Role of hypothalamic interleukin-1beta  in fever induced by cecal ligation and puncture in rats

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Role of hypothalamic interleukin-1 $beta$ in fever induced by cecal ligation and puncture in rats

Alexander V. Gourine, Karin Rudolph, Johannes Tesfaigzi, and Matthew J. Kluger

Lovelace Respiratory Research Institute, Inhalation Toxicology Laboratory, Albuquerque, New Mexico 87185

ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Bacterial endotoxin induces fever by causing the release of interleukin (IL)-1 $beta$ into the circulation or the brain. IL-1 $beta$ isbelieved to mediate fever via triggering the production and/orrelease of IL-6 in the hypothalamus. The present study examinedwhether IL-1 $beta$ and IL-6 in the hypothalamus of the rat are alsoinvolved in fever during bacterial sepsis caused by cecal ligationand puncture (CLP). CLP induces fever for 2 days. Polyclonal rabbitantibody against rat IL-1 $beta$ (anti-IL-1 $beta$ , 2 µg/µl) or control rabbitIgG (2 µg/µl) was unilaterally microinjected into the hypothalamusof rats immediately after or 24 h after CLP or sham-CLP surgery.Anti-IL-1 $beta$ injected 24 h after CLP (when fever was already present)or sham-CLP surgery did not affect fever. Microinjection of anti-IL-1 $beta$ into the hypothalamus immediately after surgery caused a significantdecrease in body temperature during the night after CLP surgeryand a 48% reduction of fever on the following day. Although bloodplasma levels of IL-6 were significantly elevated 1.5, 6, 24,and 48 h after CLP surgery, there were no differences in IL-6concentrations in the extracellular fluid of the anterior hypothalamus(collected by push-pull perfusion). These data suggest that feverdue to bacterial sepsis is initiated by IL-1 $beta$ within the hypothalamus,and this febrile response, unlike endotoxin-induced fever, isnot accompanied by elevation in the hypothalamic concentrationof IL-6.

cytokines; endotoxin; push-pull perfusion; temperature regulation

	INTRODUCTION

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FEVER IS A REGULATED RISE in body temperature (T_b) and one of the most common responses to infection, injury, or trauma. Administrationof bacterial endotoxin lipopolysaccharide (LPS) is used widelyas a laboratory model of fever. Some endogenously produced proteinsare thought to be responsible for the induction of fever by alteringthe "set point" for T_b regulation. Interleukin (IL)-1 is thoughtto be an endogenous pyrogen during LPS-induced fever. Intraperitoneal,intravenous, intracerebroventricular, and intrahypothalamic injectionsof recombinant IL-1 cause fever in various species [for review,see Kluger (13)]. It is believed, on the basis of the observationthat intravenous administration of antiserum to murine recombinantIL-1 $alpha$ does not affect the rise in T_b during fever and that IL-1 $alpha$ is not involved in LPS-induced fever (16). On the other hand,intraperitoneal injection of neutralizing antibody to IL-1 $beta$ ledto a significant attenuation of LPS-induced fever in rats (17,26). Intraperitoneal (29) or intracerebroventricular (18,22) injections of IL-1 receptor antagonist have also attenuatedLPS-induced fever in rats. Klir et al. (11) found that microinjectionof neutralizing antibody to IL-1 $beta$ into the anterior hypothalamusof rats led to an attenuation of LPS-induced fever. The presenceof IL-1 type I receptors in thermoregulatory centers has beendemonstrated (34). IL-6 has also been reported to be pyrogenicwhen injected [for review, see Kluger (13)]. Hypothalamic concentrationsof IL-6 rise during LPS-induced fever in guinea pigs (25) andrats (12). Infusion of IL-6 into the anterior hypothalamus ata concentration that simulates levels seen after injection ofLPS causes a significant rise in T_b (12). Rothwell et al. (27)found that a central injection of antibody to IL-6 inhibits thefebrile response to LPS in rats. The probable site of action ofendogenous pyrogens is the anterior hypothalamus. IL-1 $beta$ in vivo(10) and in vitro (20) and IL-6 in vitro (33) predominantlydecrease the unit activity of warm-sensitive neurons and increasethat of cold-sensitive neurons of the rostral hypothalamus. Thesedata are consistent with the hypothesis that IL-1 $beta$ and IL-6 acton the thermoregulatory neurons to cause a rise in T_b. Thus numerousdata indicate that IL-1 $beta$ and IL-6 are endogenous pyrogens duringLPS-induced fever, the production of these cytokines in the brainincreases after administration of exogenous pyrogens, and IL-1 $beta$ and IL-6 might possess their pyrogenic action via their actionson thermosensitive neurons of the hypothalamus.

