| Nome |
# |
|
Selection and Experimental Evaluation of Universal Primers to Study the Fungal Microbiome of Higher Plants, file e2047587-0d18-7e24-e053-6605fe0afb29
|
403
|
|
Metabarcoding: A powerful tool to investigate microbial communities and shape future plant protection strategies, file e2047587-0d10-7e24-e053-6605fe0afb29
|
276
|
|
Alternative management technologies for postharvest disease control: The journey from simplicity to complexity, file e2047588-8ff3-7e24-e053-6605fe0afb29
|
194
|
|
Olive leaf spot caused by Venturia oleaginea: An updated review, file 2a1feaba-0462-4554-afa4-c3bc8502e63a
|
163
|
|
Control of postharvest fungal rots on citrus fruit and sweet cherries using a pomegranate peel extract., file e2047588-956e-7e24-e053-6605fe0afb29
|
119
|
|
Intensificazione sostenibile per la filiera olivicolo-olearia: approfondimenti sulle filiere di interesse per l’ambiente mediterraneo, file e2047588-4a1d-7e24-e053-6605fe0afb29
|
91
|
|
Pre- and postharvest application of alternative means to control Alternaria brown spot of citrus, file e2047587-0e62-7e24-e053-6605fe0afb29
|
68
|
|
Characterization of colletotrichum ocimi population associated with black spot of sweet basil (Ocimum basilicum) in Northern Italy, file e2047586-efd8-7e24-e053-6605fe0afb29
|
62
|
|
Control of olive anthracnose and leaf spot disease by bloom treatments with a pomegranate peel extract, file e2047589-a09f-7e24-e053-6605fe0afb29
|
61
|
|
Dieback of Pinus nigra seedlings caused by a strain of Trichoderma viride, file e2047587-2127-7e24-e053-6605fe0afb29
|
43
|
|
Characterization of citrus-associated Alternaria species in Mediterranean areas, file e2047587-2114-7e24-e053-6605fe0afb29
|
40
|
|
Analysis of the fungal diversity in citrus leaves with greasy spot disease symptoms, file e2047588-9694-7e24-e053-6605fe0afb29
|
40
|
|
Impact of Bactrocera oleae on the fungal microbiota of ripe olive drupes, file e2047587-0d1d-7e24-e053-6605fe0afb29
|
37
|
|
Metagenomics approaches for the detection and surveillance of emerging and recurrent plant pathogens, file e2047588-2247-7e24-e053-6605fe0afb29
|
37
|
|
Fungal endophytic community of ancient wheat varieties, file e2047587-0d0d-7e24-e053-6605fe0afb29
|
24
|
|
Metabarcoding analysis of Phytophthora diversity using genus specific primers and 454 pyrosequencing., file e2047587-1d16-7e24-e053-6605fe0afb29
|
23
|
|
Nothophytophthora gen. nov, a new sister genus of Phytophthora from natural and semi-natural ecosystems, file e2047587-21ec-7e24-e053-6605fe0afb29
|
19
|
|
Molecular analysis of Phytophthora diversity in nursery-grown ornamental and fruit plants, file e2047587-2124-7e24-e053-6605fe0afb29
|
16
|
|
Fungal communities associated with bark and ambrosia beetles trapped at international harbours, file e2047588-91a1-7e24-e053-6605fe0afb29
|
16
|
|
Elicitation of resistance responses in grapefruit and lemon fruits treated with a pomegranate peel extract, file e2047587-1d45-7e24-e053-6605fe0afb29
|
14
|
|
Revealing cues for fungal interplay in the plant-air interface in vineyards, file e2047586-f536-7e24-e053-6605fe0afb29
|
11
|
|
Multiple new cryptic pathogenic Phytophthora species from Fagaceae forests in Austria, Italy and Portugal, file e2047587-098a-7e24-e053-6605fe0afb29
|
11
|
|
Decline of jackfruit (Artocarpus heterophyllus) incited by Phytophthora palmivora in Vietnam, file e2047587-2123-7e24-e053-6605fe0afb29
|
11
|
|
Chemical characterization of different sumac and pomegranate extracts effective against Botrytis cinerea rots., file e2047587-1dde-7e24-e053-6605fe0afb29
|
10
|
|
Fungal Planet description sheets: 558–624, file e2047587-2216-7e24-e053-6605fe0afb29
|
10
|
|
Transcriptomic analysis of orange fruit treated with pomegranate peel extract (PGE), file e2047587-0d0b-7e24-e053-6605fe0afb29
|
9
|
|
Spatial and compositional variation in the fungal communities of organic and conventionally grown apple fruit at the consumer point-of-purchase, file e2047587-1d13-7e24-e053-6605fe0afb29
|
8
|
|
Genetic Analysis of Phytophthora nicotianae Populations From Different Hosts Using Microsatellite Markers, file e2047587-1d18-7e24-e053-6605fe0afb29
|
7
|
|
