Protective effect of chlorpromazine against the lethality of interleukin 1 in adrenalectomized or actinomycin D-sensitized mice

Interleukin 1 (IL-1) and Tumor Necrosis Factor (TNF) are thought to play a key role in septic shock and inflammation. We have tested the effect of dexamethasone (DEX) and chlorpromazine (CPZ) on the lethal effect of IL-1, TNF and endotoxin. Two different experimental models were used to sensitize mice to the lethal effect of IL-1: adrenalectomy and pretreatment with actinomycin D. CPZ (4 mg/kg) was found to protect mice against IL-1 and endotoxin toxicity in all cases, while DEX had a protective effect only in adrenalectomized mice. In contrast to its protective effect against IL-1 and endotoxin, CPZ did not protect mice against TNF. These findings might be useful in the analysis of the differences in the actions of IL-1 and TNF in vivo, and in the development of new drugs preventing their toxicity.     

Potentiation of lethal endotoxin shock by streptococcal pyrogenic exotoxin in rabbits: Possible relevance of hyperreactivity of macrophages to endotoxin

Abstract Streptococcal pyrogenic exotoxin (SPE) potentiates lethal shock induced by endotoxin. We have previously reported that macrophages derived from SPE-treated rabbits showed hyperreactivity to endotoxin, and that the effect of SPE on macrophages was mediated by a lymphokine(s). Here we show that culture supernatants of SPE-stimulated lymphocytes, when administered into rabbits three hours before or together with endotoxin, potentiate a variety of endotoxin-induced pathophysiological changes and even lethal shock. These results suggest that SPE-induced lymphokine(s) mediates the potentiating effect of SPE on the lethal endotoxin shock through enhancing endotoxin reactivity of macrophages which play the central role in mediating endotoxin toxicity.     

Experimental studies on the bacterial product CANTASTIM derived from Pseudomonas aeruginosa. V. Protective effect in endotoxin shock

In this paper, we investigated the effect of the treatment with the bacterial immunomodulator CANTASTIM in a model of endotoxin shock in mice. Among the different mouse models described for septic shock, we have chosen the low-dose endotoxin model using D-galactosamine sensitized mice. We noticed a significant increase in the survival rate of the mice treated with CANTASTIM before the endotoxin challenge. This protective effect was correlated with a strong reduction in the level of TNF alpha in the sera of treated mice. Prior exposure to CANTASTIM also attenuated subsequent ex vivo nitric oxide production by peritoneal macrophages of the mice. In this model of endotoxin shock, the major role has been attributed to TNF alpha acting through its receptor TNFRI (p55). A downregulation of this receptor as a consequence of the treatment with CANTASTIM may be hypothesized. However, the intervention of CANTASTIM in other points in the cytokine network involved in endotoxin shock cannot be excluded.     

Inhibition of hepatic enzyme induction as a sensitive assay for endotoxin

Bacterial endotoxins in mice reduced the induction by cortisone of two hepatic enzymes, tryptophan oxygenase, and phosphoenolpyruvate carboxykinase, they prevented the glyconeogenesis in liver induced by the same hormone, and they induced in intact animals the liver enzyme tyrosine-alpha-ketoglutarate transaminase, all in proportion to their ld(50). When cortisone was given in the least amount (100 mug), it resulted in near maximal induction of tryptophan oxygenase; a smaller amount of endotoxin reduced significantly the level of enzyme than that required when 5 mg of hormone was injected. The smallest amount of endotoxin that prevented tryptophan oxygenase induction was given intravenously to adrenalectomized mice in which 25 mug of cortisone was administered. The amount (0.01 mug) is 1/40,000th of the ld(50). The other metabolic processes subject to alteration by endotoxin required at least 100 to 400 times as much. This property of endotoxin can serve as a sensitive bioassay, although the dose-response curve is steep.     

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.     

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.     

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.     

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.     

Effect of Endotoxin and Cortisone on Synthesis of Ribonucleic Acid and Protein in Livers of Mice

The effect of cortisone and endotoxin, singly and in combination, on ribonucleic acid (RNA) synthesis in livers of adrenalectomized mice was determined. This was accomplished by measuring the incorporation either of inorganic (32)P or of (14)C-orotic acid into the RNA. Under similar conditions, the effect of these agents on the rate of protein synthesis was examined with the use of (14)C-leucine. Bacterial endotoxin was found to augment the uptake of isotope in the RNA and in the protein of the liver. These reactions did not appear to be mediated via the pancreatic hormone insulin, which was found to depress the incorporation of the radioactive compounds into RNA. Cortisone increased the uptake of isotope in liver RNA but depressed the incorporation of leucine into hepatic protein. These results indicate that the previously observed ability of endotoxin to prevent the hormone induction of hepatic enzymes, such as tryptophan oxygenase, is not associated with impaired synthesis of liver RNA or protein.     

