Quantification of bacterial polysaccharides by the purpald assay: measurement of periodate-generated formaldehyde from glycol in the repeating unit

Anandamide (ANA) and 2-arachidonoylglycerol (2-AG), two endogenous cannabinoids, can be generated by activated macrophages and platelets, respectively, in the context of endotoxic shock, and are proposed to play a crucial role in the induction of the shock-related hypotension. Taking advantage of our recently discovered function of polymyxin B (PMB) binding to ANA and 2-AG, we developed a new method for measuring ANA and 2-AG by applying PMB-immobilized beads to selectively adsorb them in biological fluids, instead of organic solvent extraction. The eluate from beads can be directly fractionated by reverse-phase high-performance liquid chromatography (HPLC), and the fractionations corresponding to authentic ANA and 2-AG are collected and derivatized with fluorogenic reagent and subsequently quantified by HPLC with fluorometric detection. The calibration graphs of ANA and 2-AG were linear over a range of 1 to 500 pmol/ml. The limits of detection for ANA and 2-AG were 20 and 50 fmol, respectively. Intraassay precision was 2.24-4.25 and 3.47-5.44%, and interassay was 4.05-6.14 and 4.92-7.28% for ANA and 2-AG, respectively. Using this method, we first determined a 4-fold and 3-fold higher level of ANA and 2-AG, respectively, in the sera of patients with endotoxic shock than in normal serum. This finding should help in elucidating the role of the endogenous cannabinoids in the hypotension of human endotoxic shock. This method is rapid, sensitive, and reliable for simultaneously quantifying ANA and 2-AG in biological fluids, and has potential for clinical usage.     

Polymyxin B: an ode to an old antidote for endotoxic shock

Endotoxic shock, a syndrome characterized by deranged hemodynamics, coagulation abnormalities, and multiple system organ failure is caused by the release into the circulation of lipopolysaccharide (LPS), the structurally diverse component of Gram-negative bacterial outer membranes, and is responsible for 60% mortality in humans. Polymyxin B (PMB), a cyclic, cationic peptide antibiotic, neutralizes endotoxin but induces severe side effects in the process. The potent endotoxin neutralizing ability of PMB, however, offers possibilities for designing non-toxic therapeutic agents for combating endotoxicosis. Amongst the numerous approaches for combating endotoxic shock, peptide mediated neutralization of LPS seems to be the most attractive one. The precise mode of binding of PMB to LPS and the structural features involved therein have been elucidated only recently using a variety of biophysical approaches. These suggest that efficient neutralization of endotoxin by PMB is not achieved by mere binding to LPS but requires its sequestration from the membrane. Incorporation of this feature into the design of endotoxin neutralizing peptides should lead to the development of effective antidotes for endotoxic shock.     

The antibiotic polymyxin B modulates P2X7 receptor function

The natural peptide polymyxin B (PMB) is a well-known and potent antibiotic that binds and neutralizes bacterial endotoxin (LPS), thus preventing its noxious effects among LPS-mediated endotoxin shock in animal models. We have investigated the effect of PMB on responses mediated by the P2X(7)R in HEK293 and K562 cells transfected with P2X(7) cDNA and in mouse and human macrophages. In addition, in view of the potential exploitation of P2X(7)-directed agonists in antitumor therapy, we also investigated the effect of PMB in B lymphocytes from patients affected by chronic lymphocytic leukemia. PMB, at an optimal concentration dependent on the given cell type, greatly potentiated the effect of nucleotide-mediated P2X(7) stimulation. In particular, ATP-mediated Ca(2+) influx, plasma membrane permeabilization, and cytotoxicity were enhanced to an extent that, in the presence of PMB, cells were killed by otherwise ineffective nucleotide concentrations. The synergistic effect due to the combined application of ATP and PMB was prevented by incubation with the irreversible P2X blocker oxidized ATP (oATP), but not with the reversible antagonist 1-(N,O-bis(1,5-isoquinolinesulfonyl)-N-methyl-l-tyrosyl)-4-phenilpiperazine (KN-62). Cells lacking P2X(7) were fully insensitive to the combined stimulation with PMB and ATP. Furthermore, PMB at the concentrations used had no untoward effects on cell viability. These results point to PMB as a useful tool for the modulation of P2X(7)R function and suggest that care should be used in the evaluation of ATP-stimulated immune cell responses in the presence of PMB as they may not solely be affected by removal of contaminating LPS.     

Polymyxin B-horseradish peroxidase conjugates as tools in endotoxin research.

