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Previous Article | Next Article 
Infection and Immunity, June 2001, p. 3980-3988, Vol. 69, No. 6
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.6.3980-3988.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Influence of Vector-Encoded Cytokines on
Anti-Salmonella Immunity: Divergent Effects of
Interleukin-2 and Tumor Necrosis Factor Alpha
Basel K.
al-Ramadi,1,*
Mariam
H.
Al-Dhaheri,1
Nada
Mustafa,1
Mounir
AbouHaidar,1,
Damu
Xu,2
F. Y.
Liew,2
Miodrag L.
Lukic,1 and
Maria J.
Fernandez-Cabezudo1
Department of Medical Microbiology, Faculty
of Medicine and Health Sciences, UAE University, Al Ain, United Arab
Emirates,1 and Department of Immunology,
University of Glasgow, Western Infirmary, Glasgow, United
Kingdom2
Received 14 November 2000/Returned for modification 8 January
2001/Accepted 13 March 2001
 |
ABSTRACT |
Attenuated Salmonella strains are of interest as new
vaccine candidates and as vectors of cloned genes of other organisms. Attenuated strains expressing specific cytokines were constructed as a
means of manipulating the immune response in various disease settings.
In the present study, interleukin-2 (IL-2)-expressing (GIDIL2) or
tumor necrosis factor alpha (TNF-
)-expressing (GIDTNF) strains were
compared with the parent strain (BRD509) for the effect of cytokines on
anti-Salmonella immunity. Expression of IL-2 resulted in
a rapid clearance of the organism soon after vaccination. The reduction
in GIDIL2 CFU was 50- to 300-fold higher than that of BRD509 and
correlated with a markedly decreased splenomegaly. Furthermore, no
evidence for any significant activation, including upregulation of
surface markers and production of nitric oxide (NO), was observed in
spleens of GIDIL2-injected mice. In contrast, the host response to
GIDTNF was marked by an early, strong, splenic cellular influx, but
surprisingly, the degree of induced splenomegaly and NO secretion was
only 50% of that observed in BRD509-treated mice. Despite this,
bacterial colonization of the spleen in GIDTNF-immunized animals was
either slightly decreased from or equivalent to that of the
BRD509-treated group, suggesting the induction of additional antimicrobial mechanisms by TNF-. In vivo protection studies demonstrated that, at limiting doses, GIDIL2 was inferior to GIDTNF and
BRD509 in its capacity to protect against virulent challenge. At high
doses, however, all three strains exhibited equal protective efficacy.
These results demonstrate that the immune response against intracellular bacteria can be manipulated by pathogen-expressed cytokines and open the way for further fine tuning of immune responses not only to Salmonella strains themselves but also to
the heterologous gene(s) carried by them.
| |
INTRODUCTION |
Salmonellae comprise a
family of enteric pathogens characterized as facultative intracellular
bacteria capable of inducing a range of systemic diseases, including
typhoid fever, gastroenteritis, and bacteremia in human and animal
hosts. Attenuated strains of Salmonella have been developed
by genetic targeting of genes involved in essential metabolic pathways.
The most widely used approach has been the introduction of defined
deletions into genes encoding enzymes involved in the biosynthetic
pathway of aromatic amino acids (16). The resultant
mutants are thus rendered avirulent by virtue of their inability to
synthesize several critically needed aromatic compounds not found in
mammalian hosts. Such mutants have become of great interest not only
for their potential as the next generation of new and improved vaccines
against Salmonella infections but also as mucosal vaccine
delivery systems of a wide range of heterologous antigens of other
pathogens (reviewed in reference 8). Salmonella
enterica strains of both the Typhimurium and Typhi serovars
carrying single or double mutations in aro genes were shown
to be effective in providing long-term protection in the mouse model of
typhoid fever as well as in inducing good cell-mediated and humoral
immunity in human volunteers (21, 42, 43). Additionally,
several aroA/aroD double mutants of serovar
Typhimurium have been engineered to express defined cytokines, such as
interleukin-1
(IL-1), IL-2, IL-4, IL-6, tumor necrosis factor
alpha (TNF-), and gamma interferon (IFN-
), and were shown to be
efficient vectors for the delivery of these cytokines in certain in
vivo experimental conditions (7, 9, 12, 46). Thus,
targeted delivery of cytokines can potentially be useful as a
therapeutic approach in the treatment of autoimmune conditions, infectious diseases, and cancer.