Citrus pectin attenuates endotoxin shock via suppression of Toll-like receptor signaling in Peyer's patch myeloid cells

Pectin, a water-soluble dietary fiber, has been found to improve survival in endotoxin shock. However, the underlying mechanism by which pectin exerts its protective effect against endotoxin shock remains unknown. Apart from its prebiotic effects, it has been suggested that pectin directly affects immune cells to regulate inflammatory responses. In this study, we investigated the direct effect of pectin in murine model of endotoxin shock. Citrus pectin solution was administered to male C57BL/6 mice for 10 days. Thereafter, hypothermia was induced in the mice with intraperitoneal injection of lipopolysaccharide (LPS). The pectin-treated mice showed attenuation of both the decrease in rectal temperature and increase in serum IL-6 level as compared to vehicle control mice. Simultaneously, the pectin-treated mice showed reduced levels of inflammatory cytokine mRNA in Peyer's patches and mesenteric lymph nodes, but not in the spleen. Peyer's patch cells from the pectin-treated mice were sorted and their levels of IL-6 production on LPS stimulation were measured. The results of ex vivo analysis indicated that IL-6 secretion from CD11c⁺ cells was suppressed by oral administration of pectin. Furthermore, IL-6 secretion from Toll-like receptor (TLR)-activated RAW264.7 cells was suppressed by pretreatment with pectin in vitro. This suppression was observed even with degraded pectin pretreatment but not with polygalacturonic acid, as the principal constituent of the pectin backbone. Taken together, these results suggest that pectin intake suppresses TLR-induced inflammatory cytokine expression in Peyer's patch myeloid cells, presumably through inhibition of TLR signaling by the pectin side chains.     

Cutting edge: targeted disruption of the C3a receptor gene demonstrates a novel protective anti-inflammatory role for C3a in endotoxin-shock

The complement anaphylatoxin C3a, on binding the C3aR, mediates numerous proinflammatory activities. In addition, recent in vitro studies with C3a have implicated C3aR as a possible anti-inflammatory receptor. Because of its possible dual role in modulating the inflammatory response, it is uncertain whether C3aR contributes to the pathogenesis of endotoxin shock. Here, the targeted-disruption of the C3aR in mice is reported. These mice exhibit an enhanced lethality to endotoxin shock with a pronounced gene dosage effect. In addition, the plasma concentration of IL-1beta was significantly elevated in the C3aR(-/-) mice compared with their littermates following LPS challenge. These findings demonstrate an important protective role for the C3aR in endotoxin shock and indicate that, in addition to its traditionally accepted functions in mediating inflammation, the C3aR also acts in vivo as an anti-inflammatory receptor by attenuating LPS-induced proinflammatory cytokine production.     

Potential role of myeloid cell/eosinophil-derived IL-17 in LPS-induced endotoxin shock

IL-17RA is a shared receptor subunit for several cytokines of the IL-17 family, including IL-17A, IL-17C, IL-17E (also called IL-25) and IL-17F. It has been shown that mice deficient in IL-17RA are more susceptible to sepsis than wild-type mice, suggesting that IL-17RA is important for host defense against sepsis. However, it is unclear which ligands for IL-17RA, such as IL-17A, IL-17C, IL-17E/IL-25 and/or IL-17F, are involved in the pathogenesis of sepsis. Therefore, we examined IL-17A, IL-17E/IL-25 and IL-17F for possible involvement in LPS-induced endotoxin shock. IL-17A-deficient mice, but not IL-25- or IL-17F-deficient mice, were resistant to LPS-induced endotoxin shock, as compared with wild-type mice. Nevertheless, studies using IL-6-deficient, IL-21Rα-deficient and Rag-2-deficient mice, revealed that neither IL-6 and IL-21, both of which are important for Th17 cell differentiation, nor Th17 cells were essential for the development of LPS-induced endotoxin shock, suggesting that IL-17A-producing cells other than Th17 cells were important in the setting. In this connection, IL-17A was produced by macrophages, DCs and eosinophils after LPS injection. Taken together, these findings indicate that IL-17A, but not IL-17F or IL-25, is crucial for LPS-induced endotoxin shock. In addition, macrophages, DCs and eosinophils, but not Th17 cells or γδ T cells, may be sources of IL-17A during LPS-induced endotoxin shock.     

