Heterogeneity in the Activity of Mexican Helicobacter pylori Strains in Gastric Epithelial Cells and Its Association with Diversity in the cagA Gene

Helicobacter pylori CagA is translocated into gastric epithelialcells by a type IV secretion system and interacts with the Srchomology 2 phosphatase, altering cell morphology. Multiple EPIYAmotifs in CagA are associated with increased activity in cellsand with gastric cancer. The aim of this work was to study theheterogeneity in activity in cells of multiple H. pylori singlecolonies isolated from a single patient and its associationwith polymorphism in cagA. The presence of cagA, cagE, cagT,and cag10 was studied with 318 H. pylori isolates from the antraand corpora of 18 patients. AGS gastric epithelial cells wereinfected with 75 isolates, and interleukin-8 (IL-8) secretion,cytoskeletal changes, CagA translocation, and tyrosine phosphorylationwere measured. The cagA 3'-variable region was sequenced for30 isolates to determine the number and types of EPIYA motifs.Isolates from an individual stomach were usually geneticallyrelated and had quantitatively similar phenotypic effects oncells (IL-8 induction and cytoskeletal changes). However, strainsfrom different patients with similar CagA EPIYA motif patternsvaried widely in these phenotypes. Among isolates with an EPIYA-ABCpattern, the phenotype was variable: IL-8 induction ranged from200 to 1,200 pg/ml, and morphological changes occurred in 20to 70% of cells. In several cases, cagA sequence diversity appearedto explain the lack of CagA activity, as isolates with an EPIYA-ACCpattern or a modified B motif had reduced cell activity. cagpathogenicity island-positive H. pylori isolates displayed ahigh level of heterogeneity in the capacity to induce IL-8 secretionand morphological changes; an absent or modified B motif wasassociated with low activity.

INTRODUCTION

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INTRODUCTION

Helicobacter pylori infects up to 50% of the world's human population,lives for decades in the human stomach (17), and is associatedwith duodenal ulcers (16), gastric ulcers, distal gastric adenocarcinoma,and gastric mucosa-associated lymphoid tissue lymphoma (13).Its ability to cause disease has been associated with the expressionof several virulence factors, including the VacA cytotoxin (5,6), BabA (19), the neutrophil-activating protein (HP-NAP) (30,38), outer inflammatory protein A (OipA) (50), the duodenalulcer-promoting gene (dupA) (28), and the cag pathogenicityisland (cagPAI). The cagPAI is a 40-kb region originally acquiredhorizontally and inserted into the glutamate racemase gene (1,15); it is present in about 50 to 60% of H. pylori isolatesfrom Western countries and in >90% of isolates from EastAsian countries. Some studies have shown that severe gastroduodenaldiseases are associated with H. pylori strains that harbor anintact cagPAI (11, 22, 24, 26, 29, 32, 33), whereas other studiescould not find a relationship (7, 25).

Genes in the cagPAI encode a type IV secretion system (17) throughwhich CagA is translocated into gastric epithelial cells, whereit is phosphorylated by Src kinases on the tyrosine residuesof a five-amino-acid (EPIYA) motif (10, 34, 40, 44). Once phosphorylatedCagA interacts with Src homology 2 (SHP-2) phosphatase, it stimulatesdownstream signaling cascades involved in the reorganizationof the cytoskeleton, resulting in cellular morphological changessuch as the "hummingbird" phenotype, which is characterizedby a prominent elongation and spreading of host cells, includingthe production of filopodia and lamellipodia (20, 39). Attachmentof H. pylori to gastric epithelial cells also induces the productionof interleukin-8 (IL-8), mobilizing inflammatory cells to thesite of infection in a process involving NF- ${kappa}$ B activation (36,42, 43). Recently, some authors reported that IL-8 release mightbe mediated by mitogen-activated protein kinases through tyrosinephosphorylation of CagA (14, 27).

The cagA gene contains a 5' end which is highly conserved anda 3' end which is variable. The 3'-variable region containsseveral repeat sequences, each of which contains an EPIYA motif;the size variation in CagA correlates with the number of repeatsequences located in this region (47). EPIYA motifs in WesternH. pylori isolates are classified as EPIYA-A, EPIYA-B, and EPIYA-Cand are defined by the amino acid sequences surrounding theEPIYA motifs. It has been suggested that the number of EPIYA-Csites directly correlates with the level of tyrosine phosphorylation,SHP-2 binding activity, and cell damage. CagA proteins in EastAsian H. pylori isolates possess EPIYA-A, EPIYA-B, and EPIYA-Dmotifs; the EPIYA-D motif has a higher affinity for SHP-2 thandoes the Western EPIYA-C motif and appears to induce more severecellular changes (21).

