| Nome |
# |
|
Bioformulation of microbial biocontrol agents for a sustainable agriculture, file e1dbfeab-f1a3-4ac9-e053-1705fe0a1c61
|
980
|
|
Effect of environmental factors on the interaction plant-pathogen-Bacillus amyloliquefaciens S499, file e1dbfeaa-5e60-4ac9-e053-1705fe0a1c61
|
673
|
|
Stepwise flow diagram for the development of formulations of non spore-forming bacteria against foliar pathogens: the case of Lysobacter capsici AZ78, file e1dbfeaa-8cd2-4ac9-e053-1705fe0a1c61
|
662
|
|
Leaf treatments with a protein-based resistance inducer partially modify phyllosphere microbial communities of grapevine, file e1dbfeaa-e2e7-4ac9-e053-1705fe0a1c61
|
420
|
|
The Lysobacter capsici AZ78 genome has a gene pool enabling it to interact successfully with phytopathogenic microorganisms and environmental factors, file e1dbfeaa-d068-4ac9-e053-1705fe0a1c61
|
366
|
|
Pea broth enhances the biocontrol efficacy of Lysobacter capsici AZ78 by triggering cell motility associated with biogenesis of type IV pilus, file e1dbfeaa-e1a2-4ac9-e053-1705fe0a1c61
|
335
|
|
Fusarium oxysporum f.sp. radicis-lycopersici induces distinct transcriptome reprogramming in resistant and susceptible isogenic tomato lines, file e1dbfeaa-ce74-4ac9-e053-1705fe0a1c61
|
288
|
|
Grapevine resistance induced by protein hydrolysates against mildews, file e1dbfeaa-e1ff-4ac9-e053-1705fe0a1c61
|
273
|
|
Non-targeted side effect of microbial fungicides on grapevine: fact or fantasy, file e1dbfeab-2a9e-4ac9-e053-1705fe0a1c61
|
264
|
|
Advantages and limitations involved in the use of microbial biofungicides for the control of root and foliar phytopathogens of fruit crops, file e1dbfeab-7636-4ac9-e053-1705fe0a1c61
|
238
|
|
Transcriptomic responses of a simplified soil microcosm to a plant pathogen and its biocontrol agent reveal a complex reaction to harsh habitat, file e1dbfeaa-f9d7-4ac9-e053-1705fe0a1c61
|
234
|
|
Draft genome sequence of Lysobacter capsici AZ78, a bacterium antagonistic to plant-pathogenic oomycetes, file e1dbfeaa-810e-4ac9-e053-1705fe0a1c61
|
214
|
|
A complex protein derivative acts as biogenic elicitor of grapevine resistance against powdery mildew under field conditions, file e1dbfeaa-8be6-4ac9-e053-1705fe0a1c61
|
199
|
|
Il dialogo molecolare tra piante e microorganismi nell'ambiente: caratteristiche e possibili applicazioni in agricoltura, file e1dbfeaa-7755-4ac9-e053-1705fe0a1c61
|
181
|
|
Key impact of an uncommon plasmid on Bacillus amyloliquefaciens subsp. plantarum S499 developmental traits and lipopeptide production, file e1dbfeaa-f85d-4ac9-e053-1705fe0a1c61
|
180
|
|
The rare sugar tagatose inhibits the growth of Phytophthora infestans and not Phytophthora cinnamomi by inhibiting mitochondrial processes, file e1dbfeab-c6cf-4ac9-e053-1705fe0a1c61
|
170
|
|
Selection of plant growth promoting rhizobacteria sharing suitable features to be commercially developed as biostimulant products, file e1dbfeab-f08c-4ac9-e053-1705fe0a1c61
|
125
|
|
Ecological impact of a rare sugar on grapevine phyllosphere microbial communities, file e1dbfeab-baaa-4ac9-e053-1705fe0a1c61
|
119
|
|
Impact of individual and combined abiotic stresses on plant growth promoting bacteria, file e1dbfeab-b129-4ac9-e053-1705fe0a1c61
