Abstract
The antinociceptive effects of interleukin (IL)-4, -10, and -13 were investigated in two different experimental pain models. Our results showed that pretreatment (30 min) with IL-4 (1–5 ng/animal), IL-10 (0.4–10 ng/animal), or IL-13 (0.4–2.5 ng/animal) inhibited the writhing response induced by the i.p. administration of acetic acid (53–89%) or zymosan (63–74%) in mice, and the knee joint incapacitation induced by i.a. injection of zymosan (49–66%) in rats. Neither of the cytokines affected the pain elicited in mice using the hot-plate test. This analgesic effect of IL-4, -10, and -13 was not reversed by the combined pretreatment with the opioid receptor antagonist naloxone. IL-4, -10, or -13 significantly inhibited the release of both tumor necrosis factor (TNF)-α (60, 53, and 100%, respectively) and IL-1β (80, 100, and 100%, respectively) by mice peritoneal macrophages obtained after local (i.p.) injection of zymosan. Antisera against IL-4, -10, and -13 potentiated both the zymosan-induced writhing response and the articular incapacitation. Our results demonstrate that IL-4, -10, and -13 display analgesic activity that is probably not due to endogenous opioid release. This analgesic effect could be related to a peripheral mechanism, probably via the inhibition of the release of the pro-inflammatory cytokines TNF-α and IL-1β by resident peritoneal macrophages.
Cytokines constitute a link between cellular injury and recognition of nonself and the development of local and systemic signs and symptoms of inflammation (Dinarello et al., 1986; Ferreira et al., 1988; Faccioli et al., 1990). In this context, it was shown in a model of mechanical hyperalgesia that carrageenin-evoked hyperalgesia results from the combined effects of the release of cyclooxygenase products and sympathomimetic amines (Nakamura and Ferreira, 1987). A cascade of cytokine release preceded the generation of these mediators. Carrageenin and lipopolysaccharide caused the release of bradykinin, which stimulated the release of TNF-α. TNF-α induced the release of IL-1β and -6, which stimulated the production of cyclooxygenase products and IL-8, which, in turn, stimulated production of sympathomimetic mediators (Cunha et al., 1991, 1992a; Ferreira et al., 1993). In a different model, the writhing test in mice, zymosan, or acetic acid-induced writhing was also mediated by cyclooxygenase products and sympathomimetic amines, the release of which was mediated by TNF-α, IL-1β, and IL-8 (Duarte et al., 1988; Thomazzi et al., 1997). These cytokines appear to be released by resident peritoneal macrophages and mast cells since the depletion of these cells from the mouse peritoneal cavity abolished the acetic acid- or zymosan-induced writhing response. Furthermore, the increase in the numbers of these cells in the peritoneal cavity enhanced the number of writhing movements induced by both stimuli (Ribeiro et al., 2000).
Within the last decade, cytokines generally regarded as anti-inflammatory have been described that inhibit the production of other cytokines such as IL-1β, -6, -8, and TNF-α, which are generally regarded as proinflammatory. The class of anti-inflammatory cytokines includes IL-4, -10, -13, and transforming growth factor-β (Hart et al., 1989; Fiorentino et al., 1991; Cassatella et al., 1993;Callard et al., 1996).
IL-10 is produced by several cell types, including Th2 lymphocytes, monocytes, macrophages, and mast cells (Fiorentino et al., 1989). IL-10 is believed to play a role in inhibiting delayed-type hypersensitivity reactions (Howard and O'Garra, 1992) and in the suppression of macrophage functions such as class II expression (De Waal Malefyt et al., 1991), adhesion (Fiorentino et al., 1991), the synthesis of proinflammatory cytokines, and the expression of COX-2 and iNOS (Bogdan et al., 1991; De Waal Malefyt et al., 1991; Fiorentino et al., 1991; Oswald et al., 1992;Cunha et al., 1992b; Niiro et al., 1995, 1997). Recently, it was shown that IL-10 inhibits the inflammatory mechanical hyperalgesia induced by carrageenin through two mechanisms: inhibition of hyperalgesic cytokine release and blockade of COX-2 induction (Poole et al., 1995).
