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Infection and Immunity, December 1999, p. 6257-6263, Vol. 67, No. 12
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Induction and Regulation of Th1-Inducing Cytokines
by Bacterial DNA, Lipopolysaccharide, and Heat-Inactivated
Bacteria
L.-Y.
Huang,1
A. M.
Krieg,2
N.
Eller,1 and
D. E.
Scott1,*
Center for Biologics Evaluation and Research,
U.S. Food and Drug Administration, Bethesda, Maryland
20892,1 and Department of Internal
Medicine, University of Iowa, Iowa City, Iowa
522422
Received 30 March 1999/Returned for modification 17 July
1999/Accepted 7 September 1999
 |
ABSTRACT |
Th1 immune responses, characterized by production of gamma
interferon (IFN-
), are associated with protective immunity to viruses and intracellular bacteria. Heat-killed Brucella
abortus promotes secretion of Th1-inducing cytokines such as
interleukin-12 (IL-12) and IFN- and has been used as a carrier to
induce Th1 responses to vaccines. To explore which bacterial
constituents could mediate this response and how it is regulated,
murine spleen cells were cultured with B. abortus derived
DNA, lipopolysaccharide (LPS), or whole killed organisms. Each
constituent induced similar, substantial amounts of IL-10. However,
only B. abortus and B. abortus DNA induced high
levels of IFN- and IL-12. B. abortus and B. abortus DNA-stimulated IL-12 production was maximal by 6 to
18 h, while IL-10 production steadily accumulated over this time
period. These kinetics suggested that IL-10 may eventually downmodulate
the Th1-like cytokine response to B. abortus and B. abortus DNA, which was confirmed by using neutralizing antibody. In the absence of IL-10, B. abortus LPS induced strong
IFN- responses, but IL-12 p70 levels were still undetectable from
BALB/c spleen cells. LPS induced IL-12 if the spleen cells were primed
with IFN- and IL-10 was neutralized, indicating that LPS can
stimulate IL-12 production under the most favorable conditions.
Responses to Escherichia coli LPS and DNA mirrored the
responses to B. abortus components, suggesting that immune
effects observed with these constituents may be generalizable to many
microbial species. In vivo experiments demonstrated the same hierarchy
of responses for IL-12 production. These findings support the
likelihood that microbial components, if used as carriers or adjuvants,
can differ substantially in their ability to effect a Th1 response.
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INTRODUCTION |
Optimal immunity to viruses and
intracellular bacteria is typically mediated by the Th1 subset of
CD4+ T lymphocytes. Th1 cells are characterized by the
production of IFN-, the ability to help CTL responses, and the
promotion of complement-fixing antibody isotypes such as immunoglobulin G2a (4, 15, 39, 44). Interleukin-12, chiefly a product of
antigen-presenting cells (APC), is usually critical for the development
of Th1 responses (28, 36, 54). In contrast, Th2 cells, which
produce interleukin-4 (IL-4), IL-5, IL-6, and IL-10, mediate allergic
and some antiparasitic responses (15, 17, 18). Ineffective
containment of viral infections, such as human immunodeficiency virus,
is correlated with Th2-like responses (10, 55). Thus,
antiviral vaccine strategies need to focus upon adjuvants which steer
the immune response in a Th1 direction. Intense interest is being
directed toward the use of bacterial derivatives which promote Th1-like
responses. These include monophosphoryl lipid A (modified
lipopolysaccharide [LPS]), as well as plasmids and
immunostimulatory oligonucleotides, which contain sequences that mimic
the stimulatory properties of bacterial DNA (bDNA) (2, 9, 11, 13,
28, 30, 45, 46, 56, 57). Less-well-defined bacterial preparations
from intracellular pathogens, such as soluble toxoplasmosis antigens,
soluble listerial antigens, and heat-killed Brucella abortus
can also be used to stimulate Th1-like responses in mice (16, 26,
47, 49, 51). The purpose of these studies was to directly compare
the abilities of different bacterial constituents to stimulate
secretion of Th1-inducing cytokines such as IL-12 and gamma interferon
(IFN-) (27, 34, 36, 54). The requirement for priming with
IFN- and the sensitivity to IL-10 downregulation was also examined. In this report we demonstrate that B. abortus and bDNA, but
not LPS, elicit high amounts of Th1-promoting cytokines from spleen cells in vitro and in vivo, even in the absence of priming with exogenous IFN-. Similar levels of endogenous IL-10 production are
stimulated by all three constituents, and thus the amount of IL-10 in
culture cannot account for the inferior IL-12 and IFN- induction by
LPS in normal mice. These results indicate that bacterial constituents
can differ in their ability to trigger the type of innate immune
responses which drive the adaptive response in a Th1 direction. In
particular, bDNA, and complex bacterial mixtures such as B. abortus, are more potent IL-12 inducers than is LPS, although they
retain the ability to induce IL-10. These considerations are important
for the development of Th1-promoting vaccine adjuvants and carriers
which are both effective and safe.