Several studies have demonstrated the importance of the innate immune
response in limiting bacterial multiplication in the early phase of
Salmonella infection, ascribing roles for macrophages, NK
cells, and 
T cells in this process (reviewed in reference 18). Salmonella pathogenicity is strongly
correlated with the ability to resist the antimicrobial defense
mechanisms of and survive within the tissue macrophages of the host
(13). In addition to serving as host cells to
Salmonella organisms, macrophages also initiate the innate
immune response by producing IL-12, a known growth factor for NK cells
(44). The importance of NK cells has been shown to be
largely due to their ability to rapidly secrete IFN-, a cytokine
with potent macrophage activation properties, following infection
(35, 37). The early release of IFN- and TNF- results
in the activation of tissue macrophages, enabling them to control
bacterial growth and multiplication (28, 29). Tissue
macrophages utilize two main antimicrobial mechanisms: production of
reactive nitrogen intermediates and reactive oxygen intermediates,
catalyzed by inducible nitric oxide synthase (NOS2) and phagocyte
oxidase enzymes, respectively (6, 38). Both pathways
contribute to defense against Salmonella infection and have
largely overlapping functions in maintaining host resistance to
endogenous microbial flora (38). In addition to the direct cytotoxic function of reactive nitrogen intermediates against microbial
pathogens, recent evidence demonstrated an important regulatory role
for nitric oxide (NO) in the innate immune response. Within a few hours
of pathogen entry, NOS2 is activated transiently, an event shown to be
critical for the activation and maturation of NK cells
(10). This regulatory role of NOS2 appears to relate to
its participation in the IL-12 signaling pathway in NK cells, enabling
these cells to secrete large amounts of IFN- (11). Thus, the secretion of IFN- by NK cells during the innate phase of
the immune response, which is critical for empowering host macrophages
with the ability to control microbial infection via the production of
NO, is itself dependent on an early and transient activation of NOS2.
This pattern of interaction illustrates a hitherto unappreciated degree
of sophistication governing innate immune responses.
We undertook a comprehensive analysis of the regulation of immunity to
facultative intracellular bacteria by studying the host response to
Salmonella following immunization with Salmonella strains expressing defined inflammatory as well as regulatory cytokines. In this report, the outcome of administering attenuated serovar Typhimurium strains expressing IL-2 or TNF- was compared with that for the non-cytokine-expressing parent strain by using a
number of parameters. The results demonstrate that the immune response
can be readily and rapidly influenced by bacterially expressed
cytokines. Furthermore, the differential activation of immune response
parameters is shown to have a profound effect on the overall level of
protection afforded by these vaccine strains of Salmonella.
| |
MATERIALS AND METHODS |
Mice.
BALB/c mice were purchased from Harlan Olac (Bicester,
United Kingdom) and bred in the animal facility of the Faculty of
Medicine and Health Sciences, UAE University. Female mice aged 8 to 12 weeks of age were used.
Bacterial strains and growth conditions.
The aroA/aroD
mutant strain of S. enterica
serovar Typhimurium, designated BRD509, has been described previously
(41). The derivation of cytokine-expressing strains GIDIL2
and GIDTNF, producers of murine IL-2 and TNF-, respectively, was
fully described elsewhere (46). Cytokine expression is
under the control of the anaerobic growth-induced nirB
promoter, and cytokine expression plasmids were maintained in
Salmonella by selection on 100 µg of ampicillin/ml. The
fully virulent Salmonella strain, SL1344, is the parental wild-type strain from which BRD509 was originally derived (16, 41). The 50% lethal dose (LD50) for
BALB/c mice of BRD509, GIDIL2, or GIDTNF, given intraperitoneally
(i.p.), is >2 × 106 CFU; in contrast, the
LD50 of SL1344 is <5 CFU (our unpublished data).
Aliquots of frozen bacteria were plated on Trypticase soy agar (Oxoid,
Basingstoke, United Kingdom) plates with (GIDIL2 and GIDTNF) or without
(BRD509 and SL1344) ampicillin. Five to ten CFU was cultured overnight
in Trypticase soy broth and then diluted 1:10 in fresh medium and grown
for a further 2 to 3 h at 37°C. Appropriate dilutions were made
in pyrogen-free phosphorus-buffered saline (PBS) (Sigma Chemical Co.,
St. Louis, Mo.), and 0.5-ml aliquots were given i.p. per mouse.
Bacterial doses were confirmed by CFU plate counts.
Determination of in vitro bacterial growth rate.
Bacterial
CFU were inoculated into 20 ml of Trypticase soy broth. The density of
bacterial suspension was adjusted to an optical density at 600 nm
(OD600) of 0.03 and grown to log phase. Samples were incubated at 37°C with gentle shaking, and
OD600 readings were taken every hour for a total of
5 h.
Enumeration of bacteria in spleen homogenates.
Groups of
mice (five mice per group) were sacrificed by cervical dislocation at
different time points after infection. Spleens were removed
aseptically, individually weighed, and homogenized in 5 ml of cold
sterile water in an Ultra-terrax T25 tissue homogenizer (Janke & Kunkle, Staufenim Breisgau, Germany). A 100-µl aliquot of the
homogenate or an appropriate dilution was plated on Trypticase soy agar
in the presence or absence of ampicillin, and the number of viable CFU
was determined after an overnight incubation.
Flow cytometry analysis.
Spleen cell suspensions were
prepared from animals infected i.p. 7 days previously with a dose of
0.5 × 106 to 1.0 × 106 BRD509, GIDIL2, or GIDTNF bacteria per mouse.
Following hypotonic shock to eliminate red blood cells, cells were
washed and resuspended in staining buffer (PBS-1% fetal calf
serum-0.1% NaN3) to a concentration of
107/ml. Aliquots of 100 µl
(106 cells) were dispensed into wells of a
round-bottomed 96-well plate and incubated with specific anti-CD16/CD32
monoclonal antibody (MAb) for 15 min on ice to block all FcR sites.
