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Next Article 
Infection and Immunity, April 1999, p. 1539-1546, Vol. 67, No. 4
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Febrile-Range Temperature Modifies Early Systemic Tumor Necrosis
Factor Alpha Expression in Mice Challenged with Bacterial
Endotoxin
Qingqi
Jiang,1,2
Louis
DeTolla,3
Nico
van
Rooijen,4
Ishwar S.
Singh,1
Bridget
Fitzgerald,1,5
Michael M.
Lipsky,2
Andrew S.
Kane,2
Alan S.
Cross,6 and
Jeffrey D.
Hasday1,2,5,7,*
Division of Pulmonary and Critical Care
Medicine1 and Division of Infectious
Disease,6 Department of Medicine,
Department of Pathology,2 and Program of
Comparative Medicine,3 University of
Maryland School of Medicine, UMAB Cytokine Core
Laboratory,5 and Medicine and Research
Services of the Baltimore VA Medical
Center,7 Baltimore, Maryland 21201, and
Department of Cell Biology and Immunology, Vrije
Universiteit, Amsterdam, The Netherlands4
Received 20 July 1998/Returned for modification 5 October
1998/Accepted 25 November 1998
 |
ABSTRACT |
Fever improves survival in acute infections, but the effects of
increased core temperature on host defenses are poorly understood. Tumor necrosis factor alpha (TNF-
) is an early activator of host defenses and a major endogenous pyrogen. TNF- expression is
essential for survival in bacterial infections but, if disregulated,
can cause tissue injury. In this study, we show that passively
increasing core temperature in mice from the basal (36.5 to 37.5°C)
to the febrile (39.5 to 40°C) range modifies systemic TNF-
expression in response to bacterial endotoxin (lipopolysaccharide). The
early TNF- secretion rate is enhanced, but the duration of maximal TNF- production is shortened. We identified Kupffer cells as the
predominant source of the excess TNF- production in the warmer animals. The enhanced early TNF- production observed at the higher temperature in vivo could not be demonstrated in isolated Kupffer cells
or in precision-cut liver slices in vitro, indicating the participation
of indirect pathways. Therefore, expression of the endogenous pyrogen
TNF- is regulated by increments in core temperature during fever,
generating an enhanced early, self-limited TNF- pulse.
| |
INTRODUCTION |
The beneficial effects of fever in
bacterial, fungal, and viral infections have been widely reported
(reviewed in reference 22). Fever accelerates the
resolution of human viral infections (12, 39) and
shigellosis (28) and is positively correlated with survival
in patients with gram-negative bacteremia (7, 39). Studies
of induced hyperthermia in infected animals have provided evidence that
an increase in body temperature may enhance host defenses. For example,
housing herpesvirus-infected mice in a 38°C ambient environment
increased their core temperature by approximately 2°C and increased
survival to 100% compared with 0% survival in mice maintained at
a normal laboratory temperature (1). Bell and Moore
(2) reported similar protection by passive warming of
rabies virus-infected mice. However, the mechanisms through which an
increase in core temperature can improve survival in the infected host
are incompletely understood.
Tumor necrosis factor alpha (TNF-) is an early and essential
activator of host defenses (9, 10, 30); however,
inappropriate TNF- expression can cause multiorgan failure, shock,
and death (41). This apparent paradox has led to the
evolution of redundant regulation of TNF- expression. We previously
reported that raising incubation temperature from basal (37°C) to
febrile (38.5 to 40°C) levels reduced the duration of
lipopolysaccharide (LPS)-induced TNF- secretion in
macrophages in vitro (13, 14). However, the
ability of fever to regulate TNF- expression in vivo has not
been clearly determined. To address this question, we developed a mouse
model in which endogenous thermoregulation was suspended with
anesthesia and core temperature was rigorously controlled by immersion
in a constant-temperature water bath. Based on our in vitro
observations, we predicted that raising core temperature to
febrile levels would attenuate systemic TNF- production in vivo. We
found that increasing core temperature from basal (36.5 to 37.5°C) to
febrile (39.5 to 40°C) ranges immediately before or coincident with
LPS challenge reduced the duration of TNF- production but
surprisingly enhanced the rate of early TNF- production by
Kupffer cells, leading to a self-limited TNF- pulse in the warmer animals.
| |
MATERIALS AND METHODS |
Temperature control.