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MATERIALS AND METHODS |
Mice.
IL-10 knockout (KO) mice (on a B10.D2 background) and
IFN- KO mice (on a BALB/c background) were obtained from the Jackson Laboratory (Bar Harbor, Maine). BALB/c and B10.D2 mice were obtained from Jackson or from the Division of Cancer Treatment, National Cancer
Institute (Frederick, Md.). Animals were used according to National
Institutes of Health guidelines on animal use and care.
Reagents and antibodies.
LPS and DNA from Escherichia
coli and control eukaryotic herring testis DNA were obtained from
Sigma (St. Louis, Mo.). Heat-killed B. abortus 1119.3 was
kindly provided by Barbara Martin at the U.S. Department of Agriculture
(Ames, Iowa). B. abortus LPS was purified by butanol
extraction as described previously (24). B. abortus DNA was extracted from B. abortus by using
the Qiagen genomic DNA protocol and reagents (Valencia, Calif.). The
LPS content of the DNA preparations was determined by using the
Limulus amebocyte lysate test (BioWhittaker, Walkersville,
Md.), which was performed by Pankaj Amin (Center for Biologics
Evaluation and Research, U.S. Food and Drug Administration). The amount
of LPS in DNA preparations ranged from 30 to 300 pg/µg of DNA.
Recombinant mouse IFN- and anti-IL-10 and anti-IL-12 monoclonal
antibodies were obtained from Pharmingen (San Diego, Calif.). For
neutralization experiments, antibodies were used at 10 µg/ml in culture.
Cell preparation and culture.
Spleens were removed from
mice, and single cell suspensions were prepared by gentle teasing
through cell strainers (Becton Dickinson, Franklin, N.J.). Erythrocytes
were lysed by using ACK lysing buffer (BioWhittaker) and washed three
times in phosphate-buffered saline (PBS) before resuspension in RPMI
(Life Technologies, Gaithersburg, Md.). RPMI was supplemented with 10%
fetal bovine serum (HyClone, Logan, Utah), penicillin-streptomycin,
HEPES buffer, 2-mercaptoethanol, nonessential amino acids, and
pyruvate. Spleen cells were cultured in 48-well flat-bottom plates
(Costar, Cambridge, Mass.) at a concentration of 107
cells/ml. Preliminary experiments determined that this
concentration of cells provided optimal IFN- production at all time
points tested, to LPS, bDNA, and B. abortus. Preliminary
dose-response analyses were conducted with bDNA concentrations ranging
from 0.5 to 100 µg/ml and LPS concentrations ranging from 3 to 750 µg/ml. Optimal IFN--producing conditions were 25 µg/ml for bDNA and 30 µg/ml for LPS; these concentrations were used for all
experiments. Cultures were incubated at 37°C with 5%
CO2. Supernatants were harvested and frozen at 
20°C for
the cytokine assays.
Cytokine ELISA.
Cytokine content in supernatants was
determined by enzyme-linked immunosorbent assay (ELISA) by using
commercial kits for IFN- (Life Technologies), IL-10 and IL-12 p70
(Endogen, Woburn, Mass.), and IL-12 p40 (Biosource, Camarillo, Calif.).
