Expanding the febrigenic role of cyclooxygenase-2 to the previously overlooked responses

Previous studies on the role of cyclooxygenase (COX)-1 and -2 in fever induced by intravenous LPS have failed to investigate the role of these isoenzymes in the earliest responses: monophasic fever (response to a low, near-threshold dose of LPS) and the first phase of polyphasic fever (response to higher doses). We studied these responses in 96 mice that were COX-1 or COX-2 deficient (-/-) or sufficient (+/+). Each mouse was implanted with a temperature telemetry probe into the peritoneal cavity and a jugular catheter. The study was conducted at a tightly controlled, neutral ambient temperature (31 degrees C). To avoid stress hyperthermia (which masks the onset of fever), all injections were performed through a catheter extension. The +/+ mice responded to intravenous saline with no change in deep body temperature. To a low dose of LPS (1 microg/kg iv), they responded with a monophasic fever. To a higher dose (56 microg/kg), they responded with a polyphasic fever. Neither monophasic fever nor the first phase of polyphasic fever was attenuated in the COX-1 -/- mice, but both responses were absent in the COX-2 -/- mice. The second and third phases of polyphasic fever were also missing in the COX-2 -/- mice. The present study identifies a new, critical role for COX-2 in the mediation of the earliest responses to intravenous LPS: monophasic fever and the first phase of polyphasic fever. It also suggests that no product of the COX-1 gene, including the splice variant COX-1b (COX-3), is essential for these responses.     

Thermoregulatory responses of rats to conventional preparations of lipopolysaccharide are caused by lipopolysaccharide per se-- not by lipoprotein contaminants

LPS preparations cause a variety of body temperature (T(b)) responses: monophasic fever, different phases of polyphasic fever, and hypothermia. Conventional (c) LPS preparations contain highly active lipoprotein contaminants (endotoxin proteins). Whereas LPS signals predominantly via the Toll-like receptor (TLR) 4, endotoxin proteins signal via TLR2. Several TLR2-dependent responses of immunocytes to cLPS in vitro are triggered by endotoxin proteins and not by LPS itself. We tested whether any T(b) response to cLPS from Escherichia coli 055:B5 is triggered by non-TLR4-signaling contaminants. A decontaminated (d) LPS preparation (free of endotoxin proteins) was produced by subjecting cLPS to phenol-water reextraction. The presence of non-TLR4-signaling contaminants in cLPS (and their absence in dLPS) was confirmed by showing that cLPS (but not dLPS) induced IL-1beta expression in the spleen and increased serum levels of TNF-alpha and IL-1beta of C3H/HeJ mice; these mice bear a nonfunctional TLR4. Yet, both cLPS and dLPS caused cytokine responses in C3H/HeOuJ mice; these mice bear a fully functional TLR4. We then studied the T(b) responses to cLPS and dLPS in Wistar rats preimplanted with jugular catheters. At a neutral ambient temperature (30 degrees C), a low (0.1 microg/kg iv) dose of cLPS caused a monophasic fever, whereas a moderate (10 microg/kg iv) dose produced a polyphasic fever. In the cold (20 degrees C), a high (500 microg/kg iv) dose of cLPS caused hypothermia. All T(b) responses to dLPS were identical to those of cLPS. We conclude that all known T(b) responses to LPS preparations are triggered by LPS per se and not by non-TLR4-signaling contaminants of such preparations.     

Albumin is not an irreplaceable carrier for amphipathic mediators of thermoregulatory responses to LPS: compensatory role of alpha1-acid glycoprotein

