Comparative study of several lymphocyte functions in two strains of mice with different models of endotoxic shock

Previously, the changes in phagocyte functions such as adherence, chemotaxis or TNFalpha production were found to be associated with oxidative stress in endotoxin-induced septic shock. However, in this type of oxidative stress the lymphocyte involvement has rarely been studied. In the present report, we analyzed the above functions in peritoneal lymphocytes from male and female BALB/c mice with a lethal endotoxic shock caused by intraperitoneal injection of E. coli lipopolysaccharide (LPS) (100 mg/kg), male and female Swiss mice with lethal endotoxic shock caused by intraperitoneal injection of LPS (150 and 250 mg/kg, respectively) or non-lethal endotoxic shock (100 mg/kg). In peritoneal lymphocytes obtained at 0, 2, 4, 12 or 24 h after LPS injection, the first two functions of these cells in the immune response, i.e. adherence to tissues and directed migration (chemotaxis), were studied. At 0, 0.5, 1, 1.5, 2, 4, 12 and 24 h after LPS injection, TNFalpha released by lymphocytes was also analyzed. The results show that endotoxic shock increases the adherence and TNFalpha release, and decreases the chemotaxis of peritoneal lymphocytes. These changes were more significant in mice with lethal than with non-lethal endotoxic shock, a fact that confirms the important role of lymphocytes during endotoxic shock.     

Changes in the superoxide production and other macrophage functions could be related to the mortality of mice with endotoxin-induced oxidative stress

Free radicals and proinflammatory cytokines from phagocytes have been implicated in the pathogenesis of endotoxic shock, a disease with high mortality caused by Gram-negative bacterial endotoxin. In the present study, male BALB/c and Swiss mice received intraperitoneally lipopolysaccharide (LPS) at 100 mg/kg and 150 mg/kg, respectively, that led to a lethal endotoxic shock (100 % of mortality before 30 h). Swiss mice injected with 100 mg/kg, that did not show lethal endotoxic shock, were also studied. Peritoneal macrophages were obtained from animals at 2, 4, 12 or 24 h after injection of LPS or saline (control) solutions. Superoxide anion and tumor necrosis factor (TNFalpha) production were determined in these cells as well as other functions such as adherence capacity, chemotaxis and phagocytosis. The increase in superoxide anion production after endotoxin injection was higher in cells from mice with lethal shock than in those with non-lethal shock. However, the enhancement of TNFalpha production was similar in all cases, although in Swiss mice the highest levels of TNFalpha were observed at 1.5 h after endotoxin injection, while in BALB/c mice they occurred at 2 h after LPS injection. This oxidative stress was also revealed by the other functions analyzed, since adherence to substrate and phagocytosis were stimulated and chemotaxis was decreased after endotoxin injection as compared to controls, the differences being even more significant in animals with lethal shock. These data suggest that these changes, mainly the increased production of free radicals even more than the TNFalpha release, could be involved in mouse mortality caused by LPS.     

Protective effect of wogonin on endotoxin-induced lethal shock in D-galactosamine-sensitized mice.

The effects of wogonin, a major flavonoid from Scutellaria baicalensis Georgi, on lipopolysaccharide (LPS)-induced lethal shock in mice was investigated. Wogonin pretreatment prevented the lethal shock in mice injected with D-galactosamine (D-GalN) and LPS, but not in mice injected with a high dose of LPS. Wogonin definitely inhibited the hepatic injury in mice injected with D-GalN, and LPS and reduced the level of circulating tumor necrosis factor (TNF)-alpha. The reduction was more marked in mice injected with D-GalN and LPS compared with that in mice injected with a high dose of LPS. Wogonin pretreatment did not inhibit the lipid peroxidation in mice receiving either D-GalN and LPS or a high dose of LPS. Wogonin inhibited the in vitro production of TNF-alpha and nitric oxide in LPS-stimulated RAW 264.7 cells. The mechanism of the protective effect of wogonin on the lethal shock in mice injected with D-GalN and LPS is discussed.     