Samples were assayed in duplicate, and all experiments were performed at least twice. All data shown are from reproducible experiments. Values are expressed as the means with the standard deviations for
duplicate samples. The lower limit of detection for IL-12 p70 was 5 pg/ml.
In vivo experiments.
BALB/c mice were injected intravenously
with B. abortus (108 organisms), B. abortus DNA (100 µg), E. coli DNA (100 µg),
B. abortus LPS (30 µg), low-dose B. abortus DNA
(0.1 µg), or PBS. Injection volumes were 0.1 to 0.2 ml/mouse. The
dose of B. abortus was selected because it is nontoxic,
suppresses Th2 responses, and induces IL-12 mRNA (49). The
100-µg dose of bDNA has been shown to stimulate IFN- secretion in
vivo (11). A 30-µg portion of LPS was selected because
this is the amount of LPS contained in 108 organisms of the
B. abortus preparation. The 0.1-µg dose of bDNA (low dose)
used is the amount of bDNA contained in 108 B. abortus organisms. At 3 h after injection, spleens were
removed and prepared by gentle teasing through cell strainers. After a washing, cells were cultured in RPMI as detailed above at a
concentration of 5 × 106 cells/ml in 48-well plates,
without further stimulation. Supernatants were harvested at 18 to
24 h for ELISA.
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RESULTS |
B. abortus and bDNA are more potent inducers of IFN-
secretion than is LPS.
IFN-, chiefly a product of T and NK
cells, is an important contributor to the development of primary and
recall Th1 responses (4-6). In addition, IFN- suppresses
Th2 development (21, 40, 42, 44). IFN-, secreted in an
antigen-nonspecific fashion at the onset of an immune response,
enhances macrophage activation and antigen uptake and primes
macrophages for IL-12 production (4, 20, 25, 33, 55).
Therefore, IFN- induction is a measure of potential adjuvant
activity by bacterial constituents. The ability of bDNA, LPS, and
B. abortus to induce IFN- was measured in whole spleen
cell cultures, which were used in order to provide an environment
closest to that seen in vivo. Preliminary dose-response studies
indicated that for bDNA and for LPS, 25 to 50 and 30 µg/ml, respectively, were optimal stimulatory doses. B. abortus was
added at 108 organisms/ml, a dose which is stimulatory and
nontoxic. The amount of bDNA contained in the dose of B. abortus used is 500 ng/ml, which is below the threshold dose of
purified bDNA for IFN- production. B. abortus and bDNA,
but not LPS, promoted high levels of IFN- secretion (Fig.
1). Similar results were seen in 10 separate experiments. Typically, IFN- production by LPS-treated
cells was similar to control levels, although in some experiments it
exceeded control culture levels. This interexperimental variation may
reflect occasional in vivo priming if mice were exposed to
microorganisms in the animal care facility. The source of LPS was not a
factor, since neither E. coli nor B. abortus LPS
induced high levels of IFN- (Fig. 1; see also Fig. 3).
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FIG. 1.
IFN- induction by B. abortus, bDNA, and
LPS. BALB/c spleen cells were cultured with the indicated stimuli;
supernatants were harvested at 24, 48, and 72 h, and supernatants
were assayed for IFN- by ELISA. LPS was derived from either E. coli (LPS-EC) or B. abortus (LPS-BA). Controls include
cells stimulated with eukaryotic herring testis DNA (DNA-HT) and
untreated cells.
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Unprimed spleen cells produce IL-12 p70 in response to B. abortus and DNA but not LPS.
The greater ability of B. abortus and bDNA to induce IFN- in vitro, compared to LPS,
could be explained by low IL-12 production in response to LPS. Indeed,
IL-12 p70 secretion appeared to correlate with subsequent IFN-
production (Fig. 2). At early time
points, both B. abortus and bDNA, but not LPS, noticeably
increased IL-12 secretion. IFN- is typically required to elicit
significant amounts of IL-12 from cultured cells exposed to LPS
(20, 37). These results show that robust IL-12 secretion,
induced by B. abortus and bDNA, does not require priming
with exogenous IFN-.
