Cryptochromes: Photochemical and structural insight into magnetoreception

Cryptochromes (CRYs) function as blue light photoreceptors in diverse physiological processes in nearly all kingdoms of life. Over the past several decades, they have emerged as the most likely candidates for light‐dependent magnetoreception in animals, however, a long history of conflicts between in vitro photochemistry and in vivo behavioral data complicate validation of CRYs as a magnetosensor. In this review, we highlight the origins of conflicts regarding CRY photochemistry and signal transduction, and identify recent data that provides clarity on potential mechanisms of signal transduction in magnetoreception. The review primarily focuses on examining differences in photochemistry and signal transduction in plant and animal CRYs, and identifies potential modes of convergent evolution within these independent lineages that may identify conserved signaling pathways.     

Phytochrome phosphorylation in plant light signaling.

Reversible protein phosphorylation is a switching mechanism used in eukaryotes to regulate various cellular signalings. In plant light signaling, sophisticated photosensory receptor systems operate to modulate growth and development. The photoreceptors include phytochromes, cryptochromes and phototropins. Despite considerable progresses in defining the photosensory roles of these photoreceptors, the primary biochemical mechanisms by which the photoreceptor molecules transduce the perceived light signals into cellular responses remain to be elucidated. The signal-transducing photoreceptors in plants are all phosphoproteins and/or protein kinases, suggesting that light-dependent protein phosphorylation and dephosphorylation play important roles in the function of the photoreceptors. This review focuses on the role of phytochromes' reversible phosphorylation involved in the light signal transduction in plants.     

Action and function of phytochrome family members revealed through the study of mutant and transgenic plants

The adaptation of plant growth and development to changes in the light environment is dependent upon photoperception by information transducing photoreceptors. The red/far-red light-absorbing phytochromes are perhaps the best characterized of these regulatory photoreceptors. Higher plants possess multiple, discrete phytochromes, the apoprotein components of which are the products of a small, divergent gene family. Different phytochromes have different biochemical and physiological properties, and are differentially expressed in the growing plant. This has led to the proposal that different phytochromes have different physiological roles. Mutations that disrupt the normal perception of light signals have proved to be a valuable resource in assigning physiological roles to different phytochromes as well as in identifying residues/domains critical for phytochrome function and in attempting to elucidate the signal transduction pathway(s) downstream of phytochromes. This article reviews some recent progress in these areas from the study of conventional and transgenic photomorphogenic mutants.     

Genetic and molecular analysis of light-regulated plant development

Light regulates many physiological and developmental events in plants through the action of multiple sensory pigment systems. Although our understanding of the regulatory photoreceptors, including phytochromes (that principally absorb red and far-red energy) and blue light receptors, has advanced considerably in the recent past, the mechanisms of light signal transduction in higher plants are poorly understood. To unravel the molecular events associated with light-regulated plant development, a large number of photomorphogenic mutants have been isolated in several different plant species, including Arabidopsis, cucumber, tomato, pea, Brassica and Sorghum, which are either impaired in normal perception of light signal (photoreceptor mutants) or are affected in some specific or a sub-set of phenotypic traits (signal transduction mutants). Their physiological and molecular analysis is proving to be valuable in (1) assigning specific function to discrete phytochrome species, (2) elucidation of elements that constitute the transduction pathway downstream of signal perception, and (3) determining how different photosensory systems regulate many diverse responses. The progress made in the analysis of photomorphogenic mutants, as reviewed in this article, clearly indicates that multiple photoreceptors, either of the same or different class, interact through an intricate network of signal transduction pathways to finally determine the light-dependent phenotype of both monocots and dicots.     

蓝光、紫外光的受体及其对CHS表达诱导的研究

植物在进化过程中形成了对环境信号反应的能力,光是植物生长发育中的一个重要的环境信号,综述了蓝光,紫外光的受体及蓝光,紫外光对编码植物类黄酮合成中的一个重要的限速酶－苯基苯乙烯酮合酶基因CHS的诱导作用,并介绍该反应信号转导的可能组分。     

Photobiology: Light signal transduction and photomorphogenesis

正Light is crucial for plants, not only because of photosynthesis, but also because of photomorphogenesis. As one of the most important environmental cues, light influences multiple responses in plants,including seed germination, seedling de-etiolation,shade avoidance, phototropism, stomata and chloroplast movement, circadian rhythms, and flowering     

The grand design of photosynthesis: Acclimation of the photosynthetic apparatus to environmental cues