Cells were then doubly stained with a combination of directly
conjugated MAbs to the T-cell receptor C chain, B220, and CD11b
(m subunit of Mac-1) (purchased from
PharMingen, San Diego, Calif.). Anti-Sca-1 (Ly-6A/E) MAb
(30) was affinity purified on a protein G-Sepharose column
and biotinylated in our laboratory using a standard method. All
antibodies were pretitrated in preliminary experiments and used at
saturating concentrations. Cell staining was done for 30 min on ice,
and washed cells were analyzed on a FACSort (Beckton Dickinson,
Mountain View, Calif.). Data collected on 25,000 cells were analyzed
using CELLQUEST software.
Cell preparation.
Erythrocyte-depleted single-cell
suspensions of spleen cells were prepared as previously described
(1, 2) and suspended in RPMI medium supplemented with 5%
fetal calf serum, 2 mM L-glutamine, 1 mM sodium pyruvate,
1× essential amino acids (catalog no. 21135), 1× nonessential amino
acids (catalog no. 11140), 100 U of penicillin/ml, 100 µg of
streptomycin/ml, 50 µg of gentamicin/ml, and 2 × 10
5 M 2-mercaptoethanol (2-ME) (Gibco BRL,
Paisley, United Kingdom). Cells were cultured without further
stimulation at a concentration of 107 cells/ml in
24-well plates and were incubated for 48 h at 37°C with 5%
CO2. Culture supernatants were then collected,
spun free of any cells, and kept at 
20°C until assayed for nitrite content.
Nitric oxide determination.
Accumulation of
NO2 was used to determine
production of NO according to the Griess method, as detailed elsewhere
(3). Briefly, 100 µl of cell-free culture supernatant
was mixed with an equal volume of Griess reagent and incubated at room
temperature for 10 to 15 min. The absorbance at 562 nm was measured in
an automated microplate reader. Nitrite concentration was quantitated
using NaNO2 as the standard and expressed as the
micromolar concentration of
NO2 per
107 spleen cells.
Cytokine ELISAs.
Overnight cultures of the BRD509, GIDIL2,
and GIDTNF bacteria were diluted 1:5 and grown for a further 2 h
at 37°C in the presence (GIDIL2 and GIDTNF) or absence (BRD509) of
ampicillin. Cytokine expression was also tested after induction of the
nirB promoter by growing bacterial colonies in the presence
of ampicillin and 4 mg of glucose/ml in a closed screw-cap tube, as
described (46). At the end of the incubation period,
bacteria were spun down at 6,000 × g 8,000 rpm for
10 min at 4°C. Bacterial pellets were sonicated in 0.5 ml of lysis
buffer containing 1% Triton X-100 supplemented with NaF,
phenylmethylsulfonyl fluoride, aprotinin, and leupeptin, as described
previously (4). Bacterial lysates were cleared by a 15-min
high-speed centrifugation at 13,400 × g at 4°C and
analyzed for cytokine content by specific enzyme-linked immunosorbent
assays (ELISAs). IL-2 and TNF- content was quantitated by ELISA
using specific kits from Endogen (Cambridge, Mass.) following the
manufacturer's instructions.
Vaccination and challenge experiments.
For these
experiments, groups of mice (five per group) were immunized i.p. with
strains GIDIL2 and GIDTNF with doses ranging from 6 × 103 to 6 × 105
bacteria per mouse. Four weeks later, mice were challenged i.p. with
the virulent SL1344 strain (LD50 < 5), and
deaths were scored for 60 days after challenge.
Statistical analysis.
Statistical significance was analyzed
using Student's t test. Differences between experimental
groups were considered significant when P was <0.05.
| |
RESULTS |
Cytokine expression by Salmonella strains.
The
BRD509 strain of serovar Typhimurium is attenuated as a result of
deletions in the aroA and aroD genes. It is very
efficient in affording protection against virulent
Salmonella challenge, with an immunizing dose of
105 bacteria per mouse i.p., resulting in 100%
protection against up to 10,000 LD50s of virulent
Salmonella (unpublished data). Two recombinant strains of
BRD509, GIDIL2 and GIDTNF, were derived that expressed IL-2 and TNF,
respectively, under the control of the nirB promoter
(46). Given that both innate immunity and adaptive
immunity are important for controlling infections by intracellular
bacteria, we wished to study the influence of bacterially expressed
cytokines on the anti-Salmonella immunity in the susceptible BALB/c mouse strain.
The extent of cytokine expression by the recombinant strains was first
determined using specific ELISAs. The two recombinant strains (GIDIL2
and GIDTNF) were found to express their respective cytokines
specifically, while the parental BRD509 strain is negative for both
IL-2 and TNF-. Moreover, under uninduced growth conditions, the
level of expression was calculated to be 4,000 and 1,250 pg/1010 organisms for the GIDIL2 and GIDTNF
strains, respectively. Expression of the cytokines increased by
~1,000-fold when the bacteria were grown under anaerobic conditions,
as described in Materials and Methods, to induce the nirB
promoter. The values for the mean plus the standard error of the mean
for GIDIL2 and GIDTNF under inducing growth conditions were 4,315 + 835 and 922 + 149 ng/1010 organisms, respectively.
