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Journal of Bacteriology, October 2001, p. 6036-6045, Vol. 183, No. 20
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.20.6036-6045.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
SseBCD Proteins Are Secreted by the Type III Secretion
System of Salmonella Pathogenicity Island 2 and Function
as a Translocon
Thomas
Nikolaus,1
Jörg
Deiwick,1
Catherine
Rappl,1
Jeremy A.
Freeman,2
Werner
Schröder,3
Samuel I.
Miller,2,4 and
Michael
Hensel1,*
Lehrstuhl für Bakteriologie, Max von
Pettenkofer-Institut für Hygiene und Medizinische
Mikrobiologie, Ludwig-Maximilians-Universität München,
Munich,1 and Fachbereich Biologie,
Chemie, Pharmazie, Freie Universität Berlin,
Berlin,3 Germany, and Departments of
Microbiology2 and
Medicine,4 University of Washington,
Seattle, Washington
Received 24 April 2001/Accepted 26 June 2001
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ABSTRACT |
The type III secretion system encoded by
Salmonella pathogenicity island 2 (SPI2) is required for
systemic infections and intracellular accumulation of Salmonella
enterica. This system is induced by intracellular
Salmonella and subsequently transfers effector proteins
into the host cell. Growth conditions either inducing
expression of the type III secretion system or the secretion of
substrate proteins were defined. Here we report the identification of a
set of substrate proteins consisting of SseB, SseC, and SseD that are
secreted by the SPI2 system in vitro. Secretion was observed if
bacterial cells were exposed to acidic pH after growth in minimal medium with limitation of Mg2+ or phosphate. SseB, -C, and
-D were isolated in a fraction detached from the bacterial cell surface
by mechanical shearing, indicating that these proteins are
predominantly assembled into complexes on the bacterial cell surface.
The three proteins were required for the translocation of SPI2 effector
proteins SspH1 and SspH2 into infected host cells. Thus, SseB, SseC,
and SseD function as the translocon for effector proteins by
intracellular Salmonella.
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INTRODUCTION |
The translocation of virulence
proteins into the cells of an infected host organism has a central role
for the pathogenesis of infections by many gram-negative bacteria. This
specific virulence trait is linked to type III secretion systems
(TTSS), complex molecular machines that require the function of at
least 20 genes. TTSS are involved in very different aspects of
pathogenesis, such as invasion of host cells and paralysis of
phagocytes as well as establishment of symbiotic relationships (for a
review, see reference 14). In most cases, sets of
substrate proteins are secreted by the TTSS. However, only a subset of
substrate proteins act as translocated effector proteins. Another
subset of substrate proteins is required for the translocation of
effector proteins and thus acts as a translocator, e.g., by forming
pilus-like structures (17, 27) or by pore formation in the
host cell membrane (31, 32) through which effector
proteins are translocated.
Salmonella enterica is a highly successful pathogen
that causes diseases ranging from mild gastrointestinal
infections to life-threatening systemic infections such as typhoid
fever. A large number of virulence genes is required for S. enterica to be successful as a pathogen in both forms of disease
and in a large number of different hosts. S. enterica
possesses two TTSS with different functions in pathogenesis. Both TTSS
are encoded by large chromosomal gene clusters referred to as
Salmonella pathogenicity islands or SPI. SPI1 encodes a TTSS
that is required for the interaction of extracellular
Salmonella with cells of the gastrointestinal mucosa (for a
review, see reference 7). SPI1 effector proteins have
multiple functions in triggering invasion of Salmonella into nonphagocytic cells and induction of apoptosis and gastrointestinal symptoms.
The second TTSS encoded by SPI2 has an entirely different role in
Salmonella pathogenesis since its function is mainly
restricted to intracellular pathogenesis (for a review, see reference
10). Mutant strains defective in SPI2 are highly
attenuated in virulence and have reduced rates of intracellular
survival and replication (2, 11, 26).
Several substrate proteins of the TTSS of SPI2 in S. enterica serovar Typhimurium have been identified so far. SseB, a
protein with sequence similarity to EspA of enteropathogenic
Escherichia coli (EPEC), is secreted by S. enterica serovar Typhimurium after induction of the SPI2 and
exposure to acidic pH (1). Substrate proteins SseC and
SseD have sequence similarity to EPEC proteins EspD and EspA,
respectively, and recently secretion of SseC and SseD has been shown
(15). EspA, -B, and -D are substrate proteins of the EPEC
TTSS and are required for translocation of the EPEC effector Tir.
A number of proteins appear to be translocated by the SPI2 TTSS into
infected eukaryotic cells. Several of these, including the leucine
repeat proteins SspH1 and SspH2 (24), share a conserved
N-terminal domain which may function to target these proteins to the
secretion apparatus (23).
