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Infection and Immunity, May 2001, p. 2894-2901, Vol. 69, No. 5
Department of Medical Microbiology and Immunology, College
of Medicine, Texas A&M University, College Station, Texas
778431; Department of Microbiology and
Immunology, University of Tennessee, Memphis, Tennessee
381632; Chemical and Life Sciences
Laboratory, University of Illinois, Urbana, Illinois
618014; and The Sanger Centre, The
Wellcome Trust Genome Campus, Hixton,
Cambridge,3 and Department of
Biochemistry, Imperial College, London SW7 2AZ,5
United Kingdom
Received 1 December 2000/Accepted 29 January 2001
Salmonella enterica serotype Typhi differs from
nontyphoidal Salmonella serotypes by its strict host
adaptation to humans and higher primates. Since fimbriae have been
implicated in host adaptation, we investigated whether the serotype
Typhi genome contains fimbrial operons which are unique to this
pathogen or restricted to typhoidal Salmonella serotypes.
This study established for the first time the total number of fimbrial
operons present in an individual Salmonella serotype. The
serotype Typhi CT18 genome, which has been sequenced by the Typhi
Sequencing Group at the Sanger Centre, contained a type IV fimbrial
operon, an orthologue of the agf operon, and 12 putative
fimbrial operons of the chaperone-usher assembly class. In addition to
sef, fim, saf, and tcf, which had been
described previously in serotype Typhi, we identified eight new
putative chaperone-usher-dependent fimbrial operons, which were termed
bcf, sta, stb, ste, std, stc, stg, and sth.
Hybridization analysis performed with 16 strains of
Salmonella reference collection C and 22 strains of
Salmonella reference collection B showed that all eight
putative fimbrial operons of serotype Typhi were also present in a
number of nontyphoidal Salmonella serotypes. Thus, a simple
correlation between host range and the presence of a single fimbrial
operon seems at present unlikely. However, the serotype Typhi genome
differed from that of all other Salmonella serotypes
investigated in that it contained a unique combination of putative
fimbrial operons.
The genus Salmonella
contains pathogens which are closely related genetically but differ in
their host range (7). One end of the spectrum is formed by
broad-host-range pathogens such as Salmonella enterica
serotype Typhimurium, which is frequently associated with cases of
disease in a number of animal species, including mice, pigs, poultry,
horses, cattle, and sheep (19, 43, 52). At the other end
of the spectrum are pathogens whose ability to cause disease is
restricted to a single genus or related genera of vertebrate species.
Serotype Typhi is a prototypical host-restricted serotype which causes
typhoid fever in humans and higher primates but is unable to produce
illness in other vertebrate species. Since there is no inexpensive
animal model with which to study serotype Typhi pathogenesis, little is
known about virulence factors which are responsible for its apparent adaptation to the human host and its ability to cause typhoid fever.
With the sequence of the whole serotype Typhi genome now almost
complete, we can begin to address these questions using comparative
genomic analysis.
One of the virulence factors recently implicated in adaptation of
serotype Typhi to the human host is a fimbrial operon termed tcf, for Typhi colonization factor. Serotype Typhi is the
only serotype within Salmonella reference collection C
(SARC), a strain collection consisting of 16 isolates
representing all phylogenetic lineages within the genus
Salmonella, which hybridizes with a DNA probe specific to
the tcf operon (20). The serotype Typhi tcf operon consists of four genes, tcfABCD, which
display sequence homology to genes within the coo operon,
encoding CS1 fimbriae of human-adapted enterotoxigenic
Escherichia coli. Interestingly, colonization factor
antigens such as CS1 confer the species specificity of enterotoxigenic
E. coli isolates that are adapted to the human host
(14). From the restricted distribution among
Salmonella serotypes and its homology with genes encoding a
human colonization factor, Folkesson and coworkers concluded that the
tcf operon encodes serotype Typhi-specific fimbriae, which
may play a role in the strict human specificity observed for this
pathogen (20).