There is evidence that the rise in IL-6, which is responsible for fever, is triggered in part by IL-1 $beta$ . Shalaby et al. (28)demonstrated that IL-1 $beta$ is a strong inducer of IL-6 productionin vivo, and LeMay et al. (15) found that the rise in plasmaand cerebrospinal fluid concentration of IL-6 in rats injectedwith LPS was attenuated when the rats were pretreated with anti-IL-1 $beta$ .Klir et al. (11) showed that the intrahypothalamic administrationof the antibody to IL-1 $beta$ not only blocked a significant portionof the rise in T_b in response to LPS, but also completely abrogatedthe rise in hypothalamic IL-6. Klir and colleagues (11) concludedthat IL-1 $beta$ mediated LPS-induced fever via an increase in intrahypothalamicIL-6.

Although injection of LPS is a reasonable model of real infection, LPS-induced fever is not the "typical" fever. LPS is usuallycleared from the circulation within 1 h after intravenous injectionand induces relatively short-lasting fever. However, in most casesfever is induced and maintained for long periods of time by continuouspyrogenic stimulation. On the other hand, there is little clinicalevidence that plasma LPS levels correlate with the developmentof sepsis (6), and the failure of the antiendotoxin approachin clinical trials of sepsis treatment (2a) also suggests thatLPS is probably only one of several agents responsible for feverand sickness behavior during infections. These data support thehypothesis that the mechanisms of LPS-induced febrile response(laboratory model of fever) may be different from that of naturallyoccurring fever.

The model of cecal ligation and puncture (CLP) was used in this study. It is widely accepted by many investigators as a modelof sepsis, acute infection, and bacterial peritonitis (7, 31,32). This model involves continuous pyrogenic stimulation andsimulates a real infection much better than infusion of constantamounts of LPS (simulated infection).

The purpose of the present study was to investigate whether hypothalamic IL-1 $beta$ and IL-6 are involved in the development offever in response to bacterial infection (CLP model). Becauseof the poor correlation between circulating and brain levels ofIL-1 and fever (4, 12, 13), we did not measure the hypothalamiclevels of this cytokine. Neutralizing antibody to IL-1 $beta$ was injectedintrahypothalamically, and the effect of this injection on thedevelopment of CLP-induced fever was studied. In addition, becauseIL-6 levels in the hypothalamus correlate well with fever (11,12), we measured this cytokine in push-pull perfusate.

	MATERIALS AND METHODS

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Animals

Specific pathogen-free male Sprague-Dawley rats (Harlan Sprague Dawley, Indianapolis, IN) weighing 260-300 g were used. Ratswere housed one per cage in specific pathogen-free animal quartersin a room maintained at a constant temperature of 25 ± 1°C, atemperature within the thermoneutral zone of rats, and in a 12:12-hlight-dark cycle with light onset at 0600. Drinking water andlaboratory rodent chow were provided ad libitum. All experimentalprocedures were approved by the Institutional Animal Care andUse Committee of the Lovelace Respiratory Research Institute.All studies were conducted in facilities fully accredited by theAssociation for the Assessment and Accreditation of LaboratoryAnimal Care.

Surgery

The animals were anesthetized with a mixture of ketamine hydrochloride (87.0 mg/kg) and xylazine hydrochloride (13.0 mg/kg)injected intramuscularly. First, a miniature battery-operated,temperature-sensitive telemetry transmitter (model VMFH; Mini-Mitter,Sunriver, OR) was implanted into the abdominal cavity for continuousmonitoring of T_b. Then a 26-gauge guide injection cannula (PlasticProducts, Roanoke, VA) was stereotaxically implanted into thebrain, according to the atlas developed by Paxinos and Watson(24). Coordinates for injections or perfusions of the centralpart of the anterior hypothalamus were 1.8 mm posterior to bregma,0.5 mm lateral to right of midline, and 8.6 mm below surface ofskull, and coordinates of the lateral ventricle were 0.8 mm posteriorto bregma, 1.5 mm lateral to right of midline, and 4.0 mm belowthe surface of the skull. Two small screws were placed into theskull, and the cannula was secured in place by dental acrylic.The guide cannula was closed with a dummy cannula that extendedfrom the tip of the guide cannula by $<=$ 0.2 mm. Animals were allowedto recover for at least 7 days before any experiment. At the endof the experiment, rats were perfused transcardially with salinefollowed by 4% paraformaldehyde solution, brains were removed,and the location of the tip of cannula was histologically confirmed.