Here we report the direct identification of a set of secreted substrate
proteins of the TTSS of SPI2. We analyzed the functional requirements
for the secretion of these proteins and their role in translocation of
SPI2 effector proteins into host cells.
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
The strains used in
this study are listed in Table 1 and the
position of mutations in various SPI2 genes are indicated in Fig.
1. S. enterica serovar
Typhimurium and E. coli strains were routinely cultivated in
Luria broth (LB) containing antibiotics (carbenicillin at 50 µg/ml,
kanamycin at 50 µg/ml, and chloramphenicol at 10 to 50 µg/ml) if
required to maintain plasmids. The composition of minimal media has
been described before (3). Briefly,
low-Mg2+ minimal medium containing N-salts [5 mM
KCl, 7.5 mM
(NH4)2SO4, 0.5 mM K2SO4, 100 mM
bis-Tris-HCl], 30 µM MgCl2, 38 mM glycerol, and 0.1% Casamino Acids was adjusted to pH 7.0 or 5.0 as indicated. Minimal media containing high (PCN) or low (PCN-P) concentrations of
phosphate were used as described before (3). For PCN-P
medium at pH 5.8, 80 mM MOPS (morpholinepropanesulfonic acid) was
replaced by 80 mM MES (morpholineethanesulfonic acid). Minimal media
were prepared with double-distilled water.
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FIG. 1.
Genetic organization of SPI2 and position of mutations
used in this study. sse genes encoding secreted
substrate proteins of the TTSS of SPI2 characterized in this work are
indicated by black arrows. Genes encoding the TTSS
(ssa), the regulatory system (ssr), and
chaperones of substrate proteins (ssc) are represented
by shaded, hatched, and cross-hatched symbols, respectively. Open
arrows indicate further genes for putative secreted substrate proteins.
The alternative designations of SPI2 genes used by Ochman et al.
(26) are indicated in parentheses.
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Generation of antisera against recombinant SPI2 proteins.
Generation of antisera against recombinant SseB (rSseB) has been
described (1) and recombinant SPI2 proteins were expressed and purified essentially as outlined before (3). Briefly,
primers were used to amplify sseD and the 3' portion of
sseC and to introduce restriction sites as indicated in
Table 2. PCR products were then ligated
to vectors of the pQE3x and pQE4x series to generate fusions with an
N-terminal tag of six histidines. Fusion proteins were expressed
in E. coli M15(pREP) (Qiagen, Hilden, Germany) and
purified under denaturing conditions on Hi-trap chelating columns
(Pharmacia, Freiburg, Germany) according to the manufacturers' instructions. Recombinant proteins were further purified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) on
preparative gels and electroelution of the relevant protein bands. For
the generation of antisera, purified recombinant proteins were
emulsified with complete and incomplete Freund's adjuvant for initial
and booster immunizations, respectively. Antisera were raised in
rabbits following standard procedures (8) and in
accordance with the national and institutional guidelines for animal
handling.
Immunoglobulin G (IgG) of the antiserum against SseB was purified using
a protein G-Sepharose column (Pharmacia) according
to the
manufacturer's instructions. For labeling, the carboxysuccinimidyl
ester derivative of fluorescein (NHS-fluorescein; Pierce) was
coupled to IgG as described by Hermanson (
12). Unbound
NHS-fluorescein
was removed by gel filtration using a PD-10 column
(Pharmacia).
The resulting IgG fraction had a fluorescence-to-protein
ratio
of 0.95.
Preparation of secreted proteins.
For preparation of
secreted proteins, bacteria were precultured in LB for 8 h at
37°C. Bacteria were washed once in minimal medium, and equal amounts
of bacteria adjusted by optical density at 600 nm
(OD600) were used to inoculate cultures in
minimal medium at neutral or acidic pH. Cultures (400 ml) in 1-liter
glass flasks without baffles were incubated overnight with agitation of
200 rpm at 37°C. Bacteria were pelleted by centrifugation at
6,000 × g for 15 min and resuspended in 20 ml of
phosphate-buffered saline (PBS). This suspension was agitated at
maximum speed in 50-ml centrifuge tubes (Falcon) on a Vortex mixer
(Vortex Genie 2; Scientific Industries) for 60 s. Bacterial cells
were pelleted by centrifugation at 10,000 × g for 10 min and the supernatant was passed through a 0.2-µm-pore-size filter
to remove residual bacteria. Protein in the supernatant fractions
(detached fraction) was recovered by precipitation with trichloroacetic
acid (10% [wt/vol] final concentration) on ice for 1 h and
centrifugation for 1 h at 10,000 × g. The pellet
was washed twice with 15 ml of acetone and recovered by centrifugation
at 10,000 × g for 30 min. The final pellet was air
dried and resuspended in SDS-PAGE sample buffer (50 mM Tris-HCl [pH
6.8], 4% SDS, 2% 
-mercaptoethanol, 12.5% glycerol, and 0.01%
bromophenol blue). The final concentration of protein in the detached
fraction was adjusted by the cell density of the original culture
(OD600 of 100 ml of culture × 100 = x µl of sample buffer).
