Helicobacter pylori Activates the Cyclin D1 Gene through Mitogen- Activated Protein Kinase Pathway in Gastric Cancer Cells

doi:10.1128/IAI.69.6.3965-3971.2001

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Infection and Immunity, June 2001, p. 3965-3971, Vol. 69, No. 6
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.6.3965-3971.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Helicobacter pylori Activates the Cyclin D1 Gene through Mitogen- Activated Protein Kinase Pathway in Gastric Cancer Cells

Yoshihiro Hirata,^* Shin Maeda, Yuzo Mitsuno, Masao Akanuma, Yutaka Yamaji, Keiji Ogura, Haruhiko Yoshida, Yasushi Shiratori, and Masao Omata

Department of Gastroenterology, University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8655, Japan

Received 27 November 2000/Returned for modification 2 February 2001/Accepted 26 March 2001

	ABSTRACT

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Helicobacter pylori induces cellular proliferation in host cells, but the mechanism remains unclear. Thus, we examined theeffect of H. pylori on cyclin D1, an important regulator of thecell cycle, especially in relation to intracellular signalingpathways. In a Northern blot analysis, cyclin D1 transcriptionin gastric cancer (AGS) cells was enhanced by coculture with H.pylori strain TN2 in a time-dependent and multiplicity-of-infection-dependentmanner. An isogenic mutant form of vacA also increased cyclinD1 transcription, but mutant forms of cagE or the entire cag pathogenicityisland did not enhance cyclin D1 transcription. These effectswere confirmed with a luciferase assay of the cyclin D1 promoter(pD1luc). Cyclin D1 promoter activation by H. pylori was inhibitedby MEK inhibitors (U0126 and PD98059), indicating that the mitogen-activatedprotein kinase pathway may be involved in intracellular signaltransduction. In contrast, transfection of a reporter plasmidhaving any point mutations of the NF- $kappa$ B binding sites in the promoter(pD1- $kappa$ B1M, pD1- $kappa$ B2M, or pD1- $kappa$ B1/2M) or cotransfection of dominantnegative I $kappa$ B $alpha$ did not affect cyclin D1 activation by H. pylori.In conclusion, H. pylori activates cyclin D1 through the mitogen-activatedprotein kinase pathway and not through NF- $kappa$ B activation in AGScells. This activation of cyclin D1 is partly dependent on thecag pathogenicity island but not on vacA.

	INTRODUCTION

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Colonization of the human gastric mucosa by Helicobacter pylori induces various diseases, such as atrophic gastritis, pepticulcer diseases, and gastric adenocarcinoma (12, 21, 23,28, 30, 34). It has been recently demonstrated that H. pyloriaffects intracellular signal conduction in host cells, leadingto the activation of transcriptional factors (18, 19, 22,24, 25, 42) and the induction of proinflammatory cytokines(8, 29, 32, 41). The cag pathogenicity island (PAI) genesof H. pylori and their products are responsible for the bacterium-hostinteractions, including activation of the NF- $kappa$ B and mitogen-activatedprotein (MAP) kinase pathways (19, 22, 24, 25, 42).The cag PAI genes have been suggested as the cause of gastricdiseases in vivo (3, 6, 21), and we confirmed this inthe Mongolian gerbil model (33).

H. pylori infection is also associated with enhanced cellular proliferation of host cells (9, 14, 16, 36, 37);however, the mechanism of cellular proliferation induced by H.pylori infection remains unclear. In mammalian cells, cellularproliferation is regulated in a cell cycle governed by the sequentialformation and degradation of cyclins and cyclin-dependent kinases.Among various cyclins, cyclin D1 regulates passage through therestriction point and entry into the S phase (43). Furthermore,cyclin D1 overexpression shortens the G₁ phase and increases therate of cellular proliferation (15, 38-40). Various factors,such as the MAP kinase cascade (20), NF- $kappa$ B (13), and the Wntsignal (44, 47), are known regulators of cyclin D1 expression.In addition, some of these factors are already known to be activatedby H. pylori infection; however, little is known about the effectof H. pylori infection on cyclin D1 expression. Thus, in thisstudy, we tried to elucidate the mechanism of host cell proliferationcaused by H. pylori in relation to cyclin D1transcription.