D-氨基半乳糖敏化小鼠内毒素休克模型的优化(英文)

目的:建立D-氨基半乳糖敏化小鼠内毒素休克的规范化模型。方法:选择对内毒素休克小鼠死亡率有影响的3个因素:D-氨基半乳糖增敏剂量、内毒素攻击剂量及其给药途径每个因素选取3个水平,按L9(34)正交试验表安排试验。以小鼠48h死亡率为评价指标,并通过验证试验,优化与实验要求相符的造模条件。结果:各因素对动物死亡率影响程度依次为:D-氨基半乳糖增敏剂量>内毒素给药途径>内毒素攻击剂量。采用D-氨基半乳糖600 mg.kg-1敏化小鼠,腹腔注射内毒素0.5 mg.kg-1的给药方案为佳。结论:规范内毒素休克模型的复制条件,将有利于科学评价药物的抗内毒素活性。     

Comparative Analysis of Hepatic CD14 Expression between Two Different Endotoxin Shock Model Mice: Relation between Hepatic Injury and CD14 Expression

CD14 is a glycoprotein that recognizes gram-negative bacterial lipopolysaccharide (LPS) and exists in both membrane-bound and soluble forms. Infectious and/or inflammatory diseases induce CD14 expression, which may be involved in the pathology of endotoxin shock. We previously found that the expression of CD14 protein differs among the endotoxin shock models used, although the reasons for these differences are unclear. We hypothesized that the differences in CD14 expression might be due to liver injury, because the hepatic tissue produces CD14 protein. We investigated CD14 expression in the plasma and liver in the carrageenan (CAR)-primed and D-galN-primed mouse models of endotoxin shock. Our results showed that severe liver injury was not induced in CAR-primed endotoxin shock model mice. In this CAR-primed model, the higher mRNA and protein expression of CD14 was observed in the liver, especially in the interlobular bile duct in contrast to D-galN-primed-endotoxin shock model mice. Our findings indicated that the molecular mechanism(s) underlying septic shock in CAR-primed and D-galN-primed endotoxin shock models are quite different. Because CD14 expression is correlated with clinical observations, the CAR-primed endotoxin shock model might be useful for studying the functions of CD14 during septic shock in vivo.     

Suppressive effect of adrenalectomy on growth of L1210 leukemic cells in ascites

This study was designed to evaluate the effect of adrenalectomy on growth of L1210 leukemic cells in ascites of BDF1 mice. Varying doses of 1.5 x 10(4), 5.0 x 10(5), and 1.5 x 10(6) viable tumour cells were inoculated intraperitoneally into groups of either adrenalectomized or sham-operated mice. At days 4 to 7 after the inoculation, adrenalectomized mice inoculated with 1.5 x 10(4) or 5.0 x 10(5) tumour cells had a smaller number of tumour cells in ascites than sham-operated controls. However, after inoculation of 1.5 x 10(6) cells, no significant differences were found at days 2 to 4 between adrenalectomized and sham-operated mice. The growth retardation by adrenalectomy was not observed in adrenalectomized mice supplemented with 4 or 6 micrograms dexamethasone per day per mouse. It suggested that the ablation of glucocorticoids was at least partially responsible for the growth retardation observed in adrenalectomized mice. Cell kinetic analysis revealed that the difference in a potential doubling time could not explain these results. Tumour retention in the peritoneal cavity was measured using [125I]-iododeoxyuridine-labelled tumour cells as a tracer. At days 4 to 6 after inoculation of 5.0 x 10(5) labelled cells, radioactivity in the peritoneal cavity in adrenalectomized mice was about 70 per cent of that in sham-operated mice. This ratio was almost equivalent to the ratio of the number of cells in ascites of adrenalectomized mice to that of sham-operated ones. Consequently, growth retardation observed in adrenalectomized mice resulted from an increase in tumour cell migration and/or in tumour cell death, but not from an increase in doubling time.     

Host-parasite interaction in serious infections due to gram-negative bacteria

Gram-negative rods such as Enterobacteriaceae and Pseudomonadaceae are normal habitants of the digestive tract. However, if defense mechanisms of the host are compromised by underlying diseases such as malignant neoplasms, renal insufficiency, extensive traumata, or immunosuppressive therapy, invasion of the blood-stream can occur. Gram-negative septicaemia is associated with high morbidity and mortality, despite intensive care and administration of potent antibiotics. A central role in the pathophysiology of life-threatening bacteraemia is attributed to endotoxin, a constituent of the gram-negative cell wall. This paper reviews current concepts of septic shock, the acquisition of gram-negative bacteraemia and the role of endotoxin. It also deals with a new approach to prevention and control of severe gram-negative infections using serotherapy based on the structure of endotoxin.     