In view of the potential involvement of peripherally synthesized, circulating amphipathic mediators [such as platelet-activating factor (PAF) and prostaglandin E(2)] in the systemic inflammatory response to lipopolysaccharide (LPS), we hypothesized that transport of amphipaths by albumin is essential for conveying peripheral inflammatory signals to the brain. Our first specific aim was to test this hypothesis by studying LPS-induced fever and hypothermia in Nagase analbuminemic rats (NAR). NAR from two different colonies and normalbuminemic Sprague-Dawley rats were preimplanted with jugular catheters, and their febrile responses to a mild dose of LPS (10 microg/kg i.v.) at thermoneutrality and hypothermic responses to a high dose of LPS (500 microg/kg i.v.) in the cold were studied. NAR of both colonies developed normal febrile and hypothermic responses, thus suggesting that transport of amphipathic mediators by albumin is not indispensable for LPS signaling. Although alternative carrier proteins [such as alpha(1)-acid glycoprotein (AGP)] are known to assume transport functions of albumin in NAR, it is unknown whether inflammatory mediators are capable of inducing their actions when bound to alternative carriers. To test whether PAF, the most potent amphipathic pyrogen, causes fever when administered in an AGP-bound form was our second aim. Sprague-Dawley rats were preimplanted with jugular catheters, and their thermal responses to infusion of a 1:1 [PAF-AGP] complex (40 nmol/kg i.v.), AGP (40 nmol/kg i.v.), or various doses of free (aggregated) PAF were studied. The complex, but neither free PAF nor AGP, caused a high ( approximately 1.5 degrees C) fever with a short (< 10 min) latency. This is the first demonstration of a pyrogenic activity of AGP-bound PAF. We conclude that, in the absence of albumin, AGP and possibly other carriers participate in immune-to-brain signaling by binding and transporting amphipathic inflammatory mediators.     

Effects of different serotypes of Escherichia coli lipopolysaccharides on body temperature in rats

The effects of Escherichia coli O55:B5, O127:B8, and O111:B4 serotypes' lipopolysaccharides (LPS) on body temperature were investigated in rats. LPSs were injected intraperitoneally at doses of 2, 50, and 250 microg/kg. A multiphasic and no-dose dependent increase in rectal temperature was observed in response to E. coli O55:B5 LPS at all doses, and in response to E. coli O127:B8 LPS at 2 and 50 microg/kg doses. The highest dose of the latter caused a dual change in rectal temperature, in which hypothermia preceded fever. E. coli O111:B4 LPS was either pyrogenic or hypothermic at 2 and 250 microg/kg doses; respectively, whereas a dual response was observed when the 50 microg/kg dose was injected. Although dual responses were observed after administration of all LPSs at 50 microg/kg dose when the body temperature was recorded by biotelemetry, the hypothermia induced by E. coli O55:B5 LPS was significantly smaller. These data suggest that LPSs induce dose and serotype-specific variable changes on body temperature in rats. This variability may be related to the structure of LPSs. The data also indicate that LPS causes hypothermia with or without fever in rats.     

Indomethacin impairs LPS-induced behavioral fever in toads.

We tested the hypothesis that PGs mediate lipopolysaccharide (LPS)-induced behavioral fever in the toad Bufo paracnemis. Measurements of preferred body temperature (T(b)) were performed with a thermal gradient. Toads were injected intraperitoneally with the cyclooxygenase inhibitor indomethacin (5 mg/kg), which inhibits PG biosynthesis, or its vehicle (Tris) followed 30 min later by LPS (0.2 and 2 mg/kg) into the lymph sac. LPS at the dose of 0.2 mg/kg caused a significant increase in T(b) from 7 to 10 h after injection, and then T(b) returned toward baseline values. LPS at the dose of 2 mg/kg produced a different pattern of response, with a longer latency to the onset of fever (10th h) and a longer duration (until the end of the experiment at the 15th h). Tris significantly attenuated the fever induced by LPS at 0.2 mg/kg, but not at 2 mg/kg. Moreover, indomethacin completely blocked the fever evoked by LPS (2 mg/kg). These results indicate that the behavioral fever induced by LPS in toads requires the activation of the COX pathway, suggesting that the involvement of PG in fever has an ancient phylogenetic history and that endogenous PGs raise the thermoregulatory set point to produce fever, because behavioral thermoregulation seems to be related to changes in the thermoregulatory set point.     

Localized vs. systemic inflammation in guinea pigs: a role for prostaglandins at distinct points of the fever induction pathways?