IL-4 and -13 are produced mainly by Th2lymphocytes and by mast cells (McKenzie et al., 1993; Burd et al., 1995; De Waal Malefyt et al., 1995) and share a number of biological properties, including the inhibition of proinflammatory cytokine production (Hart et al., 1989; Callard et al., 1996; Muchamuel et al., 1997) and the induction of COX-2 and of iNOS with a consequent reduction in the production of prostaglandins and nitric oxide (Seitz et al., 1994; Niiro et al., 1995; Onoe et al., 1996). Also, IL-4 can suppress the delayed-type hypersensitivity in experimental animals and in humans (Röcken et al., 1996), possibly because of its capacity to induce Th2 cell responses. IL-13 may exert an important role in rheumatoid arthritis since it is present at high levels in synovial fluid and can inhibit the production of IL-1 and TNF by mononuclear cells (Isomaki et al., 1996). Recently, it was shown that IL-4 (probably released by local mast cells) and IL-13 (probably released by local T lymphocytes) inhibited the mechanical hyperalgesia induced by carrageenin, bradykinin, and TNF-α (Cunha et al., 1999;Lorenzetti et al., 2001). This antihyperalgesic effect appeared to be due to inhibition of prostaglandin E and cytokine production.
Given the demonstrated capacity of IL-4, -10, and -13 to inhibit mechanical hyperalgesia in rats and the production of proinflammatory hyperalgesic cytokines, the present study extended the investigation of the antinociceptive effect of these molecules, testing their possible antinociceptive effects in the writhing test in mice (Collier et al., 1968), the knee joint incapacitation test in rats (Tonussi and Ferreira, 1992), and the hot-plate test in mice (Eddy and Leimbach, 1953). This last test was used to investigate the possible central effect of these cytokines. The involvement of opioids in the antinociceptive effect of these cytokines was also investigated.
Materials and Methods
Animals
Male Swiss mice weighing 25 to 30 g and male Wistar rats (180–200 g) from the animal colony of the Federal University of Ceará were used for nociceptive tests. The animals received water and food ad libitum. The ethical guidelines in the NIH Guide for Care and Use of Laboratory Animals were followed throughout the experiments described.
Nociceptive Tests
Writhing Test.
The writhing test is described in detail elsewhere (Collier et al., 1968). Zymosan or acetic acid were injected into the peritoneal cavities of mice, which were placed in a large glass cylinder, and the intensity of nociception was quantified by counting the total number of writhings occurring between 0 and 30 min after stimulus injection. The writhing response consists of a contraction of the abdominal muscles together with a stretching of the hind limbs. The doses of the nociceptive stimuli were: zymosan (1 mg/0.2 ml/mouse) and acetic acid (0.1 ml/10 g body weight of a 0.6% v/v solution).
Rat Knee Joint Incapacitation Test.
The rat knee joint incapacitation test is described in detail elsewhere (Tonussi and Ferreira, 1992; Rocha et al., 1999). In this test, a computer-assisted device measures the length of time that a specific hind paw fails to touch the surface of a rotating cylinder in a 1-min period (paw elevation time). In normal animals, paw elevation time is approximately 10 to 15 s. In our experiments, incapacitation was studied in animals injected with zymosan (1 mg/animal) into the knee joint, and the period for which the hind paw failed to touch the rotating cylinder was interpreted as being proportional to the pain felt by the animal. Paw elevation time was measured before zymosan administration (control time, T0) and, thereafter, every hour for 4 h (T1,T2,T3, andT4). The results were expressed as Δ paw elevation time [T(1–4) −T0].
Hot-Plate Test.