	MATERIALS AND METHODS

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Cell culture. Human gastric adenocarcinoma cell line AGS cells were maintained in Ham's F12 medium supplemented with 10% fetal bovine serum(Life Technologies, Inc., Grand Island, N.Y.) in an incubatorwith 5% CO₂.

Bacterial strains and growth conditions. H. pylori strain TN2 possessing both the cag PAI and vacA was generously donated by M. Nakao (Takeda Chemical Industries,Ltd., Osaka, Japan). Infection with this strain induced gastriccancer in Mongolian gerbils (49). The isogenic mutants cagE-disruptedTN2- $Delta$ cagE and vacA-disrupted TN2- $Delta$ vacA were prepared as describedpreviously (22, 32). TN2- $Delta$ PAI, a strain in which all of thePAI genes are disrupted, was prepared as follows. A partial fragmentof the cagA gene (700 bp) was amplified by PCR and cloned intothe plasmid vector pCRII (Invitrogen, San Diego, Calif.). A 700-bpfragment of the cag5 gene, which is localized in cagII, was alsoamplified and cloned into pCRII containing a cagA gene fragmentat the KpnI site oriented in the same direction. A kanamycin resistancegene cassette was then inserted into the vector at the BamHI sitebetween cagA and the cag5 fragment. The resulting construct wastransferred into parental H. pylori cells (strain TN2) by electroporation.After selection by kanamycin resistance and Southern blot hybridizationto confirm the disruption of the genes, a clone was selected foruse as TN2- $Delta$ PAI.

These strains were grown in brucella broth with 5% (vol/vol) fetal bovine serum under microaerobic conditions (Campy-Pak Systems;BBL, Cockeysville, Md.), diluted to the desired multiplicity ofinfection (MOI), and then used for experiments. The number ofbacterial cells in the suspension was quantified by optical densitymeasurements.

Heat-killed H. pylori was prepared by boiling the bacteria for 30 min. H. pylori filtrate was prepared by suspending the bacteriain antibiotic-free medium for 30 min, pelleting the bacteria bycentrifugation, and then filtering the medium through a 0.22-µm-pore-sizefilter (Nihon Millipore Ltd., Tokyo,Japan).

Plasmids. Cyclin D1 promoter-containing construct pD1luc and vectors pD1- $kappa$ B1M, pD1- $kappa$ B2M, and pD1- $kappa$ B1/2M, possessing mutations in theirNF- $kappa$ B binding sites, were kindly donated by M. Strauss (HumboldtUniversität, Berlin, Germany). Plasmid pD1luc is consistent withan EcoRI/PvuII fragment (1,226 bp) of the cyclin D1 promoter.pD1- $kappa$ B1M possesses mutations in the NF- $kappa$ B binding site betweennucleotides $-$ 840 and $-$ 831, pD1- $kappa$ B2M has mutations in the NF- $kappa$ Bbinding site between nucleotides $-$ 33 and $-$ 24, and pD1- $kappa$ B1/2M possessesboth of these mutations (13, 27). The dominant-negative I $kappa$ B $alpha$ expression vector mutant (SS32/36AA) was generously donated byH. Suzuki (Yamanouchi Pharmaceutical Co., Ltd., Ibaraki, Japan)(46).

Northern blot analysis. AGS cells were serum starved for 72 h and subsequently cultured with H. pylori at an MOI of 10 to 300. Cells were harvestedat the times indicated, and total RNA was isolated by using Isogen(Wako, Osaka, Japan) in accordance with the manufacturer's instructions.Fifteen micrograms of total RNA was loaded onto a 1% agarose-formaldehydegel, separated by electrophoresis, and then transferred onto aHybond N membrane (Amersham Pharmacia Biotech, Buckinghamshire,UnitedKingdom).

