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Infect Immun, February 1998, p. 839-842, Vol. 66, No. 2
Departments of
Microbiology,1
Pediatrics,2 and
Comparative
Medicine,3 The University of Alabama at
Birmingham, Birmingham, Alabama 35294
Received 16 May 1997/Returned for modification 2 July 1997/Accepted 18 November 1997
Pneumolysin-deficient mutant strains of Streptococcus
pneumoniae are known to cause less-severe sepsis than wild-type
pneumococcal strains that produce pneumolysin. This difference is
associated with greater host resistance in mice infected with the
pneumolysin-deficient strains. These studies show that the host
resistance developed during the first 1 to 2 days after infection with
a pneumolysin-deficient mutant strain is dependent on tumor necrosis
factor alpha but is apparently independent of interleukin 1 We previously reported that the
capsular type 2 pneumococcal strain D39 and its pneumolysin-deficient
mutant, PLN, exhibit different growth patterns in the blood of
CBA/N-XID mice after intravenous (i.v.) challenge (3). The
number of CFU of D39 increases exponentially from inoculation until the
death of the mouse, generally within 24 to 36 h of challenge, when
the level of CFU in the blood becomes greater than 109/ml.
The number of CFU of PLN in the blood increases in parallel with that
of D39 until reaching 106 to 107 per ml, at
which point the number of CFU of PLN ceases to increase and is
maintained at a relatively constant level for several days. Once the
number of PLN pneumococci in the blood reaches 106 CFU/ml,
a subsequent infection with D39 is no longer able to cause rapid death.
We hypothesized that the host response generated in the absence of
pneumolysin was partially protective and accounted for the control of
bacteremia at 106 CFU/ml. In contrast, the host response
generated in the presence of pneumolysin was not protective, thus
allowing the numbers of pneumococci in the blood to increase
exponentially (3). Using derivatives of D39 which express
point mutations in pneumolysin (6), we showed that the
hemolytic and complement-activating properties of the toxin did not
account for the difference in bacteremia associated with D39 and PLN
infections (5).
Our previous results also demonstrated that mice actively infected with
D39 produced more interleukin 6 (IL-6) per CFU in plasma than mice
infected with comparable levels of PLN, exactly the opposite of what
would have been expected if the host resistance that developed during
PLN infections was dependent on IL-6 (3). Gamma interferon
(IFN- To investigate further the nature of the host response to pneumococcal
bacteremia caused by strains D39 and PLN, we examined the levels of
proinflammatory cytokines in blood, such as TNF- Pneumococcal bacteremia model.
CBA/CAHN-XID/J mice (Jackson
Laboratories, Bar Harbor, Maine), at 8 weeks of age, were challenged
i.v. as previously described (4) with approximately 5 × 104 CFU of strain D39 (2) or strain PLN
(7). The numbers of CFU per milliliter of blood of PLN and
D39 were determined at selected time points postinfection by
quantitative plating on blood agar (4). For quantitation of
circulating cytokine levels, individual blood samples were diluted with
4 to 9 volumes of Ringer's solution, centrifuged to remove the cells,
and the plasma was stored at Effect of administration of antibody to TNF-
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Role of Tumor Necrosis Factor Alpha in the Host
Response of Mice to Bacteremia Caused by Pneumolysin-Deficient
Streptococcus pneumoniae
ABSTRACT
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(IL-1) or IL-6. Survival beyond 5 days appeared to depend on the
ability of the mice to produce IL-1.
TEXT
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Abstract
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) also did not appear to be responsible for the host resistance
of PLN-infected mice; IFN- in plasma was detected only in mice
infected with D39 (not PLN), and then only when the mice were extremely
septic and near death (3). Thus, neither of these cytokines
appeared to be responsible for mediating the host resistance of
PLN-infected mice. Other studies have shown that tumor necrosis factor
alpha (TNF-
) may be important for host resistance to lung infections
with wild-type pneumococci (15) and that purified
pneumolysin induces the production of TNF- and IL-1 in isolated
human monocytes and a human monocyte cell line (11).
, IL-1, and IL-6;
cytokines with potential regulatory functions in mediating
inflammation, such as IL-4 and IL-10; and cytokines which are not
believed to play a central role in mediating inflammation, such as IL-2
and IL-5 (9, 12). We also reexamined the induction of
IFN-, which is the best-known activator of macrophages
(12). We examined the roles of TNF- and IL-1 in the
pathogenesis of pneumococcal bacteremia through in vivo neutralization
via administration of polyclonal antibody to TNF- or IL-1.