LPS purified from Escherichia
coli 0111:B4 prepared according to the Boivin method was obtained
from Difco (Detroit, Mich.). Preparation of LPS by this method
preserves more of the associated proteins than does preparation by
methods that make use of phenol (11, 35). Six- to
eight-week-old male CD-1 mice weighing 25 to 30 g were purchased
from Harlan-Sprague Co. (Indianapolis, Ind.), housed in the University
of Maryland, Baltimore, animal facility under the supervision of a
full-time veterinarian, and used within 4 weeks. All animal protocols
were approved by the Institutional Animal Care and Use Committee of the
University of Maryland, Baltimore. Mice were anesthetized
subcutaneously with tribromoethanol (Sigma). The anesthetized animals
were suspended in water baths (VWR; temperature variation, <0.2°C)
to the level of the axillae. Body temperature was continuously
monitored with rectal thermistors. When body temperature reached bath
temperature, 0.25 ml of either LPS or vehicle (pyrogen-free saline) was
administered as an intraperitoneal (i.p.) injection. To control for the
effects of anesthesia and water immersion, we also studied a group of conscious, unrestrained mice at normal laboratory temperatures (22 to
24°C). To model endotoxemia or bacteremia in the setting of
established infection in febrile hosts, we increased core temperature to febrile levels before administering LPS. The basal core temperature range in conscious mice was 36.5 to 37.5°C but fell to ambient levels
within 30 min of induction of anesthesia. In the temperature-controlled mice, core temperature reached water bath temperature in less than 10 min and varied by <0.2°C during the experiments. To avoid the
influence of diurnal cycling, all experiments were started at
approximately the same time each day (between 8:00 a.m. and 10:00
a.m.).
Plasma TNF- and LPS levels.
Mouse TNF- was measured by
a standard two-antibody enzyme-linked immunosorbent assay (ELISA) with
a commercial antibody pair and a recombinant standard (Endogen, Boston,
Mass.), a biotin-streptavidin-peroxidase detection system (Research
Diagnostics Inc., Flanders, N.J.), and a commercial substrate
preparation (Dako, Carpinteria, Calif.). The mouse TNF- ELISA had a
lower detection limit of 3 pg/ml and measured predominantly free,
biologically active TNF-. The results of the TNF- ELISA
correlated with the measurement of TNF- activity by an L929 cell
bioassay. In preliminary experiments, ELISA results were confirmed by
the L929 cell bioassay. LPS was analyzed by a commercial colorimetric
Limulus amebocyte lysate assay (Associates of Cape Cod,
Falmouth, Mass.) with a minimal detection limit of 10 pg/ml. Clearance
of circulating TNF- was determined by measuring the clearance of
exogenous human TNF- levels in temperature-controlled, LPS-challenged mice. Mice received 1 ng of recombinant human TNF- (Endogen) via the tail vein, heparinized blood was sequentially collected from the retro-orbital plexus, and the concentration of human
TNF- in plasma was measured by an ELISA with a monoclonal antibody
pair specific for human TNF- (Endogen). This ELISA had a lower
detection limit of 1 pg/ml for human TNF- and showed no
cross-reactivity with 10 ng of mouse TNF- per ml. The half-life of
circulating human TNF- was calculated with an iterative exponential curve-fitting algorithm (Deltagraph; Deltapoint).
Organ-specific TNF- expression.
Organs were collected and
snap frozen after the circulatory system was flushed with 10 ml of
4°C phosphate-buffered saline containing protease inhibitors (4 mM
EDTA, 1 mM phenylmethylsulfonyl fluoride, and leupeptin at 1 µg/ml),
injected through the left ventricle and drained from the left atrium.
Organs were powdered under liquid nitrogen, homogenized in 1 ml of
lysing buffer (150 mM NaCl, 25 mM Tris [pH 7.4], 1% Nonidet P-40, 4 mM EDTA, protease inhibitors), and cleared by centrifugation. Total
protein concentrations in organ homogenates were measured with a
commercial reagent (Bio-Rad, Mountain View, Calif.) and with bovine
serum albumin (Sigma) as a standard. To minimize the background signal
from endogenous biotin-containing proteins, 50 µl of a 3-mg/ml avidin
solution (Sigma) was added to 470 µl of homogenate, and an ELISA was
performed as described above except for a 20-min incubation with 20 µg of free biotin (Sigma) per ml added between the sample incubation and the addition of the detecting antibody. This method reduced background noise by >99% without affecting the specific cytokine signal. Cytokine concentrations in organ homogenates were standardized to total protein concentrations.
Immunostaining for TNF-.