Partial cDNA (200 bp) for cyclin D1 was produced by PCR using primers 5'-ATGGAACACCAGCTCCTGTG-3' (forward) and 5'-ACCTCCAGCATCCAGGTGGC-3'(reverse). The DNA sequence of the product was confirmed by usinga cycle DNA sequencing system (Perkin-Elmer Applied Biosystems,Foster City, Calif.). This cyclin D1 probe was labeled with anAlkPhos Direct Labelling Module (Amersham Pharmacia Biotech) usedin accordance with the manufacturer's instructions and then hybridizedwith the membrane for 12 h. After several washes of the membrane,cyclin D1 mRNA was detected by CDP-Star Detection Reagent (AmershamPharmacia Biotech), followed by analysis using the LAS1000 imagingsystem (Fuji Photo Film Co., Ltd., Tokyo,Japan).

After the hybridization, the membrane was reprobed with the human gene for glyceraldehyde 3-phosphate dehydrogenase to controlfor equal loading of theRNA.

Transfections and luciferase assays. AGS cells (1.5 × 10⁵) were seeded into six-well plates and transfected 24 h later with 200 ng of pD1luc or the mutant vectorand the indicated expression vectors using FuGENE 6 TransfectionReagent (Roche Diagnostic Corporation, Indianapolis, Ind.). Tennanograms of Renilla luciferase vector (Promega, Madison, Wis.)was included in each sample for standardization of transfectionefficiency. The total DNA amount was kept constant by supplementationwith empty vectors. After 24 h, H. pylori (strain TN2 or an isogenicmutant) was added at an MOI of 10 to 100 and incubated for theindicated times. 12-O-Tetradecanoylphorbol-13-acetate (TPA) (5to 50 ng/ml) was used as a positive control. When evaluating theeffect of the MAP kinase signaling pathway on activation of thecyclin D1 promoter, the specific MEK inhibitor PD98059 (Wako)or U0126 (Promega) (10) or vehicle (dimethyl sulfoxide) alonewas added 2 h before coculture with H. pylori. The cells wereharvested and washed with phosphate-buffered saline and lysedin a luciferase lysis buffer (Piccagene; Toyo Ink, Tokyo, Japan).The lysates were assayed for luciferase and seapansy luciferaseactivity with a luminometer. After standardization with seapansyluciferase activity, luciferase activity was calculated and representedas the fold induction, compared with the control, of more thanthree independentexperiments.

Statistical analysis. The significance of differences was assessed by analysis of variance and, if the F value was significant, by Dunnett's posthoctests.

	RESULTS

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H. pylori increases transcription of the cyclin D1 gene in gastric cancer cells in a time- and MOI-dependent manner. When serum-starved AGS cells were cocultured with H. pylori strain TN2 at an MOI of 100, the amount of cyclin D1 mRNA wasmarkedly increased from 60 to 120 min, as observed by Northernblot analysis (Fig. 1A). A similar increase in the cyclin D1 genewas observed when AGS cells were incubated with H. pylori at differentMOIs. H. pylori increased transcription of the cyclin D1 genein an MOI-dependent manner up to an MOI of 100 (Fig. 1B).

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FIG. 1. H. pylori induces cyclin D1 mRNA and activates the cyclin D1 promoter in AGS cells. (A) AGS cells were serum starved for 72 h and infected with H. pylori strain TN2 at an MOI of 100 for the times indicated, and cyclin D1 mRNA was measured by Northern blot analysis. (B) AGS cells were serum starved for 72 h and infected with H. pylori strain TN2 at different MOIs for 90 min, and cyclin D1 mRNA was measured by Northern blot analysis. (C and D) AGS cells which were transiently transfected with 200 ng of pD1luc were infected with H. pylori strain TN2 at an MOI of 100 (C) or treated with TPA at 50 ng/ml (D) for the indicated times. (E and F) AGS cells which were transiently transfected with 200 ng of pD1luc were infected with H. pylori strain TN2 at different MOIs (E) or treated with several concentrations of TPA (F) for 24 h. (G) Live H. pylori (MOI of 100), heat-killed H. pylori (MOI of 100), or H. pylori filtrate (extracted from the same number of bacteria) was added to AGS cells which were transiently transfected with pD1luc, and the mixture was incubated for 24 h. Luciferase activity is presented as a relative ratio against the basal level measured in untreated cells. The values shown are the means ± the standard deviations of more than five independent experiments. GAPDH: glyceraldehyde 3-phosphate dehydrogenase.