In guinea pigs, dose-dependent febrile responses were induced by injection of a high (100 microg/kg) or a low (10 microg/kg) dose of bacterial lipopolysaccharide (LPS) into artificial subcutaneously implanted Teflon chambers. Both LPS doses further induced a pronounced formation of prostaglandin E(2) (PGE(2)) at the site of localized subcutaneous inflammation. Administration of diclofenac, a nonselective cyclooxygenase (COX) inhibitor, at different doses (5, 50, 500, or 5,000 microg/kg) attenuated or abrogated LPS-induced fever and inhibited LPS-induced local PGE(2) formation (5 or 500 microg/kg diclofenac). Even the lowest dose of diclofenac (5 microg/kg) attenuated fever in response to 10 microg/kg LPS, but only when administered directly into the subcutaneous chamber, and not into the site contralateral to the chamber. This observation indicated that a localized formation of PGE(2) at the site of inflammation mediated a portion of the febrile response, which was induced by injection of 10 microg/kg LPS into the subcutaneous chamber. Further support for this hypothesis derived from the observation that we failed to detect elevated amounts of COX-2 mRNA in the brain of guinea pigs injected subcutaneously with 10 microg/kg LPS, whereas subcutaneous injections of 100 microg/kg LPS, as well as systemic injections of LPS (intra-arterial or intraperitoneal routes), readily caused expression of the COX-2 gene in the guinea pig brain, as demonstrated by in situ hybridization. Therefore, fever in response to subcutaneous injection of 10 microg/kg LPS may, in part, have been evoked by a neural, rather than a humoral, pathway from the local site of inflammation to the brain.     

Restraint increases afebrile body temperature but attenuates fever in Pekin ducks (Anas platyrhynchos)

In mammals, procedures such as handling, restraint, or exposure to open spaces induces an increase in body temperature (T(b)). The increase in temperature shares some characteristics with pyrogen-induced fever and so is often called "stress fever." Birds also respond to acute handling with a stress fever, which may confound thermoregulatory studies that involve animal restraint. We have measured the T(b) responses of Pekin ducks on days when they were restrained and compared them to days when the birds remained unrestrained. Restraint induced a 0.5 degrees C increase in T(b) that was sustained for the entire 8 h of restraint. To determine whether the restraint-induced increase in T(b) is mediated by prostaglandins (PGs) we compared the T(b) responses during restraint after intraperitoneal injection with saline to the responses during restraint after injection with diclofenac sodium (15 mg/kg). There was no difference in response, suggesting that restraint affects T(b) by a PG-independent mechanism. We also compared the T(b) response to intramuscular injection of lipopolysaccharide (LPS; 100 microg/kg), a bacterial pyrogen, when the ducks were restrained or unrestrained. Despite T(b) being higher at the time of LPS injection when the ducks were restrained, the maximum temperature reached after LPS injection was higher, and the period that T(b) remained elevated was longer when the ducks were unrestrained. We conclude that restraint should be considered as a potential confounder in thermoregulatory studies in birds and presumably other species too.     

Intracerebroventricular injection of neuronal and inducible nitric oxide synthase inhibitors attenuates fever due to LPS in rats.

Nitric oxide (NO) has been shown to be an important mediator of febrile response to lipopolisaccharide (LPS). To clarify the role of different isoforms of NO synthase (NOS) in febrile response to immune challenge, effects of selective iNOS and nNOS inhibitors on fever to LPS were examined in freely moving biotelemetered rats. Vinyl-L-NIO (N(5) - (1-Imino-3-butenyl) - ornithine (vL-NIO), a neuronal nitric oxide synthase (nNOS) inhibitor, and aminoguanidine hydrochloride, an inducible nitric oxide synthase (iNOS) inhibitor, were injected intracerebroventricularly at a dose of 10 microg/rat just before intraperitoneal injection of LPS at a dose of 50 microg/kg. Both inhibitors injected at a selected doses had no effect on normal day-time body temperature (T(b)) and normal night-time T(b). vinyl-L-NIO and aminoguanidine injected intracerebroventricularly at a dose of 10 microg/animal suppressed the LPS-induced fever in rats. The fever index calculated for rats pretreated with v-LNIO or with aminoguanidine and injected with LPS was reduced by 43% and 72%, respectively, compared to that calculated for water-pretreated and LPS-injected rats. Whereas vL-NIO partly attenuated both phases of febrile rise in T(b), administration of aminoguanidine into the brain completely prevented fever induced by LPS. These data indicate that activation of iNOS inside the brain is not only responsible for triggering but also for maintaining of LPS-induced fever in rats. It is, therefore, reasonable to hypothesize that, activation of iNOS inside the brain is more important in fever development than activation of nNOS.     