These levels are presumably a better reflection of the situation in
vivo, as these bacteria are intracellular pathogens and reside mainly
inside macrophages.
In vitro growth rate of recombinant Salmonella
strains.
The growth rate of BRD509 was compared with those of the
cytokine-expressing derivatives. Bacterial colonies were inoculated into fresh medium, and the suspension density was adjusted to be equal
among all three strains. The in vitro rate of growth was followed over
a period of 5 h, and the results are shown in Fig.
1. As can be clearly seen, all three
strains exhibit nearly identical growth rates in vitro.
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FIG. 1.
Cytokine-expressing Salmonella strains
show growth rates identical to that of the parental strain in vitro.
Five to 10 CFU from each strain was used to inoculate a 20-ml broth.
The cell density of all three cultures was adjusted to an
OD600 of 0.03 and incubated over a 6-h period to log phase.
OD readings were taken at different intervals and plotted against time
of culture. The growth curve of BRD509 was compared with those of the
GIDIL2 and GIDTNF strains. Each data point represents the mean of two
readings. Standard deviation was <10%. The results are representative
of four independent experiments.
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Phenotypic analysis of immunized spleen cell populations.
Four
groups of mice were immunized with either BRD509, GIDIL2, GIDTNF, or
PBS as a control. Spleens were harvested 7 days later and analyzed by
flow cytometry to ascertain any alteration in the cellular composition
of the spleen and to determine the extent and makeup of the
inflammatory cell infiltrate. As shown in Fig.
2, the extent of the splenic cellular
influx, delineated on the basis of the forward scatter/side scatter
(FSC/SSC) profile by the indicated R2 gate, differs among the
four groups of animals. In PBS-treated mice (Fig. 2A), the majority of
splenocytes (93.2% of total) are observed outside this gate,
reflecting the standard phenotype of resting spleen lymphocytes. The
percentage of cells exhibiting a relatively elevated FSC/SSC profile is
6.8%, which reflects most of the macrophage and polymorphonuclear
leukocyte populations (2). In vaccinated mice, the
percentage of cells within the R2 gate rises significantly to 33.3, 18.7, and 56.3% in BRD509-, GIDIL2-, and GIDTNF-injected mice,
respectively (Fig. 2B to D). This rise is mostly attributed to the
influx of inflammatory cells (mainly macrophages and neutrophils) into
the spleen and/or the activation of resident splenic lymphocytes (see
below) (2, 26). It is noteworthy that the percentage seen
in GIDIL2-immunized mice is reduced (18.7%), while that of
GIDTNF-injected mice is substantially increased (56.3%), compared to
the percentage for animals immunized with BRD509 (compare Fig. 2C and D
with 2B).
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FIG. 2.
Extent of splenic cellular influx in immunized animals.
Spleens were analyzed at day 7 postimmunization with 1 × 106 to 2 × 106 organisms of BRD509 (B),
GIDIL2 (C), or GIDTNF (D). As a control, splenocytes of PBS-treated
mice are also shown (A). The results are shown as dot plots depicting
FSC level versus SSC level. The percentage of cells with elevated SSC
(representing the inflammatory influx) is shown in each panel. Data
from a total of 25,000 cells per group were collected and analyzed. The
results are representative of four independent experiments.
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The cellular composition of the various spleen populations was also
analyzed. Figure 3 shows the profile of
the total, ungated splenocyte population after staining with MAbs to
CD11b and Sca-1 (Ly-6A/E). CD11b is widely expressed on myeloid lineage
cells, including macrophages and neutrophils, as well as on NK cells (15, 24). Sca-1 is expressed on all hematopoietic stem
cells and is also an activation marker of diverse types of lymphoid and
myeloid lineage cells (23, 31, 33, 40). In PBS-treated mice, 6.6% of splenocytes were
CD11b+/Sca-1 (Fig. 3A),
representing resting cells of myeloid origin. In addition, 22.4% of
cells were CD11b/Sca-1lo,
indicating cells of lymphoid origin with low levels of Sca-1 expression. In BRD509-injected mice, the level of Sca-1 expression increased dramatically on both lymphoid and myeloid cells, resulting in
73.3% CD11b/Sca-1hi and
20.8% CD11b+/Sca-1+ cells,
respectively (Fig. 3B). Moreover, despite being clearly positive for
Sca-1, CD11b+ cells exhibited a bimodal pattern
of Sca-1 expression (Fig. 3B). Gating of the respective populations of
CD11b+/Sca-1+ cells
indicated that the great majority (~78%) of these cells expressed
very high Sca-1 levels, while ~22% showed relatively lower levels
(analysis not shown). In sharp contrast, GIDIL2-treated spleens
exhibited an overall pattern of expression that was similar to that of
control spleens (compare Fig. 3A and C). The two main changes observed
in GIDIL2-injected mice were the increased percentage of
CD11b/Sca-1+ (34.4%
compared to 22.4% in control mice) and
CD11b+/Sca-1 cell
populations (17.0% compared to 6.6% in control mice). Importantly, despite the evidence of a small increase in the number of
CD11b+ cells in GIDIL2-injected spleens, there
was no upregulation of Sca-1 expression on these cells. Moreover,
splenocytes of GIDIL2-treated animals were noticeably devoid of any
cells exhibiting high levels of Sca-1 expression (Fig. 3C).
