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Infection and Immunity, October 2002, p. 5503-5511, Vol. 70, No. 10
0019-9567/02/$04.00+0     DOI: 10.1128/IAI.70.10.5503-5511.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

Representational Difference Analysis between Afa/Dr Diffusely Adhering Escherichia coli and Nonpathogenic E. coli K-12

Institut National de la Santé et de la Recherche Médicale (INSERM), Unité 510, Faculté de Pharmacie Paris XI, 92296 ChÂtenay-Malabry,¹ INSERM U411, Faculté de Médecine Necker-Enfants Malades, 75730 Paris,² Unité de Pathogénie Bactérienne des Muqueuses, Institut Pasteur, 75724 Paris, France,⁴ Department of Microbiology, Immunology, and Parasitology, Universidade Federal de Sao Paulo, Escola Paulista de Medicina, Sao Paulo, Brazil³

Received 24 April 2002/ Accepted 25 June 2002

	ABSTRACT

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Diffusely adhering Escherichia coli strains harboring Afa/Dr adhesins (Afa/Dr DAEC) have been associated with diarrhea and urinary tract infections (UTIs). The present work is the first extensive molecular study of a Afa/Dr DAEC strain using the representational difference analysis technique. We have searched for DNA sequences present in strain C1845, recovered from a diarrheagenic child, but absent from a nonpathogenic K-12 strain. Strain C1845 harbors part of a pathogenicity island (PAI_CFT073) and several iron transport systems found in other E. coli pathovars. We did not find genes encoding factors known to subvert host cell proteins, such as type III secretion system or effector proteins. Several C1845-specific sequences are homologous to putative virulence genes or show no homology with known sequences, and we have analyzed their distribution among Afa/Dr and non-Afa/Dr clinical isolates and among strains from the E. coli Reference Collection. Three C1845-specific sequences (MO30, S109, and S111) have a high prevalence (77 to 80%) among Afa/Dr strains and a low prevalence (12 to 23%) among non-Afa/Dr strains. In addition, our results indicate that strain IH11128, an Afa/Dr DAEC strain recovered from a patient with a UTI, is genetically closely related to strain C1845.

	INTRODUCTION

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Diffusely adhering Escherichia coli (DAEC) strains, which are characterized by their diffuse adherence pattern on cultured epithelial HeLa cells (56), have been recognized as the sixth class of diarrheagenic E. coli and appear as a heterogeneous group (12, 41). A subclass of DAEC strains harbors adhesins of the Afa/Dr family (including Afa-I, Afa-III, Dr, Dr-II, and F1845), which recognize the decay-accelerating factor (DAF, or CD55) as a common receptor (43). Afa/Dr DAEC strains are identified in epidemiological studies by hybridization to a specific probe, daaC, which is common to operons encoding Afa/Dr adhesins (5). In addition, a PCR assay to detect Afa/Dr strains has been described recently (35). Afa/Dr DAEC strains have been associated with diarrhea in children (20, 22, 24, 28). However, some studies have reported that Afa/Dr DAEC strains are found equally in children with and without diarrhea (1, 17). Discrepancies between epidemiological studies could be explained in part by age-dependent susceptibility (37). Unlike other diarrheagenic pathovars of E. coli, Afa/Dr DAEC strains are also important in urinary tract infections (UTI) (43).

