Neuroendocrine-immune interactions in the neonate.

Cytokine responses to lipopolysaccharides in neuroendocrine tissues are age- and tissue-dependent in neonatal pigs. Developmental differences in serum and tissue-specific responses are not necessarily equivalent. Lower levels of cytokine gene expression in neuroendocrine tissues of early neonates potentially could influence neuroendocrine and immune responses to infection. The limited information on neuroendocrine-immune responses and interactions in neonatal farm animals presents significant challenges, as well as opportunities for new discoveries and improvements of livestock production.

Effects of thermal environment on response to acute peripheral lipopolysaccharide challenge exposure in neonatal pigs.

OBJECTIVE: To evaluate effects of thermal environment on response to acute peripheral lipopolysaccharide (LPS) challenge exposure in neonatal pigs. ANIMALS: 26 neonatal pigs. PROCEDURE: Pigs were assigned to the following treatment groups: 1 warm environment/LPS; 2 warm environment/saline solution; 3 cool environment/LPS; and 4 cool environment/saline solution. For each pig given LPS, 1 littermate of the same sex was given saline solution. Sows with baby pigs were housed in a warm (32 C) or cool (21 C) thermal environment. At 28 days of age, pigs were given 150 micrograms/kg of body weight of Escherichia coli LPS or saline solution intraperitonealy as a control. Rectal temperature and signs of sickness were monitored for 3 hours after LPS administration, when pigs were euthanatized and blood samples were collected to determine serum concentrations of tumor necrosis factor (TNF) alpha and cortisol. To determine in vitro production of TNF alpha, alveolar macrophages were collected by tracheal lavage and incubated for 24 hours at 37 or 41 C, with or without LPS (10 micrograms/ml). RESULTS: Thermal environment had a significant (P = 0.0004) effect on rectal temperature; LPS administration induced a febrile response (P = 0.0007) only in pigs in the warm environment. All LPS-injected pigs developed signs of endotoxemia; serum TNF alpha and cortisol concentrations were significantly increased (TNF alpha, P = 0.003; cortisol, P = 0.0001); there was no significant in vivo thermal effect on serum TNF alpha and cortisol concentrations. LPS-stimulated alveolar macrophages produced significantly less (P = 0.0086) TNF alpha when incubated at 41 C. CONCLUSIONS: Thermal environment can have a significant impact on the response of neonatal pigs exposed to bacterial endotoxins.

Thermoregulatory responses to thermal stimulation of the preoptic anterior hypothalamus in the red fox (Vulpes vulpes).

The preoptic anterior hypothalamus (POAH) thermoregulatory controller can be characterized by two types of control, an adjustable setpoint temperature and changing POAH thermal sensitivity. Setpoint temperatures for shivering (Tshiver) and panting (Tpant) both increased with decreasing ambient temperature (Ta), and decreased with increasing Ta. The POAH controller is twice as sensitive to heating as to cooling. Metabolic rate (MR) increased during both heating and cooling of the POAH. Resting temperature of the POAH was lower than internal body temperature (Tb) at all temperatures. This indicates the presence of some form of brain cooling mechanism. Decreased Tb during POAH heating was a result of increased heat dissipation, while higher Tb during POAH cooling was a result of increased heat production and reduced heat dissipation. The surface temperature responses indicated that foxes can actively control heat flow from body surface. Such control can be achieved by increased peripheral blood flow and vasodilation during POAH heating, and reduced peripheral blood flow and vasoconstriction during POAH cooling. The observed surface temperature changes indicated that the thermoregulatory vasomotor responses can occur within 1 min following POAH heating or cooling. Such a degree of regulation can be achieved only by central neural control. Only surface regions covered with relatively short fur are used for heat dissipation. These thermoregulatory effective surface areas account for approximately 33% of the total body surface area, and include the area of the face, dorsal head, nose, pinna, lower legs, and paws.

Metabolic rate and evaporative water loss at different ambient temperatures in two species of fox: the red fox (Vulpes vulpes) and the Arctic fox (Alopex lagopus).

