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Department of Physiology, University of Tennessee, Memphis, Tennessee 38163
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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We reported recently that the complement (C) system may play a role in the febrile response of guinea pigs to intravenous lipopolysaccharide (LPS) administration because C depletion abolished the LPS-induced rise in core temperature (Tc). The present study was designed to investigate further the relation between C reduction [induced by cobra venom factor (CVF); 20, 50, 100, and 200 U/animal iv] and the fever of adult, conscious guinea pigs produced by LPS injected intravenously (2 µg/kg) or intraperitoneally (8, 16, 32 µg/kg) 18 h after CVF; control animals received pyrogen-free saline. Serum C levels were measured as total hemolytic C activity before and 18 h after CVF injection and expressed as CH100 units. In other experiments, serum C levels were determined at various intervals after the intravenous and intraperitoneal injections at different doses of LPS alone. LPS produced fevers generally of similar heights but of different onset latencies and durations, depending on the dose and route of administration. CVF caused dose-related reductions in serum C, from ~1,136 U to below detection. These reductions proportionately attenuated the fevers induced by intraperitoneal LPS, but not by intravenous LPS. Intravenous and intraperitoneal LPS per se caused reductions in serum C of 25 and 40%, respectively, indicating activation of the C cascade. These decreases were transient, however, occurring early during the febrile rise ~30 min after LPS injection. These data thus support the notion that the C system may be critically involved in the febrile response of guinea pigs to systemic, particularly intraperitoneal, LPS.
anaphylatoxins; lipopolysaccharides; macrophages; interleukin-1; tumor necrosis factor; prostaglandin E2
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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IN GUINEA PIGS, a characteristically biphasic fever is
induced within 10-15 min after the intravenous injection of
lipopolysaccharide (LPS; the protein-free form of bacterial endotoxin)
at a dose of 2 µg/kg, concomitantly with an increase in the levels of
both circulating and brain
PGE2 (a putative
mediator of fever; Ref. 4). It is now generally thought that these
effects are not mediated by LPS itself, but by secondarily host-derived
cytokines or endogenous pyrogens, among which tumor necrosis factor-
(TNF-), interleukin (IL)-1
, and IL-6 are
considered to be particularly important (12). These are thought to be
produced mainly by mononuclear phagocytes that release them into the
bloodstream for transport to and action in the brain, specifically the
preoptic area (POA) of the anterior hypothalamus (4). A difficulty with
this notion, however, is that the first of these cytokines to be
released, TNF-, is not detectable in blood exiting the liver (the
major source of these cytokines in response to circulating LPS) until, at the earliest, 30 min after the intravenous injection of LPS (19,
25). Moreover, very recently, evidence has been adduced that TNF-
may not have a role in the initiation (first phase) of LPS fever in
guinea pigs, but only in its maintenance (second phase) (41). This
would suggest, therefore, that circulating cytokines may not be the
direct stimuli that initiate the body temperature and preoptic
PGE2 rises in response to
intravenously injected LPS. But, on the other hand, threshold
concentrations of relevant pyrogenic cytokines could be reached in the
vicinity of their producing cells and activate appropriate local
sensors, if they existed, well before these cytokines would be
detectable in the general circulation. Indeed, the rapidity of the
febrile response to intravenous LPS would imply a neural rather than a humoral communications pathway between peripheral endogenous pyrogens and the POA.
Because circulating LPS is cleared primarily by hepatic macrophages
[Kupffer cells (Kc); Ref. 32], it is conceivable that vagal
afferents originating in the liver may convey their released pyrogenic
messages to the brain. In support, bilateral truncal subdiaphragmatic
vagotomy (40, 43, 54) and, more particularly, selective hepatic
vagotomy (45), block the febrile responses of guinea pigs and rats,
respectively, to intravenous LPS. However, whereas the binding of LPS
to its receptors in Kc occurs very rapidly, the subsequent half-maximal
induction time of TNF- requires a minimum of 20 min of contact with
LPS in vitro (29); the half-maximal induction time of the other
pyrogenic cytokines is still longer, i.e., longer in all cases than the
latency of fever onset. We considered, therefore, whether the stimulus
for Kc cytokine production might be provided not by LPS per se but by
secondary mediators occurring in almost immediate reaction to the
presence of LPS with blood. The intravenous administration of LPS
triggers within 2 min the complement (C) cascade via both the classical
and alternative pathways, resulting in the production in blood of the
anaphylatoxic C fragments, C4a, C3a, and C5a, and of surface-bound and
fluid-phase C3b and iC3b (reviewed in Ref. 52). Kc express the
receptors for various C-derived fragments (23), and the production of cytokines and PGE2 by Kc and other
phagocytes is initiated after their addition (1, 7, 22a, 39).
Consequently, we hypothesized that the rapid onset of intravenous
LPS-induced fever may be mediated via intravascular C activation by LPS
and subsequent Kc stimulation by C anaphylatoxins. In support, we
reported recently (44) that guinea pigs rendered hypocomplementemic or
Kc deficient by prior treatment with cobra venom factor (CVF) or
gadolinium chloride, respectively, exhibited body core temperature
(Tc) falls instead of rises and
greatly attenuated elevations of preoptic
PGE2 after intravenous LPS
compared with untreated controls. Thus the onset of LPS fever may
indeed critically depend on the activation of intravascular C and the
subsequent stimulation of Kc by C fragments.
Although C was implicated previously in the fever caused by antigen-antibody complexes (34), to our knowledge ours was the first demonstration of its possible involvement in LPS-induced fever. There are no consistent reports in the literature, however, that human patients hereditarily deficient in one or another anaphylatoxic C do not fever normally during infections of various etiologies, albeit the severity of their effector responses is often attenuated (37). To preclude, therefore, that our finding might have represented only an unusual situation, the present study was designed to verify, under more detailed conditions, the putative relationship between C and the fever of guinea pigs produced by LPS. To this end, we injected graded doses of LPS intravenously or intraperitoneally and compared their effects on the febrile courses of animals with different degrees of CVF-induced decomplementation and, in other experiments, on the plasma C levels of C-sufficient animals at various intervals over the duration of their fevers. The results suggested a greater dependence on C when LPS was injected intraperitoneally than when it was administered intravenously.