Evidence showing that CagA proteins with more EPIYA motifs aremore frequent in strains associated with cases of atrophic gastritisand gastric cancer than in strains from patients with chronicgastritis has been presented, suggesting an association betweenthe size of the 3'-variable region of cagA and the clinicaloutcome (8, 9). In South Africa, H. pylori strains with fourto six EPIYA motifs and higher CagA molecular weights were isolatedfrom patients with gastric cancer (4). In addition, the studydemonstrated that when H. pylori is cocultured with gastricepithelial cells, a correlation between the size of the CagAprotein, the magnitude of tyrosine phosphorylation, and theintensity of cellular elongation exists (4). Similar resultshave been reported for strains from Chinese patients (51).

Several studies have addressed the correlation between geneticdiversity in the cagPAI and disease, but few have reported onphenotypic diversity regarding the cellular activities of multipleisolates obtained from single patients. Accordingly, the aimof this work was to study phenotypic diversity in the activityin gastric epithelial cells of multiple H. pylori single coloniesisolated from single patients and to correlate this diversitywith the polymorphisms observed in the 3'-variable region ofthe cagA gene.

(Part of this work was submitted as a requirement for the D.Sc.degree of Adriana Reyes-Leon at Doctorado en Ciencias Biomedicas,Universidad Nacional Autonoma de Mexico.)

MATERIALS AND METHODS

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MATERIALS AND METHODS

Patients. We studied 10 children with chronic abdominal pain (seven boysand three girls) attending the Gastroenterology Department atthe Hospital de Pediatria, Centro Medico Nacional Siglo XXI(CMN-SXXI), Instituto Mexicano del Seguro Social (IMSS), MexicoCity, Mexico, with a mean age of 10.7 years (ranging from 7to 16 years), and eight adults (five men and three women) attendingthe Gastroenterology Department at the Hospital de Especialidades,CMN-SXXI, IMSS, with a mean age of 57.2 years (ranging from28 to 88 years). Three adult patients had gastric ulcers, fourhad duodenal ulcers, and one had nonulcer dyspepsia. Patientswere subjected to endoscopy as part of the usual diagnosticprotocol, and two biopsies each were taken from the antrum andcorpus; one biopsy from each region was used to culture H. pylori.The study was approved by the ethics committee of the Hospitalde Pediatria at CMN-SXXI, IMSS.

Helicobacter pylori culture and isolation of multiple single colonies from biopsies. Antrum and corpus biopsy specimens were placed in sterile 0.9%saline solution, homogenized, and inoculated onto blood agarbase (BBL, MD) plates supplemented with 5% sheep blood. Theplates were incubated at 37°C in a 9% CO₂ atmosphere forup to 5 days. H. pylori was identified by colony and microscopicmorphology and by positive oxidase, catalase, and urease tests.From each primary growth, 7 to 10 single colonies each wereisolated from the antrum and corpus and propagated on bloodagar medium. We studied a total of 200 isolates from children(mean of 20 per patient) and 118 isolates from adults (meanof 15 per patient).

Detection of cagPAI genes. DNAs were isolated from confluent plate cultures of each isolate,using the commercial Wizard method (Promega Corporation, Madison,WI) according to the manufacturer's instructions. DNAs fromH. pylori strains 84-183 (ATCC 53726), 26695 (ATCC 700392),and Tx30a (ATCC 51932) were prepared for use as controls. ThecagE, cagT, and cag10 genes were selected for study becausethey are distributed along the cagPAI and because they are homologousto known genes in type IV secretion systems; in addition, cagAwas studied because it encodes the protein which is translocatedby this system. The presence of these genes was evaluated inthe 318 H. pylori isolates by PCRs using specific primers (Table1). Two sets of primers were used for each gene examined, exceptfor the cag10 gene (Table 1). All PCR mixtures consisted of1 µl of chromosomal DNA template (100 ng), 1x PCR buffer,1.5 mM MgCl₂, a 0.2 mM concentration of each deoxynucleosidetriphosphate (Boehringer Mannheim, Germany), 25 pmol of eachprimer, and 1.25 units of Taq DNA polymerase (Invitrogen, LifeTechnologies, Brazil) in a final volume of 25 µl. PCRswere performed in a thermal cycler (GeneAmp PCR system 9700;PE Applied Biosystems). Positive (strains 26695 and 84-183)and negative (strain Tx30a) controls for the cagPAI were includedin each run. To test for the absence of the cagPAI, we usedthe cag empty-site assay with primers 2 and 25, which flankthe left and right ends of the cagPAI (1). The PCR conditionsfor each reaction were described previously (1, 24, 29, 37,47, 51). PCR products were electrophoresed, stained with ethidiumbromide, and visualized under UV light.