The advent of complete genome sequencing allows identification of all
putative fimbrial operons present in a bacterial pathogen. The
information obtained from shotgun sequencing of the serotype Typhi
genome can hence be used to investigate further whether the presence of
genes encoding an individual adhesin or a combination of putative
fimbrial operons correlates with adaptation of this pathogen to the
human host. To cover the spectrum of genetic diversity among
Salmonella serotypes, the distribution of putative serotype Typhi fimbrial operons can be determined by hybridization with strains
of the SARC collection, which represent isolates of all phylogenetic
lineages within the genus Salmonella, including
Salmonella bongori and S. enterica subspecies I,
II, IIIa, IIIb, IV, VI, and VII (9). Within the SARC
collection, one phylogenetic group, S. enterica subspecies
I, is of particular interest for public health because it contains
approximately 60% of known Salmonella serotypes
(38). Furthermore, members of S. enterica
subspecies I are frequently isolated from mammals and birds and account
for more than 99% of cases of disease reported from humans and
domesticated animals (1). In contrast, members of S. bongori and S. enterica subspecies II to VII are rarely
isolated from mammals or birds but rather represent reptile-associated
Salmonella serotypes (7, 38). The SARC
collection contains only two serotypes of S. enterica subspecies I, the host-restricted serotype Typhi and the
broad-host-range serotype Typhimurium (9). Thus, to
compare the repertoire of putative serotype Typhi fimbrial operons with
that of other serotypes adapted to humans, livestock, or domestic fowl,
hybridization analysis with fimbrial biosynthesis genes has to be
extended to include common S. enterica subspecies I
serotypes which are not represented in the SARC collection. For
instance, S. enterica subspecies I contains a number of
well-characterized host-restricted serotypes, such as the avian-adapted
Gallinarum, the bovine-adapted Dublin, the porcine-adapted
Choleraesuis, and several human-adapted typhoidal serotypes, including
Paratyphi A, Paratyphi B, Paratyphi C, and Sendai. In addition, several
broad-host-range serotypes of S. enterica subspecies I, such
as Enteritidis, Heidelberg, and Agona, are frequently associated with
diarrheal disease in humans and hence should be included in an
investigation on the distribution of fimbrial operons within this genus.
In this study, we have identified open reading frames in the serotype
Typhi genome which display homology to fimbrial biosynthesis genes.
Hybridization analysis was performed to compare the genomic repertoire
of putative fimbrial operons present in serotype Typhi with that
present in strains of the SARC collection and a representative collection of S. enterica subspecies I serotypes. This
analysis provided an impression of the complete makeup of fimbrial
biosynthesis genes present in serotype Typhi and its relation to the
fimbrial repertoires present in other members of its genus.
Bacterial strains.
SARC has been described previously
(9). Salmonella serotypes of S. enterica subspecies I were isolates from Salmonella reference collection B (SARB), which has been reported recently (8). CT18 is multiple-antibiotic-resistant, Vi-positive
serotype Typhi strain carrying two plasmids (pHCM1 and pHCM2) which was isolated in the Mekong Delta (Vietnam) from a child with uncomplicated typhoid fever. The serotype Typhi strain Ty2 was first isolated in 1918 in Cherson, and this laboratory strain was obtained from stock
maintained at the American Type Culture Collection (ATCC 19430). An
avirulent derivative of strain Ty2, termed Ty21a, which was
subsequently licensed for use as a live oral vaccine, was originally
described by Germanier and Fürer (21) and received from the American Type Culture Collection (ATCC 33459). H901 is a
serotype Typhi strain with reduced virulence which was obtained from
the American Type Culture Collection (ATCC 33458) and has been
described previously (24). Clinical serotype Typhi strains from the State of California Health Laboratory isolated in different years have been described previously (29). The E. coli strain TA One Shot was purchased from Invitrogen.
DNA analysis.
