<i>Arabidopsis</i>
            nph1 and npl1: Blue light receptors that mediate both phototropism and chloroplast relocation

Sakai, Tatsuya; Kagawa, Takatoshi; Kasahara, Masahiro; Swartz, Trevor E.; Christie, John M.; Briggs, Winslow R.; Wada, Masamitsu; Okada, Kiyotaka

doi:10.1073/pnas.101137598

Cited by 663 publications

(757 citation statements)

References 30 publications

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“…To test whether light perception by these photoreceptors is required for P. syringae-induced defense responses and disease resistance, we examined the interactions of the following Arabidopsis double mutants impaired in either cryptochrome, phototropin, or phytochrome photoperception, with an avirulent (Psm avrRpm1) or a virulent strain (Psm) of P. syringae pv. maculicola: cry1cry2 (cry1-304 cry2-1; Mockler et al, 1999), phot1phot2 (phot1-5 phot2-1; Sakai et al, 2001), and phyAphyB (phyA-211 phyB-9; Cerdán and Chory, 2003). Common genetic background for all examined mutants is accession Col (Col-0 for cry1cry2 and phyAphyB; Col-3 for phot1phot2), implicating that each line harbors the resistance gene Rpm1 whose product recognizes the bacterial avirulence protein AvrRpm1.…”

Section: Photoreceptor Signaling Only Moderately Affects Induction Ofmentioning

confidence: 99%

Light Regulation and Daytime Dependency of Inducible Plant Defenses in Arabidopsis: Phytochrome Signaling Controls Systemic Acquired Resistance Rather Than Local Defense

2008

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We have examined molecular and physiological principles underlying the light dependency of defense activation in Arabidopsis (Arabidopsis thaliana) plants challenged with the bacterial pathogen Pseudomonas syringae. Within a fixed light/dark cycle, plant defense responses and disease resistance significantly depend on the time of day when pathogen contact takes place. Morning and midday inoculations result in higher salicylic acid accumulation, faster expression of pathogenesis-related genes, and a more pronounced hypersensitive response than inoculations in the evening or at night. Rather than to the plants' circadian rhythm, this increased plant defense capability upon day inoculations is attributable to the availability of a prolonged light period during the early plant-pathogen interaction. Moreover, pathogen responses of Arabidopsis double mutants affected in light perception, i.e. cryptochrome1cryptochrome2 (cry1cry2), phototropin1phototropin2 (phot1phot2), and phytochromeAphytochromeB (phyAphyB) were assessed. Induction of defense responses by either avirulent or virulent P. syringae at inoculation sites is relatively robust in leaves of photoreceptor mutants, indicating little cross talk between local defense and light signaling. In addition, the blue-light receptor mutants cry1cry2 and phot1phot2 are both capable of establishing a full systemic acquired resistance (SAR) response. Induction of SAR and salicylic-acid-dependent systemic defense reactions, however, are compromised in phyAphyB mutants. Phytochrome regulation of SAR involves the essential SAR component FLAVIN-DEPENDENT MONOOXYGENASE1. Our findings highlight the importance of phytochrome photoperception during systemic rather than local resistance induction. The phytochrome system seems to accommodate the supply of light energy to the energetically costly increase in whole plant resistance.

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Section: Photoreceptor Signaling Only Moderately Affects Induction Ofmentioning

confidence: 99%

Light Regulation and Daytime Dependency of Inducible Plant Defenses in Arabidopsis: Phytochrome Signaling Controls Systemic Acquired Resistance Rather Than Local Defense

2008

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“…Mutants of Arabidopsis impaired in hypocotyl phototropism were isolated (Khurana and Poff, 1989;Liscum and Briggs, 1996), and molecular genetic analysis of these mutants has lead to the discovery of novel proteins that participate in the early process of phototropism. Most importantly, phototropin 1 (phot1) was uncovered as the major photoreceptor for phototropism (Huala et al, 1997) and phototropin 2 (phot2) as an additional photoreceptor that functions at high fluence rates (Sakai et al, 2001) (for the receptor nomenclature, see Briggs et al, 2001). The protein NPH3 was identified as a signaling component that is essential for hypocotyl phototropism and probably functions by directly interacting with phot1 (Motchoulski and Liscum, 1999).…”

