about
Endophytic Actinobacteria and the Interaction of Micromonospora and Nitrogen Fixing PlantsThe Hidden World within Plants: Ecological and Evolutionary Considerations for Defining Functioning of Microbial EndophytesAHL-priming functions via oxylipin and salicylic acidLinking Bacterial Endophytic Communities to Essential Oils: Clues from Lavandula angustifolia Mill.Recent advances in natural product discovery.Colonization of lettuce rhizosphere and roots by tagged Streptomyces.Selenium hyperaccumulators harbor a diverse endophytic bacterial community characterized by high selenium resistance and plant growth promoting propertiesOasis desert farming selects environment-specific date palm root endophytic communities and cultivable bacteria that promote resistance to drought.Diversity and distribution of the endophytic bacterial community at different stages of Eucalyptus growth.Spatial and Temporal Variation of Cultivable Communities of Co-occurring Endophytes and Pathogens in WheatThe genome and genetics of a high oxidative stress tolerant Serratia sp. LCN16 isolated from the plant parasitic nematode Bursaphelenchus xylophilusAn in vitro study of the antifungal activity of Trichoderma virens 7b and a profile of its non-polar antifungal components released against Ganoderma boninense.Microbial inoculants for the biocontrol of Fusarium spp. in durum wheat.Metabolic profiling of two maize (Zea mays L.) inbred lines inoculated with the nitrogen fixing plant-interacting bacteria Herbaspirillum seropedicae and Azospirillum brasilense.Endophytic Cultivable Bacteria of the Metal Bioaccumulator Spartina maritima Improve Plant Growth but Not Metal Uptake in Polluted Marshes SoilsMorphological, Physiological, and Taxonomic Characterization of Actinobacterial Isolates Living as Endophytes of Cacao Pods and Cacao Seeds.Salicornia strobilacea (Synonym of Halocnemum strobilaceum) Grown under Different Tidal Regimes Selects Rhizosphere Bacteria Capable of Promoting Plant Growth.Structural variability and niche differentiation in the rhizosphere and endosphere bacterial microbiome of field-grown poplar treesHost-Parasite-Bacteria Triangle: The Microbiome of the Parasitic Weed Phelipanche aegyptiaca and Tomato-Solanum lycopersicum (Mill.) as a Host.Plant-endophyte symbiosis, an ecological perspective.Microbial communication leading to the activation of silent fungal secondary metabolite gene clusters.Implications of endophyte-plant crosstalk in light of quorum responses for plant biotechnology.Extensive Overlap of Tropical Rainforest Bacterial Endophytes between Soil, Plant Parts, and Plant Species.Identification and evaluation of potential bio-control fungal endophytes against Ustilagonoidea virens on rice plants.Functional and phylogenetic diversity of cultivable rhizobacterial endophytes of sorghum [Sorghum bicolor (L.) Moench].Endophytic actinobacteria: Diversity, secondary metabolism and mechanisms to unsilence biosynthetic gene clusters.Chemical ecology of antibiotic production by actinomycetes.Diversity of endophytic fungal and bacterial communities in Ilex paraguariensis grown under field conditions.Sequencing rare marine actinomycete genomes reveals high density of unique natural product biosynthetic gene clusters.Tuning of azine derivatives for selective recognition of Ag(+) with the in vitro tracking of endophytic bacteria in rice root tissue.An endophyte of Picrorhiza kurroa Royle ex. Benth, producing menthol, phenylethyl alcohol and 3-hydroxypropionic acid, and other volatile organic compounds.Petroleum Contamination and Plant Identity Influence Soil and Root Microbial Communities While AMF Spores Retrieved from the Same Plants Possess Markedly Different CommunitiesThe Role of Soil Microorganisms in Plant Mineral Nutrition-Current Knowledge and Future Directions.Transmission of Bacterial Endophytes.Mangrove endophyte promotes reforestation tree (Acacia polyphylla) growth.Rice bacterial endophytes: isolation of a collection, identification of beneficial strains and microbiome analysis.Biocontrol potential of endophytes harbored in Radula marginata (liverwort) from the New Zealand ecosystem.Plant-endophytes interaction influences the secondary metabolism in Echinacea purpurea (L.) Moench: an in vitro model.Inner Plant Values: Diversity, Colonization and Benefits from Endophytic Bacteria.An IgaA/UmoB-family protein from Serratia marcescens regulates motility, capsular polysaccharide, and secondary metabolite production.
