Mycobacterium bovis bacillus Calmette-Guérin induces TLR2-mediated formation of lipid bodies: intracellular domains for eicosanoid synthesis in vivo.
about
Lipid body-phagosome interaction in macrophages during infectious diseases: host defense or pathogen survival strategy?Host Lipid Bodies as Platforms for Intracellular Survival of Protozoan ParasitesMycobacterium tuberculosis: Manipulator of Protective ImmunityTrypanosoma cruzi infection and host lipid metabolismLipid Droplet Formation, Their Localization and Dynamics during Leishmania major Macrophage InfectionLipid Body Organelles within the Parasite Trypanosoma cruzi: A Role for Intracellular Arachidonic Acid MetabolismThe internal architecture of leukocyte lipid body organelles captured by three-dimensional electron microscopy tomographyPPARγ in Bacterial Infections: A Friend or Foe?Granulomas and Inflammation: Host-Directed Therapies for Tuberculosis.Foamy macrophages and the progression of the human tuberculosis granulomaMycobacterium tuberculosis uses host triacylglycerol to accumulate lipid droplets and acquires a dormancy-like phenotype in lipid-loaded macrophagesFoamy macrophages from tuberculous patients' granulomas constitute a nutrient-rich reservoir for M. tuberculosis persistenceInduction of ER stress in macrophages of tuberculosis granulomas.Lutzomyia longipalpis saliva triggers lipid body formation and prostaglandin E₂ production in murine macrophages.Type I interferon signaling regulates Ly6C(hi) monocytes and neutrophils during acute viral pneumonia in miceQuantification of lipid droplets and associated proteins in cellular models of obesity via high-content/high-throughput microscopy and automated image analysis.Pathogenicity of Mycobacterium tuberculosis is expressed by regulating metabolic thresholds of the host macrophage.Lipidomics reveals that adiposomes store ether lipids and mediate phospholipid traffic.Lipid bodies in inflammatory cells: structure, function, and current imaging techniques.Lipid droplets: size matters.Caseation of human tuberculosis granulomas correlates with elevated host lipid metabolism.Metabolic footprinting of extracellular metabolites of brain endothelium infected with Neospora caninum in vitro.Mycobacterium tuberculosis wears what it eatsMannose-capped lipoarabinomannan- and prostaglandin E2-dependent expansion of regulatory T cells in human Mycobacterium tuberculosis infectionUnraveling the complexity of lipid body organelles in human eosinophils.Transcriptomic signature of Leishmania infected mice macrophages: a metabolic point of view.Culture of mouse peritoneal macrophages with mouse serum induces lipid bodies that associate with the parasitophorous vacuole and decrease their microbicidal capacity against Toxoplasma gondii.Mycobacterium leprae intracellular survival relies on cholesterol accumulation in infected macrophages: a potential target for new drugs for leprosy treatment.Prostaglandin E2/leukotriene B4 balance induced by Lutzomyia longipalpis saliva favors Leishmania infantum infection.Characterization of host and microbial determinants in individuals with latent tuberculosis infection using a human granuloma model.Critical role of TLR2 and MyD88 for functional response of macrophages to a group IIA-secreted phospholipase A2 from snake venomApoptosis is an innate defense function of macrophages against Mycobacterium tuberculosisMycobacterium tuberculosis and the intimate discourse of a chronic infection.Natural killer cell activation distinguishes Mycobacterium tuberculosis-mediated immune reconstitution