The alterations induced by wild-type Afa/Dr DAEC strains on polarized host epithelial cells have been studied extensively, but these strains remain poorly characterized at the molecular level. Infection of polarized cultured human intestinal cells by Afa/Dr DAEC strain C1845, isolated from a patient with diarrhea, or IH11128, recovered from a patient with UTI, is followed by elongation of brush border microvilli resulting from rearrangement of cytoskeleton proteins (4, 47), alteration of tight-junction-associated proteins (46), and impairment of several brush border-associated enzymatic activities (45, 47). The Afa/Dr adhesin operon also encodes invasins, AfaD, and DraD (18). Afa/Dr DAEC strains invade epithelial cells at a low rate by CD55- and CD66e-independent mechanisms through interaction with the ₅ß₁ integrin and a pathway involving caveolae and dynamic microtubules (23, 25). A recent study has reported that 50% of DAEC strains hybridize with an irp2 probe, which is part of the yersiniabactin operon, encoding a siderophore-dependent iron transport system (12). In addition, two diverse pathogenicity islands (PAIs) have been described for some DAEC isolates. First, a few DAEC strains contain a homologue of the locus of enterocyte effacement (LEE) pathogenicity island and exhibit pathogenic properties characteristic of enteropathogenic E. coli (EPEC) strains (3). Second, it has recently been shown that the pyelonephritogenic Afa/Dr DAEC strain EC7372 harbors a PAI similar to the one described for the uropathogenic strain CFT073 (PAI_CFT073) (26), which encodes the classical UTI determinants hemolysin and P pili (27). Other Afa/Dr strains carrying the hly and pap operons and a marker from PAI_CFT073 have been described recently (32).

To explore Afa/Dr DAEC at the molecular level, we have used a genomic approach, representational difference analysis (RDA) (38, 59), to analyze Afa/Dr strain C1845, recovered from a child with diarrhea (5). We have identified sequences present in strain C1845 but absent from a nonpathogenic E. coli K-12 strain. Our results indicate that E. coli C1845 harbors part of the PAI_CFT073 and genes from several iron acquisition systems that are common to other enteric bacterial species. We also recovered C1845-specific sequences homologous to putative virulence genes or with no homology to known sequences, and we have analyzed their distribution among Afa/Dr and non-Afa/Dr clinical isolates and among strains from the E. coli Reference Collection (ECOR collection) (44). This analysis allowed us to identify sequences that have a high prevalence in Afa/Dr strains and a low prevalence in non-Afa/Dr strains.

	MATERIALS AND METHODS

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Bacterial strains. Strains used for subtractive hybridization were the DAEC strain C1845 (O75:NM), harboring the fimbrial adhesin F1845, isolated from a child with diarrhea (5), and the nonpathogenic laboratory E. coli K-12 strain MG1655, whose genome has been sequenced (6). The uropathogenic DAEC strain IH11128 (O75:H5:K), harboring the Dr adhesin, was isolated from a patient with pyelonephritis (60). EC7372, harboring the Dr-II adhesin, was isolated from a patient with pyelonephritis (50). Prototypes of the different classes of diarrheagenic E. coli are the EPEC strain 2348/69 (36), the enterohemorrhagic E. coli (EHEC) O157:H7 strain EDL931 (Pasteur Institute collection), the enterotoxigenic E. coli (ETEC) strain H10407 (15), and the enteroaggregative E. coli (EAEC) strain 042 (40).

The ECOR collection encompasses 72 strains that are representative of the range of genotypic variation in the E. coli species as a whole (44). We used 42 strains from the ECOR collection that are representative of the four main phylogenetic groups: 10 strains from group A, 8 strains from group B1, 15 strains from group B2, 7 strains from group D, and 2 strains that do not belong to any of the four groups. We have included the three strains (ECOR 64, ECOR 50, and ECOR 37) that hybridize with the daaC probe (29).

Afa/Dr DAEC clinical isolates were from children with diarrhea, asymptomatic children, or patients with pyelonephritis. Twenty E. coli strains that tested positive by colony DNA hybridization to the daaC probe were isolated in Brazil as described previously (55). Ten strains were recovered from infants with acute diarrhea, and 10 strains were recovered from a control group of asymptomatic children. Twenty-five strains that tested positive by the afa PCR assay (35) were recovered from children with diarrhea in New Caledonia (21). In addition, we have included as a control 20 strains isolated from children with diarrhea in the same study (21) that are negative by the afa PCR assay. Twelve strains testing positive by the afa PCR assay were from patients with pyelonephritis (2).

Chromosomal DNA extraction. Bacterial genomic DNA was extracted as described previously (49).

