Tissue Tropism of Enteropathogenic Escherichia coli Strains Belonging to the O55 Serogroup

Four enteropathogenic Escherichia coli (EPEC) strains belongingto the O55 serogroup (G21 and G30 [both O55:H6], G35 [O55:H-],and G58 [O55:H7]) were tested for their tissue tropism by usinghuman intestinal in vitro organ culture. Strains showed restrictedadhesion with attaching-and-effacing activity to follicle-associatedepithelium of Peyer's patches, with no apparent adhesion toduodenum or colon. G35 and G58 express intimin ${gamma}$ and show a similartropism to intimin ${gamma}$ -expressing enterohemorrhagic E. coli (EHEC)O157:H7. However, strains G21 and G30 were unusual because theyexpressed intimin ${alpha}$ and had a restricted tissue tropism of intimin ${gamma}$ phenotype. The amino acid sequence of the carboxy-terminal280 amino acids of intimin from G21 was determined. Comparisonwith the prototype intimin ${alpha}$ from strain E2348/69 (O127:H6) showeda single amino acid difference (corresponding to Val907 andAla907 in the whole intimins). This mutation was reproducedby site-directed mutagenesis in an intimin ${alpha}$ plasmid template,pCVD438, with the hypothesis that it may induce a change intropism. However, when the mutated plasmid was placed in bothEPEC and EHEC backgrounds, duodenal adhesion in a manner similarto strain E2348/69 was evident upon in vitro organ culture.Thus, additional factor(s) unrelated to intimin exist in theO55:H6 genome that influence human intestinal tissue tropism.

INTRODUCTION

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Introduction

Enteropathogenic Escherichia coli (EPEC) are an important causeof acute and prolonged diarrhea in the developing world withbetween 30 to 40% of diarrhea in the first year of life beingattributed to EPEC (31).

E. coli is a clonal species, with clones identified on a combinationof O and H antigens. The O antigen is part of the lipopolysaccharidepresent in the outer membrane of gram-negative bacteria (42,45). E. coli serogroup O55 is the third most frequent EPEC Oserogroup involved in infantile diarrhea, and O55:H6, O55:H7,and O55:H- account for 90% of the strains isolated (37). EPECand enterohemorrhagic E. coli (EHEC) can be divided into twomajor groups of related clones, designated EPEC clones 1 and2 and EHEC clones 1 and 2. EPEC clone 1 typically expressesflagellar antigen H6, whereas EPEC clone 2 expresses flagellarantigens H2 or H-. EHEC clone 1 includes the O157:H7 serogroup,whereas EHEC clone 2 contains other Shiga toxin-positive E.coli serogroups. In addition, EHEC strains belonging to clone2 are closely related to the typical EPEC strains, whereas EHECO157:H7 is related to the atypical EPEC O55:H7 (12).

Typical EPEC strains are classified as being positive for geneprobes to eae (encoding intimin), EAF (EPEC adherence factorplasmid), and bfpA (encoding bundlin, the subunit pillin ofthe bundle-forming pilus) (20). The O55:H- strains are consideredto have lost their flagella by mutation, since the nonmotilederivatives and the motile progenitor usually have the samebiochemical properties. Therefore, it has been suggested thatH- strains of the O55 serogroup are derived from H6 or H7 strains(37).

EPEC and EHEC have the ability to produce attaching-and-effacing(A/E) lesions on enterocytes (30, 35, 44). The A/E lesion ischaracterized by localized destruction of the brush border microvilliwith intimate attachment of the bacteria to the enterocyte.The area underlying the bacteria consists of polymerized actin,ezrin, talin, and myosin (14) and the actin-regulating proteinsWASP (Wiskott-Aldrich syndrome family of proteins) and Arp 2/3(actin-related proteins 2 and 3 complex) (19). This host cell-bacteriuminterface may be raised above the host cell surface producinga pedestal. The genes necessary and sufficient for the productionof an A/E lesion by EPEC are located on a pathogenicity islandtermed the locus of enterocyte effacement (LEE) (28). EHEC andother A/E bacteria, such as Citrobacter rodentium, also containthe LEE (4, 27) but in EHEC the LEE is necessary but not sufficientfor A/E lesion production (8). Intimin, a 94- to 97-kDa proteinencoded by the eae gene within the LEE, is an adherence factor,which has been shown to play a key role in intestinal colonization(12). Intimin mediates intimate attachment to the epithelialcell by binding to another LEE-encoded protein, the translocatedintimin receptor (Tir), which is delivered into the host cellby a type III secretion system (22). The importance of intiminin human disease is highlighted by an eae mutant being significantlyattenuated in human volunteers compared to the wild-type parentstrain (7) and by the presence of a high titer of serum intiminantibodies in both individuals infected with EHEC (18) and inthe colostrum of mothers in Brazil where EPEC infection is endemic(25).