In the reporter assay using pD1luc, cyclin D1 promoter activity was enhanced in cells cocultured with H. pylori (Fig. 1C)in a time-dependent manner, in the same way as in cells treatedwith TPA at 50 ng/ml (Fig. 1D). Cyclin D1 promoter activity wasincreased 1.4-fold by 8 h, 3.0-fold by 16 h, and 6.4-fold by 24h of incubation with H. pylori, compared with that of an uninfectedcontrol. MOI-dependent transactivation was also observed in cellscocultured with H. pylori for 24 h (Fig. 1E), as was observedin cells treated with TPA (Fig. 1F). This activation was observedonly when live bacteria were added to the cells. Neither heat-killedbacteria nor bacterial filtrate activated the cyclin D1 promoter(Fig. 1G). Subsequent reporter assays were performed with cellscocultured with live H. pylori at an MOI of 100 for 24h.

Effects of virulence factors on cyclin D1 transcription in AGS cells. To assess the relationship between the virulence genes of H. pylori and cyclin D1 activation, AGS cells were cultured withisogenic mutant strain TN2- $Delta$ cagE, TN2- $Delta$ vacA, or TN2- $Delta$ PAI at anMOI of 100. Northern blot analysis showed that the induction ofcyclin D1 mRNA by TN2- $Delta$ cagE and TN2- $Delta$ PAI was significantly lessthan that by wild-type TN2; however, disruption of the vacA genedid not affect cyclin D1 induction (Fig. 2A).

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FIG. 2. Effects of virulence factors of H. pylori on cyclin D1 transcription. (A) AGS cells were infected with several isogenic mutant strains of H. pylori (TN2, TN2- $Delta$ cagE, TN2- $Delta$ PAI, and TN2- $Delta$ vacA) at an MOI of 100 for 90 min. Cyclin D1 mRNA was analyzed by Northern blot analysis. (B) AGS cells were transiently transfected with 200 ng of pD1luc and infected with different strains of H. pylori at an MOI of 100 for 24 h. Luciferase activity is presented as a relative ratio against the basal level measured in untreated cells. The values shown are the means ± the standard deviations of 10 independent experiments. *, P < 0.05 versus wild-type TN2. GAPDH, glyceraldehyde 3-phosphate dehydrogenase.

A luciferase reporter assay showed that TN2- $Delta$ cagE and TN2- $Delta$ PAI induced 4.5- and 3.7-fold increases in cyclin D1 promoter activity,respectively. The induction by TN2- $Delta$ PAI was significantly lessthan that by wild-type TN2 (P < 0.05). In contrast, TN2- $Delta$ vacAinduced a 6.7-fold increase in cyclin D1 promoter activity, avalue similar to that of wild-type TN2 (Fig. 2B).

MAP kinase activation is required for induction of cyclin D1 by H. pylori. Since cyclin D1 expression is regulated by MAP kinase cascades, we examined whether the MAP kinase cascade is involved inH. pylori-induced cyclin D1 transcription by using the specificMEK inhibitors U0126 and PD98059. U0126 (5 to 20 µM) and PD98059(50 to 200 µM) were added to the culture medium of AGS cells 2h before coculture with H. pylori. Activation of the cyclin D1promoter by H. pylori was markedly inhibited by each compoundin a dose-dependent manner (Fig. 3A and B), as was observed inthe cells treated with TPA (data not shown). U0126, at a doseof 20 µM, reduced cyclin D1 promoter activation to 34% (P < 0.05),and PD98059, at a dose of 200 µM, reduced promoter activationto 21% (P < 0.05). With the Northern blot analysis, preincubationof the cells with U0126 or PD98059 reduced cyclin D1 mRNA inductionby coculture with H. pylori (Fig. 3C).