Sensitization and desensitization to lethal effects of tumor necrosis factor and IL-1

BALB/c mice were sensitized to lethal effects of human rTNF-alpha and of human rIL-1 alpha by simultaneous treatment with sublethal doses of actinomycin D (Act D) or D-galactosamine (GalN). In contrast, treatment with sublethal doses of TNF or IL-1 themselves resulted in desensitization of the mice to the lethal effect of these cytokines: mice injected with TNF or IL-1 in the absence of Act D or GalN responded to a second injection of TNF or IL-1, this time together with Act D or GalN, by a significantly delayed death, or even survived. Desensitization developed rapidly (0.5-1.0 h) and abated 24 to 48 h postinjection. Each of the two cytokines induced hyporesponsiveness to its own lethal effect as well as to that of the other. Injection of TNF or IL-1 at sublethal doses resulted also in hyporesponsiveness to the lethal effect of LPS on mice primed with bacillus Calmette-Guérin, an effect which most likely is mediated by TNF and IL-1 produced in those mice in response to the LPS. TNF and IL-1 in combination had an additive effect both in lethality and in desensitization of the mice. These findings suggest that some of the deleterious effects of TNF and IL-1 are modulated by antagonistic mechanisms; mechanisms which can be suppressed by sensitizing agents, specifically by agents inhibiting the synthesis of RNA or protein; but which, in the absence of such agents, are found to be augmented in response to TNF and IL-1, thus resulting in desensitization.     

Flavonoids protect mice from two types of lethal shock induced by endotoxin

The protective effect of flavonoids on two types of lethal endotoxic shock was studied. A lethal endotoxic shock was induced by administration of lipopolysaccharide (LPS) into D-galactosamine (D-GalN)-sensitized mice and another one was done by administration of a high dose of LPS into normal mice. Pretreatment with a series of flavonoids protected mice from two types of endotoxin lethality. Flavonoid pretreatment reduced the serum tumor necrosis factor-alpha (TNF-alpha) level in mice injected with D-GalN and LPS, but not in mice injected with a high dose of LPS. TNF-alpha-induced lethal shock in D-GalN-sensitized mice was also protected by pretreatment with flavonoids, suggesting that flavonoids augmented the resistance to TNF-alpha lethality. On the other hand, flavonoids reduced the plasma level of lipid peroxides in mice injected with a high dose of LPS, but not in D-GalN-sensitized mice. Taken together, these results indicated that flavonoids might protect mice from two types of endotoxin lethality. The protective mechanism of flavonoids in each endotoxin lethality is discussed.     

Several functions of immune cells in mice changed by oxidative stress caused by endotoxin

We have studied natural killer (NK) activity, lymphoproliferative response, the release of several cytokines (IL-2, TNF alpha and IL-1 beta) and the ROS production in peritoneal leukocytes obtained 0, 2, 4, 12 and 24 h after lipopolysaccharide (LPS) injection. Lethal septic shock (100 % mortality occurred at 30 h after LPS administration) was caused in female BALB/c mice by intraperitoneal injection of 100 mg/kg of E. coli LPS. Cytotoxicity and lymphoproliferation assay were preformed together with the measurement of IL-1 beta, IL-2 and TNF alpha production, and quantification of ROS. Natural killer activity, spontaneous lymphoproliferative response, IL-2, TNF alpha, IL-beta release and ROS production were increased after LPS injection. In conclusions, ROS and proinflammatory mediators produced by immune cells in response to LPS are involved in the oxidative stress of endotoxic shock. This oxidative state alters some functional characteristics of leukocytes (proliferation and NK activity).     

High serum IL-6 level reflects susceptible status of the host to endotoxin and IL-1/tumor necrosis factor.