Reaction times were measured by the low-temperature (51.5 ± 2°C) hot-plate method described by Eddy and Leimbach (1953). Each mouse was subjected to two trials on the hot plate separated by a 30-min interval. The first trial was used for habituation of the animals with the test procedure. The second trial served to obtain the control reaction time (licking of the hind feet or jumping) for each animal. Male Swiss mice were preselected, and animal showing a reaction time greater than 10 s were discarded. The reaction time for each mouse was determined on the hot-plate surface before and 30, 60, and 90 min after drug administration. To avoid injuries, the animals were never left more than 40 s on the hot plate.
Production of TNF-α and IL-1β by Cells Harvested from Peritoneal Cavities Stimulated with Zymosan
Saline (0.2 ml) or zymosan (1 mg/0.2 ml) was injected i.p. in the mice. After 15 min, the peritoneal cavities were washed with saline (1 ml/cavity), and the exudates were centrifuged at 300 g for 10 min. Pelleted cells were resuspended in 500 μl of RPMI 1640 medium supplemented with 10% fetal calf serum; cells were then counted, and 5 × 105 cells were plated onto 48-well plastic tissue culture plates. The concentrations of TNF-α and IL-1β in the supernatants after 12 h of culture were determined by an enzyme-linked immunosorbent assay, as described previously (Cunha et al., 1999). Briefly, microtiter plates were coated overnight at 4°C with an antibody against murine TNF-α or IL-1β (10 μg/ml). After blocking the plates, the samples and standards at various dilutions were added in duplicate and incubated at 4°C for 24 h. The plates were washed three times with buffer, and a second biotinylated polyclonal antibody against TNF-α or IL-1β (diluted 1/1000; 100 μl/well) was added. After a further incubation at room temperature for 1 h, the plates were washed, and 100 μl of avidin-horseradish peroxidase, diluted 1:5000, was added.O-Phenylenediamine color reagent (100 μl) was added 15 min later, and the plates were incubated in the dark at 37°C for 15 to 20 min. The enzyme reaction was stopped with H2SO4, and the absorbency at 490 nM was measured. Results are reported as means ± S.E.M. of three animals.
Experimental Protocols
Effect of Pretreatment with IL-4, -10, and -13 on the Writhing Response Induced by Acetic Acid or Zymosan.
Mice were treated i.p. with murine IL-4 (1–5 ng/cavity), IL-10 (0.4–10 ng/cavity), or human IL-13 (0.4–2.5 ng/cavity), and after 30 min, zymosan (1 mg/0.2 ml/mouse) or 0.1 ml/10 g body weight of acetic acid solution at concentration of 0.6% (v/v) was injected i.p. The number of writhes was counted as described above.
Effect of Pretreatment with IL-4, -10, and -13 on the Rat Knee Joint Incapacitation Induced by Zymosan.
Rats were treated i.p. with human IL-4 (1–5 ng/cavity), IL-10 (2–10 ng/cavity), or IL-13 (1–2.5 ng/cavity), and after 30 min, zymosan (1 mg/joint) was injected i.a. in a volume of 50 μl. Incapacitation was measured as described above.
Effect of IL-4, -10, and -13 in the Hot-Plate Test.
Immediately after determination of control reaction time (see above), groups of six mice were treated i.p. with saline, IL-4 (5 ng/cavity), IL-10 (10 ng/cavity), IL-13 (2.5 ng/cavity), morphine (5 mg/kg), or indomethacin (2 mg/kg) in a volume of 0.2 ml. The reaction time was measured 30, 60, and 90 min after the treatment.
Effect of Pretreatment with Naloxone upon the Antinociceptive Activity of IL-4, -10, and -13 in Acetic Acid-Induced Writhings in Mice.