GIDTNF-injected mice showed a different pattern of Sca-1/CD11b
expression from that of any of the other three experimental groups
(compare Fig. 3D with Fig. 3A to C). The percentage of splenic
CD11b+ cells increased to >44%, nearly twice
the number observed in BRD509-treated animals and sevenfold that of
control mice (Fig. 3D). Of the CD11b+ cells,
nearly half were negative for Sca-1
(CD11b+/Sca-1, 20.4%)
while the other half
(CD11b+/Sca-1+, 23.8%)
expressed Sca-1 at levels varying from intermediate to high. The
remaining splenocytes of lymphoid origin
(CD11b) expressed Sca-1 at high levels, very
similar to what was observed in BRD509-injected animals (compare Fig.
3B and D). Furthermore, a similar analysis of the cell population
within the R2 gate indicated that CD11b+ cells
were the predominant cell type, accounting for ~54.4, 58.7, 74.3, and
76.3% of cells in PBS-, BRD509-, GIDIL2-, and GIDTNF-treated mice,
respectively (data not shown). Taken together, it can be concluded that
(i) the different recombinant bacterial strains induce distinct
cellular phenotypic changes in spleens of vaccinated animals, (ii)
expression of IL-2 (GIDIL2 strain) results in a marked attenuation of
the inflammatory influx as compared to the non-cytokine-expressing
strain (BRD509), and (iii) immunization with GIDTNF induces several
changes in the cellular composition and phenotypes which are quite
distinct from those in other groups.
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FIG. 3.
Phenotypic analysis of spleen cells. Single-cell
suspensions were prepared from spleens of animals immunized 7 days
previously with either PBS (A), BRD509 (B), GIDIL2 (C), or GIDTNF (D).
The results are shown as dot plots depicting staining with Sca-1 versus
CD11b. The cell percentages within each quadrant are given in the
figure. Data from a total of 25,000 cells per group were collected and
analyzed. The results are representative of four independent
experiments.
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Bacterial colonization and splenomegaly.
Inherently
susceptible BALB/c mice were immunized with a dose of 0.8 × 106 organisms of the BRD509, GIDIL2, or GIDTNF
strain. Enumeration of viable bacteria was done on homogenates of
spleens obtained at 2, 7, 14, and 21 days after immunization. As
illustrated in Fig. 4A, maximal numbers
of CFU in the spleen were observed at day 7 postimmunization for all
three bacterial strains. At day 21 postimmunization, BRD509 CFU were
<1% of the injected dose and those of GIDTNF were reduced by
>40-fold. The bacterial growth curves of BRD509 and GIDTNF strains
were very similar. However, GIDTNF bacteria appeared to persist at
higher levels in the spleen at day 21 postimmunization, as evidenced by
the highly reproducible 5- to 10-fold-higher number of CFU seen
colonizing the spleens of GIDTNF-treated mice. Moreover, the most
striking feature, which was also consistently observed, is the rapid
clearance of the GIDIL2 transductant in vivo. Even at the height of the
observed bacterial CFU (day 7 postinjection), the number of GIDIL2
bacteria never exceeded 0.5% of the injected dose. These findings are
consistent with the reduced inflammatory influx observed in
GIDIL2-injected mice by flow cytometry (Fig. 2). Since all bacterial
strains were shown to grow equally well in vitro (Fig. 1), these
results point to an increased capacity of susceptible BALB/c mice to
specifically limit the growth of the GIDIL2 bacterial transductants.
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FIG. 4.
Cytokine expression alters the rate of bacterial
colonization and splenomegaly in Salmonella-immunized
mice. The levels of bacterial load (A) and splenomegaly (B) were
compared over a period of 3 weeks in mice injected with
~106 organisms of the BRD509, GIDIL2, or GIDTNF
strain. Each data point represents the mean ± standard error of
three to five mice per group. The arrow in panel A indicates the
bacterial dose used for injection. The results are representative of
five independent experiments. Asterisks denote significant differences
(P  0.05) between the indicated groups and the
corresponding BRD509 group.
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Next we investigated the ability of the different bacterial strains to
induce splenomegaly. As can be seen in Fig. 4B, the degree of
splenomegaly induced by BRD509 was maximal at day 14 postimmunization,
reaching a level that was more than seven times the normal size, and
began to decrease thereafter. The GIDTNF-induced splenomegaly followed
a kinetic pattern identical to that of BRD509 up to 7 days
postimmunization. However, unlike the case with BRD509, no further
increase in splenomegaly was observed at later time points, with the
maximal level reached never exceeding four times the normal spleen
size. Strikingly, the degree of splenomegaly observed at day 21 posttreatment in BRD509-injected animals was approximately threefold
that of GIDTNF-injected counterparts, even though the number of
bacterial CFU was significantly higher in the latter mice (Fig. 4A). In
contrast, the GIDIL2 strain induced only a small degree (less than two
times the normal size) of splenomegaly throughout the experiment,
consistent with the flow cytometry analysis data.
Production of nitric oxide.
