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: UNIPROT:P43026 (lipopolysaccharide)
62,215 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Although Escherichia coli strains possessing the K1 capsule are predominant among isolates from neonatal E. coli meningitis and most of these K1 isolates are associated with a limited number of 0 lipopolysaccharide (LPS) types, the basis of this association of K1 and certain 0 antigens with neonatal E. coli meningitis is not clear. The present study examined in experimental E. coli bacteremia and meningitis in newborn and adult rats whether or not the K1 capsule and/or O-LPS antigen are critical determinants in the development of meningitis. Rats received subcutaneously at K1 E. coli strain (018+K1+) or mutants lacking either the K1 capsule (018+K1-) or 0 side-chain (018-K1+). 12-24 h later, blood and cerebrospinal fluid (CSF) specimens were obtained for quantitative cultures. The isolation of E. coli from CSF was observed in both newborn and adult rats infected with K1+ strains regardless of LPS phenotype (018+ or 18-) who also developed a high degree of bacteremia (e.g., greater than 10(4) CFU/ml of blood). In contrast, none of the newborn and adult rats infected with 018+K1- and developing bacteremia of greater than 10(4) were found to have positive CSF cultures. These findings indicate that the presence of the K1 capsule and a high degree of bacteremia are key determinants in the development of E. coli meningitis, suggesting that there may be specific binding sites present in the brain which have an affinity for the K1 capsule and thus may be responsible for the entry of K1-encapsulated E. coli into the meninges.
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PMID:The K1 capsule is the critical determinant in the development of Escherichia coli meningitis in the rat. 132

The molecular basis of central nervous system invasiveness by Haemophilus influenzae has been studied by using genetically defined mutants and in vivo and in vitro model systems. Capsular polysaccharide and lipopolysaccharide are important microbial determinants of the ability of H. influenzae to traverse the nasopharynx and localize in the cerebrospinal fluid and meninges after bacteremia. The genes for type b capsule confer greater invasive potential than do those for other capsular polysaccharides, although the molecular basis for this is not understood. Mutants have also indicated the role of lipopolysaccharide in enhancing the efficiency of bacterial translocation from the nose to the blood and in facilitating intravascular survival. Organisms that localize successfully in the blood and central nervous system are the progeny of a small fraction of the original challenge inoculum, often a single bacterium.
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PMID:Molecular basis of invasive Haemophilus influenzae type b disease. 158 86

Neither excitotoxic neurodegeneration nor lipopolysaccharide induces an acute myelomonocytic exudate in the murine central nervous system (CNS) parenchyma (Andersson, P.-B., V. H. Perry, and S. Gordon. 1991. Neuroscience, 42:201; Andersson, P.-B., V. H. Perry, and S. Gordon. 1992. Neuroscience 48:169). In this study formyl-methionyl-leucyl-phenylalanine, platelet-activating factor, interleukin 8 (IL-8), IL-1, or tumor necrosis factor alpha were injected into the hippocampus to assess whether these leukocyte chemotaxins and known mediators of recruitment could bypass this block. They induced morphologic activation of microglia and widespread leukocyte margination but little or no cell exudation into the CNS parenchyma. By contrast, there was acute myelomonocytic cell recruitment to the choroid plexus, meninges, and ventricular system, comparable to that in the skin after subcutaneous injection. The normal CNS parenchyma appears to be a tissue unique in its resistance to leukocyte diapedesis, which is shown here to be at a step beyond chemotactic cytokine secretion or induction of leukocyte adhesion to cerebral endothelium.
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PMID:Intracerebral injection of proinflammatory cytokines or leukocyte chemotaxins induces minimal myelomonocytic cell recruitment to the parenchyma of the central nervous system. 161 59