The peptide antibiotic Polymyxin B (PMB) binds to bacterial endotoxin (lipopolysaccharide, LPS). We prepared covalent conjugates of PMB and horseradish peroxidase (HRP) by periodation of HRP-linked oligosaccharides followed by direct condensation with PMB. In addition we prepared monoclonal antibodies (Mabs) to PMB. The PMB-HRP conjugates and anti-PMB Mabs were used to study in ELISA the binding of PMB to LPS from Escherichia coli, Klebsiella pneumoniae, and Pseudomonas aeruginosa. In addition, PMB-HRP was used to quantify lipid A in ELISA, and to stain gram-negative bacteria histochemically. For the study of PMB-LPS interaction, PMB-HRP proved to be superior to the anti-PMB Mabs. PMB-HRP conjugates are useful general probes to detect or measure lipid A and LPS of various species using very simple methods and to stain bacteria, and they may obviate the need for many specific antisera. Thus, PMB-HRP conjugates are useful probes for endotoxin research.     

Platelet-activating factor: an endogenous mediator for bowel necrosis in endotoxemia

We have developed a model of isochemic bowel necrosis in the rat by injecting platelet-activating factor (PAF) or PAF in combination with bacterial endotoxin. PAF causes profound hypotension, and it has been suggested that it is released during endotoxin shock. Because ischemic bowel necrosis is often associated with shock or infection, it is possible that PAF is the endogenous mediator that causes shock and bowel necrosis during sepsis. In this study, we have demonstrated that: 1) normal intestine contained a small amount of PAF; 2) necrotic lesions of the intestine could be induced by endotoxin injection; 3) PAF production in the bowel is markedly increased in animals treated with endotoxin; 4) pretreatment of the animal with PAF antagonists prevent endotoxin-induced necrosis; 5) isolated, buffer-perfused small intestine produced a small quantity of PAF in response to endotoxin injection. Therefore, we conclude that PAF is a likely endogenous mediator in endotoxemia, which causes bowel necrosis and shock.     

Endotoxin shock: prevented by naloxone in intact but not hypophysectomized rats

Previous studies established that naloxone reverses hypotension in endotoxin, hemorrhagic, and spinal shock. We studied endotoxin shock in hypophysectomized (Hx) rats, which have little circulating beta-endorphin. Hx or intact rats received surgically implanted jugular catheters for drug injection and aortic catheters for arterial blood pressure (MAP) recording. On the second day after implantation, rats were pretreated with either naloxone or saline. Two minutes later each rat received endotoxin. Following endotoxin, all rats showed a brief biphasic hypertensive-hypotensive response followed by stabilization of MAP near baseline. Within 20 min, all Hx rats, regardless of pretreatment, and the saline-treated intact rats, showed progressive hypotension (P less than 0.005). Only the naloxone-pretreated intact rats maintained a stable MAP. Plasma endorphin measured at 20 min was undetectable in Hx rats in contrast to intact rats (P less than 0.001); plasma corticosterone levels were likewise suppressed in the Hx rats (P less than 0.01). Thus (1) naloxone protected only the rats with an intact pituitary-adrenal-sympathetic system, and (2) pituitary endorphin is not required to generate endotoxin shock in hypophysectomized rats.     

Interference of the PAF-acether antagonist BN 52021 with endotoxin-induced hypotension in the guinea-pig

Because of the potential role of PAF-acether in the pathogenesis of endotoxin shock, we examined the preventive and curative effects of BN 52021, a new PAF-acether antagonist in guinea-pig challenged with S. Typhimurium endotoxin. A biphasic reduction of mean arterial pressure was elicited by i.v. endotoxin (300 micrograms/kg) in control animals, with a rapid drop of blood pressure (maximal decrease within 10 min), partial recovery at 20 min and a second gradual decrease after 30 min. Treatment with BN 52021 injected 15 min prior to endotoxin reduced the initial rapid drop of blood pressure from 38.5 +/- 5 mmHg in vehicle-treated controls (n = 15) to 17 +/- 3 mmHg (p less than 0.01) in animals treated with 1 mg/kg BN 52021(n = 10) and to 9.5 +/- 8 mmHg (p less than 0.01) in guinea-pigs treated with 6 mg/kg BN 52021 (n = 5). The early hypotensive phase was associated with severe thrombocytopenia-leukopenia; only the thrombocytopenia was reduced by BN 52021. The prolonged secondary phase of hypotension was reduced by BN 52021 pretreatment whereas a small increase of hematocrit persisted. The two phases of the arterial pressure profile during endotoxic shock were not observed in animals previously made thrombopenic by rabbit and anti-platelet serum and only the late hypotensive phase persisted. This late hypotension induced by endotoxin in thrombopenic animals was suppressed by BN 52021 pretreatment suggesting that BN 52021 may act via a platelet-independent mechanism. The intravenous injection of BN 52021 during the prolonged secondary phase of shock was followed by an immediate increase of the depressed blood pressure. This increase of blood pressure was dose-dependent, maximum at 6 mg/kg BN 52021, and observed in normal and thrombopenic animals. The interference of BN 52021 with endotoxin shock may be related to its PAF-acether antagonist properties and suggests that PAF-acether is an important participant in endotoxic shock.     

