The bacterially produced metabolite violacein is associated with survival of amphibians infected with a lethal fungus.
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Using "Omics" and Integrated Multi-Omics Approaches to Guide Probiotic Selection to Mitigate Chytridiomycosis and Other Emerging Infectious DiseasesEvaluation of microorganisms cultured from injured and repressed tissue regeneration sites in endangered giant aquatic Ozark Hellbender salamandersMitigating amphibian disease: strategies to maintain wild populations and control chytridiomycosisFirst line of defence: the role of sloughing in the regulation of cutaneous microbes in frogs.Cutaneous bacteria of the redback salamander prevent morbidity associated with a lethal disease.Inhibition of Batrachochytrium dendrobatidis Caused by Bacteria Isolated from the Skin of Boreal Toads, Anaxyrus (Bufo) boreas boreas, from Grand Teton National Park, Wyoming, USA.Cool temperatures reduce antifungal activity of symbiotic bacteria of threatened amphibians--implications for disease management and patterns of decline.Characterization of a gene cluster and its putative promoter region for violacein biosynthesis in Pseudoalteromonas sp. 520P1.Motile zoospores of Batrachochytrium dendrobatidis move away from antifungal metabolites produced by amphibian skin bacteria.Interactions between amphibians' symbiotic bacteria cause the production of emergent anti-fungal metabolites.Tagging frogs with passive integrated transponders causes disruption of the cutaneous bacterial community and proliferation of opportunistic fungiAntinematode activity of Violacein and the role of the insulin/IGF-1 pathway in controlling violacein sensitivity in Caenorhabditis elegansGerm tube mediated invasion of Batrachochytrium dendrobatidis in amphibian skin is host dependent.Surviving chytridiomycosis: differential anti-Batrachochytrium dendrobatidis activity in bacterial isolates from three lowland species of Atelopus.Tolerance of fungal infection in European water frogs exposed to Batrachochytrium dendrobatidis after experimental reduction of innate immune defenses.Eco-Evo-Devo: developmental symbiosis and developmental plasticity as evolutionary agents.The pathogen Batrachochytrium dendrobatidis disturbs the frog skin microbiome during a natural epidemic and experimental infection.The cutaneous bacterium Janthinobacterium lividum inhibits the growth of Trichophyton rubrum in vitro.Microbial community dynamics and effect of environmental microbial reservoirs on red-backed salamanders (Plethodon cinereus).Bioactive pigments from marine bacteria: applications and physiological rolesMost of the Dominant Members of Amphibian Skin Bacterial Communities Can Be Readily CulturedAccumulation of the antibiotic phenazine-1-carboxylic acid in the rhizosphere of dryland cerealsGenome Sequence of the Soil Bacterium Janthinobacterium sp. KBS0711.Characterization of the Skin Microbiota in Italian Stream Frogs (Rana italica) Infected and Uninfected by a Cutaneous Parasitic Disease.Larval Environment Alters Amphibian Immune Defenses Differentially across Life Stages and Populations.Community Structure and Function of Amphibian Skin Microbes: An Experiment with Bullfrogs Exposed to a Chytrid FungusMolecular Keys to the Janthinobacterium and Duganella spp. Interaction with the Plant Pathogen Fusarium graminearum.Panamanian frog species host unique skin bacterial communitiesBacterial calligraphy: a memento for undergraduate research students.Vertebrate Hosts as Islands: Dynamics of Selection, Immigration, Loss, Persistence, and Potential Function of Bacteria on Salamander SkinThe Search for Violacein-Producing Microbes to Combat Batrachochytrium dendrobatidis: A Collaborative Research Project between Secondary School and College Research Students.Direct and Indirect Horizontal Transmission of the Antifungal Probiotic Bacterium Janthinobacterium lividum on Green Frog (Lithobates clamitans) TadpolesEx situ diet influences the bacterial community associated with the skin of red-eyed tree frogs (Agalychnis callidryas).Chromobacterium violaceum and its important metabolites--review.Mitigating amphibian chytridiomycosis with bioaugmentation: characteristics of effective probiotics and strategies for their selection and use.Temporal changes in cutaneous bacterial communities of terrestrial- and aquatic-phase newts (Amphibia).Variation in the Presence of Anti-Batrachochytrium dendrobatidis Bacteria of Amphibians Across Life Stages and Elevations in Ecuador.A novel combinatorial biocatalytic approach for producing antibacterial compounds effective against Mycobacterium tuberculosis (TB).Dietary Carotenoid Supplementation Enhances the Cutaneous Bacterial Communities of the Critically Endangered Southern Corroboree Frog (Pseudophryne corroboree).Pathway redesign for deoxyviolacein biosynthesis in Citrobacter freundii and characterization of this pigment.
