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Previous Article | Next Article 
Infection and Immunity, July 2001, p. 4618-4626, Vol. 69, No. 7
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.7.4618-4626.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
In Vivo Visualization of Bacterial Colonization, Antigen
Expression, and Specific T-Cell Induction following Oral
Administration of Live Recombinant Salmonella
enterica Serovar Typhimurium
Dirk
Bumann*
Abteilung Molekulare Biologie,
Max-Planck-Institut für Infektionsbiologie, D-10117 Berlin,
Germany
Received 11 December 2000/Returned for modification 5 February
2001/Accepted 5 April 2001
 |
ABSTRACT |
Live attenuated Salmonella strains that express a
foreign antigen are promising oral vaccine candidates. Numerous genetic modifications have been empirically tested, but their effects on
immunogenicity are difficult to interpret since important in vivo
properties of recombinant Salmonella strains such as
antigen expression and localization are incompletely characterized and the crucial early inductive events of an immune response to the foreign
antigen are not fully understood. Here, methods were developed to
directly localize and quantitate the in situ expression of an ovalbumin
model antigen in recombinant Salmonella enterica serovar
Typhimurium using two-color flow cytometry and confocal microscopy. In
parallel, the in vivo activation, blast formation, and division of
ovalbumin-specific CD4+ T cells were followed using a
well-characterized transgenic T-cell receptor mouse model. This
combined approach revealed a biphasic induction of ovalbumin-specific T
cells in the Peyer's patches that followed the local ovalbumin
expression of orally administered recombinant Salmonella
cells in a dose- and time-dependent manner. Interestingly, intact
Salmonella cells and cognate T cells seemed to remain in
separate tissue compartments throughout induction, suggesting a
transport of killed Salmonella cells from the colonized subepithelial dome area to the interfollicular inductive sites. The
findings of this study will help to rationally optimize recombinant Salmonella strains as efficacious live antigen carriers for
oral vaccination.
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INTRODUCTION |
Vaccination is an effective approach
to control infectious diseases, but for many pathogens efficacious
vaccines have not yet been developed. Live attenuated
Salmonella strains that express a foreign antigen can be
administered via the easy, safe, and well-accepted oral route and can
induce strong mucosal and systemic immune responses to the foreign
antigen that confer protective immunity against numerous pathogens in
several animal models (3, 24, 41). Despite encouraging
preclinical results, the few clinical trials with live recombinant
Salmonella strains showed weak to undetectable human immune
responses to the foreign antigens, indicating the need for further optimization.
In general, antigen localization, dose, and timing are key parameters
for the optimization of an immune response (47). Indeed, numerous genetic modifications of recombinant Salmonella,
including attenuating mutations and antigen expression systems that are likely to influence in vivo localization and antigen expression have
been shown to result in altered immune responses (10-12, 30, 31,
44, 45). However, the results are difficult to interpret since
the in vivo localization and antigen expression levels of the various
Salmonella strains are still largely unknown. Moreover, the
crucial early events of the induction of an immune response have not
been characterized in detail because of technical problems due to the
low precursor frequency of antigen-specific immune cells. As a result
of this incomplete understanding, the optimization of live recombinant
Salmonella strains has remained largely empirical.
Here, novel methods were used to localize and quantitate the in vivo
antigen expression of an orally administered live recombinant Salmonella strain. In parallel, the early inductive events
of an antigen-specific CD4+ T-cell response were followed
using a well-characterized transgenic T-cell receptor (tgTCR) mouse
model (37). The results of this combined approach show how
vaccine properties in vivo relate to the induction of a cellular immune
response and suggest several options for the rational optimization of
these promising oral vaccines.
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MATERIALS AND METHODS |
Construction of recombinant Salmonella strains.
An ovalbumin peptide (amino acids 319 to 343) that is recognized by
DO11.10 T cells (33) was fused to the C terminus of a
bright variant of green fluorescent protein (GFP) (7) and expressed from the Ptac promoter in the
medium-copy-number plasmid pKK223-3 (Pharmacia), yielding
pGFP_OVA (Bumann, unpublished data). As a control, a similar plasmid
encoding GFP without fused ovalbumin was also constructed (pGFP).
Salmonella enterica serovar Typhimurium aroA
strain SL3261 (15) was electrotransformed with either pGFP or pGFP_OVA.
SDS-PAGE, immunoblotting, and quantification of expression in
vitro.