T_b Measurements

Deep T_b (±0.1°C) was monitored with implanted telemetry units (Mini-Mitter). Recordings were made at 5-min intervals by useof a peripheral processor (Datacol III system, Mini-Mitter) connectedto an IBM PC, as described previously (15).

CLP

The rats were anesthetized with a mixture of 4% halothane in air. A 2-cm midline abdominal incision was made to expose thececum. The base of the cecum was ligated with 3-0 silk just belowthe ileocecal valve to permit intestinal continuity. Then theantimesenteric cecal surface was punctured two times with an 18-gaugeneedle, the cecum was placed back into the abdominal cavity, andthe incision was sutured. The wound area was then swabbed withtopical antibiotics. The control sham-operated rats had theirceca exposed but not ligated and punctured.

Microinjections

The hypothalamus or lateral ventricle was microinjected with an internal injection cannula connected to PE-20 tubing attachedto a 10-µl syringe (Hamilton, Reno, NV). The volumes of injectionswere 1 µl for the hypothalamus and 3 µl for the lateral ventricle.

Push-Pull Perfusion

The dummy cannula was unscrewed, and the internal cannula with the rest of the push-pull assembly was attached. The assemblyconsisted of the internal cannula inserted into the guide cannula,two PE-20 tubing lines (push and pull), and the infusion-withdrawalpump (Harvard Apparatus, South Natick, MA). A small area nearthe tip of the cannula was continuously bathed with artificialcerebrospinal fluid (aCSF) at a flow rate of 20 µl/min. Each perfusionlasted ~15 min. The samples of perfusate were immediately storedat $-$ 20°C. The rat could move freely in its cage during the wholeexperiment.

Animal Perfusion and Histology

Rats were anesthetized with halothane (4% in air mixture) and perfused transcardially with saline followed by phosphate-buffered4% paraformaldehyde. The brains were removed, stored in the samefixative for 24 h, and submerged in 20% sucrose for an additional24 h. Series of coronal sections from the hypothalamic regionwere cut at 10 µm. Slide-mounted sections were stored at $-$ 20°Cuntil immunohistochemical staining was initiated.

Immunohistochemistry

The distribution of the rabbit IgG injected in the hypothalamus was determined by immunohistochemistry using a biotinylatedgoat anti-rabbit IgG. Tissue sections were sequentially incubatedin 2% hydrogen peroxide in methanol for 30 s to inactivate endogenousperoxidases and blocked in 1% normal goat serum and 0.1% TritonX-100 in 100 mM Tris · HCl (pH 7.8) for 45 min. After the reactionwith the biotinylated goat anti-rabbit IgG (1:200; Vector Laboratories,Burlingame, CA) in 0.5% normal goat serum and 0.1% Triton X-100in 100 mM Tris · HCl (pH 7.8) for 1 h, tissues were incubatedwith an avidin-biotin complex (Vector Elite kit; 1:100 in 100mM Tris · HCl, pH 7.8) for an additional hour at room temperature.After extensive rinsing, the distribution of IgG was visualizedusing the chromagen diaminobenzidine (Vector DAB Staining kit,Vector Laboratories, Burlingame, CA). The diaminobenzidine reactionwas terminated after 10 min, and sections were counterstainedwith hematoxylin, dehydrated in alcohol, cleared in xylene, andpermanently placed under a coverslip with Permount. Sections wereobserved with a Zeiss microscope, and IgG distribution was determined.

IL-6 Assay

The IL-6-dependent mouse B9 hybridoma cell line was used to determine IL-6 levels. The B9 line was kindly provided by Dr.Lucien Aarden; see Aarden et al. (1). Details of the IL-6 bioassayhave been described (11, 12). The sensitivity of the bioassaywas 0.2 U/ml (1 U = 0.01 ng; 1st International Standard Code 89/548,Stephen Poole, National Institute for Biological Standards andControl). Because we did not specifically neutralize the activityof the proliferative factor with IL-6 blocking antibodies, thereported values must be considered "IL-6-like" activity. ImmunoreactiveIL-6 was also measured using a rat IL-6 ELISA kit (Biosource International,Camarillo, CA).

Materials

Anti-IL-1 $beta$ . The rabbit anti-rat IL-1 $beta$ antibody used for hypothalamic microinjection was obtained from Cytokine Sciences (Boston, MA).This polyclonal antibody neutralized both recombinant and naturalrat IL-1 $beta$ . It was dissolved in aCSF (see aCSF below) to obtaina final concentration of 2 µg in 1 µl. We confirmed the activityof these antibodies by demonstrating that injection into the hypothalamusin a dose of 2 µg blocked a significant portion of fever inducedby intraperitoneal injection of LPS, data similar to those ofKlir et al. (11).