RDA. Clones of DNA fragments present in the genome of E. coli C1845 but absent from E. coli MG1655 were prepared as described previously (59). Chromosomal DNA from strain C1845 was digested with the restriction endonuclease MspI, Tsp509I, or Sau3AI. Three subtractive libraries, resulting each time from two rounds of subtraction using first-round adapters (R) and second-round adapters (J) (59), were obtained. For the MspI library, adapters were RMsp10 (5'-CGGTCGGTGA-3'), RMsp24 (5'-CAGCCACTCTCCGACCTCTCACGA-3'), JMsp10 (5'-CGGGTTCATG-3'), and JMsp24 (5'-ACCGACGTCGAC-3').

Analysis of clones from subtractive libraries. DNA from the subtractive libraries was cloned into the ClaI (MspI library) or EcoRI (Tsp509I library) site of the pBluescript vector (Stratagene) and then transformed into E. coli DH5. Clones for the Sau3AI library were obtained by using the pUC18 SmaI/BAP vector of the SureClone ligation kit (Amersham Pharmacia Biotech, Orsay, France) and competent cells of the TOPO TA cloning kit (Invitrogen, Carlsbad, Calif.). Inserts were amplified by PCRs performed on transformant colonies by using primers P1 (5'-CCCCTCGAGGTCGACGGTAT-3') and P2 (5'-CCGCTCTAGAACTAGTGGAT-3') for the MspI and Tsp509I libraries and primers UP (5'-GTAAAACGACGGCCAGT-3') and RP (5'-CAGGAAACAGCTATGAC-3') for the Sau3a library.

(i) DNA sequencing. PCR fragments were sequenced by using the PRISM Ready Reaction Big Dye Terminator kit and an automated ABI PRISM 377 XL DNA sequencer (both from Perkin-Elmer Applied Biosystems, Courtaboeuf, France) according to the manufacturer's instructions. Sequences were analyzed by using the BLASTN and BLASTX computer programs at the National Center for Biotechnology Information (Bethesda, Md.).

(ii) DNA hybridization techniques. To check for specificity, the amplified difference product from the second subtraction round of each bank was labeled by random-primed incorporation of [-³²P]dCTP and used as a probe against DraI- and EcoRV-digested DNA from C1845 and MG1655 in Southern blot experiments.

To study the distribution of C1845-specific sequences, purified PCR fragments were labeled by using the ECL direct nucleic acid labeling and detection system (Amersham Pharmacia Biotech) according to the manufacturer's protocol. Colony blotting was performed by using Hybond-N+ membranes (Amersham Pharmacia Biotech) and the ECL detection system according to the manufacturer's protocol. For Southern hybridization, BamHI-digested chromosomal DNA was applied to an agarose gel and transferred by capillarity onto Hybond-N+ membranes as described elsewhere (54). Hybridizations were performed at 42°C with the ECL kit. Detection by chemiluminescence was performed and revealed by use of X-Omat film (Kodak).

PCR. Colony PCR was carried out by using PCR Beads Ready To Go (Amersham Pharmacia Biotech) according to the manufacturer's protocol and the Gene Amp PCR system 2400 (Perkin-Elmer Applied Biosystems). Oligonucleotides used in PCR experiments are described in Table 1. PCR was performed as follows: after an initial denaturation (5 min at 94°C), samples were subjected to 30 cycles of amplification, each of which consisted of 30 s at 94°C, 30 s at 55°C, and 1 min at 72°C. The annealing temperature was lowered to 46°C to investigate the presence of C1845-specific sequences among Afa/Dr clinical isolates. PCR fragments were purified from agarose gels by using the Qiaex II gel extraction kit (Qiagen, Courtaboeuf, France).

Nucleotide sequence accession numbers. The sequences of the subtracted DNA fragments have been assigned GenBank accession numbers AZ935556 to AZ935604.

