about
The genome of the domesticated apple (Malus × domestica Borkh.)Chemical diversity of microbial volatiles and their potential for plant growth and productivityIdentification of genes differentially expressed during interaction of resistant and susceptible apple cultivars (Malus x domestica) with Erwinia amylovora.Stable expression and phenotypic impact of attacin E transgene in orchard grown apple trees over a 12 year periodCharacterization of the MLO gene family in Rosaceae and gene expression analysis in Malus domestica.Putative resistance gene markers associated with quantitative trait loci for fire blight resistance in Malus 'Robusta 5' accessionsIdentification of Pyrus single nucleotide polymorphisms (SNPs) and evaluation for genetic mapping in European pear and interspecific Pyrus hybridsDifferential expression of CPKs and cytosolic Ca2+ variation in resistant and susceptible apple cultivars (Malus x domestica) in response to the pathogen Erwinia amylovora and mechanical woundingCharacterization of resistance gene analogues (RGAs) in apple (Malus × domestica Borkh.) and their evolutionary history of the Rosaceae family.The draft genome sequence of European pear (Pyrus communis L. 'Bartlett')Species-specific duplications driving the recent expansion of NBS-LRR genes in five Rosaceae species.Genome mapping of postzygotic hybrid necrosis in an interspecific pear population.Nonsense Mutation Inside Anthocyanidin Synthase Gene Controls Pigmentation in Yellow Raspberry (Rubus idaeus L.).DNA-Free Genetically Edited Grapevine and Apple Protoplast Using CRISPR/Cas9 Ribonucleoproteins.Calcium imaging perspectives in plants.Bioprospecting bacterial and fungal volatiles for sustainable agriculture.Fine-Tuning Next-Generation Genome Editing Tools.Frequency of a natural truncated allele of MdMLO19 in the germplasm of Malus domestica.Biomolecular characterization of the levansucrase of Erwinia amylovora, a promising biocatalyst for the synthesis of fructooligosaccharides.Knockdown of MLO genes reduces susceptibility to powdery mildew in grapevine.The knock-down of the expression of MdMLO19 reduces susceptibility to powdery mildew (Podosphaera leucotricha) in apple (Malus domestica)Modulation of defense responses of Malus spp. during compatible and incompatible interactions with Erwinia amylovora.Activation of three pathogen-inducible promoters of tobacco in transgenic pear (Pyrus communis L.) after abiotic and biotic elicitation.Expression of viral EPS-depolymerase reduces fire blight susceptibility in transgenic pear.Breeding next generation tree fruits: technical and legal challenges.Homologous and heterologous expression of grapevine E-(β)-caryophyllene synthase (VvGwECar2).Is there room for improving the nutraceutical composition of apple?Activation of the pathogen-inducible Gst1 promoter of potato after elicitation by Venturia inaequalis and Erwinia amylovora in transgenic apple (Malus x domestica).Adjusting the scent ratio: using genetically modified Vitis vinifera plants to manipulate European grapevine moth behaviour.Induction of Terpene Biosynthesis in Berries of Microvine Transformed with VvDXS1 Alleles.Looking forward to genetically edited fruit crops.Steroid 