Formalin-fixed,
paraffin-embedded, 8-µm-thick liver sections were incubated overnight
with a 1:400 dilution of rabbit anti-mouse TNF- antiserum (Genzyme,
Cambridge, Mass.). TNF- was detected with biotinylated goat
anti-rabbit immunoglobulin G (Dako) and an avidin-biotin complex
detection system (Vector, Burlingame, Calif.) in accordance with the
manufacturer's protocol. Groups of three animals were studied.
In vivo Kupffer cell depletion.
Liposome-encapsulated
clodronate (0.1 ml) prepared as previously described (42)
was injected via the tail vein 2 days prior to temperature controlling
and LPS challenge. Control mice received 0.1 ml of pyrogen-free,
sterile saline via tail vein injection. This method has been shown by
rigorous histochemical analysis to deplete predominantly Kupffer cells
and less predominantly splenic macrophages and to spare circulating
monocytes and pulmonary and peritoneal macrophages (42).
Macrophage isolation and preparation of precision-cut liver
slices.
Raw 264.7 macrophages were obtained from the American Type
Culture Collection (Rockville, Md.) and maintained in RPMI 1640 supplemented with 10 mM HEPES (pH 7.3), 1 mM sodium pyruvate, 2 mM
L-glutamine, 50 µg of streptomycin per ml, 50 U of
penicillin per ml, and 10% heat-inactivated fetal calf serum (FCS;
Hyclone, Logan, Utah) (CRPMI). Peritoneal macrophages were elicited by injecting mice with 1 ml of thioglycolate broth (Sigma) i.p. 4 days
prior to sacrifice. Following sacrifice by anesthesia and cervical
dislocation, cells were harvested by peritoneal lavage with 5 ml of
4°C FCS-free CRPMI and collected by centrifugation at 600 × g for 10 min. The macrophages were purified by adherence to
plastic. The macrophages were preincubated with CRPMI-10% FCS at 37 or 40°C for 30 min and stimulated with 100 ng of LPS per ml, and
culture supernatants were sequentially analyzed for TNF- concentrations by an ELISA. Kupffer cells were isolated from livers by
collagenase digestion and Nycodenz gradient centrifugation as
previously described by ten Hagen et al. (40), except that Kupffer cells were purified by differential adherence in FCS-free CRPMI
for 30 min (36) rather than by elutriation. Based on the morphologic appearance of Diff-Quik (Baxter Scientific Products, Miami, Fla.)-stained cells, the monolayers comprised >90%
Kupffer cells. The monolayers were preincubated with
CRPMI-10% FCS at 37 or 40°C for 30 min and stimulated with 5 µg of LPS per ml, and TNF- concentrations in culture supernatants
were sequentially analyzed by an ELISA. The viability of all macrophage
cultures was determined to be >95% by trypan blue dye exclusion.
Precision-cut liver slices were prepared by cutting 175-µm-thick
slices from 8-mm cores of liver tissue with a Krumdieck tissue slicer
(Alabama Research and Development, Munford, Ala.) as previously described (24). The slices were cultured in CRPMI-10% FCS
with continuous shaking (27, 37), preincubated at 37 or
40°C for 30 min, and stimulated with 50 µg of LPS per ml, and
supernatants were sequentially analyzed for TNF- concentrations. All
solutions used for the isolation and culturing of Kupffer cells and
liver slices contained 2 µg of polymyxin B (Sigma) per ml to prevent inadvertent activation by contaminating LPS. Evaporation was minimized by filling the outer wells of each culture plate with sterile water and
sealing them with Parafilm. Volume loss was <5% over 24 h and
was not different in the 37 and 40°C culture wells.
Data analysis.
All data are presented as means ± standard errors (SE). Differences among groups were tested by a
Fisher protected least-squares difference test applied to a one-way
analysis of variance. Survival was analyzed with a Gehan-Wilcoxon test
of a Kaplan-Meier plot.
| |
RESULTS |
Influence of core temperature on circulating levels of
TNF-.
We initially compared LPS-induced TNF-
expression in mice temperature controlled at 37 and 40°C. Treatment
i.p. with 50 µg of LPS induced the appearance of circulating
TNF- in both groups of mice. As we anticipated, based on our in
vitro studies (13, 34a), plasma TNF- levels peaked
and began to decline earlier in the 40°C mice (Fig.
1A), indicating a shorter duration of
TNF- expression in the warmer mice. However, plasma TNF-
peaked at 2.2-fold-higher levels in the 40°C mice. The clearance of
circulating TNF-, as estimated by the half-life of an
intravenous bolus of exogenous human TNF-, was comparable in the
37 and 40°C mice (data not shown). Taken together, these data suggest
that the early TNF- production rate was greater but that the
duration of maximal TNF- expression was shorter in the warmer
mice. The net result of these two temperature-dependent effects is an
accelerated and enhanced but self-limited pulse of systemic TNF-
expression in the 40°C mice.