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TABLE 1. Specific primers used to identify cagPAI genes in this study

To confirm the PCR results, dot blot hybridization was performedas follows. The PCR products for the cagA, cagE, cagT, and cag10genes were amplified with specific primer pairs F1 and B1, 101and 102, cagT-F and cagT-R, and cag10-F and cag10-R, respectively,using chromosomal DNA from strain 84-183. PCR products wereelectrophoresed, and appropriate fragments (probes) were purified(Rapid Gel extraction system; Marligen Bioscience) and radioactivelylabeled with [ ${alpha}$ -³²P]dCTP by random primer extension (MegaprimeDNA labeling system kit; Amersham Pharmacia Biotech). Hybridizationwas performed using Hybond-N⁺ nylon membranes (Amersham PharmaciaBiotech), using 20 ng of genomic DNA per spot for each isolate.Membranes were incubated with the probes, washed, and processedfor autoradiography with X-ray film (Kodak).

RAPD-PCR method. Random amplified polymorphic DNA PCRs (RAPD-PCRs) were carriedout in a 25-µl volume containing 20 ng of H. pylori genomicDNA, 2.5 µl of 10x PCR buffer, 3.5 mM MgCl₂, 20 pmol ofprimer 1254 or 1281 (Table 1), a 0.25 mM concentration of eachdeoxynucleoside triphosphate (Boehringer Mannheim, Germany),and 1.2 units of Taq DNA polymerase (Invitrogen, Life Technologies,Brazil), as previously reported (2). An aliquot of 20 µlof PCR product was electrophoresed in a 2% agarose gel at 80V, stained, and visualized.

Sequencing of the 3'-variable region of the cagA gene. The 3'-variable region of cagA was amplified with primers cag2and cag4 (37) (Table 1), and nucleotide sequencing was performedusing the dideoxynucleotide chain termination method with aBigDye Terminator v3.1 cycle sequencing kit (Applied Biosystems)in an ABI PRISM 377 automated DNA sequencer (Applied Biosystems),as previously described (8). Nucleotide and derived amino acidsequences were analyzed and aligned with the Chromas (version1.62; Technelysium) and DNAMAN (version 3.0; Lynnon BioSoft)programs.

Biological activities of H. pylori on gastric epithelial cells. For translocation, phosphorylation, and IL-8 induction assays,the AGS cell line (ATCC CRL-1739) was grown in 75-cm² flaskswith Ham's F-12 nutrient mixture (GIBCO, Invitrogen Corporation)supplemented with 10% heat-inactivated fetal bovine serum (F-12-10%FBS) (GIBCO, Invitrogen Corporation, USA) at 37°C in a 5%CO₂ atmosphere for 48 h. Next, serum-free F-12 medium was added,and cells were incubated for an additional 24 h. For cellularelongation assays, AGS cells (1 x 10⁵/ml) were grown in six-wellplates with F-12-10% FBS for 48 h. H. pylori strains to be testedwere grown for 48 h in blood agar plates, and a single colonywas reseeded on an agar plate and incubated for 24 h. H. pyloricolonies were harvested and resuspended in serum-free F-12 mediumto reach an optical density of 0.1 at 550 nm (1.2 x 10⁸ bacteria/ml)before addition to AGS cells at a multiplicity of infectionof 1:100. AGS cells in either 75-cm² flasks or six-well plateswere cocultured with H. pylori isolates in serum-free F-12 mediumfor up to 48 h (see below). H. pylori strains 26695 and 60190(ATCC 49503) were used as positive controls.

After coculture for 6 h, the cell culture supernatant was collectedand stored at –80°C until it was tested for IL-8 induction.The amount of IL-8 in each sample was measured by an enzyme-linkedimmunosorbent assay, using an OptEIA human IL-8 kit (BD Biosciences)following the manufacturer's instructions. Cells were then washedtwice with phosphate-buffered saline (PBS) containing 1 mM calciumchloride and 0.5 mM magnesium chloride, scraped from the flasksinto 5 ml PBS containing 1 mM sodium vanadate, harvested bycentrifugation at 1,000 x g for 10 min, and resuspended in 100µl PBS-sodium vanadate and 50 µl 4x sample loadingbuffer (0.2 M Tris-HCl, pH 6.8, 0.4 M dithiothreitol, 8% sodiumdodecyl sulfate, 40% glycerol, 0.4% bromophenol blue). Sampleswere boiled and analyzed by sodium dodecyl sulfate-polyacrylamidegel electrophoresis. Proteins were separated in 9% polyacrylamidegels, electrotransferred to nitrocellulose membranes by standardprocedures, and examined for the presence of the CagA proteinby using a polyclonal antibody (1:1,000) (bN-20; Santa CruzBiotechnology). Phosphorylated tyrosine was detected with amonoclonal antibody (1:3,000) (PY99; Santa Cruz Biotechnology).Blots were then incubated with horseradish peroxidase-conjugatedrabbit anti-goat and goat anti-mouse antibodies (Zymed Laboratories,CA) and developed with ECL Western blotting detection reagents(Amersham Biosciences, Piscataway, NJ). In some cases, translocatedCagA was detected using sera from infected patients (1:50 dilutionin PBS) with high levels of anti-CagA antibodies, incubatedwith a peroxidase-conjugated goat antibody to human immunoglobulinG (Zymed Laboratories, CA) (1:1,000 dilution), and developedwith ECL Western blotting detection reagents (18).

