Helicobacter pylori Activates the Histidine Decarboxylase Promoter through a Mitogen-activated Protein Kinase Pathway Independent of Pathogenicity Island-encoded Virulence Factors

doi:10.1074/jbc.275.5.3629

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Helicobacter pylori Activates the Histidine Decarboxylase Promoter through a Mitogen-activated Protein Kinase Pathway Independent of Pathogenicity Island-encoded Virulence Factors^*

Silja Wessler^§, Michael Höcker^§^¶, Wolfgang Fischer, Timothy C. Wang^**, Stefan Rosewicz^¶, Rainer Haas, Bertram Wiedenmann^¶, Thomas F. Meyer, and Michael Naumann

From the Max-Planck-Institut für Infektionsbiologie, Abteilung Molekulare Biologie, Berlin, the ^¶ Medizinische Klink mit Schwerpunkt Gastroenterologie und Hepatologie, Universitätsklinikum Charité, Campus Virchow-Klinikum, Humboldt Universität Berlin, the Max von Pettenkofer Institut für Medizinische Mikrobiologie und Hygiene, Abteilung Bakteriologie, 80336 München, Germany, and the ^** Gastrointestinal Unit and Department of Medicine, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts, 02114

ABSTRACT

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
REFERENCES

Helicobacter pylori infection of the gastric mucosa is accompanied by an activated histamine metabolism. Histamine plays acentral role in the regulation of gastric acid secretion and isinvolved in the pathogenesis of gastroduodenal ulcerations. Histidinedecarboxylase (HDC) is the rate-limiting enzyme for histamineproduction, and its activity is regulated through transcriptionalmechanisms. The present study investigated the effect of H. pyloriinfection on the transcriptional activity of the human HDC (hHDC)promoter in a gastric epithelial cell line (AGS) and analyzedthe underlying molecular mechanisms. Our studies demonstrate thatH. pylori infection potently transactivated the hHDC promoter.The H. pylori-responsive element of the hHDC gene was mapped tothe sequence +1 to +27 base pairs, which shows no homology toknown cis-acting elements and also functions as a gastrin-responsiveelement. H. pylori regulates the activity of this element viaa Raf-1/MEK/ERK pathway, which was activated in a Ras-independentmanner. Furthermore, we found that H. pylori-induced transactivationof the hHDC promoter was independent of the cag pathogenicityisland and the vacuolating cytotoxin A gene and therefore maybe exerted through (a) new virulence factor(s). A better understandingof H. pylori-directed hHDC transcription can provide novel insightsinto the molecular mechanisms of H. pylori-dependent gene regulationin gastric epithelial cells and may lead to new therapeuticapproaches.

INTRODUCTION

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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Helicobacter pylori has been identified as a major pathogen associated with the development of chronic gastritis and gastroduodenalulcer disease as well as gastric adenocarcinoma and mucosa-associatedlymphoid tissue lymphoma (1-5). H. pylori strains expressingthe vacuolating toxin A and genes encoded by the cytotoxin-associatedgene A (cagA)¹-associated pathogenicity island (PAI) have been considered associatedwith enhanced pathogenic potential of the bacterium (1, 6-8).Individuals infected with PAI-positive H. pylori strains displaymore severe courses of gastric inflammation and gastroduodenalulcer disease and appear to develop more frequently gastric adenocarcinomasand mucosa-associated lymphoid tissue lymphomas (9, 10).

The PAI represents a cluster of 31 genes that encode presumably a specialized secretion system that enables the bacteriumto expose or secrete particular proteins that are involved ininduction of intracellular signaling cascades of target cells(7). A molecular concept for the enhanced pathogenicity ofPAI-positive H. pylori strains has been provided by the observationthat genes located within the PAI are indispensable for activationof NF- $kappa$ B and AP-1 as well as stimulation of IL-8 production andsecretion in gastric epithelial cells and therefore seem to elicita more pronounced immune response (7, 11-15). In addition tocag-related genes, factors outside the PAI also appear to contributeto the differences in the pathogenic potential of H. pylori (16,17).

The gastric inflammatory response to H. pylori is characterized by mucosal infiltration of neutrophils and lymphocytes leadingto enhanced release of cytokines and chemokines (3, 18).In addition, increased gastric histamine secretion appears tocontribute to the inflammatory changes and tissue damage associatedwith chronic H. pylori infection of the gastric mucosa (19-21).Histamine represents the major stimulus controlling gastric acidsecretion and is produced and secreted by enterochromaffin-like(ECL) cells of the corpus mucosa (22-26). Histidine decarboxylase(HDC) is the key enzyme for histamine production in gastric ECLcells, and its enzymatic activity is to a large extent regulatedthrough enhanced transcription of the HDC gene (27-30). In additionto its central role in regulation of gastric acid secretion, increasedHDC gene expression has also been found to be associated withgastric inflammation and development of gastroduodenal ulceration(31-35). Furthermore, we found that oxidative stress, which iscommonly increased in ulcerative and inflammatory diseases affectingthe gastric mucosa, is capable of transactivating the hHDC promoterin vitro (36). Aside from its ulcerogenic potential, histaminehas also been shown to possess immunomodulatory properties inthe context of mucosal inflammations, contributes to the healingof ulcerative lesions of the gastric and intestinal mucosa, andhas also been shown to stimulate the growth of gastric epithelialcells (37-41). A current in vivo study demonstrated that H. pyloriinfection is associated with increased mucosal histamine levelsas well as an expansion of the gastric ECL cell lineage (42).The hypothesis that these changes could be at least in part beattributed to a direct effect of H. pylori on ECL cells has beensubstantiated by the finding that H. pylori can stimulate histaminesecretion from isolated rat ECL cells as well as ECL cell proliferationin vitro (43). Although these findings strongly suggested thatH. pylori can directly influence the histamine metabolism of gastricECL cells, potential molecular mechanisms that could underliethis effect areunclear.

