about
Comparison of gene expression between upland and lowland rice cultivars under water stress using cDNA microarray.OsMIOX, a myo-inositol oxygenase gene, improves drought tolerance through scavenging of reactive oxygen species in rice (Oryza sativa L.).An improved 2b-RAD approach (I2b-RAD) offering genotyping tested by a rice (Oryza sativa L.) F2 populationOverexpression of OsMYB48-1, a novel MYB-related transcription factor, enhances drought and salinity tolerance in riceGenetic analysis of cold tolerance at the germination and booting stages in rice by association mappingFine Mapping of Two Additive Effect Genes for Awn Development in Rice (Oryza sativa L.).OsLG3 contributing to rice grain length and yield was mined by Ho-LAMap.OsASR5 enhances drought tolerance through a stomatal closure pathway associated with ABA and H2 O2 signalling in rice.Natural variation in CTB4a enhances rice adaptation to cold habitatsRoot and shoot traits responses to phosphorus deficiency and QTL analysis at seedling stage using introgression lines of rice.QTL mapping of root traits in a doubled haploid population from a cross between upland and lowland japonica rice in three environments.Mapping QTLs of root morphological traits at different growth stages in rice.Domestication and geographic origin of Oryza sativa in China: insights from multilocus analysis of nucleotide variation of O. sativa and O. rufipogon.Genetic structure and differentiation of Oryza sativa L. in China revealed by microsatellites.Natural variation in Early flowering1 contributes to early flowering in japonica rice under long days.Fine mapping of QTL qCTB10-2 that confers cold tolerance at the booting stage in rice.Natural variation in OsPRR37 regulates heading date and contributes to rice cultivation at a wide range of latitudes.A core collection and mini core collection of Oryza sativa L. in China.Genetic structure and phylogeography of rice landraces in Yunnan, China, revealed by SSR.Genetic Basis Underlying Correlations Among Growth Duration and Yield Traits Revealed by GWAS in Rice (Oryza sativa L.).Gnp4/LAX2, a RAWUL protein, interferes with the OsIAA3-OsARF25 interaction to regulate grain length via the auxin signaling pathway in riceLoci and natural alleles underlying robust roots and adaptive domestication of upland ecotype rice in aerobic conditionsNatural Variation in Increases Drought Tolerance in Rice by Inducing ROS ScavengingFine mapping of the awn gene on chromosome 4 in rice by association and linkage analysesNew alleles for chlorophyll content and stay-green traits revealed by a genome wide association study in rice (Oryza sativa)QTL mapping and QxE interactions of grain cooking and nutrient qualities in rice under upland and lowland environmentsAssessing indica-japonica differentiation of improved rice varieties using microsatellite markersAlternative splicing of OsLG3b controls grain length and yield in japonica riceNatural alleles of GLA for grain length and awn development were differently domesticated in rice subspecies japonica and indicaGenetic analysis of roots and shoots in rice seedling by association mappingAuthor Correction: Variation of a major facilitator superfamily gene contributes to differential cadmium accumulation between rice subspeciesVariation of a major facilitator superfamily gene contributes to differential cadmium accumulation between rice subspeciesIdentification and Validation of Aerobic Adaptation QTLs in Upland RiceGenetic basis and identification of candidate genes for salt tolerance in rice by GWAS
P50
Q33298506-4366D4DA-D5EE-4EA0-9355-85D7987A5076Q34423259-F2AEFA55-BA97-4B26-9F03-A6F7A6AB857FQ34537343-9DB3F08E-94FF-4875-A7D0-FBD1F63FE9D2Q35131065-4D068CD9-B8DD-47FE-A0BE-69FECA60AFF3Q35195685-244B7CED-80C9-45A5-95BB-289A253AB01DQ36096069-F750A60D-06BF-41A7-BC8E-F48E6C7FC7E7Q36338928-BCE5C04C-49E2-4EE8-B47E-90A44E4E25ECQ37601543-0B3F83D3-0913-4DF1-BC1D-5897AEC6450CQ37733823-98E0EBED-286A-4466-BFBE-C4B3F039BAF4Q39175630-21BE9C11-F701-4546-90F6-5DB500888145Q39178109-345097D2-69C7-45BA-A390-A00C5025417AQ39374121-6CAA5028-B92D-4EBB-B237-9D0BCFE00300Q39584436-A6DA571A-F475-4A3B-B380-F367D72CDB70Q39625258-D846E68B-132A-465E-9333-7EC5C7ED5B29Q44169221-48432F05-8C8A-40E8-B362-F8598352DE44Q47651907-AE3DE32F-48E0-4BDD-AB3C-96CBB5B0DCCCQ50955984-0F6025FA-16E5-42CB-85E2-E2F36FB8996BQ51670022-1BE39CEB-47ED-4A9F-B4EB-14337A20751DQ54181120-5DBD6F23-A831-4E18-AF93-CB233CB03711Q55117396-52AB99AA-FEB7-43FF-9FAF-F1BFDA279340Q57192123-61D5B538-8281-428C-BE20-E95EE3327364Q58791257-93D39E9A-ACA1-4118-A2E2-95D11F66054EQ58804401-5A5294B3-5E2F-451D-9C70-176D7B229279Q59270376-465299CC-D21E-4241-8A9F-A7959B3EE1BCQ64116419-823E0C47-7816-4685-86E4-94F576751906Q80459735-41645200-E9FC-47D0-8A10-A12460C92A00Q83843005-3CC51138-B90A-418B-9A77-D97D968411AAQ87876198-EB8238B0-0997-4FA0-AFC6-C608178E64EBQ91135373-704B9CAD-A80A-43A4-A549-7091FB526E48Q91644082-2E962418-4ADD-43AA-9D2B-274A66251144Q92034621-E1B68161-6D1C-4BC5-832B-76F8AA824DE0Q92690724-CB31094E-F5DF-46E4-8593-1188F01D1E72Q95309849-E706523F-0DF3-41D7-9CC2-F7F47447BAECQ96609593-DFDCD3C0-3A4A-434D-A12B-94A1077B8C8D
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Zichao Li
@ast
Zichao Li
@en
Zichao Li
@es
Zichao Li
@nl
Zichao Li
@sl
type
label
Zichao Li
@ast
Zichao Li
@en
Zichao Li
@es
Zichao Li
@nl
Zichao Li
@sl
prefLabel
Zichao Li
@ast
Zichao Li
@en
Zichao Li
@es
Zichao Li
@nl
Zichao Li
@sl
P106
P1153
8385769200
P31
P496
0000-0002-3186-1132