Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0036690 (sepsis)
59,461 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The reaction between luminol as a chemiluminescence probe and 3-morpholinosydnonimine (SIN-1) as a peroxynitrite donor was evaluated in order to determine the action of several antioxidants. Several well-known antioxidants found in biological fluids or cells modify the light profile of the reaction between SIN-1 and luminol. One main modification was characterized by a transient suppression of the light signal, thus permitting evaluation of an induction time (sigma) which is linearly related to the concentration of the additive. From induction time measurements and using Trolox as a reference antioxidant, the trapping ability of a compound against oxidants and radicals produced in the luminol-SIN-1 reaction at pH 7. 4 was determined. Uric acid showed higher antioxidant capacity than Trolox, while bilirubin and ascorbic acid, in decreasing order, were slightly less efficient. On the other hand the main modification of the light signal produced by superoxide dismutase, desferrioxamine and myoglobin was characterized by a decrease of the luminescence during the course of the reaction. The reaction luminol-SIN-1 was compared with the known luminol-ABAP (2,2'-azo-bis-2-amidinopropane) method for evaluation of antioxidant capacity in human plasma, since this biological fluid modifies the luminol-SIN-1 reaction with well-defined induction times. Samples were obtained from patients with sepsis, a condition where it has been postulated that excess oxygen radicals including peroxynitrite are produced. Using Trolox as reference, the results (mean +/- standard error of mean) of both assays showed that the patients (SIN-1, 263 +/- 16; ABAP, 218 +/- 13; n = 19) have significantly (SIN-1, p < 0.02; ABAP, p < 0.001) lower values in comparison to non-septic controls (SIN-1, 330 +/- 16; ABAP, 398 +/- 16; n = 20). SIN-1 could be useful as a source of oxidant for the characterization of antioxidant behaviour in a system where superoxide and nitric oxide are simultaneously generated.
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PMID:Effect of antioxidants on induction time of luminol luminescence elicited by 3-morpholinosydnonimine (SIN-1). 1039 65

Tumor necrosis factor-alpha (TNF-alpha) and free radicals have been implicated in the pathogenesis of neonatal septicemia and its complications. This case control study was conducted between November 1996 to July 1997 to determine the levels of TNF-alpha and free radical scavengers viz. superoxide dismutase (SOD) and glutathione peroxidase (GPX) in the serum of 30 septic neonates and 20 healthy controls. Patients with neonatal sepsis registered significantly higher levels of TNF-alpha, SOD and GPX in comparison to controls (p < 0.05). The neonates with septic shock had five fold increase in TNF-alpha levels (2262 +/- 605.8 pg/ml) as compared to those without shock (738.8 +/- 728.8 pg/ml). There was no statistically significant difference in levels of antioxidant enzymes between neonates with shock and without shock. The levels of TNF-alpha and antioxidant enzymes were not affected by the type of organism isolated in blood culture.
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PMID:Serum TNF-alpha and free radical scavengers in neonatal septicemia. 1079 4

Septicaemia is a major threat to survival during the early stages of life. There are several reports that suggest that reactive oxygen species (ROs) play a role in a wide variety of diseases. We estimated the activity of xanthine oxidase (XO), malondialdehyde (MDA) content, creatine phosphokinase (CPK) activity, activities of key enzymatic antioxidants, such as superoxide dismutase (SOD), glutathione peroxidase (GPx) and peroxidase (PO), and non-enzymatic antioxidants, viz. uric acid (UA) and albumin (ALB), in 30 neonates with sepsis and 20 age-matched controls. The babies were categorized as preterm/term, early onset/late onset, and shock/without shock, as per clinical and laboratory investigations. The study was carried out to evaluate the status of antioxidant enzymes and non-enzymatic antioxidants with a view to suggesting the introduction of antioxidant therapy in neonatal sepsis. The activities of serum XO, CPK, SOD and GPx, and the content of MDA were found to be significantly elevated in the neonates with sepsis when compared with controls. Conversely, the activity of PO and the levels of UA and ALB were decreased. The septic, full-term neonates registered significantly higher CPK activity (70%) than the preterm septic neonates. However, infants with late-onset and shock sepsis had a significant decrease in CPK activity (p < 0.05) compared with their corresponding sub-groups. Likewise, UA levels were found to be 28% depressed (p < 0.05) in the babies with late-onset sepsis and 51% increased (p < 0.001) in babies with shock compared with their respective sub-groups. Neonates with septic shock also registered a significant elevation in GPx activity (28%) compared with those without shock. This study suggests increased production of ROs in neonates with sepsis, as evidenced by the positive regulation of XO, SOD and GPx activity. The elevation of antioxidant enzymes, however, was not so effective as to protect from cellular damage and thereby result in higher MDA production. It is evident that antioxidant therapy might be useful in the management of neonates with sepsis but further detailed clinico-biochemical investigations are required to define effective antioxidant therapy.
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PMID:Alterations in antioxidant status during neonatal sepsis. 1082 10