P2860
Q26773138-98AF12CF-F427-40DB-81B9-EBDD61C7119AQ27008650-DD7CBABD-2EE0-4A27-8B34-5D871B1645F8Q27022163-753A1FA0-1656-4F78-B17F-B4B5BF947437Q33757917-5F639C75-E427-41A5-A0F0-F29B658C94B6Q34620967-A550DD98-E70E-462B-9B9F-BF2079277BC9Q35056823-3EBDB2D6-4BE7-4AB8-AB2D-0FA41843535EQ35135445-9586836A-9143-4893-94EA-6D9B88535D75Q35649295-E2EF26CA-3D11-488D-8A9E-425AE8EAEE07Q35968522-140ACA4C-188C-421F-8684-E9DD6F2E9EE9Q35986040-39AE2A8B-FD86-4547-8271-65283185E5B4Q35997637-C62A2052-A42E-4BA5-8974-3A3316E2D3DAQ36178219-972F0382-C2B1-4431-8783-D38BDD3F48D5Q36235190-5B9792E1-09FD-4F22-A6FB-F9BFF7B08B87Q36330038-32C9F4D7-2F04-4A95-92B0-AEA7BB0EACF4Q36391988-6A6B990F-BB76-4445-9FAC-721D3D8CA094Q36685086-4AB65035-D396-489E-AD9B-EA822946029DQ37192808-A7C13DB9-B33A-4E31-94FF-CD55BF689CF2Q37663326-725ECAD1-A841-4123-86BD-57513A12DEABQ37672395-722709E3-25FA-46A8-AEB0-2D0123825A00Q38370201-C4C532BA-F306-4ACB-B450-0EA122178CFDQ38459251-D6F3B487-346D-4EAD-89E7-1D750DED0BA4Q38477837-62D8865D-9088-4151-B1A9-58DFF758CB92Q38712854-F303781E-D0ED-44FA-B6BD-48FAB89B449CQ38788483-E9B612B1-4669-491C-950B-A437F3C92659Q39030428-9DFAEE8D-6012-426B-98A0-36F02391FDC8Q39208836-DD872926-CD82-44BD-89C6-4AB4452B9B74Q39315931-ACB02A8C-B132-4994-AA52-A0509A17ECF5Q39960775-E1CAC551-631F-4B93-83EA-F9EF3085B3AEQ40429748-0A078A56-34A3-4C18-BFD4-CFE78D8CE1E3Q40433591-E540F5CD-34A7-42AC-B547-6D86704CD5F5Q40684021-BA00A195-14E5-4CFA-9E9C-F696136A92C4Q41334825-408947A0-CA6A-4198-91ED-96E467E4F707Q41956172-098A48C1-A5E1-4D2D-BC72-F1CF2C89C982Q46115966-87360312-38C2-4CE4-9F59-D3E3F1D4C942Q46326154-459893A7-A383-4FE8-B882-279153C81E39Q46570099-A2254B9E-E9FF-4C9A-9EF0-73A95FE4462CQ46855784-B8945347-15F4-459D-A0C4-E58A20E94751Q47160659-721E3627-F954-4554-AFE7-7A6AE15845A1Q47194206-6496B446-BDCC-4AB1-B224-A975DE511008Q47203557-2DA0F037-B01D-4012-B93F-5C190C5E8904
P2860
description
2013 nî lūn-bûn
@nan
2013 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
Metabolic potential of endophytic bacteria.
@ast
Metabolic potential of endophytic bacteria.
@en
type
label
Metabolic potential of endophytic bacteria.
@ast
Metabolic potential of endophytic bacteria.
@en
prefLabel
Metabolic potential of endophytic bacteria.
@ast
Metabolic potential of endophytic bacteria.
@en
P2093
P2860
P1476
Metabolic potential of endophytic bacteria.
@en
P2093
Birgit Mitter
Friederike Trognitz
Günter Brader
Stéphane Compant
P2860
P356
10.1016/J.COPBIO.2013.09.012
P577
2013-10-22T00:00:00Z
2014-06-01T00:00:00Z