|
113
|
|
Tools and challenges in pesticide use and risk reduction on grapevine, file e1dbfeaa-64b8-4ac9-e053-1705fe0a1c61
|
103
|
|
Mining the genome of Lysobacter capsici AZ78 to identify the mechanism involved in the biological control of Phytophtora infestans and Plasmopara viticola, file e1dbfeaa-8073-4ac9-e053-1705fe0a1c61
|
98
|
|
A novel biopesticide with a new mechanism of action against grapevine downy mildew, file e1dbfeab-769e-4ac9-e053-1705fe0a1c61
|
96
|
|
Improvement of the natural phyllosphere microbiota of the grapevine to increase resistance against downy mildew, file e1dbfeaa-de87-4ac9-e053-1705fe0a1c61
|
94
|
|
Volatile organic compounds from Lysobacter capsici AZ78 as potential candidates for biological control of soilborne plant pathogens, file e1dbfeab-d60e-4ac9-e053-1705fe0a1c61
|
89
|
|
Genomics to plant health: effect of climate change on plant self-protection, file e1dbfeaa-6999-4ac9-e053-1705fe0a1c61
|
83
|
|
Humic acid enhances the growth of tomato promoted by endophytic bacterial strains through the activation of hormone-, growth-, and transcription-related processes, file e1dbfeab-dbe6-4ac9-e053-1705fe0a1c61
|
82
|
|
A complex protein derivative acts as biogenic elicitor of grapevine resistance against powdery and downy mildews, file e1dbfeaa-d9bc-4ac9-e053-1705fe0a1c61
|
79
|
|
The effect of temperature on bacillus Amyloliquefaciens strain S499 and on its interaction with crop plants, file e1dbfeaa-6b10-4ac9-e053-1705fe0a1c61
|
78
|
|
Characterization of the volatilome of Lysobacter capsici AZ78 and its bioactivity against soilborne plant pathogenic fungi and oomycetes, file e1dbfeab-9bd2-4ac9-e053-1705fe0a1c61
|
78
|
|
Functional divergence of flagellar type III secretion system: a case study in a non-flagellated, predatory bacterium, file e1dbfeab-f887-4ac9-e053-1705fe0a1c61
|
77
|
|
RNA-Seq unveiled the bacterial mycophagy mechanisms implemented by Lysobacter capsici AZ78 interacting with Phytophthora infestans, file e1dbfeab-4c69-4ac9-e053-1705fe0a1c61
|
71
|
|
Resistance to copper in Lysobacter capsici AZ78: a starting point for the development of a new sustainable management of Plasmopara viticola?, file e1dbfeaa-a155-4ac9-e053-1705fe0a1c61
|
70
|
|
Dual RNA-SEQ unearthed the unsuccessful response of a phytopathogenic oomicete to the antagonistic strategies implemented by the biocontrol bacterium Lysobacter capsici AZ78, file e1dbfeab-7263-4ac9-e053-1705fe0a1c61
|
69
|
|
Volatile-mediated inhibitory activity of Rhizobacteria as a result of multiple factors interaction: the case of Lysobacter capsici AZ78, file e1dbfeab-f6fb-4ac9-e053-1705fe0a1c61
|
69
|
|
Characterisation of the antibiotic profile of Lysobacter capsici AZ78, an effective biological control agent of plant pathogenic microorganisms, file e1dbfeab-f88c-4ac9-e053-1705fe0a1c61
|
67
|
|
The perception of rhizosphere bacterial communication signals leads to transcriptome reprogramming in Lysobacter capsici AZ78, a plant beneficial bacterium, file e1dbfeac-0452-4ac9-e053-1705fe0a1c61
|
60
|
|
Combination of copper with Lysobacter capsici AZ78: towards new strategies for the biological control of Plasmopara viticola, file e1dbfeaa-80ab-4ac9-e053-1705fe0a1c61