Samples of late-log-phase cultures of SL3261(pGFP) and
SL3261(pGFP_OVA) were applied to standard sodium dodecyl sulfate-12% polyacrylamide gel electrophoresis (SDS-12% PAGE) gels,
electroblotted onto nitrocellulose, and stained with polyclonal rabbit
antibodies to GFP or ovalbumin followed by a peroxidase-coupled
antibody to rabbit immunoglobulin G (IgG) and chemoluminescence
detection. All antibodies were preadsorbed with SL3261 lysate to reduce
nonspecific binding.
To estimate the expression levels of GFP and GFP_OVA, SL3261,
SL3261(pGFP), and SL3261(pGFP_OVA) were grown to the
mid-logarithmic growth phase and lysed by sonification. The lysate was
centrifuged and filtered through a 0.2-µm-pore-size filter to remove
residual intact bacteria and absorbance spectra were measured in the
range of 400 to 600 nm. The spectra were normalized for lysate protein content as determined with the bicinchoninic acid assay (Pierce) and
the spectrum of SL3261 was subtracted from the other spectra for
background correction. The peak absorption at 485 nm was used to
calculate the amount of GFP or GFP_OVA based on an extinction coefficient of 55,000 cm
1 M1 (Living
ColorsTM red fluorescent protein, October 1999, p. 1; Clontech, Palo
Alto, Calif.).
Mice, adoptive transfer, and immunization.
BALB/c mice and
DO11.10 mice (33) were bred in the Bundesamt für
Gesundheitlichen Verbraucherschutz und Veterinärmedizin, Berlin,
Germany, and were kept under specific-pathogen-free conditions in full
accordance with German guidelines for animal care. All experiments were
approved by the local Animal Welfare Committee.
Ammonium chloride-treated splenocytes from 8- to 12-week-old female
DO11.10 × BALB/c crosses were transferred by tail vein injection into
sex- and age-matched BALB/c recipient mice (4 × 106
tgTCR CD4+ T cells per recipient mouse), and mice were
immunized 1 day later. For oral immunization, an overnight culture of
SL3261(pGFP) or SL3261(pGFP_OVA) cells was diluted 1:8 in fresh
Luria-Bertani (LB) medium and grown to the late logarithmic growth
phase at 37°C and 200 rpm. The bacteria were harvested by
centrifugation at 4,000 × g for 5 min, washed in LB
medium containing 3% NaHCO3, and resuspended in the same
medium to 1.2 × 1010 to 4 × 1011
CFU ml1, and 100 µl of this suspension was
intragastrically administered to mice with a round-tip stainless steel needle.
For immunization with inactivated bacteria, SL3261(pGFP_OVA) cells were
grown to the late logarithmic phase and heated for 5 min to 80°C or
for 2 h to 60°C. Alternatively, live bacteria were treated with
2% formalin in phosphate-buffered saline for 1 h. After
inactivation, the bacterial suspensions were washed, resuspended, and
administered as described for live Salmonella cells.
Recovery of bacteria from colonized mice.
At various time
intervals postimmunization, mice were anesthetized and killed. The
spleens, mesenteric lymph nodes, and Peyer's patches were prepared.
Single-cell suspensions of the various organs were treated with 0.1%
Triton X-100 and plated on LB plates containing 90 µg of streptomycin
ml1 or 90 µg of streptomycin ml1 plus 100 µg of ampicillin ml1.
Immunofluorescence and immunohistochemistry.
To localize
Salmonella cells that expressed GFP_OVA with confocal
microscopy, cryosections (20 µm) of Peyer's patches were fixed with
2% formalin in phosphate-buffered saline and stained with a polyclonal
rabbit antibody to Salmonella lipopolysaccharide (LPS)
serogroup B (Sifin) and an Alexa546-conjugated polyclonal antibody to
rabbit IgG (Molecular Probes). Stack projections (15 µm) of optical
sections (0.2 to 0.4 µm) are shown.
To colocalize Salmonella cells and ovalbumin-specific
T-helper cells, cryosections were fixed with ethanol, stained with
biotinylated monoclonal antibodies KJ1-26 (14) and ABC
(Vector) using the substrate 3-amino-9-ethylcarbazole (AEC), blocked
with 0.4% peroxide, and stained with a rabbit polyclonal antibody to
Salmonella LPS serogroup B and a peroxidase-coupled
polyclonal antibody to rabbit IgG using the substrate
3,3'-diaminobenzidine (DAB) in the presence of nickel.
Flow cytometry.
To measure bacterial antigen
expression, SL3261(pGFP_OVA) cultures or Triton
X-100-treated tissue samples were analyzed for green and orange
fluorescence (channels FL-1 [515 to 545 nm] and FL-2 [563 to 607 nm], respectively) without compensation for spectral overlap as
described previously (Bumann, unpublished data) using a FACScan flow
cytometer (Becton Dickinson). Salmonella cells expressing
GFP were identified based on their typical emission ratios (FL-2/FL-1),
which were about 1 order of magnitude smaller than those of
autofluorescent tissue fragments.