For induction of cellular elongation of AGS cells, AGS cellsinfected with H. pylori isolates were incubated for up to 48h. Cells were then examined for cellular elongation by lightmicroscopy (magnification, x20), reading three randomly chosenfields (4); results were reported as percentages of cells exhibitingthe cellular elongation effect.

Each isolate was tested for IL-8 induction, CagA translocationand phosphorylation, and cellular elongation in two separateexperiments, with each sample run in duplicate in each assay.

H. pylori adherence and viability during coinfection. To assess H. pylori adherence to AGS cells, coinfections weremonitored by light microscopy (x40) during different periodsto visualize bacteria attached to cells and bacterial mobility.The viability of the inoculated bacteria was monitored 1, 24,and 48 h after coinfection; for this purpose, an aliquot of10 µl of a 1:100 dilution of the cell culture supernatantwas taken, spread on blood agar plates, and cultured for 48h.

Statistical analysis. A two-tailed Student t test was used to assess the relationshipof cagPAI⁺ and cagPAI^– strains to induction of IL-8 releaseand cellular elongation in AGS cells. A P value of <0.05(two-sided) was considered statistically significant.

Nucleotide sequence accession numbers. Nucleotide sequences were deposited in GenBank under accessionnumbers EF552407 to EF552424.

RESULTS

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RESULTS

Presence of cagA, cagE, cagT and cag10 genes. Among the 318 H. pylori isolates studied, 250 isolates (78.6%)had all four cagPAI genes (cagA, cagE, cagT, and cag10) (cagPAI⁺)and 48 isolates (15.1%), which were positive for the PCR emptysite, did not have the cagPAI genes (cagPAI^– isolates)(Table 2). In all 20 isolates from patient 365, cagA was absent,but cagE, cagT, and cag10 were present, indicating a partialdeletion in the cagPAI. Patient 259 was colonized with bothcagPAI⁺ and cagPAI^– isolates, which had different RAPDpatterns (data not shown), showing evidence of a mixed infection(Table 2).

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TABLE 2. Characteristics of H. pylori isolates tested for the presence of the cagPAI, the size of the cagA 3' region, and activity on cells

The 3'-variable region of the cagA gene was amplified from the250 cagA-carrying isolates. There was diversity in the sizeof the fragment among isolates, with PCR products showing lengthsof between 500 and 850 bp (Table 2). Although in the majorityof cases all isolates from a patient showed the same length,in three cases (patients 555, 259, and 261) isolates presenteddifferent sizes for the cagA 3'-variable region. For patient555, 19 isolates had a cagA fragment size of 550 bp and onehad a size of 650 bp. Patient 261 had one isolate with a cagAfragment of 800 bp, whereas all others had a size of 550 bp(Table 2 and Fig. 1); analysis by RAPD-PCR showed that thisvariation was due to infection with multiple H. pylori strains.For patient 259, most isolates had a fragment size of 550 bpand two isolates had a size of 500 bp (Table 2 and Fig. 1);RAPD-PCR analysis showed that these isolates were of the samestrain, with polymorphic variation in the 3' region.

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FIG. 1. Determination of the size of the cagA 3'-variable region by PCR. PCR products from single-colony isolates from different patients or from the same patient (259, 261, and 555) showed size variation. Lane M, molecular size marker.

Diversity in IL-8 secretion by AGS cells cocultured with cagPAI⁺ and cagPAI^– isolates. We selected a group of 75 H. pylori isolates, 62 of which werecagPAI⁺, 4 of which had a partial cagPAI (cagA negative), and9 of which were cagPAI^–, to analyze their ability to induceIL-8 secretion (Fig. 2A). Among the cagPAI⁺ H. pylori isolatestested, wide diversity in the ability to induce IL-8 secretionwas observed, with IL-8 levels which ranged from <50 to over1,500 pg/ml. IL-8 levels induced by cagPAI^– isolates andby isolates with a partial cagPAI (cagA negative) were below200 pg/ml in all cases, which is significantly lower than levelsinduced by cagPAI⁺ isolates (Fig. 2A).