It has been demonstrated that in gastric epithelial cells H. pylori infection elevates the abundance of "classical" secondmessenger molecules such as Ca²⁺, cyclic adenosine monophosphate (cAMP), and inositol trisphosphate(44). Although H. pylori has been shown to stimulate phosphorylationof several cellular proteins in gastric cancer cells in vitro(44, 45), intracellular signaling cascades activated by thebacterium are largely unknown. In a current study, we investigatedthe effect of H. pylori on the AP-1 transcription factor complexin gastric cancer cells in vitro and found that AP-1 activityis regulated by H. pylori through activation of c-Jun NH₂-terminalkinase (JNK) (13), which belongs to the superfamily of "mitogen-activatedprotein kinases" (MAP kinases) (46, 47). In addition to theJNK cascade, the MAP kinase superfamily comprises the extracellular-regulatedkinase (ERK) pathway (46). Although some overlap between bothpathways has been described (46), the JNK cascade activatesprimarily transcription factors involved in the "stress response"of eukaryotic cells, whereas the ERK pathway has been linked togenes involved in cellular proliferation and differentiation (46-48).Recently we demonstrated that ERK-related signaling cascades alsoplay a central role in the transmission of the effects of gastrinand oxidative stress on the hHDC promoter in gastric cancer cells,whereas the JNK pathway is not involved in hHDC gene regulation(36, 49). Therefore, it is highly likely that the ERK cascaderepresents a potential target signaling route through which activatorsof hHDC gene transcription exert their transactivating effecton the hHDCpromoter.

To investigate whether H. pylori can directly influence the transcriptional activity of the hHDC promoter, we performed invitro studies employing hHDC-luciferase reporter gene constructsas well as various hHDC promoter mutants. Furthermore, we aimedto analyze the signal transduction pathways and nuclear factorsresponsible for transmission of this effect on the hHDC promoter.Finally, we analyzed the virulence factors involved in regulationof the hHDC promoter by H. pylori.

EXPERIMENTAL PROCEDURES

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Cell Culture-- The human gastric adenocarcinoma cell line (AGS) was grown in RPMI 1640 (Life Technologies, Inc., Heidelberg, Germany) supplementedwith 4 mM glutamine, 100 units ml¹ penicillin, 100 µg ml¹ streptomycin, and 10% fetal calf serum (Life Technologies, Inc.)in a humidified 5% CO₂ atmosphere. AGS-B cells express the cholecystokinin-B/gastrinreceptor through stable transfection and were described before(30). Where indicated, cells were treated with 50 nM phorbol12-myristate 13-acetate (PMA, Sigma, St. Louis, MO) for 4 h ortreated with 200 ng/ml EGF (Promega, Heidelberg, Germany) for6 h. AGS-B cells were stimulated with 10⁷ M gastrin (Calbiochem, San Diego, CA) for 12 h. To block MEKactivation, cells were preincubated with 50 µM PD98059 (Calbiochem)for 30 min beforeinfection.

Bacteria and Infection-- The following H. pylori strains were used for infection experiments: P12 strains (wild type) and the isogenic cagA^* (cagA with a probable polar effect), vacA (50), and PAI (missingthe cag pathogenicity island (PAI); and G27 (wild type) and theisogenic cagI strain (8). For the construction of the PAI straintwo approximately 2-kb DNA fragments upstream of the cag-PAI (region545254-547164) and downstream of the PAI (584570-586563) (51)were amplified by polymerase chain reaction and cloned into pBluescriptseparated by a kanamycin resistance gene. The plasmid was transformedinto H. pylori (P12), and one transformant was analyzed by polymerasechain reaction for correct allelic exchange of the PAI with theresistance gene. H. pylori strains were grown on agar plates containing10% horse serum in a microaerophilic atmosphere (generated byCampy-Gen, Oxoid, Basingstoke, U. K.) at 37 °C for 48-72 h. 24h after infection H. pylori was harvested in phosphate-bufferedsaline (pH 7.4), diluted corresponding to the multiplicity ofinfection (m.o.i.), and incubated with the epithelial monolayer.Infection with H. pylori was monitored routinely by lightmicroscopy.

Transient Transfections and Luciferase Reporter Assays-- 24 h prior to transfection, cells were seeded in tissue culture plates and grown to 60-70% confluence. Transient transfectionsof 1-2 µg of reporter constructs were carried out using cationicliposomes (Dac-30, Eurogentec, Sart Tilman, Belgium) accordingto a protocol reported previously (13, 52). Transactivationof hHDC-luciferase reporter gene constructs was measured aftertransfection of 5'-deletion constructs (hHDC1000, hHDC480, hHDC400,hHDC125, +1 to +27 TK luc) as described previously (49, 53,54). Transactivation activity of NF- $kappa$ B and AP-1 was measuredas described previously (13, 52). Cotransfection of dominantnegative kinase cDNAs (DNERK1(K71R), DNERK2(K52R), DNRaf-1, DNRas15(G15A),DNRas17(S17N), and DNMEKK1(K432M)) with appropriate hHDC constructshas been described previously (49, 52). After transfectionthe cells were deprived of serum and maintained in RPMI 1640 supplementedwith 4 mM glutamine and 0.1% fetal calf serum for 20-24 h. Theexpression of the transfected dominant negative kinase constructswas controlled by immunoblotting. For measurement of transactivationactivity transfected cells were harvested, and luciferase activitywas assayed as recommended by the manufacturer's instructions(Promega). The results were recorded on a Wallac 409 $beta$ -counter(Berthold-Wallac, Bad Wildbach, Germany). The data represent themean ± S.D. calculated from three independent experiments as foldactivation compared with the control. Activities varied <15% amongtransfectionexperiments.

