about
Heterogeneous Cloud Framework for Big Data Genome Sequencing.A D53 repression motif induces oligomerization of TOPLESS corepressors and promotes assembly of a corepressor-nucleosome complex.Deficient plastidic fatty acid synthesis triggers cell death by modulating mitochondrial reactive oxygen species.Critical roles of soluble starch synthase SSIIIa and granule-bound starch synthase Waxy in synthesizing resistant starch in rice.A natural tandem array alleviates epigenetic repression of IPA1 and leads to superior yielding riceGenome-wide association studies dissect the genetic networks underlying agronomical traits in soybean.Copy number variation at the GL7 locus contributes to grain size diversity in rice.IPA1 functions as a downstream transcription factor repressed by D53 in strigolactone signaling in rice.eResponseNet: a package prioritizing candidate disease genes through cellular pathways.DWARF14, A Receptor Covalently Linked with the Active Form of Strigolactones, Undergoes Strigolactone-Dependent Degradation in Rice.Construction of a Genome-Wide Mutant Library in Rice Using CRISPR/Cas9.Tissue-Specific Ubiquitination by IPA1 INTERACTING PROTEIN1 Modulates IPA1 Protein Levels to Regulate Plant Architecture in Rice.DWARF 53 acts as a repressor of strigolactone signalling in rice.Genetic variations in ARE1 mediate grain yield by modulating nitrogen utilization in rice.Identification of Regulatory DNA Elements Using Genome-wide Mapping of DNase I Hypersensitive Sites during Tomato Fruit Development.Genome-wide binding analysis of the transcription activator ideal plant architecture1 reveals a complex network regulating rice plant architecture.Developmental systems biology flourishing on new technologies.Genomic variation in 3,010 diverse accessions of Asian cultivated rice.Malate transported from chloroplast to mitochondrion triggers production of ROS and PCD in Arabidopsis thaliana.xCas9 expands the scope of genome editing with reduced efficiency in riceSLR1 inhibits MOC1 degradation to coordinate tiller number and plant height in rice.Detection of major loci associated with the variation of 18 important agronomic traits between Solanum pimpinellifolium and cultivated tomatoesA Core Regulatory Pathway Controlling Rice Tiller Angle Mediated by the LAZY1-Dependent Asymmetric Distribution of AuxinRapid and specific isolation of intact mitochondria from Arabidopsis leavesA single transcription factor promotes both yield and immunity in riceTiller Bud Formation Regulators MOC1 and MOC3 Cooperatively Promote Tiller Bud Outgrowth by Activating FON1 Expression in RiceTowards a deeper haplotype mining of complex traits in rice with RFGB v2.0.Regulation of mitochondrial NAD pool via NAD+ transporter 2 is essential for matrix NADH homeostasis and ROS production in ArabidopsisStrigolactone promotes cytokinin degradation through transcriptional activation of CYTOKININ OXIDASE/DEHYDROGENASE 9 in riceRetrospective and perspective of rice breeding in ChinaTranscriptional regulation of strigolactone signalling in Arabidopsis
P50
Q30992743-EDA5108D-2142-4EB8-80FE-F6F72CF6F534Q33758355-2DAA4B86-6039-46AB-9C0C-410C2F9420DDQ35578968-E18F1F49-ECF2-4C9B-906C-425229CD219EQ37417798-539B73AC-DDDD-4EFE-8E1D-70BB51E3C890Q37719279-4DF3C201-21AC-408B-8955-CD65B61AFAFDQ38637627-67880BDD-3344-4029-8957-DE5BA575428FQ40765488-17AA33C9-0BAB-47CA-9E66-9A91010F5809Q41625155-9E993EC6-B342-4258-973F-AF5B26EDACEEQ45710621-EA8D59B0-235A-4B33-BB0C-ED51F3C3DB84Q45850306-7D132FE7-D070-472F-BCCC-2CA3161EDBA1Q47990870-EA5D5B60-5B70-4EA0-84FE-1D5B14D0F4AEQ48120091-266F0517-95CD-40C7-99C1-29C7F57E1C71Q50233444-60F52B68-740A-4C4F-828A-CE8C4AAE9B47Q50296450-B12F8F8B-7A5F-4544-B7E2-9A639E81DBF0Q50507668-4CFABDB0-EAD9-4BD0-8DE8-D747ECD51A0FQ50712798-74D60CD8-79E3-4857-A22F-FC5A7D599EAAQ51947743-CA25EE9F-8CA4-4158-9873-1FEB04DFA3C5Q52309448-F078358F-24B8-4989-89EA-3491A016B578Q52355314-7CA46AA8-D6B9-4EB3-8614-4D82B7E3266CQ64266747-B65761C8-5898-442F-BD33-A4D9CA17184DQ64934081-57D3B9CF-49A4-4184-AAC1-BC46D454A821Q88603300-DE45B3C5-FDEB-413B-9CB8-DBAB8BDEBBD6Q89143880-BB073488-035D-4F36-B9B5-76A70E727A2DQ89864694-30BE3E9E-39ED-45B4-A984-81862FD2B0E6Q91321809-818F4CB4-D3B4-4B83-9E46-127D51B0EE28Q91707511-AA3D9259-24B7-4ADE-B8C5-DD664B7057B6Q92122669-FD24ECC6-091F-4F5F-A48C-622387A2B564Q92552591-7079723A-2082-4412-A4F6-842A396EAE45Q92998591-8F3EC0DD-6E85-41E3-BF6B-6E5693732954Q93199379-F73DDD50-2BF2-4F17-9FC0-1DB7A4FC47A5Q96302949-CADE0904-75AE-4BB8-BA7B-589F44EE82DC
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Hong Yu
@ast
Hong Yu
@en
Hong Yu
@es
Hong Yu
@nl
Hong Yu
@sl
type
label
Hong Yu
@ast
Hong Yu
@en
Hong Yu
@es
Hong Yu
@nl
Hong Yu
@sl
prefLabel
Hong Yu
@ast
Hong Yu
@en
Hong Yu
@es
Hong Yu
@nl
Hong Yu
@sl
P1053
H-2770-2012
P106
P2456
55/6749-11
P31
P3829
P496
0000-0002-1748-8693