Metabarcoding analysis of fungal diversity in the phyllosphere and carposphere of olive (Olea europaea), file e2047587-20f5-7e24-e053-6605fe0afb29
|
7
|
|
Quantitative detection of Colletotrichum godetiae and C. acutatum sensu stricto in the phyllosphere and carposphere of olive during four phenological phases, file e2047588-904c-7e24-e053-6605fe0afb29
|
7
|
|
A Metabarcoding Survey on the Fungal Microbiota Associated to the Olive Fruit Fly, file e2047588-907d-7e24-e053-6605fe0afb29
|
7
|
|
Eight new Halophytophthora species from marine and brackish-water ecosystems in Portugal and an updated phylogeny for the genus, file e2047589-700a-7e24-e053-6605fe0afb29
|
7
|
|
Characterization of Phytopythium Species Involved in the Establishment and Development of Kiwifruit Vine Decline Syndrome, file 5ec2ae69-2922-4a2b-900a-8a4546299bb0
|
6
|
|
Apple endophytic microbiota of different rootstock/scion combinations suggests a genotype specific influence, file e2047587-0983-7e24-e053-6605fe0afb29
|
6
|
|
Evaluation of a pomegranate peel extract as an alternative means to control olive anthracnose, file e2047587-14ef-7e24-e053-6605fe0afb29
|
6
|
|
Pomegranate peel extracts as safe natural treatments to control plant diseases and increase the shelf-life and safety of fresh fruits and vegetables, file e2047588-7b27-7e24-e053-6605fe0afb29
|
6
|
|
Response of Tomato Rhizosphere Bacteria to Root-Knot Nematodes, Fenamiphos and Sampling Time Shows Differential Effects on Low Level Taxa, file e2047586-ef23-7e24-e053-6605fe0afb29
|
5
|
|
Two previously unknown Phytophthora species associated with brown rot of Pomelo (Citrus grandis) fruits in Vietnam., file e2047587-1c05-7e24-e053-6605fe0afb29
|
5
|
|
First report of Verticillium dahliae causing wilt of goji (Lycium barbarum) in Italy, file e2047587-221b-7e24-e053-6605fe0afb29
|
5
|
|
Diversity and distribution of Phytophthora species in protected natural areas in Sicily, file e2047587-0e63-7e24-e053-6605fe0afb29
|
4
|
|
Phytophthora nicotianae diseases worldwide: new knowledge of a long-recognised pathogen, file e2047587-1cbe-7e24-e053-6605fe0afb29
|
4
|
|
Identification of Phytophthora species by a high resolution melting analysis: an innovative tool for rapid differentiation, file e2047587-201d-7e24-e053-6605fe0afb29
|
4
|
|
Olive leachates affect germination of Colletotrichum godetiae conidia and the development of appressoria, file e2047587-2129-7e24-e053-6605fe0afb29
|
4
|
|
Plant Genotype Shapes the Bacterial Microbiome of Fruits, Leaves, and Soil in Olive Plants, file e2047589-a156-7e24-e053-6605fe0afb29
|
4
|
|
Plant genotype influence the structure of cereal seed fungal microbiome, file b27fab45-b13b-4fac-a3c1-c0aad3d624b1
|
3
|
|
Detection and quantification of P. ramorum, P. kernoviae, P. citricola and P. quercina in symptomatic leaves by multiplex real-time PCR, file e2047586-184a-7e24-e053-6605fe0afb29
|
3
|
|
Phytophthora citrophthora is the predominant Phytophthora species in Syrian citrus groves, file e2047586-1866-7e24-e053-6605fe0afb29
|
3
|
|
Trichoderma viride may be a plant pathogen. Journal of plant pathology., file e2047586-2ebf-7e24-e053-6605fe0afb29
|
3
|
|
Effectiveness of a pomegranate peel extract (PGE) in reducing Listeria monocytogenes in vitro and on fresh-cut pear, apple and melon, file e2047586-ef20-7e24-e053-6605fe0afb29
|
3
|
|
New insights into scabby canker of opuntia ficus-indica, caused by neofusicoccum batangarum, file e2047586-f142-7e24-e053-6605fe0afb29
|
3
|
|
The Top 10 oomycete pathogens in molecular plant pathology, file e2047587-2122-7e24-e053-6605fe0afb29
|
3
|
|
Metagenomic analysis of fungal diversity on strawberry plants and the effect of management practices on the fungal community structure of aerial organs, file e2047587-2249-7e24-e053-6605fe0afb29
|
3
|
|
Experimental evidence of microbial inheritance in plants and transmission routes from seed to phyllosphere and root, file e2047588-f37c-7e24-e053-6605fe0afb29
|
3
|
|
Selection of yeasts for their anti-mold activity and prospective use in table olive fermentation, file e2047589-07f3-7e24-e053-6605fe0afb29
|
3
|
|
Exploring microbiomes for plant disease management, file e2047589-7141-7e24-e053-6605fe0afb29
