Circulating levels of glucagon-like peptide-2 in human subjects with inflammatory bowel disease

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Circulating levels of glucagon-like peptide-2 in human subjects with inflammatory bowel disease

Qiang Xiao¹^,^*, Robin P. Boushey²^,^*, Maria Cino³, Daniel J. Drucker³^,⁴, and Patricia L. Brubaker¹^,³

Departments of ¹ Physiology, ³ Medicine, and ² Surgery, Mount Sinai Hospital and the Toronto General Hospital, Toronto M5G 2C4; and the ⁴ Banting and Best Diabetes Centre, University of Toronto, Toronto, Ontario, Canada M5S 1A8

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Glucagon-like peptide-2 (GLP-2) is a recently characterized intestine-derived peptide that exerts trophic activity in thesmall and large intestine. Whether circulating levels of GLP-2are perturbed in the setting of human inflammatory bowel disease(IBD) remains unknown. The circulating levels of bioactive GLP-2-(1 $---$ 33)compared with its degradation product GLP-2-(3 $---$ 33) were assessedusing a combination of RIA and HPLC in normal and immunocompromisedcontrol human subjects and patients hospitalized for IBD. Theactivity of the enzyme dipeptidyl peptidase IV (DP IV), a keydeterminant of GLP-2-(1 $---$ 33) degradation was also assessed in theplasma of normal controls and subjects with IBD. The circulatinglevels of bioactive GLP-2-(1 $---$ 33) were increased in patients witheither ulcerative colitis (UC) or Crohn's Disease (CD; to 229± 65 and 317 ± 89%, P < 0.05, of normal, respectively). Furthermore,the proportion of total immunoreactivity represented by intactGLP-2-(1 $---$ 33), compared with GLP-2-(3 $---$ 33), was increased from 43± 3% in normal healthy controls to 61 ± 6% (P < 0.01) and 59 ±2% (P < 0.01) in patients with UC and CD, respectively. The relativeactivity of plasma DP IV was significantly reduced in subjectswith IBD compared with normal subjects (1.4 ± 0.3 vs. 5.0 ± 1.1mU/ml, respectively; P < 0.05). These results suggest that patientswith active IBD may undergo an adaptive response to intestinalinjury by increasing the circulating levels of bioactive GLP-2-(1 $---$ 33),facilitating enhanced repair of the intestinal mucosal epitheliuminvivo.

Crohn's disease; ulcerative colitis; short bowel syndrome; intestine

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

CROHN'S DISEASE (CD) and ulcerative colitis (UC) represent intestinal diseases characterized by repeated episodes of mucosalinflammation that may result in marked alterations in intestinalepithelial structure and function. Although the etiology of bothconditions remains unknown, current therapeutic strategies aimto modulate the inflammatory response, minimizing further intestinalinjury and allowing endogenous repair mechanisms to restore intestinalintegrity (15). Failure of these reparative mechanisms, througheither an inadequate reparative response or through repeated episodesof repair and remodeling, may result in fibrosis and stricture,often requiring surgical resection, leading to further compromiseof the intestinal epithelium, especially in patients withCD.

Numerous cell populations within the intestine participate in the reparative response through the production and secretionof various cytokines, endocrine peptides, and growth factors withpleiotropic biological activities. The intestinal mucosa containscells that secrete molecules important for cell proliferationand migration, extracellular matrix formation, immune regulation,and tissue remodeling. Several families of growth factors playan important role in the response to intestinal injury, includingthe epidermal growth factor family, the transforming growth factor(TGF) superfamily, insulin-like growth factors (IGF), fibroblastgrowth factors (FGF), hepatocyte growth factor, trefoil factors,platelet-derived growth factor, keratinocyte growth factor (KGF),and vascular endothelial growth factor (9, 23, 24), aswell as several members of the cytokine family (15).

