Endogenous opioids: role in prostaglandin-dependent and -independent fever

Fraga, Daniel; Machado, Renes R.; Fernandes, Luíz Cláudio; Souza, Glória Emília Petto de; Zampronio, Aleksander Roberto

doi:10.1152/ajpregu.00465.2007

Cited by 30 publications

(27 citation statements)

References 56 publications

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“…Nevertheless, it is clear from the results of our study and from the results of mammalian studies that IL-6 and PGs are not exclusively responsible for LPS-induced fevers. Macrophage inflammatory protein-1␤, corticotropin-releasing factor, and endothelin-1 have been identified as PG-independent mediators of fever in mammals (11,12). In addition, Fraga et al (12) showed that, in mammals, LPS and endogenous pyrogens (except IL-1␤ and PGs) recruit the opioid system to cause a -receptor-mediated fever independent of PG.…”

Section: Absence Of Pge 2 In Csf Of Lps-treated Pekin Ducksmentioning

confidence: 99%

Brain IL-6- and PG-dependent actions of IL-1β and lipopolysaccharide in avian fever

Marais

Maloney

Gray

2011

American Journal of Physiology-Regulatory, Integrative and Comp

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Marais M, Maloney SK, Gray DA. Brain IL-6-and PG-dependent actions of IL-1␤ and lipopolysaccharide in avian fever. Am J Physiol Regul Integr Comp Physiol 301: R791-R800, 2011. First published June 15, 2011; doi:10.1152/ajpregu.00136.2011There is no persuasive evidence of a correlation between proinflammatory cytokines and avian fever. In this study, for the first time, we use avian cytokines to investigate a role for proinflammatory cytokines in the central component of avian fever. IL-1␤ and IL-6 injected intracerebroventricularly into Pekin ducks (n ϭ 8) initiated robust fevers of equal magnitude and duration, although there was a significant difference in the latency to a febrile response. In addition, the IL-1␤-induced fever could be abolished with an intracerebroventricular injection of antibodies to avian IL-6 or an oral administration of a PG synthesis inhibitor. Our findings indicate the following sequence of events within the central component of the avian febrile mechanism: IL-1␤ gives rise to bioactive IL-6, which stimulates an accelerated synthesis of PGs, and these PGs then adjust the sensitivity of warmsensitive neurons in the avian brain stem to mediate fever. Yet PGE 2 was not upregulated in the cerebrospinal fluid of ducks made febrile with LPS. We conclude that IL-1␤ and IL-6 may well mediate fever by instigating an accelerated synthesis of brain-derived PG, of a class other than PGE2, or that IL-6 serves as one of the terminal mediators of the avian febrile response.interleukin-1␤; interleukin-6; Pekin duck; prostaglandin E2 BIRDS, LIKE MAMMALS, DEVELOP fever when exposed to viruses and bacteria (25). The physiological mechanism responsible for febrile mediation in birds has not been elucidated. In homeothermic animals, thermoregulation is controlled by the central nervous system; therefore, fever, a nonthermal modifier of thermoregulation, requires adjustment of thermoregulatory controllers in the brain (35,46). The hypothalamus, with its temperature-sensitive neurons, serves as the dominant controller of temperature regulation in mammals, whereas the rostral brain stem is thought to house neurons that govern body temperature in birds (46). Despite these phylogenetic differences, it is clear that, in mammals and in birds, peripheral activation of the innate immune system results in physiological modifications at the site of thermoregulatory control.In mammals, proinflammatory cytokines, specifically IL-1␤ and IL-6, are known to act as mediators between the detection of an infectious stimulus by immune cells in the periphery and the stimulation of fever (5,(35)(36)(37). IL-1␤ is thought to activate IL-6, and circulating IL-6 concentrations are correlated with the upregulated expression of PG-synthesizing enzymes in the periphery and in brain vasculature (5,34,49). Humoral PGE 2 , produced by macrophages of the lungs and liver, was shown to initiate the first febrile phase in mammals (49), while subsequent febrile phases are thought to be mediated by an upregulated expression of PGE 2 in the br...

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Section: Absence Of Pge 2 In Csf Of Lps-treated Pekin Ducksmentioning

confidence: 99%

Brain IL-6- and PG-dependent actions of IL-1β and lipopolysaccharide in avian fever

Marais

Maloney

Gray

2011

American Journal of Physiology-Regulatory, Integrative and Comp

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“…injected zymosan. We previously found that eOPs participate in the febrile response that is induced by ET-1 and CRF but not prostaglandins [20]. Kanashiro et al [24] reported that ET-1 and CRF do not participate in the febrile response induced by i.a.…”

Section: Discussionmentioning

confidence: 87%

“…The CRF/ET-1 pathway is not involved in i.a. zymosan-induced fever [24], indicating that the eOPs are not released through the CRF or ET-1 during the febrile response; instead, they appear to be released through cytokines, such as TNF-α and IL-6 [20,21].…”

Section: Discussionmentioning

confidence: 99%

“…The first study that suggested that endogenous opioids (eOPs) also participated in the LPS-induced febrile response was published by Blatteis et al [19]. Fraga et al [20] further confirmed these results by proving that μ-opioid receptors (MORs) are involved in modulating fever. Some redundancy in the pathways that lead to the release of these central mediators (i.e.…”