Mice were pretreated s.c. with saline or naloxone (2 mg/kg). Fifteen minutes later they were injected i.p. with saline, murine IL-4 (5 ng/cavity), murine IL-10 (10 ng/cavity), human IL-13 (2.5 ng/cavity), or morphine (5 mg/kg). Thirty minutes after, acetic acid (0.1 ml/10 g body weight of a 0.6% v/v solution) was injected i.p., and the number of writhings was determined as described above.
Effect of IL-4, -10, and -13 Pretreatment upon TNF-α and IL-1β Production by Peritoneal Cells Harvested from Cavities Stimulated with Zymosan.
Mice were pretreated i.p. with murine IL-4 (5 ng/cavity), murine IL-10 (10 ng/cavity), or human IL-13 (2.5 ng/cavity) 30 min before the i.p. administration of zymosan (1 mg/cavity). The control group received only saline (S) (0.2 ml) and a nontreated (NT) group received saline before the zymosan. After 15 min, total resident peritoneal cells were harvested with RPMI 1640 culture medium, plated (5 × 105 cells/well) and incubated in a CO2 incubator. TNF-α and IL-1β levels were measured in the supernatants after 12 h of culture.
Effect of Antisera against Interleukin-4, -10, and -13 upon the Nociceptive Activity of Zymosan in the Writhing Test.
Fifty microliters of antiserum against murine interleukin-4, -10, or -13, or of a control (preimmune) serum were diluted in 250 μl of saline and then injected into the peritoneal cavities of mice; 15 min later, animals received an i.p. injection of zymosan (500 μg/0.2 ml/mouse). The writhings were counted as described above.
Effect of Antisera against Interleukin-4, -10, and 13 upon the Nociceptive Activity of Zymosan in the Rat Knee Joint Incapacitation Test.
Fifty microliters of antiserum against rat interleukin-4, -10, or -13, or of a control (preimmune) serum were injected into the rat right knee joint cavity; 15 min later, zymosan (500 μg/25 μl/cavity) was injected into the same articular cavity. Articular incapacitation was measured as described above.
Compounds
The following materials were obtained from the sources indicated: zymosan A (Sigma-Aldrich, St. Louis, MO), glacial acetic acid (Merck, São Paulo, Brazil), indomethacin (Merck, Sharp and Dohme-MSD, São Paulo, Brazil), morphine (Cristalia-Brazil, São Paulo, Brazil), naloxone (Rhodia Farma, São Paulo, Brazil). Recombinant human and murine IL-4, human and murine IL-10, and human IL-13 [National Institute for Biological Standards and Control (NIBSC) preparations coded: 88/656, 92/516, and 94/662]. The specific activities of these materials are: IL-4, 1000 IU 100 ng−1 ampoule−1; IL-10, 5000 IU 1 μg−1ampoule−1; and IL-13, 1000 IU 1 mg−1 ampoule−1. Zymosan, morphine, naloxone, and the cytokines used were all diluted in a 0.9% NaCl solution. Indomethacin was diluted in a 5% NaHCO3 solution, and pH was adjusted to 8.0 using 0.1 N HCl. Glacial acetic acid was diluted in deionized water. Sheep anti-murine or anti-rat IL-4, -10, and -13 sera, and preimmune serum were NIBSC preparations.
Data Analysis
Results are presented as means ± S.E.M. of measurements made on at least six animals in each group. Differences between responses were evaluated by analysis of variance followed by Tukey's test. Statistical differences were considered to be significant atp < 0.05.
Results
Effect of Pretreatment with IL-4, -10, and -13 on the Writhing Response to Acetic Acid or Zymosan.
The intraperitoneal injection in mice of 0.1 ml/10 g body weight of a 0.6% (v/v) solution of acetic acid or zymosan (1 mg/mouse) induced a writhing response between 0 and 30 min later. IL-4 (1–5 ng/cavity), IL-10 (0.4–10 ng/cavity), or IL-13 (0.4–2.5 ng/cavity) injected i.p. 30 min before either of the stimuli significantly inhibited the nociceptive response (p < 0.001) with 59, 53, and 89% of inhibition on average for the different doses when the stimulus was acetic acid (Fig.1A) and 63, 74, and 62% on average for the different doses when the stimulus was zymosan (Zym) (Fig. 1B), for IL-4, -10, and -13, respectively.