Immunoblotting-- To detect activated MEK1/2 and ERK1/2 total AGS cell extracts were prepared in 20 mM Tris (pH 7.5), 0.42 M NaCl, 1.5 mM MgCl₂,0.2 mM EDTA, 10 mM K₂HPO₄, 1 mM Na₃VO₄, 10 mM NaF, 1.25% NonidetP-40, and 10% glycerol. Equal amounts of protein extracts wereseparated in SDS-polyacrylamide gel electrophoresis and blottedon membranes. Western blot analysis was performed using phospho-specificantibodies (New England Biolabs, Beverly, MA) to detect pMEK1/2and pERK1/2. Each sample was probed with anti-MEK1 and anti-ERK2antibodies (Santa Cruz Biotechnology, Santa Cruz, CA) to indicateequivalent protein amounts in all lanes. To detect I $kappa$ B $alpha$ , sampleswere probed with an anti-I $kappa$ B $alpha$ antibody (Santa Cruz Biotechnology,Santa Cruz,CA).

Electrophoretic Mobility Shift Assay (EMSA)-- Nuclear extracts were prepared by using a non-ionic detergent method as described previously (55). For the detection ofgastrin-responsive element (GAS-RE) DNA binding activity, equalamounts of nuclear protein extracts were incubated with labeledoligonucleotides containing the +1 +27 GAS-RE binding site sequenceof the human HDC promoter:

5'-ACCCTTTAAATAAAGGGCCCACACTGG-3'

5'-CCAGTGTGGGCCCTTTATTTAAAGGGT-3'.

The oligonucleotide containing the GAS-RE recognition site was labeled using T4 kinase (Roche Molecular Biochemicals GmbH,Mannheim, Germany) in the presence of [ $gamma$ -³²P]ATP. The DNA binding reactions were performed using a bindingbuffer containing 10 mM Tris (pH 7.5), 2 µg of poly(dI-dC), 1µg of bovine serum albumin, 10 mM MgCl₂, 100 mM KCl, 1 mM EDTA,1 mM dithiothreitol, and 4% Ficoll for 20 min at room temperature.For competitions, increasing amounts of an unlabeled oligonucleotidewere included in the bandshift reaction. The DNA binding activityof NF- $kappa$ B was performed with an Ig $kappa$ oligonucleotide as describedpreviously (55). The DNA binding reactions were performed usinga binding buffer containing 20 mM HEPES (pH 8.4), 60 mM KCl, 5mM dithiothreitol, 1 µg of bovine serum albumin, 2 µg of poly(dI-dC),and 10% glycerol for 20 min at 30 °C. The reaction products wereanalyzed by electrophoresis in a 6% polyacrylamide gel using 12.5mM Tris, 12.5 mM boric acid, and 0.25 mM EDTA (pH 8.3). The gelswere dried and exposed to Amersham TM films (Amersham PharmaciaBiotech) at $-$ 70 °C using an intensifyingscreen.

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H. pylori Infection Stimulates HDC Promoter Activity through a Minimal 27-Base Pair Promoter Element-- AGS cells were transiently transfected with the hHDC1.8kb-luc construct and colonized with H. pylori (P12) at different m.o.i.values for 4 h. H. pylori stimulated hHDC promoter activity ina m.o.i.-dependent manner already at a m.o.i. of 5 compared withnoninfected cells (Fig. 1A). Further increase of the infection-doseup to a m.o.i. of 50 raised the hHDC promoter activity to maximalstimulation.

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Fig. 1. H. pylori stimulates the transcriptional activity of the hHDC promoter. A, AGS cells were transiently transfected with 1 µg of the 1.8-kb hHDC-luciferase construct and colonized with H. pylori (P12) at different m.o.i. values for 4 h or left untreated ( $-$ ). B, identification of the H. pylori-responsive element of the hHDC promoter by 5'-deletion analysis. AGS cells were transiently transfected with a series of hHDC 5'-deletion constructs or with the empty vector (control) and infected with H. pylori (P12) at a m.o.i. of 50 for 4 h. In addition, a construct in which luciferase expression is under the control of a single copy of the hHDC +1 to +27 bp element was used. Shown is the fold luciferase activity of three independent experiments against the noninfected cells. C, H. pylori stimulates the binding of nuclear proteins to the hHDC +1 to +27 bp element. To determine the influence of H. pylori infection of AGS cells on the binding of nuclear proteins to the hHDC +1 to +27 bp element, the hHDC +1 to +27 bp sequence was used in EMSAs as ³²P-labeled probe. Nuclear extracts were prepared from AGS cells after infection with H. pylori (P12) at a m.o.i. of 50 (lanes 1-4) or treatment with 50 nM PMA (lanes 5-7) for different periods of time. For competitions, the indicated amounts of an unlabeled +1 to +27 oligonucleotide were used (lanes 8-10). Only the sections of protein-DNA complexes of the autoradiograms are shown. The position of the protein-DNA complex is indicated.

