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Journal of Bacteriology, April 2000, p. 2341-2344, Vol. 182, No. 8
Institute for Animal Health, Compton,
Berkshire RG20 7NN, United Kingdom,1 and
Indian Veterinary Research Institute, Izatnagar, Bareilly
243122, India2
Received 12 November 1999/Accepted 31 January 2000
Type III secreted Sop protein effectors are delivered into target
eukaryotic cells and elicit cellular responses underlying Salmonella pathogenicity. In this work, we have identified
another secreted protein, SopE2, and showed that SopE2 is an important invasion-associated effector. SopE2 is encoded by the sopE2
gene which is present and conserved in pathogenic strains of
Salmonella. SopE2 is highly homologous to SopE, a protein
encoded by a gene within a temperate bacteriophage and present in only
some pathogenic strains.
A variety of gram-negative
pathogenic bacteria possess a dedicated protein secretion system,
denoted type III, which is of primary importance for the successful
engagement of eukaryotic host cells (for a recent review, see reference
8). Type III secretion systems play a central role
in virulence, directing secretion and translocation of several
bacterial effector proteins into the cytoplasm of host cells. It is
becoming apparent that the mechanism of type III secretion and
translocation is conserved in a variety of bacteria, although each
pathogen appears to have a specific set of secreted protein effectors.
Upon translocation, the bacterial protein effectors affect different
host cell functions and elicit a variety of responses. This, in turn,
has a major impact on the development and progress of infection.
Recent work by our group and others has identified a number of protein
effectors (3, 4, 5, 9, 12, 17) secreted and translocated
into eukaryotic cells by the Salmonella Inv/Spa type III
secretion system, which is one of two type III systems present in
salmonellae (for a review, see reference 2). The Inv/Spa system is encoded within a pathogenicity island, SPI-1 (13), and is required for eliciting host cell responses
which in turn result in host cell cytoskeleton rearrangements which assist bacterial entry into nonphagocytic epithelial cells and aid in
the production of proinflammatory signals (for a recent review, see
reference 1). Four of the key proteins in these processes are Sip A, B, C, and D. All these proteins are encoded by a
single polycistronic operon located adjacent to the inv/spa loci (7, 10, 11, 16). At least some of the Sip proteins appear to have multiple activities and perform several functions, but
it is believed that the major function of Sip B, C, and D is to execute
the translocation of a set of specific effector proteins into
eukaryotic cells. One such translocated effector is SopE (5,
17). SopE contributes to the expression of Salmonella invasion by stimulating membrane ruffling via guanidine nucleotide exchange on Rho GTPases CDC42 and Rac (6). The
sopE gene is located outside SPI-1 and is encoded within a
temperate bacteriophage (5, 15). Interestingly, not all
strains of Salmonella carry the sopE gene
(15), suggesting either that the SopE function is redundant
or that there is another protein with functions similar to those of
SopE, in at least some Salmonella strains. We have investigated this suggestion.
SopE was initially identified as a component of protein aggregates
accumulated in the culture media of Salmonella enterica serovar Dublin B1 (sipB mutant) (17). This
suggested that sipB mutants of different
Salmonella strains may have different profiles of Sop
proteins deposited into filamentous aggregates. In order to assess the
Sop protein profiles from Salmonella strains with different
host specificities, we first transduced the polar sipB mutation from serovar Dublin B1 into a variety of other
Salmonella strains (virulent field isolates from the IAH
strain collection) by using P22 transduction. The correct mutations in
Cmr transfectants (one for each strain) were confirmed by
PCR (data not shown). Different sipB mutant strains were
then grown overnight at 25°C in Luria-Bertani medium, were diluted
10-fold in fresh LB medium, and were incubated for 5 h at 37°C.