Surface plasmon resonance studies resolve the enigmatic endotoxin neutralizing activity of polymyxin B.

Polymyxin B (PMB), a cyclic cationic peptide antibiotic, despite its severe side effects continues to occupy a premiere position for treating endotoxicosis. Its mode of neutralization of endotoxin has remained elusive for the last three decades. Several synthetic peptide mimics of PMB, capable of binding endotoxin, have been made. However, the binding ability alone appears to be a deceptive indicator of endotoxin neutralizing activity as molecules with similar binding propensities could either sequester or opsonize the toxin. Hence identification of additional physical parameters which describe adequately the outcome of PMB-endotoxin interaction become imperative. Surface plasmon resonance (SPR) studies reported here show that several mimics of PMB despite exhibiting lipopolysaccharide binding affinities comparable with it but, unlike it, do not sequester the endotoxin. These studies thus provide a striking illustration of the difference in the behavior of PMB, vis a vis its mimics toward the endotoxin lamellae, and define further, in chemical terms, mechanism of the action of PMB and allow us to posit that the design of molecules as effective antidotes for sepsis should incorporate the ability to sequester endotoxin specifically.     

Septic Shock

Septic shock may be defined as hypotension caused by bacteremia and accompanied by decreased peripheral blood flow, evidenced by oliguria. Clinically, a shaking chill is the warning signal. The immediate cause of hypotension is pooling of blood in the periphery, leading to decreased venous return: later, peripheral resistance falls and cardiac failure may occur. Irreversible shock is comparable to massive reactive hyperemia. Reticuloendothelial failure, histamine release, and toxic hypersensitivity may be factors in the pathogenesis of septic shock. Adrenal failure does not usually occur, but large doses of corticosteroid are employed therapeutically to counteract the effect of histamine release or hypersensitivity to endotoxin. The keys to successful therapy are time, antibiotics, vasopressors, cortisone and correction of acidosis.     

Synthesis and application of a novel ligand for affinity chromatography based removal of endotoxin from antibodies

Endotoxin or lipopolysaccharide (LPS) contamination in proteins expressed by Gram-negative bacteria is a major drawback associated with protein expression. Endotoxin intoxication in humans and animals above a certain threshold level can result in a fatal immune response. Reduction in endotoxin levels is therefore essential before proteins can be used in in vivo studies or sold as pharmaceutical products. Affinity chromatography employing the peptide Polymyxin B (PMB) as an affinity ligand is one way in which endotoxin contamination has been addressed; this is, however, a costly process. We describe the synthesis of a novel affinity ligand based on the structure of the drug pentamidine, which can be applied effectively in endotoxin removal. The synthetic route to this ligand is straightforward and inexpensive, while the ligand can be readily immobilized onto activated sepharose beads. Thus, we demonstrate that these pentamidine affinity beads bind endotoxin/LPS with comparable capacity to PMB affinity systems, that the beads can be recycled efficiently and economically without loss of binding capacity, and application of the functionalized beads for endotoxin removal in an authentic contaminated antibody sample.     

Protection from endotoxic shock by EVK-203, a novel alkylpolyamine sequestrant of lipopolysaccharide

Lipopolysaccharides (LPS) play a key role in the pathogenesis of septic shock, a major cause of mortality in the critically ill patient. The only therapeutic option aimed at limiting downstream systemic inflammatory processes by targeting lipopolysaccharide is Toraymyxin, an extracorporeal hemoperfusion device using solid phase-immobilized polymyxin B (PMB). While PMB is known to effectively sequester LPS, its severe systemic toxicity proscribes its parenteral use, and hemoperfusion may not be feasible in patients in shock. In our continuing efforts to develop small-molecule mimics which display the LPS-sequestering properties, but not the toxicity of PMB, a series of mono- and bis-substituted dialkylpolyamines were synthesized and evaluated. We show that EVK-203, an alkylpolyamine compound, specifically binds to and neutralizes the activity of LPS, and affords complete protection in a murine model of endotoxic shock. EVK-203 is without any apparent toxicity when administered to mice at multiples of therapeutic doses for several days. The specific endotoxin-sequestering property along with a very favorable therapeutic index renders this compound an ideal candidate for preclinical development.     