Patients with high level of serum endotoxin did not necessarily develop into lethal shock, whereas some patients died of septic shock even when their serum endotoxin levels were low. These results indicate that limiting factor which determines the host to be endotoxin shock principally depends on the host susceptibility to endotoxin instead of serum endotoxin level. To understand this susceptible status of the host to endotoxin, we used Propionibacterium acnes primed mouse endotoxin shock model. We found that P. acnes-primed mice responded to low dose of LPS by enhanced production of IL-1 and TNF. And such mice were highly susceptible to the lethal shock inducing effect of IL-1 and/or TNF, which also induced high level of serum IL-6 in these mice. Therefore, measurement of serum IL-6 level provides us with the information of the preceding exposure of the host to either LPS or IL-1 and/or TNF and the highly susceptible status of the host to these stimuli. Based on these results obtained from animal model, we investigated the relationship between serum IL-6 levels and serum endotoxin levels in the patients with malignant hematologic disorders. We found that these patients fell into two groups; an endotoxin susceptible group, equivalent to P. acnes-primed mice, showing high level of serum IL-6 with low level of serum endotoxin, and a nonendotoxin susceptible group, equivalent to P. acnes-nonprimed mice, showing low or undetectable level of serum IL-6 with high level of serum endotoxin. We propose that the measurement of serum IL-6 level in the patients positive for endotoxin is a useful tool in evaluating diagnosis and prognosis of endotoxin shock.     

Beneficial effects of antibacterial peptide PR-39 in a neonatal murine model of endotoxic shock

The lethal effects occurring in neonatal (< 24-h old) BALB/c mice after challenge with E. coli lipopolysaccharide (LPS) were significantly counteracted by pretreatment with antibacterial peptide PR-39. Neonatal mice protection was probably related to the depressive effect of PR-39 on production of TNF-alpha known to be the major mediator of the lethal effects of neonatal endotoxic shock. Indeed, TNF-alpha plasmatic levels were consistently lower in pups pretreated with PR-39 compared with controls. Administration 24 h after challenge was no longer effective. Although PR-39 and anti-TNF-alpha doses were ineffective alone, when combined at different ratios protected neonatal mice. The present experiments show the potential use of peptide PR-39 in preventing neonatal endotoxic shock.     

LPS-induced serum TNF production and lethality in mice: effect of L-carnitine and some acyl-derivatives

The effect of L-carnitine and some of its acyl derivatives on serum TNF production and lethality in a murine experimental endotoxin shock model was investigated. In some instances, serum IL-6 production was also evaluated. In this experimental model, C57BL/6 mice received 30 mg/kg LPS (E. cell 055:B5) injected intraperitoneally, while L-carnitine and its derivatives were administered according to different schedules. Serum levels of TNF and IL-6 were evaluated 1 h following LPS injection. The treated animals were also monitored daily for differences in body temperature, feeding, and survival for 10 days after LPS injection. Although some derivatives were able to significantly affect TNF production, the marked decrease in serum TNF levels of LPS-treated mice was not paralleled by a substantial increase in survival.     

Modulation of murine macrophage function by N-acetylcysteine in a model of endotoxic shock

In previous studies we have observed changes in several functions of peritoneal macrophages from BALB/c mice with irreversible endotoxic shock caused by intraperitoneal injection of E. coli lipopolysaccharide (LPS) (100 mg/kg), which were associated with a high production of superoxide anion. Since antioxidants, such as N-acetylcysteine (NAC), are free radical scavengers that improve the immune response, in the present work we have studied different functions of peritoneal macrophages from BALB/c mice suffering the endotoxic shock above indicated and administered N-acetylcysteine (150 mg/kg i.p.) at 30 minutes after LPS injection. In the peritoneal macrophages obtained at 2, 4, 12 and 24 h after LPS injection, the following functions were studied: adherence to substrate, mobility, ingestion of particles, and production of superoxide anion and tumour necrosis factor (TNF alpha). The increase in adherence, ingestion and superoxide anion and TNF alpha production shown by macrophages from animals with endotoxic shock was counteracted by NAC injection. Moreover, the survival time of mice with endotoxic shock was increased in the presence of NAC. These data suggest that NAC, administered intraperitoneally, may be useful for the treatment of irreversible endotoxic shock by modulation of the function of macrophages with decreased superoxide anion and TNF alpha production and concomitant increase of survival time.     