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FIG. 3. Role of MAP kinase activation in the induction of cyclin D1 promoter by H. pylori. AGS cells transfected with pD1luc were infected with H. pylori at an MOI of 100 or left uninfected in the presence of the MEK inhibitor U0126 (A) or PD98059 (B) or dimethyl sulfoxide (DMSO) (control). Luciferase activity is presented as a relative ratio against the basal level measured in untreated control cells. The values shown are the means ± the standard deviations of more than three independent experiments. *, P < 0.05 versus H. pylori with DMSO preincubation. (C) Serum-starved AGS cells were infected with H. pylori at an MOI of 100 for 90 min in the presence of 20 µM U0126, 200 µM PD98059, or DMSO alone. Fifteen micrograms of total RNA was tested for cyclin D1 mRNA by Northern blot analysis. GAPDH: glyceraldehyde 3-phosphate dehydrogenase.

Effect of NF- $kappa$ B activation on H. pylori-induced cyclin D1 promoter transactivation. We examined the role of NF- $kappa$ B activation on H. pylori-induced cyclin D1 transcription since the type 1 strain of H. pylorican activate NF- $kappa$ B and cyclin D1 transcription is also reportedlyregulated by NF- $kappa$ B. We examined the effect of H. pylori on thepromoter constructs containing point mutations in the $kappa$ B sites(pD1- $kappa$ B1M, pD1- $kappa$ B2M, and pD1- $kappa$ B1/2M). These mutant reporters weretransfected into AGS cells instead of pD1luc, and luciferase expressioninduced by H. pylori was measured. Coculture with H. pylori causedabout a sixfold increase in the activation of luciferase expressionon each promoter construct (Fig. 4A).

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FIG. 4. Role of NF- $kappa$ B activation on H. pylori-induced cyclin D1 promoter transactivation. (A) AGS cells transiently transfected with 200 ng of pD1luc or a mutant reporter (pD1- $kappa$ B1M, pD1- $kappa$ B2M, or pD1- $kappa$ B1/2M) were infected with H. pylori at an MOI of 100 for 24 h or left uninfected. The luciferase activity of each reporter is presented as a relative ratio against the basal level measured in uninfected cells. The values shown are the means ± the standard deviations of five independent experiments. (B) AGS cells were transfected with various amounts of the dominant-negative I $kappa$ B $alpha$ expression vector together with pD1luc for 24 h. The total DNA amount was kept constant by supplementation with an empty vector (pcDNA3). The cells were infected with H. pylori at an MOI of 100 for 24 h or left uninfected. Luciferase activity is presented as a relative ratio against the basal level measured in uninfected control cells. The values shown are the the means ± the standard deviations of more than five independent experiments.

In addition, we cotransfected the dominant negative form of I $kappa$ B $alpha$ (SS32/36AA) with pD1luc to inhibit NF- $kappa$ B activation by H.pylori. Although activation of NF- $kappa$ B was completely inhibitedby this dominant-negative form of I $kappa$ B $alpha$ (22), induction of thecyclin D1 promoter was not reduced by the mutant of I $kappa$ B $alpha$ (Fig.4B). These data indicate that H. pylori transactivates the cyclinD1 promoter independently of NF- $kappa$ B activation in AGScells.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this study, we demonstrated that live H. pylori transactivates cyclin D1, one of the critical regulators of the cell cycle,in AGS cells in a time- and dose-dependent manner. Although manystudies have revealed that H. pylori induces cellular proliferation(9, 14, 16, 36, 37), the underlying mechanism has notyet been clarified. Our result indicating that H. pylori directlyaffects the cell cycle regulator molecule represents one possiblereason for cellular proliferation. Furthermore, overexpressionof cyclin D1 has been demonstrated to contribute to the oncogenictransformation of cells in vitro and in vivo (1, 4, 11,26, 48, 50). Although little is known about the relationshipbetween cyclin D1 and gastric cancer, transactivation of cyclinD1 and an accelerated cell cycle caused by H. pylori infectioncan be among the factors contributing to malignanttransformation.