To date, five intimin types have been identified and designated ${alpha}$ , ß, ${gamma}$ , ${delta}$ , and ${varepsilon}$ (1, 32). Intimin ${alpha}$ and intimin ${gamma}$ are associatedwith different evolutionary branches of EPEC and EHEC. Intimin ${alpha}$ is associated with EPEC branch 1 and intimin ${gamma}$ is specificallyassociated with EHEC O157:H7 and the related EPEC O55:H7 (46).Intimin exchange studies in piglets have shown that varyingthe intimin type can alter the site of intestinal colonizationby EHEC (43). This activity of intimin was further characterizedby using in vitro organ culture (IVOC). The prototype intimin ${alpha}$ -expressing strain O127:H6 E2348/69 produces A/E lesions onduodenum, terminal ileum, Peyer's patches and, in a small percentageof incubations, on the colon (33). In contrast, intimin ${gamma}$ -expressingEHEC exhibited a restricted tropism toward the follicle-associatedepithelium (FAE) of Peyer's patches (35). When intimin ${gamma}$ fromO157:H7 was placed in an eae mutant strain of E2348/69, adherenceto the FAE predominated, thus mimicking the restricted tissuetropism of O157:H7 (35). In contrast, placing intimin ${alpha}$ in aneae mutant strain of O157:H7 resulted in colonization of thesmall intestine, as well as Peyer's patches (9). Thus, intiminis able to modulate the tissue tropism of EPEC and EHEC on humanintestinal explants, producing characteristic intimin ${alpha}$ - and ${gamma}$ -related phenotypes.

The receptor binding activity of intimin has been localizedto the C-terminal 280 amino acids (Int280) (10). The globalfold of Int280 ${alpha}$ was determined by nuclear magnetic resonance(21) and crystallography (26), which showed that it is builtfrom three globular domains with the first two comprising ß-sheetsandwiches. The third C-terminal domain (residues 183 to 280)has a topology that resembles C-type lectin domains (CTLD),a family of proteins responsible for cell surface carbohydraterecognition. Analysis of intimin-Tir complexes revealed aminoacids likely to be involved in binding (3, 26) and showed theseresidues to be concentrated in a solvent-exposed region of theCTLD. Site-directed mutagenesis of residues within the CTLDwas able to modulate the biological activity of intimin; inparticular, substituting a valine at 911 with alanine in intimin ${alpha}$ produced a derivative, which bound to intestinal mucosa inan intimin ${gamma}$ -like phenotype (36).

We studied the EPEC O55 serogroup, which expresses differentintimin types, by using in vitro organ culture to further elucidatethe mechanisms involved in tissue tropism.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains and plasmids. Bacterial strains and plasmids used in this study are listedin Table 1. Strains and plasmids were grown overnight at 37°Cwith shaking (250 rpm) in L broth (LB; Sigma) for DNA sequencingand site-directed mutagenesis; for infection assays, bacterialstrains were grown overnight without shaking in brain heartinfusion broth.

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TABLE 1. List of strains and plasmids used during this study

Human intestinal in vitro organ culture adhesion assay. Tissue was obtained with fully informed parental consent andlocal ethical committee approval by using grasp forceps duringroutine endoscopic (Olympus PCF pediatric endoscope) investigationof intestinal disorders. Duodenal, terminal ileal, Peyer's patch,and transverse colonic biopsies were taken from areas showingno macroscopic abnormalities. Light microscopy subsequentlyshowed no histological abnormality. IVOC infections were performedas described previously (15). Briefly, 25 µl of an overnightbacterial culture was inoculated onto the biopsy samples fromthe various regions of the gut. The IVOC medium was changedevery 2 h, and the assay was terminated at 8 h. Each bacterialstrain was examined on several occasions by using tissue fromdifferent patients. Samples were fixed with 2.5% glutaraldehydeand postfixed in 1% aqueous osmium tetroxide and viewed by scanningelectron microscopy (SEM) and transmission electron microscopy(TEM).