1. Resting metabolic rate (RMR) and evaporative water loss (EWL) of adult red and arctic foxes were determined over ambient temperature (Ta) ranges of -13-37 degrees C and -5-30 degrees C as oxygen consumption and amount of water in expired air using an open flow system. 2. The average RMR was 2.60 +/- 0.14 W/kg for the winter red fox, 2.59 +/- 0.14 W/kg for the summer red fox, and 2.35 +/- 0.11 W/kg for the winter arctic fox. 3. The rate of increase of RMR was significant (P less than 0.05) only for Ta range above 27 degrees C. The slopes for this Ta range were 0.152 for the winter red fox, and 0.283 for the winter arctic fox. 4. The upper critical temperature (Tuc) of the red fox is probably between 30 and 32 degrees C. The Tuc of the arctic fox is probably between 26 and 28 degrees C. The lower critical temperatures (Tlc) were not reached. 5. A strong linear relationship between the EWL and Ta was found for Ta range above 27 degrees C. The slopes for this Ta range were 0.523 for the winter red fox, and 1.025 for the winter arctic fox. 6. Probably, there are neither significant intraspecific seasonal nor interspecific differences in the RMR and EWL. The two species seem to differ only in their critical temperatures.

Interleukin-1 beta causes the increase in anterior hypothalamic interleukin-6 during LPS-induced fever in rats.

The purpose of this study was to determine, using push-pull perfusion, whether the central pyrogenic action of interleukin-6 (IL-6) during lipopolysaccharide (LPS)-induced fever in rats is induced by interleukin-1 beta (IL-1 beta) and to determine the source of the hypothalamic IL-6 (i.e., from the periphery or from the brain). Samples of cerebrospinal fluid were collected 60 min before and 60, 120, 180, and 240 min after the intraperitoneal injection of LPS or saline as a control. Immediately before the injection of LPS, anti-rat neutralizing IL-1 beta antibody (anti-IL-1 beta) or control immunoglobulin G antibody (IgG) was microinjected into the anterior hypothalamus (AH) of each rat. At the end of the last perfusion, blood was collected by cardiac puncture. Microinjection of anti-IL-1 beta into the AH caused a 58% reduction of LPS fever (measured by biotelemetry). AH microinjection of anti-IL-1 beta or IgG followed by intraperitoneal injection of saline did not result in significant change in core body temperature. AH injection of anti-IL-1 beta also resulted in a 97% reduction in AH IL-6 levels during LPS fever, with the average values of IL-6 for the four post-LPS time points being 113 +/- 50 U/ml for the rats injected with IgG and LPS and 3 +/- 2 U/ml for the rats injected with anti-IL-1 beta and LPS (P = 0.024).(ABSTRACT TRUNCATED AT 250 WORDS)

An infrared thermographic study of surface temperature in relation to external thermal stress in the Mongolian gerbil, Meriones unguiculatus.

1. Temperatures of different body surface regions and deep body temperature (Tb) of unrestrained adult Mongolia gerbils exposed to ambient temperatures (Ta) of -10-35 degrees C were measured using infrared (i.r.) thermography and a thermocouple. 2. A strong positive linear relationship between the surface temperature and Ta was found. For Ta range -4-35 degrees C, the slope was lowest for the areas around the eyes and dorsal head, and steepest for the body extremities. At -10 degrees C, surface temperatures of the areas around the eyes and dorsal head were significantly lower then predicted. 3. Tb was lowest at Ta of 25 and 30 degrees C, increased at all temperatures above and up to Ta of -4 degrees C below this range, and began decline at -10 degrees C. 4. The thermoneutral zone (TNZ) is probably between 28 and 32 degrees C, and the absolute lower critical temperature (Tabsl) is probably -4 degrees C. 5. The Mongolian gerbil shows little control of surface temperature and in contrast to larger mammals it has not developed any special thermoregulatory surface areas to regulate heat exchange with its environment. At temperatures below -4 degrees C, this species is unable to maintain the surface temperature of body extremities above the freezing point. 6. It is suggested that the Mongolian gerbil uses mainly behavioral and ecological adaptive strategies to attenuate the stressful effects of its habitat.

TNF soluble receptor and antiserum against TNF enhance lipopolysaccharide fever in mice.

We tested the effects of tumor necrosis factor (TNF) soluble receptor (sTNFR) and anti-TNF serum (anti-TNF) administered intraperitoneally on fever induced by lipopolysaccharide (LPS) in mice. Both agents have been shown to block bioactivity of mouse TNF-alpha. Core temperature (Tb) and locomotor activity in unrestrained mice were measured by biotelemetry. Within 1 h from the LPS injection (2.5 mg/kg ip) Tb decreased below normal for 5-6 h and motor activity was depressed for the following 48 h. After this initial reduction, Tb increased and reached a peak at approximately 24 h postinjection. Anti-TNF and sTNFR blocked this "hypothermic phase" after LPS, and the fevers started sooner; however, the levels and time of peak temperature did not change markedly. In addition, a human recombinant TNF-alpha given intraperitoneally abolished fever and prolonged the fall of Tb in mice after LPS. We conclude that the reduction of Tb soon after injection of LPS in mice is dependent on TNF-alpha.