syndrome from chronic HIV and HIV/MTB coinfection.Evasion of innate immunity by Mycobacterium tuberculosis: is death an exit strategy?Emerging role of lipid droplets in host/pathogen interactions.In Situ Characterization of Splenic Brucella melitensis Reservoir Cells during the Chronic Phase of Infection in Susceptible MiceThe tuberculous granuloma: an unsuccessful host defence mechanism providing a safety shelter for the bacteria?Insulin-containing lipogenic stimuli suppress mast cell degranulation potential and up-regulate lipid body biogenesis and eicosanoid secretion in a PPARγ-independent manner.Mycobacterium marinum Degrades Both Triacylglycerols and Phospholipids from Its Dictyostelium Host to Synthesise Its Own Triacylglycerols and Generate Lipid Inclusions
P2860
Q21131401-260DEE44-DFBE-4331-995D-CC327B87B6D2Q26747388-0EEBE30A-1C12-46F6-AF9E-4BC0D5B71249Q26765471-35E10A9D-79E8-49F4-8DAE-4C11639FC9C6Q26823791-989CD02A-9022-4103-A75A-BBB9EFF8F4B3Q27322977-EB6CCB2B-D117-4A8E-B0D1-09018FA1AE7AQ27331716-F12B21B9-60D0-40B1-9491-9AA3BEB813B4Q27333495-0F230F23-B6D3-4BAD-9D21-AB21A732055AQ28070173-F65E8349-45B6-4DA5-9C5E-E25B5A795DCFQ28076037-64D8F43B-946C-4B3C-A332-33749D6914A9Q28255669-E2B4C397-D501-4CE2-AAED-F0E03BCB1C5AQ28478716-B9C7CC2F-4D79-4CDB-9C13-1D6CECF7BCBDQ33383817-393BCD5F-08E6-4BD4-AACC-F9FD72AC4F91Q33697646-86040DE7-EC5F-451D-B73E-C70D23439461Q33745236-82AA5857-C652-40F9-A36B-72E140E21A83Q33839474-74D94E20-5393-46C5-8563-4D3B720FE901Q33860061-3443FE4D-05B4-4DCF-9A97-2B6FF0A830DDQ33946174-0C1D9818-BDF4-4073-B63D-4D90CA7B98AEQ34001841-BB48DF4F-6798-4DCF-BFF9-30B33C0594C4Q34026238-DEA13A37-6729-4CF4-A600-5CB38719E5E0Q34028156-719F1487-F19C-426F-9824-659773BA1B4DQ34033091-619AE106-F228-48F3-B49A-782A391BBB5CQ34041371-51522510-E9D0-43A4-B83B-52088E59B73FQ34089860-71FE2C50-723C-4C8C-A9D1-7517C2325882Q34202238-F6E3FEED-9808-4282-9F0D-C759D32CED04Q34341337-18E223AF-1B03-410E-BAF2-649E2E04F52FQ34396113-BE9CD33D-BDB2-4BB2-8008-4B0EF680D39AQ34548440-240766A4-F708-4340-A5AB-6B8700CD84EFQ34669776-5294CDD2-6AC8-40FF-AE36-117260DB79CDQ34808101-89208B14-4AA6-4693-88E8-914E29EF100AQ35111159-0B6D8C99-9B73-41F4-9AFC-128C7A04CEC6Q35143981-6ADB3D90-D7DE-48A6-9855-84571BA34A24Q35163164-65820469-A918-4EC7-B39E-5B46F4141877Q35216595-BE1AEE9D-257E-4C16-9BE3-5286E5BCBA0EQ35387470-81262784-9003-4E16-93F3-B4BA106E2BE8Q35566913-896AE588-030C-416F-AF21-726CEA059A0FQ35709709-EE2C463E-F856-4F65-A799-9FAA89942745Q35777394-9686EBC7-D581-4934-A8B0-0D15CC711039Q36090400-5F9BA368-3B29-4C3A-9B74-29EBF98A301AQ36188874-2E9A10CB-616A-491C-9AE5-0384C0C99686Q36254134-BED8D778-4E44-49AF-9D05-CF7DB9762D2B
P2860
Mycobacterium bovis bacillus Calmette-Guérin induces TLR2-mediated formation of lipid bodies: intracellular domains for eicosanoid synthesis in vivo.
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
2006年學術文章
@zh-hant
name
Mycobacterium bovis bacillus C ...... eicosanoid synthesis in vivo.
@en
Mycobacterium bovis bacillus C ...... eicosanoid synthesis in vivo.
@nl
type
label
Mycobacterium bovis bacillus C ...... eicosanoid synthesis in vivo.
@en
Mycobacterium bovis bacillus C ...... eicosanoid synthesis in vivo.
@nl
prefLabel
Mycobacterium bovis bacillus C ...... eicosanoid synthesis in vivo.
@en
Mycobacterium bovis bacillus C ...... eicosanoid synthesis in vivo.
@nl
P2093
P1476
Mycobacterium bovis bacillus C ...... eicosanoid synthesis in vivo.
@en
P2093
Eduardo Werneck-Barroso
Gleydes G Parreira
Heloisa D'Avila
Hugo C Castro-Faria-Neto
Patrícia T Bozza
Rossana C N Melo
P304
P356
10.4049/JIMMUNOL.176.5.3087
P407
P577
2006-03-01T00:00:00Z