A major feature of septic shock is the development of a vascular crisis characterized by nonresponsiveness to sympathetic vasoconstrictor agents and the subsequent irreversible fall in blood pressure. In addition, sepsis, like other inflammatory conditions, results in a large increase in the production of free radicals, including superoxide anions (O(2)) within the body. Here we show that O(2) reacts with catecholamines deactivating them in vitro. Moreover, this deactivation would appear to account for the hyporeactivity to exogenous catecholamines observed in sepsis, because administration of a superoxide dismutase (SOD) mimetic to a rat model of septic shock to remove excess O(2) restored the vasopressor responses to norepinephrine. This treatment with the SOD mimetic also reversed the hypotension in these animals; suggesting that deactivation of endogenous norepinephrine by O(2) contributes significantly to this aspect of the vascular crisis. Indeed, the plasma concentrations of both norepinephrine and epinephrine in septic rats treated with the SOD mimetic were significantly higher than in untreated rats. Interestingly, the plasma concentrations for norepinephrine and epinephrine were inversely related to the plasma concentrations of adrenochromes, the product of the autoxidation of catecholamines initiated by O(2). We propose, therefore, that the use of a SOD mimetic represents a new paradigm for the treatment of septic shock. By removing O(2), exogenous and endogenous catecholamines are protected from autoxidation. As a result, both hyporeactivity and hypotension are reversed, generation of potentially toxic adrenochromes is reduced, and survival rate is improved.
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PMID:Inactivation of catecholamines by superoxide gives new insights on the pathogenesis of septic shock. 1094 34

Recent studies indicate that sepsis is associated with enhanced generation of several free radical species (nitric oxide, superoxide, hydrogen peroxide) in skeletal muscle. While studies suggest that free radical generation causes uncoupling of oxidative phosphorylation in sepsis, no previous report has examined the role of free radicals in modulating skeletal muscle oxygen consumption during State 3 respiration or inhibiting the electron transport chain in sepsis. The purpose of the present study was to examine the effects of endotoxin-induced sepsis on State 3 diaphragm mitochondrial oxygen utilization and to determine if inhibitors/scavengers of various free radical species would protect against these effects. We also examined mitochondrial protein electrophoretic patterns to determine if observed endotoxin-related physiological derangements were accompanied by overt alterations in protein composition. Studies were performed on: (a) control animals, (b) endotoxin-treated animals, (c) animals given endotoxin plus PEG-SOD, a superoxide scavenger, (d) animals given endotoxin plus L-NAME, a nitric oxide synthase inhibitor, (e) animals given only PEG-SOD or L-NAME, (f) animals given endotoxin plus D-NAME, and (g) animals given endotoxin plus denatured PEG-SOD. We found: (a) no alteration in maximal State 3 mitochondrial oxygen consumption rate at 24 h after endotoxin administration, but (b) a significant reduction in oxygen consumption rate at 48 h after endotoxin, (c) no effect of endotoxin to induce uncoupling of oxidative phosphorylation, (d) either PEG-SOD or L-NAME (but neither denatured PEG-SOD nor D-NAME) prevented endotoxin-mediated reductions in State 3 respiration rates, (e) some mitochondrial proteins underwent tyrosine nitrosylation at 24 h after endotoxin administration, and (f) SDS-page electrophoresis of mitochondria from endotoxin-treated animals revealed a selective depletion of several proteins at 48 h after endotoxin administration (but not at 24 h); (g) administration of L-NAME or PEG-SOD prevented this protein depletion. These data provide the first evidence that endotoxin-induced reductions in State 3 mitochondrial oxygen consumption are free radical-mediated.
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PMID:Free radicals alter maximal diaphragmatic mitochondrial oxygen consumption in endotoxin-induced sepsis. 1113 3