To identify the H. pylori-responsive element of the hHDC promoter sufficient for the transcriptional response, we analyzeda series of hHDC 5'-deletion constructs (Fig. 1B). Removal ofnucleotides from the 5'-end down to 125 bp upstream of the Capsite (+1) had no significant influence on the H. pylori-inducedluciferase activity. Similar results were obtained in cells treatedwith PMA (data not shown). Because this region comprises the +1to +27 bp GAS-RE of the hHDC proximal promoter, we used a luciferaseconstruct in which the GAS-RE sequence hHDC +1 to +27 was ligatedupstream of the enhancerless herpes simplex virus 1 thymidinekinase (TK) promoter. We found that this element was capable ofconferring H. pylori responsiveness to the same extend as thelongest hHDC 5'-flankingfragments.

To underline that the GAS-RE is activated by H. pylori through enhanced binding of nuclear factors, we analyzed the DNA bindingactivity of nuclear proteins to the +1 to +27 sequence in EMSAs.Enhanced binding of AGS nuclear proteins was observed within 30min postinfection (Fig. 1C, lanes 1-4). Treatment of AGS cellswith PMA, a strong inducer of hHDC promoter activity, resultedin a strong increase of DNA binding activity of transcriptionfactors within 10 min (Fig. 1C, lanes 5-7). Because H. pylori-and PMA-induced complexes produced identical bandshifts it canbe concluded that the H. pylori-stimulated complex consists ofGAS-RE-binding proteins (GAS-RE-BPs). This was further confirmedby the finding that the complex stimulated by H. pylori couldbe competed away by an excess of unlabeled hHDC +1/+27 bp oligonucleotide(Fig. 1C, lanes 8-10). Based on these data, H. pylori was identifiedto induce very specific (m.o.i. of 5-50) enhanced hHDC promoteractivity through activation of the GAS-RE-BP1/2 transcriptionfactors that bind to the +1 to +27 bp minimalelement.

Activation of the hHDC Promoter Is Independent of cag-PAI-encoded Gene Expression-- To investigate the role of cag genes for activation of the hHDC promoter by H. pylori, AGS cells were colonized with differentisogenic mutants lacking certain cag genes. AGS cells transfectedwith the 1.8-kb hHDC-luc construct exerted after infection withH. pylori wild type strains (P12 and G27) a strong increase inluciferase activity (Fig. 2A, left panel). Similar activationwas obtained in AGS cells, infected with isogenic mutants, lackingthe vacA, cagA*, and cagI genes. Additionally, the isogenic H.pylori strain PAI, which lacks the entire PAI, potently inducedthe hHDC promoter activity, supporting the notion of a cag-independentactivation of the hHDC promoter by H. pylori. In contrast, inAGS cells transfected with a reporter gene construct in whichluciferase expression was under control of the NF- $kappa$ B consensuselement of the HIV promoter, H. pylori mutants lacking cagA*-cagI genes or the entire PAI did not stimulate reporter gene expression(Fig. 2A, right panel). The cag-independent activation of theHDC promoter activity was also investigated by EMSA. EnhancedDNA binding of the GAS-RE-BP1/2 to the HDC enhancer element wasobserved in AGS cells infected with any H. pylori (Fig. 2B, lane1-8, left panel). Using the Ig $kappa$ -NF- $kappa$ B oligonucleotide to detectNF- $kappa$ B DNA binding activity, colonization with the H. pylori strainsP12, vacA, and G27 induced strong activation of NF- $kappa$ B (Fig. 2B,lanes 1-3 and 6, right panel), whereas the knockout mutants cagA*,cagI, and PAI showed a strongly reduced NF- $kappa$ B DNA binding activity(Fig. 2B, lanes 4, 7, and 8, right panel).

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Fig. 2. H. pylori-induced activation of the hHDC promoter is independent of the expression of vacA and cag genes. A, AGS cells were transfected with 1 µg of the 1.8-kb hHDC promoter luciferase construct and infected with H. pylori strains P12 and G27, their isogenic mutants vacA, cagA*, PAI, and cagI at a m.o.i. of 50 for 4 h, or left untreated ( $-$ ) (left panel). As a control, the effect of H. pylori on NF- $kappa$ B-dependent transactivation was analyzed in AGS cells transfected with 0.5 µg of a HIV-NF- $kappa$ B luciferase reporter construct (right panel). Results of three independent experiments are expressed as fold induction compared with the control. B, the influence of various isogenic H. pylori mutants on the binding of nuclear factors to the hHDC +1 to +27 bp element was analyzed after infection of AGS cells with H. pylori strains at a m.o.i. of 50. For EMSAs, nuclear extracts were prepared after a 60-min infection with H. pylori strains and analyzed for DNA binding activity to the hHDC +1 to +27 bp sequence using this sequence as a probe (left panel). As a control, nuclear extracts were analyzed for NF- $kappa$ B DNA binding activity using a ³²P-labeled probe representing a consensus Ig $kappa$ NF- $kappa$ B binding site. For these experiments, nuclear extracts were prepared after a 90-min infection with H. pylori strains (right panel). Only the sections of protein-DNA complexes of the autoradiograms are shown. The positions of protein-DNA complexes are indicated with arrows.