All Salmonella strains tested produced filaments similar to
those produced by serovar Dublin B1. The protein filament aggregates
accumulated in each flask were collected and washed in
phosphate-buffered saline, essentially as described earlier
(17). Filaments were dissolved in sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) loading buffer,
and proteins were separated by SDS-12% PAGE. The gel was stained with
Coomassie brilliant blue (Fig. 1A) or was
blotted onto a nitrocellulose membrane and probed with an anti-SopE
monoclonal antibody (Fig. 1B). The analysis of the Coomassie-stained
gel revealed that filament aggregates isolated from each
Salmonella strain were composed of a similar set of proteins, migrating in each case with a profile closely resembling that
of serovar Dublin (Fig. 1A). The monoclonal anti-SopE antibodies (17), however, did not recognize the ~30-kDa protein from
Salmonella enterica serovar Typhimurium F98 isolated from a
chicken and serovar Typhimurium ST5306 isolated from a pig (Fig. 1B).
In both cases, however, this protein appeared to migrate with the same
apparent molecular weight as SopE from serovar Dublin. We then
attempted to amplify a sopE-specific DNA fragment by PCR by
using genomic DNA from different Salmonella strains as a
template with SEup (5'-ACCGAGAAAAGATCTTTAGCAAAAA-3') and
SEdown (5'-CAAGATCAGCTCACACT-3') primers, based on the known
DNA sequence of sopE from serovars Dublin and Typhimurium.
No DNA fragment was amplified when DNA from serovar Typhimurium F98 or
ST5306 was used as a template, but a sopE-specific DNA
fragment of the expected size was amplified in all other samples (data
not shown). This further suggested that serovar Typhimurium F98 and
ST5306 did not possess sopE and that the ~30-kDa protein
from these two strains may be a different protein. To investigate this
protein further, we extracted the 30-kDa protein produced by serovar
Typhimurium F98, subjected it to N-terminal amino acid sequencing, and
used it for immunization of mice to raise monoclonal antibodies. The
sequence of 15 amino acids was determined to be
X-N-I-T-L-S-T-Q-H-Y-R-I-H-R-S. This sequence was then analyzed by using
the BLAST search program against a partial genomic sequence of serovar
Typhimurium and Salmonella enterica serovar Paratyphi
available from the Genome Sequencing Center at Washington University
School of Medicine, St. Louis, Mo.
(http://genome.wustl.edu/gsc/bacterial/salmonella.shtml) and against
that of serovar Typhi available from Sanger Center
(http://www.sanger.ac.uk/Projects/S_typhi/blast_server.shtml). This
analysis revealed a match with the product of an open reading frame
(ORF) present in all three Salmonella serotypes. (In the available nucleotide sequence from serovar Typhi there is a deletion of
one nucleotide at position 73 within this ORF leading to a frame shift.
It is unclear at this moment if this is due to a posisble sequencing
mistake.) The deduced amino acid sequence of the protein product of
this ORF was highly homologous to SopE (see below). We therefore
designated this protein SopE2, and the ORF was designated
sopE2. DNA fragments containing a complete sopE2
gene and upstream areas from serovars Dublin 2229 and Typhimurium F98
were amplified by PCR by using an upstream primer SE3
(5'-TTAAGCATAAGCTTAATTCCATTTGTT-3') and a downstream primer
SE4 (5'-CTGATAAATGAATTCAGGCCGCATC-3') based on the available
sequence from serovar Typhi and modified to include restriction sites.
Chromosomal DNA from serovars Dublin 2229 and Typhimurium F98 were used
as templates. The resulting DNA fragments were cloned into pBluescript
to yield pSopE2sd and pSopE2st, respectively. The sequence of the
cloned DNA in both plasmids was identical to that of an ORF obtained
from the serovar Typhimurium genome database. The deduced amino acid
sequence of the SopE2 protein was 64% identical to that of SopE (Fig.