The intestinotropic and protective properties of various cytokines and growth factors have prompted analyses of their activityin animal models of experimental intestinal injury. The presenceor absence of TGF- $alpha$ correlates well with the susceptibility tochemically induced intestinal injury in mice (12, 13), whereasadministration of either IGF-I or KGF attenuates mucosal injuryin rodents with experimental colitis (17, 32). Similarly,deficiency or overexpression of intestinal trefoil factors correlateswith increased or reduced susceptibility, respectively, to experimentalintestinal injury in murine models in vivo (20, 22). Thesefindings have led to the suggestion that one or more growth factorsmay be therapeutically useful for enhancing the reparative responseto intestinal injury in patients with intestinaldisease.

Regulatory peptides with intestinotrophic activity have also been implicated in the response to intestinal inflammation andinjury. Coinfusion of peptide YY with parenteral nutrition inrats significantly augmented intestinal mass and protein content,compared with findings in rats infused with parenteral nutritionalone (4). Similarly, administration of neurotensin or bombesinresults in stimulation of mucosal epithelial proliferation inrodents in vivo (5, 6). The findings that intestinal injuryin rodents and humans is commonly associated with increased levelsof the gut proglucagon-derived peptides (PGDPs; 1), taken togetherwith observations of gut growth in patients with glucagon-producingtumors (14, 26), ultimately led to the identification of oneof the PGDPs, GLP-2, as yet another member of the intestinal regulatorypeptide family with trophic properties in vivo (10).

GLP-2 is an endocrine peptide derived from the posttranslational processing of proglucagon in the intestine. GLP-2 and thestructurally related PGDP GLP-1 are derived from the same proglucagonprecursor, and both peptides are produced and secreted in a nutrient-dependentfashion by the enteroendocrine L cells of the small and largeintestine (8, 25, 31). Whereas GLP-1 regulates pancreaticendocrine function and gastric motility (8), GLP-2 is trophicto the intestinal mucosal epithelium via stimulation of cryptcell proliferation and reduction of enterocyte apoptosis (29).Despite the emerging interest in a potential role for GLP-2 inthe pathophysiology and/or treatment of intestinal disease, littleinformation is available about the circulating levels of the biologicallyactive form of the molecule, GLP-2-(1 $---$ 33), in rodents or humansubjects. Furthermore, there is no information available regardingthe levels of circulating GLP-2-(1 $---$ 33) in patients with intestinaldisease. As the levels of PGDPs have been reported to be alteredin the adapting or injured intestine (1), we have now determinedwhether patients with intestinal injury exhibit abnormalitiesin the levels and/or the molecular forms of circulating GLP-2invivo.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Study group. Blood for analysis of GLP-2 was collected from the following groups of patients after written informed consent:1) normal healthy controls (n = 14, 6 males and 8 females, meanage 28.9 ± 4.8 yr); 2) immune controls (patients with rheumatologicaldiseases, n = 18, 2 males and 16 females, mean age 57.3 ± 16 yr,mean duration of disease 12.4 ± 9.9 yr and patients with livertransplants, n = 20, 11 males and 9 females, mean age 53.2 ± 8yr, mean number of years after transplant 7.6 ± 5.9); 3) patientswith CD without bowel resection (n = 30, 17 males and 13 females,mean age 31.9 ± 11.8 yr, 12 with small bowel disease, 10 withlarge bowel disease, and 8 with combined small and large bowelinvolvement, mean duration of clinical disease 4.5 ± 5.1 yr);4) patients with UC (n = 21, 17 males and 4 females, mean age29.0 ± 11.0 yr, 20 with pancolitis, 1 with left-sided colitis,mean duration of disease 4.3 ± 5.9 yr); and 5) CD and intestinalresection (n = 9, 3 males and 6 females, mean age 39.3 ± 13.2yr, 4 patients with distal small bowel resection, 1 patient withcolonic resection, and 4 with combined small and large bowel resection,mean duration of disease 12.9 ± 12.7 yr). Blood for analysis ofdipeptidyl peptidase IV (DP IV) was collected from six healthycontrols (3 males and 3 females, mean age 27.5 ± 4.9 yr), onepatient with CD without bowel resection (female, age 27 yr, duration8 yr), four patients with CD and bowel resection (3 males and1 female, mean age 32.5 ± 3.0 yr, mean duration 14.3 ± 3.8 yr),and one patient with UC (male, age 23 yr, duration 1yr).