To measure ovalbumin-specific T-helper-cell activation, single-cell
suspensions of Peyer's patches, mesenteric lymph nodes, and spleens
were stained with biotinylated anti-tgTCR clonotype antibody KJ1-26
(14), anti-CD4-fluorescein, anti-CD69-phycoerythrin, and
anti-B220-allophycocyanin, followed by streptavidin-FarRed (Gibco),
and analyzed with a Calibur flow cytometer (Becton Dickinson). CD4+ tgTCR+ B220 lymphocytes were
analyzed for their forward scatter and CD69 expression. Alternatively,
cells were stained with biotinylated KJ1-26, anti-CD45RB-fluorescein,
anti-CD4-phycoerythrin, and anti-B220-allophycocyanin, followed
by streptavidin-FarRed (Gibco), and CD4+ tgTCR+
B220 lymphocytes were analyzed for CD45RB expression. To
analyze the in vivo division of the transgenic T cells in the chimeric
mice, the cells were labeled prior to their adoptive transfer with 0.5 µM carboxyfluorescein diacetate succinimidyl ester (CFSE) (Molecular Probes) for 10 min at 37°C as previously described (36).
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RESULTS |
Construction and characterization of SL3261(pGFP_OVA).
To
follow the interaction of Salmonella cells and the adaptive
immune response of the host, GFP was fused to a minimal part of
ovalbumin (amino acids 319 to 343) consisting of a dominant I-Ad-restricted T-cell epitope and the four adjacent N- and
C-terminal amino acid residues that might influence antigen processing
for class II presentation (34). The fusion protein
GFP_OVA was expressed from the Ptac promoter
(pGFP_OVA). As a control, an analogous construct was made for the
expression of GFP alone without the fused ovalbumin epitope (pGFP).
The well-characterized attenuated strain S. enterica serovar
Typhimurium SL3261 carrying aroA (15) was used
as a prototype Salmonella carrier. The transformants
SL3261(pGFP) and SL3261(pGFP_OVA) expressed an additional protein band
with the expected molecular mass (28 or 31 kDa, respectively; Fig.
1A). Both proteins were recognized by an
antibody to GFP (Fig. 1B), and the fusion protein GFP_OVA was
recognized by a polyclonal antibody to ovalbumin (Fig. 1C). Almost
all the detectable GFP and ovalbumin was part of the intact
GFP_OVA fusion protein, suggesting that the GFP fluorescence in
SL3261(GFP_OVA) can be used as an estimate for the expression level of
the model T-cell epitope.
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FIG. 1.
In vitro characterization of Salmonella
strains expressing GFP (lanes 1) or GFP_OVA (lanes 2). (A) SDS-PAGE.
(B) Immunoblot with an antibody to GFP. (C) Immunoblot with an antibody
to ovalbumin. (D) Absorbance spectra of Salmonella lysates.
(E) Flow cytometry of SL3261(pGFP_OVA) cultures at the logarithmic
(log) and stationary (stat) growth phases. The inset shows an SDS-PAGE
gel of both cultures, with the arrow marking GFP_OVA. Similar data were
obtained for three independent experiments.
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Absorption spectra of lysates from logarithmic-phase SL3261(pGFP_OVA)
and SL3261(pGFP) cultures were identical, indicating that the fusion of
the ovalbumin epitope to GFP did not alter its spectroscopic properties
(Fig. 1D). SL3261(pGFP) and SL3261(pGFP_OVA) expressed almost identical
GFP and GFP_OVA levels of 30 ± 10 ng of protein per 106
bacteria, equivalent to 600,000 copies of the ovalbumin epitope per
cell for SL3261(pGFP_OVA). Flow cytometry of logarithmic-phase cultures
showed that GFP expression was high and homogeneous in all bacteria,
but it was downregulated and heterogeneous in stationary-phase cultures
(Fig. 1E), although the bacteria remained viable and retained the
functional expression plasmid, as determined by plating with or
without ampicillin selection and flow cytometry of fresh subcultures. The growth phase-dependent expression of
GFP_OVA was confirmed by SDS-PAGE (Fig. 1E, inset). Low GFP_OVA
levels during the stationary phase could reflect a decreased promoter activity and/or an enhanced degradation of transcripts and proteins. Otherwise identical plasmids in which alternative promoters other than
Ptac drive gfp_ova transcription show
the opposite expression pattern, with increased GFP_OVA levels during
stationary phase (Bumann, unpublished data), suggesting that promoter
activities play a major role in differential regulation in
SL3261(pGFP_OVA), although mRNA and protein turnover might also
contribute to regulation. The downregulation of
Ptac during stationary phase might be related to
inefficient binding of the alternative 
-factor RpoS to the Ptac promoter and/or to the relaxation of
negative supercoiling of the expression plasmid (1), which
is known to diminish the Ptac promoter strength
(42).