Central effects of glucocorticoid receptor antagonist RU-38486 on lipopolysaccharide and stress-induced fever.

Intracerebroventricular administration of the glucocorticoid type II receptor antagonist RU-38486 leads to an increased fever after injection of lipopolysaccharide (LPS) in awake unrestrained rats, indicating that endogenous glucocorticoids act centrally to lower temperature after the intraperitoneal injection of LPS. The current study examined where in the brain glucocorticoids exert these effects on fever and if these effects involve plasma interleukin-6 and corticosterone. RU-38486 injected intracerebroventricularly (10 ng/animal) led to a significantly greater rise in biotelemetered body temperature (BT) 120-240 min post-LPS (50 mg/kg ip) compared with controls (0.89 +/- 0.14 vs. 0.44 +/- 0.22 degree C, P = 0.0482), confirming our earlier study, and also led to a significantly greater rise in BT after exposure to an open field when the RU-38486 was infused intracerebroventricularly (10 ng/ml, 1 microliter/h) for 20 h before the exposure (1.48 +/- 0.18 vs. 1.06 +/- 0.11 degree C, P = 0.023). When rats were injected with RU-38486 into the anterior hypothalamus (1 ng/animal), there was an increased rise in BT after injection of LPS (1.74 +/- 0.27 vs. 0.82 +/- 0.22 degree C, P = 0.0075) but not after exposure to an open field (1 ng intrahypothalamically, 1 h preexposure). There were no differences in plasma interleukin (IL)-6-like activity or plasma corticosterone after intracerebroventricular injection of RU-38486 and intraperitoneal injection of LPS. We conclude that endogenous glucocorticoids are working centrally to modulate fever after LPS and exposure to open field, and that LPS-induced fever is modulated by glucocorticoids in the anterior hypothalamus.(ABSTRACT TRUNCATED AT 250 WORDS)

The CNS site of glucocorticoid negative feedback during LPS- and psychological stress-induced fevers.

Glucocorticoids exert negative feedback in the anterior hypothalamus (AH) during lipopolysaccharide (LPS)-induced fevers, but the central location of their negative feedback during psychological stress-induced fever has not been determined. To confirm that glucocorticoid modulation of LPS fever occurs in the AH, adrenalectomized animals were injected intrahypothalamically with either 0.25 ng of corticosterone or vehicle followed by 50 micrograms/kg LPS intraperitoneally. Animals pretreated with corticosterone developed significantly smaller fevers (P = 0.007) than animals given vehicle. To determine if glucocorticoid modulation during psychological stress-induced fever may occur in the hippocampus, the fornix was transected to block hippocampal communication with the AH. This resulted in significantly larger psychological stress-induced fevers (P = 0.02) compared with sham-operated animals. There were no differences between these groups for LPS-induced fevers (P = 0.92). To determine where in the hippocampus glucocorticoids might exert their negative feedback during psychological stress, rats were microinjected with either 1 ng RU-38486 (a type II glucocorticoid receptor antagonist) or vehicle into the dentate gyrus prior to exposure to the open field. There were no differences between the psychological stress-induced fevers of the RU-38486- and vehicle-injected groups, supporting the hypothesis that these fevers are modulated elsewhere in the hippocampus. Our data support the hypothesis that glucocorticoids modulate LPS-induced fever in the AH and do not involve the hippocampus, and that psychological stress-induced fevers are modulated by neural connections between the hippocampus and the hypothalamus. The precise sites of action of glucocorticoid negative feedback on stress-induced fevers in the hippocampus (or other brain regions) are not yet known.

Attenuation of lipopolysaccharide fever in rats by protein kinase C inhibitors.