|
59
|
|
First insights on the ability of a Lysobacter capsici member to induce resistance mechanisms in grapevine plants, file e1dbfeab-5414-4ac9-e053-1705fe0a1c61
|
58
|
|
Ecological role of volatile organic compounds emitted by Pantoea agglomerans as interspecies and interkingdom signals, file e1dbfeab-f6ff-4ac9-e053-1705fe0a1c61
|
57
|
|
Development of a biopesticide based on Lysobacter capsici AZ78: formulation and fate in the environment, file e1dbfeaa-80a9-4ac9-e053-1705fe0a1c61
|
50
|
|
Protein-based products as resistance inducers: disease control and mechanisms of action, file e1dbfeab-4cc0-4ac9-e053-1705fe0a1c61
|
49
|
|
The differential growth inhibition of Phytophthora spp. caused by the rare sugar tagatose is associated with species-specific metabolic and transcriptional changes, file e1dbfeac-09c0-4ac9-e053-1705fe0a1c61
|
47
|
|
First insights on the impact of temperature on the survival and biocontrol efficacy of a member of the Lysobacter genus, file e1dbfeaa-80a7-4ac9-e053-1705fe0a1c61
|
43
|
|
Grapevine protection: from proof of concepts to pre-industrial biofungicides, file e1dbfeab-4cc1-4ac9-e053-1705fe0a1c61
|
42
|
|
How to select efficient and suitable PGPR for biostimulant product development: design of a tailored screening program, file e1dbfeab-b93e-4ac9-e053-1705fe0a1c61
|
39
|
|
The biocontrol agent Pseudomonas chlororaphis subsp. aureofaciens M71 originates natural mutants impaired in the ability to control Fusarium oxysporum f. sp. radicis-lycopersici on tomato, file e1dbfeab-54a6-4ac9-e053-1705fe0a1c61
|
29
|
|
First report of strawberry bacterial blight caused by Pantoea ananatis in Italy, file c61c2756-9e83-424d-bc45-a361c752ad47
|
24
|
|
This tree is on fire: a review on the ecology of Erwinia amylovora, the causal agent of fire blight disease, file 6f4c9064-2ca2-4483-91a4-8a0a0d8a54f7
|
16
|
|
Isolation and identification of bacterial strains from apple flowers in Trentino and their evaluation as biocontrol agents of Erwinia amylovora, file efecb4d0-eeb6-4466-b12d-ba7c65930cfc
|
9
|
|
The perception of indole negatively modulates biocontrol activities in the plant beneficial Rhizobacterium Lysobacter capsici AZ78, file 5f6583b5-e12c-45e2-a456-a3b879ea3ca2
|
5
|
|
Growth media affect the volatilome and antimicrobial activity against Phytophthora infestans in four Lysobacter type strains, file e1dbfeab-12ad-4ac9-e053-1705fe0a1c61
|
4
|
|
Suppressive activity of Glechoma hederacea extracts against the phytopathogenic Oomycete Plasmopara viticola, and first screening of the active metabolites, file ec6ebd35-b94d-4b44-8b09-ac4b9f330f23
|
4
|
|
The inibithory activity of the biocontrol agent Lysobacter capsici AZ78 is negatively modulated by Bacillus spp. isolated from grapevine leaves, file e1dbfeab-5acf-4ac9-e053-1705fe0a1c61
|
3
|
|
New concepts in the identification and practical application of biocontrol agents against plant pathogens, file e1dbfeab-61b4-4ac9-e053-1705fe0a1c61
|
3
|
|
Characterization of the volatilome of Lysobacter capsici AZ78 and its bioactivity against soilborne plant pathogenic fungi and oomycetes, file e1dbfeab-9a36-4ac9-e053-1705fe0a1c61