Colonization in mice and localization within Peyer's
patches.
Mice were intragastrically inoculated with 4 × 1010 SL3261(pGFP_OVA) cells, and colonization was
determined by plating. The few hundred clones that were present in the
Peyer's patches at 6 h expanded exponentially until day 7, with a
peak number of recovered CFU around 6 × 104 (Fig.
2A) followed by a decline over the next 2 weeks, which is in close agreement with previous studies using similar
doses of recombinant SL3261 (11). The mesenteric lymph
nodes were colonized with similar kinetics but with 10-fold-lower peak
numbers (Fig. 2A), whereas the spleen was colonized by only a few
hundred Salmonella cells for some mice (data not shown).
Plating on medium with or without ampicillin revealed that at 7 and 18 days postimmunization more than 80% of the ex vivo clones still
retained the expression plasmid (Fig. 2A). All of the
plasmid-containing clones expressed large amounts of GFP in vitro, as
indicated by their yellow color and flow cytometric data.
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FIG. 2.
Colonization and in situ antigen expression of orally
administered live SL3261(pGFP_OVA) cells. Averages and SEMs of CFU
values for three mice per data point are shown. (A) Colonization of
Peyer's patches ( ,  ) and mesenteric lymph nodes ( ,  ). The
open symbols represent all recovered Salmonella cells,
whereas the closed symbols represent Salmonella cells that
retained the plasmid as determined by plating on selective medium.
Similar results were obtained for three independent experiments. p.i.,
postimmunization. (B) Total in situ expression of GFP_OVA in the
Peyer's patches () and mesenteric lymph nodes () as determined
by two-color flow cytometry (see text for description). (C)
Subepithelial dome of a Peyer's patch 7 days postimmunization. Bar, 50 µm. The dotted line represents the apical border of the
follicle-associated epithelium. L, intestinal lumen. (D) Enlarged
micrograph of a single infected cell in the subepithelial dome 7 days
postinfection. Bar, 5 µm. Similar images were obtained for 10 mice at
various time points postimmunization from two independent
experiments.
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To visualize the localization of the recombinant Salmonella
cells in colonized Peyer's patches, cryosections were stained with an
antibody to Salmonella LPS and viewed by confocal
microscopy. While control sections from naive mice did not stain for
Salmonella LPS, Peyer's patches from colonized mice
contained many LPS-positive particles with a size of about 1 µm,
representing individual bacteria (Fig. 2C and D). Serial sections of
mice sacrificed at various time points postimmunization showed that
throughout the colonization period, most Salmonella cells
localized to the subepithelial dome area, with few bacteria in the
follicles and almost none in the interfollicular T-cell area. At time
points later than 5 h, no Salmonella cells were
detected in the intestinal lumen or in the crypts. A similar
localization of recombinant Salmonella to the subepithelial
dome area has been previously observed for a Salmonella PhoPc strain at a very early time point (4 h
postimmunization) (16, 17).
In situ antigen expression as measured by two-color flow
cytometry.
A strong background of abundant small autofluorescent
particles makes it difficult to detect bacterial GFP expression in the host by one-color flow cytometry (16, 23), but two-color
flow cytometry efficiently separates autofluorescence from GFP emission (Bumann, unpublished data). In this approach, the green GFP
fluorescence is discriminated from the yellowish autofluorescence based
on the differential spectral components that can be measured in
channels FL-1 (515 to 545 nm) and FL-2 (563 to 607 nm) of the FACScan
flow cytometer. Autofluorescence has a stronger orange emission
component (FL-2) compared to GFP, which results in a larger FL-2/FL-1
emission ratio. A quantitative analysis of GFP expression by
SL3261(pGFP_OVA) in colonized mice suggested that almost all
Salmonella cells expressed GFP in situ but did so at levels
that decreased about 10-fold over the first 2 days and then remained at
25,000 to 80,000 copies per bacterium (Bumann, unpublished data). This
low expression level was similar to that of fully stationary in vitro
cultures (Fig. 1E) and was not a consequence of plasmid loss or
mutation, as more than 80% of the Salmonella cells retained
the plasmid and the ability to produce large amounts of GFP_OVA in
vitro throughout colonization. Instead, differential promoter
activities and/or enhanced degradation of transcripts and proteins
might be involved. Otherwise identical constructs in which alternative
promoters other than Ptac drive
gfp_ova transcription show increased in vivo GFP_OVA levels
compared to the respective in vitro cultures (Bumann, unpublished
data), suggesting that transcriptional regulation plays a major role in
vivo, as it does in stationary in vitro cultures (see above). The gene
regulation of Salmonella grown in vivo has previously been
observed to resemble in vitro stationary cultures (27,
35). In addition to transcriptional regulation, stress proteases
such as HtrA that are known to be induced in vivo (19, 38)
might further decrease the in vivo GFP_OVA levels (see Discussion).