Section: Introductionmentioning

confidence: 95%

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Central mediators of the zymosan-induced febrile response

Bastos-Pereira

Fraga

Dreifuss

et al. 2017

Journal of Basic and Clinical Physiology and Pharmacology

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Background: Zymosan is a fungal cell wall protein-carbohydrate complex that is known to activate inflammatory pathways through the Toll-like receptors and is commonly used to induce fever. Nevertheless, the central mediators that are involved in the zymosan-induced febrile response are only partially known. Methods:The present study evaluated the participation of prostaglandins, substance P, endothelin-1 (ET-1), and endogenous opioids (eOPs) in the zymosan-induced febrile response by using inhibitors and antagonists in male Wistar rats. Results: Both nonselective (indomethacin) and selective (celecoxib) cyclooxygenase inhibitors reduced the febrile response induced by an intraperitoneal (i.p.) injection of zymosan. Indomethacin also blocked the increase in the prostaglandin E 2 levels in the cerebrospinal fluid. An intracerebroventricular injection of the neurokinin-1, ET B , and μ-opioid receptor antagonists also reduced the febrile response induced by the i.p. injected zymosan. Moreover, the μ-opioid receptor antagonist CTAP also reduced the febrile response induced by intra-articular injection of zymosan.Conclusions: These results demonstrate that prostaglandins, substance P, ET-1, and eOPs are central mediators of the zymosan-induced febrile response.

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“…POMC peptide is a precursor for several biologically active neuropeptides including ␣-MSH, ␤-endorphin, and ACTH (40). Of particular interest to the current study is ␤-endorphin as blockade of -opioid receptor, one of the receptors for ␤-endorphin either by specific antagonists or genetic mutation abrogates the fever response induced by classical pyrogens including LPS (4,5,16,44,61) via several different mechanisms, including a central hypothermic action, peripheral vasodilation, and peripheral antipyretic activity (44).…”

Section: Discussionmentioning

confidence: 99%

Acute starvation alters lipopolysaccharide-induced fever in leptin-dependent and -independent mechanisms in rats

Inoue

Luheshi

2010

American Journal of Physiology-Regulatory, Integrative and Comp

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Inoue W, Luheshi GN. Acute starvation alters lipopolysaccharideinduced fever in leptin-dependent and -independent mechanisms in rats. Am J Physiol Regul Integr Comp Physiol 299: R1709 -R1719, 2010. First published October 13, 2010; doi:10.1152/ajpregu.00567.2010.-A decrease in leptin levels with the onset of starvation triggers a myriad of physiological responses including immunosuppression and hypometabolism/hypothermia, both of which can counteract the fever response to pathogens. Here we examined the role of leptin in LPSinduced fever in rats that were fasted for 48 h prior to inflammation with or without leptin replacement (12 g/day). The preinflammation fasting alone caused a progressive hypothermia that was almost completely reversed by leptin replacement. The LPS (100 g/kg)-induced elevation in core body temperature (Tcore) was attenuated in the fasted animals at 2-6 h after the injection, an effect that was not reversed by leptin replacement. Increasing the LPS dose to 1,000 g/kg caused a long-lasting fever that remained unabated for up to 36 h after the injection in the fed rats. This sustained response was strongly attenuated in the fasted rats whose T core started to decrease by 18 h after the injection. Leptin replacement almost completely restored the prolonged fever. The attenuation of the prolonged fever in the fasted animals was accompanied by the diminution of proinflammatory PGE 2 in the cerebrospinal fluid and mRNA of proopiomelanocortin (POMC) in the hypothalamus. Leptin replacement prevented the fasting-induced reduction of POMC but not PGE 2 . Moreover, the leptin-dependent fever maintenance correlated closely with hypothalamic POMC levels (r ϭ 0.77, P Ͻ 0.001). These results suggest that reduced leptin levels during starvation attenuate the sustained fever response by lowering hypothalamic POMC tone but not PGE 2 synthesis. fasting; energy balance; prostaglandin; proopiomelanocortin FEVER IS A COMMON RESPONSE to various types of infection and constitutes an important component of an adaptive strategy for fighting disease (18,29). The development of fever is a finely tuned, complex event that involves both the immune and the central nervous systems through which a series of inflammatory, thermoregulatory, and metabolic processes are regulated (46). The sum of the changes required to mount an effective fever response is an energy-demanding process that can be influenced by the energy status of the host. This was clearly shown by a number of studies reporting that malnutrition prior to the induction of inflammation compromises the fever response in various species of experimental animals (20,21,24,28,30,53,54,60). The suggested explanations for this observation include suppression of inflammatory responses (20,21,53), an alteration of the thermoregulatory response (24, 30), and an attenuation of thermogenic effecter activity (28, 54). However, it remains unclear how the signal relating to the reduced energy status of the host is relayed to the aforementioned fever-related functions and subseq...

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Endogenous opioids: role in prostaglandin-dependent and -independent fever

Cited by 30 publications

References 56 publications

Brain IL-6- and PG-dependent actions of IL-1β and lipopolysaccharide in avian fever

Brain IL-6- and PG-dependent actions of IL-1β and lipopolysaccharide in avian fever

Central mediators of the zymosan-induced febrile response

Acute starvation alters lipopolysaccharide-induced fever in leptin-dependent and -independent mechanisms in rats

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