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FIG. 2. Diversity in biological activities on AGS cells of 62 cagPAI⁺ isolates, 4 isolates with a partial cagPAI (cagA negative), and 9 cagPAI^– isolates. (A) Induction of IL-8 expression. (B) Induction of cellular elongation. The intensities of both activities varied considerably among the cagPAI⁺ isolates and were significantly higher than those of partial cagPAI and cagPAI^– isolates. Horizontal lines indicate mean values. The results represent the means for three independent experiments. The cutoff values for both activities were estimated as the means plus 3 standard deviations of the values obtained with the Tx30a reference strain and nine cagPAI^– isolates.

Isolates from individual patients, on the whole, gave similarresults (Fig. 3). However, wide variation was seen between patients.For further analysis, we developed a definition of a non-IL-8-inducingisolate; using a cutoff value of the mean plus 3 standard deviationsof the values obtained with the Tx30a reference strain and thenine cagPAI^– isolates (<200 pg/ml), 16 of the 62 cagPAI⁺isolates were defined as negative for IL-8 induction (25.8%).Among these 16 isolates, 5 isolates were from patient 646 (6isolates), 3 were from patient 248 (4 isolates), and a fractionof isolates were from patients 648, 555, 259, 256, 249, and261 (Fig. 3).

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FIG. 3. Diversity in the induction of cellular elongation and IL-8 secretion by multiple cagPAI⁺ H. pylori strains, isolates with a partial cagPAI, and cagPAI^– isolates from single patients. Patient numbers are indicated on the x axis, and intensities of cell activities are shown on the y axes. Horizontal lines indicate mean values, and bars indicate standard deviations. The results represent the means for three independent experiments.

Diversity in the induction of cellular elongation in AGS cells cocultured with cagPAI⁺ and cagPAI^– isolates. AGS cells were infected with the same 75 H. pylori isolatesthat were tested for IL-8 induction. Among the H. pylori cagPAI⁺isolates tested, there was wide diversity in the ability toinduce cellular elongation, with values ranging from <10%to over 70% of cells affected. cagPAI^– isolates and isolateswith a partial cagPAI (cagA negative) induced elongation in<20% of the cells (Fig. 2B); these values were significantlylower than those induced by cagPAI⁺ isolates. In general, isolatesfrom the same patient induced similar values, although widevariation was seen between patients. Most strains inducing highlevels of IL-8 also caused the most cytoskeletal changes, althoughthere were clear exceptions (e.g., patients 307, 475, 249, and261)(Fig. 3). We defined the cutoff value for cellular elongationas the mean plus 3 standard deviations of the values obtainedwith the Tx30a reference strain (negative control) and ninecagPAI^– isolates (<20%). Using this cutoff value, 11of the 62 (17.7%) cagPAI⁺ isolates were negative for cellularelongation, with 4 of 4 isolates from patient 248 and a fractionof isolates from patients 648, 646, and 555 being negative (Fig.3).

H. pylori adherence and viability during coinfection. cagPAI⁺ isolates with low or high activity on AGS cells weremonitored for adherence and viability. Both types of isolates,either positive or negative for cell activity, showed similarpatterns of adherence to AGS cells, which increased over time,as shown in Fig. S1 in the supplemental material; the mobilityof bacteria was evident during the 48 h of the assay. ViableH. pylori cells (>10¹⁰ CFU/ml) could be recovered on agarplates even after 48 h of coinfection with both types of isolates;in addition, images show the growth of H. pylori colonies onthe surfaces of AGS cells after hours of coinfection (see Fig.S1 in the supplemental material). In summary, no differencewas observed in adherence, mobility, or viability between isolateswith low or high activity on cells.

Translocation and phosphorylation of CagA in AGS cells. The above results showed that H. pylori cagPAI⁺ isolates hadvariable effects on AGS cells. To further study this variability,we analyzed the translocation and phosphorylation of the CagAprotein in the same 75 isolates in AGS cells. We observed differencesin the size of the CagA proteins, which correlated with variationin the size of the 3'-variable region of cagA (Fig. 4). Accordingto our results, 58 of the 62 cagPAI⁺ isolates tested had CagAtranslocated and phosphorylated within AGS cells. In the remainingfour isolates (all from patient 236), the CagA protein was notrecognized by the commercial polyclonal anti-CagA antibody (bN-20)we used; however, the translocated CagA protein was recognizedby the anti-phosphorylated tyrosine antibody (PY99) (Fig. 4).In addition, the CagA proteins from these isolates were recognizedby immunoglobulin G in sera from two H. pylori-infected patients(see Fig. S2 in the supplemental material).

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FIG. 4. Translocation and phosphorylation of the CagA protein in AGS cells infected with cagPAI⁺ and partial cagPAI-carrying H. pylori isolates. Western blot analysis of CagA translocation into AGS cells was performed with a polyclonal anti-CagA antibody, and detection of CagA phosphorylation was done with an anti-phosphotyrosine monoclonal antibody. Isolate 365a3 is a partial cagPAI-carrying (cagA negative) isolate; all other isolates (from 646a5 to 249c5) are cagPAI⁺. Isolate 236c6 was negative for Western blotting with anti-CagA but positive with anti-phospho-Tyr. Isolates with variability in biological activity levels are marked with circles or squares.