We also demonstrated the effects of virulence genes of H. pylori on cyclin D1 activation. In a Northern blot analysis, TN2- $Delta$ cagEand TN2- $Delta$ PAI exerted weaker effects on H. pylori-induced cyclinD1 activation compared with wild-type TN2, while TN2- $Delta$ vacA inducedcyclin D1 transcription at a level similar to that of the wildtype. In the reporter assay, strains containing all of the cagPAI genes (TN2 and TN2- $Delta$ vacA) activated the promoter more stronglythan did strains partially or completely lacking cag PAI genes(TN2- $Delta$ cagE and TN2- $Delta$ PAI). Although we did not evaluate the cellcycle directly, these data may be compatible with a previous reportby Peek et al. which demonstrated that H. pylori possessing cagPAI accelerated the progression of the cell cycle from G₁ intoG₂-M in AGS cells at 6 h (37). We have recently demonstratedin the Mongolian gerbil model that TN2- $Delta$ cagE did not induce anysevere gastric diseases, in contrast to wild-type TN2 and TN2- $Delta$ vacA,in spite of the similar colonization abilities (33). Togetherwith other host responses such as transcriptional factor activation(18, 19, 22, 24, 25, 42) and apoptosis (17, 37),which can be enhanced by cag PAI-positive H. pylori, acceleratedcell proliferation may provide one of the reasons for the highprevalence of gastric cancer in patients suffering from cag PAI-positiveH. pylori (3, 21, 35).

It is not known, however, how cag PAI genes contribute to the differences in host response. Possibly only cag PAI-positivestrains transport certain molecules of H. pylori, which directlyactivate intracellular signal transduction. Some of the cag PAIgenes and their products have been thought to form a type IV secretionsystem (5, 7). Very recently, CagA protein was reportedto be transported into AGS cells by this secretion system andthe transportation was blocked by cagE knockout (2, 31, 45).However, since the mutant strains used in this study also weaklyinduced cyclin D1 transcription, the proteins transported by thissecretion system cannot be the sole molecules responsible forcyclin D1activation.

In the Northern blot analysis, an increased level of cyclin D1 mRNA was observed 60 to 120 min after coculture with H. pylori.The time-dependent increase in cyclin D1 mRNA levels was alsoobserved when MKN-28 cells were cocultured with H. pylori (datanot shown). This time lag suggests an involvement of intracellularsignal transduction. Cyclin D1 expression is regulated by manysignaling cascades, such as mitogenic stimuli and the MAP kinasecascade, inflammation and NF- $kappa$ B activation, and Wnt signaling(13, 20, 44, 47). Some of these signaling cascades areinvolved in H. pylori-mediated host responses. Thus, we determinedthe intracellular signaling pathway for H. pylori-induced cyclinD1activation.

The present results showing that MEK inhibitors reduced H. pylori-induced cyclin D1 activation suggest the involvement ofMAP kinase cascades. Since the cag PAI mutant strains are knownto be less potent in activating the MAP kinase cascades (19,24, 25), less activation of cyclin D1, as shown by the mutantstrains used in this study, is reasonable. We also performed invitro kinase assays to measure MAP kinase activity, and we confirmedthat H. pylori had the ability to activate MAP kinase, and thisability was correlated with the status of cag PAI (data not shown).On the other hand, the use of a mutant reporter plasmid of theNF- $kappa$ B binding site or dominant-negative I $kappa$ B $alpha$ expression vectorin the present study showed that NF- $kappa$ B activation is not requiredfor cyclin D1 transactivation in AGScells.

In conclusion, we have demonstrated that H. pylori activates cyclin D1 expression and that this activation is partly dependenton the cag PAI genes. Furthermore, cyclin D1 expression was activatedthrough the MAP kinase signaling pathway but not by activationof NF- $kappa$ B. It is possible that other signaling pathways which canbe induced by H. pylori exist, as well as another mechanism forcyclin D1 transactivation. These possibilities should be investigatedin futurestudies.

	ACKNOWLEDGMENTS

This study was supported in part by a Grant-in-Aid for Scientific Research from the Ministry of Education, Science, Sports,and Culture(11557040).

We appreciate the generous donation of plasmid constructs by M. Strauss and H. Suzuki, and we thank Mitsuko Tsubouchi forexcellent technicalassistance.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Gastroenterology, Faculty of Medicine, University of Tokyo, 7-3-1 Hongo,Bunkyo-ku, Tokyo 113-8655, Japan. Phone: 3-3815-5411, ext. 33056.Fax: 3-3814-0021. E-mail: HIRATAY-INT{at}h.u-tokyo.ac.jp.

Editor: J. D. Clements

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