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FIG. 1.
Effects of temperature controlling on plasma TNF-
expression. (A) Kinetics of TNF- expression. Male CD-1 mice were
temperature controlled by anesthesia with subcutaneous tribromoethanol
and immersion in 37 or 40°C constant-temperature water baths. When
the core temperature measured by a rectal thermistor probe reached the
bath temperature (5 to 10 min), mice were injected i.p. with 50 µg of
LPS. Control mice (not temperature controlled) were injected with LPS
but remained conscious at a normal ambient temperature (22 to 24°C).
Groups of six mice were sacrificed just before and 1, 2, or 3 h
after LPS injection, and plasma TNF- concentrations (conc.) were
measured by an ELISA. Data are means ± SE. The asterisk indicates
that the P value for 40°C mice versus 37°C mice or
control mice was <0.02. (B) LPS dose response. Groups of five mice
were temperature controlled at 37 or 40°C, injected i.p. with the
indicated doses of LPS, and sacrificed 1 h later for quantitation
of plasma TNF- concentrations. An asterisk indicates that the
P value for 40°C mice versus 37°C mice was <0.01. (C)
Effects of core temperature on LPS-induced mortality. Groups of 16 mice
were temperature controlled at 37 or 40°C and injected i.p. with 250 µg of LPS, and temperature controlling was continued for 3 h.
The mice were allowed to recover, and survival was assessed over the
next 5 days. Survival was analyzed with a Gehan-Wilcoxon test of a
Kaplan-Meier plot (P, 0.198). (D) Effects of intermediate
temperatures on TNF- expression. Groups of five mice were
temperature controlled at the indicated temperatures, injected i.p.
with 50 µg of LPS, and sacrificed 1 h later for quantitation of
plasma TNF- concentrations. An asterisk indicates that the
P value for mice at the indicated temperature versus 37°C
mice at the same time point was <0.01.
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The temperature-dependent enhancement of TNF- expression was
greater as the LPS dose was increased (Fig. 1B). While the LPS dose-response curve for plasma TNF- expression was flat between 50- and 250-µg doses in the 37°C mice, as previously described (27), the LPS dose-response curve remained steeply positive over this range in the 40°C mice. While TNF- is protective in the infected host (10, 30), it is also a central mediator of
LPS-induced shock and death (3). In mice treated with 250 µg of LPS, survival time tended to be shorter in the 40°C than in
the 37°C animals, but the difference did not reach statistical significance (P, 0.198) (Fig. 1C).
To define the threshold temperature required to amplify early
TNF- expression, we measured plasma TNF- levels 1 h
after LPS treatment in 37 and 40°C mice (Fig. 1D). The threshold for increasing plasma TNF- levels consistently occurred between 39 and 39.5°C, a temperature that is within the normal murine febrile range (19). The effect of temperature controlling on
TNF- expression was critically dependent on the timing of the
core temperature increase relative to the LPS challenge. While
increasing the core temperature to 40°C coincident with LPS
treatment modified TNF- expression, delaying the temperature
increase until 30 min after LPS challenge completely abrogated this
effect (data not shown). To determine if anesthesia
influenced the temperature-dependent, LPS-induced
TNF- expression, plasma TNF- levels were measured 1 h after treatment with 250 µg of LPS in conscious mice
maintained in 38 or 24°C cages. Core temperatures were 39.7 and
37.1°C in the two groups of animals, and plasma TNF- levels
were 5.6-fold higher in the warmer mice than in the mice housed in
24°C cages.
Major tissue site of temperature-dependent TNF-
expression.
To determine if the excess plasma TNF- in the
40°C mice was generated by circulating leukocytes, we
measured TNF- expression in blood in vitro. Heparinized
blood was collected from 37 and 40°C mice 30 min after LPS challenge
and incubated at 37 or 40°C (Fig. 2A).
The peak TNF- concentrations generated in blood samples in vitro
were <1% of the peak plasma TNF- levels attained in the mice
in vivo (Fig. 2A) and were not affected by changes in either in vivo
core temperature or in vitro incubation temperature, excluding
circulating blood leukocytes as the predominant source of circulating
TNF- in either group of mice.
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FIG. 2.