20°C until cytokine enzyme-linked
immunosorbent assays were performed. TNF-, IL-1, and IL-6
concentrations in the plasma of infected mice were measured with mouse
Quantikine M Immunoassay kits (R&D Systems, Inc., Minneapolis, Minn.)
according to the manufacturer's instructions. Numbers of CFU per
milliliter of blood and cytokine levels for groups of mice were
expressed as geometric means with standard errors. Statistical
differences between treated and control groups were calculated with the
Wilcoxon two-sample rank test.
on levels of
TNF-, IL-1, and IL-6 in plasma.
Mice were placed into four
experimental groups consisting of six mice each. Two groups received
103 U of polyclonal rabbit anti-mouse TNF- antibody
(Genzyme, Cambridge, Mass.), diluted with Ringer's solution to a
volume of 200 µl, by intraperitoneal injection, and two control
groups received injections of equivalent volumes of Ringer's solution.
One hour later, one group that received anti-TNF- antibody and one
control group (untreated mice) were infected i.v. with strain D39. The other anti-TNF- antibody-treated group and untreated group were infected with strain PLN. Samples of blood for determination of CFU and
cytokine levels were obtained over a period of 42 h postchallenge (Fig. 1).
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FIG. 1.
Effects of anti-TNF- antibody on infection with D39
and PLN. The geometric means (±standard errors) of CFU per ml of blood
(A) and TNF- (B), IL-1 (C), and IL-6 (D) per ml of plasma were
determined for groups of six mice, which either were untreated or
received 103 U of anti-TNF- antibody 1 h prior to
i.v. challenge with 5 × 104 CFU of D39 or PLN. The
absence of standard error bars indicates that the standard error was
too small to be depicted. The 20-h time point for untreated mice
infected with D39 includes data from the five surviving mice. All mice
infected with D39 died prior to the 42-h time point. The 42-h time
point for mice infected with PLN that received anti-TNF- antibody
includes data from the two survivors. The lower limit of detection of
each cytokine was 0.5 log pg/ml. Data points plotted at this level
indicate that the plasma samples contained no detectable cytokine. The
lower limit of detection of pneumococci was 2.0 log CFU per ml.
in plasma at any time point. However, levels of TNF- in plasma were
detected in untreated mice at 12 and 20 h after challenge with D39
(Fig. 1B). The fact that levels of TNF- in plasma were observed only
in mice infected with D39 may have been due to the much higher CFU
levels in mice infected with D39 than in those infected with PLN.
Measurable levels of TNF- in plasma were observed only in mice
infected with D39 once the CFU levels had reached 5 × 107. In mice infected with PLN, the numbers of CFU in the
blood did not exceed 1.3 × 106 during the same period
of observation (Fig. 1A).
In mice infected with D39, the increase in levels of TNF- in plasma
between 12 and 20 h was significant at P = 0.0087. The administration of antibody to TNF- was shown to effectively
eliminate the appearance of TNF- in the plasma of mice challenged
with D39. This finding demonstrated that the anti-TNF- antibody
treatment used was able to neutralize TNF- in vivo as expected
(15).
Effect of administration of antibody to TNF- on the levels of
bacteremia and mouse survival times postinfection with D39 and
PLN.
In Fig. 1A, it is apparent that D39 caused exponential sepsis
and rapid death, whereas the concentration of PLN in the blood of
untreated mice leveled off around 106 CFU/ml of blood as
expected (3). The mean CFU levels of PLN in the blood of
anti-TNF--treated mice were 10-fold higher at 12 h, 295-fold
higher at 20 h, and 140-fold higher at 42 h than those of
untreated mice. The differences at 12 and 20 h were significant at
P = 0.0022. A valid statistical comparison of CFU
levels could not be made at the 42-h time point, because there were
only two survivors in the anti-TNF--treated group challenged with
PLN. Mice infected with PLN died significantly (P = 0.0022) sooner if they were treated with anti-TNF- antibody (1.7 mean days of survival) than if they were untreated (5.8 mean days of
survival) (Fig. 2A).
|
antibody
had essentially no effect on the level of bacteremia or survival time
of mice (Fig. 1A and 2A). The CFU levels of D39 did not differ between
the untreated and anti-TNF- antibody-treated mice. The median
survival time of mice challenged with D39 was 0.9 days for both the
anti-TNF- antibody-treated and untreated groups of mice. Thus,
although the treatment of mice with antibody to TNF- abolished their
ability to limit the growth of PLN pneumococci in the blood and
resulted in decreased survival times of mice, it had no effect on
infections with D39. The inability of anti-TNF- treatment to affect
the level of CFU or survival time of D39-infected mice may be an
indication that D39 is already growing at its maximum in vivo rate in
untreated mice.