Given the wide spectrum of clinical presentation in patients with inflammatory bowel disease (IBD), we have limited our investigationto patients with clinically active IBD requiring hospitalizationfor either complications of their underlying disease or due torefractoriness to conventional forms of medical management. Allpatients included in this study had a diagnosis of CD or UC establishedon the basis of 1) clinical history, 2) distribution of disease,and 3) histological diagnosis on previous intestinal biopsy orresection when available. All patients underwent diagnostic testingto localize areas of active intestinal disease, including endoscopy,intestinal contrast studies, or computerized-automated tomographyafter venipuncture during their hospitalization. All of the bloodsamples were obtained before any abdominal surgery. All patientsand controls fasted from midnight on, and a blood sample was obtainedvia venipuncture the following morning between 8:00 and 10:00AM. The characteristics of the 60 patients analyzed for levelsof GLP-2 and 6 patients studied for DP IV activity in this studyare shown in Table 1.

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Table 1. Profiles of hospitalized patients with IBD analyzed in this study for levels of circulating GLP-2 (patients 1-60) or DP-IV activity (patients 61-66)

Sample collection. For RIA of immunoreactive (IR)-GLP-2, blood samples were collected on ice in 10% vol/vol of Trasylol-EDTA-DiprotinA (5,000 kallikrein inhibitory units of Trasylol/ml; Miles Canada,Etobicoke, Canada):1.2 mg/ml EDTA:0.1 mM Diprotin A (ILE-PRO-ILE;Sigma Chemical, St. Louis, MO), an inhibitor of DP IV activity,to prevent enzymatic degradation of intact GLP-2 as previouslydescribed (2, 11). For assay of DP IV activity, blood wascollected in 10% vol/vol Trasylol-EDTA. After centrifugation,plasma was collected and stored at $-$ 70°C until extraction. Allblood samples were obtained after patients gave signed informedconsent under protocols approved by the Human Ethics Committeeat the Mount Sinai and Toronto General Hospital (Toronto, ON,Canada).

Peptide extraction. Plasma samples were acidified by addition of two volumes of 1% trifluoroacetic acid (TFA; pH adjustedto 2.5 with diethylamine), and peptides were extracted by passagetwice through a Sep-Pak C₁₈ cartridge (Waters Associates, Milford,MA). After being washed with 0.1% TFA, the peptides adsorbed ontothe cartridge were eluted with 80% isopropanol containing 0.1%TFA. Recovery of GLP-2 with this extraction technique is 84 ±17%, as reported previously (2, 11).

RIA. RIA for GLP-2 was performed using antiserum UTTH7, as described previously (2, 11, 31). This antiserum recognizesthe midsequence of GLP-2 (amino acids 25-30), and thus cross-reactsequally with intact GLP-2-(1 $---$ 33), biologically inactive GLP-2-(3 $---$ 33),and the inactive pancreatic precursor, major proglucagon fragment(MPGF), but has no cross-reactivity with GLP-1, glucagon, or otherstructurally related peptides (Fig. 1A). Fifty percent bindingof the tracer was observed at 125 pg/tube, and the sensitivityof the assay was 10 pg/tube.