Source of excess TNF- production in mice at
40°C. (A) Effect of temperature on TNF- generation in blood ex
vivo. Groups of five mice were temperature controlled at either 37 or
40°C and given a single 50-µg dose of LPS i.p., and temperature
controlling was continued for 30 min. Heparinized (10 U/ml) blood was
collected and incubated at the indicated in vitro temperature. At the
indicated times, samples were diluted with 3 volumes of 4°C CRPMI,
cells were removed by centrifugation, and TNF- concentrations in
the diluted plasma were measured by an ELISA. The broken line indicates
the peak plasma TNF- levels reached 1 h after LPS treatment
in vivo in 40°C mice. (B) Effects of core temperature on
organ-associated and peritoneal fluid TNF- concentrations
(conc.). Male CD-1 mice were anesthetized, temperature controlled at 37 or 40°C, and injected i.p. with 50 µg of LPS, and groups of five
animals were sacrificed just before (0 h) or 1 or 3 h after LPS
injection. Control (not temperature controlled) animals received LPS
but remained conscious at a normal ambient temperature (22 to 24°C).
After sacrifice, the circulation was flushed with 0.9% NaCl containing
protease inhibitors, and the lungs, kidneys, liver, and spleen were
snap frozen in liquid nitrogen. The frozen organs were powdered under
liquid nitrogen, homogenized, and cleared by centrifugation, and
TNF- concentrations in the supernatants were measured by an
ELISA. Levels were standardized to total protein concentrations. For
quantitation of TNF- in peritoneal fluid, groups of five mice
were temperature controlled at either 37 or 40°C and injected i.p.
with 250 µg of LPS, and temperature controlling was continued until
sacrifice. Peritoneal lavage was done with 5 ml of FCS-free CRPMI, the
cells were removed by centrifugation, and TNF- concentrations
were measured by an ELISA. Data are means ± SE. The asterisk
indicates that the P value for 40°C mice versus 37°C and
control mice was <0.05.
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|
TNF- is not uniformly expressed during endotoxemia
(18). To determine if fever alters the tissue distribution
of TNF- and to identify the potential tissue sources of the
excess circulating TNF- in the 40°C mice, we measured
TNF- in peritoneal lavage fluid and homogenates of liver,
spleen, lung, and kidney tissues obtained from LPS-challenged,
temperature-controlled animals (Fig. 2B). These organs were selected
for study because they either are important sources of systemic
TNF- expression (15) or are frequently injured in
sepsis (6). As previously reported (15), the
liver appeared to be the predominant source of TNF- after LPS
challenge. The peak total TNF- content of the liver (93 ± 21 ng) was 2 to 3 orders of magnitude higher than the total TNF- content of the spleen (0.10 ± 0.02 ng), lungs (0.06 ± 0.04 ng), kidneys (1.1 ± 0.1 ng), or peritoneal lavage fluid
(0.98 ± 0.28 ng). Furthermore, of the organs analyzed, the liver
was the only organ in which TNF- accumulated more rapidly in the
40°C than in the 37°C mice, parallelling the changes in plasma
TNF- levels and suggesting that the liver was the predominant
source of the excess circulating TNF- in the 40°C mice.
Kupffer cells are the predominant source of liver-associated and
circulating TNF-.
Among hepatic cells, Kupffer cells have
the greatest capacity to secrete TNF-, but marginated
intravascular leukocytes and hepatocytes are also capable of
TNF- expression (27). To identify the cellular source
of the excess hepatic TNF- expression in the 40°C mice, we
performed an immunohistochemical analysis for TNF- in livers
from 37 and 40°C mice 1 h after LPS challenge. Not only was
TNF- staining limited almost exclusively to Kupffer cells, but
also the proportion of TNF--staining Kupffer cells was threefold
higher in the 40°C than in the 37°C mice (Fig.
3A).
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FIG. 3.
Source of excess hepatic TNF- production in mice
at 40°C. (A) TNF- immunostaining. Mice were temperature
controlled at 37 or 40°C, treated i.p. with 50 µg of LPS, and
sacrificed 1 h later. Livers were analyzed for TNF- by
immunostaining with a rabbit anti-mouse TNF- antibody and a
streptavidin-biotin detection system. Representative micrographs from a
total of three experiments are shown. Kupffer cells staining positively
for TNF- are indicated by arrowheads. (B) Kupffer cell depletion
in vivo. Kupffer cells were depleted in groups of four mice by
administration of a single 0.1-ml dose of liposome-encapsulated
clodronate intravenously 2 days prior to LPS challenge. Control mice
received 0.1 ml of saline. Mice were temperature controlled at 37 or
40°C, injected i.p. with 50 µg of LPS, and sacrificed 1 h
later. TNF- concentrations in plasma and liver homogenates were
quantified by an ELISA. TNF- concentrations in liver homogenates
were standardized to total protein concentrations. Data are means ± SE. An asterisk indicates that the P value for 40°C
versus 37°C mice was <0.05; a double dagger indicates that the
P value for mice with depletion of Kupffer cells versus
control mice was <0.01.