H. pylori-stimulated hHDC Promoter Activity Involves Activation of the ERK/MEK Kinases-- To study the signaling that is induced by H. pylori in a cag-independent manner, we investigated the capability of H. pylorito induce activation of certain MAP kinase pathways. Subconfluentmonolayers of AGS cells were infected with H. pylori (P12), andcell lysates were prepared after different time points postinfectionand analyzed for activated and phosphorylated ERK1/2 and MEK1/2by Western blot analysis using phospho-specific antibodies. H.pylori activated both ERK1 and ERK2 in AGS cells within 30 minafter infection (Fig. 3A, lanes 1-5), comparable to the activationinduced by stimulation with PMA (Fig. 3A, lanes 6-9). Similarresults were obtained using phospho-specific antibodies to detectactivated MEK1/2. MEK1 and MEK2 were also phosphorylated within30 min after H. pylori infection or PMA treatment (Fig. 3B, lanes1-9). To investigate whether the H. pylori-induced activationof the ERK/MEK kinases is cag-independent, we studied the effectsof the H. pylori mutants on the activation of ERK1/2 and MEK1/2.In contrast to the AP-1-activating kinase pathway (13) the infectionof AGS cells with H. pylori knockout mutants (vacA, cagA, PAI,and cagI) in all cases stimulated activation of ERK1/2 and MEK1/2(Fig. 3A and B, right panel). As a control, we used the same extractsto analyze the H. pylori-infected cells for degradation of theNF- $kappa$ B inhibitor I $kappa$ B $alpha$ . Colonization of AGS cells with H. pylori(P12) for different periods of time resulted in decreasing amountsof I $kappa$ B $alpha$ (Fig. 3C, lanes 1-5) as well as treatment of the cellswith PMA (Fig. 3C, lanes 6-8). Corresponding to the NF- $kappa$ B activation(Fig. 2B, lower panel), I $kappa$ B $alpha$ is degraded in response to infectionwith H. pylori strains P12, vacA, and G27 (Fig. 3C, lanes 10,11, and 14) but remains unaffected after infection with H. pyloristrains cagA*, PAI, and cagI (Fig. 3C, lanes 12, 13, and 15).These data indicate that H. pylori infection has the capacityto induce ERK/MEK activation independent of H. pylori cag geneexpression.

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Fig. 3. Infection with H. pylori stimulates phosphorylation of ERK1/2 and MEK1/2 kinases. AGS cells were infected with H. pylori (P12) at a m.o.i. of 100 or stimulated with 50 nM PMA for the indicated time points (left panels). Studying the H. pylori mutants, AGS cells were infected for 30 min (right panels). Cells were lysed, and 30 µg of lysates were separated by SDS-polyacrylamide gel electrophoresis and blotted onto membranes. Phosphorylation of ERK1/2 (A) and MEK1/2 (B) was detected using phospho-specific antibodies in Western blot analysis (upper panels). As a loading control, the same amounts of the cell lysates were blotted and probed with non-phospho-specific anti-ERK2 and anti-MEK1 antibodies (lower panels). Additional bands, beside ERK2 and MEK1, observed in some lanes represent a cross-reactivity with other antigens recognized by the antibodies. C, as an additional control we determined the I $kappa$ B $alpha$ abundance in response to H. pylori colonization using an I $kappa$ B $alpha$ antibody for immunodetection. The positions of the recognized proteins are indicated.

To examine whether these H. pylori-activated MAP kinases are involved in the upstream signaling regulating the hHDC promoteractivity, we cotransfected AGS cells with the 1.8-kb hHDC-luciferaseconstruct and dominant negative ERK1 (DNERK1) and ERK2 (DNERK2)constructs. Infection of AGS cells with H. pylori or PMA treatmentresulted in a 3-fold induction of the HDC promoter activity comparedwith nontreated cells (Fig. 4A, left panel). After cotransfectionof single inhibitory kinase constructs (DNERK1 or DNERK2), theH. pylori- and PMA-stimulated transactivation activity of theHDC promoter was completely inhibited, just as after expressionof both DNERK1 and DNERK2 together. As an additional control weused the AGS-B cell line, which has been stably transfected withthe human cholecystokinin-B/gastrin receptor (30). Cells exposedto gastrin reacted with a strong increase of the hHDC promotertransactivation activity after 12 h, which was diminished by expressionof DNERK1 and DNERK2 mutants (Fig. 4A, left panel). The selectiveeffect of the DNERK1 and DNERK2 kinase constructs was demonstratedusing a luciferase construct driven by a HIV-NF- $kappa$ B enhancer element.In contrast to the PMA-induced NF- $kappa$ B transactivation, overexpressionof dominant negative mutants of ERK1 and ERK2 did not block theH. pylori-induced NF- $kappa$ B transactivation (Fig. 4A, right panel).These data indicate a strong and selective involvement of ERKkinases in the HDC promoter-activating pathway.