Fever induction by localized subcutaneous inflammation in guinea pigs: the role of cytokines and prostaglandins.

In guinea pigs, dose-dependent febrile responses can be induced by injection of a high (100 micro g/kg) or low (10 micro g/kg) dose of bacterial lipopolysaccharide (LPS) into artificial subcutaneously implanted Teflon chambers. In this fever model, LPS does not enter the systemic circulation from the site of localized tissue inflammation in considerable amounts but causes a local induction of the proinflammatory cytokines tumor necrosis factor (TNF) and interleukin-6 (IL-6), which can be measured in lavage fluid collected from the chamber area. Only in response to the high LPS dose, small traces of TNF are measurable in blood plasma. A moderate increase of circulating IL-6 occurs in response to administration of both LPS doses. To investigate the putative roles of TNF and prostaglandins in this fever model, a neutralizing TNF binding protein (TNF-bp) or a nonselective inhibitor of cyclooxygenases (diclofenac) was injected along with the high or low dose of LPS into the subcutaneous chamber. In control groups, both doses of LPS were administered into the chamber along with the respective vehicles for the applied drugs. The fever response to the high LPS dose remained unimpaired by treatment with TNF-bp despite an effective neutralization of bioactive TNF in the inflamed tissue area. In response to the low LPS dose, there was an accelerated defervescence under the influence of TNF-bp. Blockade of prostaglandin formation with diclofenac completely abolished fever in response to both LPS doses. In conclusion, prostaglandins seem to be essential components for the manifestation of fever in this model.     

Effect of interleukin-18 on mouse core body temperature

We have studied, using a telemetry system, the pyrogenic properties of recombinant murine interleukin-18 (rmIL-18) injected into the peritoneum of C57BL/6 mice. The effect of IL-18 was compared with the febrile response induced by human IL-1beta, lipopolysaccharide (LPS), and recombinant murine interferon-gamma (rmIFN-gamma). Both IL-1beta and LPS induced a febrile response within the first hour after the intraperitoneal injection, whereas rmIL-18 (10-200 microg/kg) and rmIFN-gamma (10-150 microg/kg) did not cause significant changes in the core body temperature of mice. Surprisingly, increasing doses of IL-18, injected intraperitoneally 30 min before IL-1beta, significantly reduced the IL-1beta-induced fever response. In contrast, the same pretreatment with IL-18 did not modify the febrile response induced by LPS. IFN-gamma does not seem to play a role in the IL-18-mediated attenuation of IL-1beta-induced fever. In fact, there was no elevation of IFN-gamma in the serum of mice treated with IL-18, and a pretreatment with IFN-gamma did not modify the fever response induced by IL-1beta. We conclude that IL-18 is not pyrogenic when injected intraperitoneally in C57BL/6 mice. Furthermore, a pretreatment with IL-18, 30 min before IL-1beta, attenuates the febrile response induced by IL-1beta.     

The influence of bacterial lipopolysaccharide on the thermoregulation of the box turtle Terrapene carolina

Ectotherms can adjust their thermoregulatory set points in response to bacterial infection; the result may be similar to endothermic fever. We examined the influence of dose on the set point of body temperature (T(b)) in Terrapene carolina. After acclimating postprandial turtles to 20 degrees C, we injected them with two doses of bacterial endotoxin (LPS; lipopolysaccharide from Escherichia coli), 0.0025 or 0.025 mg LPS/g nonshell body mass, or with reptilian saline (control group). We placed the animals singly in linear thigmothermal gradients and recorded their T(b)'s for 48 h. The turtles showed dose-influenced thermal selection. Turtles injected with the high dose had T(b)'s significantly higher than control turtles, whereas low-dose turtles had T(b)'s significantly lower than control turtles. Also, there was a low daily effect on the T(b) of the turtles injected with the high dose. High-dose turtles had significantly higher T(b)'s than the control turtles during the first day but not during the second. Our results support the prediction of Romanovsky and Székely that an infectious agent may elicit opposite thermoregulatory responses depending on quality and quantity of the agent and the host health status.     