Effect of Pretreatment with IL-4, -10, and -13 on the Rat Knee Joint Incapacitation Induced by Zymosan.
The intra-articular injection of zymosan (1 mg/cavity) induced articular incapacitation, which was maximal in the 3rd and 4th h after stimulus injection. IL-4 at a dose of 5 ng/cavity, but not at a dose of 1 ng/cavity, significantly inhibited the zymosan-evoked nociception in the 3rd h by 49% (p < 0.01; Fig.2A). IL-10 (2 and 10 ng/cavity) blocked the nociceptive effect in the 3rd and 4th h by 65 and 66% (p < 0.01), respectively (Fig. 2B). IL-13 (1 and 2.5 ng/cavity) inhibited the nociceptive response in the 3rd h by 57% (p < 0.05), but only the dose of 1 ng/cavity was effective in the 4th h of incapacitation (35%; p < 0.05) when compared with the control group (Fig. 2C).
Effect of IL-4, -10, and -13 on the Hot-plate Response.
IL-4 (5 ng/cavity), IL-10 (10 ng/cavity), IL-13 (2.5 ng/cavity), or indomethacin (2 mg/kg) administrated i.p. to mice did not alter the reaction time during 90 min of observation. In contrast, morphine (5 mg/kg, i.p.), used as a positive control, caused a significant elevation (up to 660%) of the reaction time of the animals during this period (Fig. 3).
Effect of Pretreatment with Naloxone Upon the Antinociceptive Activity of IL-4, -10, and -13 in Acetic Acid-Induced Writhing in Mice.
Subcutaneous injection of naloxone 15 min before IL-4 (5 ng/cavity), IL-10 (10 ng/cavity), or IL-13 (2.5 ng/cavity) did not affect the antinociceptive activity of these cytokines in the writhing response to acetic acid (0.1 ml/10 g body weight of a 0.6% v/v solution) in mice. This dose of naloxone, however, blocked the analgesic effect of morphine (5 mg/kg, i.p.; Fig.4). In the same manner, naloxone had no effect upon antinociceptive activity of the cytokines on articular incapacitation induced by zymosan (data not shown).
Effect of IL-4, -10, and IL-13 upon TNF-α and IL-1β Production by Peritoneal Cells Harvested from Cavities Stimulated with Zymosan.
The peritoneal cells harvested from cavities stimulated 15 min before with zymosan (1 mg/animal) released significant amounts of TNF-α and IL-1β into the supernatant after incubation for 12 h in vitro compared with the cells harvested from cavities injected only with saline. IL-4 (5 ng/cavity), IL-10 (10 ng/cavity), or IL-13 (2.5 ng/cavity) pretreatment caused a significant decrease of both TNF-α (60%, p < 0.05; 53%, p< 0.05; 100%, p < 0.001, respectively) and IL-1β (80%, p < 0.05; 100%, p < 0.001; 100%, p < 0.001, respectively) release when compared with the zymosan-only group (Fig. 5).
Potentiation by Antisera Against Interleukin-4, -10, or -13 of the Nociceptive Response to Zymosan in the Writhing Test in Mice.
Antisera against IL-4, -10, and -13 (50 μl; i.p.), but not a preimmune (control) serum (50 μl; i.p.), injected 15 min before zymosan (500 μg/0.2 ml/mouse; i.p.) potentiated the zymosan-induced nociceptive writhing response: Ab IL-4 = 63% (p< 0.05); Ab IL-10 = 95% (p < 0.01), and Ab IL-13 = 95% (p < 0.01; Fig.6A).