IgG. Purified rabbit IgG used as a control for hypothalamic microinjection of anti-IL-1 $beta$ was obtained from Sigma (St. Louis, MO).It was dissolved in aCSF to a final concentration of 2 µg in 1µl of aCSF.

hrIL-1 $beta$ . Human recombinant IL-1 $beta$ (hrIL-1 $beta$ ; specific activity 1.66 × 10⁹ IU/mg) was obtained from Immunex (Seattle, WA). It was dissolvedin aCSF to a final concentration of 50 ng (8.3 × 10⁴ IU) in 3 µl of aCSF.

hrIL-1ra. Human recombinant IL-1 receptor antagonist (hrIL-1ra) was obtained from Synergen (Boulder, CO). It was dissolved in aCSF toa final concentration of 100 µg in 3 µl of aCSF.

aCSF. The aCSF used for microinjections consisted of (in mM) 145.0 NaCl, 3.3 KCl, 1.3 CaCl₂, and 1.0 MgCl₂ dissolved in sterilepyrogen-free water.

Experimental Design

Experiment 1: Effect of intrahypothalamic injection of neutralizing antibody to IL-1 $beta$ (24 h after surgical procedure) on fever caused by CLP. T_b was monitored for 2 days before and 3 days after the surgical procedure. Animals were conditioned to handling once a dayfor 5 days before the experiment. Each animal was anesthetizedwith 4% halothane for ~10 min during the CLP or sham-CLP surgery.Anti-IL-1 $beta$ or control IgG was injected intrahypothalamically 24h after the surgery in a 2-µg dose. This dose has been effectivein attenuating the LPS-induced fever after intrahypothalamic administration(11).

Experiment 2: Effect of intrahypothalamic injection of neutralizing antibody to IL-1 $beta$ (immediately after surgical procedure) on fever caused by CLP. T_b was monitored for 2 days before and 3 days after the surgical procedure. CLP or sham surgery was performed between 0900and 1100. Intrahypothalamic injections of anti-IL-1 $beta$ or controlIgG were performed immediately after surgery. Antibody was injectedin the same dose of 2 µg. During surgical procedure and subsequentinjections of antibodies, each animal was anesthetized with 4%halothane for ~15 min.

Experiment 3: Distribution of rabbit IgG in hypothalamus after unilateral microinjection. Eight rats received an intrahypothalamic microinjection of IgG (2 µg) between 0900 and 1000. Brains were removed for histologyand immunohistochemistry 2 h (4 rats) and 24 h (4 rats) afterinjections. IgG was identified using the procedure described.

Experiment 4: Effect of intracerebroventricular injection of hrIL-1 $beta$ on T_b in rats. To test the ability of IL-1 $beta$ to induce long-lasting fever, we injected hrIL-1 $beta$ into the lateral ventricle of the rats, andT_b was monitored for 48 h. The hrIL-1 $beta$ was administered in a doseof 50 ng (8.3 × 10⁴ IU). Earlier studies from this laboratory on the pyrogenic activityof this cytokine revealed that 50 ng (8.3 × 10⁴ IU) is the lowest dose of hrIL-1 $beta$ injected into the lateral ventricleof rats that elicits a febrile response (L. R. Leon, unpublishedobservations). The hrIL-1ra was administered into the same brainsite before hrIL-1 $beta$ treatment to confirm that the effect of hrIL-1 $beta$ was realized through its specific receptors. The hrIL-1ra wasinjected in a dose of 100 µg, which is an average dose from theamounts effective in attenuating LPS-induced fevers after centraladministration (18, 22).

Experiment 5: Level of IL-6 activity in hypothalamus and plasma during fever caused by CLP. CLP or sham surgery was performed between 0900 and 1100. After 1.5, 6, 24, and 48 h, push-pull perfusion samples of the extracellularfluid of the hypothalamus were collected and stored at $-$ 20°C untilassayed. For comparison of hypothalamic and circulatory levelsof IL-6, another set of CLP and sham rats was anesthetized with4% halothane and blood was collected by cardiac puncture at thesame time points. Immediately after the collection, plasma wasseparated by centrifugation and stored at $-$ 20°C.

Statistical Analysis

Data are reported as means ± SE. Comparisons between experimental groups were made using one-way ANOVA followed by Fisher'spost hoc test. A value of P < 0.05 was considered significant.