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Fig. 1. A: structure of mammalian preproglucagon encoding glucagon-like peptide (GLP)-2. In the pancreas, incompletely processed major proglucagon fragment is liberated, whereas in the intestine, GLP-2-(1 $---$ 33) that is generated undergoes further cleavage in the circulation to produce GLP-2-(3 $---$ 33). Antiserum used for these studies, UTTH7 (arrowhead), cross-reacts with all of these molecular forms. GRPP, glicentin related pancreatic polypeptide; IP-1, intervening peptide-1; IP-2, intervening peptide-2. B: circulating levels of total immunoreactive (IR)-GLP-2 in normal healthy control subjects (HC; n = 14), immunocompromised controls (IC; n = 38), patients with ulcerative colitis (UC; n = 21), patients with unresected Crohn's Disease (CD; n = 30), and patients with CD with previous intestinal resection (CD+R; n = 9). * P < 0.05 and ** P < 0.01 vs. normal controls. Arrowhead, proglucagon-derived peptides (PGDPs) recognized by GLP-2 assay for total IR-GLP-2.

Reversed-phase HPLC. HPLC was performed using a Waters system with a uBondapak C₁₈ column (Waters Associates). The solventsystems used were 0.1% (vol/vol) TFA in water (solvent A) and0.1% (vol/vol) TFA in acetonitrile (solvent B). All plasma sampleswere extracted by Sep-Pak before loading onto the HPLC column.GLP-2-(1 $---$ 33) was separated from GLP-2-(3 $---$ 33) with the use of agradient of 30-60% solvent B over 45 min, followed by a purgewith 99% solvent B for 10 min. The solvent flow rate was 1.5 ml/min,and 18-s fractions were collected (2, 11, 31).

DP IV assay. Ninety-six well plates were loaded with 50 µl of 0.1 mM Tris (pH 7.4), 60 µl of plasma, and 90 µl of 1.11 mMGly-Pro-p-nitroanilide (substrate; Sigma Chemical). Absorbanceat 450 nm was recorded immediately on addition of the substrateand then at 5-min intervals for 30 min to monitor the appearanceof the product p-nitroaniline, using a Packard SpectraCount MicroplatePhotometer (Canberra Packard Canada, Mississauga, ON, Canada).A standard curve was prepared using concentrations of p-nitroaniline(Sigma Chemical) ranging from 0 to 1 mM in 0.1 M Tris buffer.Enzyme activity was determined as the micromoles of p-nitroanilineproduced per minute per milliliter of plasma (U/ml), as previouslydescribed (3).

Data analysis. All data are expressed as means ± SE. Statistical differences between groups were determined by unpaired Student'st-test or by ANOVA using n $-$ 1 post hoc custom hypotheses tests,as appropriate, on a SAS system (Statistical Analysis Systems,Cary,NC).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

It is well established that a number of growth factors demonstrate trophic effects on the intestinal epithelium. With theexception of nutrient ingestion (31), the factors that regulateproduction and secretion of human GLP-2-(1 $---$ 33) have yet to beelucidated. As the proglucagon gene is expressed in the endocrinepancreas and gastrointestinal tract, circulating levels of totalIR-GLP-2 are therefore composed of at least three different molecularforms (Fig. 1A) of GLP-2 (2, 11, 31), including bioactiveGLP-2-(1 $---$ 33) liberated from intestinal endocrine cells, inactiveGLP-2-(3 $---$ 33) (produced via DP IV-mediated cleavage at Ala²), and inactive MPGF (16, 21) containing the unprocessed carboxyterminal sequences of proglucagon, including both GLP-1 and GLP-2.Antisera against the carboxy terminal region of the GLP-2 moleculewill potentially recognize at least three different PGDPs, includingMPGF, GLP-2-(1 $---$ 33), and GLP-2-(3 $---$ 33) (31).