内毒素耐受的机制研究

内毒素是革兰阴性菌细胞壁的成分,能够激发机体的免疫反应。当细菌释放大量的内毒素到血液,即可引起内毒素血症,内毒素血症可以伴随多种疾病出现,引起致死性感染性休克,循环功能衰竭,其病死率极高。内毒素耐受是指机体接受小剂量内毒素刺激后对后续内毒素刺激的反应性降低,表现为促炎因子释放减少而抗炎因子释放增加,机体发热,缺氧,低血压,休克的症状减轻。内毒素耐受的发生机制极其复杂,受机体内多种因素的调节,但目前尚无明确的结论。近年来,有关其机制的研究有许多报道,其中,对内毒素耐受的信号机制的研究最为广泛,大量的研究表明内毒素的主要受体,细胞内的信号蛋白,负调控因子以及转录因子可能在内毒素耐受的发生过程中起重要作用。也有报道表明免疫细胞的凋亡,染色体修饰和基因重排以及小RNA的参与可能诱导内毒素耐受的发生。本文从细胞、分子水平对内毒素耐受的发生机制进行综述,拟对炎症性疾病如内毒素血症的预防和治疗提供理论依据。     

Endotoxin-endothelium interactions in "low-perfusion state" research.

LPS/endotoxin provokes a plethora of pathological events some of which may be considered as examples of "low perfusion state". These are discussed here. It is well known that hypotension and refractoriness to vasocostrictors are the hallmark of endotoxic shock. Nevertheless, there are some vascular beds, such as mesenteric circulation, that respond with vasoconstriction - not vasodilation to endotoxin. Aminoguanidine, an inhibitor of NOS-2, blocks endotoxin- induced increase of resistance in mesenteric bed and endotoxin-induced translocation of bacteria through the gut wall. It is postulatede that endotoxin has antiarrythmogenic action due to the release of nitric oxide and increase in intracellular cGMP levels. Although we demonstrate that endotoxin increases nitric oxide formation in spleen and liver, its contribution to the injury of these organs by endotoxin is not fully established. In addition, we present our immunochemistry data on nitrotyrosine formation in the liver and spleen of endotoxin-treated animals.     

亲和介质及溶液条件对蛋白质溶液中内毒素去除的影响

生物制品中内毒素的去除是一项十分重要的工作。为了更好地去除各种生物制品中的内毒素,采用合成的多粘菌素B琼脂糖亲和介质,通过静态吸附的方法去除蛋白质溶液中的内毒素。重点考察了介质的间臂长度、配基密度以及各种溶液条件(pH值、盐种类和浓度、蛋白质种类和浓度、内毒素浓度、添加剂等)对内毒素去除率及蛋白质回收率的影响。分别采用动态浊度法和Lowry法检测内毒素含量和蛋白质浓度。结果表明该介质具有载量高、去除速度快、去除率高、可重复使用的特点。此外,配基密度、pH值、盐浓度和蛋白质特性(等电点和疏水性)对内毒素去除效果均有重要影响。在优化的条件下,血红蛋白、人血清白蛋白和溶菌酶的回收率分别达到87.2%、73.4%和97.3%,相应的内毒素去除率分别达到99.8%、97.9%和99.7%。阐明了各种因素对内毒素去除率和蛋白质回收率的影响规律,为生物制品中内毒素的高效去除提供了参考。     

刺激腓深神经对低血压或休克狗心血管活动的影响

实验在麻醉狗中进行。静脉内匀速注射硝普钠时,平均动脉压和左心室收缩压明显降低,左心室dp/dt_(max)、-dp/dt_(max)和心力环面积均明显减小。此时电刺激一侧腓深神经可使动脉血压和左心室收缩压明显升高,dp/dt_(max)和心力环面积也显著增加。停止刺激后,动脉血压和左心室收缩压逐渐回向刺激前的水平。停止注射硝普钠5～15分钟后,上述各项观察指标基本恢复到注药前的水平。在用大肠杆菌内毒素造成休克的狗中,电刺激一侧腓深神经,也能使平均动脉压和左心室收缩压升高,同时dp/dt_(max)、-dp/dt_(max)和肠系膜血管阻力明显增高,但肾血管阻力增加不明显。本实验结果与以往的实验资料一起表明,在用扩血管药造成低血压时,躯体神经刺激引起的升压效应似乎以心肌收缩力增加为主;而在内毒素休克时,躯体神经刺激可通过改善心肌收缩功能和增加内脏血管阻力而引起升压作用。     