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METHODS |
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Animals
Male Hartley guinea pigs (301-350 g; Charles River Laboratories, Wilmington, MA) were used in these experiments. The animals were quarantined for 1 wk, three to a cage, before any experimental use. Tap water and food (Agway Prolab guinea pig diet) were available ad libitum. The ambient temperature (Ta) in the animal room was 23 ± 1°C, and light and darkness were alternated, with light on from 0600 to 1800. After quarantine, to moderate the psychological stress associated with the experiments, the animals were trained to the experimental procedure for 1 wk (daily for 4 h) by handling and placement in individual, locally fabricated, wire-mesh stocks designed to prevent their turning around and to minimize their forward and backward movements without causing restraint stress.Drugs
CVF (Naja naja kaouthia) was purchased from Calbiochem-Novabiochem (San Diego, CA). LPS was Salmonella enteritidis LPS B (batch no. 651628, Difco Laboratories, Detroit, MI) suspended in pyrogen-free saline (PFS). The vehicle for all the solutions was PFS (0.9% NaCl, USP; Abbott Laboratories, Chicago, IL). Heparin was purchased from Elkins-Sinn (Cherry Hill, NJ).Surgery
All the animals received the antibiotic gentamicin sulfate (6 mg/kg im) prophylatically before any surgical procedure. Under ketamine-xylazine (35-5 mg/kg im) anesthesia, a siliconized catheter (ID 0.020 in., OD 0.037 in.; Baxter Healthcare, McGraw Park, IL) prefilled with heparinized (10 IU/ml) PFS was inserted through the left jugular vein into the superior vena cava of each guinea pig. The distal end of the catheter was passed subcutaneously and exteriorized on the top of the head, knotted, rolled into a coil, and placed inside a protective polypropylene shield that was fixed to the skull with dental acrylic cement and four self-tapping, miniature stainless steel screws. Gentamicin sulfate was administered during the following 2 days. The catheters were flushed with heparinized (3 IU/ml) PFS daily; 48 h before an experiment, heparinized PFS was replaced with PFS only (55).Temperature Recording
Seven days after this surgery, the guinea pigs, fully conscious, were loosely restrained in their individual wire mesh cages at Ta 23 ± 1°C. The Tc of the guinea pigs were monitored constantly and recorded at 2-min intervals for the duration of the experiments on a Macintosh Plus lMb microcomputer through an analog-to-digital converter using precalibrated copper-constantan thermocouples inserted 5 cm into the colon. The data were displayed digitally on a monitor, printed on an ImageWriter printer, and stored on a diskette. A 90-min stabilization period to achieve thermal equilibrium preceded all the measurements. To obviate possible effects of circadian variations, the experiments were begun at the same time of day (0830).Assay of Serum Total Hemolytic C Activity (CH100)
At fixed intervals, blood (200 µl) was withdrawn through the venous catheter, clotted in ice for 30 min, and centrifuged (3,000 rpm, 4°C, 10 min) to obtain the serum. The samples were then stored at
70°C until assayed. For an assay, 5 µl of serum were added to wells placed in agarose gel containing standardized sheep
erythrocytes sensitized with hemolysin (kit RC001; The Binding Site,
San Diego, CA). Plates were incubated for 18 h at 4°C and then for
1 h at 37°C. The areas of the zones of hemolysis around each well
(radial immunodiffusion) were measured by imaging these zones with a
charge-coupled device (CCD) camera, then scanning the images and
calculating their relative optical densities using the National
Institutes of Health (NIH) Image version 1.61 for analyzing
electrophoretic gels. These values were converted to
CH100 units (one unit being the
amount of C that lyses 100% of the erythrocytes) by interpolation from
calibration curves plotted using the manufacturer's standard, diluted
from neat to 1:32 (minimum sensitivity, 32 CH100 units).
Experiments
The following experiments were conducted.Experiment 1. To determine, before all the other experiments, the conditions that would achieve graded, sustained reductions in serum C levels, guinea pigs received through their preinserted venous catheters either PFS (0.6 ml) or, initially, 20 U of CVF in 0.6 ml of PFS per animal; blood samples were collected for serum CH100 assays at 6, 12, 18, and 24 h and daily for the following 5 days thereafter. Because this experiment established that 18 h post-CVF was a suitable interval to achieve the desired effect (please see RESULTS), in the subsequent dose-response tests, 50, 100, and 200 U/animal were injected (the latter 2 doses in 2 boluses, namely, the first bolus at 50 U and the remaining dose in a second bolus delivered 2 h later to minimize the acute effects of decomplementation; Ref. 44), and blood was withdrawn at 18 h only.
Experiment 2. To determine the effect of different degrees of hypocomplementemia on the febrile response to LPS, guinea pigs were injected through their intravenous catheters with PFS or CVF at 20, 50, 100, or 200 U/animal, as in experiment 1. Eighteen hours later, they received, either through the same catheters or via sterile 23-gauge needles directly into the peritoneum, a bolus injection of 0.2 ml of PFS or, respectively, 2, 8, or 16 µg of LPS (in 0.2 ml of PFS)/kg body wt. Blood was withdrawn immediately before the LPS administration to assess the serum total hemolytic C activity. These intraperitoneal doses were chosen on the basis of preliminary dose-response studies designed to determine those over the range from 2 to 32 µg/kg body wt that would most closely mimic the febrile courses evoked by 2 µg of LPS/kg iv (please see RESULTS).
Experiment 3. To determine whether the small pyrogenic doses of LPS delivered in the preceding experiments do in fact, like larger doses (52), activate the C cascade, i.e., induce the consumption of C, guinea pigs were injected through their preinserted venous catheters or by needle into the peritoneum with, respectively, 2, 8, or 16 µg, or 8, 16, or 32 µg of LPS (in 0.2 ml of PFS)/kg body wt. Blood for C activity measurements was sampled at 0, 2, 5, 10, 20, 30, 120, and 360 min after intravenous PFS or LPS and at 0, 15, 30, 60, 120, and 360 min after intraperitoneal PFS or LPS.
Experiment 4. Because in the present study the effect of 200 U of CVF on the febrile response to 2 µg iv of LPS/kg was different from that observed in our previous study (44) in which the guinea pigs were instrumented with, in addition to intravenous catheters, stereotaxically preimplanted intra-POA microdialysis probes, an a posteriori experiment was conducted in which the responses of animals with and without such intracerebral devices were compared. Thus guinea pigs were prepared exactly as described under Surgery above, i.e., with an intravenous catheter alone or according to the procedure described previously (44), with, first, stereotaxically implanted guide cannulas in the left medial POA followed 4 days later by the insertion of the catheters into the jugular vein. CVF (200 U/animal) was delivered intravenously in the nonprobe group 7 days and in the probe group 10 days after the only or first surgery, respectively, and LPS (2 µg/kg) was injected intravenously 18 h later. No blood was collected in this series.
Experiment 5. To verify whether LPS
activates macrophages preponderately in the liver, irrespective of its
route of administration, we injected 0.3 ml of FITC-labeled
Escherichia coli LPS (Sigma Chemical,
St. Louis, MO; 3 µg/µl of PFS/animal; this dose is in excess of
pyrogenic doses in guinea pigs) or fluorescein sodium salt (0.013 µg · µl
PFS
1 · animal1;
this dose is equivalent to the amount of fluorescein in the FITC-LPS
conjugate) through their preinserted venous catheters or by needle into
the peritoneal cavity of conscious guinea pigs. Fifteen or sixty
minutes after these injections, the animals were anesthetized with
ketamine-xylazine (35-5 mg/kg im) and perfused through a cannula inserted into their left ventricle with,
successively, 200 ml of heparinized (1,000 IU/ml) PFS for 15 min and
250 ml of neutral 10% Formalin for 20 min. The guinea pigs were then laparotomized, and their livers were excised and stored in neutral 10%
Formalin for later cryostat sectioning. One hundred-micrometer-thick slices were prepared for confocal laser scanning microscopy (Biorad 1024 Lasersharp) using a laser line of 488 lambda for green color only.