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FIG. 2.
IL-12 is induced by B. abortus and bDNA but
not LPS. BALB/c spleen cells were cultured with LPS and bDNA (from
B. abortus and E. coli) and with B. abortus. Supernatants were removed at the indicated times and
assayed for IL-12 p70 levels by ELISA. Cells cultured with LPS, and
untreated cells produced similar constitutive amounts of IL-12 p70, at
levels near the detection limits of the ELISA (5 pg/ml). In contrast,
bDNA and B. abortus both elicited IL-12 production in excess
of the control cultures at early time points. The results of one of
three similar experiments are shown.
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While IL-12 is the most likely cytokine to be responsible for IFN-
production in this system, other cytokines produced in
response to
pathogens such as type 1 IFNs and IL-18 (IGIF) can
also promote IFN-
secretion (
7,
35,
41,
58). Indeed,
human cells secrete IL-18
in response to stimulatory DNA sequences,
and
B. abortus
induces type 1 IFNs (
15,
48). To confirm that
IFN-
secretion in this system was dependent upon IL-12, cells
were cultured
in the presence of anti-IL-12 or isotype control
antibody.
B. abortus and bDNA-induced IFN-
production was completely
IL-12
dependent (Fig.
3). These data suggest
that other IFN-
-inducing
cytokines do not substitute for the IL-12
requirement to stimulate
IFN-
release.
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FIG. 3.
IFN- induction by B. abortus, LPS, and
bDNA is IL-12 dependent. BALB/c spleen cells were cultured for 72 h with or without anti-IL-12 (10 µg/ml), and supernatants were
assayed by ELISA. More than 90% of the IFN- induction by bDNA and
B. abortus was prevented by anti-IL-12. This experiment is
representative of four separate experiments in two strains of mice
(BALB/c and B10.D2), which all showed significant reduction of IFN-
secretion by antibodies to IL-12.
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Removal of IL-10 permits LPS induction of IFN- and increases
B. abortus and bDNA IFN-.
Interleukin-10 is a
potent downregulator of Th1 responses (19, 38, 55).
Macrophage-secreted IL-10 attenuates IL-12 and IL-1 secretion, thus
limiting the strength of inflammatory reactions and therefore potential
damage to host tissues (3, 55). LPS, bDNA, and B. abortus can all induce some IL-10 (1, 3, 38, 53). The
lack of robust IFN- production by spleen cells exposed to LPS could
be explained by induction of high IL-10 levels, relative to those
induced by B. abortus and bDNA. However, all three
bacterially derived preparations induced similar quantities of IL-10
(Fig. 4). The kinetics of IL-10 secretion
were inversely correlated with those of IL-12 in that, as IL-10
increased, IL-12 levels diminished to baseline amounts by 72 h in
B. abortus and bDNA cultures. The rate of IFN-
accumulation decreased between 48 and 72 h in most experiments,
consistent with downregulation of IL-12, followed by IFN-. Thus, the
amount of IFN- in supernatants was still elevated at 72 h,
reflecting production from earlier timepoints.
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FIG. 4.
IL-10 production is not enhanced in LPS cultures. BALB/c
spleen cells were cultured with the indicated additives for 6 to
72 h. Supernatants were assayed for IL-10 by ELISA. IL-10
production, like IFN-, peaked at the latest time point and showed
similar kinetics for all constituents.
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Although in this system, similar levels of IL-10 were seen after
B. abortus, bDNA, and LPS, it was still possible that
(potential)
LPS-induced IFN-
secretion is more sensitive to IL-10
downregulation
than the pathways used by bDNA and
B. abortus. To explore this
issue, IFN-
production was determined
after incubation of cells
with anti-IL-10 (Fig.
5). In the presence of anti-IL-10,
LPS consistently
induced small amounts of IFN-
secretion. Anti-IL-10
also increased
production of IFN-
by cells cultured with bDNA and
B. abortus.
To confirm these results, cells from IL-10 KO
mice were cultured
with LPS or bDNA. Cells cultured with
E. coli LPS or
B. abortus LPS produced large amounts of
IFN-
(72.3 ± 5.6 and 75.2 ± 2.8
ng/ml, respectively), as
did cells cultured with
E. coli DNA or
B. abortus
DNA (92.5 ± 1.0 and 73.8 ± 4.3 ng/ml, respectively).