DNA sequencing of intimin from O55:H6 strain G21. Genomic DNA from G21 was isolated by using the DNAeasy tissuekit (Qiagen), according to manufacturer's instructions. The3' end of the eae gene encoding Int280 ${alpha}$ from O55:H6 was amplifiedby PCR by using high-fidelity Pfu DNA polymerase (1 cycle of94°C for 1 min, followed by 25 cycles of 94°C for 30s, 50°C for 1 min, and 74°C for 1 min, followed by 1cycle of 74°C for 5 min; forward primer, 5'-GGAATTCATTACTGAGATTAAGGCT-3';reverse primer, 5'-CGGGATCCTTATTTTACACAAGTGGC-3'). The amplifiedDNA and the plasmid pMAL-c2 were cut by using the restrictionenzymes EcoRI and BamHI. The amplified DNA was inserted intocut pMAL-c2 by ligation with T4 DNA ligase. pMAL-c2 was transformedinto E. coli XL1-Blue cells. Ampicillin resistant transformantswere randomly selected and screened for the appropriate insert.XL1-Blue colonies containing the recombinant plasmid were grownovernight in LB, the plasmids isolated by using the plasmidminiprep kit (Qiagen) and ethanol precipitation. DNA sequencingwas performed with 1 to 2 µg of plasmid DNA, and the Int280forward and reverse primers (36).

Site-directed mutagenesis. Site-directed mutagenesis of intimin ${alpha}$ was performed by usingthe QuickChange site-directed mutagenesis kit (Stratagene) accordingto the manufacturer's instructions. Plasmid pCVD438 encodingintimin ${alpha}$ (5) was used as a template. A complementary mutagenesisoligonucleotide pair incorporating a single amino acid substitutionwas designed. Primers were as follows: forward primer (5'-CAGCTCAAGATGTGAAGAGTGGTGTTGC-3')and reverse primer (5'-GCAACACCACTCTTCACATCTTGAGCTG-3').

Mutated plasmid containing staggered nicks was generated byextension of primers annealed to opposite strands of the denaturedplasmid by temperature cycling in the presence of the high-fidelityPfu DNA polymerase. Synthesized DNA containing the desired mutationwas selected from the original DNA template by incubation withthe enzyme DpnI at 37°C for 1 h, which cleaves the parentalDNA at dam methylated GATC sequences, leaving the unmethylatednewly synthesized mutated plasmid intact. Nicks in the plasmidwere repaired after transformation of 1 µl of the synthesizedDNA into competent E. coli XL1-Blue cells. Chloramphenicol-resistanttransformants were randomly selected and grown overnight inLB. Plasmid DNA was isolated by using the plasmid miniprep kit(Qiagen) and ethanol precipitation. Correct incorporation ofthe mutation was monitored by DNA sequencing by using an automatedDNA sequencer. The mutated plasmids were then transformed intoeae deletion mutants of EPEC strain CVD206 (5) and EHEC strainICC170 (9).