Potentiation by Antisera Against Interleukin-4, -10, or -13 of the Nociceptive Response to Zymosan in the Rat Knee Joint Incapacitation Test.
Antisera against IL-4, -10, or -13 (50 μl i.a.), but not a preimmune (control) serum (50 μl i.a.), injected 15 min before zymosan (500 μg/25 μl/cavity; i.a.) potentiated the zymosan-induced nociception in the knee joint when compared with nontreated animals: Ab IL-4 = 181% (p < 0.05), Ab IL-10 = 222% (p < 0.05), and Ab IL-13 = 287% (p < 0.001; Fig. 6B).
Discussion
IL-4, -10, and -13 are classified as anti-inflammatory cytokines. The principal anti-inflammatory activities of these molecules are a consequence of their capacity to inhibit the production of proinflammatory cytokines such as IL-1β, -6, -12, -18, TNF-α, and chemokines (Hart et al., 1989; De Waal Malefyt et al., 1991; Fiorentino et al., 1991; Cassatella et al., 1993; Isomaki et al., 1996; Muchamuel et al., 1997). Moreover, they also inhibit the induction of the enzymes COX-2 and iNOS, which are involved in the production of prostaglandins and NO, respectively (Cunha et al., 1992b; Niiro et al., 1995; Onoe et al., 1996; Niiro et al., 1997). Using a model of inflammatory mechanical hyperalgesia (a rat paw pressure test), it was shown that IL-4, -10, and -13 have antihyperalgesic effects. These antihyperalgesic effects are due to inhibition of the release of hyperalgesic cytokines and also eicosanoids, although we cannot exclude the possibility of the involvement of other mediators (Poole et al., 1995; Cunha et al., 1999; Lorenzetti et al., 2001).
In the present study, we demonstrated that IL-4, -10, and -13 inhibited the writhing response in mice after the intraperitoneal injection of zymosan or acetic acid, and the knee-joint incapacitation induced by the intra-articular injection of zymosan into the rat knee joints. The mediators involved in the genesis of the nociception observed in the writhing test are the eicosanoids and sympathomimetic amines, the release of which is preceded by the release of the nociceptive cytokines TNF-α, IL-1β, and IL-8 (Duarte et al., 1988; Thomazzi et al., 1997; Ribeiro et al., 2000). The rat knee-joint incapacitation test was designed for the study of articular incapacitation, defined as the inability of a rat subjected to an experimentally induced arthritis to deambulate normally (Tonussi and Ferreira, 1992). In this test, articular incapacitation is assumed to be due to altered nociception following injection of an inflammatory substance, such as carrageenin or zymosan, into the joints (Tonussi and Ferreira, 1992;Rocha et al., 1999). After zymosan injection, the animals display a progressive articular incapacitation that begins in the 2nd h and is maximal between the 3rd and 4th h of arthritis (Rocha et al., 1999). Eicosanoids and TNF-α are involved in the genesis of the knee joint incapacitation (Tonussi and Ferreira, 1992; Rocha et al., 1999).
There is evidence in the literature showing that several cytokines, including peripherally released IL-10, are able to cross the blood-brain barrier and act on the central nervous system (Di Santo et al., 1997). To investigate a possible central component of IL-4, -10, and IL-13 antinociceptive effects, the hot-plate test was used. Although morphine, used as a control, caused a significant elevation in the test reaction time, the cytokines had no effect. There is evidence in the literature, however, showing that IL-10 injected peripherally is able to inhibit pain behavior following intraspinal injection of quisqualic acid (Plunkett et al., 2001). The use of different experimental models could explain these apparently conflicting results. Although we used the hot-plate test in this study, other authors have used a model in which there is a marked expression of inflammatory cytokines within the central nervous system (Di Santo et al., 1997;Plunkett et al., 2001). In our study, IL-4, -10, and -13 seem to exert their antinociceptive effect through a peripheral mechanism via inhibition of the release of proinflammatory cytokines, although we cannot exclude the interference of a centrally derived mechanism.