Differential response of a(2)-macroglobulin-deficient mice in models of lethal TNF-induced inflammation

Tumor necrosis factor (TNF) is an essential mediator in the pathogenesis of Gram-negative septic shock. Injection of TNF into normal mice leads to systemic, lethal inflammation, which is indistinguishable from lipopolysaccharide (LPS)-induced lethal inflammation. alpha(2)-macroglobulin (A2M) is a major positive acute phase protein with broad-spectrum protease-inhibitory activity. Mouse A2M-deficient (MAM-/-) mice were significantly protected against lethal systemic inflammation induced by TNF. The protection is not due to faster clearance of the injected TNF. The induction of tolerance to TNF-induced lethality by repetitive administration of small doses of human TNF for five consecutive days was equally efficient in both mutant mice compared to wild-type mice. In D-(+)-galactosamine (GalN)-sensitized mice, TNF induces lethal inflammatory hepatitis. MAM(-/-) mice are equally sensitive to the lethal combination of TNF/GalN. Furthermore, interleukin-1-induced desensitization to TNF/GalN was not impaired in MAM(-/-) mice. We conclude that MAM plays a mediating role in TNF-induced lethal shock and that MAM deficiency does not reduce changes in efficiency of tolerance and desensitization to TNF and TNF/GalN-induced lethality, respectively.     

Involvement of the liver, but not of IL-6, in IL-1-induced desensitization to the lethal effects of tumor necrosis factor.

C57BL/cnb mice were found to be protected against a lethal combination of recombinant murine (m) TNF and GalN by pretreatment with several cytokines. At certain doses, rmTNF and human (h) TNF protected completely. The clearest protection was induced by rIL-1: all four rIL-1 species (both m and h, as well as alpha and beta) protected when given 12 h before the challenge. LPS and rmIFN-gamma protected weakly, whereas rmIL-6 and rhIL-6 did not protect at all. Also adrenocorticotropic hormone, dexamethasone, or dexamethasone in combination with rhIL-6 could not protect. A single IL-1 injection also completely protected mice against a lethal dose of mTNF in the absence of GalN sensitization. The desensitization by IL-1 cannot be explained by a faster clearance of the challenge TNF. In addition, we demonstrate that the IL-1-induced desensitization was only observed when a functioning liver was present, that IL-1-pretreated animals did not show decreased numbers of hepatocyte TNF receptors, and that the amount of TNF-induced IL-6 was not reduced.     

Anti-tumor necrosis factor antibody therapy fails to prevent lethality after cecal ligation and puncture or endotoxemia.

Cytokines have been studied intensively to delineate their role in the altered pathophysiology observed in septic shock. We studied the role of TNF in the lethality of two well characterized models of septic shock by inhibiting TNF's activity with a specific antibody. In the first model, sepsis was induced by cecal ligation and puncture (CLP), and in the second model sepsis was induced by either an i.p. or i.v. injection of LPS. After CLP, plasma endotoxin was detectable within 4 h and reached a peak at 8 h (136 +/- 109 ng/ml). TNF bioactivity peaked at 12 h (528 +/- 267 pg/ml) at a significantly higher level than sham-operated control mice (64 +/- 31 pg/ml). After i.p. LPS, TNF peaked much more quickly (90 min) compared with CLP and at a significantly higher level (107,900 +/- 25,000 pg/ml). Another cytokine studied in septic shock, IL-6, peaked at 12 h after CLP at 1011 +/- 431 pg/ml, and at 90 min after lethal LPS at 16,300 +/- 3,700 pg/ml. Mice were treated with an anti-TNF antibody that has been shown previously to inhibit in vivo TNF activity. Antibody treatment of mice subjected to CLP significantly reduced TNF bioactivity but did not reduce mortality or pulmonary neutrophilic infiltration. In the i.v. LPS model, anti-TNF antibody treatment concomitant with LPS injection reduced plasma TNF activity from 80,000 +/- 20,000 pg/ml to undetectable levels. However, anti-TNF treatment immediately before either i.v. or i.p. LPS did not reduce mortality. Additionally, when the antibody was administered 4 h before the lethal i.v. LPS, there was no reduction in lethality. These data show that in two separate models of septic shock blockade of TNF biologic activity will not prevent lethality.     