The observation that anti-TNF- antibody treatment enhanced
bacteremia in mice infected with PLN demonstrates that the protective host response generated during infection with PLN is dependent on
TNF-. This result was particularly interesting, since mice infected
with PLN did not have measurable (<3 pg/ml) levels of TNF- in
plasma at 12, 24, or 40 h. One interpretation of this observation
is that the effect of TNF- on host resistance may be systemic but
occurs at levels below our experimental limit of detection. A more
likely interpretation is that TNF- has local effects in the spleen
and other sites of blood filtration without leading to detectable
levels in plasma.
Effect of administration of antibody to TNF- on levels of
IL-1 and IL-6 in plasma.
Levels of IL-1 in plasma were
observed in all mice infected with PLN or D39 at the 12- and 20-h time
points, regardless of whether they received antibody to TNF- (Fig.
1C). At the 12- and 20-h time points, the levels of IL-1 observed in
untreated mice infected with D39 were higher (P = 0.015 and P = 0.0043, respectively) than those of the
anti-TNF- antibody-treated mice, a finding that is consistent with
earlier studies indicating that elevations in TNF- can lead to
elevated IL-1 levels (9). Among mice challenged with PLN,
there was no significant difference in the levels of IL-1 in plasma
between the anti-TNF- antibody-treated and untreated groups at any
time point. This result indicates that inducers other than TNF- were
probably responsible for IL-1 production in the PLN-infected mice,
which, unlike D39-infected mice, had no detectable TNF- in their
blood.
antibody-treated mice, had measurable IL-6 levels. This difference in
IL-6 levels was not statistically significant. In mice infected with
D39, the untreated group exhibited significantly higher levels of IL-6
in plasma than the anti-TNF- antibody-treated group at the 12- and
20-h time points (P = 0.0022 and P = 0.0043, respectively). These effects of anti-TNF- antibody on IL-6
levels are consistent with past results showing that elevations in
TNF- can lead to elevated levels of IL-6 (1, 9).
Interpretation of the effect of treatment with anti-TNF- antibody on
IL-1 and IL-6 levels is complicated by the fact that anti-TNF-
antibody leads to increased levels of infection at the same time it
probably reduces the local TNF- levels. The failure of anti-TNF-
antibody to lead to low levels of IL-1 and IL-6 may thus be due to a
compensating TNF--independent stimulation resulting from high levels
of infection. When the levels of IL-1 and IL-6 were normalized for
CFU levels, both cytokines were significantly higher in untreated mice
than in mice that received anti-TNF- antibody (data not shown). In
any case, IL-1 and IL-6 are probably not important in the
TNF--mediated host resistance to infection seen in PLN mice, because
the levels of IL-1 and IL-6 are approximately the same with or
without TNF- treatment.
Effect of administration of antibody to IL-1 on levels of
IL-1 and IL-6 in plasma in mice infected with PLN.
To further
test the possible role of IL-1 and IL-6 in host immunity elicited by
infection with PLN, five CBA/N mice received 300 µg of polyclonal
rabbit anti-mouse IL-1 (Genzyme, Cambridge, Mass.) diluted in 200 µl of normal rabbit serum (NRS), by intraperitoneal injection 1 h prior to challenge with PLN. Control mice received an equal volume of
NRS or Ringer's lactate solution. The levels of IL-1 in plasma of
infected mice treated with anti-IL-1 antibody did not differ
significantly from those of mice not treated with anti-IL-1 antibody
(Fig. 3B). In Fig. 3, the untreated
controls represent pooled data from mice that received NRS or Ringer's solution, since these two treatments did not yield statistically different results. Although levels of IL-1 in plasma were not significantly affected, anti-IL-1 treatment blocked the production of measurable levels of IL-6 in plasma (Fig. 3C). Thus, it appeared that the antibody to IL-1 may have interfered with the biologic activity of IL-1, even though it did not affect its level in plasma
as detected by ELISA.
|
Effect of administration of antibody to IL-1 on bacteremia and
survival times of mice infected with PLN.