	RESULTS

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Production of libraries of DNA fragments of Afa/Dr DAEC strain C1845 not found in the genome of E. coli K-12. By using RDA, we subtracted the genome of the nonpathogenic E. coli K-12 strain MG1655, which has recently been sequenced (6), from that of the pathogenic strain C1845, harboring the F1845 adhesin. Three libraries were produced by using the MspI, Sau3AI, and Tsp509I restriction enzymes. To confirm that the sequences amplified from the second round of subtraction were C1845 specific, the difference product of each bank was labeled and used as a probe against DraI- and EcoRV-digested DNAs from C1845 and the K-12 strain. Strong reactivity was observed with the pathogenic strain C1845, whereas no signal was detected for the K-12 strain (data not shown). Accordingly, the background of nonspecific sequences was very low, since only 5.5% of the sequences recovered were found in the K-12 genome.

Altogether, 172 C1845-specific clones were isolated and sequenced. Of these, 118 clones were unique. Ninety percent of the clones showed significant homology to known sequences, among which, for example, the clone of the F1845 adhesin operon (clone T006) confirms the validity of the RDA method. About 45% of the C1845-specific sequences recovered from RDA had homology to various plasmids (F, R100, R64, pColIb-P9, pO157, and pKYM), including sequences involved in plasmid transfer (tra), plasmid replication, plasmid transposases, insertion sequences, and noncoding plasmid sequences (data not shown). In addition, 8% of the C1845-specific sequences exhibited homology to prophage sequences, including P2 sequences and sequences homologous to O157:H7 EDL933 prophages (data not shown). Plasmid and phage sequences might be associated with virulence sequences, but it is unlikely that these sequences themselves play a role in virulence. Table 2 summarizes the clones that showed significant homology with published sequences other than plasmid and phage sequences. Sequences homologous to PAIs or iron acquisition systems are described in more detail below. A few sequences showed homology to putative virulence genes encoding a putative toxin (M008) or putative proteins involved in fimbrial assembly (S164 and S184). Finally, less than 10% of the C1845-specific clones had no homology with published sequences (Table 2). However, some sequences (S064, S094, S109, T007, and T027) were homologous to sequences from the genome projects of E. coli RS218 and the pyelonephritogenic E. coli strain CFT073 (available at www.genome.wisc.edu).

View larger version (17K): [in this window] [in a new window]   FIG. 1. E. coli C1845 harbors sequences from the left and right regions of PAICFT073. The schematic representation of PAICFT073 is derived from the work of Guyer et al. (reprinted from reference 27 with permission). Sequences homologous to the L6, R12, R6, R4, and R3 ORFs were recovered by RDA (Table 2). Positions of primers complementary to PAICFT073 sequences used in PCR experiments are indicated. Dotted lines, strain C1845 fragments amplified by PCR.

View larger version (55K): [in this window] [in a new window]   FIG. 2. Southern hybridization of BamHI-digested DNA from E. coli C1845, EC7372, or EDL931 with hly, pap, or eae probes. Gene-specific probes were generated by PCR amplification on chromosomal DNA. hlyA, papA, and papF probes are derived from E. coli EC7372. Both eae probes are derived from E. coli 2348/69 (7, 52). Hybridization with a probe derived from E. coli C1845 (M030) is shown as a control.

E. coli C1845 encodes several iron acquisition systems. Pathogenic bacteria have adapted to the host iron-limiting environment by developing a variety of iron assimilation systems. A recent study has reported that strain C1845 harbors irp2, which is part of the yersiniabactin operon, encoding a siderophore-dependent iron transport system (12). Three DNA sequences recovered from RDA, S057, T011, and T035, exhibited significant homology to other iron acquisition systems found in pathogenic enteric bacteria (Table 2). Clone S057 carries the sequence of the iucB gene, which is part of the aerobactin operon. The siderophore aerobactin is produced by a variety of enteric bacteria, including Shigella spp. and some E. coli strains (13). Clone T011 is homologous to the shuU sequence. The shu operon, which allows the use of hemin as a carbon source, has been identified in Shigella spp. and is found in pathogenic E. coli strains (chu locus) (39, 63). We have shown by PCR using specific primers that another gene of the shu operon, shuA (Table 1), is also present in strain C1845. Clone T035 is homologous to a putative molybdenum transport protein encoded by PAI_CFT073. In addition, we have shown by using specific oligonucleotides (30) the presence in E. coli C1845 of a putative virulence gene, iroN, encoding a siderophore catechole receptor that is prevalent among E. coli isolates from patients with UTI or bacteremia (30, 53). Hence, strain C1845 contains multiple genes involved in iron acquisition systems which probably play roles during host infection.