Recent studies have indicated that sepsis is associated with enhanced generation of several free-radical species (nitric oxide [NO], superoxide, hydrogen peroxide) in skeletal muscle. It is also known that this enhanced free-radical generation results in reductions in skeletal muscle force-generating capacity, but the precise mechanism(s) by which free radicals exert this effect in sepsis has not been determined. We postulated that free radicals might react directly with the contractile proteins in this condition, altering contractile protein force-generating capacity. To test this theory, we compared the force generation of single Triton-skinned diaphragmatic fibers (Triton skinning exposes the contractile apparatus, permitting direct assessment of contractile protein function) from the following groups of rats: (1) control animals; (2) endotoxin-treated animal; (3) animals given endotoxin plus polyethylene glycol- superoxide dismutase (PEG-SOD), a superoxide scavenger; (4) animals given endotoxin plus N(omega)-nitro-L-arginine methylester (L-NAME), a NO synthase inhibitor; (5 ) animals given only PEG-SOD or L-NAME; and (6 ) animals given endotoxin plus denatured PEG-SOD. We found that endotoxin administration produced both a reduction in the maximum force-generating capacity (Fmax) (i.e., a decrease in Fmax) of muscle fibers and a reduction in fiber calcium sensitivity (i.e., an increase in the Ca2+ concentration required to produce half-maximal activation [Ca50]). L-NAME and PEG-SOD administration preserved Fmax and Ca50 in endotoxin-treated animals; neither drug affected these parameters in non-endotoxin treated animals. Denatured PEG-SOD failed to inhibit endotoxin-related alterations in contractile protein function. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of skinned fibers from endotoxin-treated animals revealed a selective depletion of several proteins; administration of L-NAME or PEG-SOD to endotoxin-treated animals prevented this protein depletion, paralleling the effect of these two agents to prevent a reduction in contractile protein force-generating capacity. These data indicate that free radicals (superoxide, NO, or daughter species of these radicals) play a central role in altering skeletal muscle contractile protein force-generating capacity in endotoxin-induced sepsis.
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PMID:Free radical-induced contractile protein dysfunction in endotoxin-induced sepsis. 1115 56

Oxidative damage plays a key role in septic shock induced by lipopolysaccharide (LPS) which is known to enhance the formation of reactive oxygen species (ROS). In this study, biochemical parameters indicative of oxidative stress were tested in the rat heart following LPS challenge, with and without pretreatment with the antioxidants NAO (natural antioxidant) and apocynin. NAO is a natural antioxidant isolated and purified from spinach and its main components are flavonoids and coumaric acid derivatives. Treatment with LPS alone significantly (P<0.05) increased the malondialdehyde (MDA) level in heart, both in cytosolic and mitochondrial fractions by 1.5- and 2.4-fold, respectively, and in plasma (2.66 fold). In the heart homogenate, the level of hydroperoxides also increased significantly (P<0.05). In addition, LPS treatment significantly (P<0.05) increased NADPH oxidase activity in the heart microsomal fraction by approximately 10-fold compared to control. Pretreatment for 7 days with either apocynin or NAO prior to the LPS challenge significantly (P<0.05) improved rat survival, decreased MDA levels in both fractions and decreased microsomal NADPH-oxidase activity, compared to LPS alone. Catalase (CAT) activity slightly increased at 24 h post-LPS injection in LPS group and returned to the control level in the apocynin treated group. No meaningful changes were indicated for glutathione peroxidase activity among all the treatment groups. The activities of cytosolic and mitochondrial superoxide dismutase (SOD) enzymes significantly (P<0.05) increased approximately 20% in the LPS-treated group, compared to control. Apocynin significantly (P<0.05) decreased SOD level in the mitochondrial fraction with no effect on the cytosolic fraction; whereas, NAO had no important effect on SOD level in both fractions. The beneficial pretreatment effects of the antioxidants against oxidative stress in the rat heart presented in this study may suggest a potential chemopreventive effect of this compound in sepsis prevention.
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PMID:The effect of natural antioxidants, NAO and apocynin, on oxidative stress in the rat heart following LPS challenge. 1151