As shown in Fig. 1B, plasma levels of total IR-GLP-2 were not different between normal healthy and immunocompromised controlsubjects (706 ± 44 pg/ml, n = 14 vs. 781 ± 75 pg/ ml, n = 38,respectively). Total IR-GLP-2 levels were also not different fromnormal controls in patients with UC (660 ± 69 pg/ml, n = 21).However, circulating levels of total IR-GLP-2 in patients withCD were significantly decreased (532 ± 46 pg/ml, n = 30; P < 0.05vs. normal controls). There were no significant differences intotal IR-GLP-2 levels between the different patients with CD whenthese individuals were subgrouped according to the site of diseaseactivity (e.g., small intestine: 526 ± 105 pg/ml, n = 12; largeintestine: 547 ± 49 pg/ml, n = 10; and both small and large intestine:521 ± 61 pg/ml, n = 8). However, a significant decrease in totalIR-GLP-2 levels was observed in those patients with CD who hada history of intestinal resection (373 ± 44 pg/ml, n = 9; P <0.01).

As total GLP-2-IR comprises multiple molecular forms of GLP-2 (Fig. 1A), including MPGF, GLP-2-(1 $---$ 33), and its circulatingdegradation product GLP-2-(3 $---$ 33), the plasma levels of total IR-GLP-2are clearly much higher than the levels of intact bioactive GLP-2-(1 $---$ 33)(31). Accordingly, reversed-phase HPLC was used to determinethe circulating levels of GLP-2-(1 $---$ 33) and GLP-2-(3 $---$ 33) (Fig.2). Plasma samples from all subjects contained two peaks of IR-GLP-2that eluted with the same retention times as synthetic human GLP-2-(1 $---$ 33)and GLP-2-(3 $---$ 33) (as shown in Fig. 2A for normal controls or patientswith UC or CD). Consistent with results of previous studies (11,31), the concentration of circulating intestinal GLP-2-(1 $---$ 33)plus GLP-2-(3 $---$ 33) (as determined from area under the curve analysesof the HPLC profiles) in normal human subjects was 67.5 ± 3.2pg/ml, and this was not significantly altered in patients withIBD (Fig. 2B). However, when the levels of GLP-2-(1 $---$ 33) alonewere determined, the levels of this bioactive peptide were increasedto 229 ± 65% of normal in patients with UC and to 317 ± 89% (P< 0.05) in those with CD. Furthermore, the proportion of GLP-2-(1 $---$ 33)compared with GLP-2-(3 $---$ 33) was increased in patients with IBD;GLP-2-(1 $---$ 33) accounted for 43 ± 3% of these peptides in normalsubjects (ratio 1:1.4 ± 0.2), whereas the proportion of GLP-2-(1 $---$ 33)was increased to 61 ± 6% (P < 0.01) of normal in patients withUC (ratio 1:0.7 ± 0.1) and to 59 ± 2% (P < 0.01) of normal inpatients with CD (ratio 1:0.7 ± 0.1; Fig. 3). The relative proportionsof GLP-2-(1 $---$ 33) and GLP-2-(3 $---$ 33) were not altered in immunocompromisedcontrol patients (data not shown).

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Fig. 2. A: representative HPLC profiles of IR-GLP-2 in 1 ml plasma from normal HCs or patients with UC or CD with disease focus in small intestine (CD-SI), large intestine (CD-LI), and both small and large intestine (CD-SI&LI). Arrows, elution positions of synthetic GLP-2-(1 $---$ 33) and GLP-2-(3 $---$ 33). B: absolute values for areas under the curve for GLP-2-(1 $---$ 33) (filled bars) and GLP-2-(3 $---$ 33) (hatched bars) in normal HC (n = 4) compared with patients with either UC (n = 4) or CD without intestinal resection (n = 7: n = 2 for disease focus in small intestine, n = 3 for disease focus in large intestine, and n = 2 for disease focus in both small and large intestine). * P < 0.05 for GLP-2-(1 $---$ 33) levels in CD vs. normal HC.

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Fig. 3. Proportion of IR-GLP-2 found as intact GLP-2-(1 $---$ 33) in HPLC profiles (as determined from areas under the curve of data presented in Fig. 2) of plasma from normal HC (n = 4), patients with UC (n = 4), and patients with CD (n = 7; n = 2 for SI, n = 3 for LI, and n = 2 for SI&LI). ** P < 0.01 vs. normal HCs.