Statistical Analyses
The results are reported here as means ± SE. The values of Tc are changes from basal values [Tci (initial), the Tc at 2-min intervals averaged over the last 10 min of the preceding 90-min stabilization period] plotted at 6-min intervals. Fever indexes were derived from the area under the 6-h fever curve by imaging with a CCD camera, then scanning the images using NIH Image version 1.61. These values were converted to degree Celsius per hour by interpolation from a calibrated standard area that was 1°C high and 1-h long. Serum total hemolytic C activities were determined as absolute CH100 units and are expressed here as relative changes normalized to their initial values. Student's paired t-test was used to compare pre (initial Tc, CH100, etc.) and post (maximal Tc, CH100, etc.) values within treatment groups. Differences in Tc or CH100 between treatment groups were evaluated by a repeated-measures analysis of variance model, in which factor 1 was the between-groups factor (the experimental treatment) and factor 2 was the within-subject factor (the different sampling periods). Each variable was considered to be independent. The strength of correlation between serum C reductions and fever indexes was calculated from the regression lines. Latencies of fever onset were determined as the intervals (in min) between the time of LPS injection and that of the first Tc rise that continued uninterruptedly >0.5°C. The 5% level of probability was accepted as statistically significant.| |
RESULTS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Experiment 1
The intravenous administration of CVF very rapidly caused a profound reduction in the guinea pigs' serum CH100 activities from their initial 1,136 ± 67 U level (Fig. 1B). The extent and duration of this reduction were both dose dependent, that is, CH100 decreased to its lowest level commensurate with the given CVF dose within 6 h, then progressively recovered over the following 6 days, the rate of recovery being slower the higher the dose. This is illustrated for the lowest dose of CVF tested, 20 U/animal, in Fig. 1A. To minimize potential circadian effects on the variables being measured, we traditionally begin our experiments at 0830, administering the first treatment 90 min later, i.e., at ~1000 (please see METHODS). On the basis of the above findings, we selected 18 h post-CVF as the time point to be coincident with the 1000 treatment in the subsequent studies. Hence, CVF was injected at 1600 on the previous day. The effects of various doses of CVF on serum CH100 activities extant 18 h after drug administration are illustrated in Fig. 1B. The variations are due to differential sensitivities inherent among the animals and divergences among the lots of CVF and CH100 assay plates received.
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Experiment 2
LPS intravenously at 2 µg/kg induced characteristically biphasic, ~1.3°C, fevers with onset latencies of ~11 min (Fig. 2B, PFS). The first febrile peak occurred ~48 min after LPS administration and the second 84 min after the first. The return to Tci values was gradual but essentially completed by 270 min after LPS injection. The Tc of guinea pigs given PFS intravenously did not vary significantly over the same 6-h duration (Fig. 2A, PFS). CVF given intravenously 18 h before similarly had no apparent effect on the Tc of the guinea pigs that received PFS subsequently (Fig. 2A, CVFs). Likewise, pretreatment with CVF did not demonstrably alter the febrile response to LPS of these animals (Fig. 2B, CVFs), albeit it appeared that at one CVF dose, 50 U/guinea pig (Fig. 2B, CVF 50), both the first and second febrile rises were attenuated and the postfebrile recovery stabilized at a lower level than that of the PFS group. In view of this disparity, this series was replicated; hence, the larger n value. However, the onset latency, time to first peak, and febrile course proved not significantly different in this larger group compared with the other LPS-treated groups. Higher LPS doses were not tested in this phase of the experiment, because 2 µg/kg is already a nearly maximally effective pyrogenic intravenous dose in guinea pigs (see Ref. 3).
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Although the fever heights produced by intraperitoneal LPS were similar
for all the doses we tested (2, 4, 8, 16, and 32 µg/kg), the patterns
and durations of the fevers were different, such that the fever indexes
increased progressively at 2 and 4, were maximal at 8, then decreased
again at 16 and 32 µg/kg (not illustrated). The onset latencies, on
the other hand, steadily decreased as the LPS doses were increased.
These data are summarized in Table 1.
Although the onset latency of intraperitoneal LPS at 8 µg/kg was
significantly longer than that of intravenous LPS at 2 µg/kg, its
other characteristics were quite similar (Figs.
2B and
3B, PFS,
respectively). We therefore chose this dose as the standard for our
subsequent intraperitoneal LPS studies.
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Figure 3 depicts the effects of intraperitoneal PFS (Fig. 3A) and LPS (Fig. 3B) on the Tc of the animals pretreated intravenously with PFS or the four doses of CVF employed 18 h before their injections. As before, the CVF pretreatment had no demonstrable effect on the Tc of the animals that received PFS. On the other hand, it dose dependently reduced (20, 50, and 100 U) or completely prevented (200 U) the LPS fever. Indeed, both the change in maximal Tc (not illustrated) and the fever indexes (Fig. 3C) of the CVF-pretreated guinea pigs in this experiment were strongly correlated (r = 0.614; n = 23) with the reduction in serum C activity. Decomplementation also dose dependently delayed the onset of fever (Fig. 3B).
To characterize further the susceptibility of intraperitoneally
injected LPS fever to decomplementation, guinea pigs were injected
intraperitoneally with 16 µg · LPS1 · kg
body wt1 18 h after CVF at
50, 100, and 200 U. The fevers evoked were quite similar to those
produced by 8 µg/kg (Fig. 3B, PFS),
except that the onset latency after the larger dose was shorter than after the lower (Fig. 4, PFS and Table 1).
Whereas, as described above, CVF pretreatment from 20 U upward dose
dependently both delayed the onset and reduced the height of the
febrile response to 8 µg of LPS/kg ip, it required 100 U of CVF to
begin to effect the same result (Fig. 4, CVFs), i.e.,
the higher the endotoxic stimulus, the more resistant the fever to C
reduction.
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Experiment 3
The fevers produced by intravenous LPS at 2, 8, and 16 µg/kg were essentially similar; the response to 8 µg/kg is illustrated in Fig. 5A. This dose caused the Tc rise with the quickest onset and the highest first maximum. It also produced a significant, ~40%, decrease in serum CH100 activity 30 min after its administration (Fig. 5B). This dose, however, had no effect on C levels at any other sampled time over the febrile course. Two and sixteen micrograms of LPS per kilogram body weight, on the other hand, did not induce statistically significant changes in CH100 at any time (not illustrated). The intravenous injection of PFS caused no change in Tc and CH100 over the same time course.