Nucleotide sequences of serotype Typhi with
homology to fimbrial biosynthesis genes were identified by homology
search using the programs BlastX and BlastP (2, 3). The
sequence data of clinical isolate CT18 were produced by the Typhi
Sequencing Group at the Sanger Centre and can be obtained from
http://www.sanger.ac.uk/Projects/S_typhi. Comparison of deduced amino
acid sequences and design of PCR primers were performed using the
program MacVector 6.5 (Oxford Molecular Group Inc.).
Generation of nucleotide probes.
DNA probes specific for the
pef, lpf, agf, fim, and sef operons have been
described previously (6). The major fimbrial subunits of
the tcf operon (tcfA) and the bcf
operon (bcfA) were PCR amplified and cloned into vector
pCR2.1-TOPO (Invitrogen) to give rise to plasmids pNK37 and pNK38,
respectively (Table 1). A fragment of the
safC gene was PCR amplified and cloned (pST4) to generate a
DNA probe specific for the saf operon. DNA regions
containing fragments of staAB, stbA, stcAB, stdA, steB, stgAB, and sthAB were PCR amplified and cloned into
plasmid vector pCR2.1-TOPO to give rise to plasmids pNK4, pNK9, pNK29,
pNK13, pST11, pNK1, and pST13, respectively. The primers for PCR
amplification of fimbrial biosynthesis genes are listed in Table 1.
After agarose gel electrophoresis, PCR products were isolated using a
QiaexII kit (Qiagen) and the protocols provided by the manufacturer.
Subsequently, PCR products were cloned using a TA-TOPO cloning kit from
Invitrogen. Plasmid DNA was isolated using ion exchange columns from
Qiagen. DNA probes were generated after EcoRI restriction of
plasmids and gel purification of insert DNA by labeling the restriction fragments depicted in Fig. 1 using the labeling and detection kit
(nonradioactive) from NEN.
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.5.2894-2901.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Salmonella enterica Serovar Typhi Possesses a Unique
Repertoire of Fimbrial Gene Sequences
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
TABLE 1.
Oligonucleotide primers used in this study
Southern hybridization. Isolation of total bacterial DNA was performed as recently described (4). DNA was restricted with EcoRI, and the fragments were separated on a 0.5% agarose gel. Southern transfer of DNA onto a nylon membrane was performed as previously described (4). Hybridization was performed at 65°C in solutions without formamide. One 15-min wash was performed under nonstringent conditions at room temperature in 2× SSC (1× SSC is 0.15 M NaCl plus 0.015 M sodium citrate)-0.1% sodium dodecyl sulfate (SDS). Subsequently, one 15-min wash was performed under stringent conditions at 65°C in 0.2× SSC-0.1% SDS. Hybrids were detected using the labeling and detection kit (nonradioactive) from NEN.
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Identification of putative fimbrial operons. Three pathways for the assembly of fimbrial adhesins have been described in members of the family Enterobacteriaceae to date. These include the chaperone-usher-dependent assembly pathway (46), the nucleator-dependent assembly pathway (22), and the assembly pathway for type IV fimbriae (25). While exported fimbrial subunits that assemble into fimbrial filaments show little sequence homology, the amino acid sequences of components involved in the export and assembly process do tend to be conserved within each pathway. To identify putative fimbrial operons in the serotype Typhi genome, we therefore performed homology searches using sequences of fimbrial proteins known to be involved in assembly.
