MDCK, Madin-Darby canine kidney; MVEC, microvascular endothelialcell; RT, reverse transcription.

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