The finding of an increase in the ratio of GLP-2-(1 $---$ 33) to GLP-2-(3 $---$ 33) in patients with IBD suggested that the rate of DPIV-mediated degradation to GLP-2-(3 $---$ 33) might be reduced in somepatients with this condition. To address this possibility, wemeasured DP IV enzyme activity in plasma (collected in the absenceof DP IV inhibitors) from normal subjects and patients with IBD.As shown in Fig. 4, plasma DP IV activity was significantly decreasedin patients with IBD compared with normal subjects (1.4 ± 0.3vs. 5.0 ± 1.1 mU/ml, respectively; P < 0.05).

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Fig. 4. Dipeptidyl peptidase IV (DP IV) activity as measured by temporal production of p-nitroaniline from Gly-Pro-p-nitroanilide in plasma from normal HCs (

; n = 6) and patients with inflammatory bowel disease (IBD;

; n = 5 with CD and n = 1 with UC). P < 0.05 for IBD vs. normal HCs.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The results of the present study indicate that the circulating levels of total IR-GLP-2 are reduced in patients with CD, butnot in those with UC, when compared with healthy or immunocompromisedcontrols. Analysis of plasma total IR-GLP-2 in immunocompromisedcontrol patients did not demonstrate altered levels of circulatingtotal IR-GLP-2, when compared with normal controls, suggestingthat the decreased circulating levels of total IR-GLP-2 observedin patients with CD was not simply due to the inflammatory processor to the unique profile of medications administered to thesepatients. In addition, we have not observed changes in the intestinallevels of GLP-2 in mice administered combinations of agents usedto treat human subjects with IBD (unpublished observations). However,as pancreatic MPGF accounts for much of the circulating totalIR-GLP-2 in human plasma (31), the changes observed in patientswith CD suggest that pancreatic MPGF secretion or clearance maybe altered in these individuals. Furthermore, the most striking(~50%) reduction in circulating levels of total IR-GLP-2 was observedin patients with CD and previous ileal resection, in keeping withthe localization and relative abundance of GLP-2-producing enteroendocrineL cells in the distalileum.

The finding that patients with intestinal resection exhibit reduced levels of circulating GLP-2 is consistent with a recentreport describing impaired meal-stimulated increases in circulatingGLP-2 in patients with intestinal failure and ileal resection(18). In contrast, extensive damage to or surgical resectionof the terminal ileum (18) produces a state of relative GLP-2deficiency, due to impaired function or resection of enteroendocrinecells that produce GLP-2. The latter findings led Jeppesen andcolleagues (18) to postulate that restoration of adequate levelsof GLP-2 in patients with intestinal failure may represent a physiologicallyrelevant form of intestinal hormone replacement invivo.

In contrast to GLP-2 deficiency in patients with ileal resection, HPLC analysis demonstrated a striking two- to threefoldelevation in the level of bioactive GLP-2-(1 $---$ 33) in nonresectedIBD patients with either CD or UC. Interestingly, previous studiesdemonstrated elevated plasma levels of some of the intestinalPGDPs in rodents with intestinal injury and in several human diseases(including acute infective diarrhea, intestinal resection, jejunoilealbypass, celiac disease, and tropical sprue) as part of the normalintestinal adaptive response to injury or inflammation (1,27, 28). Nevertheless, the relative levels or the molecularforms of circulating GLP-2 were not specifically examined in theseprevious studies. Our studies establish, for the first time, thatlevels of the intestinotrophic bioactive form of GLP-2 are clearlyelevated in human patients with intestinal injury in the settingofIBD.