The purpose of this study was to assess the effects of inhibitors of protein kinase C (PKC) on lipopolysaccharide (LPS)-induced fever and changes in circulating interleukin-6 (IL-6) levels in freely moving biotelemetered rats. We used PKC inhibitors with different inhibition constants (Ki): H-7 (Ki = 6 microM) and chelerythrine (Chel; Ki = 0.66 microM; a more potent PKC inhibitor). Rats were injected subcutaneously with either 3 or 15 microM/kg of these inhibitors and then 1 h later were injected intraperitoneally with LPS (50 micrograms/kg). Blood samples for IL-6 bioassay were collected 4 h after LPS injection. H-7 at lower doses did not significantly affect fever and LPS-induced elevation of circulating IL-6, whereas at a higher dose (15 microM/kg) H-7 reduced both fever and the increase of IL-6 (analysis of variance, Scheffé's test, P < 0.05). Chel (3 and 15 microM/kg) significantly reduced fever and almost completely inhibited the LPS-induced elevation of plasma IL-6. In separate experiments, we studied the effect of H-7 on antipyresis due to dexamethasone (Dex). Dex at a dose of 0.6 microM/kg given subcutaneously 1 h before LPS partially prevented fever (approximately 55% inhibition) and attenuated the increase of IL-6 (P < 0.05). Simultaneous pretreatment of the rats with Dex and H-7 (3 microM/kg; a dose that did not affect fever and IL-6 elevation) led to a potentiation of the antipyretic effect of Dex, resulting in no fever. H-7 did not potentiate, however, the inhibitory effect of Dex on LPS-induced elevation of circulating IL-6. We conclude that PKC is involved in the regulation of LPS fever and constitutes a rate-limiting factor in modulation of the fever by glucocorticoids.

Role of hypothalamic interleukin-6 and tumor necrosis factor-alpha in LPS fever in rat.

The purpose of this study was to determine, using push-pull perfusion, the levels of interleukin (IL)-1-like, IL-6-like, and tumor necrosis factor-alpha (TNF)-like activity in the anterior hypothalamus during lipopolysaccharide (LPS)-induced fever in rats. Additionally, slow anterior hypothalamic infusions of human recombinant IL-6 (hrIL-6) or TNF (hrTNF) for several hours were performed to determine possible febrile effects of these two cytokines. Artificial cerebrospinal fluid (aCSF) was infused as a control. Samples of cerebrospinal fluid were collected 60 min before and 60, 180, 300, and 420 min after the intraperitoneal injection of LPS. A control group was injected intraperitoneally with saline. The core temperature (measured by biotelemetry) of LPS-injected rats was significantly higher (P < 0.05) than the temperature of the rats injected with saline at 180, 300, and 420 min after the injection. The average postinjection IL-6 levels were significantly higher (P < 0.05) in the LPS-injected group. TNF was significantly higher (P < 0.05) than the baseline only at 180 min. There were no changes in levels of IL-1-like activity. Infusion of hrIL-6 at a level similar to the peak IL-6 level measured during LPS-induced fever resulted in a slowly developing and long-lasting increase in core temperature. Infusion of hrTNF at a level corresponding to the peak TNF level measured during LPS-induced fever did not induce a significant increase in core temperature. These results support the hypothesis that elevated hypothalamic concentrations of IL-6 are involved in the induction of fever elicited by peripheral (intraperitoneal) injection of LPS.

Systemic but not central administration of tumor necrosis factor-alpha attenuates LPS-induced fever in rats.

The purpose of this study was to test the hypothesis that tumor necrosis factor-alpha (TNF) limits fever induced by lipopolysaccharide (LPS) in rats and to determine whether such antipyretic action of this cytokine is outside or inside the central nervous system (CNS). The CNS effects on LPS-induced fever were tested by injecting a subpyrogenic amount (0.20 microgram) of human recombinant TNF (hrTNF) intracerebroventricularly or by slowly infusing into the anterior hypothalamus an amount previously measured in this brain region during LPS fever (0.24 U in 0.13 microliter of artificial cerebrospinal fluid/min). The peripheral effects of this cytokine on LPS fever were tested by injecting 1 micrograms/kg of hrTNF intraperitoneally or by intraperitoneal administration of 300 micrograms/kg of the hrTNF soluble receptor p80 (hrTNFsr). The core temperature (measured by biotelemetry) during LPS fever was not significantly affected by administration of hrTNF intracerebroventricularly or intrahypothalamically. An intraperitoneal injection of hrTNF (1 microgram/kg) had a significant antipyretic effect on febrile response to LPS (mean temperature 2-8 h after injections was 37.28 +/- 0.12 degrees C in rats injected with hrTNF and LPS vs. 38.73 +/- 0.04 degrees C in rats injected with saline and LPS; analysis of variance among groups, P = 0.0001; Fisher's protected least significant difference, P < 0.05). When rats were injected intraperitoneally with hrTNFsr, the febrile response to LPS was enhanced (analysis of variance among groups, P = 0.0001; Fisher's protected least significant difference, P < 0.05). These results support the hypothesis that TNF acts to limit the magnitude of LPS-induced fever and that this action occurs outside the CNS.