Distribution of C1845-specific sequences among Afa/Dr and non-Afa/Dr clinical strains and strains from the ECOR collection. We have investigated the distribution of several C1845-specific sequences, including putative virulence genes and sequences with no homology to sequences in the databases, among E. coli Afa/Dr and non-Afa/Dr isolates and strains from the ECOR reference collection. We have used 20 Afa/Dr E. coli isolates recovered from children with or without diarrhea in Brazil, 25 Afa/Dr E. coli isolates recovered from children with diarrhea in New Caledonia, and 14 Afa/Dr E. coli isolates recovered from patients with pyelonephritis (see Materials and Methods). As a control, we have used strains from the ECOR collection and non-Afa/Dr clinical isolates recovered from children with diarrhea in New Caledonia. We have chosen 42 strains from the ECOR collection, including the 3 strains which hybridize with the daaC probe (29). ECOR strains belong to four main phylogenetic groups (A, B1, B2, and D), and most of the pathogenic E. coli isolates are concentrated in groups B2 and D (29). Using specific oligonucleotides (11), we have shown by PCR that E. coli C1845 most likely belongs to the B2 group.

In a preliminary experiment, we investigated by PCR the presence of 22 C1845-specific sequences in the 20 Afa/Dr isolates from Brazil (data not shown). These sequences (oligonucleotides are described in Table 1) include putative virulence genes (M008, S164, S184, T011 [shuU], and T034 [iha]), putative metabolic genes (M014 and T018), and sequences with no homology to known proteins. Only four sequences had a high prevalence (>70%) among the Afa/Dr isolates (M030, S109, S111, and S164). The frequencies of the putative virulence sequences M008, S184, T011 (shuU), and T034 (iha) were 30, 25, 55, and 45%, respectively. Interestingly, some sequences (M008, S014, S094, and T024; M030 and S111; S081 and S184) had the same distribution, suggesting a genetic linkage. We then analyzed by colony hybridization on Afa/Dr and non-Afa/Dr strains the distribution of several sequences including M030, S109, S111, S164, and C1845-specific sequences with low or no homology with the published sequences that are not found in the databases of the E. coli RS218 and CFT073 genome projects (M020, S070, S081, S177, S184, S199, and T018). The results shown in Table 3 indicate that three clones (M030, S109, and S111) have a high prevalence among Afa/Dr strains and a low prevalence among non-Afa/Dr strains. These three clones did not hybridize with EPEC, EHEC, ETEC, or EAEC prototype strains (data not shown). In addition, these results confirmed that M030 and S111 have an identical distribution among E. coli strains.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

 
In the present study, we provide the first extensive molecular analysis of an Afa/Dr DAEC strain. Using the RDA approach, we have identified sequences from the genome of the Afa/Dr DAEC strain C1845, harboring the F1845 adhesin and recovered from a child with diarrhea, that are absent from the nonpathogenic E. coli K-12 strain MG1655. E. coli C1845 harbors several iron acquisition genes, genes from PAI_CFT073, and other putative virulence genes. However, our results indicate that C1845 does not harbor genes encoding factors known to subvert host cell proteins to induce brush border lesions, such as type III secretion system and effector proteins. An epidemiological approach allowed us to identify sequences that have a high prevalence in Afa/Dr strains and a low prevalence in non-Afa/Dr strains. Our results indicate that diarrheagenic E. coli C1845 is very close to Afa/Dr DAEC uropathogenic isolates.