Putative serotype Typhi fimbrial operons of the nucleator-dependent assembly class were identified by homology search (BlastP) with amino acid sequences of aggregative (also known as curli) fimbrial proteins from serotype Typhimurium (40). Only one fimbrial operon was identified, which represented the serotype Typhi orthologue of the aggregative fimbrial (agf) operon of serotype Typhimurium. The presence in some Salmonella serotypes of genes encoding type IV fimbriae is suggested by hybridization analysis using genes encoding the bundle-forming pilus (bfp) of enteropathogenic E. coli as DNA probes. However, this DNA probe does not hybridize with genomic DNA from serotype Typhi (42). The identification of a gene cluster for the production of serotype Typhi type IV pili was described recently (54). This fimbrial operon was located on a large (>135 kb) DNA region which was absent from serotype Typhimurium (Genome Sequencing Center, personal communication) and contained capsule (Vi antigen) biosynthesis genes and a bacteriophage carrying the sopE1 gene. The serotype Typhi genome was scanned for additional putative type IV fimbrial operons using the amino acid sequences of the type IV prepilin peptidases TcpJ of Vibrio cholerae, BfbP of enteropathogenic E. coli, PilC and PilD of Pseudomonas aeruginosa, and PilD of Neisseria gonorrhoeae (26, 28, 35, 53). An operon orthologous to the cryptic E. coli ppdD hopBC operon was detected in the serotype Typhi genome (51). Due to the apparent lack of type IV fimbriae in E. coli K-12 and the lack of phenotype of an E. coli hopB mutant, the function of the ppdD hopBC operon, if any, is presently unclear. It is questionable whether the cryptic ppdD hopBC operon is related to fimbrial biosynthesis, because homologues of these genes encode transfer functions of conjugative plasmids or are found in the genomes of filamentous phages. The ppdD and hopBC genes may hence represent the remnant of an integrated plasmid or bacteriophage, and the serotype Typhi orthologues were not characterized further in this study. Twelve putative serotype Typhi fimbrial operons of the chaperone-usher-dependent assembly class were identified by NCBI Blast homology searches within the serotype Typhi genome (Fig. 1). Four of these operons, sef, tcf, saf, and fim, had been described previously (16, 20, 41). However, the CT18 genome contained stop codons in sefA, sefD, and fimI (Fig. 1). Furthermore, an additional open reading frame (safE) was detected in the saf operon of strain CT18. The saf and tcf operons were present on an approximately 60-kb DNA region which was absent from the E. coli K-12 genome and flanked on one side by a tRNA gene (aspV). Similarly, the sef operon was located on a DNA region that was absent from E. coli K-12 and flanked on one side by a tRNA gene (leuX). In contrast, an orthologue of the serotype Typhi fimACDHF operon (designated sfmACDHF) was located at the corresponding map position (5' of the folD gene) in the E. coli K-12 genome. It should be pointed out that the E. coli orthologue of the serotype Typhi fim operon is not identical with the E. coli fim operon. The fim operon of E. coli maps to a different location than that of serotype Typhi, and both gene clusters are distinct in gene order and the number of genes present. Thus, despite the fact that the fim operons of E. coli and serotype Typhi both encode mannose-sensitive adhesins which are termed type I fimbriae, these two operons are clearly paralogous. An orthologue of the E. coli fim operon was not present in the serotype Typhi genome.
|
Distribution of putative fimbrial operons of the
chaperone-usher-dependent assembly pathway within the genus
Salmonella.
The serotype Typhi genome contained 12 putative fimbrial operons of the chaperone-usher-dependent assembly
class (Fig. 1). The distribution among a representative set of S. enterica subspecies I serotypes has been determined for only three
of these operons, fim, saf, and sef (5, 16,
20, 45). To determine the distribution of the remaining fimbrial
operons of the chaperone-usher-dependent assembly pathway among strains
of S. enterica subspecies I, Southern blot analysis was
performed with genomic DNA from 20 strains of the SARB collection (Fig.
2A). Each DNA probe gave hybridization signals with several Salmonella serotypes. Furthermore, none
of the fimbrial operons was restricted to typhoidal
Salmonella serotypes (Typhi and Paratyphi A, B, and C).
While hybridization analysis demonstrated that safB, bcfAB, stbA,
stdA, steB, and sthAB are well conserved among isolates
of S. enterica subspecies I, DNA probes specific for
tcfB, staAB, stcAB, and stgAB produced a
scattered hybridization pattern within this group. The scattered
phylogenetic distribution of tcfBC, staAB, stcAB, and
stgAB suggests that deletions and/or horizontal transfer
events of the corresponding putative fimbrial operons occurred multiple
times within S. enterica subspecies I, generating different
combinations of fimbrial operons in different serotypes.
