about
PHI-base: a new database for pathogen host interactionsPHI-base update: additions to the pathogen host interaction databaseThe trans-kingdom identification of negative regulators of pathogen hypervirulenceThe Pathogen-Host Interactions database (PHI-base): additions and future developmentsUsing the pathogen-host interactions database (PHI-base) to investigate plant pathogen genomes and genes implicated in virulenceThe pathogen-host interactions database (PHI-base) provides insights into generic and novel themes of pathogenicityPublishing FAIR Data: An Exemplar Methodology Utilizing PHI-BaseGPCRs from fusarium graminearum detection, modeling and virtual screening - the search for new routes to control head blight diseaseNetwork-based data integration for selecting candidate virulence associated proteins in the cereal infecting fungus Fusarium graminearumA role for topoisomerase I in Fusarium graminearum and F. culmorum pathogenesis and sporulation.An ATP-driven efflux pump is a novel pathogenicity factor in rice blast diseaseOmniMapFree: a unified tool to visualise and explore sequenced genomesPhytoPath: an integrative resource for plant pathogen genomics.PHI-base: a new interface and further additions for the multi-species pathogen-host interactions databaseThe Fusarium graminearum genome reveals a link between localized polymorphism and pathogen specialization.Whole-genome analysis of Fusarium graminearum insertional mutants identifies virulence associated genes and unmasks untagged chromosomal deletions.The completed genome sequence of the pathogenic ascomycete fungus Fusarium graminearumCharacterisation of the Fusarium graminearum-Wheat Floral Interaction.Structure-based virtual screening of hypothetical inhibitors of the enzyme longiborneol synthase-a potential target to reduce Fusarium head blight disease.Annotation of Fusarium graminearum (PH-1) Version 5.0.Control of mating and development in Ustilago maydis.Arabidopsis is susceptible to the cereal ear blight fungal pathogens Fusarium graminearum and Fusarium culmorum.Fusarium graminearum gene deletion mutants map1 and tri5 reveal similarities and differences in the pathogenicity requirements to cause disease on Arabidopsis and wheat floral tissue.The infection biology of Fusarium graminearum: defining the pathways of spikelet to spikelet colonisation in wheat ears.The velvet gene, FgVe1, affects fungal development and positively regulates trichothecene biosynthesis and pathogenicity in Fusarium graminearum.The induction of mycotoxins by trichothecene producing Fusarium species.Characterization of the sterol 14α-demethylases of Fusarium graminearum identifies a novel genus-specific CYP51 function.First Draft Genome Sequence of a UK Strain (UK99) of Fusarium culmorum.Ensembl Genomes 2018: an integrated omics infrastructure for non-vertebrate species.RNAi as an emerging approach to control Fusarium head blight disease and mycotoxin contamination in cereals.A conserved fungal glycosyltransferase facilitates pathogenesis of plants by enabling hyphal growth on solid surfaces.Sharing mutants and experimental information prepublication using FgMutantDb (https://scabusa.org/FgMutantDb).Inter-genome comparison of the Quorn fungus Fusarium venenatum and the closely related plant infecting pathogen Fusarium graminearumThe adaptation of Fusarium culmorum to DMI Fungicides Is Mediated by Major Transcriptome Modifications in Response to Azole Fungicide, Including the Overexpression of a PDR Transporter (FcABC1).PHI-base: the pathogen-host interactions databasePHI-Nets: A Network Resource for Ascomycete Fungal Pathogens to Annotate and Identify Putative Virulence Interacting Proteins and siRNA TargetsGenome Sequence of Fusarium graminearum Strain CML3066, Isolated from a Wheat Spike in Southern Brazil
P50
Q24538409-E1A08D8C-B90B-4BBF-B22D-B98A20B537B7Q24650654-8B89DE0A-D9C4-43AF-A418-6DB7406C7001Q26782915-DF02334B-F954-46F0-86F9-8AA07861085FQ28251904-CC9BF36B-88E4-43E3-851A-CF8A5B2C3579Q28266537-0B624483-2486-42A7-B1A5-6BB5C01D178AQ28277820-7E0E89E5-1A39-41F6-9C5C-1099160CC403Q28597234-B1695B56-2FFF-4D53-8097-C1B72235AB18Q28818657-2F72B965-698B-4D49-A464-C35382090BB6Q30655688-1B0F819E-3E69-4E00-B297-C40D06C71930Q33549510-72BB699C-29CD-4EDD-BE9E-BC4A48EA49D9Q33890356-FA677236-D373-465E-89A1-8A5AE6DA364FQ34074883-951C480A-39F5-46C5-B346-4B30FF03444BQ34498367-634BB1BA-EFBA-4B22-94A4-5B2DDCA137F9Q34546595-F2357EB2-9CE9-43E5-AEC7-4525BDDF7F09Q34682180-C84FC947-34F3-4C51-9013-148AB7FF5997Q35503863-62C30241-66EB-4FEA-A592-84A15B6618E2Q35704516-9F281793-189A-4DF7-85DD-B842C7FBDBC5Q35910229-084A7A49-786E-437B-801B-2ADA49880E27Q36057287-9E1A22C8-5526-4797-B3D4-897F958BC2A1Q37599701-A2584B7A-3F57-4406-923B-CBE9F5BC487DQ39385733-11DC4DC9-A7ED-4806-818A-9170E45EE36FQ39638189-AD4E3423-76F6-464E-8747-79D3D1721AFAQ39828020-A242E97B-96D7-4F85-ADAB-57CAB4C3697DQ39954658-15951A89-5B30-47A3-88C9-18E88D07AD75Q40003665-711226FF-5C99-42A4-922D-D1B874DBF1C3Q40012781-9889C002-2350-49AC-8963-7F88C83FD32BQ40094640-E8D95134-9EEC-4B3B-AC5D-A37801F0008AQ40405375-3D325040-E4BE-4950-AC8E-10FAEA3289B8Q46270713-894D5642-4855-450B-AF9D-60D1EDBBE30BQ46297442-430B6EDD-AD54-49F5-8F7B-142E3595EF73Q46485453-C4608D6D-2079-4A7A-808F-45F77885B21AQ49885306-6EFFD7C1-66B7-4FEC-9887-A0D13CDBAC65Q55123935-7CFB39C1-686F-418B-A3DB-22937BCA3D70Q55644830-54C40D52-137F-469F-B056-B6E7175A6E50Q91304271-E89333E9-CA76-4E06-B7B5-645B3846157FQ92188508-127DDD15-6F2E-464F-B9E6-F7DACCF1ACA0Q94547912-05B054C3-1A4D-4B8F-9F93-7FF0EA3AB75A
P50
description
researcher
@en
հետազոտող
@hy
name
Martin Urban
@ast
Martin Urban
@en
Martin Urban
@es
Martin Urban
@nl
Martin Urban
@sl
type
label
Martin Urban
@ast
Martin Urban
@en
Martin Urban
@es
Martin Urban
@nl
Martin Urban
@sl
prefLabel
Martin Urban
@ast
Martin Urban
@en
Martin Urban
@es
Martin Urban
@nl
Martin Urban
@sl
P106
P31
P496
0000-0003-2440-4352