| Nome |
# |
|
L'oidio della vite, file e1dbfeaa-5ad9-4ac9-e053-1705fe0a1c61
|
27.456
|
|
La peronospora della vite, file e1dbfeab-6540-4ac9-e053-1705fe0a1c61
|
6.375
|
|
Il mal dell'esca della vite, file e1dbfeaa-5ad8-4ac9-e053-1705fe0a1c61
|
5.459
|
|
I marciumi radicali della vite, file e1dbfeaa-5ad6-4ac9-e053-1705fe0a1c61
|
2.656
|
|
La muffa grigia della vite, file e1dbfeaa-5ada-4ac9-e053-1705fe0a1c61
|
2.629
|
|
5th International workshop on grapevine downy and powdery mildew, file e1dbfeab-6402-4ac9-e053-1705fe0a1c61
|
2.026
|
|
L'oidio della fragola, file e1dbfeaa-5adc-4ac9-e053-1705fe0a1c61
|
1.818
|
|
Modelling the impact of climate change on the interaction between grapevine and its pests and pathogens: European grapevine moth and powdery mildew, file e1dbfeaa-632e-4ac9-e053-1705fe0a1c61
|
1.554
|
|
Plasmopara viticola: a review of knowledge on downy mildew of grapevine and effective disease management, file e1dbfeaa-60a9-4ac9-e053-1705fe0a1c61
|
1.396
|
|
Climate change impact on plant pathogens and plant diseases, file e1dbfeaa-692c-4ac9-e053-1705fe0a1c61
|
990
|
|
La peronospora della vite, file e1dbfeaa-5ade-4ac9-e053-1705fe0a1c61
|
704
|
|
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
|
|
Effects of climate change on grapevine protection, file e1dbfeab-0383-4ac9-e053-1705fe0a1c61
|
649
|
|
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
|
|
Fungal endophytic communities in grapevines (Vitis vinifera L.) respond to crop management, file e1dbfeaa-bbc5-4ac9-e053-1705fe0a1c61
|
357
|
|
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
|
|
The effect of hydrolysis and protein source on the efficacy of protein hydrolysates as plant resistance inducers against powdery mildew, file e1dbfeab-34d9-4ac9-e053-1705fe0a1c61
|
305
|
|
Characterization of Trichoderma harzianum T39 induced resistance against Plasmopara viticola during abiotic stresses, file e1dbfeaa-6b12-4ac9-e053-1705fe0a1c61
|
295
|
|
Enviro and innovative web mapping tool to monitor and forecast plant and pests dynamics based on climate data, file e1dbfeaa-6a1f-4ac9-e053-1705fe0a1c61
|
273
|
|
Stimulation of conidial germination of the powdery mildew hyperparasite Ampelomyces quisqualis, file e1dbfeaa-a2f0-4ac9-e053-1705fe0a1c61
|
273
|
|
Grapevine resistance induced by protein hydrolysates against mildews, file e1dbfeaa-e1ff-4ac9-e053-1705fe0a1c61
|
273
|
|
A phloem-feeding insect transfers bacterial endophytic communities between grapevine plants, file e1dbfeab-152a-4ac9-e053-1705fe0a1c61
|
265
|
|
Non-targeted side effect of microbial fungicides on grapevine: fact or fantasy, file e1dbfeab-2a9e-4ac9-e053-1705fe0a1c61
|
264
|
|
Transcriptomic analysis of grapevine induced resistance against downy mildew, file e1dbfeaa-6470-4ac9-e053-1705fe0a1c61
|
262
|
|
Proteomic analysis of grapevine resistance induced by Trichoderma harzianum T39 reveals specific defence pathways activated against downy mildew, file e1dbfeaa-72a9-4ac9-e053-1705fe0a1c61
|
259
|
|
Volatiles of grape inoculated with microorganisms: modulation of grapevine moth oviposition and field attraction, file e1dbfeab-9ad3-4ac9-e053-1705fe0a1c61
|
258
|
|
Whole-genome comparative analysis of virulence genes unveils similarities and differences between endophytes and other symbiotic bacteria, file e1dbfeaa-d8e2-4ac9-e053-1705fe0a1c61