RESULTS

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Results

IVOC tissue tropism of O55 serogroup strains G21, G30, G35, and G58. Intimin, from EPEC and EHEC, is essential for A/E lesion formationin IVOC (9, 15). All of the EPEC strains expressed intimin,as shown by Western blotting with a universal intimin antiserum(2) (data not shown). SEM of the uninoculated controls showedgood preservation of mucosal architecture, the epithelium wasintact and there was no evidence of excess extrusion of enterocytesor mucus. All O55 strains showed a restricted pattern of A/Elesion formation, which was limited to FAE overlying ileal Peyer'spatches (Fig. 1 and Table 2). Thus, the intimin ${gamma}$ -expressingstrains G35 (O55:H-) and G58 (O55:H7) showed the same tissuetropism as EHEC O157:H7 (35), which expresses intimin ${gamma}$ . Strainsexpressing intimin ${alpha}$ can produce A/E lesions on duodenum andileum, as well as Peyer's patches (9, 33). However, O55:H6 strainG21, which expresses intimin ${alpha}$ , did not reproduce this phenotype,forming A/E lesions on Peyer's patches alone. In order to investigateif this phenomenon is unique to strain G21 or common to otherO55:H6 strains, a second isolate, strain G30 was tested in IVOC.Like G21, strain G30 did not adhere to duodenum, terminal ileum,or colon. These results indicate that intimin ${alpha}$ strains may showa variable pattern of tissue tropism.

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FIG. 1. SEM of IVOC of O55 Strains. (A) Low-power view of lymphoid follicles within IVOC sample from ileal Peyer's patch region. (B to D) O55:H6 (B), O55:H- (C), and O55:H7 (D), showing adhesion of strains to the FAE of an ileal Peyer's patch. Bars: 100 µm (A), 0.5 µm (B and C), 5 µm (D).

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TABLE 2. Patient age and number of biopsies with adherent bacteria expressed as a proportion of biopsies inoculated

TEM was used to confirm the presence of A/E lesions on intestinalPeyer's patch explants (Fig. 2). In all three O55 strains, intimateadherence of bacteria to the enterocyte with effacement of microvillicould be seen. The bacterium-enterocyte interface was primarilyseen as a depression, with only a few pedestal-like structuresobserved. No bacteria were observed within enterocytes.

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FIG. 2. TEM of IVOC of O55 Strains. (A to C) O55:H6 (A), O55:H- (B), and O55:H7 (C), showing A/E lesions on the FAE of an ileal Peyer's patch. Note the lack of pedestal formation. Bar, 0.5 µm.

Sequencing of intimin ${alpha}$ from O55:H6 strain G21. Site-directed mutagenesis within the CTLD region of intimin ${alpha}$ has shown that the mutation of a specific residue (Val911)can lead to the production of an intimin ${alpha}$ -expressing EPEC derivativewith a restricted colonization phenotype (36). To determinewhether the eae gene of G21 contained any variation in thisregion, the carboxy-terminal region encoding Int280 was comparedto that of the prototype intimin ${alpha}$ from O127:H6 strain E2348/69.This revealed a single amino acid change at position 907 (Fig.3), i.e., a valine residue in G21 instead of an alanine residueas in E2384/69. In order to assess the influence of the presenceof valine at position 907 in the intimin ${alpha}$ of G21, site-directedmutagenesis was performed on pCVD438, which contains eae ${alpha}$ fromE2348/69, generating plasmid pCPG2. The plasmid was transformedinto the eae mutant E2348/69 strain CVD206 and the eae mutantO157:H7 85/170 strain ICC170. These strains, CVD206(pCPG2) andICC170(pCPG2), were tested by using the IVOC assay.

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FIG. 3. Comparison of carboxy-terminal amino acid sequences of intimin ${alpha}$ from E2348/69 (AAC 38392) and G21 (O55:H6). Amino acids are numbered according to the position in intimin ${alpha}$ of E2348/69.

IVOC assay of CVD206(pCPG2) and ICC170(pCPG2). CVD206(pCPG2) was tested for A/E lesion formation on duodenumby using the IVOC assay. It was important to use duodenal explantsas A/E lesion formation on the proximal small intestine is areported characteristic of intimin ${alpha}$ strains, whereas A/E lesionformation on FAE of Peyer's patches is synonymous with strainsexpressing intimin ${alpha}$ and with strains expressing intimin ${gamma}$ . CVD206showed no adhesion (Table 2) as reported earlier in qualitativeform. CVD206(pCPG2) produced A/E lesions on the duodenum ina manner similar to that of E2348/69 (Table 2 and Fig. 4A).This indicates that the difference in intimin amino acid sequencebetween G21 and E2348/69 cannot be the determining factor inthe restricted tissue tropism of G21.

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FIG. 4. SEM of IVOC. (A and B) CVD206(pCPG2) (A) and ICC170(pCPG2) (B), both showing A/E lesion formation on the duodenum. Bar, 0.5 µm.