	RESULTS

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Experiment 1: Effect of Intrahypothalamic Injection of Neutralizing Antibody to IL-1 $beta$ , 24 h After Surgical Procedure, on Fever Caused by CLP

The temperature response of rats to CLP and sham surgery followed in 24 h by an intrahypothalamic administration of anti-IL-1 $beta$ or control IgG is shown in Fig. 1. The day before surgery, animalsshowed the normal circadian rhythm of T_b, which rises during thedark period (day, $-$ 28 to $-$ 17 h; night, $-$ 16 to $-$ 5 h). Because ofanesthesia, the surgical procedure itself induced a drop in T_bin all groups of rats. During the first (20-31 h) and second (44-55h) days after surgery, CLP rats developed fever and maintainedsignificantly (P < 0.05) higher T_b (~38°C) than sham-operatedrats (Fig. 1). The handling (day before surgery) as well as theinjection procedure (day after surgery) induced short-term, stress-inducedrises in T_b. Intrahypothalamic injection of anti-IL-1 $beta$ 24 h afterthe surgical procedure did not significantly influence CLP-inducedfever (Fig. 1).

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Fig. 1. Effect of microinjection of anti-rat interleukin (IL)-1 $beta$ antibody [anti-IL-1; 2 µg in 1 µl of artificial cerebrospinal fluid (aCSF)] or control IgG (in equivalent dose and volume) into hypothalamus on cecal ligation and puncture (CLP)-induced fever in rats [2-h averages of body temperature (T_b)]. Rats were injected with anti-IL-1 $beta$ or IgG 24 h after CLP or sham-CLP surgery. I, time of conditioning on day before surgery; II, time of surgical procedure; III, time of anti-IL-1 $beta$ or IgG injections on day after surgery. Black horizontal bars indicate dark periods in a 12:12-h light-dark cycle. Numbers in parentheses indicate sample sizes. Data are presented as mean ± SE.

Experiment 2: Effect of Intrahypothalamic Injection of Neutralizing Antibody to IL-1 $beta$ , Immediately After Surgical Procedure, on Fever Caused by CLP

Figure 2 shows a 2-h average T_b for the groups of animals during the whole experiment. Figure 3 shows a 12-h average T_b duringthe night and the day after surgery. As shown in Figs. 2 and 3,injection of the neutralizing antibody to IL-1 $beta$ considerably modifiedthe response to CLP. Intrahypothalamic administration of anti-IL-1 $beta$ induced a significant decrease in T_b in CLP rats during the nightafter surgery (Figs. 2 and 3). Average core temperatures for thenight after surgery were 37.30 ± 0.14 for CLP + anti-IL-1 $beta$ versus37.74 ± 0.12 for CLP + IgG (P < 0.05). Compared with sham ratsinjected intrahypothalamically with IgG, the CLP rats injectedthe same way with IgG developed a 0.99°C rise in T_b (average temperaturesduring next 12 h of daylight on day after surgery). CLP rats injectedintrahypothalamically with anti-IL-1 $beta$ compared with sham-operatedrats injected with anti-IL-1 $beta$ showed a 0.51°C rise in T_b duringthe same time, which represents a 48% reduction in fever. Theactual average T_b on the day after surgery of the CLP rats injectedwith IgG was 38.46 ± 0.09, whereas the T_b of CLP rats injectedwith anti-IL-1 $beta$ was 38.09 ± 0.08 during this time (P < 0.05).On the second day after surgery, there was no difference in themagnitude of fever in CLP rats injected with anti-IL-1 $beta$ comparedwith CLP rats injected with IgG (Fig. 2).

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Fig. 2. Effect of microinjection of anti-rat IL-1 $beta$ antibody (anti-IL-1; 2 µg in 1 µl of aCSF) or control IgG (in equivalent dose and volume) into hypothalamus on CLP-induced fever in rats (2-h averages of T_b). Rats were injected with anti-IL-1 $beta$ or IgG immediately after CLP or sham-CLP surgery. Arrowhead, time of surgical procedure and subsequent injections. Black horizontal bars indicate dark periods in a 12:12-h light-dark cycle. Numbers in parentheses indicate sample sizes. Data are presented as means ± SE. * Average temperatures 14-30 h postsurgery were significantly lower in CLP rats injected with anti-IL-1 $beta$ than in CLP rats injected with IgG (P < 0.05).

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Fig. 3. Twelve-hour averages of T_b in CLP- and sham-CLP-operated rats to intrahypothalamic microinjection of anti-rat IL-1 $beta$ antibody (anti-IL-1; 2 µg in 1 µl of aCSF) or control IgG (in equivalent dose and volume). Numbers in parentheses indicate sample sizes. Data are presented as means ± SE. Left columns (8-19 h) represent first dark period after surgery, and right columns (20-31 h) represent next light period after surgery. * Significant difference in values at P < 0.05.