2). The SopE2 sequence was found to be
remarkably conserved in different Salmonella serotypes, with
only six amino acid substitutions in SopE2 in serovar Paratyphi
compared to that in serovars Typhimurium and Dublin. We next designed
two primers, SE2up (5'-TCGTGGGAGCGGATCCGAGGGTAGGGCAGTAT-3') and SE2down (5'-TGCGCAGCCTCGAGTATCTCTTTCAGAAA-3'),
from an internal part of sopE2 and used them in PCR
with DNA from different Salmonella strains as template. The
sopE2-specific DNA was present in all Salmonella
strains analyzed, including strains with different host specificities
(data not shown). Together, these data suggest that the
sopE2 sequence is present and conserved in different S. enterica strains.
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Identification of SopE2, a Salmonella
Secreted Protein Which Is Highly Homologous to SopE and Involved in
Bacterial Invasion of Epithelial Cells
ABSTRACT
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FIG. 1.
Analysis of the proteins secreted by different
Salmonella strains (sipB mutants). The secreted
proteins deposited by each strain into proteinaceous filaments were
isolated as described earlier (17). The protein samples from
serovar Dublin B1 (lane 1), Salmonella enterica serovar
Gallinarum S9.B1 (lane 2), Salmonella enterica serovar
Enteritidis S13.B1 (lane 3), serovar Typhimurium F98.B1 (lane 4),
serovar Typhimurium ST4/74.B1 (lane 5), serovar Typhimurium ST5306.B1
(lane 6), and Salmonella enterica serovar Choleraesuis
A57.B1 (lane 7) were separated by SDS-12% PAGE and were stained with
Coomassie brilliant blue (A) or were transferred onto nitrocellulose
membrane and probed with an anti-SopE monoclonal antibody (B).
Molecular mass is shown on the left.
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FIG. 2.
Sequence alignment of serovars Dublin SopE and
Typhimurium F98 SopE2. Lines indicate identical amino acids, and colons
and periods indicate conservative amino acid substitutions.
A DNA fragment amplified by using serovar Typhimurium DNA was cloned
into the pDM4 suicide plasmid (14) to yield pSB1.
sopE2 mutant serovar Typhimurium SE2.1 was constructed by
crossing pSB1 from Escherichia coli S17.1 
pir into
parental serovar Typhimurium F98, and correct insertion of the suicide
plasmid was confirmed by PCR. The mutation was transcomplemented by
introducing the pSopE2st plasmid into serovar Typhimurium SE2.1. The
growth characteristics of the sopE2 mutant and the
transcomplemented strains in LB medium at 37°C were undistinguishable
from those of the wild-type strain (data not shown). The proteins
produced and secreted by the different Salmonella strains in
LB medium at 37°C were isolated as described earlier (17)
and were analyzed by SDS-PAGE and Western blotting by using monoclonal
anti-SopE2 antibodies. The SDS-PAGE analysis revealed that the
sopE2 mutation did not cause any apparent effect on the
expression and secretion of secreted proteins other than a 30-kDa
protein (data not shown). The Western blot analysis revealed that a
faint protein band at 30 kDa, present in the wild-type strain, was
missing in the sopE2 mutant but reappeared in the transcomplemented strain (Fig. 3),
suggesting that the observed 30-kDa protein is SopE2.
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The wild-type, mutant, and transcomplemented strains were then assessed
in a cultured cell invasion assay, essentially as described earlier
(17). The results of this experiment clearly showed that
serovar Typhimurium SE2.1 had a reduced ability to invade HeLa cells
(Fig. 4). The invasion phenotype was
partially restored by complementing the mutations in trans,
demonstrating that the invasion defect in the mutant strain is due to
inactivation of sopE2.
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Thus, we have identified SopE2, an invasion-associated secreted protein of Salmonella. Structurally, sopE2 is very similar to sopE, suggesting that these two genes have the same evolutionary origin and/or that one of these genes is a product of gene duplication. The high structural similarity between SopE2 and SopE and the similar phenotypic effects caused by inactivation of SopE- and SopE2-encoding genes suggest that these two proteins are likely to have similar mechanisms of action. Unlike sopE, sopE2 appears to be broadly distributed in salmonellae, suggesting that conservation of this gene may be more important than that of sopE. Thus, it appears that at least some Salmonella strains possess two functional genes, encoding virulence-associated type III secreted proteins highly similar to each other. This finding prompted us to compare sequences of other known secreted proteins with sequences deposited in the Salmonella genome database. No homologues were found for SopB (3), AvrA (4), or SptP (12). However, our analysis revealed that there is a gene encoding a SopD (9) homologue. The sequence of this protein is 41% identical to that of SopD (data not shown).