The use of the EPEC derived strain CVD206 as a recipient, forpCPG2, may have been a factor in the inability of CVD206(pCPG2)to reproduce the restricted phenotype associated with G21. Totest this, pCPG2 was placed in ICC170, an eae mutant strainderived from EHEC 85/170 which only produces A/E lesions onfollicle-associated epithelium (9). The resultant strain, ICC170(pCPG2),produced A/E lesions on duodenum in a manner similar to thatof CVD206(pCPG2) (Table 2 and Fig. 4B). Therefore, the restrictedtissue tropism of O55:H6 G21 is associated with a factor distinctfrom intimin, which is not in the EPEC E2348/69 or the EHEC85-170 backgrounds.

DISCUSSION

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Discussion

The E. coli O55 serogroup is a prominent cause of infantilediarrhea. Each EPEC serogroup is made up of clones with distinctcombinations of virulence factors. In the case of the O55 serogroupthis results in some strains belonging to the classic EPEC genotypeand others having an atypical EPEC genotype with close linksto EHEC O157:H7. The similarity between O55:H7 and O157:H7 isdemonstrated by their nearly identical sequences for the H7flagellin gene and the similarity of their eae alleles (29,37). The eae gene encodes the outer membrane protein intimin,which allows EPEC and EHEC to adhere to human intestinal cellsand produce A/E lesions (9, 15). This protein can be dividedinto three globular domains. The CTLD, at the carboxy terminusof intimin, is responsible for binding of intimin to its translocatedreceptor, Tir. The 280-amino-acid carboxy-terminal region alsoallows intimin to induce microvillus-like processes on Hep-2cells (34), acts as an immune modulator (16), and may bind ahost cell receptor (12). Intimin ${alpha}$ has been show to bind ß1integrin in vitro (11), although this process is not essentialfor A/E lesion formation (23). In addition, intimin ${gamma}$ binds nucleolin,which may act as a host-derived cell surface receptor duringthe initial stages of EHEC adhesion (40).

Intimin can be divided according to antigenicity, and so farfive distinct subtypes have been published (1, 32). The significanceof the different subtypes in pathogenesis remains to be fullyelucidated. Recent studies have shown a correlation betweenintimin type and tissue tropism (9, 33). The data showed thatintimin ${alpha}$ and intimin ${gamma}$ produce different tropism phenotypes ina manner that is Tir type independent. Using IVOC, intimin ${alpha}$ has been shown to allow both EPEC and EHEC to produce A/E lesionson duodenum and Peyer's patches, whereas intimin ${gamma}$ limits A/Elesion formation to Peyer's patches.

In this study we have shown that EPEC strains from the O55 serogroup,expressing intimin ${alpha}$ or intimin ${gamma}$ , adhered preferentially to theFAE of Peyer's patches. In the case of O55:H6 strains G21 andG30, this is the first example of intimin ${alpha}$ -expressing strainsshowing the lack of adherence to the small intestinal villoussurface.

A recent study of the biological activity of intimin ${alpha}$ highlightedcertain important residues involved in intimin-Tir interaction(36). The valine at position 911 is hydrophobic and lies atthe top end of the Tir-binding site. It is solvent exposed andas such is ideally placed to interact with Tir (21). Its mutationto an alanine residue resulted in restricted tissue tropism,with A/E lesion formation being limited to the FAE of Peyer'spatches. An equivalent alanine substitution at position 906in intimin ${gamma}$ led to disruption of Tir-binding activity (24).Thus, the removal of a hydrophobic valine residue, within theTir-binding site of intimin ${alpha}$ and intimin ${gamma}$ , and substitutionwith alanine led to altered binding activity and in the caseof intimin ${alpha}$ , restricted A/E lesion formation in IVOC. The intimin ${alpha}$ of G21 was sequenced and showed a single amino acid mutationat position 907 compared to the intimin ${alpha}$ of O127:H6 strain E2348/69.Using the intimin ${alpha}$ template plasmid, pCVD438, we constructedan intimin ${alpha}$ with a valine at position 907, thus matching G21.When this plasmid (pCPG2) was placed in an EPEC or an EHEC background,it showed a typical intimin ${alpha}$ phenotype and adhered to duodenum.Thus, the mutation at position 907 was not a factor involvedin the restricted adherence of G21 to FAE of Peyer's patches.It is theoretically possible that residues outside the C-terminaldomain of intimin are involved in the determination of tissuetropism, but these residues show >90% homology between thevarious intimin types, so it remains a remote possibility. Itis more likely that the restricted tissue tropism of G21 isdetermined by other genes which are specific to the O55:H6 genome.Several different infection models have shown that intimin isinvolved in tissue tropism (9, 33, 36, 43) and thus it appearsthat an O55:H6 factor is operating to prevent colonization ofsmall intestinal villous surfaces despite the possession ofintimin ${alpha}$ . If this factor can be identified it will be interestingto see whether it is also present in the intimin ${gamma}$ -positive O55:H-,O55:H7, and O157:H7 strains, which would suggest a multifactorialcontrol of restricted adhesion to the FAE of Peyer's patches.