To determine the total in situ amount of ovalbumin peptide, the
integrated GFP levels from flow cytometric profiles were multiplied by
the number of CFU (Fig. 2B). After a small initial antigen peak caused
by the still-elevated GFP_OVA expression level at day 1, there was a
strong increase in the antigen amount until day 6, with a peak level of
some 150 pg for all Peyer's patches of an individual mouse followed by
a steady decline over the next 10 days. Much lower total amounts were
expressed in the mesenteric lymph nodes.
Confocal microscopy of Peyer's patches showed that all detectable
GFP_OVA fluorescence was confined to particles with a size of about 1 µm that were also positive for S. enterica serovar Typhimurium LPS (Fig. 2C and D). In agreement with flow cytometry, GFP_OVA expression varied widely between individual bacteria. Bacteria
with both high and low expression levels occurred together in single
host cells and were scattered throughout the colonized tissue with no
obvious differential distribution. No green fluorescence above
background was detected in mice colonized by SL3261 not expressing GFP.
Induction of ovalbumin-specific T cells.
To determine the site
and kinetics of induction for T cells that specifically recognize an
antigen expressed by Salmonella, a well-characterized tgTCR
adoptive transfer system was used (37). CD4+ T
cells from DO11.10 mice that are transgenic for a major
histocompatibility complex class II-restricted TCR recognizing an
ovalbumin epitope (33) were transferred to syngeneic,
nontransgenic BALB/c mice. In the chimeric mice, the ovalbumin-specific
transgenic T cells were traced using a clonotypic monoclonal antibody
(14) (Fig. 3A). One day
after transfer, 0.5% ± 0.1% (mean ± standard error of the
mean [SEM]) of the total splenic lymphocytes (B and T cells), 0.8% ± 0.2% of the mesenteric lymph node lymphocytes, and
0.2% ± 0.05% of the Peyer's patch lymphocytes in the chimeric
mice were CD4+ T cells expressing the ovalbumin-specific
tgTCR, whereas BALB/c control mice contained no positive cells, which
was in good agreement with previous data (5, 21). The
rather small transgenic population in the Peyer's patches partially
reflects the small proportion of naive T cells in this compartment
(32). The transgenic T-cell population declined slowly in
all lymphoid organs of nonimmunized chimeric mice, with a half-life of
about 2 weeks, indicating that there was a typical slow loss but no
rejection.
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FIG. 3.
Detection of transgenic ovalbumin-specific T cells in
chimeric mice after immunization with a recombinant
Salmonella strain. (A) Flow cytometry of adoptively
transferred ovalbumin-specific tgTCR CD4+ T cells in
Peyer's patches of a recipient 1 day after transfer. (B) Total number
of ovalbumin-specific T cells in Peyer's patches after various time
intervals postimmunization (p.i.) with SL3261(pGFP_OVA). Averages and
SEMs of values for three to seven mice per data point from two
independent experiments are shown.
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After oral administration of SL3261(pGFP_OVA) cells to chimeric mice,
there was a weak biphasic accumulation of ovalbumin-specific transgenic
CD4+ T cells in the Peyer's patches around day 3 and from
day 7 to day 12, with a transient decay around day 5. This weak pattern was observed consistently in three independent experiments and was
absent in control mice colonized by SL3261(pGFP) cells, but individual
variation prevented statistically significant results. To calculate the
total numbers of ovalbumin-specific T cells, the concentrations were
multiplied by the total number of lymphocytes in the Peyer's patches
for each time point (Fig. 3B). There was a large increase of specific T
cells with a peak at day 8 followed by a decline to the initial values,
but the whole pattern largely followed the general accumulation of
lymphocytes in the Peyer's patches during Salmonella
colonization. A similar accumulation was observed in the mesenteric
lymph nodes and the spleen.
Despite their weak selective accumulation, many ovalbumin-specific T
cells became activated after administration of SL3261(pGFP_OVA) cells.