Tumor necrosis factor alpha (TNF-alpha) is a cytokine that is responsible, in part, for several aspects of the acute-phase response to inflammation, including the generation of fever. TNF-alpha has direct effects on central nervous system neurons deep within the hypothalamus that are involved in producing the febrile response, but the blood-brain barrier prevents circulating TNF-alpha from having access to these sites. We therefore have hypothesized that TNF-alpha may be produced in the brain and used as a mediator in the cerebral components of the acute-phase response. We used in situ hybridization to determine the distribution of production of TNF-alpha mRNA in the mouse brain after systemic administration of lipopolysaccharide. During the initial phase of fever, hybridization was observed in perivascular cells and neurons in circumventricular organs, including the vascular organ of the lamina terminalis, median eminence, and area postrema, as well as along the ventral surface of the medulla; hybridization was also prominent over many cell in the meninges. During the late phase of the response, hybridization was observed over neurons in the pericircumventricular nuclei such as the anteroventral periventricular and arcuate nuclei of the hypothalamus and the nucleus of the solitary tract. TNF-alpha produced by a cascade of neurons within the brain may participate in the complex autonomic, neuroendocrine, metabolic, and behavioral responses to infection and inflammation.
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PMID:Regional induction of tumor necrosis factor alpha expression in the mouse brain after systemic lipopolysaccharide administration. 797 71

Depending on its concentration and target site, nitric oxide (NO) is an intracellular messenger or inflammatory mediator. Recent research supports an expanded role for NO in the pathophysiology of neuroinflammatory diseases. Using analytical and pharmacological techniques, the present study identifies NO as a potential inflammatory mediator in experimental meningitis in the rat. Intracisternal administration of lipopolysaccharide (LPS) induced NO synthesis from the lateral and third ventricle choroid plexi and surface meninges but not from systemic white blood cells, suggesting that meningeal inflammation was restricted to the central nervous system. The time course of NO production revealed at 3 hr lag after intracisternal LPS, followed by a peak of 8 hr and subsequent decrease to baseline 24 hr after LPS dosing. The pharmacological rank order of NO synthase inhibitors in meningeal preparations (NG-aminoarginine > NG-methylarginine approximately aminoguanidine) was slightly different than the rank order for the LPS-stimulated monocyte-macrophage cell line, J774A.1 (NG-aminoarginine approximately NG-methylarginine > aminoguanidine). A prolonged inhibition of NO production was observed in cultured meningeal preparations or J774A.1 cells briefly exposed to and washed free from NO synthase inhibitors. These findings implicate NO as an inflammatory mediator during experimental meningitis, and suggest that NO synthase inhibitors might be potentially useful agents for meningeal inflammation.
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PMID:Pharmacological characterization of nitric oxide production in a rat model of meningitis. 873 93

Production of prostaglandins is a critical step in transducing immune stimuli into central nervous system (CNS) responses, but the cellular source of prostaglandins responsible for CNS signalling is unknown. Cyclooxygenase catalyzes the rate-limiting step in the synthesis of prostaglandins and exists in two isoforms. Regulation of the inducible isoform, cyclooxygenase 2, is thought to play a key role in the brain's response to acute inflammatory stimuli. In this paper, we report that intravenous lipopolysaccharide (LPS or endotoxin) induces cyclooxygenase 2-like immunoreactivity in cells closely associated with brain blood vessels and in cells in the meninges. Neuronal staining was not noticeably altered or induced in any brain region by endotoxin challenge. Furthermore, many of the cells also were stained with a perivascular microglial/macrophage-specific antibody, indicating that intravenous LPS induces cyclooxygenase in perivascular microglia along blood vessels and in meningeal macrophages at the edge of the brain. These findings suggest that perivascular microglia and meningeal macrophages throughout the brain may be the cellular source of prostaglandins following systemic immune challenge. We hypothesize that distinct components of the CNS response to immune system activation may be mediated by prostaglandins produced at specific intracranial sites such as the preoptic area (altered sleep and thermoregulation), medulla (adrenal corticosteroid response), and cerebral cortex (headache and encephalopathy).
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PMID:Intravenous lipopolysaccharide induces cyclooxygenase 2-like immunoreactivity in rat brain perivascular microglia and meningeal macrophages. 913 Jun 63