For the isolation of secreted protein from culture supernatant,
bacterial cultures were grown overnight in 40 ml of
low-Mg
2+ minimal medium, pH 5.0, in flasks
without baffles. Bacterial
cells were removed by centrifugation (5 min
at 4,000 ×
g) and
filtration of the supernatant
through a 0.45-µm-pore-size filter.
Protein from cell-free culture
supernatants was precipitated by
addition of trichloroacetic acid (10%
[wt/vol] final concentration),
recovered by centrifugation for 1 h at 10,000 ×
g, and washed
twice with
acetone.
-Galactosidase activities in various fractions were determined
according to a standard procedure (
25).
Protein analysis.
Cell-associated and secreted protein
profiles of various S. enterica serovar Typhimurium strains
were routinely analyzed by SDS-PAGE on Tricine gels (12%) or Tris gels
(12%) according to the methods of Schägger and von Jagow
(28) and Laemmli (19), respectively. Protein
bands were visualized by Coomassie brilliant blue staining or silver
staining according to the method of Heukeshoven and Dernick
(13). For analysis by Western blotting, proteins were
transferred onto nitrocellulose membranes (BA85; Schleicher and
Schuell) using the discontinuous semidry blotting procedure (18). Western blots were processed using ECL detection
(Amersham-Pharmacia).
For microsequencing, proteins were transferred onto polyvinylidene
difluoride membranes (Millipore) and stained with Coomassie
brilliant
blue. Microsequencing by Edman degradation was performed
on an Applied
Biosystems A473 sequencer according to the instructions
of the
manufacturer.
Translocation assay.
Determination of SspH1 and SspH2
translocation by the SPI2 TTSS was performed as previously described
(24). Briefly, RAW264.7 murine macrophages were infected
with bacteria harboring a plasmid-borne SspH1-CyaA or SspH2-CyaA
fusion. For infection, bacteria were grown to stationary phase and were
added to macrophages at a multiplicity of infection of 10 for 1 h.
Subsequently, medium containing gentamicin was added to kill
extracellular bacteria and incubation was performed for seven
additional hours to allow for SPI2-dependent translocation by
internalized bacteria. Infected macrophages were then lysed in 0.1 N
HCl and boiled for 5 min. Cellular cyclic AMP (cAMP) levels were
determined with the Direct cAMP Correlate-EIA Kit (Assay Designs, Ann
Arbor, Mich.). The cellular cAMP content was then normalized for
protein concentration as determined by the Bradford assay and is
presented as picomoles of cAMP per microgram of protein. All
experiments were performed in triplicate at least twice.
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RESULTS |
Identification of substrate proteins of the TTSS of
SPI2.
Previous work established that SseB, a substrate protein of
the TTSS encoded by SPI2, is secreted when bacteria are exposed to
media at pH 5.0 or below (1). The majority of SseB,
however, was located on the cell envelope rather than being secreted
into the media. SseB was recovered from the cell envelope by extraction with organic solvents such as hexadecane. We observed that SseB was
also detached from bacterial cells by mechanical shearing. Based on
these observations, we set out to identify further substrate proteins
secreted by the TTSS of SPI2. Bacteria were grown under conditions
inducing the secretion of SPI2 proteins, concentrated, and subjected to
vigorous mixing. Protein detached from the bacterial surface by this
procedure was concentrated and analyzed (Fig. 2). This fraction of secreted proteins
will be referred to as the detached fraction.
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FIG. 2.
Identification of substrate proteins of the TTSS of
SPI2. The S. enterica serovar Typhimurium wild-type (wt)
and ssaV mutant (HH109
ssaV::aphT) strains were grown
overnight in low-Mg2+ minimal medium at pH 7.0 or 5.0. Secreted protein from equal amounts of bacterial cells was recovered by
vigorous mixing and concentrated by acetone precipitation as described
in Materials and Methods. Protein extracts were subjected to
SDS-PAGE on 12% Tricine gels. Subsequently, proteins were visualized
by staining with Coomassie brilliant blue (A) or by silver staining
(B). The N-terminal animo acid sequence of the protein of about 20 kDa
was determined and compared to the predicted gene product of
sseD [SseD (theo.)] (C). For Western blot analyses,
lysates of equal amounts of bacteria grown in low-Mg2+
minimal medium at pH 7.0 or 5.0 (total cell fraction) or protein
recovered by mechanical shearing from equal amounts of bacteria
(detached fraction) was separated by SDS-PAGE and transferred onto
nitrocellulose membranes. Proteins were detected by Western blotting
with antisera raised against rSseC ( SseC), rSseB, or rSseD (D).