Gastrointestinal plasma leakage in endotoxic shock. Inhibition by prostaglandin E2 and by a platelet-activating factor antagonist

The effects of pretreatment with prostaglandin E2 or the platelet-activating factor antagonist, CV-3988, on endotoxin-induced gastric damage, gastrointestinal plasma protein leakage, and systemic hypotension were examined in the rat. Endotoxic shock was induced by intravenous administration of lipopolysaccharide from Escherichia coli and was characterized by prolonged hypotension, gastrointestinal hyperemia and hemorrhage, and marked leakage of radiolabelled albumin into the interstitium and lumen of the gastrointestinal tract. Prostaglandin E2 (25-100 micrograms/kg i.v.) dose-dependently inhibited the hypotension and gastric damage induced by endotoxin. At the dose tested, CV-3988 (10 mg/kg i.v.) also significantly reduced endotoxin-induced hypotension and gastric damage. Both prostaglandin E2 (50 micrograms/kg) and CV-3988 reduced endotoxin-induced plasma protein leakage into the interstitium and lumen of the gastrointestinal tract, although there were differences in terms of the regions most affected by the two compounds. The results of the present study suggest that prostaglandin E2 and CV-3988 may have acted via a similar mechanism, possibly involving inhibition of a mediatory role of platelet-activating factor in endotoxic shock.     

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.     

NG-monomethyl-l-arginine (NMA) restores arterial blood pressure but reduces cardiac output in a canine model of endotoxic shock

Previous studies have suggested that NMA or similar inhibitors of nitric oxide synthesis from L-arginine reverses or prevents the hypotension associated with endotoxin administration. We wanted to determine if vascular and cardiac responses to NMA support the idea that inhibitors of nitric oxide synthesis might be useful in the treatment of septic shock. Pentobarbital-anesthetized beagle dogs were administered endotoxin for 2 hours at a dose of 250 ng/kg/min. This resulted in reductions in systemic vascular resistance (34% decrease) and mean arterial pressure (25% decrease). Administration of NMA (30 mg/kg, IV) caused large and sustained increases in mean arterial pressure and systemic vascular resistance, and a large decrease in cardiac output and femoral arterial blood flow. Although NMA restored arterial pressure, the large and sustained fall in cardiac output suggests that the cardiovascular action of NMA is detrimental to dogs treated with endotoxin.     

Kinetics of the interaction of endotoxin with polymyxin B and its analogs: a surface plasmon resonance analysis

Lipopolysaccharide, the invariant structural component of Gram-negative bacteria, when present in minute amounts in the circulation in humans elicits 'endotoxic shock' syndrome, which is fatal in 60% of the cases. Polymyxin B (PMB), a cyclic cationic peptide, neutralizes the endotoxin, but also induces many harmful side effects. Many peptide-based drugs mimicking the activity of PMB have been synthesized in an attempt to reduce toxicity while still retaining the anti-endotoxic activity. The study attempts to use the recent technique of surface plasmon resonance (SPR), in determining the kinetics of association and dissociation involved in the interaction of endotoxin with a few selected peptides that have structural features resembling PMB. The results, in conjunction with the thermodynamic data derived using isothermal titration calorimetry (ITC), stress the vital role played by amphiphilicity of the peptides and hydrophobic forces in this biologically important interaction.     

Beneficial effects of prostaglandin E2 in endotoxic shock are unrelated to effects on PAF-acether synthesis

The effects of endotoxic shock on the synthesis of PAF-acether by the stomach, duodenum and lung were examined in the rat. Furthermore, the effect of pretreatment with prostaglandin E₂ on endotoxin induced PAF-acether synthesis and changes in vascular permeability were examined. Administration of endotoxin resulted in significant increases in PAF-acether synthesis in all tissues studied. Such increases were apparent within 5–15 minutes of the administration of endotoxin, corresponding to the time when significant hypotension, hemoconcentration and increases in gastrointestinal vascular permeability were first observed. Pretreatment with prostaglandin E₂ resulted in a significant reduction of endotoxin-induced hypotension, hemoconcentration and changes in vascular permeability in the gastrointestinal tract. However, prostaglandin pretreatment did not significantly alter endotoxin-induced PAF-acether release from the gastrointestinal tissues studied. These results demonstrate that prostaglandin E₂ can significantly attenuate several of the systemic and gastrointestinal manifestations of endotoxic shock. The mechanism responsible for these beneficial actions appears to be unrelated to effects of prostaglandin E₂ on PAF-acether synthesis.