about
A Lin28 homologue reprograms differentiated cells to stem cells in the moss Physcomitrella patensMining small RNA sequencing data: a new approach to identify small nucleolar RNAs in ArabidopsisAGROBEST: an efficient Agrobacterium-mediated transient expression method for versatile gene function analyses in Arabidopsis seedlings.Natural selection on cis and trans regulation in yeasts22-Nucleotide RNAs trigger secondary siRNA biogenesis in plants.HUA ENHANCER1 is involved in posttranscriptional regulation of positive and negative regulators in Arabidopsis photomorphogenesis.Translational landscape of photomorphogenic Arabidopsis.Transcriptome dynamics of developing maize leaves and genomewide prediction of cis elements and their cognate transcription factors.Bioinformatic prediction and experimental validation of a microRNA-directed tandem trans-acting siRNA cascade in Arabidopsis.Widespread translational control contributes to the regulation of Arabidopsis photomorphogenesisInsights into the regulation of C4 leaf development from comparative transcriptomic analysis.A vicilin-like seed storage protein, PAP85, is involved in tobacco mosaic virus replication.LWD-TCP complex activates the morning gene CCA1 in Arabidopsis.Gene expression regulation in photomorphogenesis from the perspective of the central dogma.Unraveling multifaceted contributions of small regulatory RNAs to photomorphogenic development in Arabidopsis.Molecular analyses of the Arabidopsis TUBBY-like protein gene family.Molecular events in senescing Arabidopsis leaves.Elevated auxin biosynthesis and transport underlie high vein density in C4 leaves.Comparative transcriptome analysis reveals significant differences in gene expression and signalling pathways between developmental and dark/starvation-induced senescence in Arabidopsis.Differential regulation of Ku gene expression in etiolated mung bean hypocotyls by auxins.Plant dual-specificity tyrosine phosphorylation-regulated kinase optimizes light-regulated growth and development in Arabidopsis.Arabidopsis bZIP16 transcription factor integrates light and hormone signaling pathways to regulate early seedling development.LZF1, a HY5-regulated transcriptional factor, functions in Arabidopsis de-etiolation.The Arabidopsis B-box zinc finger family.Two new clock proteins, LWD1 and LWD2, regulate Arabidopsis photoperiodic flowering.An incoherent feed-forward loop switches the Arabidopsis clock rapidly between two hysteretic statesTOR and RPS6 transmit light signals to enhance protein translation in deetiolating seedlingsLIGHT-REGULATED WD1 and PSEUDO-RESPONSE REGULATOR9 form a positive feedback regulatory loop in the Arabidopsis circadian clockIron is involved in the maintenance of circadian period length in ArabidopsisCOP1-mediated degradation of BBX22/LZF1 optimizes seedling development in ArabidopsisComparative transcriptomics method to infer gene coexpression networks and its applications to maize and rice leaf transcriptomesProcessing bodies control the selective translation for optimal development of Arabidopsis young seedlings
P50
Q30837303-55C68ABE-54FD-49E3-9189-E4D56FC351EDQ33428456-D2E3E5F7-16C4-46A0-BCC5-57D5F0AC945AQ33826758-72767004-5B10-4E7E-B5B4-99F9A6C978AAQ33881377-E1903D62-35D0-4C83-B524-873456F81AFCQ34093679-77BD3DB2-7D50-497F-85BB-0E765C1CC2B6Q34430370-32898BA9-5F36-400C-A588-96472CB22A0BQ35030087-CB78E1DF-23C8-4BE1-9E5F-A69DC4A49B80Q35616234-AE3FCDAD-E117-4B2A-8073-45637697D756Q35652561-C493309C-698B-4336-AB2D-E477BD592B9EQ35811144-12422499-DDE2-48E4-B457-EA5161DA4538Q35909352-979A62AB-D088-4063-8CEC-1BB373F2E608Q36911783-D38683C5-33E7-4882-B9EB-1716338C9C22Q37341966-5915B99A-8484-45E4-A838-99A1B6D4BD03Q38208060-3E06E9CB-F657-45E7-BED7-9B59CE2E1DCDQ41111491-E13443BF-CF32-4509-9218-243EC864D1C0Q44830260-507E0A46-6347-45FC-AEC9-17CD273732B1Q44992341-30732DC0-DE4C-4D61-94E4-93463DA7207EQ46328111-A594689C-33E9-4596-84D6-E849BF11C799Q46462448-84B5FC7B-295F-43E1-BC24-011BA8FE76C6Q48079415-3B0CB5C4-2AC0-4178-8AD9-BDAED0FCAA5AQ48238914-B472B976-3DFC-46F2-9679-88E1F90A6E51Q50488594-F8F7D025-FA4D-4074-AA71-9069EB30F9CCQ50663329-BC90FEB2-3137-41E7-9AE9-5AD6FF07F988Q51774784-F967B597-30E9-4E12-BB4D-37FBB2F58F60Q54521787-DAD9085A-729D-418A-91BF-95DBFBEF4830Q58733894-8C95E8D7-1622-4628-8004-02506D180F79Q60311372-47E5678E-F9F8-4054-A3D5-0935F0A8862AQ61762869-72BA792F-22A2-487C-A724-387A0B50BC63Q63640998-1936462B-5EF7-47DB-A49D-645B38949750Q63641002-1433320E-308C-401C-B900-11C6DAFF17BAQ63641059-0177F738-270C-4C6E-B693-15D777BE1D70Q64118087-0B3B66C8-EF49-4D32-BCCB-64645CA2649A
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Shu-Hsing Wu
@ast
Shu-Hsing Wu
@en
Shu-Hsing Wu
@es
Shu-Hsing Wu
@nl
Shu-Hsing Wu
@sl
type
label
Shu-Hsing Wu
@ast
Shu-Hsing Wu
@en
Shu-Hsing Wu
@es
Shu-Hsing Wu
@nl
Shu-Hsing Wu
@sl
prefLabel
Shu-Hsing Wu
@ast
Shu-Hsing Wu
@en
Shu-Hsing Wu
@es
Shu-Hsing Wu
@nl
Shu-Hsing Wu
@sl
P106
P31
P496
0000-0002-7179-3138