Within 2 days, many ovalbumin-specific T cells in the Peyer's patches
upregulated the very early activation marker CD69 and became larger, as
indicated by their increased forward scattering (Fig.
4A and 5A and
B). A small fraction of
ovalbumin-specific T cells in the mesenteric lymph nodes also became
activated (Fig. 4A), whereas no activation was observed in the spleen.
A second wave of strong ovalbumin-specific T-cell activation occurred
in the Peyer's patches from day 7 to day 10 (Fig. 4A and 5A). Because of the large general accumulation (Fig. 3B), a greater total number of
ovalbumin-specific T cells became activated during this second activation wave than during the first wave around day 2 (Fig. 5B). The
second wave coincided with the maximal Salmonella
colonization and antigen expression around day 7 and ceased together
with the decay of in situ antigen levels (Fig. 2B). The T-cell
activation was antigen specific since in mice colonized by
SL3261(pGFP), ovalbumin-specific T cells were not activated in both
Peyer's patches (Fig. 4B and 5A) and mesenteric lymph nodes (data not shown).
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FIG. 4.
Activation of ovalbumin-specific T cells after
immunization with a recombinant Salmonella strain. (A) CD69
expression and forward scatter of ovalbumin-specific T cells in
Peyer's patches (PP) and mesenteric lymph nodes (mLN) after oral
immunization with SL3261(pGFP_OVA). Similar results were obtained
for three independent experiments. d, days. (B) CD69 expression and
forward scatter (fsc) of ovalbumin-specific T cells in Peyer's patches
2 and 7 days (d) after oral immunization with SL3261(pGFP). (C)
Fluorescence of CFSE-labeled ovalbumin-specific T cells prior to or 12 days (d) after oral immunization (p.i.) with SL3261(pGFP_OVA).
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FIG. 5.
Blast formation and in vivo division of
ovalbumin-specific T cells after oral immunization with a recombinant
Salmonella strain. p.i., postimmunization. (A) Fraction of
large cells (gated as in Fig. 4A) among ovalbumin-specific T cells in
the Peyer's patches after oral immunization with SL3261(pGFP_OVA)
() or SL3261(pGFP) (). Averages and SEMs of values for three to
seven mice per data point are shown. The statistical significance of
differences between SL3261(pGFP) and SL3261(pGFP_OVA) was analyzed with
the t test (**, P < 0.001). Similar
results were obtained for three independent experiments. (B) Total
number of large ovalbumin-specific T cells in the Peyer's patches
after oral immunization with SL3261(pGFP_OVA). (C) Fraction of
CFSE10 cells (gated as in Fig. 4C) among ovalbumin-specific
T cells in the Peyer's patches (, ) and mesenteric lymph nodes
( ) after immunization with SL3261(pGFP_OVA) (, ) or
SL3261(pGFP) (). Averages and SEMs of values for three mice per data
point are shown. The statistical significance of differences between
SL3261(pGFP) and SL3261(pGFP_OVA) was analyzed with the t
test (*, P < 0.05). Similar results were obtained
for two independent experiments. (D) Dose-response relationship between
in situ expression of GFP_OVA and the fraction of large cells (gated as
in Fig. 4A) among ovalbumin-specific T cells in the Peyer's patches 7 days after oral immunization with 1.2 × 109 (+),
6 × 109 (), or 4 × 1010 (×)
SL3261(pGFP_OVA) cells. The dotted line represents background staining
after immunization with 4 × 1010 SL3261(pGFP) cells.
The statistical significance of differences between SL3261(pGFP) and
SL3261(pGFP_OVA) was analyzed with the t test (1.2 × 109 CFU, P < 0.05; 6 × 109 CFU, P < 0.01; 4 × 1010 CFU, P < 0.001).
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The occurrence of a second T-cell response about 7 to 10 days after the
initial response resembled a prime-boost immunization with initially
primed T cells becoming restimulated. However, among the
ovalbumin-specific large T cells that were formed at day 7 in the
Peyer's patches, 86 to 94% expressed high levels of CD45RB,
indicating that the cells activated during the second response were
mostly naive and distinct from the ones that had been initially activated.
The size increase of many ovalbumin-specific T cells during
SL3261(pGFP_OVA) colonization suggested blast formation. This was
confirmed by CFSE labeling of the transgenic T cells prior to their
adoptive transfer. After oral administration of SL3261(pGFP_OVA) but
not SL3261(pGFP) cells to chimeric mice, many ovalbumin-specific T
cells in the Peyer's patches (Fig. 4C and 5C) and in the mesenteric lymph nodes (Fig. 5C) lost part of their CFSE fluorescence, indicating blast formation and in vivo division.