Results in IL-10 KO mice differed from those in normal mouse cultures
treated with anti-IL-10. The potency of LPS and bDNA for IFN-
induction was similar in IL-10 KO spleen cultures, but it was
dissimilar in normal mice, with bDNA always stimulating more IFN-
than LPS when spleens were cultured with anti-IL-10. Such results
may
reflect differences in the reactivity of cell populations
in KO mice,
which have developed in the complete absence of endogenous
IL-10.
Overall, however, these results suggest that LPS, while
capable of
inducing IFN-
secretion, can only be a potent inducer
in the absence
of IL-10, whereas the bDNA and pathway of IFN-
induction can proceed
in the presence of IL-10.
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FIG. 5.
IFN- produced when endogenous IL-10 is blocked is
IL-12 dependent. BALB/c spleen cells were cultured with various stimuli
in the presence of anti-IL-10, anti-IL-12, or both antibodies (10 µg/ml). Supernatants were collected at 72 h and analyzed for
IFN- by ELISA. The results from one of two similar experiments are
shown.
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Interestingly, even though IFN-
was increased in
LPS-
IL-10-treated cells, no amplification of IL-12 p70 secretion
was detected
(not shown), suggesting a possible action of another
IFN-
-inducing
factor in this setting. To explore this possibility,
cells were
cultured with LPS-
IL-10 in the presence or absence of
IL-12
(Fig.
5). Coculture with
IL-12 and
IL-10 eliminated the
LPS-induced
IFN-
. Thus, small increases of IL-12, which were
difficult to
detect by ELISA but large enough to cause IFN-
secretion, were
produced when cells were exposed to LPS in the absence
of IL-10.
Role of IFN- priming for IL-12 production in response to
B. abortus bDNA, and LPS.
Murine and human macrophages
exposed to IFN- have enhanced ability to produce IL-12 when
stimulated with LPS (14, 25, 55). The mechanism of this
priming effect appears to be an IFN--mediated increase of IL-12 p40
mRNA transcription and stability (25, 33). It has not been
determined whether bDNA-induced IL-12 is also susceptible to this
priming effect. IFN- KO mice were used for these experiments to
eliminate the possibility of in vivo priming of cells by IFN- due to
environmental factors. IFN- enhanced IL-12 production by cells
cultured with bDNA and B. abortus to a greater extent than
those cultured with LPS (Fig. 6). Only B. abortus and bDNA-cultured cells from IFN- KO mice
produced IL-12 in the presence of anti-IL-10, even without the
exogenous addition of IFN-. Furthermore, neutralization of IL-10 was
synergistic with the addition of IFN- for IL-12 production when
cells were cultured with B. abortus bDNA, or LPS, but the
amount of IL-12 produced was always greatest in B. abortus
cultures. As in normal mice, anti-IL-10 addition could not suffice to
stimulate measurable increases of IL-12 production from LPS-exposed
cells. These results emphasize the limited ability of LPS alone to
provide a strong Th1-promoting environment, compared to B. abortus organisms or bDNA.
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FIG. 6.
B. abortus and bDNA-induced IL-12 are
enhanced by IFN- priming, especially in the presence of anti-IL-10.
LPS only induced detectable IL-12 with the combination of IFN-
addition and anti-IL-10. Spleen cells from IFN- KO mice (BALB/c
background) were stimulated with B. abortus, LPS, or bDNA in
the presence of IFN- (50 ng/ml) and/or anti-IL-10 (10 µg/ml). LPS,
bDNA, or B. abortus was added to the culture 10 min after
the addition of anti-IL-10 and IFN-. IL-12 p70 was measured by ELISA
18 h later. The results of one of three representative experiments
are shown. The results in normal BALB/c mice were similar.
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B. abortus and B. abortus DNA induce
splenic IL-12 in vivo.