As expected, the isolates with a partial cagPAI, with absenceof the cagA gene, and the cagPAI^– isolates did not expressthe CagA protein and did not have phosphorylated CagA in AGScells. Of interest, the cagPAI⁺ isolates that were noninducersof either cellular elongation or IL-8 secretion were still ableto translocate and phosphorylate CagA in AGS cells, althoughin several cases (such as isolate 648a9) phosphorylation wasweak (Fig. 4).

Diversity in the biological activities of multiple H. pylori isolates from single patients. Heterogeneity in the activities of multiple isolates from singlepatients on AGS cells was analyzed. Although most isolates fromsingle patients were rather homogeneous with regard to cellactivity (Fig. 3), significant diversity was observed in somecases. Isolates from patients 555, 256, and 259 displayed ahigh level of diversity in both cellular elongation and IL-8induction. In addition, we identified isolates causing a strongcellular elongation phenotype which were negative for IL-8 induction(from patients 555, 646, 249, 256, 259, and 261). Isolates negativefor cellular elongation but positive for IL-8 induction (frompatients 555, 648, and 248) were also found, although in allthese cases induction of IL-8 was rather weak (Fig. 3).

Sequencing of the 3'-variable region of the cagA gene. From the 62 cagPAI⁺ H. pylori isolates tested in the above studies,we chose 30 isolates for sequencing, representing the differentsizes in the 3' region of the cagA gene and different levelsof activity on AGS cells (Table 2). For all 30 of these isolates,cagA had the Western type sequence (Fig. 5). The number of EPIYAmotifs varied among these isolates; 20 isolates (66.6%) hadthree motifs, 5 (16.7%) had four motifs, and 5 (16.7%) had fivemotifs. The majority of the isolates with three EPIYA motifswere of the ABC type, and only two isolates (from patient 646)were of the ACC type, with a deletion between the A and C motifs.All 20 of these isolates had a 3' cagA size of $≤$ 570 bp (Table2). The isolates with four EPIYA motifs were of the ABCC type,and all had a 3' cagA size of 650 bp. Among the five isolateswith five EPIYA motifs, two were of the ABCCC type and threewere of the ABABC type, and they had 3' cagA sizes of between800 and 850 bp (Table 2).

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FIG. 5. Deduced amino acid sequences of C-terminal repeat regions of CagA from cagPAI⁺ isolates that were positive or negative for induction of IL-8 or cellular elongation (Hm). The EPIYA-A, -B, and -C motifs and the SHP-2 binding site after the EPIYA-C motif are underlined, and the Western sequence type is shaded.

Isolates from patient 259 yielded 3' cagA PCR products of 500bp (isolates c2 and c4) and 550 bp (isolates a1 and a6); thesePCR products were sequenced. Compared with isolates a1 and a6,isolate c2 had a deletion of $~$ 24 amino acids after the EPIYA-Cmotif (Fig. 5); of interest, another isolate from the corpus,c4, also showed a deletion after the EPIYA-C motif, althoughthis was shorter ( $~$ 15 amino acids). All isolates from this patientshowed similar RAPD patterns, suggesting that they were thesame strain. However, isolate c2 was negative for IL-8 induction,while isolates a1, a6, and c4 were positive, suggesting thatthe long deletion after the EPIYA-C motif might be associatedwith a loss of biological activity. Among the 20 isolates testedfrom patient 555, 19 had a 3' cagA size of 550 bp and an ABCpattern, whereas one had a size of 650 bp (a9) and an ABCC pattern.Isolate a9 displayed higher levels of IL-8 secretion and cellularelongation than did isolates with the ABC pattern; isolate a9had a different RAPD pattern, implying that it was a differentcoinfecting strain. Fourteen isolates were tested from patient261; 13 had a 3' cagA size of 550 bp and an ABC pattern, whereasone had a size of 800 bp (c1) and an ABABC pattern. IL-8 secretionand cellular elongation levels were lower in the isolate withthe ABABC pattern. Isolate c1 also had a different RAPD pattern(data not shown), implying that it was a different coinfectingstrain (Fig. 3). Thus, of three patients with isolates differingin the size of the 3' cagA region, two had mixed infectionsand one had the same strain with polymorphism in the 3' sequence.