It is known that some cytokines can stimulate endogenous opioid release (Czlonkowski et al., 1993). In this context, we found that IL-4, -10, and -13 differed from morphine in that their antinociceptive actions were not reversed by pretreatment with naloxone (an opioid antagonist), suggesting that endogenous opioids probably are not involved in the analgesic effect of these cytokines.
Recently, we have demonstrated that the writhing response induced by zymosan and acetic acid in mice is dependent on the presence of resident peritoneal macrophages and mast cells and the consequent release of IL-1β and TNF-α by these cells. It was shown that reduction of the peritoneal macrophage or mast cell population significantly inhibited the zymosan- or acetic acid-induced writhing response. On the other hand, increasing the peritoneal macrophage population caused an increase in the number of writhings induced by both stimuli (Ribeiro et al., 2000). It was also found that the mediators involved in the abdominal writhing test are multiple and include sympathomimetic amines and eicosanoids. Previous data from our group have shown that the release of these pronociceptive substances is preceded by the release of the proinflammatory cytokines IL-1, TNF, and IL-8 in zymosan and acetic acid induced writhes (Duarte et al., 1988;Thomazzi et al., 1997; Ribeiro et al., 2000). In the present study, we demonstrated that intraperitoneal administration of IL-4, -10, or -13 inhibited the release of IL-1β and TNF-α by macrophages harvested from the peritoneal cavity after zymosan injection. These molecules also inhibit the production of eicosanoids by macrophages harvested from peritoneal cavities of mice and stimulated by cytokines (Poole et al., 1995; Cunha et al., 1999; Lorenzetti et al., 2001). These results suggest that the antinociceptive effects of the cytokines used in this study are due to inhibition both of the release by resident peritoneal cells of cytokines that mediate nociception, such as TNF-α and IL-1β, and also the expression of COX-2 induced by these cytokines.
The potentiation of the zymosan-induced writhing response and knee joint incapacitation by specific antibodies to IL-4, -10, and IL-13 suggests that endogenous release of these cytokines has a role in limiting the development of the nociceptive response at least during inflammatory pain reactions. In previous studies, we have demonstrated that antibodies against IL-4, -10, and -13 also potentiated the mechanical hyperalgesia induced by intraplantar injection of carrageenin and that the potentiation was due to inhibition of the release of inflammatory cytokines (Poole et al., 1995; Cunha et al., 1999; Lorenzetti et al., 2001).
In summary, our data provide evidence that IL-4, -10, and -13 display antinociceptive activity that is at least partially due to the inhibition of the release of the proinflammatory cytokines IL-1 and TNF. Additionally, these analgesic cytokines may exert an endogenous down-regulating effect in the release of the eicosanoids. The fact that these cytokines share a similar analgesic effect suggest that a common pathogenic pathway downstream from the receptor coupling of these cytokines may be operating. Such a mechanism could be an interesting target to develop new analgesic therapeutic options.
Acknowledgments
We are grateful for the technical assistance of Sérgio Roberto Rosa and Giuliana Bertozzi Francisco.
Footnotes
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This work was supported by the grants from the following Brazilian Foundations: Fundação de Amparo àPesquisa no Estado de São Paulo, Conselho Nacional de Desenvolvimento Cientı́fico e Tecnológico (Pronex), and Coordenação de Aperfeiçoamento de Pessoal de Nı́vel Superior (Procad).
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DOI: 10.1124/jpet.102.038703
- Abbreviations:
- TNF
- tumor necrosis factor
- IL
- interleukin
- COX
- cyclooxygenase
- iNOS
- inducible nitric oxide synthase
- S
- saline
- NT
- nontreated
- Zym
- zymosan
- Ab IL
- antiserum against interleukin
- Received May 14, 2002.
- Accepted September 4, 2002.
- The American Society for Pharmacology and Experimental Therapeutics