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To determine whether this procedure affects the integrity of the
bacterial cell, we used reporter strain MvP131 (
3), which
expresses the reporters luciferase and
-galactosidase under the
growth conditions used here. Compared to the
-galactosidase activity
of the total culture (6,003 Miller units), only very low activities
were detected in the culture supernatant (2.1 Miller units) and
in the
detached fraction (0.3 Miller unit). These data indicate
that the
mechanical agitation did not result in the release of
cytoplasmic
protein due to cell
lysis.
Analysis by SDS-PAGE revealed that a significantly smaller number of
proteins was recovered by mechanical shearing than by
extraction with
hexadecane (data not shown). The protein pattern
obtained by
mechanical shearing was compared for wild-type
S. enterica
serovar Typhimurium and a mutant strain defective in
SsaV, a structural
component of the SPI2 TTSS (Fig.
2A and B).
When bacteria were grown at
pH 5.0, proteins with apparent molecular
masses of about 20, 21, and 52 kDa were secreted by the wild-type
strain but were absent in the
detached fraction of the
ssaV mutant
strain (Fig.
2A
and B). Similar protein patterns were observed
with strains harboring
mutations in
ssaC or
ssaT, further structural
components of the TTSS of SPI2 (data not shown). Therefore, secretion
of these three proteins is dependent on the function of the TTSS
of
SPI2. Another protein of about 63 kDa was present in the detached
fraction of the wild-type and
ssaV mutant strains. Thus, it
is
unlikely that this protein is a substrate of the TTSS of SPI2.
The
N-terminal sequence was determined for the protein of about
20 kDa
(Fig.
2C). A BLAST search revealed that this sequence is
similar to the
predicted N-terminal sequence of SseD. Furthermore,
antibodies raised
against recombinant SPI2 proteins rSseB, rSseC,
and rSseD reacted with
the bands at 21, 52, and 20 kDa, respectively
(Fig.
2D). Signals for
SseB, SseC, and SseD were observed in the
detached fraction of the
wild-type strain grown at pH 5.0 but
not in the detached fraction of
bacterial cultures grown at pH
7.0 or in the detached fractions of the
ssaV mutant strain (Fig.
2D). A mutation in
invG,
a structural component of the TTSS encoded
by SPI1, had no effect on
the secretion of these proteins (data
not shown). Therefore, our
analyses indicate that SseB, SseC,
and SseD are the major secreted
proteins of the SPI2 system. We
also analyzed proteins secreted into
the growth medium under these
culture conditions. Western blot analysis
indicated low amounts
of SseB (data not shown), SseC, and SseD (see
Fig.
5) in culture
supernatants.
We next used fluorescein isothiocyanate (FITC)-labeled antibodies
against SseB to analyze the location of SseB on bacterial
cells (Fig.
3). Microscopic analysis revealed that
SseB-containing
structures were present on the surface on wild-type
S. enterica serovar Typhimurium after growth in minimal
medium at acidic pH.
No staining was detected on a mutant
defective in secretion (Fig.
3) or on wild-type
S. enterica
serovar Typhimurium after growth
at neutral pH (data not shown). We
observed that SseB-containing
structures were not distributed equally
on the bacterial surface
but were concentrated at one pole of the cell.
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FIG. 3.
Detection of surface structures containing SseB. The
S. enterica serovar Typhimurium wild-type and
ssaV mutant strains were grown
overnight in low-phosphate minimal medium at pH 5.8. Bacteria were
fixed with 1.0% formaldehyde in PBS for 10 min and washed three times
in PBS. Fixed bacteria were incubated with FITC-labeled antiserum
against SseB for 1 h, and unbound antibody was removed by washing
in PBS. The suspension was then spotted on
poly-L-lysine-coated microscope slides (Sigma) and
samples were analyzed by epifluorescence microscopy. Phase-contrast
images and images of the FITC channel were overlaid using Adobe
Photoshop.
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Influence of growth conditions on the secretion of SPI2 substrate
proteins.
We previously demonstrated that growth in
low-Mg2+ minimal medium as well as in
low-phosphate minimal medium resulted in the induction of genes
encoding the TTSS of SPI2 (3). Levels of substrate
proteins SseB and SseC were compared after growth of bacterial cultures
in minimal media with different concentrations of phosphate (Fig.