Experiment 3: Distribution of Rabbit IgG in Hypothalamus After Unilateral Microinjection

To determine the site of action of anti-IL-1 $beta$ in the attenuation of fever induced by CLP, we examined the distribution ofthe antibody in the hypothalamus 2 and 24 h after injection. Animmunohistochemical study of the injected IgG distribution revealedwidespread distribution of the antibody through the hypothalamictissue 2 h after a unilateral microinjection into the centralpart of the anterior hypothalamus (1.8 mm posterior to bregma,0.5 mm lateral to right of midline, and 8.6 mm below surface ofskull). The area of IgG distribution was limited in the rostraldirection by the medial preoptic area at the level of anteriorcommissure, 0.26 mm posterior to bregma (24), and in the caudaldirection by the dorsomedial hypothalamic nucleus, 3.30 mm posteriorto bregma (24). In the mediolateral direction, IgG was distributedbetween the third ventricle and the lateral hypothalamic areaand distribution was not exclusively limited by the wall of thethird ventricle. Moderate staining was also observed on the contralateralside. However, 24 h after injection, the IgG was not detected,suggesting that the antibody was cleared from the hypothalamusduring this time.

Experiment 4: Effect of Intracerebroventricular Injection of hrIL-1 $beta$ on T_b in Rats

Although the fever observed 24 h after CLP was attenuated by the anti-IL-1 $beta$ injected shortly after surgery, anti-IL-1 $beta$ maynot be present at this time point, based on the histological finding.Therefore, we decided to test the ability of IL-1 $beta$ to cause long-lastingfever in rats. As shown in Fig. 4, injection of hrIL-1 $beta$ inducedlong-lasting elevation in T_b in rats. The initial temperatureresponse (0 h) represents a stress-induced rise in T_b caused bythe injection procedure. During the day of injection (0-8 h) andthe next light period (20-31 h), rats injected with aCSF and hrIL-1 $beta$ were febrile and this rise in T_b was completely blocked by thepreliminary injection of hrIL-1ra. The T_b of the rats injectedwith hrIL-1ra and hrIL-1 $beta$ was not different from the values theday before (control).

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Fig. 4. Long-lasting effect of human recombinant IL-1 $beta$ (hurIL-1) on T_b in rats. hurIL-1 (50 ng in 3 µl of aCSF) was injected into lateral cerebral ventricle 5 min after injection of hurIL-1 receptor antagonist (hurIL-1ra, 100 µg in 3 µl of aCSF) or aCSF into same site. Control represents values of T_b of same animals during 2 days before injections. Arrowhead, time of injections. Numbers in parentheses indicate sample sizes. Black horizontal bar indicates dark periods in a 12:12-h light-dark cycle. Data are presented as means ± SE. * Significant difference in values at P < 0.05.

Experiment 5: Level of IL-6 Activity in Hypothalamus and Plasma During Fever Caused by CLP

Table 1 shows IL-6 levels in extracellular fluid of the hypothalamus and plasma 1.5, 6, 24, and 48 h after CLP or sham surgery.At all time points, IL-6 levels in plasma of CLP rats were significantlyhigher in comparison with sham-operated animals. The maximum levelof IL-6 was reached 6 h after CLP surgery (Table 1). IL-6 levelsin the hypothalamus measured by bioassay or by the immunoassaywere very low (near detection limit) in both groups of animals,and there were no differences between experimental groups at alltime points tested.

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Table 1. Interleukin-6 activity in blood plasma and extracellular fluid of hypothalamus 1.5, 6, 24, and 48 h after CLP or sham-CLP surgery

	DISCUSSION

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This study shows that fever in response to live bacterial infection is significantly attenuated by intrahypothalamic administrationof neutralizing antibody to IL-1 $beta$ , and this febrile response isnot accompanied by an elevation in hypothalamic concentrationof IL-6.

As mentioned in the introduction, there is evidence that mechanisms of LPS-induced febrile response (laboratory model of fever)may be different from that of naturally occurring fever. The lackof correlation between plasma LPS levels and the development ofsepsis (6), together with the failure of the anti-endotoxintherapy in clinical trials of sepsis treatment (2a), suggeststhat LPS is not the only factor responsible for the elevationof core temperature and other symptoms of sickness during infections.The CLP model, used in this study, closely resembles the clinicalsituation of bowel perforation and mixed bacterial infection ofintestinal origin and is to a large extent different from LPS-inducedfebrile response. LPS is usually eliminated from the circulationwithin 1 h after intravenous injection, whereas in the case ofCLP, endotoxin is detectable in serum for at least 21 h aftersurgery (31). Variability of the approach is an obvious disadvantageof this model of fever. Indeed, the amount and type of bacteriaand the time course of leakage into the peritoneal cavity afterCLP can vary considerably among animals. However, several experimentsshowed that the febrile response of rats to CLP is very consistent(Figs. 1 and 2). Despite the inherent variability of the approach,it was found that temperature responses of individual rats toCLP were virtually identical within an experiment.