Hypothermic response produced by manassantin A, a novel neuroleptic agent

Manassantin A (MNS-A), a novel neolignoid, neutral compound shown to possess neuroleptic properties, causes hypothermic response in male and female mice of CD-1 strain when administered by the intra-cerebroventricular (icv), (0.1, 1.0, 3.2, 10 micrograms/mouse), intraperitoneal (ip), (0.1, 0.32, 1.0, 3.2 mg/kg) and oral (0.5, 1.6, 5.0, 16 mg/kg) routes. The hypothermia was found to be dose and time dependent, the maximum decrease of temperature being observed by the icv route (P less than 0.001) after 2 hours. However, ip and oral administration of lower and middle order doses were not very effective but higher doses caused significant (P less than 0.001) reduction of body temperature. The centrally-induced hypothermic response by MNS-A may give future leads as a screening model for antidepressant drugs and can be a useful tool for manipulating physiological and pharmacological processes to understand the central thermoregulatory functions.     

Effect of 5-lipoxygenase inhibitor against lipopolysaccharide-induced hypothermia in mice

Bacterial endotoxin produces sepsis associated with alterations in body temperature (fever or hypothermia). The intraperitoneal administration of bacterial endotoxin, lipopolysaccharide (LPS; 50 microg/mouse) led to a decrease in colonic temperature starting 1 hr after the injection. The hypothermic effect was accompanied by a significant increase in hypothalamic leukotriene B4 (LTB4) and prostaglandin E2 (PGE2) levels. 5-lipoxygenase inhibitor, zileuton (200 and 400 mg/kg, po) administered 30 min before LPS challenge significantly prevented hypothermia. However, non-selective cyclooxygenase inhibitor, indomethacin (10, 20 mg/kg, po) did not reverse the hypothermic response. Further, pretreatment of mice with zileuton prevented LPS-stimulated increase in hypothalamic LTB4 levels and caused a relatively small increase in PGE2 levels. Indomethacin had no effect on LTB4 levels but it reduced PGE2 levels. These results suggest a possible involvement of leukotrienes in LPS-induced hypothermia and the potential protective role of 5-lipoxygenase inhibitors in endotoxemia.     

Effects of lipopolysaccharide and acclimation temperature on induced behavioral fever in juvenile Iguana iguana

We examined the effects of acclimation temperature and two doses (2.5 and 25mgkg(-1)) of a pyrogen (lipopolysaccharide, LPS) on behavioral thermoregulation in juvenile green iguanas. Overall means of body temperatures for the three-day trial periods were compared among three groups of animals acclimated at 15, 25, and 34 degrees C. The responses of each group of animals to the two dosages of LPS and a control saline injection were examined. Within each treatment block, animals either chose high body temperatures characteristic of a fever response or chose low body temperatures characteristic of a hypothermic response. Thermoregulation was influenced by interaction effects between and among, and independent effects of, acclimation temperature, dose of LPS, and day. In some treatment blocks, individual lizard mass positively correlated with mean individual body temperature. Mean mass of lizards that chose higher body temperatures within a treatment block was higher than the mean mass of lizards that chose lower body temperatures. From these results, we concluded that LPS may induce two different behavioral thermoregulatory responses: fever or hypothermia. The actual amplitude and direction of body temperature change appears to be affected by acclimation temperature and possibly by mass or energy reserves of the animal. If the energy reserves are not sufficient to sustain the higher rate of metabolism associated with the higher body temperatures of a hyperthermic or feverish state, the animal may resort to hypothermia.     