Association of the sequence in the 3' region of cagA with activity on AGS cells. We next analyzed the sequence of the 3'-variable region, searchingfor a possible association with activity on cells, especiallyfor isolates which lacked activity on AGS cells. There was noclear association between the number and type of EPIYA motifsand the ability to induce IL-8 secretion or cellular elongation(Fig. 6). However, several interesting results were found inthe sequences for isolates negative for both cellular elongationand IL-8 induction; some had an EPIYA-ACC pattern (patient 646)(Fig. 5), suggesting the importance of the EPIYA-B motif forcell activity. Isolates from patient 248 with an EPIYA-ABC patternhad a modified B motif (B* [EPTYA]); three of four isolateswere negative for IL-8 induction, and all four were negativefor induction of cellular elongation (Fig. 6). Isolates frompatient 307 with an EPIYA-ABCC pattern had a different modificationof the B motif (B^& [EPIYT]) and induced lower levels ofcellular elongation and IL-8 secretion than did isolates withthe normal ABCC pattern (Fig. 6).

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FIG. 6. Relationship between EPIYA patterns and the ability to induce both IL-8 secretion and cellular elongation for 30 cagPAI⁺ H. pylori isolates from our population. Isolates without the B motif (ACC pattern; patient 646) or with a modified B motif (EPTYA; patient 248) had a significantly weaker cellular elongation phenotype.

For isolates from patient 236 that were cagA positive but whoseprotein products were not recognized by the commercial anti-CagApolyclonal antibody (Fig. 1), we observed a short insertionof five amino acids (DKGPE) before the EPIYA-A motif which wasnot observed for isolates from any other patient (Fig. 5); ofinterest, isolates from this patient caused moderate IL-8 andcellular elongation induction (Fig. 3).

DISCUSSION

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DISCUSSION

cagA is a highly polymorphic gene with diversity in its 3'-endregion, which is important for the biological activity of theencoded protein on gastric epithelial cells. This region encodesthe tyrosine phosphorylation site and the SHP-2 phosphatasebinding site. The interaction of these proteins activates aseries of signaling pathways, causing an increase in proliferationand abnormal cell motility (45, 46). It is therefore importantto extend studies on polymorphism in this 3' region of cagAacross populations and to correlate this diversity with thebiological activities of strains. In the present study, we addressedboth the extent of polymorphism in the cagA gene and the diversityin the biological activities of Mexican strains on gastric epithelialcells.

To better describe the extent of polymorphisms, we chose tostudy multiple single colonies isolated from different sitesof the stomach of individual patients. All isolates from theantra and corpora of 13 of the 18 patients studied had a homogeneouscagPAI content, one had a partial cagPAI content (patient 365),and for only one patient was a mixed infection with cagPAI⁺and cagPAI^– strains documented (patient 259). However,in spite of the rather homogeneous gene content in the cagPAI,diversity in the sequence of the cagA 3' region was observedin isolates from three patients. In one case, the multiple isolateswere found to be of the same strain (patient 259), and in twocases, the strains were not the same as those documented byRAPD analysis (patients 555 and 261); thus, mixed infectionwas documented in two cases and polymorphism in the 3' regionwas shown for one patient.

Once we had determined that most isolates in this study werepositive for the cagPAI, we next analyzed phenotypic diversityby studying the heterogeneity in the activities of these isolateson epithelial cells. cagPAI^– isolates and isolates witha partial cagPAI (cagA negative) induced very low levels ofcellular elongation (<20%) and IL-8 (<200 pg/ml), as expected.On the other hand, even among isolates positive for the fourgenes of cagPAI tested, including cagA, there were a numberof isolates which were unable to induce IL-8 secretion or cellularelongation, which suggests that the mere presence of the cagPAIis not sufficient for these activities. In several of thesecases, low phosphorylation of CagA might explain the low cellactivity, but in others negative activity was observed in spiteof the translocation and phosphorylation of CagA. It shouldbe stressed that in all cases, the CagA protein was translocatedand phosphorylated, suggesting the presence of a functionaltype IV secretion system. Polymorphisms in the 3' cagA regionexplained many of these cases and illustrate the importanceof the EPIYA-B motif; thus, strains lacking this motif (ACCpattern) were unable to induce either IL-8 secretion or cellularelongation, an observation which has not been reported previously.In addition, strains with a modified B motif (EPTYA) also displayedweak activity, which further confirms the importance of thewhole motif for cell activity. Deletions after the EPIYA-C motifwere also associated with either a low or absent biologicalactivity. These results show that negative or weak IL-8 or cellularelongation induction in cagPAI⁺ isolates might be due to specificmodifications in the CagA sequence. In accordance with theseresults, Brandt et al. recently reported that among cagPAI⁺strains there are high and low IL-8 inducers, and this variabilitywas associated with the number of EPIYA motifs and the aminoacid residues surrounding these motifs, stressing the need forCagA to induce IL-8 in epithelial cells (14). The diversityin the activities of different cagPAI⁺ H. pylori isolates onAGS cells does not appear to be influenced by the degree ofadherence of the isolates to AGS cells or their ability to growduring the coinfection experiment, since we found similar adherenceand growth on AGS cells by H. pylori isolates with either highor low cell activity.

