about
Setting the PAS, the role of circadian PAS domain proteins during environmental adaptation in plantsPIFs get BRright: PHYTOCHROME INTERACTING FACTORs as integrators of light and hormonal signalsNpR3784 is the prototype for a distinctive group of red/green cyanobacteriochromes using alternative Phe residues for photoproduct tuning.From photon to signal in phytochromes: similarities and differences between prokaryotic and plant phytochromes.Engineering of a red-light-activated human cAMP/cGMP-specific phosphodiesterase.Phytochrome C plays a major role in the acceleration of wheat flowering under long-day photoperiod.Chloroplasts extend stromules independently and in response to internal redox signalsThree cyanobacteriochromes work together to form a light color-sensitive input system for c-di-GMP signaling of cell aggregation.Holophytochrome-Interacting Proteins in Physcomitrella: Putative Actors in Phytochrome Cytoplasmic Signaling.The room temperature crystal structure of a bacterial phytochrome determined by serial femtosecond crystallography.Structural photoactivation of a full-length bacterial phytochrome.Light-induced structural changes in a monomeric bacteriophytochrome.Eukaryotic algal phytochromes span the visible spectrumPhototropism: some history, some puzzles, and a look ahead.Clues to the functions of plant NDPK isoforms.Structural and Vibrational Characterization of the Chromophore Binding Site of Bacterial Phytochrome Agp1.Bioarchitecture: bioinspired art and architecture--a perspective.Arabidopsis thaliana FAR-RED ELONGATED HYPOCOTYLS3 (FHY3) and FAR-RED-IMPAIRED RESPONSE1 (FAR1) modulate starch synthesis in response to light and sugar.Xanthomonas campestris attenuates virulence by sensing light through a bacteriophytochrome photoreceptor.Identification of DXCF cyanobacteriochrome lineages with predictable photocycles.There and Back Again: Loss and Reacquisition of Two-Cys Photocycles in Cyanobacteriochromes.PHYTOCHROME INTERACTING FACTORs from Physcomitrella patens are active in Arabidopsis and complement the pif quadruple mutant.A Constitutively Active Allele of Phytochrome B Maintains Circadian Robustness in the Absence of Light.Directed dimerization: an in vivo expression system for functional studies of type II phytochromes.Light Controls Cytokinin Signaling via Transcriptional Regulation of Constitutively Active Sensor Histidine Kinase CKI1.Characterization of Phytochrome Interacting Factors from the Moss Physcomitrella patens Illustrates Conservation of Phytochrome Signaling Modules in Land Plants.Common Structural Elements in the Chromophore Binding Pocket of the Pfr State of Bathy Phytochromes.Lipid anchoring of Arabidopsis phototropin 1 to assess the functional significance of receptor internalization: should I stay or should I go?Upgrading a microplate reader for photobiology and all-optical experiments.phyA-GFP is spectroscopically and photochemically similar to phyA and comprises both its native types, phyA' and phyA''.Structural communication between the chromophore-binding pocket and the N-terminal extension in plant phytochrome phyB.3D Structures of Plant Phytochrome A as Pr and Pfr From Solid-State NMR: Implications for Molecular Function.
P2860
Q26798441-9675E4E7-4F56-46E9-8C68-71C00F8FD8FBQ27014884-AB6AE891-EA40-43DB-985B-A79A4D98A513Q30368081-DC95130C-31CB-4D13-A630-545C0A81918BQ30383936-C7FF44A6-923E-4E75-99A1-DEC227CB401DQ33789962-250B6A06-47A5-41BF-A2D8-052D03423C1AQ33925741-5C019AD3-AA79-430A-892E-C47409E8EA9FQ34483810-32427626-905B-41F0-8FBD-1D9D3645FC40Q35818825-3ABD23E3-7528-4A33-8AAC-13EA53A5CDA6Q36034566-5AB2FCB6-75F8-49D2-959E-5E53A6B93B30Q36167148-197E4E0B-9E88-4A89-927B-3F0A1155608CQ37170911-6A9312E4-BC66-4EED-A986-D4C3FC9914ACQ37230497-B52C718A-9FA1-4543-BAA2-3975C4574159Q37640884-E4B09296-433D-44CB-B909-09E0F0F18AA8Q38176595-872D98D1-20D9-4345-B519-E01F5D64885FQ38223225-7133349E-27BF-4579-9C82-E5F143CE3667Q38788321-4D0B0085-4C6A-4E3E-B173-70894ABC65E9Q38880338-72FD0820-16DE-45C3-9CDE-946CE4DE9A4BQ39177619-16A923B5-758E-4179-A5E2-7D80EBE790D7Q40469154-DBCFF090-E08D-409C-B001-87E6A281C812Q41299812-9418EBB8-5B4A-4AC0-812A-00F39DD6B659Q44681691-31D81F00-1D4C-4031-9D75-D4547329F2DAQ46292768-CC879363-AA71-4195-B00F-480048E00B73Q46431898-EA6BF3D9-F85E-4C2E-B6AB-7BB289AABCC5Q48039074-222E69ED-2C1F-4E66-A119-9B807F4116E0Q48129974-23AB4C6B-FD12-41BF-AB9C-924FE2424BAAQ48310948-06B23B09-1CDE-4162-882B-74F986C9BEEAQ50207389-C473D459-41C5-41BA-919B-B270531C11B4Q50217880-92BE90F0-A272-4FE2-9D87-15A353C66BE0Q50220722-7EE6BF12-BA36-474B-A1DC-6A63D941AA20Q50448182-4D60D822-F389-4859-90B1-719D1B31969DQ51071944-C449B79E-B065-40E2-9286-37A30A2816F6Q55280970-1AECA7EB-E00F-4409-9BB5-BC0A1FCC96FF
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Phytochrome cytoplasmic signaling.
@en
type
label
Phytochrome cytoplasmic signaling.
@en
prefLabel
Phytochrome cytoplasmic signaling.
@en
P1476
Phytochrome cytoplasmic signaling.
@en
P2093
Jon Hughes
P304
P356
10.1146/ANNUREV-ARPLANT-050312-120045
P577
2013-03-13T00:00:00Z