One hypothesis to explain the increased levels of GLP-2-(1 $---$ 33) in patients with active IBD is that of enteroendocrine L celladaptation as a component of the response to mucosal injury, leadingto enhanced GLP-2 synthesis and/or secretion. For example, ilealproglucagon gene expression is increased in the intestinal remnant,and increased circulating levels of enteroglucagon and GLP-1 wereobserved in the rat after experimental intestinal resection (30).Unexpectedly, however, the proportions of GLP-2-(1 $---$ 33) and itsdegradation product GLP-2-(3 $---$ 33) were also altered in subjectswith IBD, such that patients with IBD exhibited increased relativeamounts of the bioactive GLP-2-(1 $---$ 33) peptide. These findingshighlight the importance of using antisera and/or separation techniquesthat discriminate among the different molecular forms of GLP-2for interpretation of physiological changes in the levels of IR-GLP-2peptides that circulate invivo.

We have recently shown that a significant amount of the biologically inactive GLP-2-(3 $---$ 33) is present in normal human plasmafrom fasted individuals, and the amount of this peptide increasesfurther after nutrient ingestion (31). Both GLP-1 and GLP-2contain an amino terminal alanine at position 2, rendering thesepeptides highly susceptible to cleavage by DP IV. Indeed, muchof the available literature assessing circulating levels of GLP-1is difficult to interpret because of the use of antisera thatdid not discriminate between bioactive GLP-1-(7 $---$ 36) amide andthe inactive degradation product GLP-1-(9 $---$ 36) amide (7, 19).In keeping with the findings from studies of GLP-1, the availableevidence suggests that the proportion of GLP-2-(1 $---$ 33) and GLP-2-(3 $---$ 33)is also regulated by the activity of the enzyme DP IV (2, 11).

Our observation that circulating DP IV enzymatic activity was reduced in IBD patients (by ~3.5-fold) is consistent with thepotential importance of circulating DP IV as a component of theadaptive response to intestinal injury in vivo. These findingssuggest that regulation of DP IV activity may reflect the physiologicalimportance of maintaining levels of bioactive GLP-2-(1 $---$ 33) insettings of intestinal injury such as human IBD. Whether the reducedlevels of circulating DP IV activity in IBD patients reflect adecrease in synthesis, increased clearance, and/or attenuatedenzymatic activity merits furtherexploration.

Perspectives

In summary, GLP-2 represents an intestinal-derived peptide with significant reparative activity for the mucosal epitheliumof the small and large intestine. The current study demonstratesan increase in circulating levels of bioactive GLP-2-(1 $---$ 33) inpatients hospitalized for the treatment of IBD in associationwith reduced plasma activity of DP IV. As DP IV is the key enzymeresponsible for regulating the biological activity of GLP-2-(1 $---$ 33)in vivo, these findings suggest that regulation of DP IV activitymay be a previously unrecognized adaptive mechanism accountingfor increased circulating levels of biologically active GLP-2-(1 $---$ 33)in the setting of intestinal damage and/or inflammation. Our findingsare consistent with the hypothesis that maintaining an appropriatelevel of circulating GLP-2-(1 $---$ 33) via increased synthesis or secretionand/or reduced degradation of the biologically active peptidemay contribute to the capacity for endogenous repair of epithelialinjury in the humanintestine.

	ACKNOWLEDGEMENTS

Q. Xiao was supported in part by an operating grant from NPS Allelix (Mississauga, ON, Canada). This work was supported bygrants from NPS Allelix (to P. L. Brubaker), the Medical ResearchCouncil of Canada (to P. L. Brubaker and D. J. Drucker), and theOntario Research and Development Challenge Fund (to D. J. Drucker).D. J. Drucker is a Scientist of the Medical Research Council ofCanada and is a consultant to NPS Allelix. GLP-2 is the subjectof a licensing agreement between the Toronto General Hospital,the University of Toronto, and D. J.Drucker.

	FOOTNOTES

^* Q. Xiao and R. P. Boushey were equal contributors to thisstudy.

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: P. L. Brubaker, Rm. 3366, Medical Science Bldg., Univ. of Toronto, 1 Kings College Circle, Toronto, Ontario, M5S 1A8 Canada (E-mail: p.brubaker{at}utoronto.ca).

Received 16 July 1999; accepted in final form 4 November 1999.

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