Single-spleen-cell suspensions
were prepared at different time points following the administration of
BRD509, GIDTNF, GIDIL2, or PBS as control. Cells were cultured for
48 h without any further stimulation, and cell-free culture
supernatants were assayed for content of NO by the Griess assay. The
results are shown in Fig. 5. At day 2 postimmunization, no nitrite was detected in any experimental group. At
day 7, maximal nitrite production was observed in BRD509-injected mice,
reaching a level of ~60 µM per 107 cells. At
day 14 the level was slightly reduced to ~44 µM, and by day 21 nitrite was undetectable. Nitric oxide production followed a similar
time course in GIDTNF-immunized mice, with the exception that the
amount produced was only ~50% of that observed in BRD509-treated animals. Strikingly, production of NO could not be detected in GIDIL2-treated mice at any of the time points examined. Similar results
were obtained in spleens of PBS-treated control mice (data not shown).
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FIG. 5.
Production of NO by splenocytes of immunized animals.
Spleen cells were obtained 7 days after immunization with
106 organisms of the BRD509, GIDIL2, or GIDTNF strain and
were cultured without further stimulation for 48 h. Collected
cell-free supernatants were assayed for nitrite content as a measure of
production of NO. Each data point represents the mean of three mice per
group. The standard deviation was <15%. The results are
representative of three independent experiments.
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In vivo challenge with virulent Salmonella.
Experiments were carried out to ascertain potential functional
consequence of the rapid clearance of GIDIL2 bacteria. Mice were
immunized with a single i.p. injection of ~7.0 × 103 BRD509, GIDIL2, or GIDTNF organisms per
mouse. Four weeks later, all mice were challenged with the highly
virulent SL1344 strain and scored for survival for up to 60 days after
the challenge. The results of a representative experiment are
summarized in Fig. 6A. All control
(PBS-injected) mice succumbed to an overwhelming Salmonella
infection, with death occurring between days 6 and 20. A very similar
survival curve was observed in the GIDIL2-vaccinated group, with 80%
of animals dying over the same period of time. In sharp contrast, 90%
of the mice vaccinated with BRD509 organisms and 83% of those injected
with GIDTNF organisms survived the lethal challenge (Fig. 6A). To test
the influence of bacterial dose on protection, the experiment was
repeated using a high (6 × 105 per mouse)
or low (6 × 103 per mouse) dose of GIDTNF
or GIDIL2 bacteria for vaccination (Fig. 6B). All mice injected with
saline or with a low dose of GIDIL2 strain succumbed to their infection
between days 6 and 13 after challenge (Fig. 6B). By contrast, 60% of
the mice immunized with a low dose of the GIDTNF strain survived the
lethal challenge (two of five mice died on day 9 following challenge).
When the vaccination dose was increased by 2 logs, 100% survival was
observed in mice receiving either GIDTNF or GIDIL2. It can be concluded that expression of IL-2 by Salmonella induces its rapid
clearance in a mouse strain inherently susceptible to the infection.
Furthermore, this clearance can reduce the protective efficacy of the
bacterial strain when given in limiting doses.
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FIG. 6.
Effect of cytokine expression on protective efficacy of
Salmonella strains. (A) Mice were vaccinated with
~7.0 × 103 organisms of the BRD509, GIDIL2, or
GIDTNF strain. Four weeks later, all mice were challenged with 6.4 × 103 organisms of the highly virulent SL1344 strain
(LD50 < 5). The control group received PBS for
immunization and were challenged like the other groups. The number of
mice used in each group was 12 (BRD509 and GIDIL2), 10 (GIDTNF), or 4 (PBS). (B) Mice were immunized with either 6 × 103
(low dose; L) or 6 × 105 (high dose; H) organisms of
the GIDIL2 or GIDTNF strain and were challenged 4 weeks later with
5 × 103 SL1344 organisms. There were five mice per
group (except for the PBS group which had four mice). Survival was
monitored for a total of 60 days. Results are scored as percent
survival and are representative of a total of five independent
experiments.
|
|
| |
DISCUSSION |
Attenuated Salmonella strains are becoming increasingly
attractive as vehicles to deliver heterologous proteins of diverse microbial origin for the purpose of generating protective immunity against pathogens. In addition, several attenuated strains have been
engineered to express specific cytokines that can be targeted in vivo
to enhance immunity or to manipulate immune responses in a variety of
disease conditions. It has been previously shown that bacterially
expressed cytokines continue to be expressed for up to 2 weeks
following oral administration, demonstrating the stability of the
cytokine-encoding plasmids in vivo (46). However, the
effect of cytokine expression on the immunogenicity of the engineered
bacterial strains has not been previously addressed. This report is the
first description of the influence of bacterially expressed cytokines
on anti-Salmonella immunity. The data presented in this
report demonstrate that cytokines expressed by the bacterial pathogen
can have a profound effect on the nature of the ensuing immune
response. Specifically, expression of IL-2 led to the rapid clearance
of the pathogen by the host. In contrast, expression of TNF- was
observed to bring about divergent effects. Thus, despite the induction
of a stronger inflammatory response initially (compared to the BRD509
parental strain), expression of TNF- results in decreased
splenomegaly and nitric oxide secretion. Moreover, while the in vivo
bacterial load of GIDTNF was similar to that of BRD509 over the first 2 weeks, the former strain appeared to persist for longer time periods
over the long run (Fig. 4A; data not shown). The exact mechanism(s)
responsible for cytokine-induced alterations in immune responsiveness
is the subject of investigation at the present time.