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LPS intraperitoneally at 8, 16, and 32 µg/kg induced fevers with progressively shorter latencies and different patterns, but essentially similar maxima, as already described (Table 1); the response to 8 µg/kg is depicted in Fig. 5A. No changes in serum CH100 activities were noted in response to these treatments, except a 25% reduction at 30 min after 8 µg (Fig. 5B). The similarities in the profiles of CH100 activities after 8 µg of LPS intravenously and intraperitoneally are noteworthy. PFS intraperitoneally had no effect on either of these measured variables.
Experiment 4
In confirmation of our previous identical experiments (44), the febrile responses of guinea pigs pretreated with 200 U of CVF intravenously 18 h before receiving 2 µg of LPS/kg iv were abolished and converted into ~0.9°C hypothermic responses if the animals had been prepared 10 days before CVF administration with unilaterally implanted intrapreoptic microdialysis probes, but not altered if their brains were intact (Fig. 6). Thus the integrity of the POA would seem to be a determinant of the direction of the thermal response to intravenous LPS in otherwise similarly hypocomplementemic guinea pigs. The febrile responses to LPS of C-sufficient guinea pigs were not influenced by the preimplantation of microdialysis probes unilaterally into the POA compared with intact animals (not illustrated; see Ref. 44).
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Experiment 5
FITC-labeled LPS was detectable as patches of granular fluorescence 15 min after its intravenous injection within, presumptively, aggregated Kc in the liver sinusoids (Fig. 7B). "Presumptively" because, due to a difficulty inherent in the confocal microscope itself, that is, despite its high resolution, fluorescence emitted above or below the focal plane results in blurs and halos, impeding discerning whether the fluorescence was in or on the Kc; this difficulty is compounded when the labeled cells are aggregated. At 60 min, fluorescent patches also appeared in the hepatocytes (Fig. 7C). In stark contrast, no FITC labeling appeared at 15 and 60 min in any part of the guinea pigs' livers after intraperitoneal FITC-LPS (Fig. 7, E and F). Only normal autofluorescence was observed after the intravenous or intraperitoneal administration of fluorescein sodium salt at a dose equivalent to its amount in the FITC-LPS conjugate (Fig. 7, A and D).
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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The reduction in C in this study was accomplished, as in our previous
study (44), by use of CVF, which activates the alternative pathway of
the C cascade (10). It forms a complex with factor B, CVF Bb,
which is functionally analogous to C3b Bb, the natural C3
convertase that cleaves catalytically the -chain of C3. The difference between the two compounds is that CVF Bb is highly resistant
to the normal control mechanisms that limit the activity of C3b Bb, so
that fluid-phase C activation continues unabated, drastically depleting
C. Consequently, absent the substrates from which they are produced,
all the subsequent C components are also depleted; hence,
hypocomplementemia results. Since the present data showed, in
confirmation of our earlier observations (44), that CVF-induced
hypocomplementemia, as indicated by a decreased serum
CH100 activity, impaired the
febrile response of conscious guinea pigs to systemic LPS, some or all
of the fragments from C3 to C9 must be important for fever production,
at least in guinea pigs. Unexpectedly, however, this dependence on the
C system was contingent, in turn, on the route of LPS administration;
namely, the febrile response was highly C dependent when LPS was
delivered intraperitoneally, but apparently not so when it was injected intravenously. The reason for this dichotomy is not immediately obvious; an attempt to explicate it will be made later in this section.
It is well established that LPS very rapidly activates the C cascade
(52). Lipid A initiates the classical pathway, and the polysaccharide
region initiates the alternative pathway. Among the C components
consequently generated, C3a, C3b, iC3b, C5a, C5a (desArg) and the
membrane attack complex (C5b-9, in sublytic concentrations) are of
particular interest in our context. Among their multiple inflammatory
activities, they independently induce the production of TNF-,
IL-1, IL-6, and PGE2 by
phagocytic and other cell types (1, 7, 22a, 39, 47). They also amplify
the secretions of TNF- and IL-1 induced by LPS (7). It may be
logically assumed, therefore, that to the extent that the production of
these pyrogenic mediators may be impaired in C-insufficient animals,
their febrile responses will be correspondingly attenuated. Indeed, the
involvement of C in LPS-induced host defense responses is well
documented, and the consequent C activation is associated with the
consumption of C components so that a reduction in their blood
concentrations is observed in many inflammatory diseases (37).
Therapeutic inhibition of C similarly has been shown to arrest the
process of certain diseases (26). The reductions in serum
CH100 observed in the present
study after both intravenous and intraperitoneal LPS (Fig. 5) thus lend
support to an important role for C in fever production, albeit a
limitation of measurements of C levels in serum for assessing its
activation is that only very marked reductions can be reliably
quantified by this technique because C factors are synthesized and
degraded at a very high rate. Consequently, increased utilization of C
caused by pyrogenic doses of LPS is difficult to evaluate precisely
within this background of rapid turnover.
Only few studies have been conducted as yet, however, that examined the
possible role of C specifically in fever production. In one study of
human subjects injected intravenously with low doses of
E. coli LPS, no changes in
anaphylatoxin levels were detected in the plasma, although
Tc and plasma TNF- and IL-6 levels rose after 30-45 min (50). But in another study in humans, the expression of C3b and iC3b receptors (CR1 and CR3) on neutrophils was significantly augmented (36). Upregulation of CR3 was also seen on
rabbit neutrophils within 5 min after exposure to LPS, culminating
within a further 25 min (30). Mickenberg et al. (34) reported that the
total hemolytic C activity and C3 titers of rabbits fell within 5 min
after the intravenous administration of low-dose, soluble
antigen-antibody complexes, in correlation with an attenuated febrile
course. Furthermore, rabbits depleted of C by pretreatment with CVF
exhibited diminished febrile responses in comparison with untreated
controls. These data conform with our own observations using LPS. To
the degree that fever is a manifestation of the hosts' reactions to
infectious stimuli, its reduction under these conditions is in line
with the loss of other host defense functions that are normally
coactivated with fever. These include the inability of C-deficient
animals to enhance phagocytosis, promote chemotaxis, and release
various inflammatory mediators in response to infection (37), albeit
congenitally C-deficient, clinically infected patients can present with
fever (37). However, the pathogenesis of clinical infections is more complicated than represented by the present study, generally involving, in addition to LPS, multiple other factors not incorporating C mediation.
Because it has been demonstrated in vitro that C components trigger the
production of cytokines and PGE2
by macrophages, we had hypothesized that the rapid onset of intravenous
LPS-induced fever may be mediated via the intravascular activation of C
by LPS and the subsequent stimulation of Kc by C-derived fragments to
release these mediators. Kc were favored over other macrophages in this
context because the hepatic macrophages are quantitatively the most
important (Kc constitute 80% of all resident mononuclear phagocytes in
the body) and the liver is the principal source of cytokines liberated
into the bloodstream. Other data pointing to Kc included, in conformity
with the neural hypothesis of fever induction (5, 31), recent findings
that hepatic vagal branch transection inhibits the febrile responses of
rats to intravenous LPS (40, 44, 54), that putative IL-1 receptors
exist on hepatic afferent fibers (21), and that their cell bodies
express c-fos in response to
intravenous LPS (18). It was surprising, therefore, that the fevers
induced by intravenous LPS were evidently C independent (Fig.
