The phytochrome gene family in grasses (Poaceae): a phylogeny and evidence that grasses have a subset of the loci found in dicot angiosperms.
about
New grass phylogeny resolves deep evolutionary relationships and discovers C4 originsRelationships of cereal crops and other grassesComparative sequence analysis of the phytochrome C gene and its upstream region in allohexaploid wheat reveals new data on the evolution of its three constituent genomes.Structure and expression of maize phytochrome family homeologs.Pervasive survival of expressed mitochondrial rps14 pseudogenes in grasses and their relatives for 80 million years following three functional transfers to the nucleus.Subfunctionalization of PhyB1 and PhyB2 in the control of seedling and mature plant traits in maize.Transcriptome Profiling of Tiller Buds Provides New Insights into PhyB Regulation of Tillering and Indeterminate Growth in Sorghum.The phytochrome B/phytochrome C heterodimer is necessary for phytochrome C-mediated responses in rice seedlingsIdentification of Hybrids in Potamogeton: Incongruence between Plastid and ITS Regions Solved by a Novel Barcoding Marker PHYB.Variation in Copy Number of Ty3/Gypsy Centromeric Retrotransposons in the Genomes of Thinopyrum intermedium and Its Diploid Progenitors.Phytochrome-mediated development in land plants: red light sensing evolves to meet the challenges of changing light environments.Analysis of Three Sugarcane Homo/Homeologous Regions Suggests Independent Polyploidization Events of Saccharum officinarum and Saccharum spontaneum.The tricks plants use to reach appropriate light.Enhancing the productivity of grasses under high-density planting by engineering light responses: from model systems to feedstocks.Reticulate evolution in diploid and tetraploid species of Polystachya (Orchidaceae) as shown by plastid DNA sequences and low-copy nuclear genes.Low red/far-red ratios delay spike and stem growth in wheatChlorophyll deficiency in the maize elongated mesocotyl2 mutant is caused by a defective heme oxygenase and delaying grana stackingEvolutionary divergence of phytochrome protein function in Zea mays PIF3 signaling.Plastid genome evolution in mycoheterotrophic Ericaceae.Structural characterization, expression analysis and evolution of the red/far-red sensing photoreceptor gene, phytochrome C (PHYC), localized on the 'B' genome of hexaploid wheat (Triticum aestivum L.).Reducing shade avoidance responses in a cereal crop.Molecular evolution of phytochromes in Cardamine nipponica (Brassicaceae) suggests the involvement of PHYE in local adaptation.Elongated mesocotyl1, a phytochrome-deficient mutant of maize.The phytochrome gene family in soybean and a dominant negative effect of a soybean PHYA transgene on endogenous Arabidopsis PHYA.Phytochrome B represses Teosinte Branched1 expression and induces sorghum axillary bud outgrowth in response to light signals.The Elm1 (ZmHy2) gene of maize encodes a phytochromobilin synthase.Light-regulated overexpression of an Arabidopsis phytochrome A gene in rice alters plant architecture and increases grain yield.Phylogenetics, divergence times and diversification from three genomic partitions in monocotsThe age of the grasses and clusters of origins of C4photosynthesisCanopy Light Signals and Crop Yield in Sickness and in Health
P2860
Q27659368-92052E86-63CA-40D8-893C-FE772739EEA1Q28776222-051F472A-5E5C-4DE4-BA7B-25E77AC454CDQ31004435-A4057E20-7A94-41EA-AFAB-ED0FB482EF9CQ33205260-B47AAA46-7610-4776-9C38-FF11EA09BBEBQ33250261-2A36857F-2D28-4F57-9C95-A9B4B00AB405Q33343560-551A1B16-03E2-48C1-A732-7AA04523DBEDQ33362616-73DEA5DB-EAFC-4605-89E4-3FDD2FC6F5E9Q33650154-295C125B-75E7-4D12-A86F-EF5CE1B1AA5BQ34544888-4C2E30F2-4A13-4D49-B77D-23EA4750DDF9Q36000609-F2FBA2F5-4CB3-4BA8-B699-1599435BF4C0Q36619649-B1A84E11-C75B-4A2F-AE1F-69960AA33FF3Q37738669-56A93C01-9A17-4592-BAA3-CD3CA15188DCQ37785868-29653ABF-4016-484A-BB09-1CF4777AEEDFQ38215490-A086EDA4-7394-4939-A38A-C5261629890EQ41283181-A8E24505-205D-469F-87B4-29B8BD3C4971Q41455418-3A2D2FFF-24B4-4CE7-96D9-013C488928E1Q41807291-8DFF1EED-9941-48EB-B657-3C223306F49FQ41958063-F21093A0-D0A7-48ED-8A93-A9364B7BED18Q42641137-A5E275CB-760D-4DBB-9688-BBF4CF4596FBQ42656378-3CAFE97C-955D-4951-86B7-CFD7C4021262Q42659238-C1C3E43F-E7C4-4560-916A-CF55B230615EQ43117046-1AF4C6FB-1462-43E8-8665-96CDC712E9BBQ44133948-03481620-F8B1-46A3-90C4-F0F653BA3AC1Q44822073-38A24DD8-1625-4ECC-A8BC-4FA9679AF49FQ48102291-6A67F338-B97E-48F2-88FF-A5BFAB4FFD4DQ48174547-77D9C6FA-6ABD-41E6-BCCA-5E84769C8006Q50756293-FDF1BC7A-E7B8-43A4-A345-BFC0BA266F7AQ55871724-85FDF111-626A-43E6-BA0C-3D13245924A2Q58044914-F71266F2-32ED-46EB-BFE5-C287494074BCQ58998086-5E676EF4-C4C6-4991-A6D3-633E297F949C
P2860
The phytochrome gene family in grasses (Poaceae): a phylogeny and evidence that grasses have a subset of the loci found in dicot angiosperms.
description
1996 nî lūn-bûn
@nan
1996年の論文
@ja
1996年学术文章
@wuu
1996年学术文章
@zh
1996年学术文章
@zh-cn
1996年学术文章
@zh-hans
1996年学术文章
@zh-my
1996年学术文章
@zh-sg
1996年學術文章
@yue
1996年學術文章
@zh-hant
name
The phytochrome gene family in ...... ci found in dicot angiosperms.
@en
The phytochrome gene family in grasses
@nl
type
label
The phytochrome gene family in ...... ci found in dicot angiosperms.
@en
The phytochrome gene family in grasses
@nl
prefLabel
The phytochrome gene family in ...... ci found in dicot angiosperms.
@en
The phytochrome gene family in grasses
@nl
P1476
The phytochrome gene family in ...... ci found in dicot angiosperms.
@en
P2093
R A Sharrock
P304
P356
10.1093/OXFORDJOURNALS.MOLBEV.A025677
P577
1996-10-01T00:00:00Z