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|
To confirm that Kupffer cells were the predominant source of the excess
hepatic and circulating TNF- present in 40°C animals, we
analyzed LPS-induced TNF- expression in temperature-controlled animals after depleting their Kupffer cells with intravenous
liposome-encapsulated clodronate (42). This treatment
reduced LPS-induced hepatic and plasma TNF- levels by 87 and
91%, respectively, in the 37°C mice compared with the sham-depleted
37°C control mice and reduced excess hepatic and plasma TNF-
levels by 99 and 81%, respectively, in the 40°C mice compared with
the sham-depleted mice (Fig. 3B). These data indicate that Kupffer
cells are virtually the sole source of the excess hepatic TNF-
and the major source of the excess circulating TNF- in the
40°C mice.
Mechanisms of temperature-dependent regulation of TNF-
expression.
While the earlier peak and decline in Kupffer cell
TNF- production in the warmer mice was consistent with our
previous in vitro studies (13), enhancement of the early
TNF- secretion rate was novel for in vivo studies. To determine
if the enhanced TNF- expression in the 40°C mice in vivo was
caused by a unique response of Kupffer cells to higher temperatures, we
analyzed the effects of 37 versus 40°C incubation temperatures on
TNF- secretion in freshly isolated Kupffer cell cultures (Fig.
4A), in thioglycolate-elicited peritoneal
macrophages (Fig. 4B), and in the Raw 264.7 macrophage cell line (Fig.
4C). The TNF- secretion patterns of all three macrophage types
were similar. TNF- expression peaked and declined earlier in the
40°C than in the 37°C cells, but there were no detectable
differences in the initial TNF- secretion rate between the 37 and the 40°C cells. These data suggest that raising core temperature
directly limits the duration of Kupffer cell TNF- production but
that the increase in early Kupffer cell TNF- production in vivo
involves indirect mechanisms and is probably dependent on the in vivo
environment.
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FIG. 4.
Direct effect of increased incubation temperature on
TNF- expression in vitro. (A to C) Effects of febrile-level
incubation temperature on TNF- expression by macrophages in
vitro. Kupffer cells (106 per well containing 1 ml of
CRPMI-10% FCS) were isolated from the liver by collagenase digestion
and plastic adherence and then preincubated at 37 or 40°C for 30 min,
and 5 µg of LPS per ml was added. Peritoneal macrophages were
obtained 4 days after i.p. injection of 1 ml of thioglycolate broth and
purified by plastic adherence. Raw 264.7 macrophages and peritoneal
macrophages (0.5 × 106 per well containing 1 ml of
medium) were preincubated at 37 or 40°C for 30 min, and 100 ng of LPS
per ml was added. Cell supernatants were sequentially collected, and
TNF- concentrations (conc.) were measured by an ELISA. Data are
means ± SE. An asterisk indicates that the P value for
40°C versus 37°C cells was <0.05. (D) Effects of febrile-level
incubation temperature on TNF- expression in precision-cut liver
slices in vitro. Liver slices (175 µm thick) were cut from 8-mm
tissue cores with a Krumdieck tissue slicer. The slices were
preincubated at 37 or 40°C for 30 min with continuous shaking. LPS
(50 µg/ml) was added, and supernatants were sequentially collected
for analysis of TNF- concentrations by an ELISA. The asterisk is
as defined for panel A.
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We evaluated three possible mechanisms for the Kupffer
cell-specific increase in TNF- expression in the 40°C mice,
including: (i) enhanced absorption of LPS from the peritoneum, (ii)
modification of interactions among Kupffer cells and other cell types
in the hepatic microenvironment, and (iii) release of a
circulating factor that enhances Kupffer cell TNF- expression.
The plasma LPS concentrations 1 h after i.p. injection of 250 µg
of LPS were virtually identical in the 37 and 40°C mice (2.34 ± 0.43 versus 2.29 ± 0.45 µg/ml; P, 0.89), suggesting
that systemic LPS absorption was not increased in the 40°C mice.
However, the possibility that both absorption and blood clearance of
LPS were enhanced proportionately at 40°C remains to be excluded.
To determine if the enhanced TNF- expression was mediated
through complex interactions among Kupffer cells and neighboring cells,
we analyzed TNF- expression in freshly isolated
precision-cut liver slices, in which the local
microenvironment of the Kupffer cells is preserved (Fig. 4D).