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,
operon not present.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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While the distribution among Salmonella serotypes is known for individual fimbrial operons or a selected subset of operons, previous studies fall short of establishing the total number of fimbrial operons present in a particular Salmonella serotype (6, 11, 15, 20, 45, 47). A study showing that a serotype Typhimurium strain carrying mutations in all known fimbrial operons (fim, lpf, pef, and agf) is still able to express several morphologically distinct fimbrial structures suggests that a number of fimbrial operons have not yet been described (50). To obtain a first impression of how many fimbrial operons may be present in a particular Salmonella serotype, we searched the genomic sequence of the serotype Typhi strain CT18 for putative fimbrial genes. The serotype Typhi genome contained one member of the nucleator-dependent assembly class of fimbrial operons which represented an orthologue of the serotype Typhimurium agf operon (40). Furthermore, a type IV pilus operon present in CT18 has been characterized previously in serotype Typhi (54). In addition, the serotype Typhi genome contained 12 putative fimbrial operons of the chaperone-usher-dependent assembly class, 7 of which had not previously been described in the genus Salmonella (Fig. 1). The 12 putative fimbrial operons of the chaperone-usher-dependent assembly class detected in strain CT18 were also present in seven other serotype Typhi strains investigated, including the current oral typhoid vaccine strain Ty21a (Fig. 2B).
A recent study has implicated the tcf fimbrial operon in the adaptation of serotype Typhi to the human host. In support of this idea, it was shown by hybridization analysis using strains of the SARC collection that the tcf operon is a DNA region which is restricted to serotype Typhi (20). Since the 16 strains of the SARC collection include only two serotypes of S. enterica subspecies I (Typhi and Typhimurium) (Fig. 3), we extended this analysis to include other serotypes frequently isolated from humans or domestic animals. Hybridization analysis performed with DNA from 20 representatives of S. enterica subspecies I established that sequences with homology to tcf were not restricted to serotype Typhi (Fig. 2A). While DNA from three typhoidal serotypes, including Typhi, Paratyphi A, and Sendai, hybridized with the tcfA-specific DNA probe, two typhoidal serotypes, Paratyphi B and Paratyphi C, did not contain this DNA region (Fig. 2A and B). Furthermore, DNA from a number of nontyphoidal serotypes, including Heidelberg, Choleraesuis, Montevideo, Typhisuis, and Muenchen, hybridized with the tcfA-specific DNA probe. Thus, the tcf operon is neither specific to serotype Typhi nor restricted to or characteristic of human-adapted typhoidal serotypes. Similarly, none of the other putative fimbrial operons investigated in this study were found to be restricted to serotype Typhi or to human-adapted typhoidal serotypes. This finding may not be surprising, as the detection of fimbrial biosynthesis genes by Southern hybridization does not provide clues about the potential roles of the encoded adhesins during host-pathogen interaction. For instance, the fim operon is well conserved among Salmonella serotypes, as indicated by Southern blot analysis (6, 45). However, the fim operon in serotypes Typhimurium and Typhi encodes an adhesin, termed type 1 fimbriae, which mediates mannose-sensitive hemagglutination (18, 31, 36), whereas in serotype Gallinarum, it encodes surface appendages, termed type 2 fimbriae, which do not mediate mannose-sensitive hemagglutination (13, 37). These differences in the binding specificity of the adhesin encoded by the fim operon are not detected by Southern hybridization (Fig. 2), possibly because the adhesive properties of fimbriae can be altered by point mutations, as recently shown for type 1 fimbriae of E. coli (44). Since the presence of a fimbrial operon in two Salmonella serotypes does not imply that the encoded adhesins possess identical binding properties, it is not possible to make reliable inferences regarding host adaptation using data from Southern hybridization. Although fimbriae may play a role in host adaptation, a simple correlation between host range and the presence of a single fimbrial operon seems at present unlikely.