Because iron is essential for bacterial growth and free iron is limiting within the host, bacterial pathogens have acquired diverse systems to acquire iron. In addition to the yersiniabactin siderophore (irp2), we have shown that E. coli C1845 harbors sequences encoding several iron transport systems found in other pathotypes of E. coli, including the aerobactin siderophore (iuc), a catechole siderophore receptor (iroN), a heme transport system (shu), and a molybdenum transport system (modD). However, the reason for the redundancy of iron acquisition systems is unclear, and it has been postulated that the yersiniabactin system might have an alternative function, other than iron acquisition, in pathogenic E. coli strains (57). In addition, the diverse systems might play roles at different stages of the infection.

Several PAIs, which contribute to the rapid evolution of bacterial pathogens, have been described for pathogenic E. coli strains (14). We have shown that strains C1845 and IH11128 harbor the left and right ends of a PAI identified in a pyelonephritogenic E. coli strain, PAI_CFT073 (27), but not the middle part of the island, encoding hly and pap operons. However, a remnant of the pap operon, carrying the F10 papA allele, was detected. Interestingly, the presence of a partial copy of the pap operon, with the F10 papA allele, has been found in several urosepsis strains belonging to the same serogroup as C1845 and IH11128, O75 (33), suggesting that this genetic organization is commonly found among O75 strains. One can hypothesize that the entire PAI_CFT073 has been inserted into these strains and that a deletion has subsequently taken place. Whether the internal region of the PAI has been simply deleted or replaced by different genetic material remains unknown. Among the PAI_CFT073 ORFs present in E. coli C1845 and IH11128, R4 is of particular interest because its translated sequence is identical to a novel adhesin of E. coli O157:H7, Iha, that mediates diffuse adherence to epithelial cells (58).

Besides iron acquisition systems and PAI_CFT073 genes, we have identified a few C1845-specific sequences that show homology to putative virulence genes (M008, S164, and S184). Except for S164, these clones have only a narrow distribution among the Afa/Dr clinical isolates tested. Clone S164, encoding a putative fimbrial chaperone protein, is frequently found in Afa/Dr clinical isolates but is not specific for Afa/Dr strains. It is of interest that M008 is part of a group of four clones (M008, S014, S094, and T024) that are likely to be linked on the C1845 chromosome, because they exhibit the same distribution among the diverse E. coli strains and show homology to O157:H7 sequences that are part of an island not found in E. coli K-12 MG1655 (48). Sequences highly homologous (>98%) to these clones are also found in the database of the RS218 genome project. Because this group of clones encodes a putative virulence factor, it may be part of a novel PAI that would be present in diverse E. coli pathovars. In addition, we have identified three sequences (M030, S109, and S111) that appear with a high frequency among Afa/Dr E. coli strains and a low frequency among non-Afa/Dr E. coli strains. These three Afa/Dr-specific sequences are found with similar frequencies in Afa/Dr isolates recovered from patients with diarrhea or pyelonephritis. Our results indicate that M030 and S111 are genetically linked, because they exhibit identical distribution among 121 E. coli strains. M030 exhibits low homology to an ORF of unknown function (ORF37) encoded by the 102-kb region of Yersinia pestis (9). Sequences highly homologous to M030, S109, and S111 are found in the database of the genome project for RS218, a K1 derivative responsible for meningitis, but these clones do not hybridize with EPEC, EHEC, ETEC, or EAEC prototype strains. Because of the high homology with RS218 sequences, these clones could encode factors that are important for both Afa/Dr and K1 pathogenic strains.