4A and B). A concentration of 337 µM
phosphate allowed bacterial growth (OD600 of
about 1.0 for overnight cultures) as well as high levels of SseB and
SseC synthesis. This phosphate concentration was used for low-phosphate
minimal medium in further experiments. Next, we analyzed whether SPI2
substrate proteins were secreted during growth under phosphate
limitation at acidic pH. Growth of cultures in minimal medium
containing 337 µM phosphate at pH 5.0 did not affect the levels
of SseB and SseC synthesis (Fig. 4B). SseB and SseC were detected
by antibodies in the detached protein fraction of bacterial cultures
grown under phosphate starvation at acidic pH but were absent in the
detached fractions of cultures grown at neutral pH (Fig. 4C). High
intracellular levels of Sse proteins but no secretion were observed
when cultures were grown in these media at neutral pH. Therefore,
Mg2+ limitation as well as phosphate starvation
results in the synthesis and assembly of a TTSS that is capable of
secreting SPI2 substrate proteins under acidic conditions.
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FIG. 4.
Effects of phosphate starvation on function of the TTSS
of SPI2. The S. enterica serovar Typhimurium wild type
was grown in LB or PCN minimal media, pH 7.4, containing various
amounts of phosphate as indicated. Equal amounts of bacterial cells
were subjected to Western blot analysis with antibodies raised against
rSseB ( SseB) or rSseC (A). The amounts of SseB and SseC were
analyzed by Western blot assays of total cell fractions of bacteria
grown in PCN minimal medium containing high (25 mM) or limiting (0.34 mM) amounts of phosphate at neutral or acidic pH (B). Bacteria were
grown in PCN medium containing 0.34 mM phosphate at neutral pH or in
PCN medium adjusted to pH 5.0 by the addition of HCl, and protein was
prepared from bacterial cells by mechanical shearing as described
above. The amounts of SseB and SseC in total cell fractions and in the
detached fractions were analyzed by Western blotting (C).
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Roles of SseB, SseC, and SseD in secretion.
Sensitivity
to mechanical shearing indicates that after secretion by the
TTSS, SseB, SseC, and SseD are present mainly on the surface of
the bacterial cells, suggesting their association in a surface-located
macromolecular structure. An alternative explanation is that substrate
proteins secreted into the growth medium associate with the cell
surface due to unspecific interactions, e.g., polar interactions
between proteins and charged residues in the outer membrane. To
distinguish between these possibilities, we analyzed the functional
requirements for the secretion of the main substrate proteins of SPI2.
Secretion by various strains harboring mutations in the sse,
ssc, or ssa gene (see Fig. 1 for positions
of mutations) was compared. To exclude possible polar effects of
mutations in sse genes on the synthesis of other substrate proteins, the intracellular amounts of SseB and SseC were compared under growth conditions inducing SPI2 expression but not secretion by
the TTSS (Fig. 5A, pH 7.0). A nonpolar
mutation in sseB (strain HH102) did not affect synthesis of
SseC, a mutation in sseC (HH104) had no effect on the
synthesis of SseB, and a mutation in sseD (MvP101) did not
affect intracellular levels of SseB and SseC. A transposon insertion in
sscA encoding a putative chaperone resulted in the absence
of SseC but did not affect the amount of SseB. After growth in medium
at pH 7.0, SseB, SseC, or SseD was not recovered from the
bacterial surface (Fig. 5A).
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FIG. 5.
Functional requirements for secretion by the TTSS of
SPI2. (A) The S. enterica serovar Typhimurium wild type
(wt) and various strains harboring mutations in the ssc,
sse, or ssa gene were grown in
low-Mg2+ minimal medium at pH 7.0 or pH 5.0 to induce
expression or expression and secretion, respectively, of SPI2 substrate
proteins. Lysates of equal amounts of bacteria were adjusted by
OD600 (total cell fraction), or protein recovered from
equal amounts of bacteria (detached fraction) was analyzed as described
in the legend for Fig. 2. n.d., not done. (B) Role of SseB
for secretion of SseC and SseD. Various strains were grown in
low-Mg2+ minimal medium at pH 5.0. Protein from culture
supernatants was prepared as described in Materials and Methods. Equal
amounts of bacterial cells (total cell fraction) and protein prepared
from equal amounts of culture supernatants were subjected to Western
blot analysis with antibodies raised against rSseC ( SseC) or
rSseD.
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The amounts of SseB, SseC, and SseD in the total cell
fractions and detached fractions were analyzed under growth conditions
inducing secretion (Fig.