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Fig. 4. H. pylori-induced hHDC promoter activity involves ERK and MEK kinases. A, AGS cells were transfected with 1 µg of the 1.8-kb hHDC promoter luciferase construct and either 0.5 µg of a dominant-negative ERK1 mutant (DNERK1), 0.5 µg of an ERK2 mutant (DNERK2) (or in combination 0.25 µg for each construct), or empty vector. The total amount of plasmid DNA was kept constant. Transfected cells were either infected with H. pylori (P12) at a m.o.i. of 50, treated with 50 nM PMA for 4 h, treated with 10⁷ M gastrin (AGS-B cells) for 12 h, or left untreated (left panel). Further, as a control AGS cells were transfected with a NF- $kappa$ B-dependent luciferase reporter construct (HIV/NF- $kappa$ B Luc) and DNERK constructs (right panel). B, to determine the role of the upstream ERK-activating kinase MEK, AGS cells were transfected with 1 µg of the 1.8-kb hHDC reporter construct and treated with 50 µM PD98059 (PD) for 30 min followed by infection with H. pylori (P12) at a m.o.i. of 50 or treatment with 50 nM PMA for 4 h (left panel). Further, as a control, AGS cells were transfected with a NF- $kappa$ B-dependent luciferase reporter construct and treated as described above (right panel). The data represent the means ± S.D. calculated from three independent experiments as fold induction compared with the control.

To block MEK activation in response to H. pylori colonization, we preincubated the AGS cells with the MEK-selective inhibitorPD98059. Pretreatment of AGS cells for 30 min with 50 µM PD98059resulted in a total inhibition of the hHDC promoter transactivationactivity induced by H. pylori, indicating the involvement of MEKin the upstream signaling of the hHDC promoter activity (Fig.4B, left panel). The selectivity of the targeted kinases was alsoinvestigated using a HIV-NF- $kappa$ B luciferase construct. The H. pylori-inducedNF- $kappa$ B transactivation was not affected by PD98059 pretreatment(Fig. 4B, right panel).

Raf-1-dependent Activation of the hHDC Promoter in Response to H. pylori Colonization-- Possible upstream activators of MEK1/2 are represented by molecules like Raf-1 or MEKK1 (MEK kinase 1) (46). Cells expressinga DNRaf-1 construct and infected with H. pylori or treated withPMA or gastrin were analyzed for transactivation activity of thehHDC promoter. Compared with mock-transfected cells, the hHDCpromoter transactivation activity was strongly reduced (Fig. 5A,left panel), whereas expression of DNRaf-1 had no influence onthe activation of NF- $kappa$ B induced by H. pylori (Fig. 5A, right panel).These data lead to the suggestion that the Raf-1 kinase lies upstreamin the specific signal pathway leading to MEK/ERK-directed activationof the hHDC promoter. The possible role of MEKK1 in the H. pylori-inducedactivation of the hHDC promoter was investigated using constructsexpressing DNMEKK1. Colonization of transiently transfected AGScells with H. pylori or treatment with PMA induced hHDC promoteractivity that was not affected by overexpression of dominant negativeMEKK1 (Fig. 5B, left panel). To show the functional dominant negativeeffect of the MEKK1 construct, we cotransfected the DNMEKK1 cDNAwith the AP-1 luciferase construct. Expression of DNMEKK1 inhibitedthe EGF-induced AP-1 activation (Fig. 5B, right panel).

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Fig. 5. H. pylori-stimulated activation of the hHDC promoter involves Raf-1 but not MEKK1. A, AGS cells were transfected with 1 µg of 1.8-kb HDC reporter construct and either 0.5 µg of dominant negative Raf-1 (DNRaf-1) or empty vector. Transfected cells were either infected with H. pylori (P12) at a m.o.i. of 50, treated with 50 nM PMA for 4 h, treated with 10⁷ M gastrin (AGS-B cells) for 12 h, or left untreated (left panel). As a control, AGS cells were transfected with 0.5 µg of the HIV-NF- $kappa$ B reporter reporter construct and 0.5 µg of DNRaf-1 (right panel). B, AGS cells were transfected with 1 µg of the 1.8-kb HDC reporter construct and either 0.5 µg dominant negative MEKK1 (DNMEKK1) or empty vector. Transfected cells were colonized with H. pylori (P12) at a m.o.i. of 50 or treated with 50 nM PMA for 4 h, or left untreated (left panel). As a control, AGS cells were transfected with 1 µg of an AP-1 luciferase reporter construct and 1 µg of DNMEKK1 and stimulated with 200 ng/ml EGF for 6 h (right panel). Results of three independent experiments are expressed as fold induction of untreated cells.

Activation of the H. pylori-induced hHDC Promoter Activity Based on a Ras-independent Signaling-- The small G-protein Ras is one known upstream regulator of Raf-1. In the following we studied whether Ras activation contributesto the stimulation of the hHDC promoter activity. To explore thecapacity of Ras to induce H. pylori-mediated hHDC promoter activity,we tested if dominant negative Ras (DNRas15 and DNRas17) blocksactivation of the hHDC promoter. In contrast to the inhibitionby DNERKs and DNRaf-1, neither DNRas15 nor DNRas17 blocks theH. pylori-induced hHDC promoter activity (Fig. 6, left panel),whereas the EGF-induced AP-1 transactivation activity was inhibitedsignificantly by expression of DNRas15 and DNRas17 (Fig. 6, rightpanel).