The CFU levels of strain
PLN in the blood of anti-IL-1 antibody-treated mice did not differ
significantly over the first 24 h postchallenge from those of mice
not treated with anti-IL-1 antibody (Fig. 3A). However, the survival
times of anti-IL-1 antibody-treated mice (4.8 mean days) were
significantly shorter than those of untreated mice that received NRS
(11.6 mean days, P = 0.016) or Ringer's solution (10.4 mean days, P = 0.031) (Fig. 2B). Thus, although IL-1
did not appear to play a role in controlling bacteremia during the
first 24 h, it did appear to be important in the survival of mice
beyond 5 days postinfection. These data suggest that the mechanisms
involved in regulating bacteremia in mice infected with PLN during the
first 24 h may be different from those affecting eventual
survival. Moreover, the failure of IL-6 to play a role in bacteremia
during the first 24 h is also consistent with the fact that it
does not reach maximal levels until at least 20 h, whereas the
difference in bacteremia caused by PLN between untreated mice and mice
that received anti-TNF- antibody is apparent by 12 h.
has been used successfully to
block the biologic effects of IL-1 in mouse models of meningitis and
collagen-induced arthritis (10, 13, 14, 17), although its
effect on levels of IL-1 in plasma in those studies was not reported.
Measurement of other cytokines.
In a separate experiment, we
examined the levels of IL-2, IL-4, IL-5, IL-10, and IFN- in plasma
at 12 and 20 h postinfection with D39 or PLN in untreated mice.
Assays were conducted by previously described methods (16).
The cytokines IL-2, IL-4, IL-5, and IL-10 were detected in only a small
minority of the mice and showed no relationship to the disease process.
As expected from our previous study (3), IFN- was
observed only in mice infected with D39, and then only when they were
extremely septic (5 × 107 CFU/ml of blood or
greater). IFN- was not observed in mice infected with PLN, but we
did not obtain blood samples just prior to death, since these mice
survive for variable lengths of time and the exact time of death is
difficult to predict. Thus, while the data from these surveys do not
rule out roles for IL-2, IL-4, IL-5, IL-10, or IFN-, they do fail to
provide any evidence implicating these cytokines in host immunity
elicited by infections with either D39 or PLN pneumococci.
Relationship of these results to those obtained in a pulmonary
infection model.
Our observation that the administration of
antibody to TNF- increases the virulence of PLN is consistent with a
recent report on the effect of TNF- antibody on bacteremic pneumonia
in mice (15). Systemic administration of antibody to TNF-
to mice infected intranasally with capsular type 19 pneumococci
resulted in the reduction of TNF- in plasma to undetectable levels,
increased the levels of CFU in the blood, and decreased the survival
time of the mice (15). Our study and that of Takashima et
al. (15) point to the importance of TNF--mediated host
responses in resistance to pneumococcal infection. Our studies used
capsular type 2 wild-type strain D39, which is much more virulent in
mice than strains of capsular type 19 (8), which were used
by Takashima et al. (15). Differences in the genetic
backgrounds of the pneumococci and the inbred strains of mice used, as
well as differences in the route of challenge, may have contributed to
the fact that we failed to see a role for TNF- in the resistance to
wild-type pneumococci, whereas we saw a strong role for
TNF- in resistance that developed during infections with a
less-virulent pneumolysin-deficient strain.
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ACKNOWLEDGMENTS |
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This work was supported by NIH grant AI21548 to D.E.B. K.A.B. was supported by NIH training grant AI07051.
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FOOTNOTES |
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* Corresponding author. Mailing address: BBRB 658, Box 10, University of Alabama at Birmingham, Birmingham, AL 35294-2170. Phone: (205) 934-6595. Fax: (205) 934-0605. E-mail: dbriles{at}uab.edu.
Present address: Department of Molecular Genetics and Biochemistry,
University of Pittsburgh School of Medicine, Pittsburgh, PA 15261.
Editor: V. A. Fischetti
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Infect Immun, February 1998, p. 839-842, Vol. 66, No. 2
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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