|
3
|
|
Extracts from Environmental Strains of Pseudomonas spp. Effectively Control Fungal Plant Diseases, file e2047589-af4a-7e24-e053-6605fe0afb29
|
3
|
|
Molecular analysis of Colletotrichum species in the carposphere and phyllosphere of olive, file e2047586-16b3-7e24-e053-6605fe0afb29
|
2
|
|
Characterization of Basidiomycetes Associated with Wood Rot of Citrus in Southern Italy, file e2047586-4114-7e24-e053-6605fe0afb29
|
2
|
|
Real-time PCR detection and quantification of soilborne fungal pathogens: the case of Rosellinia necatrix, Phytophthora nicotianae, P. citrophthora, and Verticillium dahliae, file e2047586-6db8-7e24-e053-6605fe0afb29
|
2
|
|
Development and application of a qPCR detection method to quantify Venturia oleaginea (Castagne) Rossman & Crous in asymptomatic olive (Olea europaea L.) leaves, file e2047586-f909-7e24-e053-6605fe0afb29
|
2
|
|
Quantitative detection of Colletotrichum godetiae and C. acutatum sensu stricto in the phyllosphere and carposphere of olive during four phenological phases, file e2047587-1cab-7e24-e053-6605fe0afb29
|
2
|
|
Selection of yeasts for their anti-mold activity and prospective use in table olive fermentation, file e2047587-2497-7e24-e053-6605fe0afb29
|
2
|
|
Characterization of Phytophthora infestans populations in northwestern Algeria during 2008-2014., file e2047588-97ad-7e24-e053-6605fe0afb29
|
2
|
|
Preharvest and postharvest applications of a pomegranate peel extract to control citrus fruit decay during storage and shelf life, file e2047588-f37e-7e24-e053-6605fe0afb29
|
2
|
|
The Fungal Microbiome of Wheat Flour Includes Potential Mycotoxin Producers, file e2047589-9162-7e24-e053-6605fe0afb29
|
2
|
|
Exploring microbiomes for plant disease management, file e2047589-bdd0-7e24-e053-6605fe0afb29
|
2
|
|
Comparative transcriptome profiling and co-expression network analysis uncover the key genes associated with pear petal defense responses against Monilinia laxa infection, file 805e41e5-4434-47af-a764-e4c6a0f187ce
|
1
|
|
Diagnostic SCAR-PCR assay for Colletotrichum clavatum, the causal agent of olive anthracnose in southern Italy, file e2047586-112a-7e24-e053-6605fe0afb29
|
1
|
|
Colletotrichum clavatum sp. nov. identified as the causal agent of olive anthracnose in Italy, file e2047586-1155-7e24-e053-6605fe0afb29
|
1
|
|
Real-time PCR identification and detection of Fuscoporia torulosa in Quercus ilex woods, file e2047586-1231-7e24-e053-6605fe0afb29
|
1
|
|
Molecular detection of the strain L47 of Aureobasidium pullulans, a biocontrol agent of post-harvest diseases, file e2047586-1312-7e24-e053-6605fe0afb29
|
1
|
|
Phytophthora × pelgrandis causes root and collar rot of Lavandula stoechas in Italy, file e2047586-16f9-7e24-e053-6605fe0afb29
|
1
|
|
Speciale Agrumi: Le malattie fungine emergenti, file e2047586-17c1-7e24-e053-6605fe0afb29
|
1
|
|
A molecular method to assess Phytophthora diversity in environmental samples, file e2047586-1834-7e24-e053-6605fe0afb29
|
1
|
|
Le malattie degli agrumi in postraccolta, file e2047586-1b0d-7e24-e053-6605fe0afb29
|
1
|
|
Use of Quantitative PCR detection methods to study biocontrol agents and phytopathogenic fungi and oomycetes in environmental samples, file e2047586-1b1b-7e24-e053-6605fe0afb29
|
1
|
|
First report of Neofusicoccum batangarum as causal agent of scabby cankers of cactus pear (Opuntia ficus-indica) in minor islands of Sicily, file e2047586-1cb7-7e24-e053-6605fe0afb29
|
1
|
|
First report of collar and root rot caused by Phytophthora nicotianae on Lycium barbarum, file e2047586-1cbb-7e24-e053-6605fe0afb29
|
1
|
|
Recent advances in the analysis of the olive fungal microbiome, file e2047586-1cbd-7e24-e053-6605fe0afb29
|
1
|
|
Genetic characterization of Phytophthora nicotianae by analysis of mitochondrial DNA, file e2047586-1cc0-7e24-e053-6605fe0afb29
|
1
|
|
Rapid and sensitive detection of Rosellinia necatrix in roots and soils by real time Scorpion-PCR, file e2047586-1ee3-7e24-e053-6605fe0afb29
|
1
|
|
Olive leaf spot, file e2047586-1f24-7e24-e053-6605fe0afb29
|
1
|
|
White and fibrous root rot of olive, file e2047586-1f4c-7e24-e053-6605fe0afb29
|
1
|
| Totale |
1.983 |