|
251
|
|
Draft genome sequence of the Wolbachia endosymbiont of Drosophila suzukii, file e1dbfeaa-6aa4-4ac9-e053-1705fe0a1c61
|
239
|
|
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
|
|
Assessment of the spectrum of activity of a new insecticide based on Clitoria ternatea extract, file e1dbfeab-1ecf-4ac9-e053-1705fe0a1c61
|
234
|
|
Bacterial endophytic communities in the grapevine depend on pest management, file e1dbfeaa-7cd4-4ac9-e053-1705fe0a1c61
|
233
|
|
Il progetto europeo CO-FREE: nuove strategie e prodotti per sostituire il rame in agricoltura, file e1dbfeaa-610a-4ac9-e053-1705fe0a1c61
|
230
|
|
Downy mildew resistance induced by Trichoderma harzianum T39 in susceptible grapevines partially mimics transcriptional changes of resistant genotypes, file e1dbfeaa-6a71-4ac9-e053-1705fe0a1c61
|
226
|
|
Linking genomics and ecology to investigate the complex evolution of an invasive Drosophila pest, file e1dbfeaa-b9c0-4ac9-e053-1705fe0a1c61
|
226
|
|
Downy mildew symptoms on grapevines can be reduced by volatile organic compounds of resistant genotypes, file e1dbfeab-46f4-4ac9-e053-1705fe0a1c61
|
226
|
|
Characterization of Trichoderma harzianum T39 induced resistance against Plasmopara viticola in heat and drought stressed grapevine plants, file e1dbfeaa-5e5e-4ac9-e053-1705fe0a1c61
|
219
|
|
Draft genome sequence of Lysobacter capsici AZ78, a bacterium antagonistic to plant-pathogenic oomycetes, file e1dbfeaa-810e-4ac9-e053-1705fe0a1c61
|
214
|
|
Vf scab resistance of Malus, file e1dbfeaa-6255-4ac9-e053-1705fe0a1c61
|
210
|
|
I marciumi radicali della vite, file e1dbfeaa-5adf-4ac9-e053-1705fe0a1c61
|
207
|
|
A complex protein derivative acts as biogenic elicitor of grapevine resistance against powdery mildew under field conditions, file e1dbfeaa-8be6-4ac9-e053-1705fe0a1c61
|
199
|
|
Insights into apple and pear bark microbiota: characterizing composition and population dynamics of beneficial and pathogenic microorganisms, file e1dbfeab-771d-4ac9-e053-1705fe0a1c61
|
199
|
|
High resolution assessment of spatio-temporal changes in O2 concentration in root-pathogen interaction, file e1dbfeab-73b9-4ac9-e053-1705fe0a1c61
|
195
|
|
Trichoderma atroviride SC1 is a good wound colonizer and can protect grapevine from infections of Phaeoacremonium aleophilum and Phaeomoniella chlamydospora in nurseries and vineyards, file e1dbfeaa-71e2-4ac9-e053-1705fe0a1c61
|
181
|
|
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
|
|
Functional and molecular analysis of grapevine induced resistance against Plasmopara viticola in relation to the physiology of the microbial inducer, file e1dbfeaa-5e5f-4ac9-e053-1705fe0a1c61
|
166
|
|
Characterization of Trichoderma harzianum T39-induced resistance of grapevine against downy mildew, file e1dbfeaa-5d89-4ac9-e053-1705fe0a1c61
|
164
|
|
Phlorizin released by apple root debris is related to apple replant disease, file e1dbfeab-0119-4ac9-e053-1705fe0a1c61
|
138
|
|
Écologie fonctionnelle des interactions vigne - communauté microbienne épiphyte dans un contexte de lutte biologique, file e1dbfeaa-62dd-4ac9-e053-1705fe0a1c61
|
135
|
|
Innovative strategies for copper-free low input and organic farming systems (EU-project co-free), file e1dbfeaa-6a25-4ac9-e053-1705fe0a1c61