The marked decrease in the in vivo survival rate of GIDIL2 organisms is
unlikely to be due to intrinsic, strain-specific growth defects. This
is most aptly shown by the almost identical in vitro growth kinetics of
GIDIL2, GIDTNF, and BRD509 bacterial strains. Instead, we believe that
the significantly smaller bacterial load of GIDIL2 is due to a rapid
clearance of the organism by the immune system. As early as 2 days
postimmunization, the splenic bacterial load of the GIDIL2 strain was
2.5 to 3 logs lower than for GIDTNF or the parental BRD509 strain. This
strongly indicates that a substantial degree of GIDIL2 bacterial
clearance has taken place in the first 48 h in the peritoneal
cavity, the site of immunization in our experiments. This conclusion is
further supported by preliminary findings indicating the rapid
induction, in the peritoneal cavity, of several host immune response
mechanisms by GIDIL2 within a few hours of immunization (B. K. al-Ramadi et al., data not shown). Preliminary evidence demonstrates
that GIDIL2 can very rapidly induce peritoneal cavity cells to
upregulate inducible nitric oxide synthase gene transcription as well
as to secrete NO and IFN- (data not shown). It is noteworthy that at
no time point could production of NO be demonstrated in cultures of
spleen cells of GIDIL2-treated mice, excluding any role for activated
splenocytes in GIDIL2 clearance. Thus, Salmonella-expressed
IL-2 leads to an early upregulation of host defense mechanisms in the
peritoneal cavity that, in turn, results in rapid clearance of
the invading organisms.
It is intriguing to note that the differences in host response to
BRD509 and to GIDIL2 in susceptible BALB/c mice appear to be very
similar to the various responses against virulent Salmonella observed in susceptible versus resistant mouse strains. Following infection with virulent Salmonella, early bacterial
replication is regulated by the nramp1 gene, which encodes
the natural-resistance-associated macrophage protein (Nramp1) expressed
on macrophages (45). This gene appears to have pleiotropic
effects on the function of macrophages, including antigen-processing
capacity and production of proinflammatory cytokines (22).
This has been directly linked to the capacity of macrophages to control
the replication of a number of intracellular pathogens (5,
25). In Salmonella-resistant (nramp1
wild-type) mouse strains, bacterial proliferation in the early phase of
infection (1 to 7 days postinfection) is kept under control by the
action of the Nramp1 protein. In contrast, rapid proliferation of
bacteria is observed in nramp1 mutant
(Salmonella-susceptible) mouse strains (17,
34). In our study, attenuated Salmonella strain
BRD509 continues to proliferate in susceptible BALB/c mice, reaching a
maximum at 7 days postimmunization. However, expression of IL-2 by the
bacteria induces a very rapid and efficient host defense response that
effectively eliminates the vast majority of invading organisms.
Although the identity of the target cell(s) is not yet known, these
findings suggest that the expression of IL-2 by the pathogen may partly
compensate for the defective function of Nramp1 protein in BALB/c
phagocytes. Alternatively, expression of IL-2 may lead to a rapid
activation of another cell type(s), such as NK and/or T cells,
which can contribute to antibacterial immune response by effectively
limiting the growth of the organism in vivo (18).
The IL-2-induced increase in the rate of Salmonella
clearance appears to be analogous to previous findings using
recombinant strains of vaccinia virus. Infection of nude,
immunodeficient mice with vaccinia virus normally results in a lethal
infection. However, expression of IL-2 by the vaccinia virus induces a
rapid host immune response that allows for the successful vaccination of mice, even in immunodeficient recipients (14, 36).
Virus-encoded IL-2 was subsequently shown to induce elevated levels of
NK cell activity and could be partly responsible for the attenuation of viral virulence in immunodeficient recipients (19).
Despite the differences in the nature of the pathogens and their in
vivo habitat, the rapid clearance of IL-2-expressing
Salmonella may well be induced through a mechanism similar
to that observed in the vaccinia virus system.
Immunization using the TNF--expressing Salmonella strain
resulted in several unique alterations in the immune response, quite distinct from those observed in GIDIL2-immunized animals. Despite being
a prototypical proinflammatory cytokine, expression of bacterially borne TNF- in GIDTNF mice induced significantly decreased
splenomegaly and secretion of NO compared to those associated with
BRD509 (responses in the former were approximately 50% of the latter).
Marked differences in production of NO by splenocytes of GIDTNF- versus
BRD509-immunized mice were apparent at both days 7 and 14 postimmunization. However, despite the decreased level of secretion of
NO in GIDTNF-immunized mice, bacterial replication was kept under
control. In fact, the CFU counts at days 2, 7, and 14 postimmunization
for the GIDTNF group were either equivalent to or lower than those for
the BRD509 group. We conclude that expression of TNF- leads to
efficient induction of additional antibacterial defense mechanisms,
such as production of reactive oxygen intermediates (32),
which act in conjunction with NO and limit bacterial multiplication
despite decreased inflammatory influx and NO production.