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Fig. 6. H. pylori transactivates the hHDC promoter through a Ras-independent mechanism. AGS cells were transfected with 1 µg of the 1.8-kb hHDC-luc construct and with 0.5 µg of the dominant negative Ras mutants DNRas15 or DNRas17 or empty vector. Transfected cells were infected with H. pylori (P12) at a m.o.i. of 50 or treated with 50 nM PMA, or left untreated for 4 h (left panel). As a control, AGS cells were cotransfected with 0.5 µg of the AP-1 luciferase reporter construct and 0.5 µg for the dominant negative Ras mutants DNRas15 or DNRas17, respectively, and treated with 200 ng/ml EGF for 6 h (right panel). Results of three independent experiments are expressed as fold induction compared with the activity in the absence of H. pylori, PMA, or EGF.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

In the present study we demonstrated that colonization of a permanent gastric epithelial cell line with H. pylori stimulatesthe transcriptional activity of the hHDC promoter in vitro. Furthermore,we found that the transactivating effect of H. pylori is independentof the vacA gene and genes encoded by the cag-associated pathogenicityisland, which have been implemented in more severe clinical outcomesof chronic gastric H. pylori infections (1, 7, 8). Theanalysis of cis- and trans-activating factors involved in H. pylori-dependenthHDC regulation revealed that a proximal element at + 1 to +27bp, which has been identified previously to be responsible forgastrin-dependent regulation of the hHDC gene, is also mediatingthe effect of H. pylori on the hHDC promoter (53, 54).

H. pylori has been shown to stimulate the expression of proinflammatory cytokines such as IL-1 $beta$ , IL-6, tumor necrosis factor- $alpha$ ,and IL-8 (18, 19). Studies about H. pylori-induced IL-8 secretion(11, 14, 15) demonstrated that activation of NF- $kappa$ B is acentral mechanism through which H. pylori transactivates the IL-8gene promoter, whereas the H. pylori-dependent transactivationof the hHDC promoter does not involve NF- $kappa$ B. The proximal hHDC+1 to +27 element does not display any homology to known transcriptionfactor binding sites, and competition studies with oligonucleotidesrepresenting consensus binding elements of various known transcriptionfactors demonstrated that this element is not bound by NF- $kappa$ B orother well characterized nuclear factors such as AP-1, Sp1, orCREB (53). The view that H. pylori-dependent transactivationof the hHDC promoter does not require NF- $kappa$ B is substantiated furtherby the finding that isogenic H. pylori mutants (cagA, PAI, cagI),which were not able to transactivate a NF- $kappa$ B-luciferase reportergene construct, stimulated the binding of nuclear proteins tothe hHDC +1 to +27 element and transactivated a hHDC 1.8-kb luciferasereporter construct in AGS cells. Therefore, it can be concludedthat the hHDC +1 to +27 bp element represents a new nuclear targetsequence of H. pylori through which the bacterium can influencegene expression independent of vacA- or PAI-encoded genes in gastricepithelial cells (Fig. 7).

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Fig. 7. Model of the signal transduction pathways induced by H. pylori in gastric epithelial cells leading to acid secretion and an innate immune response. The H. pylori-directed signaling comprises the activation of the HDC promoter and the promoters of proinflammatory cytokines and other immunomodulatory genes. Infection with H. pylori induces in a cag-independent manner the activation of a MAP kinase cascade (Raf-1/ERK/MEK) resulting in an activation of two novel transcription factors (BP1/2). In a cag-dependent manner, H. pylori induces stress response kinase signaling, which leads to the activation of the immediate early response transcription factors AP-1 and NF- $kappa$ B, low molecular mass Rho-GTPases, and sequential activation of the protein kinases PAK, MKK4, and JNK, which directs c-Jun phosphorylation controlling AP-1 activation. The solid arrows indicate direct activation of downstream targets, and the dotted arrows indicate indirect activation through an unknown component.

Previous analysis of the nuclear proteins regulating the hHDC +1 to +27 bp element demonstrated that it is bound by two sofar unknown transcription factors (54). These proteins witha molecular size of 35 and 52 kDa, respectively, were termed GAS-RE-BPsbecause their binding to the +1 to +27 element is indispensablefor full gastrin responsiveness of the hHDC promoter (54). Similarto gastrin and PMA, H. pylori infection of AGS cells stimulatedbinding of nuclear proteins to this element. EMSA analysis ofH. pylori- and PMA-stimulated AGS cells demonstrated that thenuclear proteins stimulated by both factors displayed identicalbandshifts. Additionally, the H. pylori-induced complex bindingto the hHDC +1 to +27 sequence could be competed away with anexcess of cold +1 to +27 bp oligonucleotide. Therefore, it appearsvery likely that the transcription factors binding to the +1 to+27 bp element in response to H. pylori represent the previouslydescribed GAS-RE-BPs. Because the GAS-RE-BPs represent two noveltranscription factors, further analysis of these factors may leadto the identification of genes that have so far not been linkedto the epithelial response to H. pylori. Further, our findingsindicate that in addition to the well characterized vacA and caggenes, H. pylori expresses (a) virulence factor(s), which enable(s)the bacterium to activate alternative target genes. The fact thatthis/these factor(s) appear to be independent of genetic regionsthat have been associated with enhanced pathogenic potential ofH. pylori strains indicates that additional gene loci outsidethe so far characterized virulence factors may contribute to theoverall pathogenesis of H. pylori on the gastricmucosa.

To understand the molecular pathways by which the effect of H. pylori colonization of AGS cells is transmitted into the nucleus,we analyzed signal transduction cascades involved in H. pylori-dependenthHDC transactivation. We found that the transactivating effectof H. pylori is transmitted via a signaling cascade comprisingERKs and their upstream activating kinases MEK and Raf-1, respectively.ERKs and MEKs are activated by H. pylori colonization with a similartime course showing peak phosphorylation after 30 min of infection.In contrast to the effect of H. pylori on the hHDC promoter, activationof NF- $kappa$ B and AP-1 by the bacterium strictly required cag geneexpression (13). Therefore, the virulence factor(s) underlyingH. pylori-dependent activation of Raf-1/MEK/ERK-dependent signalingcascades resulting in enhanced HDC transcription appear(s) toact independently of the bacterial factors controlling the acutecytokine response featuring activation of stress response signalingpathways and NF- $kappa$ B activation (Fig. 7). Our results indicate thatdifferent virulence factors of H. pylori are capable of activatingdistinct branches of the MAP kinases signaling system, which appearto result in transactivation of different epithelial target genes.This observation further suggests that dependent on the virulencefactors expressed, H. pylori strains may be able to elicit a differentialepithelial signaling response, which may lead to transactivationof a specific set ofgenes.