The role of IFN-gamma in the pathology of experimental endotoxemia

Proinflammatory cytokines provoked by circulating bacterial LPS mediate many of the destructive host responses characteristic of septic shock. To determine if the lymphokine IFN-gamma has a similar pathogenic role during endotoxic shock, mice were pretreated with murine rIFN-gamma (rMuIFN-gamma) at various times relative to challenge with Salmonella enteritidis LPS. Subsequent mortality was increased when rMuIFN-gamma was administered before or up to 4 h after endotoxin challenge. Pretreatment with rMuIFN-gamma resulted in nearly fivefold increases in serum TNF during endotoxemia, but TNF levels were unaffected by IFN administered after endotoxin. The increased levels of serum TNF probably reflected enhanced translation of this factor, as tissue expression of TNF mRNA did not increase correspondingly in IFN-pretreated mice. To examine the role of IFN-gamma produced endogenously during endotoxemia, mice were pretreated with 0.5 mg of anti-IFN-gamma mAb before endotoxin injection. This treatment significantly reduced mortality from endotoxic shock but caused only minor decreases in serum TNF. Anti-IFN-gamma administered 2 h after endotoxin was similarly protective. These results demonstrate a significant role for IFN-gamma in the pathology of septic shock, both indirectly as an activator of monokines known to promote lethality and possibly by other, late-acting mechanisms.     

Glucocorticoids as cytokine inhibitors: role in neuroendocrine control and therapy of inflammatory diseases

Glucocorticoids are potent inhibitors of inflammation and endotoxic shock. This probably occurs through an inhibition of the synthesis of pro-inflammatory cytokines as well as of many of their toxic activities. Therefore, endogenous glucocorticoids (GC) might represent a major mechanism in the control of cytokine mediated pathologies. GC inhibit the synthesis of cytokines in various experimental models. Adrenalectomy or GC antagonists potentiate TNF, IL-1 and IL-6 production in LPS treated mice. GC inhibit the formation of arachidonic acid metabolites and the induction of NO synthase. They also inhibit various activities of cytokines including toxicity, haemodynamic shock and fever. Adrenalectomy sensitizes to the toxic effects of LPS, TNF and IL-1. On the other hand, GC potentiate the synthesis of several cytokine induced APP by the liver. Since many of these proteins have anti-toxic activities (antioxidant, antiprotease etc.) or bind cytokines, this might well represent a GC mediated protective feedback mechanism involving the liver. Not only do GC inhibit cytokines, but in vivo LPS and various cytokines (TNF, IL-1, IL-6) increase blood GC levels through a central mechanism involving the activation of the HPA. Thus, this neuroendocrine response to cytokines constitutes an important immunoregulatory feedback involving the brain.     

N-acetylcysteine and glutathione as inhibitors of tumor necrosis factor production.

TNF is a major mediator in the pathogenesis of endotoxic shock, and its inhibition has a protective effect in various animal models of sepsis or endotoxin (lipopolysaccharide, LPS) toxicity. LPS treatment also induces an oxidative damage mediated by increased production of reactive oxygen intermediates. N-Acetylcysteine (NAC) is an antioxidant and a precursor of the synthesis of glutathione (GSH) and was reported to protect against LPS toxicity and LPS-induced pulmonary edema. In this study we investigated the effect of NAC on TNF production and LPS lethality in mice. The results indicated that oral administration of NAC protects against LPS toxicity and inhibits the increase in serum TNF levels in LPS-treated mice. The inhibition was not confined to the released form of TNF, since NAC also inhibited LPS-induced spleen-associated TNF. On the other hand, the inhibitor of GSH synthesis, DL-buthionine-(SR)-sulfoximine (BSO), had the opposite effect of potentiating LPS-induced TNF production, and this was associated with a decrease in liver GSH levels. Repletion of liver GSH with NAC reversed this effect. NAC was also active in inhibiting TNF production and hepatotoxicity in mice treated with LPS in association with a sensitizing dose of Actinomycin D. These data indicate that GSH can be an endogenous modulator of TNF production in vivo. On the other hand, NAC pretreatment did not inhibit other effects of LPS, particularly induction of serum IL-6, spleen IL-1 alpha, and corticosterone, in the same experimental model, suggesting that the observed effect could be specific for TNF.     

