Spatially and temporally regulated expression of rice MADS box genes with similarity to Arabidopsis class A, B and C genes.
about
MADS-box gene family in rice: genome-wide identification, organization and expression profiling during reproductive development and stressThe MADS and the Beauty: Genes Involved in the Development of Orchid FlowersEvolution of floral meristem identity genes. Analysis of Lolium temulentum genes related to APETALA1 and LEAFY of Arabidopsis.Overexpression of RCN1 and RCN2, rice TERMINAL FLOWER 1/CENTRORADIALIS homologs, confers delay of phase transition and altered panicle morphology in rice.Heterogeneous expression patterns and separate roles of the SEPALLATA gene LEAFY HULL STERILE1 in grasses.Morphogenesis and molecular basis on naked seed rice, a novel homeotic mutation of OsMADS1 regulating transcript level of AP3 homologue in rice.Genome-wide analysis of spatial and temporal gene expression in rice panicle development.Rice ABERRANT PANICLE ORGANIZATION 1, encoding an F-box protein, regulates meristem fate.Ectopic expression of a hyacinth AGL6 homolog caused earlier flowering and homeotic conversion in Arabidopsis.Autophagy regulated by day length determines the number of fertile florets in wheat.Rice Indeterminate 1 (OsId1) is necessary for the expression of Ehd1 (Early heading date 1) regardless of photoperiod.Rice open beak is a negative regulator of class 1 knox genes and a positive regulator of class B floral homeotic gene.MOSAIC FLORAL ORGANS1, an AGL6-like MADS box gene, regulates floral organ identity and meristem fate in rice.Functional analysis of B and C class floral organ genes in spinach demonstrates their role in sexual dimorphism.Genetic interaction of OsMADS3, DROOPING LEAF, and OsMADS13 in specifying rice floral organ identities and meristem determinacy.Rice MADS6 interacts with the floral homeotic genes SUPERWOMAN1, MADS3, MADS58, MADS13, and DROOPING LEAF in specifying floral organ identities and meristem fate.Functional analysis of all AGAMOUS subfamily members in rice reveals their roles in reproductive organ identity determination and meristem determinacy.Two AP2 family genes, supernumerary bract (SNB) and Osindeterminate spikelet 1 (OsIDS1), synergistically control inflorescence architecture and floral meristem establishment in rice.Rice LHS1/OsMADS1 controls floret meristem specification by coordinated regulation of transcription factors and hormone signaling pathways.Down-regulation of a LBD-like gene, OsIG1, leads to occurrence of unusual double ovules and developmental abnormalities of various floral organs and megagametophyte in rice.The ABCs of flower development: mutational analysis of AP1/FUL-like genes in rice provides evidence for a homeotic (A)-function in grasses.Interactions between FLORAL ORGAN NUMBER4 and floral homeotic genes in regulating rice flower development.Dynamic patterns of expression for genes regulating cytokinin metabolism and signaling during rice inflorescence developmentDEP and AFO regulate reproductive habit in rice.BeMADS1 is a key to delivery MADSs into nucleus in reproductive tissues-De novo characterization of Bambusa edulis transcriptome and study of MADS genes in bamboo floral developmentInterpreting lemma and palea homologies: a point of view from rice floral mutantsMorphology and quantitative monitoring of gene expression patterns during floral induction and early flower development in Dendrocalamus latiflorusAllopolyploidization and evolution of species with reduced floral structures in Lepidium L. (Brassicaceae).Double-stranded RNA interference of a rice PI/GLO paralog, OsMADS2, uncovers its second-whorl-specific function in floral organ patterning.Fine mapping of BH1, a gene controlling lemma and palea development in rice.Genome-wide identification, phylogenetic and co-expression analysis of OsSET gene family in riceA