Further evidence for the differential influence of cytokine expression
on immune response in vivo is seen from the flow cytometry data. Of
particular importance in this regard are the results obtained by
staining with antibodies to CD11b and Sca-1 markers. CD11b is expressed
on macrophages, granulocytes, NK cells, and dendritic cells. Sca-1
(Ly-6A/E) is constitutively expressed on hematopoietic stem cells and
is also upregulated in peripheral lymphocytes and monocytes upon
activation in BALB/c mice (27, 33). One of the most
studied aspects of the Ly-6 family of proteins, and particularly
Ly-6A/E, is their exquisite sensitivity to induction by IFN-/ and
IFN- (20, 39). Our findings confirm that Sca-1 expression is dramatically upregulated on B and T lymphocytes at day 7 postimmunization. This upregulation was mostly observed in mice
immunized with BRD509 or GIDTNF but not with GIDIL2 (Fig. 3).
Moreover, expression of Sca-1 was also upregulated on a
CD11b+, nonlymphoid population of spleen cells.
This was clearly seen in BRD509-immunized animals where the majority
(>84%) of CD11b+ cells were also Sca-1
positive. Surprisingly, despite the increased ratio of
CD11b+ cells in GIDTNF-treated mice (44.2%
compared with 24.7% in BRD509-immunized mice), a significant
percentage (~46%) of those cells failed to upregulate Sca-1
expression. Although the exact reasons for these differences are
unknown, two possible scenarios can be offered to explain the findings.
First, BRD509 and GIDTNF bacterial strains may induce not only
quantitative but also qualitative differences in the cell types in the
course of the immune response. Consequently, bacterially expressed
TNF- may lead to the accumulation of a distinct population of
CD11b+ cells in the spleen that lack Sca-1
expression. This hypothesis is supported by the significant differences
in the extent of splenomegaly as well as production of NO observed over
a period of 3 to 4 weeks following immunization. Alternatively,
differences in cellular phenotypes reflect the different kinetics of
the immune response in the two experimental groups. Thus, it is
conceivable that spleen cells modulate Sca-1 expression in
GIDTNF-treated mice more rapidly than in BRD509-injected animals and
that by day 7 postimmunization (the time point at which the flow
cytometry analysis was carried out), Sca-1 has already been
downregulated. Experiments are currently under way to answer these
questions by probing with a wider spectrum of antibodies to
cell-specific markers and examining cells at different time points
following immunization.
Whatever the explanation for the variant responses observed in this
study, it is clearly evident that vector-encoded cytokines can alter
the immune response in a profound and specific manner. Perhaps this is
best illustrated by the results of the protection studies. The rapid
clearance of GIDIL2 organisms by the enhanced immune response was shown
to indeed reduce the protective efficacy of the strain. As would be
expected, this occurred when the immunizing dose was limiting. At high
doses, both GIDIL2 and GIDTNF strains afforded a good level of
protection that was comparable to what was seen in BRD509-injected
mice. Thus, it is feasible to utilize recombinant GIDIL2 bacteria at an
appropriate concentration to induce a good level of protection while,
at the same time, minimizing the side effects associated with the
administration of large doses of gram-negative bacteria, including
bacteremia and sepsis (43). It must be emphasized,
however, that all of the studies carried out for this report used the
i.p. route for immunization and challenge. It would be important to
carry out similar studies using the oral route, since this is the
natural route of acquiring Salmonella in humans. Based on
previous work, which demonstrated the efficacy of orally administered
Salmonella-expressed cytokines in enhancing the immune
response against Leishmania infection (46), we
hypothesize that cytokine-specific modulation of immunity seen in the
present report would still be effective. These studies are currently
being undertaken. Finally, given the increasingly wide usage of
Salmonella strains as vectors of virulence genes of other
pathogens, incorporation of appropriate cytokines in the vectors may
provide a means by which the desirable immune responses can be
differentially induced.
| |
ACKNOWLEDGMENTS |
We thank Toby K. Eisenstein, Temple University School of
Medicine, for critical review of the manuscript. We are grateful to
Bruce Stocker, Stanford University School of Medicine, for providing
the serovar Typhimurium SL1344 strain.
This work was funded by a grant from the Research Committee of the
Faculty of Medicine and Health Sciences, UAE University, United Arab
Emirates. Additional support was provided by a grant from the UAE
Branch of the Terry Fox Fund for Cancer Research (Canada) to B. K. al-Ramadi.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medical Microbiology, Faculty of Medicine and Health Sciences, UAE
University, P.O. Box 17666, Al Ain, United Arab Emirates. Phone: (9713)
703-9529. Fax: (9713) 767-1966. E-mail:
ramadi.b{at}uaeu.ac.ae.
Permanent address: Department of Botany, Faculty of Science,
University of Toronto, Toronto, Canada.
Editor:
S. H. E. Kaufmann
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Infection and Immunity, June 2001, p. 3980-3988, Vol. 69, No. 6
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.6.3980-3988.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Fernandez-Cabezudo, M. J., Ullah, A., Flavell, R. A., al-Ramadi, B. K.
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[Abstract]
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Abstract
Introduction