The type III secretion/translocation mechanism appears to be conserved in many gram-negative bacteria; however, each pathogen has a specific set of type III secreted effector proteins. An ability to expand the repertoire of such effectors without the risk of loosing essential functions may allow pathogens more flexibility in adapting within different host environments. It is interesting to note a remarkable conservation of the SopE2 sequence in different Salmonella serotypes, as this is in contrast to the conservation of SopE. SopE proteins from serovars Dublin and Typhimurium, for example, show only 90% overall identity, indicating a rapid evolution of the sopE gene in Salmonella. It is also worthy to note that the sopE gene is carried by a bacteriophage (5, 15). Together, these data suggest that Salmonella appears to possess a mechanism which enables the preservation of one copy of some genes encoding effector proteins while allowing simultaneous rapid evolution of the gene sequence. Those mutated gene variants that provide selective advantage can then be disseminated throughout the population via mobile genetic elements.
Nucleotide sequence accession number. The sequence of the DNA fragment from serovar Typhimurium F98 identical to that from serovar Dublin 2229 was deposited in the EMBL database under accession no. AF200952.
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ACKNOWLEDGMENTS |
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The work presented here was supported by the Biotechnology and Biological Sciences Research Council of the United Kingdom; the United Kingdom Ministry of Agriculture, Fisheries and Food; the India/UK TOMBIT project financed by the United Kingdom Department for International Development; and the Indian Council for Agricultural Research.
C.S.B. and V.P.S. contributed equally to this work.
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FOOTNOTES |
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* Corresponding author. Mailing address: Institute for Animal Health, Compton, Berkshire RG20 7NN, United Kingdom. Phone: (44) 1635 577291. Fax: (44) 1635 577243. E-mail: edouard.galyov{at}bbsrc.ac.uk.
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REFERENCES |
|---|
|
Top
Abstract
Text
References
|
|---|
| 1. |
Darwin, K. H., and V. L. Miller.
1999.
Molecular basis of the interaction of Salmonella with the intestinal mucosa.
Clin. Microbiol. Rev.
12:405-428 |
| 2. | Galán, J. E. 1999. Interaction of Salmonella with host cells through the centisome 63 type III secretion system. Curr. Opin. Microbiol. 2:46-50[CrossRef][Medline]. |
| 3. | Galyov, E. E., M. W. Wood, R. Rosqvist, P. B. Mullan, P. R. Watson, S. Hedges, and T. S. Wallis. 1997. A secreted effector protein of Salmonella dublin is translocated into eukaryotic cells and mediates inflammation and fluid secretion in infected ileal mucosa. Mol. Microbiol. 25:903-912[CrossRef][Medline]. |
| 4. |
Hardt, W.-D., and J. E. Galán.
1997.
A secreted Salmonella protein with homology to a virulence determinant of plant pathogenic bacteria.
Proc. Natl. Acad. Sci. USA
94:9887-9892 |
| 5. |
Hardt, W.-D.,
H. Urlaub, and J. E. Galán.
1998.
A target of the centisome 63 type III protein secretion system of Salmonella typhimurium is encoded by a cryptic bacteriophage.
Proc. Natl. Acad. Sci. USA
95:2574-2579 |
| 6. | Hardt, W.-D., L.-M. Chen, K. E. Shuebel, X. R. Bustello, and J. E. Galán. 1998. Salmonella typhimurium encodes an activator of Rho GTPases that induces membrane ruffling and nuclear responses in host cells. Cell 93:815-826[CrossRef][Medline]. |
| 7. | Hermant, D., R. Menard, N. Arricau, C. Parsot, and M. Y. Popoff. 1995. Functional conservation of the Salmonella and Shigella effectors of entry into epithelial cells. Mol. Microbiol. 17:781-789[CrossRef][Medline]. |
| 8. |
Hueck, C. J.
