Integration of light signaling with photoperiodic flowering and circadian rhythm

PLANT DE-ETIOLATION IS TRIGGERED BY LIGHT SIGNALS Light is arguably the most important resource for plants, and plants have evolved an array of photosensory pig- ments enabling them to develop optimally in a broad range of ambient light conditions. The ph…     

Timing of Photoperiodic Flowering:Light Perception and Circadian Clock

Flowering symbolizes the transition of a plant from vegetative phase to reproductive phase and is controlled by fairly complex and highly coordinated regulatory pathways. Over the last decade, genetic studies in Arabidopsis have aided the discovery of many signaling components involved in these pathways. In this review, we discuss how the timing of flowering is regulated by photoperiod and the involvement of light perception and the circadian clock in this process. The specific regulatory mechanisms on CONSTANS expression and CONSTANS stability by the circadian clock and photoreceptors are described in detail. In addition, the roles of CONSTANS, FLOWERING LOCUS T, and several other light signaling and circadiandependent components in photoperiodic flowering are also highlighted.     

Timing of Photoperiodic Flowering：Light Perception and Circadian Clock

Flowering symbolizes the transition of s plant from vegetative phase to reproductive phase and is controlled by fairly complex and highly coordinated regulatory pathways. Over the last decade, genetic studies in Arabidopsis have aided the discovery of many signaling components involved in these pathways. In this review, we discuss how the timing of flowering is regulated by photoperiod and the involvement of light perception and the circadian clock in this process. The specific regulatory mechanisms on CONSTANS expression and CONSTANS stability by the circadian clock and photoreceptors are described in detail. In addition, the roles of CONSTANS, FLOWERING LOCUS T, and several other light signaling and circadian-dependent components in photoperiodic flowering are also highlighted.     

Phytochrome control of hypocotyl extension in light-grown Chenopodium rubrum

The regulation of hypocotyl extension in light-grown Chenopodium rubrum L. seedlings by light analogous to dense vegetation canopy shade has been monitored. Hypocotyl extension was controlled by both the quantity and quality of the actinic light. At the higher of the two background photon fluence rates which were used (10.0 μmol m⁻²s⁻¹ in the 400–700 nm waveband), increasing the proportion of phytochrome calculated to exist as Pfr resulted in greater inhibition of growth. At the lower photon fluence rate (1.0 μmol m⁻²s⁻¹ in the 400–700 nm waveband), a biphasic response was observed in which minimum inhibition was observed at intermediate photoequilibria. Although photosynthesis was not directly involved in the photomorphogenetic responses, it did play an indirect quantitative role in determining the response.     

Light signaling in plants

Light signals have profound morphogenic effects on plant development. Signals perceived by the red/far‐red absorbing phytochrome family of photoreceptors and the blue/green/ UV‐A absorbing cryptochrome photoreceptor converge on a group of pleiotropic gene products defined by the COP/DET loci to control the pattern of development. The signaling pathway, although still undefined, includes several classic signaling molecules, such as G‐proteins, calcium, calmodulin, and cGMP. A separate signaling pathway is involved in the modulation of the phototropic response. Additional mutants have been identified that affect subsets of light signaling responses. This review provides an overview of our current understanding of the light signaling process, in particular recent genetic and biochemical advances.     

Coaction between phytochrome and blue/UV light in anthocyanin synthesis in seedlings

Light-mediated mass production of blue/UV absorbing pigments, anthocyanin and/or other flavonoid compounds, can be considered an adaptive mechanism to protect a plant against high levels of short wavelength sunlight. Comparative studies of light-mediated formation of anthocyanin in seedlings of higher plants have been performed. As a result of Darwinian evolution, a seedling may be expected to form considerable amounts of pigment only when necessary and only to the extent required for protection ('economy principle'). The four species investigated with regard to light-mediated synthesis of anthocyanin in seedlings (mustard, milo, tomato, wheat), differ greatly with regard to their photoperception. Phytochrome is involved in the photoresponse in all cases. We conclude that the P_fr-mediated differential gene activation leading to anthocyanin synthesis is the core of the response. However, the different species differ greatly with regard to the red, blue and UV light dependent processes they perform in order to establish sensitivity towards phytochrome (P_fr), or to amplify sensitivity towards P_fr.     

植物的光敏色素

光敏色素作为植物体内的一种光受体,在植物的光形态建成过程中意义重大,本文对光敏色素的分子特性,生理功能,作用方式及基因表达调控等方面的研究作系统的总结。     

Photosensory Perception and Signal Transduction in Higher Plants — Molecular Genetic Analysis

Light plays a crucial role throughout the life cycle of higher plants modulating various aspects of their growth and development, such as seed germination, leaf differentiation, flowering, and senescence. Plants have thus evolved extremely sensitive mechanisms to continually detect the changing ambient light conditions and transduce the information to the gene expression machinery. The elucidation of this complex information sensing and transduction machinery is fundamental to our understanding of the molecular mechanisms involved in light-regulated plant development. The last decade has witnessed an immense upsurge in information in this regard and the mechanism of photosensory perception and phototransduction is turning out to be quite intricate, involving an array of cellular effectors and biochemical messengers. The analysis of photomorphogenic mutants, predominantly of Arabidopsis, has revealed interesting facts, not only about the intricacies of light signaling circuitry, but also about the multiplicity of the photoreceptors and their specialized or overlapping photosensory functions. In addition, these studies have also highlighted, and in some cases even redefined, the role of conventional plant growth regulators in modulating photomorphogenic development. Employing standard recombinant DNA techniques, substantial information has also become available about the regulatory cis-acting DNA sequences that make a gene amenable to light control and the trans-acting protein factors that can potentially interact with these cis-acting sequences on receiving the signal from the upstream transduction components. The information available to date on these emerging trends in photomorphogenesis research has been summarized and critically evaluated in this review.     