There was a clear dose-response relationship between the amount of
antigen expressed in situ and the amplitude of the ovalbumin-specific T-cell response at day 7 (R = 0.88, P < 0.001;
Fig. 5D). A minimum of about 5 pg of GFP_OVA fusion protein expressed
in live Salmonella cells was sufficient to observe a
significant specific T-cell activation (P < 0.05).
This corresponded to an initial inoculum of 1.2 × 109
CFU, which is a rather low dose compared to what is commonly used for
murine immunization studies (1 × 109 to 5 × 1010 CFU). To obtain strong responses, 4 × 1010 CFU was administered for all other experiments.
Ovalbumin-specific T-cell activation was dependent on a viable
recombinant Salmonella strain, since SL3261(pGFP_OVA)
cells that had been inactivated by mild heat or formalin treatments yet
contained unchanged amounts of fusion protein as determined by SDS-PAGE
failed to induce a detectable response at days 2 and 7 (data not shown).
Colocalization of SL3261(pGFP_OVA) and ovalbumin-specific T
cells.
To investigate the spatial relationship between
SL3261(pGFP_OVA) and antigen-specific T cells during their induction,
cryosections of Peyer's patches were stained using antibodies to the
tgTCR and to Salmonella LPS (Fig.
6). While Salmonella cells
mostly localized to the subepithelial dome areas of the Peyer's
patches throughout the colonization period, confirming the confocal
data (Fig. 2C), almost all ovalbumin-specific T cells remained confined to the interfollicular T-cell areas, which were some hundreds of
micrometers away from the Salmonella-colonized areas. This spatial separation of Salmonella and T cells was observed
throughout the entire colonization and T-cell induction process,
although only around day 7 were Salmonella and
ovalbumin-specific T cells frequent enough to colocalize them on single
sections. Naive chimeric mice were negative for Salmonella
LPS, and BALB/c mice were negative for the tgTCR.
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FIG. 6.
Colocalization of Salmonella cells (black)
and ovalbumin-specific T cells (red) in the Peyer's patches 8 days
after oral immunization with SL3261(pGFP_OVA). (A) Overview at low
magnification. u, lumen; d, subepithelial dome; f, follicle; i,
interfollicular region. Bar, 200 µm. (B) Dome area at higher
magnification. Bar, 50 µm. (C) Interfollicular area at higher
magnification. Bar, 50 µm.
|
|
| |
DISCUSSION |
Live attenuated Salmonella strains are promising oral
vaccine carriers for heterologously expressed foreign antigens. Several parameters of such recombinant constructs are known to influence the
vaccine efficacy, but optimization is still largely empirical because
key properties such as antigen amount, timing, and localization as well
as early events of the immune response have been incompletely characterized in vivo.
The amount of antigen that is being produced by recombinant
Salmonella strains can be very different in vitro and in
vivo due to complex regulatory networks (9). To measure
the levels of antigen expression in situ, a model T-cell epitope was
expressed as a GFP fusion protein and quantified using two-color flow
cytometry. GFP fluorescence was also used to localize
Salmonella cells that express the fusion protein in situ by
confocal microscopy. Almost the entire protein chain of GFP is required
for fluorescence (25); hence, most proteolytic fragments
of GFP_OVA would escape flow cytometric detection, resulting in an
underestimation of the amount of immunogenic ovalbumin peptide that is
actually present. On the other hand, this underestimation might be
moderate, since major bacterial proteases generate mostly small
peptides (46) which are unlikely to preserve the ovalbumin
13-mer peptide that is required for an efficient binding of the DO11.10
T-cell receptor (39).
To relate live vaccine properties to the early inductive events of a
specific T-cell response, a well-characterized tgTCR mouse model was
used in which a few transgenic T cells recognizing ovalbumin are
adoptively transferred into syngeneic, nontransgenic mice
(37). After oral administration of attenuated
Salmonella cells expressing GFP_OVA, there was a strong
accumulation of lymphocytes but only a weak selective accumulation of
ovalbumin-specific T cells in the Peyer's patches. An explanation for
this result could be that many other T cells recognizing various
Salmonella antigens, including the dominant antigen
flagellin C (29), competed for a limited number of
antigen-presenting cells. In contrast to our results, a strong
selective accumulation of ovalbumin-specific T cells has been observed
in the identical transgenic mouse model following subcutaneous
injection of an ovalbumin-expressing Salmonella strain
(6). In these experiments 108 CFU was injected
so that over 1,000 times more Salmonella entered the body,
in contrast to our oral immunizations with a peak colonization of only
about 6 × 104 CFU, and this possibly explains the
differential accumulation. Interestingly, the ca. 3 × 104 Salmonella cells that persisted in the
draining lymph node from day 5 to day 12 after subcutaneous injection
also failed to sustain the selective accumulation of ovalbumin-specific
T cells, confirming that many Salmonella cells are required
for specific T-cell accumulation. Despite the weak selective
accumulation after oral administration, a substantial fraction of the
ovalbumin-specific T cells became specifically activated and divided in
vivo, indicating that T-cell activation was a more sensitive
measurement compared to selective accumulation.