|
131
|
|
Selection of plant growth promoting rhizobacteria sharing suitable features to be commercially developed as biostimulant products, file e1dbfeab-f08c-4ac9-e053-1705fe0a1c61
|
125
|
|
Profiling of grapevine fungal endophytic community using Automated Ribosomal Intergenic Spacer Analysis (ARISA), file e1dbfeaa-71df-4ac9-e053-1705fe0a1c61
|
124
|
|
A Web-based decision support system for the management of integrated vineyards, file e1dbfeaa-6a3a-4ac9-e053-1705fe0a1c61
|
122
|
|
Using molecular clocks to investigate beneficial (and deleterious) microbe-host interactions in the agroecosystem, file e1dbfeaa-fd50-4ac9-e053-1705fe0a1c61
|
122
|
|
Ecological impact of a rare sugar on grapevine phyllosphere microbial communities, file e1dbfeab-baaa-4ac9-e053-1705fe0a1c61
|
119
|
|
Preharvest and postharvest application of garlic and rosemary essential oils for controlling anthracnose and quality assessment of strawberry fruit during cold storage, file e1dbfeab-f005-4ac9-e053-1705fe0a1c61
|
118
|
|
La "febbre" dell'agricoltura, file e1dbfeaa-682a-4ac9-e053-1705fe0a1c61
|
117
|
|
Impact of individual and combined abiotic stresses on plant growth promoting bacteria, file e1dbfeab-b129-4ac9-e053-1705fe0a1c61
|
113
|
|
Laser microdissection of grapevine leaves highlights site-specific transcriptional changes at the early stages of downy mildew infection, file e1dbfeaa-dcb6-4ac9-e053-1705fe0a1c61
|
111
|
|
A fast and reliable method for Diplodia seriata inoculation of trunks and assessment of fungicide efficacy on potted apple plants under greenhouse conditions, file e1dbfeab-aaca-4ac9-e053-1705fe0a1c61
|
111
|
|
Tools and challenges in pesticide use and risk reduction on grapevine, file e1dbfeaa-64b8-4ac9-e053-1705fe0a1c61
|
103
|
|
Soil microorganisms vs. pesticides: potential bioeffector molecules for an environmental-friendly viticulture, file e1dbfeaa-6b13-4ac9-e053-1705fe0a1c61
|
101
|
|
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
|
|
Climate change and possible impacts on soil, file e1dbfeaa-6934-4ac9-e053-1705fe0a1c61
|
97
|
|
A novel biopesticide with a new mechanism of action against grapevine downy mildew, file e1dbfeab-769e-4ac9-e053-1705fe0a1c61
|
96
|
|
New integrated strategies for the control of grey mold Botrytis cinerea in grapevine, file e1dbfeaa-6b04-4ac9-e053-1705fe0a1c61
|
95
|
|
Identification of volatile organic compounds emitted by different grapevine genotypes in response to downy mildew infection, file e1dbfeaa-fa8b-4ac9-e053-1705fe0a1c61
|
95
|
|
Improvement of the natural phyllosphere microbiota of the grapevine to increase resistance against downy mildew, file e1dbfeaa-de87-4ac9-e053-1705fe0a1c61
|
94
|
|
Use of Salvia officinalis extract to control grapevine downy mildew: tests in greenhouse and field, file e1dbfeaa-6aef-4ac9-e053-1705fe0a1c61
|
92
|
|
Envirochange: simulazione degli effetti fotosanitari del cambiamento climatico sulla vite in Trentino, file e1dbfeaa-62f7-4ac9-e053-1705fe0a1c61
|
91
|
|
Identification and activity testing of volatile organic compounds (VOCs) found in different grapevine genotypes in response to downy mildew infection, file e1dbfeab-23f9-4ac9-e053-1705fe0a1c61
|
91
|
|