Earlier studies from this laboratory reported that LPS-induced fever was attenuated by intrahypothalamic microinjection ofa neutralizing antibody to IL-1 $beta$ (11). The present data providefurther evidence that IL-1 $beta$ is also important for the developmentof fever due to acute bacterial infection and that the hypothalamusis the site of its pyrogenic action. Unilateral injection intothe hypothalamus of a neutralizing antibody to IL-1 $beta$ (administeredimmediately after CLP surgery) resulted in a 48% reduction offever. The injection of antibody to IL-1 $beta$ also induced a significantdecrease in T_b in CLP-operated rats the night after surgery. Afterthe CLP-induced fever had developed (24 h after surgery), theintrahypothalamic injection of anti-IL-1 $beta$ did not antagonize it.Although the fever observed on the next day after CLP was attenuatedby anti-IL-1 $beta$ injected shortly after surgery, histological findingsindicate that anti-IL-1 $beta$ may not be present at this time point,because it was found that antibody was completely cleared fromthe hypothalamus within 24 h. Acute central injection of hrIL-1 $beta$ in its lowest pyrogenic dose (L. R. Leon, unpublished observations)induced long-lasting elevation in T_b in rats. In most studieson IL-1 $beta$ pyrogenic activity, T_b was measured only during the dayof injection. In this study, T_b was monitored for 48 h and itwas found that fever in response to hrIL-1 $beta$ was observed evenon the day after injection (20-30 h postinjection). Thus feverafter acute central administration of hrIL-1 $beta$ was observed duringthe same time when fever in response to CLP was attenuated byacute injection of anti-IL-1 $beta$ . It was also found that fever inresponse to live bacterial infection, unlike LPS-induced febrileresponse, was not accompanied by changes in hypothalamic levelsof IL-6. Thus the present study revealed similarities, as wellas differences, between LPS and live bacteria-induced fever.

These data suggest that IL-1 $beta$ within the hypothalamus is probably involved in inducing, rather than maintaining, fever. 1)Anti-IL-1 $beta$ attenuates the rise in T_b when injected intrahypothalamicallybefore the development of fever; 2) anti-IL-1 $beta$ does not affectT_b when the fever has already developed; 3) injected antibodyis completely eliminated from the site of administration within24 h, indicating that when the significant difference in feveris observed, anti-IL-1 $beta$ is not present in the hypothalamus; 4)exogenous IL-1 $beta$ can induce long-lasting (30 h) fever in rats afteracute central administration; and 5) earlier studies from thislaboratory did not find a rise in IL-1 in extracellular fluidfrom the hypothalamus during the LPS-induced fever (12), andit was suggested that IL-1 in this area quickly becomes cell associated.On the basis of these data, we speculate that initial bindingof the IL-1 $beta$ (during the first hours after CLP surgery) is criticallyimportant for the subsequent fever.

The origin of the hypothalamic IL-1 $beta$ (i.e., from the brain or periphery) remains unclear. Banks et al. (3) found that IL-1 $beta$ can cross the blood-brain barrier to enter the central nervoussystem by a saturable transport system. However, data of Coceaniet al. (4) indicate that the blood-brain barrier is impermeableto IL-1. There is also considerable evidence that IL-1 can besynthesized in the brain. Tringali et al. (30) generated datasuggesting that IL-1 $beta$ released by rat hypothalamus might be ofneuronal origin. IL-1 $beta$ production in the brain was found duringLPS-induced fever (19) and after peripheral (9, 14) orcentral (5) endotoxin application. These observations suggestthat IL-1 $beta$ , which exerts its pyrogenic action on the hypothalamiclevel, might be of peripheral (by crossing blood-brain barrier)as well as brain (synthesized by neurons or glial cells) origin.