5β-Reductase from Leaves of Vitis vinifera: Molecular Cloning, Expression, and Modeling.Evaluation of transgenic 'Chardonnay' (Vitis vinifera) containing magainin genes for resistance to crown gall and powdery mildewA genome-wide phylogenetic reconstruction of family 1 UDP-glycosyltransferases revealed the expansion of the family during the adaptation of plants to life on landCRISPR-Cas9-mediated genome editing in apple and grapevineTowards map-based cloning of : identification of a receptor-like kinase candidate gene underlying the fire blight resistance locus on linkage group 10Genetically engineered Thompson Seedless grapevine plants designed for fungal tolerance: selection and characterization of the best performing individuals in a field trialChitinases of Trichoderma atroviride Induce Scab Resistance and Some Metabolic Changes in Two Cultivars of AppleTwo receptor-like genes, Vfa1 and Vfa2, confer resistance to the fungal pathogen Venturia inaequalis inciting apple scab diseaseNon-GMO genetically edited crop plants
P50
Q22122060-9BA6A84A-F0D8-4BCD-88AC-C4FAFA8E44D3Q26852234-CF37BB47-D559-42A4-AEE6-C8DFC3AE651DQ33521762-7578C3C6-6078-49F8-99A6-4AD2BBB4BF3DQ33595023-0AE145F2-1C71-42C2-AC68-CDE2DA274CAEQ34012010-9FC5CA2D-D672-42E3-8C3E-DBDD01113869Q34218487-44C2DEFB-2175-49E1-AF5F-9263D66AEC94Q35025345-20A13AAA-3320-4958-BBAE-2D370AB95CEFQ35031850-82C8E9AA-781C-46ED-9A36-1AF6EAD5C5B5Q35088025-9F4D818A-618B-4633-8F1F-3E7CC8D850E0Q35139182-347EED54-BC32-4208-A655-AA55A91267ECQ35574913-3E9CBE1B-472B-4F60-86AB-FDE6F9F47866Q36432669-287D3E3E-6BE7-4F0A-BFB6-8D828B67051FQ37512979-D0FC48E7-BB28-412A-A7FC-5362E091834DQ37518183-FD7F012A-1B42-4A6D-8DEE-BBDB6CA8FB95Q38193673-94B28772-07E6-4177-B5FD-7D6B7E5C67D6Q38347008-101B1E0A-19E8-4227-BCE5-DF4890D5F785Q38831935-761EE6FA-F05D-41B3-BD39-4B0A8F977DCEQ38996398-B7BEDF83-EC9D-4D57-91DB-A12A7CBED4AAQ39308005-D79E913B-FED3-401F-9945-D74918644E94Q40621272-63611047-58D6-46A8-B41C-AD5A312F215CQ41239928-244E6946-ADF8-4C35-8B69-2EC2E96A9707Q44248958-8DE95CB3-0DB3-4BF3-BF97-9471CEA51404Q44354326-4200CE3B-7B07-4B67-8F83-8FA591806572Q44577780-637A965D-6854-4FBC-BFAD-513215488E47Q46241586-04325329-ACCF-4DEB-8F64-442C81CC6B56Q46497020-0BB01AC3-FEAB-4872-94F9-C24922016065Q46766627-57D2EA70-EAC8-470D-B0B4-2EC6130AB300Q46941604-951ABCD1-82C6-4ECB-887F-00B8A484E72BQ47826933-1369A1C3-09EC-4213-90F4-57965FDDDC69Q49275296-0DC87C20-77EE-426F-9902-9BF652A09398Q51800888-71F93393-1B90-42DA-8F0A-E3F61120B884Q54257168-54942A9D-8C04-4D94-ABFD-EA79E7A70930Q57138266-CD369E26-7B3F-4828-B6B4-0378B4823EBFQ57704893-F7FE92BA-F1C6-4E5E-BB99-97EEEE2CFAF7Q58617578-071B465E-1AAD-468D-B20D-4591B34622DBQ58798750-DDF5A0B6-9004-4C86-A9FB-C1C3F58DDE2BQ60459707-A6D0CE6D-BC4F-4692-8280-D0B9A5478957Q79682791-7F322C95-7F29-4FA2-96E1-70ADFBCEF05EQ80822872-6D906E94-D070-4455-BE34-8595350A244BQ87317368-2A59CF04-6A63-4A30-828B-6213BE6B1034
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Mickael Malnoy
@ast
Mickael Malnoy
@en
Mickael Malnoy
@es
Mickael Malnoy
@nl
type
label
Mickael Malnoy
@ast
Mickael Malnoy
@en
Mickael Malnoy
@es
Mickael Malnoy
@nl
prefLabel
Mickael Malnoy
@ast
Mickael Malnoy
@en
Mickael Malnoy
@es
Mickael Malnoy
@nl
P106
P1153
6602897201
P31
P496
0000-0002-5158-534X