1998.
Type III protein secretion systems in bacterial pathogens of animals and plants.
Microbiol. Mol. Biol. Rev.
62:379-433 |
| 9. |
Jones, M. A.,
M. W. Wood,
P. B. Mullan,
P. R. Watson,
T. S. Wallis, and E. E. Galyov.
1998.
Secreted effector proteins of Salmonella dublin act in concert to induce enteritis.
Infect. Immun.
66:5799-5804 |
| 10. |
Kaniga, K.,
D. Trollinger, and J. E. Galán.
1995.
Identification of two targets of the type III secretion system encoded in the inv and spa loci of Salmonella typhimurium that share homology to IpaD and IpaA proteins.
J. Bacteriol.
177:7078-7085 |
| 11. |
Kaniga, K.,
S. G. Tucker,
D. Trollinger, and J. E. Galán.
1995.
Homologues of the Shigella invasins IpaB and IpaC are required for Salmonella typhimurium entry into cultured cells.
J. Bacteriol.
177:3965-3971 |
| 12. | Kaniga, K., J. Uralil, J. B. Bliska, and J. E. Galán. 1996. A secreted tyrosine phosphatase with modular effector domains encoded by the bacterial pathogen Salmonella typhimurium. Mol. Microbiol. 21:633-641[CrossRef][Medline]. |
| 13. | Mills, D. M., V. Bajaj, and C. A. Lee. 1995. A 40 kb chromosomal fragment encoding Salmonella typhimurium invasion genes is absent from the corresponding region of the Escherichia coli K-12 chromosome. Mol. Microbiol. 15:749-759[CrossRef][Medline]. |
| 14. |
Milton, D. L.,
R. O'Toole,
P. Hörstedt, and H. Wolf-Watz.
1996.
Flagellin A is essential for the virulence of Vibrio anguillarum.
J. Bacteriol.
178:1310-1319 |
| 15. |
Mirold, S.,
W. Rabsch,
M. Rohde,
S. Stender,
H. Tschäpe,
H. R ssmann,
E. Igwe, and W.-D. Hardt.
1999.
Isolation of a temperate bacteriophage encoding the type III effector protein SopE from epidemic Salmonella typhimurium strain.
Proc. Natl. Acad. Sci. USA
96:9845-9850 |
| 16. | Pegues, D. A., M. J. Hantman, I. Behlau, and S. I. Miller. 1995. PhoP/PhoQ transcriptional repression of Salmonella typhimurium invasion genes: evidence for a role in protein secretion. Mol. Microbiol. 17:169-181[CrossRef][Medline]. |
| 17. | Wood, M. W., R. Rosqvist, P. B. Mullan, M. H. Edwards, and E. E. Galyov. 1996. SopE, a secreted protein of Salmonella dublin, is translocated into the target eukaryotic cell via a sip-dependent mechanism and promotes bacterial entry. Mol. Microbiol. 22:327-338[CrossRef][Medline]. |
Journal of Bacteriology, April 2000, p. 2341-2344, Vol. 182, No. 8
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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114: 1331-1341
[Abstract] -
Cherayil, B. J., McCormick, B. A., Bosley, J.
(2000). Salmonella enterica Serovar Typhimurium-Dependent Regulation of Inducible Nitric Oxide Synthase Expression in Macrophages by Invasins SipB, SipC, and SipD and Effector SopE2. Infect. Immun.
68: 5567-5574
[Abstract] [Full Text] -
Friebel, A., Ilchmann, H., Aepfelbacher, M., Ehrbar, K., Machleidt, W., Hardt, W.-D.
(2001). SopE and SopE2 from Salmonella typhimurium Activate Different Sets of RhoGTPases of the Host Cell. J. Biol. Chem.
276: 34035-34040
[Abstract] [Full Text]
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