5A, pH 5.0). The amounts of SseB and
SseC in
total cell fractions of the
ssaV mutant strain were lower
than those for the
sse and
ssc mutant strains,
but equal amounts
of SseB and SseC were detected in nonsecreting
bacteria grown
at pH 7.0. This indicates that large amounts of SseB and
SseC
in bacteria grown at pH 5.0 are secreted and are presumably
attached
to the cell surface. Mutations in
sscA,
sseC, or
sseD had no effect
on the amount of SseB
in the detached fraction. In contrast, the
sseB mutant
strain had no detectable SseC on the cell surface.
This defect
was complemented by a plasmid-borne allele of
sseB.
The amount of secreted and surface-located SseD was highly
reduced
in the
sseB mutant background, but no
complementation by plasmid-borne
sseB was observed. A
mutation in
sseC resulted in a reduced amount
of SseD
recovered from the bacterial
surface.
We next analyzed if levels of secreted substrate proteins were affected
by mutations in
sse genes (Fig.
5B). After removal
of
bacterial cells, protein secreted into the culture supernatant
was
precipitated and analyzed. Small amounts of SseC and SseD
were present
in the culture supernatant of the wild-type strain.
In contrast, larger
amounts of SseC and SseD were present in the
culture supernatant of the
sseB mutant. SseC was not detected
in the supernatant of an
sseD mutant
strain.
Taken together, these experiments demonstrate that after secretion SseC
and SseD are located in the cell-associated fraction
if SseB is present
but they appear in the culture supernatant
if functional SseB is
absent.
Kinetics of secretion by the TTSS of SPI2.
For the kinetic
analysis of secretion of SPI2 substrate proteins, the S. enterica serovar Typhimurium wild type and the ssaV mutant strain were grown in minimal medium with
Mg2+ limitation at neutral pH. Bacteria were
harvested after reaching exponential growth phase and washed, and
incubation was continued in minimal medium at neutral or acidic pH
(Fig. 6A). Analysis of the detached
fraction revealed that SseB and SseC were recovered from the cell
surface by mechanical shearing at 2 h after the shift to acidic
pH. Neither protein was detected at 1 h after the shift or in the
detached fraction of cultures grown at neutral pH (Fig. 6B).
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FIG. 6.
Kinetics of SseB secretion. For the analysis of kinetics
of secretion by the TTSS of SPI2, the S. enterica
serovar Typhimurium wild type was grown in low-Mg2+ minimal
medium at pH 7.0. At exponential growth phase (OD600 of
about 0.3), bacteria were harvested, washed, and resuspended in fresh
medium at pH 7.0 or 5.0 (shift). The incubation was continued and
samples of the cultures were taken at various time points after the
shift as indicated (A). Total cell fractions and protein detached from
bacterial cells as described above were subjected to Western blot
analyses (B). SseC, anti-SseC antibody.
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Furthermore, we questioned whether surface-associated Sse proteins are
formed by secretion of a presynthesized pool of the
substrate proteins
or if protein synthesis is required during
secretion. Bacteria were
grown in low-Mg
2+ medium at pH 7.0. At an
OD
600 of about 0.5, bacteria were washed
and
shifted to low-Mg
2+ medium at pH 5.0, with or
without the addition of 50 µg of chloramphenicol/ml
to inhibit
protein biosynthesis. Secreted proteins in the detached
fraction were
analyzed as described before. In the presence of
chloramphenicol, SseB
and SseC were not detected in the detached
fraction (data not shown).
This result demonstrates that continuous
protein biosynthesis is
required for the secretion of substrate
proteins of
SPI2.
SseB, SseC, and SseD are required for the translocation of
SPI2 effector proteins.
In order to determine if the secreted
proteins SseB, SseC, and SseD are required for the translocation of
known SPI2 effector proteins, sseB, sseC, or
sseD mutations were transduced into S. enterica
serovar Typhimurium harboring either the SspH1-CyaA or SspH2-CyaA
fusion plasmid. These strains were then used to infect cultured murine
macrophages (RAW 264.7 cell line). In addition, the RAW 264.7 cells
were infected with the S. enterica serovar Typhimurium
wild type and the ssaT mutant strains expressing SspH1-CyaA or SspH2-CyaA as positive and negative controls, respectively. At
8 h after internalization of the bacteria, macrophages were lysed
and cellular cAMP levels were determined. Measured cAMP content was then normalized for protein concentration and is expressed as picomoles of cAMP per microgram of protein (Fig.
7). Under these assay conditions,
mutations in SPI2 genes did not affect the survival of S. enterica serovar Typhimurium in RAW 264.7 cells (data not shown).
Infection of macrophages with wild-type S. enterica serovar
Typhimurium resulted in an increase of cAMP levels, indicating that
SspH1-CyaA and SspH2-CyaA are translocated; however, no significant increase in cellular cAMP was detected in macrophages infected with the
ssaT mutant strain. Likewise, no translocation of either SspH1-CyaA or SspH2-CyaA was detected in macrophages infected with
sseB, sseC, or sseD mutant
strains.