Of note, among the cagPAI⁺ isolates, the range of IL-8 inductionvaried as much as 30 times (from 50 to over 1,500 pg/ml), andthe intensity of induction of cellular elongation varied over15 times (from 5 to 80%); such wide diversity has not been documentedpreviously, and as discussed below, polymorphisms in the cagAgene partially explain this diversity. Higashi et al. describedthat the variation in biological effects of CagA is caused bythe variation in the number and sequence of tyrosine phosphorylationsites (21). This correlation was not observed in our study,as exemplified by the fact that IL-8 and cellular elongationactivities of isolates with an ABC pattern varied from no tohigh induction. The amount of CagA translocated and phosphorylatedhad a correlation with low activity in several isolates butnot in others. As discussed above, in some of these cases variationsin the sequence of the B motif might explain the observed lowactivity on cells. Still, when cellular elongation was analyzed,the degree of induction tended to increase in the directionACC $->$ AB*C $->$ ABC $->$ ABCC $->$ ABABC, which partially agrees with previous reports(4, 31). This correlation was not observed for IL-8 induction,which is also in agreement with previous reports (3, 4, 35)and confirms that although the role of CagA in both activitiesis controversial, the mechanism of action is different for eachactivity (41). This is further supported by the fact that isolatesfrom six patients displayed a moderate or strong cellular elongationactivity but no IL-8 induction. Some reports have proposed akey role for cagE in IL-8 induction (35); however, our resultsdisagree with this, as all isolates with negative or low IL-8induction had the cagE gene present. Still, we cannot discardthe possibility that like the case for cagA, sequence diversityin cagE might cause differences in IL-8 induction. Other authorshave also reported that H. pylori can induce NF- ${kappa}$ B activation(and IL-8 secretion), via Nod1, in epithelial cells that respondto peptidoglycan delivered to the cytoplasm of the cell by thetype IV secretion system encoded by the cagPAI (49).

When phenotypic diversity was analyzed in multiple isolatesfrom a single patient, with all isolates representing uniquestrains, in many cases a rather homogeneous degree of activitywas documented among the isolates. However, there were patientsfor whom the activities of the isolates on cells varied over10 times. Some of these cases might be explained by polymorphismsin the cagA sequence among the colonizing isolates; sequencediversity, insertions, or deletions were documented in suchcases. However, in other cases, such diversity cannot be explainedby heterogeneity in the cagA sequence, and polymorphisms inother genes of the cagPAI or outside the island might help toexplain this diversity. It should be noted that isolates ofa single patient classified as the same isolate with tests suchas RAPD or amplified fragment length polymorphism analysis maystill show variation in the gene content of 3 to 5% of the genome(12, 23), and this variation may cause phenotypic diversity.The mechanisms responsible for the observed diversity in thesepatients deserve further study.

An interesting case was patient 236, whose H. pylori strainproduced a CagA protein which could not be recognized by thecommercial antibody used in this study; sequence studies showedthat it had a five-amino-acid insertion before the EPIYA-A motif.Conceivably, this might cause changes in the structure of theprotein sufficient to avoid recognition by particular antibodies.However, this modified protein was still recognized by serumfrom the same patient from whom the strain was isolated as wellas by sera from other patients.

In conclusion, our study documents a high level of diversityin the ability of cagPAI⁺ strains to induce both IL-8 productionand cellular elongation in epithelial cells; such diversitymight be explained partially by polymorphisms in the 3' regionof cagA. Another novel observation was the finding that isolateslacking the EPIYA-B motif (pattern ACC) or with a modified Bmotif displayed a negative or weak activity on epithelial cells;to our knowledge, such a possible association has not been reportedpreviously. We documented important diversity in the activitiesof isolates from single patients on cells, which in some, butnot all, cases could potentially be explained by polymorphismsin cagA.

ACKNOWLEDGMENTS

This work was partially supported by CONACYT, Mexico (SectorialSalud; grant CO1-6957). J.T. is a recipient of a Fundacion IMSSexclusivity scholarship.

FOOTNOTES

* Corresponding author. Mailing address: Unidad de Investigación Medica en Enfermedades Infecciosas y Parasitarias, Hospital de Pediatría, Centro Medico Nacional Siglo XXI, Instituto Mexicano del Seguro Social (IMSS), Av. Cuauhtemoc 330, Mexico, DF CP 06725, Mexico. Phone: 5627-6940. Fax: 5627-6949. E-mail: jtorresl57{at}yahoo.com.mx

Published ahead of print on 16 April 2007.

Supplemental material for this article may be found at http://iai.asm.org/.

Editor: F. C. Fang

REFERENCES

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