IL-12 suppression during experimental endotoxin tolerance: dendritic cell loss and macrophage hyporesponsiveness

Endotoxin tolerance, the transient, secondary down-regulation of a subset of endotoxin-driven responses after exposure to bacterial products, is thought to be an adaptive response providing protection from pathological hyperactivation of the innate immune system during bacterial infection. However, although protecting from the development of sepsis, endotoxin tolerance also can lead to fatal blunting of immunological responses to subsequent infections in survivors of septic shock. Despite considerable experimental effort aimed at characterizing the molecular mechanisms responsible for a variety of endotoxin tolerance-related phenomena, no consensus has been achieved yet. IL-12 is a macrophage- and dendritic cell (DC)-derived cytokine that plays a key role in pathological responses to endotoxin as well as in the induction of protective responses to pathogens. It recently has been shown that IL-12 production is suppressed in endotoxin tolerance, providing a likely partial mechanism for the increased risk of secondary infections in sepsis survivors. We examined the development of IL-12 suppression during endotoxin tolerance in mice. Decreased IL-12 production in vivo is clearly multifactorial, involving both loss of CD11c(high) DCs as well as alterations in the responsiveness of macrophages and remaining splenic DCs. We find no demonstrable mechanistic role for B or T lymphocytes, the soluble mediators IL-10, TNF-alpha, IFN-alphabeta, or nitric oxide, or the NF-kappaB family members p50, p52, or RelB.     

HLA transgenic mice provide evidence for a direct and dominant role of HLA class II variation in modulating the severity of streptococcal sepsis

Our epidemiologic studies on invasive Group A Streptococci (GAS) infections identified specific HLA class II haplotypes/alleles conferring high-risk or protection from streptococcal toxic shock syndrome with a strong protection conferred by the DRB1*15/DQB1*06 haplotype. We used HLA-transgenic mice to provide an in vitro and in vivo validation for the direct role of HLA class II allelic variation in streptococcal toxic shock syndrome. When splenocytes from mice expressing the protective HLA-DQB1*06 (DQ6) allele were stimulated with a mixture of streptococcal superantigens (SAgs), secreted by the prevalent M1T1 strain, both proliferative and cytokine responses were significantly lower than those of splenocytes from mice expressing the neutral DRB1*0402/DQB1*0302 (DR4/DQ8) alleles (p < 0.001). In crisscross experiments, the presentation of SAgs to pure T cells from either the DQ6 or the DR4/DQ8 mice resulted in significantly different levels of response depending on the HLA type expressed on the APCs. Presentation by HLA-DQ6 APCs elicited significantly lower responses than the presentation by HLA-DR4/DQ8 APCs. Our in vitro data were supported by in vivo findings, as the DQ6 mice showed significantly longer survival post-i.v. infection with live M1T1 GAS (p < 0.001) and lower inflammatory cytokine responses as compared with the DR4/DQ8 mice (p < 0.01). The data presented here provide evidence for a direct role of HLA class II molecules in modulating responses to GAS SAgs and underscore the dominant role of HLA class II allelic variation in potentiating the severity of GAS systemic infections.     

Mice lacking alpha(2)-macroglobulin show an increased host defense against Gram-negative bacterial sepsis, but are more susceptible to endotoxic shock

The onset of an acute phase response is one of the initial steps in the defense against an infectious organism. Alpha(2)-macroglobulin (alpha(2)M), an acute phase protein in most mammalian species, is known to have a broad antiprotease activity, but it can also bind a number of growth factors, cytokines, ions and lipid factors. We have shown that alpha(2)M-deficient (MAM-/-) mice are more resistant to a lethal Gram-negative infection compared to control mice. This increased resistance was reflected in significantly higher body temperatures, compared to control mice, during the infection as well as in a prolonged and increased survival. Moreover, the clearance of bacteria in MAM-/- mice was significantly more efficient than in control mice. On the other hand, MAM-/- mice were more susceptible to endotoxin. An LD(100) challenge with endotoxin in MAM-/- mice was not lethal for control mice. Our data suggest that alpha(2)M plays a dual role during an acute phase response. In the establishment of a lethal Gram-negative infection, leading to sepsis and septic shock, it has a mediating role by hampering the efficient clearance of bacteria. During endotoxic shock, however, alpha(2)M has a rather protective function.     

Reduced lipopolysaccharide (LPS)-induced nitric oxide production in peritoneal macrophages and inhibited LPS-induced lethal shock in mice by a sugar cane (Saccharum officinarum L.) extract

A sugar cane extract (SCE) has been found to have an immunostimulating effect in several animals. Lipopolysaccharide (LPS) is known to induce endotoxin shock via the production of inflammatory modulators such as tumor necrosis factor (TNF)-alpha and nitric oxide (NO). We examined in the present study the effects of SCE on the TNF-alpha and NO production in LPS-stimulated mice peritoneal cells and the endotoxin shock in mice. The supplementation of SCE to peritoneal macrophages cultured with LPS resulted in a significant decrease in NO production. All the mice injected intraperitoneally with LPS and D-galactosamine (LPS+GalN) died within 24 h. However, a peritoneal injection, but no intravenous or oral administration, of SCE (500-1,000 mg/kg) at 3 to 48 h before the LPS+GalN-challenge resulted in a significantly improved survival rate. These results suggest that SCE had a protective effect on LPS-induced endotoxin shock via one of possible mechanisms involving the suppression of NO production in the mouse peritoneal cavity.