Reversal of defective IL-6 production in lipopolysaccharide-tolerant mice by phorbol myristate acetate

The development of LPS tolerance has been suggested to be mediated by an inhibition of cytokine synthesis. Here we have studied serum IL-6 and TNF levels in mice after LPS administration. Repeated administration of LPS (35 micrograms daily for 4 days) to mice induced a refractoriness (tolerance) to subsequent administrations of LPS in terms of induction of circulating IL-6 and TNF. To investigate the mechanism by which LPS down-regulates its own induction of cytokine synthesis and the relationship between IL-6 and TNF production, we attempted to revert the inhibition of IL-6 and TNF production using agents like PMA or IFN-gamma, previously reported to activate macrophage production of cytokines. Pretreatment with PMA (4 micrograms, 10 min before LPS) partially restored IL-6 production in LPS-tolerant mice given 2 micrograms LPS. On the other hand, PMA did not restore TNF induction in LPS-tolerant mice, even when administered with high doses of LPS (up to 200 micrograms). A similar reversal of LPS resistance to IL-6, but not TNF, induction by PMA was observed in genetically LPS-resistant C3H/HeJ mice. IFN-gamma also restored, although to a lesser extent than PMA, IL-6 production. However, unlike PMA, IFN-gamma could also partially restore TNF production in LPS-tolerant mice, although only when LPS was administered at high doses. By contrast with PMA, IFN-gamma was clearly more active in restoring TNF synthesis than that of IL-6. Similar results were obtained in genetically LPS-unresponsive C3H/HeJ mice. These data suggest that different mechanisms are implicated in the inhibition of IL-6 and TNF synthesis in LPS-tolerant mice and that part of this inhibition can be overcome by PMA or IFN-gamma.     

Increased resistance of LFA-1-deficient mice to lipopolysaccharide-induced shock/liver injury in the presence of TNF-alpha and IL-12 is mediated by IL-10: a novel role for LFA-1 in the regulation of the proinflammatory and anti-inflammatory cytokine balance

Challenge with low doses of LPS together with D-galactosamine causes severe liver injury, resulting in lethal shock (low dose LPS-induced shock). We examined the role of LFA-1 in low dose LPS-induced shock. LFA-1(-/-) mice were more resistant to low dose LPS-induced shock/liver injury than their heterozygous littermates, although serum levels of TNF-alpha and IL-12 were higher in these mice. C57BL/6 mice were not rescued from lethal effects of LPS by depletion of NK1(+) cells, granulocytes, or macrophages, and susceptibility of NKT cell-deficient mice was comparable to that of controls. High numbers of platelets were detected in the liver of LFA-1(+/-) mice after low dose LPS challenge, whereas liver accumulation of platelets was only marginal in LFA-1(-/-) mice. Following low dose LPS challenge, serum levels of IL-10 were higher in LFA-1(-/-) mice than in LFA-1(+/-) mice, and susceptibility to low dose LPS-induced shock as well as platelet accumulation in the liver of LFA-1(-/-) mice were markedly increased by IL-10 neutralization. Serum levels of IL-10 in LFA-1(+/-) mice were only marginally affected by macrophage depletion. However, in LFA-1(-/-) mice macrophage depletion markedly reduced serum levels of IL-10, and as a corollary, susceptibility of LFA-1(-/-) mice to low dose LPS-induced shock was markedly elevated despite the fact that TNF-alpha levels were also diminished. We conclude that LFA-1 participates in LPS-induced lethal shock/liver injury by regulating IL-10 secretion from macrophages and that IL-10 plays a decisive role in resistance to shock/liver injury. Our data point to a novel role of LFA-1 in control of the proinflammatory/anti-inflammatory cytokine network.     