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FIG. 7.
Translocation of SspH1 and SspH2 is dependent upon SseB,
SseC, and SseD. Cultured RAW 264.7 murine macrophages were infected
with either the wild type or SPI2 mutant (ssaT,
sseB, sseC, and sseD)
S. enterica serovar Typhimurium harboring CyaA fusions
to the SPI2 translocated effector proteins SspH1 and SspH2. The
results presented are the means of experiments performed in
triplicate, with the error bars representing 1 standard deviation
above and below the mean.
|
|
| |
DISCUSSION |
We performed experimental analyses of the TTSS of SPI2
under in vitro conditions that mimic the phagosomal environment of intracellular S. enterica serovar Typhimurium. Growth of
S. enterica serovar Typhimurium with limitation of
Mg2+ or starvation of phosphate induces the
expression of SPI2 genes (3), and secretion of SPI2
substrate proteins was triggered by media of pH 5.0 or below
(1). Under these conditions, three substrate proteins,
SseB, SseC, and SseD, are secreted by the TTSS of SPI2 (1, 15; this
study). This observation confirms the previous hypothesis about the
identity of SPI2 substrate proteins (11). SseC is a
member of the YopB family of TTSS substrate proteins, and SseB and SseD
are most similar to EspA and EspB of EPEC, respectively
(11).
To our knowledge, the SPI2-encoded TTSS is the first example of a TTSS
whose expression and secretion can be experimentally controlled by
defined growth conditions in synthetic media. Interestingly, both
Mg2+ limitation and phosphate starvation result
in the synthesis of the TTSS that is capable of secretion of substrate
proteins upon induction by acidic environmental conditions.
In a previous study, secretion of SseB was detected within minutes
after the shift of SPI2-induced bacteria to acidic pH (1). We observed that incubation of Salmonella at acidic pH for
at least 1 h is required before Sse proteins can be detected in
the fraction obtained by mechanical shearing or before oligomers of SseB can be detected by cross-linking of surface proteins (J. Deiwick and M. Hensel, unpublished observations). Although
secretion of SseB occurs rapidly, the formation of oligomers may
require accumulation of SseB over longer periods of secretion by the
TTSS of SPI2. Continuous protein biosynthesis is required for this process.
Compared to substrate proteins of S. enterica serovar
Typhimurium SPI1 or the Yops of Yersinia spp., only small
amounts of the SPI2 proteins SseB, SseC, and SseD are released into the
growth medium. SPI2 substrate proteins appear to be predominantly
located on the bacterial cell surface. The sensitivity of these surface structures to disruption by mechanical shearing is reminiscent of
bacterial flagella and fimbriae, which have been isolated by similar
approaches (16, 30). Functional requirements for the secretion of various substrate proteins of SPI2 suggest that these proteins do not associate randomly with the bacterial cell envelope after secretion. In the absence of SseB, substrate proteins SseC and
SseD are still secreted but appear in the supernatant rather than in
the cell-associated fraction. In contrast, SseC and SseD are not
required for the secretion and surface location of SseB. SseC is not
required for secretion of SseD and vice versa. Our data demonstrate
that SseB has an important role in the assembly of SseC and SseD into a
macromolecular structure. Furthermore, polar structures containing
secreted SseB were visible by immunofluorescence microscopy.
Surface association has been observed before for substrate proteins of
the TTSS of other pathogens, for example, the Ipa proteins of
Shigella flexneri (see reference 21 for a
review). After secretion, protein-protein interaction was observed for
Ipa proteins. In S. flexneri, mutations in IpaB or IpaD
result in increased secretion of the remaining Ipa proteins into the
culture medium (22). This observation is reminiscent of
the effect of the mutation in sseB in S. enterica
serovar Typhimurium that resulted in increased amounts of SseC and SseD
in the culture supernatant. The organized association of substrate
proteins during secretion appears to be essential for the function of
the TTSS. Such protein interactions also result in the assembly of
macromolecular surface structures, e.g., by the TTSS of
Pseudomonas syringae (27) and EPEC (5, 17). SseB, SseC, and SseD are most similar to EspA, EspD, and EspB of EPEC, respectively (11). Secretion of EspA, EspB,
and EspD has been demonstrated, and all Esp proteins are required for
the attachment and effacement lesions of EPEC-infected epithelial cells
(for a review, see reference 6). EspA is the major
component of a filamentous surface structure of EPEC. Hartland et al.