At the same time, when plasma levels of IL-6 were markedly elevated during CLP-induced fever, there were no differences inIL-6 levels in the extracellular fluid of the hypothalamus betweenthe CLP and sham rats. The present data indicating that hypothalamicIL-6 levels did not increase during bacterial infection-inducedfever do not support earlier findings from this laboratory ofincreased hypothalamic IL-6 levels during LPS-induced fever (12)or observations that the IL-6 measured in the push-pull perfusatefrom the hypothalamus during LPS fever is produced at that sitein response to a local increase in IL-1 $beta$ (11). We speculatethat IL-1 $beta$ pyrogenic action during live bacterial infection, unlikeduring LPS-induced fever, is not achieved via an increase in intrahypothalamicIL-6. IL-1 $beta$ at the hypothalamic level may initiate fever by inducingthe synthesis of prostaglandins (PGs), which are considered theultimate mediators of the febrile response. There is evidencethat supports this hypothesis. 1) IL-1 can directly induce theexpression of cyclooxygenase inducible isoform COX-2 and productionof PGs (21, 23), 2) hypothalamic neuronal responses to IL-1 $beta$ are effectively blocked by mepacrine (a phospholipase A₂ inhibitor)and by sodium salicylate (a cyclooxygenase inhibitor) (10, 20).Thus it is suggested that IL-1 $beta$ in the hypothalamus directly inducesprolonged synthesis of PGs, which in turn decreases the activityof warm-sensitive neurons and increases the activity of cold-sensitiveneurons, resulting in an increase in heat production and decreasein heat loss.

The data obtained in this study might be useful in terms of the development of anti-cytokine approaches in the treatment ofsepsis. IL-1 together with tumor necrosis factor are believedto play central roles in the pathophysiological state of sepsis(simulated by CLP model). Animal studies show that hrIL-1ra iseffective in the attenuation of LPS-induced fever (18, 22,29) and in preventing morbidity and mortality of sepsis in rats(2); however, soluble IL-1ra did not protect against sepsisin clinical trials (2a). We hypothesize that anti-IL-1 therapymight be effective only during the early stages of sepsis, becausewe have shown that anti-IL-1 $beta$ treatment was effective in attenuationof fever when it was applied before but not after the developmentof sepsis.

In conclusion, this study characterizes the role of hypothalamic IL-1 $beta$ and IL-6 in the development of fever during acute bacterialinfection in rats. The data obtained revealed similarities aswell as differences between LPS and live bacteria-induced fever.The results show that fever caused by bacterial infection, likeLPS-induced fever, involves IL-1 $beta$ as an endogenous pyrogen andthat the hypothalamus is the site of its pyrogenic action. Itis speculated that IL-1 $beta$ within the hypothalamus is probably involvedin inducing, rather than maintaining, fever. The results alsoindicate that fever in response to bacterial sepsis, unlike LPS-inducedfever, is not accompanied by an elevation in hypothalamic concentrationof IL-6.

Perspectives

Fever is probably one of the most common adaptive responses to infection, injury, or trauma. Most models of fever involvethe injection of LPS, a component of the cell wall of gram-negativebacteria. These models have shown that IL-1 $beta$ at the level of theanterior hypothalamus is responsible for a portion of fever (11).In addition, the IL-1 $beta$ results in a rise in hypothalamic IL-6(11). Are all fevers identical? That is, do they all operatevia the induction of the same cytokine cascade? In the presentstudy, we measured hypothalamic concentrations of IL-6 in a modelof "real" infection: CLP. We found that CLP caused a rise in circulatingconcentration of IL-6 but no rise in the hypothalamic concentrationof this cytokine. However, when the rats had neutralizing antibodyto IL-1 $beta$ microinjected into the hypothalamus, this resulted ina significant attenuation of fever. We conclude that 1) CLP-inducedfevers act in part via hypothalamic IL-1 $beta$ , and 2) these feversmay not require the production of IL-6.

	ACKNOWLEDGEMENTS

We thank Dr. Lucien Aarden for providing the B9 cell line, Dr. John E. Sims from Immunex for generously providing hrIL-1 $beta$ ,Dr. John J. Klir for pilot studies on the role of CLP in inductionof fever in the rat, and Drs. Wieslaw Kozak and Lisa R. Leon forcritical reviews of the manuscript.

	FOOTNOTES

This study was supported by National Institute of Allergy and Infectious Diseases Grant AI-27556 to M. J. Kluger and by Grant1 FO5 TWO5291-01 from the Fogarty International Center (FIC) ofthe National Institutes of Health (NIH) to A. V. Gourine. Thecontents of this study are solely the responsibility of the authorsand do not necessarily represent the official views of the NIHor the FIC.

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate this fact.

Address for reprint requests: A. V. Gourine, Lovelace Respiratory Research Institute, Inhalation Toxicology Laboratory, PO Box 5890, Albuquerque, NM 87185.

Received 25 February 1998; accepted in final form 19 May 1998.

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