Insect immunity. Septic injury of Drosophila induces the synthesis of a potent antifungal peptide with sequence homology to plant antifungal peptides.
about
Social transfer of pathogenic fungus promotes active immunisation in ant coloniesAntiprotozoan and Antiviral Activities of Non-Cytotoxic Truncated and Variant Analogues of Mussel DefensinDiversity, evolution and medical applications of insect antimicrobial peptidesBacterial and fungal pattern recognition receptors in homologous innate signaling pathways of insects and mammalsA comparison of the transcriptome of Drosophila melanogaster in response to entomopathogenic fungus, ionizing radiation, starvation and cold shock.Drosophila melanogaster as an animal model for the study of Pseudomonas aeruginosa biofilm infections in vivoLead optimization of antifungal peptides with 3D NMR structures analysisAntifungal peptides: novel therapeutic compounds against emerging pathogensAn effector Peptide family required for Drosophila toll-mediated immunityDrosomycin-like defensin, a human homologue of Drosophila melanogaster drosomycin with antifungal activity.Characterization of Reproductive Dormancy in Male Drosophila melanogasterDifferential display of peptides induced during the immune response of Drosophila: a matrix-assisted laser desorption ionization time-of-flight mass spectrometry study.Chemosensitization of fluconazole resistance in Saccharomyces cerevisiae and pathogenic fungi by a D-octapeptide derivative.Discerning the complexity of community interactions using a Drosophila model of polymicrobial infections.Comparative profiling of the transcriptional response to infection in two species of Drosophila by short-read cDNA sequencingAntifungal Activity against Filamentous Fungi of Ts1, a Multifunctional Toxin from Tityus serrulatus Scorpion Venom.A conserved p38 mitogen-activated protein kinase pathway regulates Drosophila immunity gene expression.A recessive mutation, immune deficiency (imd), defines two distinct control pathways in the Drosophila host defenseToll-like receptor 4 in inflammation and angiogenesis: a double-edged sword.Peptide-based Antifungal Therapies against Emerging Infections.Functional divergence among silkworm antimicrobial peptide paralogs by the activities of recombinant proteins and the induced expression profiles.Innate immune responses of a scleractinian coral to vibriosis.A drosomycin-GFP reporter transgene reveals a local immune response in Drosophila that is not dependent on the Toll pathwayA mosaic analysis in Drosophila fat body cells of the control of antimicrobial peptide genes by the Rel proteins Dorsal and DIF.Constitutive expression of a single antimicrobial peptide can restore wild-type resistance to infection in immunodeficient Drosophila mutants.Control of Drosophila blood cell activation via Toll signaling in the fat body.Effects of caste on the expression of genes associated with septic injury and xenobiotic exposure in the Formosan subterranean termiteQuantitative profiling of Drosophila melanogaster Dscam1 isoforms reveals no changes in splicing after bacterial exposureSolution structure of drosomycin, the first inducible antifungal protein from insectsAssessment of virulence diversity of methicillin-resistant Staphylococcus aureus strains with a Drosophila melanogaster infection model.Peptides and proteins with antimicrobial activity.Drosophila immunity: genes on the third chromosome required for the response to bacterial infection.Cooperative control of Drosophila immune responses by the JNK and NF-kappaB signaling pathways.Structure-activity relationships of the intramolecular disulfide bonds in coprisin, a defensin from the dung beetle.The phytopathogenic bacteria Erwinia carotovora infects Drosophila and activates an immune response.Caspar, a suppressor of antibacterial immunity in Drosophila.members only encodes a Drosophila nucleoporin required for rel protein import and immune response activation.Manduca sexta moricin promoter elements can increase promoter activities of Drosophila melanogaster antimicrobial peptide genes.A genome-wide analysis of antimicrobial effector genes and their transcription patterns in Manduca sexta.The Drosophila melanogaster host model.