Afa/Dr DAEC strains have been associated with both diarrheagenic and uropathogenic infections. Recent data indicate that AfaE1, AfaE2, AfaE3, and F1845 adhesins are found in both diarrheagenic and uropathogenic human isolates (35). While strain C1845 was recovered from a child with diarrhea (5), our results indicate that this strain has several characteristics that have been associated with extraintestinal E. coli strains. These include the B2 phylogenetic group (51), the O75 serotype (42), the production of aerobactin (10), the presence of iroN (53), and the presence of sequences from PAI_CFT073 (27). On the other hand, multilocus enzyme electrophoresis indicated that Afa/Dr DAEC strain C1845, as well as other DAEC strains, is phylogenetically close to EAEC strains (12); however, the phylogenetic relationship between DAEC strains isolated from patients with diarrhea and DAEC strains isolated from patients with UTIs has not been studied. To further investigate the relation of E. coli C1845 to uropathogenic isolates, we investigated the presence of C1845-specific sequences in the Afa/Dr strain IH11128, recovered from a patient with pyelonephritis. Despite their different origins, both strains appear very similar at the molecular level. The observation that E. coli C1845, isolated from a child with diarrhea, is very close to uropathogenic isolates is in agreement with the hypothesis developed by Germani et al. (19) that a single Afa/Dr strain can be responsible for diarrhea or UTI and/or with the hypothesis that isolation of Afa/Dr DAEC strains from patients with diarrhea may be related to the presence of uropathogenic E. coli in the colon without a causative link to the disease state (17).

It has recently been extensively documented that many enterovirulent bacteria subvert functional membrane-bound proteins as receptors to colonize epithelia and exploit the cell-signaling pathways to cross talk with the host cells and cause disease. The prototype of such subversive enterovirulent pathogens is EPEC, which colonizes the intestinal epithelium by translocating bacterial proteins through a type III secretion system to activate a signaling pathway within the underlying cell and cause the reorganization of the host actin cytoskeleton (61). Like EPEC, wild-type Afa/Dr DAEC strains promote dramatic lesions in the brush border of cultured human differentiated Caco-2 intestinal cells (4, 47). Some DAEC strains contain a homologue of the LEE PAI, which encodes a type III secretion system, and exhibit pathogenic properties characteristic of EPEC strains (3, 62). Our results indicate that strain C1845 does not encode the LEE PAI and lacks type III secretion system and effector proteins, implying that the brush border cytoskeleton is altered by a mechanism different from the one developed by EPEC strains. No known virulence factors involved in cytoskeleton injuries have been found in the RDA conducted in this study, suggesting that interaction between the Afa/Dr adhesins and membrane-bound receptors is the major mechanism by which Afa/Dr DAEC pathogens subvert host cell-signaling pathways to develop pathogenicity. This interpretation is consistent with previous results (47) and with recent data showing that interaction of Afa/Dr DAEC adhesins with CD55 induces the transepithelial migration of polymorphonuclear leukocytes in human intestinal T84 cell monolayers and a proinflammatory response. This phenomenon follows the adhesin-dependent tyrosine phosphorylation of several T84 proteins and activation of the mitogen-activated protein kinases (F. Bétis, P. Brest, V. Hofman, J. Guignot, M.-H. Bernet-Camard, B. Rossi, A. L. Servin, and P. Hofman, unpublished data).

	ACKNOWLEDGMENTS

 
We thank E. Bingen (Service de Microbiologie, Hopital Robert Debré, Paris, France), A. Darfeuille-Michaud (Laboratoire de Bactériologie, Clermont-Ferrand, France), B. B. Finlay (University of British Columbia, Vancouver, Canada), S. L. Moseley (University of Washington, Seattle, Wash.), and B. J. Nowicki (The University of Texas Medical Branch, Galveston, Tex.) for providing some strains used in this study.

A.-B.B.-P. is supported by a postdoctoral grant from the Fondation pour la Recherche Médicale (FRM). The laboratory of X.N. is supported by INSERM and the Université René Descartes Paris 5.

	FOOTNOTES

 
* Corresponding author. Mailing address: INSERM Unité 510, UFR de Pharmacie Paris XI, F-92296 ChÂtenay-Malabry, France. Phone: 33 1 46 83 56 61. Fax: 33 1 46 83 58 44. E-mail: alain.servin{at}cep.u-psud.fr.

Editor: V. J. DiRita

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