A recent study described that incubation of KATO III gastric carcinoma cells with H. pylori supernatants resulted in inhibitionof ERK-signaling stimulated by EGF and that this effect was vacuolatingtoxin A-dependent (56). In contrast to this study, we foundthat exposure of AGS cells to two different strains of intactH. pylori (P12 and G27) resulted in enhanced MEK/ERK phosphorylation.Furthermore, in contrast to the findings by Pai et al. (56),the effect of H. pylori on the MEK/ERK cascade was vacuolatingtoxin A-independent. Although we did not investigate the effectof H. pylori on EGF-stimulated ERK signaling in the AGS model,the robust ERK/MEK phosphorylation in response to intact H. pyloridemonstrates that the bacterium is capable of stimulating thismitogenic pathway. Activation of the MEK-1/ERK cascade by classicalmitogens such as EGF is typically induced through activation ofRas and Raf-1 (46). Because application of two different dominantnegative Ras mutants did not influence the transactivating effectof H. pylori on the HDC promoter, the functional involvement ofRas in this context is unlikely. Previous studies from our laboratorydemonstrated that alternatively to the Ras/Raf-1 sequence, theMEK/ERK cascade in AGS cells can also be activated through a Ras-independent,protein kinase C/Raf-1-dependent pathway (49). Whether proteinkinase C-dependent signaling events are involved in the couplingof the Raf/MEK/ERK cascade to upstream signaling events triggeredby H. pylori is currently under investigation in ourlaboratory.

Based on the clinical data currently available, the exact impact of H. pylori-stimulated HDC transcription on the overallpathophysiology of H. pylori in the stomach is currently unclearand has to be further clarified in in vivo studies. It can bespeculated that dependent on the onset, duration, and/or intensityof activation, enhanced H. pylori-stimulated hHDC transcriptioncould contribute to either tissue damage or processes of mucosalrestitution and repair in the stomach (32, 33, 37, 38).Furthermore, a direct effect of H. pylori on HDC gene expressionresulting in enhanced histamine production and secretion couldhelp to maintain an acidic gastric environment, favoring the survivalof H. pylori over non-acid-resistant bacteria. Overall, H. pylori-dependenttransactivation of the hHDC gene represents a new molecular modelfor the interaction of the bacterium with gastric epithelial cells.Our data for the first time demonstrate that H. pylori is capableof activating a gastric target gene through an ERK-dependent signalingpathway, independent of vacuolating toxin A- and PAI-related virulencefactors. Therefore, a detailed analysis of the molecular mechanismsunderlying the effect of H. pylori on the hHDC gene could contributeto a better understanding of the molecular pathogenesis of H.pylori infections and could probably lead to new approaches forthe treatment of H. pylori-associated gastricdiseases.

ACKNOWLEDGEMENTS

We appreciate the generous supply of plasmid constructs by John K. Westwick, Melanie H. Cobb, Richard A. Maurer, KathleenKelly, Natalie G. Ahn, Michael Karin, John M. Kyriakis, and GeoffreyM.Cooper.

	FOOTNOTES

^* This study was supported in part by Deutsche Forschungsgemeinschaft Grants NA 292/6-1 (to M. N.) and HO 1288/6-1 (to M. H.),by Fonds der Chemischen Industrie grants (to M. N. and T. F. M.),and by Verum Stiftung and Mildred Scheel Stiftung grants (to B.W.).The costs of publication of this article were defrayed inpart by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

^§ The first two authors contributed equally to thiswork.

To whom correspondence should be addressed: Max-Planck-Institut für Infektionsbiologie, Abteilung Molekulare Biologie, Monbijoustrasse2, 10117 Berlin, Germany. Tel.: 49-30-28460-410; Fax: 49-30-28460-401;E-mail: naumann@mpiib-berlin.mpg.de.

ABBREVIATIONS

The abbreviations used are: cagA, cytotoxin-associated gene A; PAI, pathogenicity island; NF- $kappa$ B, nuclear factor $kappa$ B; AP-1, activator protein 1; IL, interleukin; ECL, enterochromaffin-like; HDC, histidine decarboxylase; hHDC, human HDC; JNK, c-Jun NH₂-terminal kinase; MAP kinase, mitogen-activated protein kinase; ERK, extracellular signal-regulated kinase; PMA, phorbol 12-myristate 13-acetate; EGF, epidermal growth factor; MEK, mitogen-activated protein kinase/extracellular signal-regulated kinase kinase; kb, kilobase(s); TK, thymidine kinase; m.o.i., multiplicity of infection; I $kappa$ B $alpha$ , inhibitory protein $kappa$ B $alpha$ ; luc, luciferase; EMSA, electrophoretic mobility shift assay; GAS-RE, gastrin-responsive element; bp, basepair(s); GAS-RE-BP, GAS-RE-binding protein; HIV, human immunodeficiency virus.

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