2B), whereas those produced by
intraperitoneal LPS were dose dependently sensitive to C reduction
(Fig. 3, B and
C). There is evidence, however, that
the activation of macrophages by LPS for synthetic responses may
proceed by various pathways. Thus CD14 is the predominant LPS receptor
on macrophages. Its activation requires that LPS complexes to
LPS-binding protein (LBP), which is present in normal plasma but absent
in blood-free peritoneal fluid (13, 48). Indeed, only minimal amounts
of LPS-induced cytokines and PGE2
are released in vitro from macrophages in general in the absence of
LBP. If LPS-CD14 interactions are not favored in the peritoneal fluid
because of the absence of LBP and yet fever develops after
intraperitoneal LPS, it may be surmised that a different LPS signaling
system may activate peritoneal macrophages, one that, according to the
present data, may be critically dependent on C. Such a system may be
provided by complement receptors CR3 (CD11b/CD18) and CR4 (CD11c/CD18),
which have been shown also to function as LPS transmembrane receptors
that activate macrophages (24). They recognize iC3b-opsonized
particles, and binding sites for LPS and for iC3b coexist in the same
molecule (56), thus mediating the attachment of iC3b-coated LPS to
macrophages and inducing IL-1 and TNF- synthesis (8). Hence, we
speculate that C fragments, LPS, and iC3b-opsonized LPS, in tandem, may coactivate peritoneal macrophages through these signaling pathways. A
decrease in C fragments for opsonization of LPS would be
expected, therefore, to concentration dependently impede the ability of these macrophages to respond to LPS and to C-derived components. It is
also conceivable, alternatively, that the activation of CR3 and CR4
contributes under these conditions to the migration and adhesion of
peritoneal macrophages to counter-receptors on other cognate cells,
perhaps in perivagal paraganglia (20); cell-to-cell contact could be a
requirement for the subsequent (1 h) induction of IL-1 by such cells
or for its binding to them (21). It may be pertinent in this context
that peripheral nerves express C receptors (51). By contrast, in the
bloodstream, C insufficiency may be less consequential than in the
peritoneal cavity because of the presence of LBP in plasma, allowing
LPS-charged CD14 to generate fever-promoting signals. If substantiated,
this speculative accounting for the differential activation of
intravascular and tissue macrophages by LPS would provide functional
verification of in vitro findings that, as yet, have no defined in vivo corollaries.
It may thus be inferred from the preceding that TNF- and IL-1
could be released by peritoneal macrophages in consequence of the
activation of the C cascade by LPS. However, their production by these
cells requires their transcription and translation, and the time course
of their synthesis in vitro is evidently not any more rapid in response
to C fragments than to LPS stimulation, namely, 1-2 h (7, 8, 22a,
29). In vivo, LPS administered intraperitoneally to rats induced the
expression of IL-1 protein in various immune cells surrounding
abdominal vagal afferents in 45-60 min (20), i.e., quicker than in
vitro. Although this interval was roughly commensurate with the onset
latencies of the fevers thus produced in rats, it was longer than those
produced in our guinea pigs by intraperitoneal LPS at doses of 8 µg/kg or greater (Table 1). This delay would suggest, therefore, at
least insofar as guinea pigs are concerned, that, to the extent that
C-derived fragments could mediate the eventual, enhanced release of
pyrogenic cytokines after LPS (7, 8), their role may not be in the
initiation of the febrile response to intraperitoneal LPS but rather in
its subsequent maintenance. On the other hand, because the onset of these fevers was delayed and their initial rises were attenuated in
proportion to the degree of hypocomplementation, C would appear also to
contribute to the initiation of the febrile response to intraperitoneal
LPS. In view of the short time frame in this study between LPS
injection and fever onset, we would suggest that the febrigenic
triggering mediator thus arising in the peritoneum of guinea pigs may
be constitutively expressed rather than induced de novo. Mast cells are
other peritoneal cell types also responsive to C fragments. Although
they reportedly contain preformed TNF- (22), which could, therefore,
be quickly released for binding to local sensory vagal terminals, it
was recently shown (41) that TNF- probably does not contribute to
the initiation of the febrile response of guinea pigs to LPS; rather,
its role also appears to be associated with the subsequent maintenance
of fever. This would conform with our earlier suggestion.
PGE2 is another product of
macrophages that could rapidly provide the initial signal for fever
onset. Thus C3a and C5a stimulate PGE2 production by, e.g., hepatic
macrophages, within 2 min (39), CVF pretreatment prevents the rise both
in plasma and in intra-POA PGE2
induced by intravenous LPS (14, 44), and
EP3 receptors have recently been
specifically implicated in the febrile response (49); the latter exist
in all the sites where the transduction of peripheral pyrogenic
messages has been proposed to occur (5, 46). There is a caveat,
however: the proposed involvement of PGE2 would be possible only if the
production of PGE2 by C were cyclooxygenase (COX)-2 mediated, because we (28) and others (reviewed
in Ref. 33) have demonstrated that LPS-, IL-1-, and TNF--induced
fevers are strictly dependent on the mediation by this isozyme of
PGE2 synthesis. Because COX-1 null
mutant mice develop normal fevers in response to LPS (28) and COX-2 is
not constitutively expressed in unstimulated macrophages, it follows that PGE2 is probably not the
triggering signal to local neural afferents. Hence, another factor,
quickly released by as yet unspecified C-responsive cells in the
vicinity, could provide this signal, but its identity remains elusive.