The temperature dependence of LPS-induced TNF- expression in the
liver slices and the isolated Kupffer cells (Fig. 4A) was similar. In
both systems, Kupffer cells failed to demonstrate enhanced TNF-
expression during a 40°C incubation, suggesting that a factor(s)
beyond the local hepatic microenvironment is required for this effect.
To determine if increasing the core temperature induces the release of
a circulating factor that enhances Kupffer cell TNF- expression,
we stimulated liver slices with 50 µg of LPS per ml in the presence
of 20% (vol/vol) plasma obtained from 37 or 40°C temperature-controlled mice 30 min after they were challenged with LPS
(Table 1). This time point was chosen
because amplification of TNF- expression in vivo required that
the core temperature be increased within 30 min of LPS challenge. The
addition of plasma from the 40°C mice did not enhance TNF-
secretion in the liver slices, suggesting that the enhanced TNF-
production which occurred in the 40°C mice could not be ascribed to a
stable circulating factor.
| |
DISCUSSION |
We (13, 14) and others (16, 38) have
reported that TNF- expression by mononuclear phagocytes is
inhibited upon exposure to febrile-range temperatures in vitro. The
temperature-dependent inhibition of TNF- expression, which is
caused by the reduced stability of TNF- mRNA (13) and
the premature deactivation of TNF- transcription
(34a), occurs in the absence of heat shock protein 70 expression (13). In this study, we have extended these
observations by analyzing the effects of febrile-range temperature on
TNF- expression in vivo. We found that increasing the core temperature from basal to febrile (40°C) levels preceding LPS challenge caused TNF- production to be accelerated and enhanced but also to peak and decline earlier. This schedule models recurrent endotoxemia and bacteremia during fever, which often occur during serious bacterial infections (34). Three previous studies
reported that increasing the core temperature in rodents either reduced (8, 21) or had no effect (4) on circulating
TNF- expression. However, in these studies the animals were
warmed to temperatures above the normal febrile range and within the
heat shock range (
41°C). Furthermore, the core temperature increase
in these studies either preceded LPS challenge by 6 to 7 h
(4) or 24 h (21) or followed LPS challenge
(8). In our model, delaying the increase in the core
temperature for 30 min after the injection of LPS abrogated the
enhancement of TNF- expression. These data suggest that the effect of increasing the core temperature on TNF-
expression may be determined by the magnitude of the temperature
increase and the timing of the LPS challenge relative to the core
temperature change.
Our temperature-controlled mouse model was designed to isolate the
effects of febrile temperature itself from the processes that generate
fever. The use of anesthetized animals avoided the effects of physical
stress (23) and provided more rapid and precise control of
the core temperature. While anesthetic agents may potentially influence
the acute-phase response, two lines of evidence suggested that the
anesthetic agents used in this study did not interfere with the
evaluation of temperature-dependent TNF- expression in the
temperature-controlled mice. First, circulating and organ-associated
TNF- levels were comparable in the 37°C temperature-controlled
mice and in the conscious control animals with similar core
temperatures. Second, the effects of passive warming on TNF-
expression were similar in anesthetized and conscious mice.
Furthermore, all temperature-controlled mice were treated with the
same anesthesia protocol.
The enhanced early TNF- pulse reflects an increased initial rate
of TNF- generation but a decreased duration of maximal TNF- expression in the warmer animals. The decreased duration of
TNF- expression appears to be a direct response of Kupffer cells
to the higher temperature and is similar to temperature-dependent responses in other mononuclear phagocytes (13, 14, 16, 38). In contrast, the enhanced early rate of TNF- generation by
Kupffer cells at febrile core temperatures could not be reconstituted in vitro with freshly isolated Kupffer cells or with liver slices, in
which local cell-cell interactions are preserved. We failed to detect a
circulating enhancer of hepatic TNF- expression in the warmer
animals but have not excluded a labile circulating or intrahepatic
enhancer of TNF- expression. While circulating levels of LPS in
mice at the two temperatures were comparable, modification of LPS
bioactivity or distribution within the liver may account for the
temperature-dependent modification of TNF- expression.
Within the liver, endothelial cells, hepatocytes, and Kupffer
cells can each bind LPS via scavenger receptors (31). While TNF- expression is predominantly limited to Kupffer
cells, endothelial cells and hepatocytes contribute to LPS clearance. The intrahepatic distribution of LPS is influenced by its
modification, primarily by binding to soluble proteins. For
example, when complexed with ApoE, LPS is redirected from Kupffer
cells to hepatocytes in vivo (31). On the other hand, when
complexed with LPS-binding protein, LPS efficiently binds to CD14
(43), the membrane-bound LPS receptor on Kupffer cells. The
influence of changes in temperature on the modification and
intrahepatic distribution of LPS has not been reported.