In order to elucidate the mechanism(s) of neuronal protection by hypothermia against ischemic damage, we examined the effect of lowering temperature on the microglial activation that is thought to cause the development of ischemia-induced neuronal damages. Cultured microglia from neonatal rats were measured for microglial activation by the following indices: production of superoxide and nitric oxide by the methods of acetyl-cytochrome c reduction and nitrite accumulation in the culture medium, respectively, and cell proliferation evaluated by [3H]thymidine uptake. At 30 degrees C, superoxide production induced by phorbol ester was approximately as low as 30% of the control at 37 degrees C, and nitric oxide production after addition of lipopolysaccharide was decreased to approximately 25% of the control. The time course of nitric oxide production indicates that the induction of nitric oxide synthase seemed to be significantly suppressed by lowering temperature. In addition, the proliferation of microglia was remarkably inhibited at 30 degrees C. The level of proliferation in the hypothermic condition is much lower in microglia (14% of the control) than those in astrocytes cultured from brain cortices (96%) and fibroblasts cultured from brain meninges (53%), suggesting that the microglial activation is highly susceptible to lowering temperature. The present study indicates that hypothermia potently inhibits proliferation, superoxide and nitric oxide production of cultured microglia and that the hypothermic protection against postischemic neuronal damage might be, at least in part, due to the suppression of microglial activation.
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PMID:Hypothermic suppression of microglial activation in culture: inhibition of cell proliferation and production of nitric oxide and superoxide. 930 Apr 14

Nitric oxide synthase (NOS)-containing neurons are found in many loci throughout the central nervous system, which include the cerebral cortex, the cerebellum, the hippocampus, and the hypothalamus. NO plays a very important role in control of neuronal activity in all of these areas by diffusing into neurons where it activates soluble guanylate cyclase (sGC) leading to generation of cyclic guanosine monophosphate (cGMP) and cyclooxygenase 1 leading to generation of prostaglandins. Both of these active agents are involved in mediating the actions of NO, the first gaseous transmitter. In the cerebellum, NO is extremely important and it is also thought to mediate long-term potentiation in the hippocampus. Various stresses and corticoids have been shown in monkeys and also in rodents to cause neuronal cell death. This may be via the stimulation of glutamic acid release, which by N-methyl-D-aspartate (NMDA) receptors causes release of NO, which can lead to neuronal cell death. In the hypothalamus,. NO stimulates corticotropin-releasing hormone (CRH), prolactin releasing factor, growth hormone-releasing hormone (GHRH), and somatostatin, lutenizing hormone-releasing hormone (LHRH), but not follicle stimulating hormone-releasing factor (FSHRF) release. In situations of increased release of NO in the hypothalamus, it could cause neuronal cell death. Following bacterial or viral infections, toxic products of the ineffective agents, such as bacterial lipopolysaccharide (LPS), circulate to the brain, where they induce interleukin-1 and iNOS mRNA and synthesis. After several hours delay, massive quantities of NO are released. Induction of iNOS occurs in the choroid plexus, meninges, in circumventricular organs, and in large numbers of iNOS neurons in the arcuate and paraventricular nuclei. The large amounts of NO released by iNOS may well produce death not only of neurons but also glial. Repeated bouts of systemic infection even without direct neural involvement could result in induction of iNOS in the central nervous system and lead to large fall out of neurons in hippocampus to impair memory, hypothalamus to decrease fever, and neuroendocrine response to infection, and could play a role in the pathogenesis of degenerative neuronal diseases of aging, such as Alzheimers. The largest induction of iNOS occurs in the anterior pituitary and pineal glands. The damage to the pituitary could also impair responses to stress and infection, and the release of NO during infection could be responsible for the degenerative changes in the pineal and diminished release of melatonin, an antioxident, and consequently, an antiaging hormone, that occur with age.
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PMID:The nitric oxide hypothesis of brain aging. 931 47