Dynamic acclimation of the photosynthetic apparatus in response to environmental cues, particularly light quantity and quality, is a widely-observed and important phenomenon which contributes to the tolerance of plants against stress and helps to maintain, as far as possible, optimal photosynthetic efficiency and resource utilization. This mini-review represents a scrutiny of a number of possible photoreceptors (including the two photosystems acting as light sensors) and signal transducers that may be involved in producing acclimation responses. We suggest that regulation by signal transduction may be effected at each of several possible points, and that there are multiple regulatory mechanisms for photosynthetic acclimation.Abbreviations FR far-red light - LHC I, LHC II light-harvesting chlorophyll a/b-protein complex of PS I and PS II, respectively - P700 primary electron donor of PS I - Pmax maximum photosynthetic capacity - Q_A primary quinone electron acceptor of PS II - q_N, q_P non-photochemical and photochemical quenching, respectively - R red light     

大型真菌光受体及其功能研究进展

真菌通过光受体感受光信号,光除了调控大型真菌生理周期、形态变化和代谢产物产生外,还是大多数大型真菌原基分化和子实体生长的必要条件。本文对近年来大型真菌的光反应和光受体研究进行了概述。大型真菌中光受体研究目前仅限于WC-1同源蛋白,WC-1既有对光信号应答的能力,同时作为转录因子,又能激活下游基因的表达,但是不同物种中可能存在不同的靶基因。wc-1基因敲除造成裂褶菌、蛹虫草子实体发育阻断。光受体及其作用机制的研究将为大型真菌子实体发育机制研究奠定基础。     

鲫鱼视网膜锌离子分布的光、电镜观察

本文应用ｎｅｏ－Ｔｉｍｍ染色法,观察了鲫鱼视网膜内锌离子的分布情况以及明,暗适应条件下鲫鱼视网膜内锌离子分布的变化。结果发现,明适应条件下,外网层、部分光感受器、双极细胞、无长突细胞以及神经节细胞胞体锌离子着色明显,含锌光感受器和双极细胞的突起伸入外网层,暗适应条件下,外网层锌离子染色减弱或消失（Ｐ〈０．０１）。外核层胞体锌离子染色阴性,少数散在分布的视锥细胞呈锌离子阳性,上述资料提示,明适应条件     

An Arabidopsis protein closely related to Synechocystis cryptochrome is targeted to organelles

Cryptochromes (CRYs) are blue/UV-A photoreceptors related to the DNA repair enzyme DNA photolyase. They have been found in plants, animals and most recently in the cyanobacterium Synechocystis. Closely related to the Synechocystis cryptochrome is the Arabidopsis gene At5g24850. Here, we show that the encoded protein of At5g24850 binds flavin adenine dinucleotide (FAD). It has no photolyase activity, and is likely to function as a photoreceptor. We have named it At-cry3 to distinguish it from the other Arbabidopsis cryptochrome homologues At-cry1 and At-cry2. At-cry3 carries an N-terminal sequence, which mediates import into chloroplasts and mitochondria. Furthermore, we show that At-cry3 binds DNA. DNA binding was also demonstrated for the Synechocystis cryptochrome, indicating that both photoreceptors could have similar modes of action. Based on the finding of a new cryptochrome class in bacteria and plants, it has been suggested that cryptochromes evolved before the divergence of eukaryotes and prokaryotes. However, our phylogenetic analyses are also consistent with an alternative explanation that the presence of cryptochromes in the plant nuclear genome is the result of dual horizontal gene transfer. That is, CRY1 and CRY2 genes may originate from an endosymbiotic ancestor of modern-day alpha-proteobacteria, while the CRY3 gene may originate from an endosymbiotic ancestor of modern-day cyanobacteria.     

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.     

植物异三聚体G蛋白研究进展

异三聚体鸟嘌呤核苷结合蛋白（简称G蛋白）是真核细胞中保守的信号转导分子,通常与G蛋白偶联受体一起将细胞外信号传递到胞质中。许多研究表明植物G蛋白介导的信号转导途径在光、激素、糖等响应过程中发挥着精细的调控作用。本文重点介绍近年来植物G蛋白在复合体组成、生化特性及其工作模式等方面的研究进展。     

Phytochrome structure and photochemistry: recent advances toward a complete molecular picture

Phytochromes are nature's primary photoreceptors dedicated to detecting the red and far-red regions of the visible light spectrum, a region also essential for photosynthesis and thus crucial to the survival of plants and other photosynthetic organisms. Given their roles in measuring competition and diurnal/seasonal light fluctuations, understanding how phytochromes work at the molecular level would greatly aid in engineering crop plants better suited to specific agricultural settings. Recently, scientists have determined the three-dimensional structures of prokaryotic phytochromes, which now provide clues as to how these modular photoreceptors might work at the atomic level. The models point toward a largely unifying mechanism whereby novel knot, hairpin, and dimeric interfaces transduce photoreversible bilin isomerization into protein conformational changes that alter signal output.