While alterations in the binding specificity of fimbriae may occur, fimbriae appear to be antigenically conserved (34). Fimbrial antigens are composed of about 1,000 copies of a major fimbrial subunit. The majority of an antibody response against intact whole fimbriae is elicited by the major fimbrial subunit (23, 30). Sequence analyses show that FimA, the major fimbrial subunit of type 1 fimbriae, has 99% sequence identity between serotypes Typhimurium and Enteritidis (17). Similarly, the sequence of serotype Typhimurium lpfA, encoding the major subunit of LP (long polar) fimbriae, differs by only one nonsynonymous change from that of serotype Enteritidis lpfA (33). As a consequence of the high degree of sequence conservation between major fimbrial antigens, serum raised against type 1 fimbriae of serotype Typhimurium or Enteritidis cross-reacts with type 2 fimbriae of serotype Gallinarum and type 1 fimbriae of other Salmonella serotypes (13, 17, 37). Similarly, LpfA of serotypes Enteritidis and Typhimurium, SefA of serotypes Dublin and Enteritidis, and AgfA of various Salmonella serotypes cross-react serologically (15, 16, 33). Furthermore, fimbriae are targeted by the immune response during an infection, as shown by analyzing the serological response to SEF-14 fimbriae during serotype Enteritidis infection in chickens (12), to type 1 fimbriae in human typhoid fever patients (10), and to LpfA during serotype Typhimurium infection in mice (32). Determining the distribution of fimbrial operons is thus a first step in assessing which fimbrial antigens may be expressed by a Salmonella serotype. Interestingly, the repertoire of putative fimbrial operons of the chaperone-usher-dependent assembly class that was detected in the genomic sequence of CT18 was found to be conserved among serotype Typhi isolates (Fig. 2B) but was distinct from that of all other Salmonella serotypes investigated (Fig. 2A). The presence of a unique repertoire of fimbrial biosynthesis genes in serotype Typhi is intriguing and illustrates that our understanding of this aspect in the genetic design of Salmonella serotypes is rather limited. For instance, it is currently an enigma which selective pressures are responsible for generating and maintaining the substantial heterogeneity of fimbrial repertoires found among Salmonella serotypes (Fig. 2).
Evidence for expression of fimbriae assembled by the chaperone-usher-dependent pathway in serotype Typhi is so far only available for the fim operon (18, 31). Thus, with the exception of fim, all operons described in this study should be considered putative. This conclusion is underscored by the finding that several open reading frames in putative fimbrial operons were interrupted by stop codons or frameshift mutations and should thus be considered pseudogenes (Fig. 1). In case these mutations affect genes important for assembly, these operons may not be functional in serotype Typhi. For instance, both fimbrial subunits encoded by the sef gene cluster were pseudogenes in serotype Typhi strain CT18, suggesting that this operon may not encode a functional adhesin. Consistent with this idea, expression of the SefA fimbrial subunit is not detectable by Western blot in serotype Typhi strains hybridizing with a sefA-specific DNA probe (16, 49).
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ACKNOWLEDGMENTS |
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We thank the Genome Sequencing Center, Washington University, St. Louis, for communication of DNA sequence data prior to publication.
Sequence analysis of the serotype Typhi CT18 genome is funded by the Beowulf Genomics Initiative of the Wellcome Trust. Work in A.B.'s laboratory is supported by the Texas Advanced Research (Technology) Program under grant 000089-0051-1999 and Public Health Service grants AI40124 and AI44170.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Medical Microbiology and Immunology, College of Medicine, Texas A&M University System Health Science Center, 407 Reynolds Medical Building, College Station, TX 77843-1114. Phone: (979) 862-7756. Fax: (979) 845-3479. E-mail: abaumler{at}tamu.edu.
Editor: A. D. O'Brien
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Abstract
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Materials and Methods
Results
Discussion
References
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Infection and Immunity, May 2001, p. 2894-2901, Vol. 69, No. 5
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.5.2894-2901.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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