|
3
|
|
Evaluation of plant protection efficacy in field conditions and side effects of Lysobacter capsici AZ78, a biocontrol agent of Plasmopara viticola, file e1dbfeac-221c-4ac9-e053-1705fe0a1c61
|
3
|
|
Lysobacter capsici AZ78 can be combined with copper to effectively control Plasmopara viticola on grapevine, file e1dbfeaa-a2ed-4ac9-e053-1705fe0a1c61
|
2
|
|
Impact of temperature on the survival and the biocontrol efficacy of Lysobacter capsici AZ78 against Phytophthora infestans, file e1dbfeaa-af2c-4ac9-e053-1705fe0a1c61
|
2
|
|
Complete genome sequence of Bacillus amyloliquefaciens subsp. plantarum S499, a rhizobacterium that triggers plant defences and inhibits fungal phytopathogens, file e1dbfeaa-e321-4ac9-e053-1705fe0a1c61
|
2
|
|
Involvement of phenazine-1-carboxylic acid in the interaction between Pseudomonas chlororaphis subsp. aureofaciens strain M71 and Seiridium cardinale in vivo, file e1dbfeab-00c3-4ac9-e053-1705fe0a1c61
|
2
|
|
Designing a dual RNA-Seq approach to dissect the mode of action of biocontrol bacteria against phytopathogenic eukaryotes, file e1dbfeab-6bfe-4ac9-e053-1705fe0a1c61
|
2
|
|
Impact of spontaneous mutations on physiological traits and biocontrol activity of Pseudomonas chlororaphis M71, file e1dbfeab-f08a-4ac9-e053-1705fe0a1c61
|
2
|
|
Pseudomonas chlororaphis metabolites as biocontrol promoters of plant health and improved crop yield, file e1dbfeab-f08e-4ac9-e053-1705fe0a1c61
|
2
|
|
The rhizosphere signature on the cell motility, biofilm formation and secondary metabolite production of a plant-associated Lysobacter strain, file e1dbfeab-f627-4ac9-e053-1705fe0a1c61
|
2
|
|
Volatile-mediated inhibitory activity of the biocontrol agent Lysobacter capsici AZ78 as a result of multiple factors interaction, file cc194143-a5d8-457a-9798-ddcc78c96dd5
|
1
|
|
Lysobacter capsici AZ78 produces cyclo(L-Pro-L-Tyr), a 2,5-diketopiperazine with toxic activity against sporangia of Phytophthora infestans and Plasmopara viticola, file e1dbfeaa-9e9f-4ac9-e053-1705fe0a1c61
|
1
|
|
Monitoring Lysobacter capsici AZ78 using strain specific qPCR reveals the importance of the formulation for its survival in vineyards, file e1dbfeaa-a35e-4ac9-e053-1705fe0a1c61
|
1
|
|
Resilience of the natural phyllosphere microbiota of the grapevine to chemical and biological pesticides, file e1dbfeaa-a6de-4ac9-e053-1705fe0a1c61
|
1
|
|
Pea broth promotes cell motility and biocontrol activity of Lysobacter capsici AZ78 and upregulates genes related to biogenesis of type IV pili, file e1dbfeaa-e21b-4ac9-e053-1705fe0a1c61
|
1
|
|
A protein derivative stimulates grapevine resistance and the natural phyllosphere microbiota against downy mildew, file e1dbfeaa-e247-4ac9-e053-1705fe0a1c61
|
1
|
|
First insights on the ability of a Lysobacter capsici member to induce resistance mechanisms in grapevine plants, file e1dbfeab-88f8-4ac9-e053-1705fe0a1c61
|
1
|
|
Grapevine protection: from proof of concepts to pre-industrial biofungicides, file e1dbfeab-99ce-4ac9-e053-1705fe0a1c61
|
1
|
|
First evidence of Pantoea ananatis infections on strawberry in Italy, file f5bb6303-41fe-4a0c-94d8-16bac8238cdb
|
1
|
| Totale |
7.969 |