The restricted adhesion of strain G35 (O55:H-) to Peyer's patchesis in line with the fact that it expresses intimin ${gamma}$ , althoughit also possesses the EAF plasmid (37) and hence the genes forBFP production (13), i.e., it is a typical EPEC (20). Thus,the presence of BFP, which has been considered to be an initialadhesion for EPEC colonization (6), is not synonymous with villousadhesion. Indeed, in a previous study with IVOC, BFP was suggestedto be involved in three-dimensional colony formation and notinitial adherence (15). Such a role would remain compatiblewith adhesion restricted to the FAE, i.e., to establish colonyunits within the gut environment, allowing nonintimate bacterium-to-bacteriumadhesion and, once a quorum of bacteria have been established,to permit disaggregation and colonization of other regions ofthe gut.

TEM showed limited evidence of pedestals (19, 38) being formedby the three O55 strains. Rather, the intimate adhesion betweenbacterium and host cell membrane resulted, generally, in slightdepressions in the surface of the enterocyte. A similar appearancewas shown in newborn pigs infected with O55:H7 (41), indicatingit is not just due to the relatively short-term length of incubationin IVOC. Some pedestal-like structures were illustrated, butthese were located on extruding cells where cytoplasmic extrusiongives the appearance of elongated pedestals (41). In addition,pedestal formation in in vivo EPEC infections (17, 39, 44) andin animal models of human EPEC infection (30) are similar tothose produced by IVOC (15). The lack of elongated pedestalor pseudopod (38) formation on gut explants highlights the differencebetween IVOC and cell line adhesion studies. Nonpolarized epithelialcells, derived from the larynx, lung, and cervix do not possesstight junctions, lack a terminal web, and do not have the complexactin-based cytoskeleton of the intestinal brush border. Thus,actin polymerization at the bacterium-host interface may bea more tightly regulated process in gut epithelium than in celllines.

Strain O55:H7 was shown to enter the enterocytes of newbornpigs, implying an invasive potential (41). This phenomenon wasnot apparent after 8 h IVOC with Peyer's patch explants andhas not been reported in other, non-O55 serogroup, in vivo EPECinfections in humans.

In summary, EPEC strains from the O55 serogroup show initialadherence to the FAE overlying Peyer's patches. The mechanismof this tissue tropism includes intimin and other factor(s)specific to the O55 genome. Further analysis of EPEC and EHECgenomes will allow us to determine the mechanisms by which thesepathogens adhere, maintain their presence, and spread withinthe gut.

ACKNOWLEDGMENTS

This study was supported by a BBSRC grant to A.D.P. and G.F.

We also thank Saghar Navabpour and Susan Hicks for their helpwith the IVOC.

FOOTNOTES

* Corresponding author. Mailing address: Centre for Paediatric Gastroenterology, Lower 3rd Floor, Royal Free Campus, Royal Free Hospital and University College Medical School, Rowland Hill St., London NW3 2PF, United Kingdom. Phone: 44-20-7830-2783. Fax: 44-20-7830-2146. E-mail: adphill{at}rfc.ucl.ac.uk.

Editor: A. D. O'Brien

REFERENCES

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