The spleen modulates the febrile response of guinea pigs to LPS

The febrile responses of splenectomized (Splex) or sham-operated (Sham) guinea pigs challenged intravenously or intraperitoneally with lipopolysaccharide (LPS) 7 and 30 days after surgery were evaluated. FITC-LPS uptake by Kupffer cells (KC) was additionally assessed 15, 30, and 60 min after injection. LPS at 0.05 microg/kg iv did not evoke fever in Sham animals but caused a 1.2 degrees C core temperature (T(c)) rise in the Splex animals. LPS at 2 microg/kg iv induced a 1.8 degrees C greater T(c) rise of the Splex animals than of their controls. LPS at 2 and 8 microg/kg ip 7 days postsurgery induced 1.4 and 1.8 degrees C higher fevers, respectively, in the Splex than Sham animals. LPS at 2 and 8 microg/kg ip 30 days postsurgery also increased the febrile responses of the asplenic animals by 1.6 and 1.8 degrees C, respectively. FITC-LPS at 7 days was detected in the controls within KC 15 min after its administration; the label density was reduced at 30 min and almost 0 at 60 min. In the Splex group, in contrast, the labeling was significantly denser and remained unchanged through all three time points; this effect was still present 30 days after surgery. Similar results were obtained at 60 min after FITC-LPS intraperitoneal injection. Gadolinium chloride pretreatment (-3 days) of the Splex group significantly reduced both their febrile responses to LPS (8 microg/kg ip) and their KC uptake of FITC-LPS 7 days postsurgery. Thus splenectomy increases the magnitude of the febrile response of guinea pigs and the uptake of systemically administered LPS.     

Tolerance to low-dose endotoxin in awake sheep

Dose response and tolerance to a small intravenous dose of Serratia marcescens lipopolysaccharide (LPS) were studied in awake sheep. Core temperature significantly increased after a dose of 0.002 micrograms/kg; changes in pulmonary arterial pressure, pulmonary vascular resistance, plasma thromboxane B2, and circulating leukocyte concentration occurred after 0.02 micrograms/kg; plasma 6-keto-prostaglandin F1 alpha increased after 0.2 micrograms/kg. Development of acute tolerance was studied by injection of S. marcescens LPS (0.02 micrograms/kg iv) on 3 consecutive days: pulmonary arterial pressure and thromboxane B2 levels were significantly lower than controls after the second dose, whereas fever and the degree of leukopenia were not diminished until the third dose. After intravenous administration of LPS given in increasing doses from 0.1 to 3.2 micrograms/kg three times weekly over 7 wk, there were no measurable changes in any of the above parameters after challenge with S. marcescens LPS (0.02 micrograms/kg) after a 1-wk rest period. In awake sheep, small intravenous doses of LPS can cause physiologically important changes of the pulmonary circulation and can alter the hemodynamic and eicosanoid mediator responses to subsequent challenges with LPS. Large intravenous doses of LPS can ablate the physiological responses to subsequent small doses of LPS.     

Thermoregulatory role of inducible nitric oxide synthase in lipopolysaccharide-induced hypothermia

We have tested the hypothesis that nitric oxide (NO) arising from inducible nitric oxide synthase (iNOS) plays a role in hypothermia during endotoxemia by regulating vasopressin (AVP) release. Wild-type (WT) and iNOS knockout mice (KO) were intraperitoneally injected with either saline or Escherichia coli lipopolysaccharide (LPS) 10.0 mg/kg in a final volume of 0.02 mL. Body temperature was measured continuously by biotelemetry during 24 h after injection. Three hours after LPS administration, we observed a significant drop in body temperature (hypothermic response) in WT mice, which remained until the seventh hour, returning then close to the basal level. In iNOS KO mice, we found a significant fall in body temperature after the fourth hour of LPS administration; however, the hypothermic response persisted until the end of the 24 h of the experiment. The pre-treatment with beta-mercapto-beta,beta-cyclopentamethylenepropionyl(1), O-Et-Tyr2, Val4, Arg8-Vasopressin, an AVP V1 receptor antagonist (10 microg/kg) administered intraperitoneally, abolished the persistent hypothermia induced by LPS in iNOS KO mice, suggesting the regulation of iNOS under the vasopressin release in this experimental model. In conclusion, our data suggest that the iNOS isoform plays a role in LPS-induced hypothermia, apparently through the regulation of AVP release.     