Section: Introductionmentioning

confidence: 99%

The Rice COLEOPTILE PHOTOTROPISM1 Gene Encoding an Ortholog of Arabidopsis NPH3 Is Required for Phototropism of Coleoptiles and Lateral Translocation of Auxin

et al. 2005

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We isolated a mutant, named coleoptile phototropism1 (cpt1), from g-ray-mutagenized japonica-type rice (Oryza sativa). This mutant showed no coleoptile phototropism and severely reduced root phototropism after continuous stimulation. A map-based cloning strategy and transgenic complementation test were applied to demonstrate that a NPH3-like gene deleted in the mutant corresponds to CPT1. Phylogenetic analysis of putative CPT1 homologs of rice and related proteins indicated that CPT1 has an orthologous relationship with Arabidopsis thaliana NPH3. These results, along with those for Arabidopsis, demonstrate that NPH3/CPT1 is a key signal transduction component of higher plant phototropism. In an extended study with the cpt1 mutant, it was found that phototropic differential growth is accompanied by a CPT1-independent inhibition of net growth. Kinetic investigation further indicated that a small phototropism occurs in cpt1 coleoptiles. This response, induced only transiently, was thought to be caused by the CPT1-independent growth inhibition. The 3 H-indole-3-acetic acid applied to the coleoptile tip was asymmetrically distributed between the two sides of phototropically responding coleoptiles. However, no asymmetry was induced in cpt1 coleoptiles, indicating that lateral translocation of auxin occurs downstream of CPT1. It is concluded that the CPT1-dependent major phototropism of coleoptiles is achieved by lateral auxin translocation and subsequent growth redistribution.

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“…Its potential role as the second phototropic receptor was cemented when Sakai and colleagues (2001) determined that phot1phot2 double mutants lack phototropic response in both low and high fluence rate blue light. However, phot2 single mutants retained an essentially wildtype response under all fluence rates tested (Sakai et al, 2001). It was therefore concluded that phot1 and phot2 function redundantly as high light receptors, while phot1 acts as the low-light photoreceptor (Sakai et al, 2001).…”

Section: Saw the Lightmentioning

confidence: 99%

“…However, phot2 single mutants retained an essentially wildtype response under all fluence rates tested (Sakai et al, 2001). It was therefore concluded that phot1 and phot2 function redundantly as high light receptors, while phot1 acts as the low-light photoreceptor (Sakai et al, 2001). The phototropins are members of a larger family of sensor proteins known as the LOV domain family (Crosson et al, 2003).…”

Section: Saw the Lightmentioning

confidence: 99%

Plant tropisms: providing the power of movement to a sessile organism

Esmon¹,

Pedmale²,

Liscum³

2005

Int. J. Dev. Biol.

108

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In an attempt to compensate for their sessile nature, plants have developed growth responses to deal with the copious and rapid changes in their environment. These responses are known as tropisms and they are marked by a directional growth response that is the result of differential cellular growth and development in response to an external stimulation such as light, gravity or touch. While the mechanics of tropic growth and subsequent development have been the topic of debate for more than a hundred years, only recently have researchers been able to make strides in understanding how plants perceive and respond to tropic stimulations, thanks in large part to mutant analysis and recent advances in genomics. This paper focuses on the recent advances in four of the best-understood tropic responses and how each affects plant growth and development: phototropism, gravitropism, thigmotropism and hydrotropism. While progress has been made in deciphering the events between tropic stimulation signal perception and each characteristic growth response, there are many areas that remain unclear, some of which will be discussed herein. As has become evident, each tropic response pathway exhibits distinguishing characteristics. However, these pathways of tropic perception and response also have overlapping components -a fact that is certainly related to the necessity for pathway integration given the everchanging environment that surrounds every plant.

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Arabidopsis nph1 and npl1: Blue light receptors that mediate both phototropism and chloroplast relocation

Cited by 663 publications

References 30 publications

Light Regulation and Daytime Dependency of Inducible Plant Defenses in Arabidopsis: Phytochrome Signaling Controls Systemic Acquired Resistance Rather Than Local Defense

Light Regulation and Daytime Dependency of Inducible Plant Defenses in Arabidopsis: Phytochrome Signaling Controls Systemic Acquired Resistance Rather Than Local Defense

The Rice COLEOPTILE PHOTOTROPISM1 Gene Encoding an Ortholog of Arabidopsis NPH3 Is Required for Phototropism of Coleoptiles and Lateral Translocation of Auxin

Plant tropisms: providing the power of movement to a sessile organism

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