In this study we investigate the mRNA expression of inhibitory factor kappaBalpha (IkappaBalpha) in cells of the rat brain induced by an intraperitoneal (i.p.) injection of lipopolysaccharide (LPS). IkappaB controls the activity of nuclear factor kappaB, which regulates the transcription of many immune signal molecules. The detection of IkappaB induction, therefore, would reveal the extent and the cellular location of brain-derived immune molecules in response to peripheral immune challenges. Low levels of IkappaBalpha mRNA were found in the large blood vessels and in circumventricular organs (CVOs) of saline-injected control animals. After an i.p. LPS injection (2.5 mg/kg), dramatic induction of IkappaBalpha mRNA occurred in four spatio-temporal patterns. Induced signals were first detected at 0.5 hr in the lumen of large blood vessels and in blood vessels of the choroid plexus and CVOs. Second, at 1-2 hr, labeling dramatically increased in the CVOs and choroid plexus and spread to small vascular and glial cells throughout the entire brain; these responses peaked at 2 hr and declined thereafter. Third, cells of the meninges became activated at 2 hr and persisted until 12 hr after the LPS injection. Finally, only at 12 hr, induced signals were present in ventricular ependyma. Thus, IkappaBalpha mRNA is induced in brain after peripheral LPS injection, beginning in cells lining the blood side of the blood-brain barrier and progressing to cells inside brain. The spatiotemporal patterns suggest that cells of the blood-brain barrier synthesize immune signal molecules to activate cells inside the central nervous system in response to peripheral LPS. The cerebrospinal fluid appears to be a conduit for these signal molecules.
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PMID:Induction of inhibitory factor kappaBalpha mRNA in the central nervous system after peripheral lipopolysaccharide administration: an in situ hybridization histochemistry study in the rat. 938 Jul 46

The inflammatory cytokine interleukin-1 has been implicated as a mediator of many centrally controlled responses, such as fever and increased activity of the hypothalamic-pituitary adrenal axis, after systemic infections. To identify the neuroanatomical loci of brain interleukin-1-producing cells during infection, we investigated interleukin-1beta messenger RNA expression by in situ hybridization histochemistry using a 500 nt ribonucleotide probe applied on brain sections from rats injected intraperitoneally with 2.5 mg/kg bacterial lipopolysaccharide or saline. In control animals, interleukin-1beta messenger RNA was not detectable. In the brains of lipopolysaccharide-injected animals, two temporally and spatially distinct waves of interleukin-1beta messenger RNA induction were observed. First, cell labelling appeared at 0.5 h, peaked at 2 h, and declined at 4-8 h. The labelled cells were concentrated in circumventricular organs--organum vasculosum of the lamina terminalis, subfornical organ, median eminence, and area postrema--and in choroid plexus, meninges, and blood vessels. Second, at 8-12 h, scattered small cells became labelled throughout the entire brain parenchyma; the labelling subsided by 24 h. Labelling was not observed in any neurons. In the pituitary, lipopolysaccharide induced strong interleukin-1beta messenger RNA expression initially in the anterior lobe at 0.5-1 h, and later in the neural lobe at 1-2 h, and subsiding thereafter. The results show that at early time points, peripheral lipopolysaccharide induces interleukin-1beta message production at the blood brain barrier and in circumventricular organs where the blood brain barrier is leaky. After a time delay of 6-10 h, however, interleukin-1beta messenger RNA is primarily expressed by non-neuronal cells of the brain in the brain parenchyma. These results suggest that the source of initial brain IL-1 activity after peripheral lipopolysaccharide injection derives from cells of the blood-brain barrier and the circumventricular organs, and the sustained interleukin-1 activity in the central nervous system thereafter is derived from glia.
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PMID:Time course and localization patterns of interleukin-1beta messenger RNA expression in brain and pituitary after peripheral administration of lipopolysaccharide. 946 17


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