During sepsis the host's system-wide response to microbial invasion seems dysregulated. Here we explore the diverse multiorgan transcriptional programs activated during systemic inflammation in a cecal ligation/puncture model of sepsis in rats. Using DNA microarrays representing 7398 genes, we examined the temporal sequence of sepsis-induced gene expression patterns in major organ systems including lung, liver, kidney, thymus, spleen, and brain. Although genes known to be associated with systemic inflammation were identified by our global transcript analysis, many genes and expressed sequence tags not previously linked to the septic response were also elucidated. Taken together, our results suggest activation of a highly complex transcriptional response in individual organs of the septic animal. Several overlying themes emerged from our genome-scale analysis that includes 1) the sepsis response elicited gene expression profiles that were either organ-specific, common to more than one organ, or distinctly opposite in some organs; 2) the brain is protected from sepsis-induced gene activation relative to other organs; 3) the thymus and spleen have an interesting cohort of genes with opposing gene expression patterns; 4) genes with proinflammatory effects were often balanced by genes with anti-inflammatory effects (eg, interleukin-1beta/decoy receptor, xanthine oxidase/superoxide dismutase, Ca2+-dependent PLA2/Ca2+-independent PLA2); and 5) differential gene expression was observed in proteins responsible for preventing tissue injury and promoting homeostasis including anti-proteases (TIMP-1, Cpi-26), oxidant neutralizing enzymes (metallothionein), cytokine decoy receptors (interleukin-1RII), and tissue/vascular permeability factors (aquaporin 5, vascular endothelial growth factor). This global perspective of the sepsis response should provide a molecular framework for future research into the pathophysiology of systemic inflammation. Understanding, on a genome scale, how an organism responds to infection, may facilitate the development of enhanced detection and treatment modalities for sepsis.
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PMID:Molecular signatures of sepsis: multiorgan gene expression profiles of systemic inflammation. 1158 46

The molecular sources of reactive oxygen species (ROS) in skeletal muscles are not well understood. We hypothesized that nonphagocyte NAD(P)H oxidase could be a source of ROS in muscle fibers. We thus investigated the existence, structure, and contribution of nonphagocyte NAD(P)H oxidase to ROS production in rat skeletal muscles. ROS production and NAD(P)H oxidase activity were evaluated by lucigenin-enhanced chemiluminescence and NADH consumption rate, whereas enzyme composition was monitored by reverse transcription-polymerase chain reaction and immunoblotting. Basal O(-)(2) production in muscle strips from normal rats averaged 1.4 nmol/mg per 10 min and increased to approximately 18 nmol/mg per 10 min in the presence of NADH. Muscle O(-)(2) production and NADH consumption were inhibited by Tiron, superoxide dismutase, apocynin, and diphenyleneiodonium but not by inhibitors of cyclo-oxygenases, xanthine oxidase, nitric oxide synthases (NOS), and mitochondrial enzymes. We detected mRNA and proteins of p22(phox), gp91(phox), p47(phox), and p67(phox) subunits in normal rat muscles. These subunits were localized in close proximity to the sarcolemma. Induction of sepsis in rats doubled muscle O(-)(2) production with no major changes in muscle NADPH oxide subunit expression. In lipopolysaccharide-treated but not in control muscles, O(-)(2) production was increased significantly by NOS inhibition. We conclude that a constitutively active NAD(P)H oxidase enzyme complex exists in normal skeletal muscle fibers and contributes to ROS production. In septic rats, this production is increased but measurable O(-)(2) is reduced by enhanced NO production.
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PMID:Molecular characterization of a superoxide-generating NAD(P)H oxidase in the ventilatory muscles. 1255 34

The effects of nitric oxide (NO) from calcium-independent NO synthase (iNOS) on microvascular protein leak in acute lung injury (ALI) are uncertain, possibly because of disparate effects of iNOS-derived NO from different cells. We assessed the contribution of iNOS from inflammatory versus parenchymal cells to pulmonary protein leak in murine cecal ligation and perforation-induced ALI. We studied iNOS+/+, iNOS-/-, and two reciprocally bone marrow-transplanted iNOS chimeric mice groups: + to - (iNOS+/+ donor bone marrow-transplanted into iNOS-/- recipient mice) and - to +. Sepsis-induced ALI was characterized by pulmonary leukocyte infiltration, increased pulmonary iNOS activity, and increased pulmonary microvascular protein leak, as assessed by Evans blue (EB) dye. Despite equal neutrophil infiltration, sepsis-induced EB-protein leak was eliminated in iNOS-/- mice and in - to + iNOS chimeras (parenchymal cell-localized iNOS) but was preserved in + to - chimeric mice (inflammatory cell-localized iNOS). EB-protein leak was also prevented by pretreatment with allopurinol and superoxide dismutase. Microvascular protein leak in sepsis-induced ALI is uniquely dependent on iNOS in inflammatory cells with no obvious contribution of iNOS in pulmonary parenchymal cells. Pulmonary protein leak is also dependent on superoxide, suggesting an effect of peroxynitrite rather than NO itself.
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PMID:Role of inducible nitric oxide synthase in pulmonary microvascular protein leak in murine sepsis. 1207 65


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