The distinct uptake of LPS by Kc depending on its route of administration was somewhat unexpected because numerous previous studies had shown that LPS injected intraperitoneally was recovered in the bloodstream and cleared primarily by the liver. However, this evidence was based on studies in which relatively large doses of LPS were injected (11, 42). Nevertheless, it may be assumed from the present results that the population of phagocytes that accomplishes LPS uptake depends on the dose and route of its administration. Thus, after jugular vein injection, as in this study, LPS appears suddenly at its full dose in the bloodstream. Although pulmonary intravascular macrophages constitute the first filter encountered, the rate of LPS clearance and detoxification by these cells is very slow in rodents (53), so that it overflows into the general circulation. Consequently, neutrophils, monocytes, and other phagocytes within the vasculature, namely, resident sinusoidal hepatic and splenic macrophages, effect the intravascular clearance of LPS; of these, the Kc are believed to assume the greater role (40%) (32, 42). Small percentages of LPS are also taken up by the kidneys, adrenal glands, lungs, and skeletal muscle (17). Kc internalize LPS by absorptive pinocytosis and cleave the sugar side chains of the core oligosaccharide to a uniform length such that the molecule can be passed to hepatocytes for final disposition (14). Our present finding that FITC-LPS is detectable in the liver sinusoids within 15 min and in hepatocytes within 60 min after its intravenous injection corroborates those earlier studies. Despite the effectiveness of this filter, however, because only about one-third of the cardiac output is distributed to the splanchnic organs, intravenously injected LPS recirculates to the liver only one-third of the time and, consequently, in larger doses partially evades first-pass hepatic clearance. Extrahepatic macrophages then also contribute to removing the spillover. This may account for the observations that subdiaphragmatic vagotomy is effective in inhibiting fever only when the intravenous LPS dose is small (40). Intraperitoneal LPS, on the other hand, is thought to be removed principally by way of the lymphatic channels that rest under the diaphragmatic mesothelium. Inspiratory and expiratory diaphragmatic movements open and close the specialized stomata that provide access from the peritoneal cavity to the lymphatic lacunae. These lead to larger intrathoracic lymphatic channels, which, in turn, enter the thoracic duct and drain into the subclavian vein (11). Therefore, in contrast to intravenously injected LPS, intraperitoneally injected LPS appears progressively in the blood. Concomitantly, intraperitoneal LPS is taken up by resident peritoneal macrophages and by macrophages in lymph nodes by receptor-mediated endocytosis and degraded by deacylation of the fatty acids of the lipid component (15, 29); obviously, this portion of the dose injected does not pass into the circulation. Indeed, if the intraperitoneal LPS dose is small, no LPS at all may appear in the circulation (6, 27). This was evidently the case in the present experiments, because no FITC-LPS was detectable in the liver at 15 and 60 min after its intraperitoneal injection.
It is not clear why the same amount of decomplementation attenuated the fevers of the guinea pigs with intrapreoptically implanted microdialysis probes, but did not affect the febrile responses of the brain-intact animals (Fig. 6 and Ref. 43). No plasma C reaches the brain when the blood-brain barrier is intact. Hence, its reduction in plasma should be without effect on the brain. But both C mRNAs and their receptors are significantly upregulated on reactive astrocytes and microglia in response to local injury (38), such as would result from the insertion of a microdialysis probe, as in this study. Although other evidence suggests that the thus breached blood-brain barrier reseals in several hours (2), it is possible that some new capillaries in the region may have a reduced blood-brain barrier and allow plasma proteins to pass into the brain parenchyma and cerebrospinal fluid (35). In that case, CVF might have gained entry and prevented the expression of C by reactive glial cells. It is also possible that the CVF pretreatment per se provoked vascular leakage into the gliotic area surrounding the probe, thus allowing its own passage into the POA and depleting local reactive microglia and other macrophages of C and perhaps, consequently, also downregulating their expression of C receptors. Whatever the mechanism, however, these results would suggest that brain C may also have a role in LPS fever genesis.
Taken together, the present data support the view that LPS-induced fever is dependent, at least in part, on LPS activation of the C cascade; the fever due to LPS delivered intraperitoneally is particularly susceptible to C reduction. The specific events associated with C activation are still unknown, but C-derived components could contribute to the elaboration of pyrogenic cytokines. However, due to the time discrepancy between their rate of synthesis and the latency of fever onset, we speculate that these elicited cytokines are probably not the initial febrigenic trigger. Whether the same factor occurs in the peritoneal fluid and in the bloodstream and whether it provokes the same or different signals also remains to be clarified. But regardless of the particular factor of the C cascade responsible or of its mechanism of action, these data show that C deficiency is associated with lower fevers, indicating a contribution of the C system to the development of intraperitoneal LPS-induced fever.
| |
ACKNOWLEDGEMENTS |
|---|
This work was supported by National Institutes of Neurological Disorders and Stroke Grant NS-34857 to C. M. Blatteis. S. Li was the recipient of a University of Tennessee Neuroscience Center of Excellence postdoctoral award.
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FOOTNOTES |
|---|
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Address for reprint requests and other correspondence: C. M. Blatteis, Dept. of Physiology, Univ. of Tennessee, Memphis, 894 Union Ave., Memphis, TN 38163 (E-mail: blatteis{at}physio1.utmem.edu).
Received 13 November 1998; accepted in final form 21 July 1999.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
|
|---|
1.
Bacle, F.,
N. Haeffner-Cavaillon,
M. Laude,
C. Couturier,
and
M. D. Kazatchkine.
Induction of IL-1 release through stimulation of the C3b/C4b complement receptor type one (CR1, CD35) on human monocytes.
J. Immunol.
144:
147-152,
1990[Abstract].
2.
Benveniste, H.,
and
N. H. Diemer.
Cellular reactions to implantation of a microdialysis tube in the rat hipocampus.
Acta Neuropathol. (Berl.)
74:
234-238,
1987[Medline].
3.
Blatteis, C. M.
Influence of body weight and temperature on the pyrogenic effect of endotoxin in guinea pigs.
Toxicol. Appl. Pharmacol.
29:
249-258,
1974[Medline].
4.
Blatteis, C. M.,
and
E. Sehic.
Prostaglandin E2: a putative fever mediator.
In: Fever: Basic Mechanisms and Management (2nd ed.), edited by P. A. Mackowiak. Philadelphia: Lippincott-Raven, 1997, p. 117-145.
5.
Blatteis, C. M.,
E. Sehic,
and
S. Li.
Afferent pathways of pyrogen signaling.
Ann. NY Acad. Sci.
856:
95-107,
1998
6.
Carlson, D. E.
Adrenocorticotropin correlates strongly with endotoxemia after intravenous but not intraperitoneal inoculations of E. coli.
Shock
7:
65-69,
1997[Medline].
7.
Cavaillon, J.-M.,
C. Fitting,
and
N. Haeffner-Cavaillon.
Recombinant C5a enhances interleukin-1 and tumor necrosis factor release by lipopolysaccharide-stimulated monocytes and macrophages.
Eur. J. Immunol.
20:
253-257,
1990[Medline].
8.
Cavaillon, J.-M.,
and
N. Haeffner-Cavaillon.
Signals involved in interleukin-1 synthesis and release by lipopolysaccharide-stimulated monocytes/macrophages.
Cytokine
2:
313-329,
1990[Medline].
10.
Cochrane, C. G.,
H. J. Müller-Eberhard,
and
B. S. Aikin.
Depletion of plasma complement in vivo by a protein from cobra venom: its effect on various immunological reactions.
J. Immunol.
105:
55-69,
1970
11.
Daniele, R.,
H. Singh,
H. E. Appert,
F. W. Pairent,
and
J. M. Howard.
Lymphatic absorption of intraperitoneal endotoxin in the dog.
Surgery
67:
484-487,
1970[Medline].
12.
Dinarello, C. A.