Evaluation of different adaption strategies to climate change in viticulture by using a multi-criteria assessment tool, file e1dbfeaa-9ad5-4ac9-e053-1705fe0a1c61
|
90
|
|
Armillaria mellea, the causal agent of grapevine root rot, induces a set of defense genes in grapevine roots, file e1dbfeaa-6500-4ac9-e053-1705fe0a1c61
|
88
|
|
Insights into Drosophila-Wolbachia interactions: innovative strategies for insect pest management, file e1dbfeaa-6a32-4ac9-e053-1705fe0a1c61
|
85
|
|
A web-gis decison support system for parasite control in Alpine regions: applications to grapevine phenology and modelling of European grapevine moth, file e1dbfeaa-6a30-4ac9-e053-1705fe0a1c61
|
84
|
|
Insights gained from metagenomic sequencing of apple fruit surface (CV. Pinova), file e1dbfeaa-d9bd-4ac9-e053-1705fe0a1c61
|
84
|
|
Cambia il clima? Sarà un vantaggio, file e1dbfeaa-5ddf-4ac9-e053-1705fe0a1c61
|
83
|
|
Genomics to plant health: effect of climate change on plant self-protection, file e1dbfeaa-6999-4ac9-e053-1705fe0a1c61
|
83
|
|
Trichoderma harzianum T39 biocontrol activity against Plasmopara viticola: rola of protein phosphorylation in initiating grapevine resistance, file e1dbfeaa-6b08-4ac9-e053-1705fe0a1c61
|
83
|
|
The soil microbial ecology and sustainability of organically and conventionally managed vineyards, file e1dbfeaa-6a42-4ac9-e053-1705fe0a1c61
|
82
|
|
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 protein extract in the plant protection: novel alternative to chemicals against powdery mildew, file e1dbfeaa-6b02-4ac9-e053-1705fe0a1c61
|
81
|
|
Farming system affects soil microbial communities in vineyard, file e1dbfeaa-6a40-4ac9-e053-1705fe0a1c61
|
80
|
|
Identification of specific grapevine biomarkers to select efficient resistance inducers, file e1dbfeaa-6b07-4ac9-e053-1705fe0a1c61
|
80
|
|
Identification of Trichoderma spp. volatile organic compounds (VOCs) by HS-SPME/GC-MS analysis, file e1dbfeab-d686-4ac9-e053-1705fe0a1c61
|
80
|
|
New strategy for the use of Ampelomyces Spp. against grapevine powdery mildew: sanitation and disease modelling, file e1dbfeaa-6a21-4ac9-e053-1705fe0a1c61
|
79
|
|
Relevance of the plant genotype for biocontrol tools based on resistance induction, file e1dbfeaa-6aec-4ac9-e053-1705fe0a1c61
|
79
|
|
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
|
|
Vineyard management and microbial endophytes: the impact of IPM on plant-associated microbial communities, file e1dbfeaa-6aed-4ac9-e053-1705fe0a1c61
|
77
|
|
Insect-mediated transfer of microbial communities across plants, file e1dbfeaa-fc97-4ac9-e053-1705fe0a1c61
|
77
|
|
Reducing primary inoculum sources of grapevine powdery mildew by the hyperparasite Ampelomyces quisqualis, file e1dbfeaa-6aea-4ac9-e053-1705fe0a1c61
|
76
|
|
Meta-analysis of microbiomes in soils affected by Apple Replant Disease, file e1dbfeab-4b78-4ac9-e053-1705fe0a1c61
|
76
|
|
How vineyard features and application time may affect the phosphonates residues in the bunches, file e1dbfeab-5d10-4ac9-e053-1705fe0a1c61
|
76
|
|
RNA-Seq analysis of grapevine induced resistance, file e1dbfeaa-6553-4ac9-e053-1705fe0a1c61
|
75
|
|
Possible and potential use of Trichoderma atroviride SC1 as biofungicide, file e1dbfeaa-6b0e-4ac9-e053-1705fe0a1c61
|
75
|
| Totale |
68.725 |