The combined data for in situ antigen expression and T-cell activation
were in good agreement with a model according to which antigen
localization regulates the induction of immune responses in a dose- and
time-dependent fashion (47). An in situ antigen expression
concentrated in the Peyer's patches and persistent over several days
induced a dose-dependent localized T-cell response in the Peyer's
patches with a similar time course. Peyer's patches were functional
induction sites, and many locally formed T-cell blasts remained there
until their first division cycles and then migrated through the
mesenteric lymph nodes as expected (32).
Both the in situ antigen expression and the T-cell response exhibited
biphasic kinetics, but the initial T-cell activation was much stronger
compared to the small antigen peak at day 1. Possibly early antigen
levels in the Peyer's patches as calculated from the number of viable
bacteria (CFU) were underestimated. In vitro and in vivo data suggest
that after entry of host phagocytic cells, most Salmonella
cells are rapidly killed before the residual bacteria adapt to the
intracellular environment, survive, and replicate (2, 28,
40). Possibly many Salmonella cells are similarly
killed early after invasion of the Peyer's patches and thereby escape
detection by plating and flow cytometry although they have delivered
their antigen. Such an undetected initial release of antigen might
explain the rather strong early activation of cognate T cells.
There was a continuous spatial separation of Salmonella and
specific T cells in the Peyer's patches, although many of the T cells
became activated, which requires physical contact with antigen-presenting cells. Host cells that have killed all their intracellular bacteria or that have taken up the remnants of killed cells and bacteria might migrate from the colonized subepithelial dome
area to the interfollicular T-cell area where they activate cognate T
cells, although such migrating cells containing killed Salmonella have not yet been detected. A migration pathway
within the Peyer's patches has been previously postulated for
dendritic cells (18, 22). Alternatively, infected
dendritic cells might reach the interfollicular area with processes
that can sometimes be as long as several hundred micrometers
(43). Further studies are required to test these and other possibilities.
The data obtained in this study could be used to further optimize
recombinant live Salmonella strains as carriers for foreign antigens. The in vivo downregulation of
Ptac-driven antigen expression provides an
additional explanation for why this promoter is suboptimal for live
recombinant Salmonella-based vaccines (4). A
rational optimization could be possible based on in situ expression
levels and T-cell induction data for several other promoters. In
addition to transcriptional regulation, antigen degradation by
Salmonella stress proteases might affect the amount of
antigen that can be delivered. Selective mutation of proteases such as
HtrA or regulatory genes such as htpR might significantly
increase the antigen level, resulting in an enhanced immune response.
Moreover, secretion or surface display of the antigen instead of
cytoplasmic expression (20) as well as the use of carriers
with different attenuations might enhance antigen presentation to
cognate T cells.
The approach and methods developed in this study make it possible to
directly test these and other concepts in vivo. The findings from the
transgenic system can then be validated with efficacy testing of
Salmonella-based vaccines in normal hosts. One particularly attractive application would be the murine Helicobacter
pylori infection model in which Salmonella-based
vaccines elicit protective immunity in a CD4+
T-cell-dependent manner (8, 13, 26). Such studies might lead to a more detailed understanding of how recombinant
Salmonella strains induce cellular immune responses and,
eventually, to an efficient rational optimization of these promising
oral vaccines.
| |
ACKNOWLEDGMENTS |
I thank Thomas F. Meyer and Toni Aebischer for helpful
discussions and generous support and Meike Wendland for excellent
technical assistance.
| |
FOOTNOTES |
*
Mailing address: Abteilung Molekulare Biologie,
Max-Planck-Institut für Infektionsbiologie, Schumannstraße
21/22, D-10117 Berlin, Germany. Phone: 49 30 28460 430. Fax: 49 30 28460 401. E-mail: bumann{at}mpiib-berlin.mpg.de.
Editor:
J. D. Clements
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Infection and Immunity, July 2001, p. 4618-4626, Vol. 69, No. 7
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.7.4618-4626.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Top
Abstract
Introduction
