about
Harnessing Mechanistic Knowledge on Beneficial Versus Deleterious IFN-I Effects to Design Innovative Immunotherapies Targeting Cytokine Activity to Specific Cell TypesIntrinsic host restriction factors of human cytomegalovirus replication and mechanisms of viral escapeHow Mouse Macrophages Sense What Is Going On.DNA Nanotechnology for Cancer TherapyExploring the Homeostatic and Sensory Roles of the Immune SystemCytosolic Innate Immune Sensing and Signaling upon InfectionModulating the Innate Immune Response to Influenza A Virus: Potential Therapeutic Use of Anti-Inflammatory DrugsMisdelivery at the Nuclear Pore Complex-Stopping a Virus Dead in Its TracksRegulation of type I interferon responsesMechanisms of chemotherapy-induced behavioral toxicitiesRecognition of cytosolic DNA by cGAS and other STING-dependent sensorsRecognition of human oncogenic viruses by host pattern-recognition receptorsCytosolic DNA sensing via the stimulator of interferon genes adaptor: Yin and Yang of immune responses to DNAThe innate immune sensor IFI16 recognizes foreign DNA in the nucleus by scanning along the duplex.Structure-Function Analysis of STING Activation by c[G(2′,5′)pA(3′,5′)p] and Targeting by Antiviral DMXAADNA sensor cGAS-mediated immune recognitionInnate immune recognition of DNA: A recent historyInternational Union of Basic and Clinical Pharmacology. XCVI. Pattern recognition receptors in health and diseaseDissecting How CD4 T Cells Are Lost During HIV InfectionTRIM30α Is a Negative-Feedback Regulator of the Intracellular DNA and DNA Virus-Triggered Response by Targeting STINGElevation of Alanine Aminotransferase Activity Occurs after Activation of the Cell-Death Signaling Initiated by Pattern-Recognition Receptors but before Activation of Cytolytic Effectors in NK or CD8+ T Cells in the Liver During Acute HCV InfectionUnique Loss of the PYHIN Gene Family in Bats Amongst Mammals: Implications for Inflammasome SensingRNF26 temporally regulates virus-triggered type I interferon induction by two distinct mechanismsRaster image cross-correlation analysis for spatiotemporal visualization of intracellular degradation activities against exogenous DNAs.Two-way learning with one-way supervision for gene expression data.Cytosolic-DNA-mediated, STING-dependent proinflammatory gene induction necessitates canonical NF-κB activation through TBK1Getting "Inside" Type I IFNs: Type I IFNs in Intracellular Bacterial InfectionsDouble-stranded DNA induces a prothrombotic phenotype in the vascular endothelium.Helicase proteins DHX29 and RIG-I cosense cytosolic nucleic acids in the human airway systemBacterial DNA Protects Monocytic Cells against HIV-Vpr-Induced Mitochondrial Membrane Depolarization.Systems-level analysis of innate immunity.AIM2 inflammasome is activated by pharmacological disruption of nuclear envelope integrityRasGRP3 limits Toll-like receptor-triggered inflammatory response in macrophages by activating Rap1 small GTPase.DNA repair synthesis and ligation affect the processing of excised oligonucleotides generated by human nucleotide excision repair.HIV-1 infection leads to increased transcription of human endogenous retrovirus HERV-K (HML-2) proviruses in vivo but not to increased virion production.Intracellular immunity: finding the enemy within--how cells recognize and respond to intracellular pathogensListeria monocytogenes induces IFNβ expression through an IFI16-, cGAS- and STING-dependent pathway.Interferon-stimulated genes: a complex web of host defenses.Interplay between Kaposi's sarcoma-associated herpesvirus and the innate immune system.Mesenchymal stem cells detect and defend against gammaherpesvirus infection via the cGAS-STING pathway.
P2860
Q21131160-29301692-77AB-4BD4-B7EC-CC4A665B1120Q26738747-1A8120A0-6912-4FE1-B545-B66681D108A9Q26745544-9C70031C-2C6D-434E-BB5B-E6A6AEA71495Q26750363-C7EBCE9C-64C3-4046-A277-1D8DE77E983FQ26750366-0E9A155A-57F6-405D-8C6C-19759498FFB0Q26751063-2F1DD193-9DC2-4607-8219-ABC81DE3DEEDQ26800158-A6F89C1E-31AD-4624-83A1-0230E3CA99A4Q26801484-1DE7B7F4-7005-4FBA-A429-D62CF0F6412DQ26853177-2381D8EC-307E-49FB-BCB9-CED3653D91CEQ26998870-98619445-E925-4653-87B0-7A6F6A475065Q27000358-59A94D7D-925C-4840-93F4-C4D96EC044B6Q27010116-7FEC614F-A6FD-4645-A7C1-F517E026F0FBQ27022855-14F04387-F7B2-4077-8191-4FA61F9E25B6Q27300264-EE6451EF-D2C6-4429-B3E8-68B52D279D8BQ27679344-91545846-26F7-441C-A013-B03B33958BA0Q28073115-D0BD20C4-230B-4354-AC54-98ACF05DC25FQ28080982-5FB261B1-C498-450D-A57E-55D24D580388Q28081406-4409A078-8A48-4CD6-86F0-3FB2AB76FB54Q28274045-BFA6E03B-7E52-4849-9FAA-3F60B5C92CD2Q28545831-D3C6FF84-BE35-4A45-9BC6-D2712F2E27C5Q28553005-DDB46B0F-56C6-4431-BD6B-585E0371A6DDQ28603861-C4C06654-2C5E-4081-AE60-8C4795EBC7F9Q29871504-9F512668-4038-4273-A8B2-E2A066B069D0Q30665945-42DF07CC-35FE-42BF-8A71-4EB33127C51BQ31170451-DB281716-0FC2-41BE-BBC7-9882EFD4D7D3Q33602916-D2C8BDA6-DD8F-4BBE-BC6D-071DD0E9F353Q33655568-13DB90F9-D2D2-440A-B7E9-B99240110082Q33682822-7709D38F-501D-4816-ACFE-C10A9C20D8F3Q33694809-2BB8027C-B1B7-4E0E-962D-062B2F910F46Q33846203-B5254430-FA0C-4EF2-BC03-DC737A5579B3Q33855179-20ED8C27-F6F2-43F9-809C-54E28586281BQ34047217-ABCB1A59-AA17-4FBD-9B1B-3BF3FD53744CQ34086384-A11A2B4C-937B-4A3C-8CB1-EE748AF2A107Q34249149-D12E8088-E6EE-4AD8-9BB5-A6EC8B53FB9CQ34262010-A340FE01-AEE9-4E96-BB0F-222B9FB435DCQ34319249-DDB9213F-D553-4E5A-9F35-642ED13F3CEDQ34324531-EE159F31-BF98-4122-9DD1-B151C2271B4FQ34405609-4990574D-5A5F-434B-9F16-5E78543F383AQ34615002-A2811303-6A15-463C-A16A-784D43F85C84Q34975235-97A21C4D-9C02-4F94-842D-8C899F8066D7
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Immune sensing of DNA
@en
type
label
Immune sensing of DNA
@en
prefLabel
Immune sensing of DNA
@en
P2860
P1433
P1476
Immune sensing of DNA
@en
P2093
Søren R Paludan
P2860
P304
P356
10.1016/J.IMMUNI.2013.05.004
P407
P577
2013-05-01T00:00:00Z