Sher et al. reported that IL-12 can be
detected in spleen cell cultures after the injection of a soluble
parasite extract (47). To determine whether the superior
IL-12-inducing ability of B. abortus and B. abortus DNA in vitro could be demonstrated in vivo, BALB/c mice
were injected intravenously with B. abortus, bDNA, or LPS.
At 3 h after injection, spleens were removed, and cells cultured
without further intervention. B. abortus, B. abortus DNA, and E. coli DNA, but not LPS, stimulated
IL-12 secretion from in vivo-treated spleen cells (Table
1). B. abortus given in vivo
was consistently the most potent IL-12-inducing substance, whereas when
exposure was entirely in vitro, bDNA often stimulated as much IL-12
release as had B. abortus. It is possible that bDNA is taken
up by other tissues and degraded by DNases before all of it can reach
the spleen, which could account for the observed decrease in in vivo
potency relative to B. abortus.
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DISCUSSION |
Vaccine adjuvants which foster Th1 responses are likely to be
useful in promoting antiviral immunity. LPS derivatives,
bDNA-containing vaccines, and synthesized immunostimulatory DNA
sequences are under investigation as enhancers of Th1 and cytotoxic T
lymphocyte responses for use against viral and parasitic pathogens. All
of these bacterial products stimulate the innate immune system, which in turn influences the type of adaptive T-cell response. To compare the
abilities of prototypic bacterial constituents to provide a
Th1-favoring environment, we studied the cytokine response to bDNA,
LPS, and whole heat-inactivated intracellular bacteria (B. abortus). In addition, the dependence of IL-12 and IFN-
responses upon IFN- and IL-10 was assessed.
Surprisingly, a direct comparison between LPSs from two different
bacteria and bDNA showed that bDNA had superior IL-12- and IFN--inducing capacities, in vitro and in vivo. Unlike this work, most studies which show that LPS induces IL-12 have been done in
APC-enriched populations or with the exogenous addition of IFN-. LPS
clearly can induce measurable IL-12 from activated splenic adherent
cells (47) and peritoneal or bone marrow-derived macrophages
(50, 52). In some studies, LPS induced IL-12 and IFN-
production from spleens in vivo, but priming by footpad injection of
LPS was required (43). Using immunohistochemical methods, a
recent study has shown that intravenous injection of LPS elicits
detectable IL-12 p40 in splenic dendritic areas, although to a much
lesser degree compared to a parasite protein extract (47).
Additional support for poor IL-12-inducing activity in the spleen by
LPS is provided by the observation that intraperitoneal injection does
not prime for the Schwartzman reaction, which is IL-12 dependent
(43). Furthermore, most studies have measured IL-12 p40
rather than the bioactive heterodimer p70. In fact, p40 homodimers can
antagonize the action of p70 (22, 23). Overall, these
reports are consistent with our findings that LPS elicits little IL-12
p70 from spleen cells.
In vitro, priming of spleen cell cultures by IFN- increases IL-12
responses to LPS (20, 55). However, other stimuli, such as
viable or heat-killed M. tuberculosis, or latex beads, do
not require IFN- priming for the production of IL-12 by macrophages (31). Our results indicate that bDNA and B. abortus-induced IL-12 does not require exogenous IFN- priming,
since bDNA and B. abortus stimulation elicited prompt IL-12
and IFN- production from normal spleen cells. In IFN- KO mice,
B. abortus and bDNA alone, still measurably increased IL-12
levels in the absence of IFN-, when IL-10 was neutralized.
Anti-IL-10 alone did not enhance IL-12 secretion from LPS-treated IFN
KO mouse cells, whereas IL-10 neutralization did stimulate IL-12
release from LPS-treated normal mouse cells. The difference between
normal and IFN- KO mice seen here suggests that constitutive in vivo
priming by low levels of environmentally induced IFN- occurs in
normal mice; this could function to provide a regulated, low level of
responsiveness to LPS. In all cases, the combination of anti-IL-10 and
exogenous IFN- caused the most IL-12 production from IFN- KO
cells, although B. abortus invariably was the most potent
stimulator under these conditions. Taken together, these results
support the hypothesis that bDNA- or B. abortus-induced
IL-12 is less dependent upon IFN- priming than is LPS-induced IL-12.