Effects of nitric oxide synthase inhibitors on the febrile response to lipopolysaccharide and muramyl dipeptide in guinea pigs

We investigated the effect of N-nitro-L-arginine methyl ester (L-NAME), an unspecific nitric oxide synthase (NOS) inhibitor, and aminoguanidine, a relatively selective inhibitor of the inducible NOS enzyme, on both gram-negative lipopolysaccharide (LPS) and gram-positive muramyl dipeptide (MDP) fever in guinea pigs. Intraperitoneal injection of either 10 mg/kg L-NAME or 25 mg/kg aminoguanidine inhibited the febrile response to an intramuscular injection of 50 microg/kg MDP. However, LPS fever (20 microg/kg) was inhibited only by L-NAME. The development of LPS fever may therefore occur independently of the synthesis of nitric oxide by the inducible NOS enzyme, while MDP fever may involve synthesis of nitric oxide by both the inducible and the constitutively expressed NOS enzymes.     

Antipyretic effect of arginine vasotocin in toads

Arginine vasotocin (AVT) is a nonmammalian analog of the mammalian hormone arginine vasopressin (AVP). These peptides are known for their antidiuretic and pressor effects. More recently, AVP has been recognized as an important antipyretic molecule in mammals. However, no information exists about the role of AVT in febrile ectotherms. We tested the hypothesis that AVT is an antipyretic molecule in the toad Bufo paracnemis. Toads equipped with a temperature probe were placed in a thermal gradient, and preferred body temperature was recorded continuously. A behavioral fever was observed after lipopolysaccharide (LPS) was injected systemically (200 microg/kg). Systemically injected AVT (300 pmol/kg) alone caused no significant change in body temperature, but abolished LPS-induced fever. Moreover, a smaller dose of AVT (10 pmol/kg), which did not affect LPS-induced fever when injected peripherally, abolished fever when injected intracerebroventricularly. We therefore conclude that AVT plays an antipyretic role in the central nervous system, by means of behavior, in an ectotherm, a fact consistent with the notion that AVT/AVP elicits antipyresis by reducing the thermoregulatory set point.     

Effect of palmitate on carbohydrate utilization and Na/K-ATPase activity in aortic vascular smooth muscle from diabetic rats

Immediately after bacterial endotoxin (LPS) enters the circulatory system there is increased production of free oxygen radicals by cells of the reticulo-endothelial system, followed by the release of cytokines considered as putative endogenous pyrogens. Fever originates by central nervous system activities, but neither exogenous nor endogenous pyrogens are able to cross the blood-brain barrier and the true signal which is transmitted to structures inside the blood-brain barrier is still unknown. To study the role of oxygen radicals in fever, we pretreated rats with methylene blue, an inhibitor of superoxide and hydroxyl radical production and investigated the febrile response to LPS in conscious rats by measuring malondialdehyde formation as an index of lipid peroxidation by oxygen radicals. Methylene blue lowered resting malondialdehyde levels to near detection level and significantly suppressed its rise which was regularly found following LPS in the untreated state. Pretreatment with methylene blue completely blocked the febrile response. Since fever is a central nervous system-mediated response these results indicate that the brain is able to sense oxidative stress and vicinal thiol groups of the redox-modulatory site of the N-methyl-D-aspartate (NMDA) subtype of glutamate receptor-channel complex could function as a possible receptive structure. To test this hypothesis we injected rabbits with the disulfide reducing agent dithiothreitol (DTT), known to penetrate the blood-brain barrier, and monitored its effect on normal and febrile body temperatures. DTT induced, independently of ambient temperature, within minutes and dose-dependently the full pattern of heat loss responses causing a fall of core temperature, indicative of a lowered thermoregulatory setpoint. Pretreatment with a bolus dose of 5 mg/kg DTT, followed by a continuous infusion of 5 mg/kg/h for 3 h completely prevented LPS-induced fever. A bolus dose of 20 mg/kg DTT, starting 30 min after LPS, immediately reversed the febrile cold defense pattern and lowered body temperature. We conclude that DTT reduces in the central nervous system oxidized vicinal thiol groups of NMDA receptors, thereby augmenting glutamate-induced nitric oxide synthase activation, and, thus, enhanced formation of NO, which, in turn, lowers the thermoregulatory setpoint. Reduction of other disulfide-containing molecules, especially oxidized glutathione and thiol-containing enzymes, by DTT by might additionally contribute to preventing fever.