Neutrophil leukocyte emigration induced by endotoxin. Mediator roles of interleukin 1 and tumor necrosis factor alpha 1

The hypothesis that cytokines mediate neutrophil emigration induced by endotoxin (LPS) was studied by examining the potency, the kinetics of neutrophil emigration, and the tachyphylaxis of intradermal sites with IL-1, TNF-alpha and LPS. Human rIL-1 alpha and IL-1 beta, synthetic lipid A, and LPS were several orders of magnitude more potent than human rTNF. The kinetic profiles of neutrophil emigration induced by IL-1 alpha, TNF, and LPS were characterized by minimal emigration in the first 30 min, followed by rapid and transient emigration. After the injection of LPS, the onset and the time at which the rate of emigration was maximal consistently appeared 30 min later than IL-alpha or TNF, suggesting that neutrophil emigration in response to LPS was mediated by a locally generated cytokine. IL-1 and TNF were then examined as potential secondary mediators of LPS-induced emigration by comparing the patterns of tachyphylaxis between LPS and IL-1 alpha or TNF; i.e., the magnitude of neutrophil emigration into inflammatory sites was compared with sites injected 6 h previously (desensitizing injections) with a cytokine or with LPS. Tachyphylaxis was dose dependent with each and also between the IL-1 species; therefore, when tachyphylaxis between the cytokines and LPS was examined, relatively higher doses were selected for the desensitizing injections than for the test injections. With this approach, desensitizing injections of IL-1 alpha diminished the neutrophil accumulation after LPS, and LPS also desensitized sites to IL-1 alpha. However, tachyphylaxis was not observed between TNF and LPS, or between TNF and IL-1 alpha. These data suggest that IL-1, but not TNF, is a potential mediator of LPS-induced neutrophil emigration.     

Neutralization of IL-18 reduces neutrophil tissue accumulation and protects mice against lethal Escherichia coli and Salmonella typhimurium endotoxemia

In addition to stimulating IFN-gamma synthesis, IL-18 also possesses inflammatory effects by inducing synthesis of the proinflammatory cytokines TNF and IL-1beta and the chemokines IL-8 and macrophage inflammatory protein-1alpha. We hypothesized that neutralization of IL-18 would have a beneficial effect in lethal endotoxemia in mice. IL-1beta converting enzyme (ICE)-deficient mice, lacking the ability to process mature IL-18 and IL-1beta, were completely resistant to lethal endotoxemia induced by LPS derived from either Escherichia coli or Salmonella typhimurium. In contrast, both wild-type and IL-1beta-/- mice were equally susceptible to the lethal effects of LPS, implicating that absence of mature IL-18 or IFN-gamma but not IL-1beta in ICE-/- mice is responsible for this resistance. However, IFN-gamma-deficient mice were not resistant to S. typhimurium LPS, suggesting an IFN-gamma-independent role for IL-18. Anti-IL-18 Abs protected mice against a lethal injection of either LPS. Anti-IL-18 treatment also reduced neutrophil accumulation in liver and lungs. The increased survival was accompanied by decreased levels of IFN-gamma and macrophage inflammatory protein-2 in anti-IL-18-treated animals challenged with E. coli LPS, whereas IFN-gamma and TNF concentrations were decreased in treated mice challenged with S. typhimurium. In conclusion, neutralization of IL-18 during lethal endotoxemia protects mice against lethal effects of LPS. This protection is partly mediated through inhibition of IFN-gamma production, but mechanisms involving decreased neutrophil-mediated tissue damage due to the reduction of either chemokines (E. coli LPS) or TNF (S. typhimurium LPS) synthesis by anti-IL-18 treatment may also be involved.