The increased potency of B. abortus and bDNA relative to LPS
could be explained if these bacterial products stimulate different cell
populations or subpopulations to produce IL-12. B cells, monocytes,
dendritic cells, and polymorphonuclear leukocytes all respond to LPS,
and are all capable of secreting IL-12 (32, 47, 54). CpG
motifs, contained in bDNA, directly stimulate B cells and macrophages
and promote B-cell production of IL-12 (8, 29, 48). If LPS
stimulates different cell populations than does bDNA, these populations
may be more sensitive to downregulatory cytokines such as IL-10, may be
simply less numerous, or may secrete less IL-12/cell. Our experiments
in IL-10 KO mice have suggested that bDNA, B. abortus, and
LPS-induced IL-12 have similar sensitivities to downmodulation by
exogenous IL-10 (not shown). Although IL-10 levels were similar in bDNA
and B. abortus cultures, B. abortus typically
stimulated higher IL-12 production. A likely explanation is that a
greater number of IL-12-secreting cells initially respond to B. abortus than to bDNA. This is supported by recent in vivo immunohistochemical analysis of IL-12 expression in B. abortus- and bDNA-treated mice, showing more numerous IL-12
secreting cells after treatment with B. abortus
(49a). Detailed dissection of responding cell populations
and the pathways through which they are stimulated should elucidate why
bDNA and B. abortus are more effective IL-12 and IFN-
stimulators than LPS.
B. abortus appeared to be similar to bDNA in its ability to
induce IL-12 from spleen cell cultures. Like bDNA, it induced IL-12
more effectively than LPS, and this IL-12 production was downregulated
by endogenous IL-10 and upregulated by IFN-. However, bDNA contained
in B. abortus is not likely to fully explain the potent
effects of B. abortus. The amount of bDNA contained in the
concentration of B. abortus used is close to 500 ng/ml
(12), which is well below our minimal stimulatory bDNA
concentration of 2.5 µg/ml. The amount of LPS in the B. abortus preparations was 30 to 35 µg/ml, a level similar to
doses of LPS used in these experiments. However, the conclusion that
stimulation of IL-12 and IFN- secretion by B. abortus is
caused by constituents other than bDNA is also not entirely proven by
these calculations. B. abortus, a macrophagotropic organism,
may preferentially target and activate APCs and thus could deliver its
constituents more effectively with other
stimulating signals or in a particularly stimulating
configuration to responding cells. Indeed, numerous endeavors in this
laboratory to remove bDNA from the B. abortus preparations by using DNase digestions coupled with sonication have failed to eliminate PCR-detectable B. abortus DNA sequences, suggesting that bDNA is protected from
degradation when contained in heat-killed bacteria. However,
efforts are under way to identify other immunostimulating compounds
in B. abortus which can promote Th1 responses.
These studies show that bDNA and LPS differ substantially in their
ability to create a Th1-promoting environment in vitro and in vivo. We
also show for the first time that bDNA-induced IL-12 is enhanced by
priming with IFN-. Although responses to both constituents and to
B. abortus were regulated by IFN- and endogenous IL-10,
at optimal doses quantitative differences among them are marked.
Further understanding of these differences may lead to the design of
more effective Th1-promoting adjuvants, which are needed for protective
responses to viral and parasitic diseases.
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ACKNOWLEDGMENTS |
We thank Hana Golding and Ray Donnelly for thoughtful review of
this manuscript. Pankaj Amin kindly assayed all bacterial constituents
for LPS content. Debra Lowry provided excellent technical assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Center for
Biologics Evaluation and Research, FDA, Bldg. 29, Rm. 232, 8800 Rockville Pike, Bethesda, MD 20892. Phone: (301) 827-3016. Fax: (301)
402-2780. E-mail: scottd{at}cber.fda.gov.
Editor:
R. N. Moore
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Infection and Immunity, December 1999, p. 6257-6263, Vol. 67, No. 12
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