Examination of Phycomyces blakesleeanus for nitrate reductase as a possible blue light photoreceptor

Phycomyces blakesleeanus is unable to grow on media which contain nitrate as the sole nitrogen source. Further, according to a number of assay procedures, there is no significant nitrate reductase activity in Phycomyces. Thus, although nitrate reductase has been proposed to be a blue-light receptor in Neurospora, no active nitrate reductase is available to serve this function in Phycomyces.     

蓝光对水稻幼苗生长及内源激素水平的影响

研究表明：与白光对照相比,蓝光明显抑制水稻幼苗的生长,并使幼苗体内的自由态IAA、GA1、玉米素和二氢玉米素含量下降,ABA含量和乙烯释放量则明显增加。说明蓝光对水稻幼苗生长的影响与其体内激素状况有关。     

The photoreceptors in the high irradiance response of plants

Several studies show that the high irradiance response (HIR) of plants is probably due to two photoreceptors. One of the photoreceptors is phytochrome, and the other is an unidentified pigment provisionally named heliochrome. One of the functions of heliochrome is the synthesis of phytochrome, using far-red and blue radiations of high intensities, to replace the phytochrome destroyed by light. Another possible function could be an interaction of heliochrome with a substance produced by phytochrome. The data presented show that heliochrome is a pigment with different properties from phytochrome. It shows a far-red/green reversibility. Heliochrome has been shown to participate with phytochrome in such HIRs as leaf movement in Albizzia and flowering in a long-day plant. The first event initiated by phytochrome and by heliochrome could be the generation of a strong positive, electrostatic charge in the cell membrane.     

Novel light-activated protein kinases as key regulators of plant growth and development

Plants have evolved highly sensitive sensory photoreceptor systems to regulate various aspects of their growth and development. Many responses such as seed germination, flowering and dormancy are controlled by red and far-red regions of the solar spectrum through the phytochrome family of photoreceptors. However, several other responses such as stem growth inhibition, phototropism and opening of stomata are controlled by blue and/or ultraviolet light absorbing photoreceptors called cryptochromes and phototropin. Despite their central role in plant biology, the mode of action of these photoreceptors has been shrouded in mystery. Even the biochemical isolation of a photoreceptor, as in the case of phytochrome was accomplished decades ago, did not help in elucidating the mechanism of action. Nevertheless, due to advances in recombinant DNA technology, generation of extensive databanks and the capability to predict function by base sequence analysis, a breakthrough has now come about. It is clear that certain phytochromes, at least in the cyanobacteria and algae which represent the simplest plants, are hybrid photoreceptor-cum-kinases. These novel kinases utilize captured photons rather than conventional ligands to trigger conformational change and in consequence enzyme activity. The kinases apparently, then, cause phosphorylation of many other types of target molecules, leading eventually to various developmental changes. There is suggestive evidence that in higher plants, too, at least some phytochromes may operate as kinases. As compared to work on phytochromes, the blue light photoreceptors have begun to be studied only recently. However, the exciting discovery has been made of at least one photoactive kinase that is critically required for phototropism. This article summarizes the above discoveries from the perspective of general biology. Dedicated to the memory of Drs Harry Borthwick, Sterling Hendricks and James Bonner whose classical studies paved the way for modern researches on mechanism of action of plant photoreceptors and whom the senior author was previleged to know.     

KIDARI, Encoding a Non-DNA Binding bHLH Protein, Represses Light Signal Transduction in Arabidopsis thaliana

Through activation tagging mutagenesis, we isolated a kidari-D (kdr-D) mutant, which exhibited a defect in blue and far-red light mediated photomorphogenesis. Under continuous blue light, the kdr-D mutant showed long hypocotyl phenotype, whereas it showed normal cotyledon opening and expansion. In addition, the kdr-D showed slightly longer hypocotyl under continuous far-red light, suggesting that KDR functions in a branch of cry signaling and mediates a cross-talk between cry and phyA. In the kdr-D mutant, a gene encoding a putative basic/Helix-Loop-Helix (bHLH) protein was overexpressed by the insertion of 35S enhancer into 10 kb upstream of the gene. Consistently, overexpression of this gene recapitulated the phenotype of kdr-D. KDR is composed of 94 amino acids with non-DNA binding HLH domain, a structure found in human Inhibitor of DNA binding 1 (Id-1) which functions as a negative regulator of bHLH proteins through heterodimerization with them. The KDR specifically interacted with HFR1, a bHLH protein regulating photomorphogenesis, in yeast two hybrid assay and the kdr-D was epistatic to 35S::HFR1 in the hypocotyl phenotype. Thus, it shows that KDR functions as a negative regulator of HFR1, similar to Id-1 in human. The KDR exhibited circadian expression pattern with an increase during the day. Taken together, our results suggest that KDR attenuates light mediated responses in day light condition through inhibition of the activity of bHLH proteins involved in light signaling.     

Mutational analysis of blue-light sensing in Arabidopsis

Blue light regulates many physiological and developmental processes in higher plants through the action of multiple photosensory systems. The analysis of photomorphogenic mutants is leading to a better understanding of how the different photosensory systems mediate the wide range of responses observed in blue light. A review of the current literature on photomorphogenic mutants makes it apparent that redundancies exist in photoreceptor function. For example, many blue-light responses that have been shown to be regulated by a blue-light photosensory system are also under phytochrome control. The study of various light-response mutants suggests that a complex sensory network regulates light-mediated responses. This article attempts to piece together information regarding the sensory systems responsible for blue-light-regulated responses.