P2860
Q21145741-04A45424-BE82-4A1E-85AF-BBCB8DA66EE5Q24806166-5601B9BE-1881-4B95-876B-C0380C1C0DC1Q26751067-2BF069EF-BF54-4EF9-BC96-B22B9C313E7FQ26866418-72AB0954-B90C-42AB-9675-D2F8B141AA46Q27321184-7358222A-595E-4CEF-9D3D-BAA89252164CQ27348828-AEA0BF49-FCA0-4223-B6D2-8ECF296F9F4FQ27643174-8D8E3B40-4800-4CA2-BADA-5136CDD79C49Q28369443-DE0DAA80-04D6-4BB1-8958-9C91B9345814Q28546751-1E54F322-C37C-4C33-AE41-30B3DA0C389AQ29871460-57793D41-2F7A-4DD7-A2A0-FA7920170EB6Q30829576-32D03228-C041-40C5-A094-77329F85A50FQ32021965-0C8389EE-BE98-4467-9FC0-891A09EBFF45Q33200348-C49C5082-491F-44F5-9F82-0997BBA73C7CQ33379091-D3324CA3-C998-4D7F-B4C3-AA6572D26CC9Q33461981-46B3123B-6F23-4CD3-8C3E-98508B9BB232Q33766302-FEEC062E-8356-462F-B730-2C8F14BA138DQ33774350-AEFF84B4-402E-4FEB-B18E-C6B906AEB05EQ33847004-3C6FC003-D23A-4E8F-9D89-DB4BB23CB3C3Q33851340-798D7B5D-7951-46EC-8875-FEAA0FFD467FQ33862289-A465A4B1-11CF-4D39-ABED-0B2559F484ADQ33867440-505E7C6F-6A15-4E77-91D9-12EFB1647136Q33887808-601A97BB-3B97-41BC-9B0E-12C72D871043Q33888386-CA0C9159-F12A-4B52-93A8-454B07BE1F8FQ33891087-3A0952FE-EAB7-449C-A9E3-540EC45057E3Q34012549-1FC3C6D3-67DB-4F33-8157-6E987C0490A2Q34015450-734279FA-12E3-4C2E-93EB-84A0925A9B16Q34070991-17E03F63-34AA-4D74-AC09-3A2DE965801EQ34331720-AA7E307C-0DE9-47AE-9A2F-2BC5686FAC2AQ34439534-9E5D9E43-D6D0-43A8-848B-C34112EEF1AFQ34486698-B66C7D00-6226-4B72-8B36-E9DF18402150Q34501382-D52E41C3-5E41-4A53-B442-326DD7229AC1Q34613236-D58CC0E7-E271-4CD0-B095-95902DE39DD2Q34767624-3F0F0AC8-9773-4D0B-8C65-50505B315715Q34798239-AA32EBF4-72B5-490B-BEF4-99ADB3FF7834Q35110457-EEB6B315-CABD-4AC3-8360-31FA310D4262Q35133822-828BBFDC-FFE5-4205-AB8F-95A1DB468719Q35200220-E16453A1-A5AC-45C7-A3BC-A281C92391C0Q35535562-9B02F69E-45B1-4EF6-B7AF-96DB4C14D09DQ35768074-FEED0069-20D5-43B1-82E4-23E333102E5DQ35773518-2273688A-7446-4865-9341-461A7DAFF588
P2860
Insect immunity. Septic injury of Drosophila induces the synthesis of a potent antifungal peptide with sequence homology to plant antifungal peptides.
description
1994 nî lūn-bûn
@nan
1994 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
1994 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
1994年の論文
@ja
1994年論文
@yue
1994年論文
@zh-hant
1994年論文
@zh-hk
1994年論文
@zh-mo
1994年論文
@zh-tw
1994年论文
@wuu
name
Insect immunity. Septic injury ...... to plant antifungal peptides.
@ast
Insect immunity. Septic injury ...... to plant antifungal peptides.
@en
Insect immunity. Septic injury ...... to plant antifungal peptides.
@nl
type
label
Insect immunity. Septic injury ...... to plant antifungal peptides.
@ast
Insect immunity. Septic injury ...... to plant antifungal peptides.
@en
Insect immunity. Septic injury ...... to plant antifungal peptides.
@nl
prefLabel
Insect immunity. Septic injury ...... to plant antifungal peptides.
@ast
Insect immunity. Septic injury ...... to plant antifungal peptides.
@en
Insect immunity. Septic injury ...... to plant antifungal peptides.
@nl
P2093
P1476
Insect immunity. Septic injury ...... y to plant antifungal peptides
@en
P2093
J A Hoffmann
P Fehlbaum
W F Broekaert
P304
33159-33163
P407
P577
1994-12-01T00:00:00Z