While our results obtained with LPS-challenged mice provide proof of
the principle that increases in core temperature to the usual febrile
range can modify an early inflammatory response, caution must be
exercised in applying these observations to actual bacterial
infections. While LPS is clearly the predominant gram-negative bacterial activation signal for macrophages (11, 26), there are important differences in the biological behaviors of the purified LPS used in the present study and bacterium-associated LPS, including tissue distribution (17), specific activity (26),
and sensitivity to inhibition by polymyxin B (26). The
method used to purify LPS also affects its biological activity
(11, 35). In the rat, purified LPS and LPS associated with
viable E. coli localizes exclusively to hepatic Kupffer
cells 1 h after intravenous injection, but the purified LPS is
partially redistributed to hepatocytes by 8 h after
administration. Since TNF- generation peaked within 1 to 2 h after LPS challenge in the present study, the difference in the late
intrahepatic distribution of different forms of LPS is not likely to be
relevant to our results. Antibiotic treatment causes the release from
gram-negative bacteria of soluble LPS (26), which may be an
important inducer of sepsis during gram-negative bacterial infections.
While LPS is the predominant macrophage activator in the supernatants
of antibiotic-treated gram-negative bacteria (26), this form
of LPS may be functionally distinct from chemically purified LPS.
Experiments comparing the temperature dependence of cytokine expression
induced by purified, native, and bacterium-associated forms of LPS are
in progress.
While fever is generally considered to be beneficial in the infected
host, we found that survival after LPS challenge was not improved and
tended to be shorter in the 40°C mice than in the 37°C mice. Plasma
TNF- levels were 13-fold higher in the warmer animals. Increases
in core temperature are associated with increases in metabolic rate and
cardiac index (29, 33). While TNF- is essential for
survival in the infected host (10, 30), the mice were
challenged with LPS, a nonreplicating agonist, rather than with viable
pathogens. Thus, enhanced antimicrobial defenses would not be
beneficial, and the increased risk of tissue injury might reduce
survival in the 40°C mice after LPS challenge. Furthermore, while
pretreating animals with heat shock has been reported to improve
survival after LPS challenge (8, 20), the effects of heat
shock and febrile temperatures are distinct (13, 14).
The enhanced TNF- expression in the warmer mice was novel and
raised the question of what survival advantage could possibly be
provided by enhancing TNF- generation during elevations of core
temperature. We believe that this temperature-dependent response may
have evolved as part of a host strategy to refine the regulation of
systemic innate defenses. While the entry of LPS into the circulation from sites of gram-negative infection signals the host to enhance the
innate defenses which protect against microbial dissemination (25,
32), LPS also continuously enters the circulation from the gut
lumen under normal physiological conditions (5).
Furthermore, LPS entry from the gut can increase during benign
conditions (5). Thus, the context in which LPS is presented
to the host may be as important as the LPS signal itself in directing
an appropriate host response. We showed that core temperature may serve
this function by modifying the stimulus-response relationship for LPS and TNF- in hepatic Kupffer cells. Variations in core
temperature within a narrow range may coregulate TNF-
expression, increasing the amplitude of the TNF- response to
bacterial pathogens when the risk of bacterial dissemination is
high (e.g., during an acute infection) and decreasing the magnitude of
the TNF- response when the risk of bacterial dissemination is
low. The early deactivation of TNF- expression in febrile hosts
may be an important counterregulatory mechanism that prevents prolonged
exposure to high TNF- levels. We conclude that the protective
effects of fever in the infected host (1, 2, 28, 39) may be
mediated in part by appropriate modification of the TNF-
response to circulating bacterial products.
| |
ACKNOWLEDGMENTS |
We thank Matthew Kluger, Simeon Goldblum, Barry Handwerger,
Sheldon E. Greisman, Phillip Mackowiak, and Rose Viscardi for valuable
time and helpful comments and Timothy Chen for assistance with the
statistical analysis.
This work was supported by VA Merit Review grant 128444284-0005.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 10 N. Greene
St., Rm. 3D127, Baltimore, MD 21201. Phone: 410-605-7197. Fax:
410-605-7915. E-mail: jhasday{at}umaryland.edu.
Editor:
J. R. McGhee
| |
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Abstract
Introduction