network of rice genes associated with stress response and seed developmentFlowering time genes Heading date 1 and Early heading date 1 together control panicle development in rice.Reconstructing the evolutionary history of paralogous APETALA1/FRUITFULL-like genes in grasses (Poaceae).The evolution of floral homeotic gene function.Cloning and expression analysis of a PISTILLATA homologous gene from pineapple (Ananas comosus L. Merr)Divergent regulatory OsMADS2 functions control size, shape and differentiation of the highly derived rice floret second-whorl organ.Rice plant development: from zygote to spikelet.Genetic basis for innovations in floral organ identity.Characterization and Functional Analysis of Five MADS-Box B Class Genes Related to Floral Organ Identification in Tagetes erecta
P2860
Q21266566-248FFC7F-3947-46CC-9DF9-707EF672537AQ28742065-40B219C9-5DAD-47CF-9844-2D14E1993EEBQ33335542-D4136AA5-2245-482D-919B-27A5E5EB4650Q33337441-29FF2CC1-93D1-4ABF-A71D-426DC83BB5CEQ33340139-560FF7F3-A6E5-4B03-A2A5-3AC39766EE21Q33341770-EE9640C3-099B-49BC-A077-2FB99D8F356FQ33342338-2DFC5BE0-EAA1-4D53-AC70-B66C0E84DF8CQ33344317-4A3A71CF-D41D-44AD-9760-153FDD576CF8Q33344631-E73AD2EF-EC2D-4A54-A0FF-C57FD2F04754Q33345665-C22524B4-7EE6-4CD4-8D09-CACE337998A6Q33345990-EB176055-1E64-429D-A334-4B7FFA42A241Q33346716-F3C0565D-6520-462E-8E2E-08427C5CD96DQ33347986-E8AFE54A-4158-40EB-B871-6AB747B269F7Q33348748-4C6ACC18-6014-4198-8738-95709BB07929Q33350888-A5B83A1E-4296-495C-902D-116A633E3B23Q33351841-7F3CBBE9-5325-4E1D-A5AC-8FB5CC183C7EQ33351917-B34B71DF-7965-456D-90B7-18945346330FQ33352351-9094CFE6-F843-4A80-ACC1-22E4472A2FE9Q33355403-BEACD90F-BC46-4AC1-BFF6-7C85B500D13BQ33359296-43F07C0C-A887-4882-B367-B35E28FEB285Q33363980-04BF0CBD-A881-4F6E-BFA7-7D56A4880350Q33364790-2402078C-0296-4E8E-952E-3B412AA47C8DQ33365233-03EA5F91-580F-4E5A-B67B-A02705DCC94FQ33526989-B8853BC8-06AD-4AAC-9790-8A2913D5D515Q33865498-C28CFFEF-9BBC-4014-B7E3-8C53B43EBD3AQ34043358-19228095-E1A5-43D5-AB5F-2300D387C3F5Q34072345-402BEE13-978E-48EE-B8B2-552EAC42CABAQ34430139-ACFA0165-EAD5-4E19-8705-25B167C1A480Q34619225-AABCB665-BDC8-4871-BB34-753E924BCC17Q34729405-DBD5CDA1-ACDB-4391-90E7-00D1270FCB6EQ34769930-97756BA2-A7A6-4E96-96A5-6D3E2D8BD9D3Q34962101-621A70DB-266C-41CB-924F-62AF7A0AA355Q35033646-CAA3429F-750F-4D99-8C8E-BC1AFB468719Q35038764-96AD44E2-697B-4C47-8633-0B0609A69E7EQ35158098-75CDE121-E0A8-452A-95B0-F485E0CB59AAQ35719568-95B73867-33F1-47E4-861C-6FA0DF87CADDQ35844813-9C77DE00-AC52-4E56-AA24-FAD5F0087CFAQ36014038-CF98AEF0-512A-4EC4-9C58-C04308A56909Q36120079-317D3785-34C0-4AEB-BD33-2F97258B1E6BQ36247661-3406C164-3B76-493F-BB42-B57FA5628B58
P2860
Spatially and temporally regulated expression of rice MADS box genes with similarity to Arabidopsis class A, B and C genes.
description
2000 nî lūn-bûn
@nan
2000 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2000 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2000年の論文
@ja
2000年論文
@yue
2000年論文
@zh-hant
2000年論文
@zh-hk
2000年論文
@zh-mo
2000年論文
@zh-tw
2000年论文
@wuu
name
Spatially and temporally regul ...... dopsis class A, B and C genes.
@ast
Spatially and temporally regul ...... dopsis class A, B and C genes.
@en
Spatially and temporally regul ...... dopsis class A, B and C genes.
@nl
type
label
Spatially and temporally regul ...... dopsis class A, B and C genes.
@ast
Spatially and temporally regul ...... dopsis class A, B and C genes.
@en
Spatially and temporally regul ...... dopsis class A, B and C genes.
@nl
prefLabel
Spatially and temporally regul ...... dopsis class A, B and C genes.
@ast
Spatially and temporally regul ...... dopsis class A, B and C genes.
@en
Spatially and temporally regul ...... dopsis class A, B and C genes.
@nl
P2093
P356
P1476
Spatially and temporally regul ...... dopsis class A, B and C genes.
@en
P2093
Kobayashi T
Shimamoto K
P304
P356
10.1093/PCP/41.6.710
P577
2000-06-01T00:00:00Z