Cytokines as endogenous pyrogens.
In: Fever: Basic Mechanisms and Management (2nd ed.), edited by P. A. Mackowiak. Philadelphia: Lippincott-Raven, 1997, p. 87-116.
13.
Fenton, M. J.,
and
D. T. Golenbock.
LPS-binding proteins and receptors.
J. Leukoc. Biol.
64:
25-32,
1998[Abstract].
14.
Fink, M. P.,
H. R. Rothschild,
Y. F. Deniz,
and
S. M. Cohn.
Complement depletion by Naja naja cobra venom factor limits prostaglandin release and improves visceral perfusion in porcine endotoxic shock.
J. Trauma
29:
1076-1085,
1989[Medline].
15.
Fox, E. S.,
P. Thomas,
and
S. A. Broitman.
Comparative studies of endotoxin uptake by isolated rat Kupffer and peritoneal cells.
Infect. Immun.
55:
2962-2966,
1987
16.
Fox, E. S.,
P. Thomas,
and
S. A. Broitman.
Clearance of gut-derived endotoxins by the liver. Release and modification of 3H, 14C-lipopolysaccharide by isolated rat Kupffer cells.
Gastroenterology
96:
456-461,
1989[Medline].
17.
Freudenberg, M. A.,
N. Freudenberg,
and
C. Galanos.
Time course of cellular distribution of endotoxin in liver, lungs, and kidneys of rats.
Br. J. Exp. Pathol.
63:
56-65,
1982[Medline].
18.
Gaykema, R. P. A.,
L. E. Goehler,
F. J. H. Tilders,
J. G. J. M. Bol,
M. McGorry,
M. Fleshner,
S. F. Maier,
and
L. R. Watkins.
Bacterial endotoxin induces Fos immunoreactivity in primary afferent neurons of the vagus nerve.
Neuroimmunomodulation
5:
234-240,
1998[Medline].
19.
Givalois, L.,
J. Dornand,
M. Mekaouche,
M. D. Solier,
A. F. Bristow,
G. Ivart,
P. Siaud,
J. Assenmacher,
and
G. Barbanel.
Temporal cascade of plasma level surges in ACTH, corticosterone, and cytokines in endotoxin-challenged rats.
Am. J. Physiol.
266 (Regulatory Integrative Comp. Physiol. 35):
R164-R170,
1994
20.
Goehler, L. E.,
R. P. A. Gaykema,
K. T. Nguyen,
J. E. Lee,
F. J. H. Tilders,
S. F. Maier,
and
L. R. Watkins.
Interleukin-1 in immune cells of the abdominal vagus nerve: a link between immune and nervous systems?
J. Neurosci.
19:
2799-2806,
1999
21.
Goehler, L. E.,
J. K. Relton,
D. Dripps,
R. Keichle,
N. Tartaglia,
S. F. Maier,
and
L. R. Watkins.
Vagal paraganglia bind biotinylated interleukin-1 receptor antagonist: a possible mechanism for immune-to-brain communication.
Brain Res. Bull.
43:
357-364,
1997[Medline].
22.
Gordon, J. R.,
and
S. J. Galli.
Mast cells as a source of both preformed and immunologically inducible TNF-/cachectin.
Nature
346:
274-276,
1990[Medline].
22a.
Haeffner-Cavaillon, N.,
J.-M. Cavaillon,
M. Laude,
and
M. D. Kazatchkine.
C3a (C3a desArg) induces production and release of interleukin-1 by cultured human monocytes.
J. Immunol.
139:
794-799,
1987[Abstract].
23.
Hinglais, N.,
M. D. Kazatchkine,
C. Mandet,
M.-D. Appay,
and
J. Bariety.
Human liver Kupffer cells express CR1, CR3, and CR4 complement receptor antigens. An immunohistochemical study.
Lab. Invest.
61:
509-514,
1989[Medline].
24.
Ingalls, R. R.,
M. A. Arnaout,
R. L. Delude,
S. Flaherty,
R. Savedra, Jr.,
and
D. T. Golenbock.
The CD11/CD18 integrins: characterization of three novel LPS signaling receptors.
Prog. Clin. Biol. Res.
397:
107-117,
1998[Medline].
25.
Jansky, L. S.,
S. Vybiral,
D. Pospisilova,
and
J. Roth.
Production of systemic and hypothalamic cytokines during the early phase of endotoxin fever.
Neuroendocrinology
62:
55-61,
1995[Medline].
26.
Kirchfink, M.
Controlling the complement system in inflammation.
Immunopharmacology
38:
51-62,
1997[Medline].
27.
Lenczowski, M. J.,
A.-M. vanDam,
S. Poole,
J. W. Larrick,
and
F. J. Tilders.
Role of circulating endotoxin and interleukin-6 in the ACTH and corticosterone response to intraperitoneal LPS.
Am. J. Physiol.
273 (Regulatory Integrative Comp. Physiol. 42):
R1870-R1877,
1997
28.
Li, S.,
Y. Wang,
K. Matsumura,
L. Ballou,
S. G. Morham,
and
C. M. Blatteis.
The febrile response to lipopolysaccharide is blocked in cyclooxygenase-2/ but not in cyclooxygenase-1/ mice.
Brain Res.
825:
86-94,
1999[Medline].
29.
Lichtman, S. N.,
J. Wang,
J. C. Zhang,
and
J. J. Lemasters.
Endocytosis and Ca2+ are required for endotoxin-stimulated TNF- release by rat Kupffer cells.
Am. J. Physiol.
271 (Gastrointest. Liver Physiol. 34):
G920-G928,
1996
30.
Lynn, W. A.,
C. R. H. Raetz,
N. Qureshi,
and
D. T. Golenbock.
Lipopolysaccharide-induced stimulation of CD11b/CD18 expression on neutrophils. Evidence of specific receptor-based response and inhibition by lipid A-based antagonists.
J. Immunol.
147:
3072-3079,
1991[Abstract].
31.
Maier, S. F.,
L. E. Goehler,
M. Fleshner,
and
L. R. Watkins.
The role of the vagus nerve in cytokine-to-brain communication.
Ann. NY Acad. Sci.
840:
289-300,
1998
32.
Mathison, J. C.,
and
R. J. Ulevitch.
The clearance, tissue distribution, and cellular localization of intravenously injected lipopolysaccharide in rabbits.
J. Immunol.
123:
2133-2143,
1979
33.
Matsumura, K.,
C. Cao,
Y. Watanabe,
and
Y. Watanabe.
Prostaglandin system in the brain: sites of biosynthesis and sites of action under normal and hyperthermic states.
Prog. Brain Res.
115:
275-295,
1998[Medline].
34.
Mickenberg, I. D.,
R. Snyderman,
R. K. Root,
S. E. Mergenhagen,
and
S. M. Wolff.
The relationshp of complement consumption to immune fever.
J. Immunol.
107:
1466-1476,
1971
35.