(9) recently reported that EspB is associated with the
EspA filament and that EspA filament formation can occur in the absence
of EspB. Our data indicate that surface-associated complexes of SseB
were assembled in the absence of SseC or SseD. These findings indicate functional similarities between substrate proteins of EPEC and SPI2 of
S. enterica serovar Typhimurium. However, it is not known whether SseB is sufficient to assemble a surface-associated filamentous structure in S. enterica serovar Typhimurium.
Recently, a family of putative translocated proteins of the SPI2 TTSS
has been identified (23). These proteins are encoded by
genes outside the SPI2 locus and have a conserved N-terminal domain
required for translocation. However, this translocation domain is
absent in SseB, SseC, SseD, and other proteins encoded by the SPI2
locus, supporting the notion that the function of SseB, SseC, and SseD
is distinct from those of the putative effector proteins. There is no
evidence that SseB, SseC, or SseD is translocated into the host cell cytoplasm.
Previous studies revealed that mutations in sseB,
sseC, or sseD each result in dramatic attenuation
of virulence of S. enterica serovar Typhimurium and in
reduced intracellular accumulation (2, 20; unpublished
observations). We observed that SseB, SseC, and SseD do not require
each other for secretion but that these proteins appear to interact
after secretion. Cross-linking experiments support the presence of an
oligomeric assembly of SseB subunits after secretion (Deiwick and
Hensel, unpublished results). Based on these observations, we propose
that after secretion SseB, SseC, and SseD are assembled into a
hetero-oligomeric complex (Fig. 8). This
complex is formed in vitro after growth of S. enterica serovar Typhimurium in minimal medium at acidic pH. In vivo, SseB, SseC, and SseD are each required for the translocation of effector proteins from intracellular S. enterica serovar Typhimurium
into the infected host cell. Translocation of effector proteins is as
reduced in sseB, sseC, and sseD
mutants as it is in mutants in structural components of the TTSS such
as SsaT. Therefore, the secreted proteins SseB, SseC, and SseD act as a
translocator for effector proteins in vivo. We hypothesize that in vivo
SseB, SseC, SseD, and putative additional substrate proteins form a structure that acts as a translocator to mediate translocation of
effector proteins of the TTSS of SPI2 from intraphagosomal S. enterica serovar Typhimurium into the host cell (Fig. 8).
Additional analysis by cross-linking experiments may reveal
further details of the putative translocator structure.
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|
FIG. 8.
Model for the secretion and function of SseBCD.
Expression of the TTSS of SPI2 and SseBCD is induced by growth of
S. enterica serovar Typhimurium in minimal media with
limiting amounts of phosphate or Mg2+. Growth media with an
acidic pH induce secretion of SseBCD by the TTSS of SPI2. Under
in vitro conditions, surface structures composed of SseBCD and putative
additional proteins are assembled. These surface structures can
be detached from the bacterial cell surface by mechanical shearing
(this study) or treatment with organic solvents (1). In
vivo, SseBCD functions as a translocon for the translocation of
STE (Salmonella translocated effector) proteins from
intraphagosomal Salmonella over the phagosomal membrane
into the host cell.
|
|
In conclusion, we have identified that in addition to SseB, substrate
proteins SseC and SseD are secreted by the TTSS of SPI2. After
secretion, these proteins assemble into a complex exposed on the
bacterial cell surface. SseB, -C, and -D are required for translocation
of effector proteins into host cells. Further work will reveal whether
this structure represents a translocator for SPI2 effector proteins and
how such a putative translocator can mediate the transfer of effector
proteins by intracellular Salmonella.
| |
ACKNOWLEDGMENTS |
This work was supported by grants from the Deutsche
Forschungsgemeinschaft (HE1964/2-3) and the BMBF (01 KI 9606) to M.H. and by grant RO1 AI48683 from the National Institutes of Health to
S.I.M. C.R. was supported by a predoctoral fellowship of the Ludwig-Maximilians-Universität.
We are indebted to J. Heesemann for generous support of this work
and for stimulating discussions.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institut
für Klinische Mikrobiologie, Immunologie und Hygiene,
Friedrich-Alexander-Universität Erlangen-Nürnberg,
Wasserturmstr. 3/5, D-91054 Erlangen, Germany. Phone: 49 (0) 9131 85 23640. Fax: 49 (0) 9131 85 22531. E-mail: hensel{at}mikrobio.med.uni-erlangen.de.
| |
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Journal of Bacteriology, October 2001, p. 6036-6045, Vol. 183, No. 20
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.20.6036-6045.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Hansen-Wester, I., Stecher, B., Hensel, M.
(2002). Type III Secretion of Salmonella enterica Serovar Typhimurium Translocated Effectors and SseFG. Infect. Immun.
70: 1403-1409
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Abstract
Introduction
