Cryptochrome 1 and phytochrome B control shade - avoidance responses in Arabidopsis via partially independent hormonal cascades

Summary Plants respond to a reduction in the red/far-red ratio [R:FR] of light, caused by the proximity of other plants, by initiating morphological changes that improve light capture. In Arabidopsis, this response [shade avoidance syndrome, SAS] is controlled by phytochromes [particularly phyB], an...

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Detalles Bibliográficos
Otros Autores: Keller, Mercedes M., Jaillais, Yvon, Pedmale, Ullas V., Moreno, Javier E., Chory, Joanne, Ballaré, Carlos Luis
Formato: Artículo
Lenguaje:Inglés
Materias:
BLUE LIGHT
BRASSINOSTEROID
DELLA
PHYTOCHROME INTERACTING FACTORS [PIFS]
PIN3
TRYPTOPHAN AMINOTRANSFERASE OF ARABIDOPSIS 1
AMINOTRANSFERASE
BRASSINOSTEROIDS
PHYTOCHROME-INTERACTING FACTORS
AMINO ACIDS
BIOCHEMISTRY
ELECTROMAGNETIC WAVE ATTENUATION
SIGNALING
TRANSCRIPTION FACTORS
BIOSYNTHESIS
ARABIDOPSIS PROTEIN
BASIC HELIX LOOP HELIX TRANSCRIPTION FACTOR
CRY1 PROTEIN, ARABIDOPSIS
CRYPTOCHROME
INDOLEACETIC ACID DERIVATIVE
PHYB PROTEIN, ARABIDOPSIS
PHYTOCHROME B
PIF4 PROTEIN, ARABIDOPSIS
PIF5 PROTEIN, ARABIDOPSIS
ARABIDOPSIS
GENE EXPRESSION REGULATION
GENETICS
GROWTH, DEVELOPMENT AND AGING
LIGHT
METABOLISM
MUTATION
PHYSIOLOGY
PLANT LEAF
RADIATION EXPOSURE
SIGNAL TRANSDUCTION
ARABIDOPSIS PROTEINS
BASIC HELIX-LOOP-HELIX TRANSCRIPTION FACTORS
CRYPTOCHROMES
GENE EXPRESSION REGULATION, PLANT
INDOLEACETIC ACIDS
PLANT LEAVES
Acceso en línea:http://ri.agro.uba.ar/files/intranet/articulo/2011Keller.pdf
LINK AL EDITOR
Aporte de:Registro referencial: Solicitar el recurso aquí
Biblioteca Central (FAUBA) de Universidad de Buenos Aires
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022 |a 1365-313X (en línea) 
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024 |a 10.1111/j.1365-313X.2011.04598.x 
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245 1 0 |a Cryptochrome 1 and phytochrome B control shade - avoidance responses in Arabidopsis via partially independent hormonal cascades 
520 |a Summary Plants respond to a reduction in the red/far-red ratio [R:FR] of light, caused by the proximity of other plants, by initiating morphological changes that improve light capture. In Arabidopsis, this response [shade avoidance syndrome, SAS] is controlled by phytochromes [particularly phyB], and is dependent on the TAA1 pathway of auxin biosynthesis. However, when grown in real canopies, we found that phyB mutants and mutants deficient in TAAI [sav3] still display robust SAS responses to increased planting density and leaf shading. The SAS morphology [leaf hyponasty and reduced lamina/petiole ratio] could be phenocopied by exposing plants to blue light attenuation. These responses to blue light attenuation required the UV-A/blue light photoreceptor cry1. Moreover, they were mediated through mechanisms that showed only limited overlap with the pathways recruited by phyB inactivation. In particular, pathways for polar auxin transport, auxin biosynthesis and gibberellin signaling that are involved in SAS responses to low R:FR were not required for the SAS responses to blue light depletion. By contrast, the brassinosteroid response appeared to be required for the full expression of the SAS phenotype under low blue light. The phyB and cry1 inactivation pathways appeared to converge in their requirement for the basic/helix-loop-helix [bHLH] transcription factors PHYTOCHROME INTERACTING FACTORs 4 and 5 [PIF4 and PIF5] to elicit the SAS phenotype. Our results suggest that blue light is an important control of SAS responses, and that PIF4 and PIF5 are critical hubs for a diverse array of signaling routes that control plant architecture in canopies. 
650 |2 Agrovoc  |9 26 
653 0 |a BLUE LIGHT 
653 0 |a BRASSINOSTEROID 
653 0 |a DELLA 
653 0 |a PHYTOCHROME INTERACTING FACTORS [PIFS] 
653 0 |a PIN3 
653 0 |a TRYPTOPHAN AMINOTRANSFERASE OF ARABIDOPSIS 1 
653 0 |a AMINOTRANSFERASE 
653 0 |a BRASSINOSTEROIDS 
653 0 |a PHYTOCHROME-INTERACTING FACTORS 
653 0 |a AMINO ACIDS 
653 0 |a BIOCHEMISTRY 
653 0 |a ELECTROMAGNETIC WAVE ATTENUATION 
653 0 |a SIGNALING 
653 0 |a TRANSCRIPTION FACTORS 
653 0 |a BIOSYNTHESIS 
653 0 |a ARABIDOPSIS PROTEIN 
653 0 |a BASIC HELIX LOOP HELIX TRANSCRIPTION FACTOR 
653 0 |a CRY1 PROTEIN, ARABIDOPSIS 
653 0 |a CRYPTOCHROME 
653 0 |a INDOLEACETIC ACID DERIVATIVE 
653 0 |a PHYB PROTEIN, ARABIDOPSIS 
653 0 |a PHYTOCHROME B 
653 0 |a PIF4 PROTEIN, ARABIDOPSIS 
653 0 |a PIF5 PROTEIN, ARABIDOPSIS 
653 0 |a ARABIDOPSIS 
653 0 |a GENE EXPRESSION REGULATION 
653 0 |a GENETICS 
653 0 |a GROWTH, DEVELOPMENT AND AGING 
653 0 |a LIGHT 
653 0 |a METABOLISM 
653 0 |a MUTATION 
653 0 |a PHYSIOLOGY 
653 0 |a PLANT LEAF 
653 0 |a RADIATION EXPOSURE 
653 0 |a SIGNAL TRANSDUCTION 
653 0 |a ARABIDOPSIS PROTEINS 
653 0 |a BASIC HELIX-LOOP-HELIX TRANSCRIPTION FACTORS 
653 0 |a CRYPTOCHROMES 
653 0 |a GENE EXPRESSION REGULATION, PLANT 
653 0 |a INDOLEACETIC ACIDS 
653 0 |a PLANT LEAVES 
700 1 |a Keller, Mercedes M.  |9 67355 
700 1 |a Jaillais, Yvon  |9 72232 
700 1 |a Pedmale, Ullas V.  |9 72233 
700 1 |a Moreno, Javier E.  |9 68555 
700 1 |a Chory, Joanne  |9 72234 
700 1 |a Ballaré, Carlos Luis  |9 672 
773 |t The Plant Journal  |g Vol.67, no.2 (2011), p.195-207 
856 |u http://ri.agro.uba.ar/files/intranet/articulo/2011Keller.pdf  |i En reservorio  |q application/pdf  |f 2011Keller  |x MIGRADOS2018 
856 |u http://www.wiley.com/  |x MIGRADOS2018  |z LINK AL EDITOR 
942 0 0 |c ARTICULO 
942 0 0 |c ENLINEA 
976 |a AAG 

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