Mitchell, J.,
R. O. Weller,
and
H. Evans.
Capillary regeneration following thermal lesions in the mouse cerebral cortex. An ultrastructural study.
Acta Neuropathol. (Berl.)
44:
167-171,
1978[Medline].
36.
Moore, E. D., Jr.,
N. A. Moss,
A. Revhaug,
D. Wilmore,
J. A. Mannick,
and
M. L. Rodrick.
A single dose of endotoxin activates neutrophils without activating complement.
Surgery
102:
200-205,
1987[Medline].
37.
Morgan, B. P.
Complement.
In: Clinical Aspects and Relevance to Disease. New York: Academic, 1990.
38.
Morgan, B. P.,
and
P. Gasque.
Expression of complement in the brain: role in health and disease.
Immunol. Today
17:
461-466,
1996[Medline].
39.
Püschel, G. P.,
U. Hespeling,
M. Opperman,
and
P. Dieter.
Increase in prostanoid formation in rat liver macrophages (Kupffer cells) by human anaphylatoxin C3a.
Hepatology
18:
1516-1521,
1993[Medline].
40.
Romanovsky, A. A.,
C. T. Simons,
M. Szekely,
and
V. A. Kulchitsky.
The vagus nerve in the thermoregulatory response to systemic inflammation.
Am. J. Physiol.
273 (Regulatory Integrative Comp. Physiol. 42):
R407-R413,
1997
41.
Roth, J.,
D. Markin,
B. Störr,
and
E. Zeisberger.
Neutralization of pyrogen-induced tumor necrosis factor by its type 1 soluble receptor in guinea pigs: effects on fever and interleukin-6 release.
J. Physiol. (Lond.)
509:
267-275,
1998
42.
Ruiter, D. J.,
J. van der Meulen,
A. Brouwer,
M. J. R. Hummel,
B. J. Mauw,
J. C. M. van der Ploeg,
and
E. Wisse.
Uptake by liver cells of endotoxin following its intravenous injection.
Lab. Invest.
45:
38-45,
1981[Medline].
43.
Sehic, E.,
and
C. M. Blatteis.
Blockade of lipopolysaccharide-induced fever by subdiaphragmatic vagotomy in guinea pigs.
Brain Res.
726:
160-166,
1996[Medline].
44.
Sehic, E.,
S. Li,
A. L. Ungar,
and
C. M. Blatteis.
Complement reduction impairs the febrile response of guinea pigs to endotoxin.
Am. J. Physiol.
274 (Regulatory Integrative Comp. Physiol. 43):
R1594-R1603,
1998
45.
Simons, C. T.,
V. A. Kulchitsky,
N. Sugimoto,
L. D. Homer,
M. Székely,
and
A. A. Romanovsky.
Signaling the brain in systemic inflammation: which vagal branch is involved in fever genesis?
Am. J. Physiol.
275 (Regulatory Integrative Comp. Physiol. 44):
R63-R68,
1998
46.
Sugimoto, Y.,
R. Shigemoto,
T. Namba,
M. Negishi,
N. Mizuno,
S. Narumiya,
and
A. Ichikawa.
Distribution of the messenger RNA for the prostaglandin E receptor subtype EP3 in the mouse nervous system.
Neuroscience
62:
919-928,
1994[Medline].
47.
Takabayashi, T.,
E. Vannier,
J. F. Burke,
R. G. Tompkins,
J. A. Gelfand,
and
B. D. Clark.
Both C3a and C3a desArg regulate interleukin-6 synthesis in human peripheral blood mononuclear cells.
J. Infect. Dis.
177:
1622-1628,
1998[Medline].
48.
Ulevitch, R. J.,
and
P. S. Tobias.
Receptor-dependent mechanisms of cell stimulation by bacterial endotoxin.
Annu. Rev. Immunol.
13:
437-457,
1995[Medline].
49.
Ushikubi, F.,
E. Segi,
Y. Sugimoto,
T. Murata,
T. Matsuoka,
T. Kobayashi,
H. Hizaki,
K. Tuboi,
M. Katsuyama,
A. Ichikawa,
T. Tanaka,
N. Yoshida,
and
S. Narumiya.
Impaired febrile response in mice lacking the prostaglandin E receptor subtype EP3.
Nature
395:
281-284,
1998[Medline].
50.
Van Deventer, S. J. H.,
H. R. Büller,
J. W. tenCate,
L. A. Tarden,
C. E. Hack,
and
A. Sturk.
Experimental endotoxemia in humans: analysis of cytokine release and coagulation, fibrinolytic, and complement pathways.
Blood
76:
2820-2826,
1990.
51.
Vedeler, C. A.,
R. Martre,
and
E. Fischer.
Isolation and characterization of complement receptor CR1 from human peripheral nerves.
J. Neuroimmunol.
23:
215-221,
1989[Medline].
52.
Vukajlovich, S. W.
Interactions of LPS with serum complement.
In: Bacterial Endotoxic Lipopolysaccharides, edited by J. L. Ryan,
and D. C. Morrison. Boca Raton, FL: CRC, 1992, vol. II, p. 213-235.
53.
Warner, A. E.,
and
J. D. Brain.
Intravascular pulmonary macrophages: a novel cell removes particles from blood.
Am. J. Physiol.
250 (Regulatory Integrative Comp. Physiol. 19):
R728-R732,
1986.
54.
Watkins, L. R.,
L. E. Goehler,
J. K. Relton,
N. Tartaglia,
L. Silbert,
D. Martin,
and
S. F. Maier.
Blockade of interleukin-1-induced hyperthermia by subdiaphragmatic vagotomy: evidence for vagal mediation of immune-brain communication.
Neurosci. Lett.
183:
1-5,
1994.
55.
Weiler, J. M.,
R. E. Edens,
R. J. Linhardt,
and
D. P. Kapelanski.
Heparin and modified heparin inhibit complement activation in vivo.
J. Immunol.
148:
3210-3215,
1992[Abstract].
56.
Wright, S. D.,
S. M. Levin,
M. T. C. Jong,
E. Chad,
and
L. G. Kabbash.
CR3 (CD11c/CD18) expresses one binding site for Arg-Gly-Asp-containing peptides and a second site for bacterial lipopolysaccharide.
J. Exp. Med.
169:
175-183,
1989
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Tc) relative to their
initial level
(Tci = average
of Tc values over last 10 min
before injection of PFS or LPS). CVF was given intravenously 18 h
before these measurements; PFS or LPS was given at
time
0. Values are means ± SE;
n = no. of animals
(CH100 = serum total hemolytic C
activity at time
0 expressed as reduction relative to
its normalized activity before CVF or PFS administration 18 h earlier).
Because no effect of CVF was demonstrable at any dose, CVF 50 and 100 are not illustrated in A.
) and intraperitoneal (
) administration of LPS (8 µg/kg).
Tc data from intraperitoneal
treatment group are reproduced from Fig.