P2860
Q26766432-316B8E89-ACBC-4942-95EE-EAAE50516BEFQ28741163-06452381-6F0B-4D44-BBCA-9BFE9A410F1AQ28744438-93136E44-3DD0-42F4-811C-A0F28C0ACF0DQ31107597-369C8285-47C7-4E03-9C87-129C1BA406DDQ33598334-31F9F828-8B47-473F-949F-6752D84CAB52Q33603232-F2AED2FF-4B61-4C70-8915-A2FE07EAAC6DQ33774008-CEAA582C-2E84-4952-A4B6-9BCF3C656052Q33864759-C34A8BA9-2147-4691-BFC0-B4E41DD60DFDQ33965092-127043A7-AD49-45F9-91FB-D3C91C40A330Q34072027-7A741C06-9158-405E-8C80-5EE609E0B427Q34107057-6E17B9DA-EC1B-4AAD-A52A-8B51938A367CQ34307513-B37D23EB-A1BF-4408-BBE2-C6CD9466236BQ34387922-582025DA-ADA6-49F8-869A-528B4E7DF8CFQ34412813-AE4C1300-1DF1-4E35-AA57-A67EB17A803DQ34453970-EA4D64CD-F6BE-4F2D-A03D-CF96D230A1E6Q34494155-418293CF-2E4C-4759-845C-FA45D86A1FDCQ34601550-657EBD56-D09D-4B0D-8E01-1E45B4E173DAQ34966635-7526B065-BC8B-4762-85E2-33B7D204F819Q35066436-98945D67-46FA-402D-AF84-94EBADA52E5DQ35232548-202262DB-BA8A-43E3-A397-07A179030570Q35688502-F5EFAF12-24B8-47AF-8A41-DE2D6C202BCAQ35688962-3E0975A9-A6FB-48C0-9B6F-132F752872AFQ35757020-6F755C73-E28E-49FC-9923-8FE56EA50789Q35775221-6B472821-46D9-457E-847F-BBEE330A0DA3Q35777427-AEB13E54-B9AF-4877-8A16-BC89D889FFFAQ36131750-4D72B648-B076-498E-A077-0C565C7E3507Q36189420-6EB39989-57AD-4D3F-BB0B-956852759ECEQ36209337-83629F7A-3CB1-4484-8831-645DDBE32C75Q36623787-12EAC67C-A40D-4B3E-9AB6-D12087698AC3Q36692028-DBC89559-6A1E-4024-929F-60F6F03DBD9CQ36703216-E0C1891E-0F49-4F5F-9BCD-919203D52A97Q37122952-5B972810-093A-48FD-9747-501C87C870ACQ37458728-8A8D6FE0-6D03-4CC9-B263-1A1D917F5F6CQ37831230-236D456F-F661-4773-9297-0FEAA36E3C5DQ38085710-C0781C55-3954-48C3-ACBB-FBEA788F65E8Q38832012-864AFACF-A816-4DB3-B55F-24DF7B6216B5Q38920774-7D9CC5BF-9505-4F3C-8B9E-43552E38668FQ39142098-EFB10791-DF88-49BA-9EB6-C52697ABCBDBQ39297079-F8B3F976-B8C8-4979-969C-11228E7D6B2FQ39385064-03439ABE-F6C4-439D-A6DC-5A26123C3163
P2860
The bacterially produced metabolite violacein is associated with survival of amphibians infected with a lethal fungus.
description
2009 nî lūn-bûn
@nan
2009 թուականի Օգոստոսին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի օգոստոսին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
The bacterially produced metab ...... infected with a lethal fungus.
@ast
The bacterially produced metab ...... infected with a lethal fungus.
@en
type
label
The bacterially produced metab ...... infected with a lethal fungus.
@ast
The bacterially produced metab ...... infected with a lethal fungus.
@en
prefLabel
The bacterially produced metab ...... infected with a lethal fungus.
@ast
The bacterially produced metab ...... infected with a lethal fungus.
@en
P2093
P2860
P356
P1476
The bacterially produced metab ...... infected with a lethal fungus.
@en
P2093
Christian R Schwantes
Kevin P C Minbiole
Matthew H Becker
Reid N Harris
Robert M Brucker
P2860
P304
P356
10.1128/AEM.01294-09
P407
P577
2009-08-28T00:00:00Z